JP2021083517A - Game machine - Google Patents

Abstract

To provide a novel game machine.SOLUTION: In a command transmitted from frame control to a CM board (an exclusive unit), there are different pieces of information transmitted in different cycles (for example, a command of fraudulence monitoring information and a command of game machine installation information). When cycles overlap, the command of the fraudulence monitoring information is prioritized. To be specific, frame control notifies CM of the game machine information. As the game machine information, there are 3 pieces of information, which are game machine installation information, game machine performance information, and parlor computer fraudulence monitoring information, and any one is notified in accordance with a notification condition of the respective pieces of information. As the game machine information notification, an order of priority is set and, when notification conditions overlap, notification is given in accordance with the order of priority.SELECTED DRAWING: Figure 350

Description

The present invention relates to a gaming machine that executes a game.

Patent Document 1 describes a pachinko machine in which different jackpot probabilities are set according to a set value.

Japanese Unexamined Patent Publication No. 5-285258

In recent years, only similar gaming machines have been proposed, and innovative gaming machines are desired. This point is the same for both pachinko machines and slot machines.

Therefore, an object of the present invention is to provide a novel gaming machine.

The present invention employs the following solutions to solve the above problems. The following solutions and the wording in parentheses are merely examples, and the present invention is not limited thereto. In addition, the present invention can be an invention including at least one specific matter for each invention shown in the following solutions. Further, each invention specifying matter shown in the following solution can be made into a subordinate concept by adding an element limiting the invention specifying matter, and can be made into a higher concept by deleting the element limiting the invention specifying matter. ..

[Basic configuration of managed gaming machines]
Solution 1: The gaming machine of the present solution includes a main control board, a frame control board that can communicate with the main control board, and a communication control means that enables communication between the frame control board and an external unit. It is a gaming machine.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board of (1) above is provided. A frame control CPU is mounted on the frame control board.

(3) A communication control means (dedicated interface, a dedicated cable, and devices, boards, circuits, CPUs, software, programs associated therewith) that enable communication between the frame control board and an external unit (dedicated unit) is provided.

According to this solution, since the frame control board is provided with a communication control means that enables communication between the frame control board and the external unit, the frame control board can exchange information (signals) with the external unit, and as a result, , Can provide a novel gaming machine.

[(1) Configuration of ball pulling operation]
Solution (1) -1: The gaming machine of the present solution is connected to a main control board, a frame control board capable of communicating with the main control board, and the frame control board, and takes out a game medium from the game machine. The eject button that triggers the transition to the ejectable state, the display device that can display the number of game media, the power is turned on while pressing the eject button, and the display content of the display device is special. When it is the display content, it is a gaming machine provided with a take-out state transition means that enables the shift to the take-out state.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board of (1) above is provided. A frame control CPU is mounted on the frame control board.

(3) It is connected to the frame control board of (2) above, and serves as an opportunity to shift to a take-out state (ball pulling operation, medal pulling operation) in which a game medium (game ball, game medal) can be taken out from the game machine. Ejection buttons (ball removal button, ball removal switch, medal removal button, medal removal button) are provided.

(4) A display device (display device for the number of game balls, etc.) capable of displaying the number of game media is provided.
(5) The power is turned on while pressing the eject button of (3) above, and the display content of the display device of (4) above is a special display content (for example, the number of game media = 0, the number of game media). = When the value is a predetermined fixed value, a numerical value within a predetermined range, etc.), a take-out state transition means (main control board, frame control board) that enables the shift to the take-out state is provided.

According to the present solution, it is possible to shift to the taking-out state (ball pulling operation) under appropriate conditions, and as a result, it is possible to provide a novel gaming machine.

[(2) Configuration of ball pulling operation 2]
Solution (2) -1: The gaming machine of the present solution is connected to a main control board, a frame control board capable of communicating with the main control board, and the frame control board, and takes out a game medium from the game machine. The main control board is provided with a take-out button that triggers a shift to the take-out state, and a take-out state shift means that enables the shift to the take-out state when the power is turned on while pressing the take-out button. When, during the take-out state, information in the take-out state indicating that the take-out state is being received is received from the frame control board by communication with the frame control board at the time of turning on the power, the game is played until the power is turned off. It is a gaming machine characterized in that it is possible to shift to a gaming stopped state.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board of (1) above is provided. A frame control CPU is mounted on the frame control board.

(3) It is connected to the frame control board of (2) above, and serves as an opportunity to shift to a take-out state (ball pulling operation, medal pulling operation) in which a game medium (game ball, game medal) can be taken out from the game machine. Ejection buttons (ball removal button, ball removal switch, medal removal button, medal removal button) are provided.

(4) The take-out state transition means (main control board, frame control board) that can shift to the take-out state when the power supply is turned on while pressing the take-out button of the above (3) is provided.

(5) The main control board of (1) is being taken out from the frame control board of (2) by communication with the frame control board of (2) when the power is turned on. When the information in the take-out state indicating the above is received, it is possible to shift to the game stop state in which the game is stopped until the power is turned off.

According to the present solution, the main control board can be controlled to an appropriate state during the taking-out state (during the ball pulling operation), and as a result, a novel gaming machine can be provided.

[(3) Configuration of telegram reserve area and reserved area]
Solution (3) -1: The gaming machine of the present solution includes a main control board and a frame control board capable of communicating with the main control board using a predetermined message, and the predetermined message is the gaming machine. The gaming machine information indicating the information of the above is included, and the gaming machine information includes preliminary information for expansion. Regarding the preliminary information, even if a value other than the initial value is stored, it is regarded as an error on the receiving side. It is a gaming machine characterized by not being handled.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board of (1) above using a predetermined telegram (command, information, notification) is provided. A frame control CPU is mounted on the frame control board.

(3) The predetermined telegram in (2) above includes game machine information indicating information on the game machine.
(4) The gaming machine information in (3) above includes preliminary information for expansion.
(5) Regarding the preliminary information in (4) above, even if a value other than the initial value is stored, the receiving side (at least one of the main control board and the frame control board) does not treat it as an error.

According to this solution, it is possible to configure a telegram that can respond to future specification changes, and it is possible to perform error handling that is not too excessive, and as a result, it is possible to provide a novel gaming machine.

[(4) Composition of telegram serial numbers]
Solution (4) -1: The gaming machine of the present solution includes a main control board, a frame control board capable of communicating with the main control board and an external unit using a predetermined telegram, and the frame control board is , When communicating with the external unit, a telegram to be transmitted to the external unit is created, and the telegram includes an independent serial number for each type of telegram, and when the frame control board communicates with the external unit. The serial number of is initialized to 0 when the power is turned on, and if the telegram is created normally, the serial number of the same type of telegram notified last time is +1. If the serial number notified last time is the maximum value, the serial number is +2. It is a gaming machine characterized by being set to 1.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board and the external unit (dedicated unit) of the above (1) using a predetermined telegram is provided. A frame control CPU is mounted on the frame control board.

(3) The frame control board of (2) above creates a telegram to be transmitted to the external unit when communicating with the external unit.
(4) The telegram includes an independent serial number (serial number) for each type of telegram.

(5) The serial number when the frame control board communicates with the external unit is initialized to 0 when the power is turned on, and if the telegram is created normally, the serial number of the same type of telegram notified last time is set to +1. When the notified serial number is the maximum value (for example, when it is 255), the serial number is +2, which is 1.

According to this solution, the serial number is configured to be "0" only when the power is turned on, and can be distinguished from the serial number used at other timings. As a result, it is possible to provide a novel gaming machine. it can.

Solution (4) -2: In any of the above-mentioned solutions, the gaming machine of the present solution transmits the main control board to the frame control board when communicating with the frame control board. A telegram is created, the telegram includes an independent serial number for each type of telegram, and the serial number when the main control board communicates with the frame control board is initialized to 0 when the power is turned on, and the telegram is created normally. If this is done, the serial number of the same type of telegram notified last time is +1. If the serial number notified last time is the maximum value, the serial number is +1.

The following features are added in the present solution.
(1) The main control board creates a telegram to be transmitted to the frame control board when communicating with the frame control board.
(2) The telegram includes an independent serial number for each type of telegram.
(3) The serial number when the main control board communicates with the frame control board is initialized to 0 when the power is turned on, and if the telegram is created normally, the serial number of the same type of telegram notified last time is set to +1. When the serial number notified last time is the maximum value (for example, when it is 255), the serial number is +1 and is set to 0.

According to the present solution, since "0" is used as the serial number even when the power is not turned on, more serial numbers can be used, and as a result, a novel gaming machine can be provided.

[(5) Configuration of display device for the number of game balls, etc.]
Solution (5) -1: The gaming machine of the present solution includes a storage means capable of storing the number of game media in a predetermined number of bytes, and the number of game media that can be stored in the storage means is predetermined. An upper limit number is set, and the predetermined upper limit number is smaller than the maximum number that can be stored in the predetermined number of bytes.

The gaming machine of the present solution has the following configurations.
(1) A storage means capable of storing the number of game media (game balls, game medals) in a predetermined number of bytes is provided. The number of game media and game media can be interpreted in the sense of the game value and the amount of game value when treated as data.
(2) A predetermined upper limit is set for the number of game media that can be stored in the storage means of (1) above.
(3) The predetermined upper limit number in (2) above is a number smaller than the maximum number that can be stored in a predetermined number of bytes.

According to this solution, even if a goto occurs, the damage can be suppressed by the upper limit number less than the maximum number, so that the damage of the goto can be suppressed, and as a result, a novel gaming machine can be provided. it can.

[(6) Setting the priority of the gaming machine information type]
Solution (6) -1: The gaming machine of the present solution includes a main control board and a frame control board capable of communicating with the main control board and the external unit, and the frame control board is provided with respect to the external unit. It is a gaming machine characterized in that different information is transmitted in different cycles, and when the cycles overlap, information with high priority is transmitted.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board and the external unit (dedicated unit) of the above (1) is provided. A frame control CPU is mounted on the frame control board.

(3) The frame control board of the above (2) transmits different information one by one to the external unit at different cycles, and when the cycles overlap, only one high-priority information is transmitted.

According to the present solution, it is possible to prevent a problem when the information transmission timings are duplicated, and as a result, it is possible to provide a novel gaming machine.

[(7) Processing for calculating performance information]
Solution (7) -1: The gaming machine of this solution includes a main control board and a frame control board that can communicate with the main control board, and the main control board is specified for the first time after the power is turned on. With the command, the frame control board transmits the performance information status notification required for the frame control board to generate the performance information to the frame control board, and the frame control board receives the performance information status notification from the main control board. It is a gaming machine characterized by generating the performance information based on the above.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board capable of communicating with the main control board of (1) above is provided. A frame control CPU is mounted on the frame control board.

(3) The main control board of (1) above is required for the frame control board of (2) above to generate performance information by the first specific command (for example, game machine information) after the power is turned on. The performance information status notification is transmitted to the frame control board of (2) above.

(4) The frame control board of the above (2) generates performance information based on the performance information status notification received from the main control board of the above (1).

According to the present solution, performance information can be quickly generated (calculated) on the frame control board immediately after the power is turned off and restored, and as a result, a novel gaming machine can be provided.

[(8) Dedicated cable disconnection]
Solution (8) -1: The gaming machine of this solution is a game when the connection confirmation power input from an external unit and the connection confirmation power supply are switched from ON to OFF while the gaming machine is running. It is a gaming machine equipped with a launch control means that makes it impossible to launch a ball.

The gaming machine of the present solution has the following configurations.
(1) A connection confirmation power supply (VL) input from an external unit (dedicated unit) is provided.
(2) Launch control means (main control board, frame control board) for disabling the launch of the game ball when the connection confirmation power supply of the above (1) is switched from ON to OFF during the activation of the gaming machine. Has been done.

According to this solution, the connection status with the external unit is confirmed by the connection confirmation power supply, and if the connection cannot be confirmed, the gaming ball cannot be launched, so that the gaming machine and the external unit are normally connected. It is possible to prevent the game from being executed in a state where the game is not played, and as a result, it is possible to provide a novel game machine.

Solution (8) -2: In any of the above-mentioned solutions, the game machine of the present solution switches the connection confirmation power supply from ON to OFF during the startup of the game machine, and the game ball cannot be launched. It is a gaming machine provided with working memory increasing means (main control board, frame control board, effect control board) that increases the working memory of the symbol when the starting opening prize is won.

According to this solution, even in a state where the game ball cannot be launched, the operation memory of the symbol (hold displayed by the main control control board, hold displayed by the effect control board) when the start opening prize is won is performed. ) To increase, protect the starting mouth winning by the game ball fired before the launch is disabled, and check whether the game machine is operating normally by the starting mouth winning by the care of the staff. As a result, it is possible to provide a novel gaming machine.

[(9) Main control state 1]
Solution (9) -1: The gaming machine of this solution stores special main control state information, which is 1-byte information capable of holding up to 8 bits of bit information that treats 1 bit as one flag. In a possible gaming machine, 0 of the bit information can be treated as a flag OFF, 1 of the bit information can be treated as a flag ON, and the special main control state information is The first specific bit information that turns on the flag during a predetermined jackpot, the second specific bit information that turns on the flag during all the jackpots, and the second specific bit information that turns on the flag during the jackpot that shifts to a predetermined state after the jackpot. It is possible to hold the specific bit information of 3, and the special main control state information can be treated as a numerical value of 255 or less by combining a plurality of the bit information including the first to third specific bit information. The third specific bit is set as a numerical value 1 when only the first specific bit information is ON, and as a numerical value 2 when only the second specific bit information is ON. When only the information is ON, it can be treated as a numerical value 4, each having at least 1 or more unused bits, and 0 is held in the unused bits. It is a game machine to play.

The gaming machine of the present solution has the following configurations.
(1) A gaming machine capable of storing special main control state information (main control state 1), which is 1-byte information capable of holding up to 8 bits of bit information that treats 1 bit as one flag.

(2) 0 of the bit information in (1) above can be treated as a flag OFF.
(3) 1 of the bit information in (1) above can be treated as a flag ON.

(4) The special main control state information in (1) above includes a first specific bit information in which the flag is turned on during a predetermined jackpot, a second specific bit information in which the flag is turned on during all jackpots, and a jackpot. It is possible to hold the third specific bit information that the flag is turned on during the big hit that later shifts to a predetermined state.

(5) The special main control state information of (1) above can be treated as a numerical value of 255 or less by combining a plurality of bit information including the first to third specific bit information. The first specific bit information can be Bit0 information, the second specific bit information can be Bit1 information, and the third specific bit information can be Bit2 information (Bit2 information). The same applies below).

(6) The special main control state information in (1) above is set to a numerical value 1 when only the first specific bit information is ON, and when only the second specific bit information is ON. Can be treated as a numerical value 2 and as a numerical value 4 when only the third specific bit information is ON, and has at least one unused bit and is an unused bit. Is held at 0. When a plurality of specific bit information is ON, it is preferable that numerical values can be added and handled.

According to this solution, by collectively managing the jackpot state, a predetermined state, etc., it is easy for the administrator to grasp the internal state of the gaming machine, and by holding it as bit information, the capacity is reduced. As a result, it is possible to provide a novel gaming machine.

[(10) Main control state 2]
Solution (10) -1: The gaming machine of this solution stores special main control state information, which is 1-byte information capable of holding up to 8 bits of bit information that treats 1 bit as one flag. In a possible gaming machine, 0 of the bit information can be treated as a flag OFF, 1 of the bit information can be treated as a flag ON, and the special main control state information is At least the first specific bit information whose flag is ON during the jackpot, at least the second specific bit information whose flag is ON when the winning probability of the special symbol lottery is high, and at least the fluctuation time of the normal symbol or the special symbol. It is possible to hold the third specific bit information whose flag is ON during the time reduction state in which is shortened, and the special main control state information includes a plurality of the first to third specific bit information. It can be treated as a numerical value of 255 or less by combining bit information, and when only the first specific bit information is ON, it is set as the numerical value 1 and only the second specific bit information is ON. If there is, it can be treated as a numerical value 2, and if only the third specific bit information is ON, it can be treated as a numerical value 4, and it has at least 1 or more unused bits. The gaming machine is characterized in that 0 is held in the unused bit.

The gaming machine of the present solution has the following configurations.
(1) A gaming machine capable of storing special main control state information (main control state 2), which is 1-byte information capable of holding up to 8 bits of bit information that treats 1 bit as one flag.

(2) 0 of the bit information in (1) above can be treated as a flag OFF.
(3) 1 of the bit information in (1) above can be treated as a flag ON.

(4) The special main control state information of the above (1) is at least the first specific bit information in which the flag is turned on during the big hit, and at least the second specific bit information in which the flag is turned on when the winning probability of the special symbol lottery is high. It is possible to hold the specific bit information of the above and at least the third specific bit information whose flag is turned ON during the time reduction state in which the fluctuation time of the normal symbol or the special symbol is shortened.

(5) The special main control state information of the above (1) can be treated as a numerical value of 255 or less by combining a plurality of bit information including the first to third specific bit information.

(6) The special main control state information in (1) above is set to a numerical value 1 when only the first specific bit information is ON, and when only the second specific bit information is ON. Can be treated as a numerical value 2 and as a numerical value 4 when only the third specific bit information is ON, and has at least one unused bit and is an unused bit. Is held at 0. When a plurality of specific bit information is ON, it is preferable that numerical values can be added and handled.

According to this solution, by managing various internal states collectively, it is easy for the administrator to grasp the internal state of the gaming machine, and by holding it as bit information, the capacity is reduced, and as a result, it is novel. Can provide a variety of gaming machines.

[(11) Display device for the number of game balls, etc.]
Solution (11) -1: The gaming machine of the present solution is a gaming machine provided with a display device capable of displaying the number of game media, and the display device has a maximum displayable value in one business hour. It is a gaming machine characterized in that it can display a value exceeding the maximum number of gaming media that may be obtained.

The gaming machine of the present solution has the following configurations.
(1) A gaming machine provided with a display device (display device such as a gaming ball) capable of displaying the number of gaming media.
(2) As the maximum value that can be displayed, the maximum value of the game medium that can be obtained in one business hour (about 12 to 15 hours for normal business, about 36 to 40 hours for special business). It is possible to display a value (for example, 500,000 to 999999, preferably 990000) exceeding the number (for example, assuming that 10,000 shots are paid out per hour on average, maximum 10,000 shots x maximum 40 hours = 400,000). is there.

According to this solution, even if a player obtains a game profit that greatly deviates from the average probability when playing a game for a long time, it is possible to prevent a situation in which the display cannot be displayed on the display device. As a result, it is possible to provide a novel gaming machine.

[(12) Game ball (number of medals) clear switch]
Solution (12) -1: The gaming machine of this solution is connected to a frame control board that can communicate with the main control board and the main control board and can store backup information, and the frame control board. It is a gaming machine including a predetermined switch and an initialization means that enables initialization of the backup information when the predetermined switch is operated by a predetermined operation.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.

(2) A frame control board that can communicate with the main control board of (1) above and can store backup information about the game medium is provided. A frame control CPU is mounted on the frame control board.

(3) A predetermined switch (game ball clear switch) connected to the frame control board of (2) above is provided. The predetermined switch is a switch other than the RAM clear switch that clears the backup information related to the game information.

(4) When a predetermined switch is operated by a predetermined operation (for example, when the power is turned on while pressing the game ball clear switch), the initialization processing execution means (frame control) that initializes the backup information related to the game medium. Substrate) is provided. The frame control board can back up backup information about the game medium.

According to the present solution, the backup information related to the game medium can be individually initialized by operating a predetermined switch (only the backup information related to the game medium is initialized without operating the RAM clear switch). As a result, it is possible to provide a novel gaming machine.

[(13) CM start confirmation]
Solution (13) -1: The gaming machine of this solution is a game ball when the connection confirmation power input from the external unit and the connection confirmation power supply are not turned on after the start of the game machine is completed. It is a gaming machine equipped with a launch control means that makes it impossible to launch.

The gaming machine of the present solution has the following configurations.
(1) A connection confirmation power supply (VL) input from an external unit (dedicated unit) is provided.
(2) Launch control means (main control board, frame control board) for disabling the launch of the game ball are provided when the connection confirmation power supply of the above (1) is not turned on after the start of the gaming machine is completed. There is.

According to this solution, if the gaming machine is activated while the external unit is not activated, the gaming ball cannot be launched, so that the game is executed when the external unit is not activated. As a result, it is possible to provide a novel gaming machine.

Solution (13) -2: In any of the above-mentioned solutions, the game machine of the present solution cannot launch the game ball because the connection confirmation power is not turned on after the start of the game machine is completed. It is a gaming machine characterized in that it is provided with a symbol changing means (main control board, frame control board) that starts the fluctuation of the symbol when the gaming ball wins a prize in the starting port even in the above-mentioned state.

According to this solution, even in a state where the game ball cannot be launched, when the game ball wins a prize at the starting port, the symbol starts to fluctuate, so that the ball is launched before the launch is disabled. It is possible to change the design by winning the starting mouth with the game ball, and to check whether the game machine is operating normally by winning the starting mouth by the care of the staff, and as a result, providing a novel game machine. can do.

[(14) Game information]
Solution (14) -1: The gaming machine of this solution is a main control board, a frame control board capable of communicating with the main control board using a predetermined message, and a connection confirmation power supply input from an external unit. The predetermined message includes game information indicating game information, the game information includes type information and count information corresponding to the type information, and the type information is a prize or a prize. The count information is information indicating the occurrence of passage, the count information is information indicating the number or number of times corresponding to the type information, and the type information and the count information are information corresponding to one-to-one. The information is not held more than the other information, and when a start opening prize occurs, the upper 4 bits of the type information are set to a numerical value corresponding to the start opening prize, and the game information is of the type information. A numerical value corresponding to the position of the starting port that has won a prize in the lower 4 bits is set, a numerical value corresponding to the number of prize balls at the time of winning the starting opening is set in the upper 4 bits of the count information, and the lower 4 bits of the count information are set. A value corresponding to the number of winnings is set, and when the starting port winnings occur a plurality of times within a predetermined period, a plurality of game informations are created corresponding to the number of occurrences, and when the start-up of the game machine is completed, the connection confirmation power supply is created. When is OFF, the state in which the game ball cannot be launched is maintained until the connection confirmation power is turned ON, but the message including the game information is periodically transmitted, and after the start of the game machine is completed, the above-mentioned When the connection confirmation power is switched from ON to OFF, the state in which the game ball cannot be launched is maintained until the connection confirmation power is turned ON, but the predetermined message including the game information is periodic. The game machine is characterized in that the period of the predetermined message transmitted to and periodically is allowed to deviate from a period equal to or less than a predetermined value.

The gaming machine of the present solution has the following configurations.
(1) A main control board is provided. A main control CPU is mounted on the main control board.
(2) A frame control board capable of communicating with the main control board of (1) above using a predetermined telegram is provided. A frame control CPU is mounted on the frame control board.
(3) A power supply for connection confirmation input from an external unit (dedicated unit) is provided.

(4) The predetermined telegram in (2) above includes game information indicating game information.
(5) The game information in (4) above includes type information and count information corresponding to the type information.

(6) The type information of (5) above is information indicating the occurrence of winning (winning to the winning opening) or passing (passing through the starting gate or a specific area).

(7) The count information in (5) above is information representing the number or number of times corresponding to the type information in (6) above.

(8) The type information and the count information are information having a one-to-one correspondence, and one information is not held more than the other information.

(9) In the game information, when the start opening prize has been generated since the previous message transmission, the upper 4 bits of the type information are set to the numerical values corresponding to the start opening prize, and the lower 4 bits of the type information are won. A numerical value corresponding to the position of the starting port is set, a numerical value corresponding to the number of prize balls at the time of winning the starting port is set in the upper 4 bits of the count information, and a value corresponding to the number of winnings is set in the lower 4 bits of the count information. Set.

(10) A plurality of game information is created according to the number of times the start opening prize is generated within a predetermined period, and when the power for connection confirmation is turned off when the start of the game machine is completed, the game information is for connection confirmation. The state in which the game ball cannot be launched is maintained until the power is turned on, but the telegram containing the game information is periodically transmitted, and the connection confirmation power is switched from ON to OFF after the start of the game machine is completed. In this case, the state in which the game ball cannot be launched is maintained until the connection confirmation power is turned on, but a predetermined telegram including the game information is periodically transmitted.

(11) The period of a predetermined message transmitted periodically is allowed to deviate from a period equal to or less than a predetermined value.

According to the present solution, it is possible to grasp detailed game information of the game machine, and as a result, it is possible to provide a novel game machine.

Solution (14) -2: In any of the above-mentioned solutions, even if the connection confirmation power is turned off when the game machine is started, the gaming machine of the present solution wins a prize at the starting port. It is possible to increase the working memory of the symbol, and even if the connection confirmation power is switched from ON to OFF after the gaming machine is started, the working memory of the symbol can be increased when the start opening prize is won. It is a gaming machine characterized by being provided with means (main control board, frame control board, effect control board).

According to this solution, even if the connection confirmation power is turned off when the gaming machine is started, the operation memory of the symbol (holding displayed by the main control control board and the effect control board) is displayed when the start opening prize is won. It is possible to increase the number of holdings to be displayed), and even if the connection confirmation power is switched from ON to OFF after the gaming machine is started, it is possible to increase the working memory of the symbol when the starting opening prize is won. Even if the power for connection confirmation is turned off in some situations, it is necessary to protect the starting port winning by the game ball and check whether the gaming machine is operating normally by the starting opening winning by the care of the staff. As a result, it is possible to provide a novel gaming machine.

[(15) Fraud detection state 1]
Solution (15) -1: The gaming machine of this solution stores special fraud detection status information, which is 1-byte information capable of holding up to 8 bits of bit information that treats 1 bit as one flag. In a possible gaming machine, 0 of the bit information can be treated as a flag OFF, 1 of the bit information can be treated as a flag ON, and the special fraud detection state information is It is possible to hold the first specific bit information that turns on the flag while changing the setting, the second specific bit information that turns on the flag while checking the setting, and the third specific bit information that turns on the flag when the RAM is cleared. Yes, the special fraud detection state information can be treated as a numerical value of 255 or less by combining a plurality of the bit information including the first to third bit information, and only the first specific bit information is ON. If it is, it is set as a numerical value 1, if only the second specific bit information is ON, it is set as a numerical value 2, and if only the third specific bit information is ON, it is set as a numerical value 2. The gaming machine is characterized in that it can be treated as a numerical value 4 and has at least 1 or more unused bits, and 0 is held in the unused bits.

The gaming machine of the present solution has the following configurations.
(1) A gaming machine capable of storing special fraud detection state information (fraud detection state 1), which is 1-byte information capable of holding up to 8 bits of bit information that treats 1 bit as one flag.

(2) 0 of the bit information in (1) above can be treated as a flag OFF.
(3) 1 of the bit information in (1) above can be treated as a flag ON.

(4) The special fraud detection status information in (1) above includes the first specific bit information whose flag is turned ON during setting change, the second specific bit information whose flag is turned ON during setting confirmation, and when the RAM is cleared. It is possible to hold the third specific bit information that turns on the flag.

(5) The special fraud detection state information in (1) above can be treated as a numerical value of 255 or less by combining a plurality of bit information including the first to third specific bit information.

(6) The special fraud detection status information in (1) above is set to a numerical value 1 when only the first specific bit information is ON, and when only the second specific bit information is ON. Can be treated as a numerical value 2 and as a numerical value 4 when only the third specific bit information is ON, and has at least one unused bit and is an unused bit. Is held at 0. When a plurality of specific bit information is ON, it is preferable that numerical values can be added and handled.

According to this solution, by collectively managing the states such as setting changes, it is easy for the administrator to grasp the internal state of the gaming machine, and by holding it as bit information, the capacity is reduced, and as a result, the capacity is reduced. It is possible to provide a novel gaming machine.

[Basic configuration of medalless pachinko machines]
SOLUTION: The gaming machine of the present solution means a main control unit capable of executing control related to a game, a medal number control unit capable of communicating with the main control unit and capable of executing control related to a game medal, and the medal. It is a gaming machine provided with a communication control means that enables communication between a number control unit and an external unit.

The gaming machine of the present solution has the following configurations.
(1) A main control unit (for example, a main control CPU, a main control rom) capable of executing control related to a game is provided.

(2) The number of medals control unit (for example, the number of medals control CPU, the number of medals) that can communicate with the main control unit of (1) above and can execute control related to game medals (calculation, calculation, etc. related to the number of game medals). Control rom) is provided.

The main control unit and the medal number control unit may be mounted on different boards (main control board, medal number control board), or may be mounted on the same board (main control board).
The main control unit and the medal number control unit may be mounted on different CPUs (main control CPU, medal number control CPU), or may be mounted on the same CPU (main control CPU).

(3) Communication control means (dedicated interface, dedicated cable, and associated devices, boards, circuits, CPUs, software) that enable communication between the medal number control unit of (2) above and an external unit (dedicated unit). , Program).

According to this solution, since the communication control means for enabling communication between the medal number control unit and the external unit is provided, the medal number control unit can exchange information (signal) with the external unit. As a result, it is possible to provide a novel gaming machine.

[(T1) Insertion control with the medal number control board]
Solution (T1) -1: The gaming machine of this solution can communicate with a main control board capable of executing control processing related to the game, the main control board, and an external unit, and has a game value (for example, a game medal). It is a gaming machine provided with a game value control board (for example, a medal number control board or other board) capable of executing a throwing control process related to the throwing of.
Further, the gaming machine of the present solution can communicate with the main control board capable of executing the control process related to the game, the main control board and the external unit, and the number of medals capable of executing the insertion control process related to the insertion of the game medal. It is a gaming machine equipped with a control board.

The gaming machine of the present solution has the following configurations.
(1) A main control board capable of executing control processing related to the game (control processing for advancing the game) is provided. A main control CPU is mounted on the main control board.

(2) It is possible to communicate with the main control board and the external unit (dedicated unit, sand) of the above (1), and execute the insertion control process (calculation process related to the number of game medals) related to the insertion of game medals (for example, bet). A possible number of medals control board is provided. A medal number control CPU is mounted on the medal number control board.

According to this solution, since the medal number control board can execute the insertion control process, the main control board does not need to execute the insertion control process, and the program capacity of the main control board can be reduced accordingly. The processing load on the main control board can be reduced, and as a result, a novel gaming machine can be provided.

Solution (T1) -2: The gaming machine of the present solution has a game value input button (for example, a game medal input button) that enables input of game value and a game value input button in any of the above-mentioned solutions. The game value control board is provided with a game value number display device (for example, a game medal number display device) capable of recording a number and displaying the number of recorded game values, and the game value control board is used as the input control process. When the operation of the game value input button is detected, the number of game values recorded on the game value number display device is subtracted, and the process of inputting the subtracted number of game values can be executed. It is a gaming machine.
Further, in the game machine of the present solution means, the game machine of the present solution means can record the game medal insertion button that enables the insertion of the game medal and the number of game medals in any of the above-mentioned solutions. The game medal number control board is provided with a game medal number display device capable of displaying the number of recorded game medals, and when the operation of the game medal insertion button is detected as the insertion control process, the game It is a gaming machine characterized in that a process of subtracting the number of game medals recorded on the medal number display device and inserting the subtracted number of game medals can be executed.

The following features are added in the present solution.
(1) A game medal insertion button (for example, a button for one bet, a button for MAX bet) is provided to enable insertion of a game medal (game medium, game value).
(2) A game medal number display device (game ball number display device) that can record the number of game medals (amount of game media, amount of game value) and can display the number of recorded game medals. It is provided.

(3) The medal number control board displays the number of game medals when the operation of the game medal insertion button is detected as the insertion control process (when the pressing of the button for 1 bet or the button for MAX bet is detected). It is possible to subtract the number of game medals recorded on the device (calculate -1 or -3) and insert the subtracted number of game medals (process of betting 1 or 3). To do.

According to this solution, the process of subtracting the number of game medals and the process of inserting game medals can be executed on the medal number control board side, so that the program capacity of the main control board can be reduced accordingly. , The processing load on the main control board can be reduced, and as a result, a novel gaming machine can be provided.

[(T2) Send the number of input and payouts without replay and with replay to the dedicated unit]
Solution (T2) -1: When the combination of symbols corresponding to the re-game is displayed on the predetermined effective line, the gaming machine of the present solution has a predetermined number of games without requiring input of new game value. A re-game execution means that enables the next game by setting a value and a communication control means that enables communication with an external unit are provided, and the communication control means is set by the re-game execution means. Information excluding the predetermined number of game values, which is the total number of input information (total number of input information) regarding the number of input of the game value accumulated from the time when the power is turned on, and the predetermined number set by the re-game execution means. It is a gaming machine characterized by transmitting total payout number information (total payout number information) regarding the number of payouts of game value accumulated from the time the power is turned on, which is information excluding the number of game values, to the external unit. ..
Further, in the gaming machine of the present solution, when a combination of symbols corresponding to the re-game is displayed on the predetermined effective line, a predetermined number of game medals are inserted without requiring the insertion of a new game medal. The re-game execution means for enabling the next game and the communication control means for enabling communication with the external unit are provided, and the communication control means is the predetermined number of games input by the re-game execution means. Information excluding medals, which is information on the total number of inserted game medals accumulated since the power was turned on, and information excluding the predetermined number of game medals inserted by the re-game execution means, which is the power supply. The gaming machine is characterized in that information on the total number of medals to be paid out regarding the number of medals to be paid out accumulated from the time of insertion is transmitted to the external unit.

The gaming machine of the present solution has the following configurations.
(1) When a combination of symbols corresponding to a replay is displayed on a predetermined effective line, a predetermined number of game medals are inserted without requiring a new game medal to be inserted, so that the next game is played. There is a re-game execution means that enables (automatically inputs the game value required for the next game).

(2) Communication control means (dedicated interface, dedicated cable, and devices, boards, circuits, CPUs, software, programs associated therewith) that enable communication with an external unit (dedicated unit) are provided.

(3) The communication control means of the above (2) is information excluding a predetermined number of game medals inserted by the re-game execution means, and is information on the total number of inserted game medals regarding the number of inserted game medals accumulated from the time when the power is turned on. In addition, the information excluding the predetermined number of game medals inserted by the re-game execution means and the total number of game medals to be paid out information accumulated from the time when the power is turned on is transmitted to the external unit.

According to this solution, since the total input number information and the total payout number information are transmitted to the external unit, the total input number information and the total number are appropriately input in the external unit, the hall computer connected to the external unit, and the external center. It becomes possible to monitor the payout number information, and as a result, it is possible to provide a novel gaming machine.

Further, since the total number of inserted information and the total number of paid-out information exclude the predetermined number of game medals inserted by the re-game execution means, the external unit or the like actually inserts or actually pays out. It is possible to accurately grasp the information of the game medals.

Solution (T2) -2: In any of the above-mentioned solutions, the communication control means includes information including the predetermined number of game values set by the re-game execution means. The information including the specified number information regarding the number of input game values (number of input sheets) in one game and the predetermined number of game values set by the re-game execution means is used for one game. A gaming machine characterized in that information on the number of payouts (information on the number of payouts) regarding the number of payouts (number of payouts) of the game value in the above is transmitted to the external unit.
Further, in any of the above-mentioned solving means, the gaming machine of the present solving means is information including the predetermined number of game medals inserted by the re-gaming executing means, and the communication controlling means once. Information on the specified number of game medals inserted in the game, and information including the predetermined number of game medals inserted by the re-game execution means, and information on the number of game medals paid out in one game. Is transmitted to the external unit, and the specified number information and the payout number information are treated as information for the external unit and as information for a hall computer connected to the external unit. It is a game machine.

The following features are added in the present solution.
(1) The communication control means is information including a predetermined number of game medals inserted by the re-game execution means, and is based on the specified number information regarding the number of game medals inserted in one game and the re-game execution means. Information including a predetermined number of inserted game medals and information on the number of game medals to be paid out in one game is transmitted to an external unit.

(2) It is preferable that the specified number information and the payout number information are treated as information for the external unit and as information for the hall computer connected to the external unit.

According to this solution, in order to transmit the specified number information and the payout number information to the external unit, the specified number information and the payout number information are appropriately transmitted to the external unit, the hall computer connected to the external unit, and the external center. It becomes possible to monitor, and as a result, it is possible to provide a novel gaming machine.

Further, since the specified number information and the payout number information include the predetermined number of game medals inserted by the re-game execution means, the external unit or the like actually inserts or actually pays out the game. Not only the medal information but also the information including the replay can be accurately grasped.

Further, according to the present solution, the specified number information and the payout number information are treated as information for the external unit and as information for the hall computer connected to the external unit. Therefore, the specified number information and the payout number information Can be treated as the same information by both the external unit and the hall computer, and as a result, a novel gaming machine can be provided.

Solution (T2) -3: In any of the above-mentioned solutions, the communication control means has input game value information (information on the number of inserted medals) regarding the number of input game values. The gaming machine is characterized in that information on the number of paid out game values (information on the number of paid out medals) regarding the number of paid out game values is transmitted to the external unit.
Further, in any of the above-mentioned solutions, the gaming machine of the present solution means that the communication control means has information on the number of inserted medals regarding the number of inserted game medals and the payout medals regarding the number of paid out game medals. The number information is transmitted to the external unit, and the inserted medal number information and the payout medal number information are treated as information for the external unit and not as information for a hall computer connected to the external unit. It is a gaming machine characterized by this.

The following features are added in the present solution.
(1) The communication control means transmits information on the number of inserted medals regarding the number of inserted game medals and information on the number of paid medals regarding the number of paid out game medals to the external unit.

(2) It is preferable that the information on the number of inserted medals and the information on the number of paid medals are treated as information for the external unit and not as information for the hall computer connected to the external unit.

According to this solution, since the information on the number of inserted medals and the information on the number of paid medals are transmitted to the external unit, the information on the number of inserted medals and the information on the number of paid medals can be appropriately monitored by the external unit, and as a result, a novel game. Machines can be provided.

Further, according to this solution, the information on the number of inserted medals and the information on the number of paid medals are treated as information for the external unit and not as information for the hall computer connected to the external unit. It is possible to use the payout number information in the external unit but not in the hall computer, and as a result, it is possible to provide a novel gaming machine.

According to the present invention, it is possible to provide a novel gaming machine.

It is a front view of a pachinko machine. It is a rear view of a pachinko machine. It is a front view which shows the game board unit alone. It is a front view which shows the part of the game board unit enlarged. It is a block diagram which shows various electronic devices equipped in a pachinko machine. It is a block diagram which shows the internal function composition of an effect control device. It is a figure which shows the memory map of the memory area used by the main control CPU 72. It is a figure which shows the relationship between the set value and the winning probability of a special symbol lottery. It is a figure which shows the state of a setting key, whether or not a setting can be changed, and whether or not it can be inserted and removed. It is a flowchart which shows the 1st procedure example of the CPU initialization processing (1/2). It is a flowchart which shows the 1st procedure example of the CPU initialization processing (2/2). It is a figure which shows the command transmission timing of the 1st procedure example of the CPU initialization processing. It is a figure which shows the list of the game machine state. It is a figure which shows the distribution of processing at the time of power-on. It is a flowchart which shows the 2nd procedure example of the CPU initialization processing (1/2). It is a flowchart which shows the 2nd procedure example of the CPU initialization processing (2/2). It is a figure which shows the command transmission timing of the 2nd procedure example of the CPU initialization processing. It is a flowchart which shows the procedure example of the main loop processing. It is a figure which shows the content of the process which is executed when a serial communication reception interrupt occurs. It is a figure which shows the content of the process which is executed when a timer interrupt occurs. It is a figure which shows the content of the process which is executed when an interrupt occurs at the time of power-off notice. It is a flowchart which shows the procedure example of the serial communication reception interrupt processing. It is a flowchart which shows the procedure example of interrupt processing at the time of power-off notice. It is a flowchart which shows the procedure example of a timer interrupt processing. It is a flowchart which shows the procedure example of a dynamic port output processing. It is a flowchart which shows the procedure example of the performance display monitor output processing. It is a figure which shows the relationship between timer interrupt processing and dynamic port output processing. It is a figure which shows the modification form of a timer interrupt processing. It is a flowchart which shows the procedure example of the setting change processing (1/2). It is a flowchart which shows the procedure example of the setting change processing (2/2). It is a flowchart which shows the procedure example of a switch management process. It is a flowchart which shows the procedure example of the 1st special symbol memory update process. It is a flowchart which shows the procedure example of the 2nd special symbol memory update processing. It is a flowchart which shows the procedure example of the effect determination processing at the time of acquisition. It is a flowchart which shows the configuration example of the special game management process. It is a flowchart which shows the procedure example of the special symbol change preprocessing. It is a figure which shows an example of the variation pattern selection table (low-probability, high-probability non-time shortening state) at the time of loss. It is a figure which shows an example of the variation pattern selection table at the time of loss (low probability time shortening state). It is a figure which shows an example of the variation pattern selection table at the time of loss (high probability time shortening state). It is a figure which shows an example of the variation pattern selection table (special section) at the time of a break. It is a figure which shows the structural example of the 1st special symbol jackpot stop symbol selection table. It is a figure which shows the structural example of the 2nd special symbol jackpot stop symbol selection table. It is a figure which shows an example of the big hit time fluctuation pattern selection table (low probability, high probability non-time shortening state). It is a figure which shows an example of the big hit time fluctuation pattern selection table (low probability time shortening state). It is a figure which shows an example of the big hit time fluctuation pattern selection table (high probability time shortening state). It is a figure which shows an example of the big hit time fluctuation pattern selection table (special section). It is a flowchart which shows the procedure example of the variation pattern determination processing at the time of disconnection. It is a flowchart which shows the procedure example of the big hit time fluctuation pattern determination processing. It is a flowchart which shows the procedure example of the special symbol storage area shift processing. It is a flowchart which shows the procedure example of the process during the special symbol stop display. It is a flowchart which shows the procedure example of a special variation management process. It is a flowchart which shows the configuration example of the variable winning device management process at the time of a big hit. It is a flowchart which shows the procedure example of the big prize opening opening pattern setting processing at the time of a big hit. It is a flowchart which shows the procedure example of the opening and closing operation process of a big winning opening at the time of a big hit. It is a flowchart which shows the procedure example of the big prize opening closing process at the time of a big hit. It is a flowchart which shows the procedure example of the end processing at the time of a big hit. It is a flowchart which shows the procedure example of the special variation number setting process. It is a flowchart which shows the configuration example of the variable winning device management process at the time of a small hit. It is a flowchart which shows the procedure example of the large prize opening opening pattern setting processing at the time of a small hit. It is a flowchart which shows the procedure example of the opening and closing operation process of a large winning opening at the time of a small hit. It is a flowchart which shows the procedure example of the process of closing a large winning opening at the time of a small hit. It is a flowchart which shows the procedure example of the end processing at the time of a small hit. It is a flowchart which shows the configuration example of the LED display setting process. It is a flowchart which shows the procedure example of the external information management processing. It is a flowchart which shows the procedure example of the security signal management processing. It is a flowchart which shows the 1st procedure example of the addition number calculation process. It is a flowchart which shows the 2nd procedure example of the addition number calculation process. It is a figure which shows the relationship between the game state and the number of fired balls. It is a flowchart which shows the procedure example of the performance display monitor control processing. It is a flowchart which shows the procedure example of the ball number addition processing. It is a flowchart which shows the procedure example of the performance display monitor total division processing. It is a flowchart which shows the procedure example of the process of a division task 1. It is a flowchart which shows the procedure example of the process of a division task 2-8. It is a flowchart which shows the procedure example of the process of a division task 9. It is a figure explaining the display mode of the performance display monitor 200. It is a figure explaining the section of the base displayed on the performance display monitor 200. It is a figure explaining the calculation method of a base. It is a timing chart which shows the setting-related processing basic operation (1/3). It is a timing chart which shows the setting-related processing basic operation (2/3). It is a timing chart which shows the setting-related processing basic operation (3/3). It is a figure which shows the processing example at the time of power-on (the first processing example). It is a figure which shows the processing example at the time of power-on (the second processing example). It is a figure which shows the processing example at the time of power-on (the third processing example). It is a flowchart which shows the procedure example of the launch position management process. It is a figure explaining the game flow in the non-time reduction state. It is a figure explaining the game flow in the time shortened state. It is a continuous figure which shows the example of the effect image corresponding to the variable display and the stop display of a special symbol. It is a continuous figure which shows the flow of the reach production executed at the time of a big hit (winning). It is a figure which shows the production example of a challenge bonus production. It is a continuous figure which partially shows the production example of the treasure challenge production. It is a continuous figure which shows the production example of a fireworks rush. It is a continuous figure which partially shows the production example of the fireworks bonus production. It is a continuous figure which shows the production example of a normal bonus production partially. It is a continuous figure which shows the production example of the coast mode. It is a flowchart which shows the procedure example of the effect control processing. It is a flowchart which shows the procedure example of the working memory effect management process. It is a flowchart which shows the procedure example of the effect symbol management processing. It is a flowchart which shows the procedure example of the effect symbol change pre-processing. It is a flowchart which shows the procedure example of the big hit time variation effect pattern selection process. It is a flowchart which shows the procedure example of the variation effect pattern selection process at the time of disconnection. It is a flowchart which shows the procedure example of a mode effect management process. It is a flowchart which shows the configuration example of the processing at the time of operation of a variable winning device. It is a figure which shows the whole outline of the game machine management system. It is a figure which shows the schematic diagram (flow of machine history management) of a game machine management system. It is a figure which shows the schematic diagram (flow of security management) of a game machine management system. It is a figure which shows the connection image of a management game machine and a dedicated unit. It is a figure which shows the security enhancement item (1/4). It is a figure which shows the security enhancement item (2/4). It is a figure which shows the security enhancement item (3/4). It is a figure which shows the security enhancement item (4/4). It is a figure which shows the flow of the monitoring information. It is a figure which shows the exploded perspective view of the management gaming machine. It is a figure which shows the front view of the management game machine. It is a figure which shows the perspective view of the management gaming machine. It is a figure which shows the back view (the state with the back cover) of the management gaming machine. It is a figure which shows the back view (the state without the back cover) of the management gaming machine. It is a figure which shows the device to be mounted on the management game machine. It is a figure which shows the block diagram of the main control function. It is a figure which shows the list of fraud detected by the management game machine main control board. It is a figure which shows the block diagram of the prize ball control function. It is a figure which shows the error detected by the prize ball control function. It is a figure which shows the block diagram of the ball coin control function. It is a figure which shows the list of the error detected by the ball lending control function. It is a figure which shows the block diagram of the counting function. It is a figure which shows the condition of the number of counting balls. It is a figure which shows the block diagram of the display function such as the number of game balls. It is a figure which shows the block diagram of a security function. It is a figure which shows the block diagram of the information output function. It is a figure which shows the content which a dedicated unit outputs to a hall computer. It is a figure which shows the block diagram of the power supply function. It is a figure which shows the block diagram of a firing function. It is a figure which shows the block diagram of the game ball circulation function. It is a figure which shows the error detected by the game ball circulation function. It is a figure which shows the block diagram of the ball polishing function. It is a figure which shows the error detected by the ball polishing function. It is a figure which shows the block diagram of the power saving function. It is a figure which shows the block diagram of the night monitoring function. It is a figure which shows the block diagram of the iron ball detection function. It is a figure which shows the block diagram of the ball pulling function. It is a figure which shows the block diagram of the pause function. It is a figure which shows the error detection function (1/6). It is a figure which shows the error detection function (2/6). It is a figure which shows the error detection function (3/6). It is a figure which shows the error detection function (4/6). It is a figure which shows the error detection function (5/6). It is a figure which shows the error detection function (6/6). It is a figure which shows the block diagram of the light amount / volume adjustment function. It is a figure which shows the outer shape of a game board and the alignment hole with a management game machine frame. It is a figure which shows the dimension of a game area. It is a figure which shows the dimension of the back surface effective area. It is a figure which shows the structure of the launching apparatus. It is a figure which shows the structure of the launching device (handle). It is a figure which shows the operating principle of a launching apparatus. It is a figure explaining the operation principle that a ball feed solenoid pays out a game ball. It is a figure explaining the operation principle that a ball feed solenoid pays out a game ball. It is a figure explaining the operation principle that a ball feed solenoid pays out a game ball. It is a schematic diagram which shows the structure of the power supply device used in the management game machine used in the management game machine. It is a figure which shows the usage use of a power source and a signal. It is a figure which shows the connector and pin arrangement specifications. It is a figure which shows the specification of the main system power supply capacity. It is a figure which shows the specification of the sub system power supply capacity. It is a figure which shows the item to perform backup. It is a figure which shows the structure of the ball polishing apparatus. It is a figure which shows the operating principle of a ball polishing apparatus. It is a figure which shows the operating principle of a ball polishing apparatus. It is a figure which shows the operating principle of a ball polishing apparatus. It is a figure which shows the operating principle of a ball polishing apparatus. It is a figure which shows the structure of the game ball circulation device. It is a figure which shows the operation principle of the game ball circulation device. It is a figure which shows the operation principle of the game ball circulation device. It is a figure which shows the operation principle of the game ball circulation device. It is a figure which shows the touch panel type liquid crystal display. It is a figure which shows the outer frame security device. It is a figure which shows the outer frame security device. It is a figure which shows the iron ball detection apparatus. It is a figure which shows the block diagram of the management game machine. It is a figure which shows the block diagram of the management game machine. It is a figure which shows the block diagram of the management game machine. It is a figure which shows the whole circuit diagram of the management game machine main system 1. It is a figure which shows the whole circuit diagram of the management game machine main system 1. It is a figure which shows the whole circuit diagram of the management game machine main system 1. It is a figure which shows the whole circuit diagram of the management game machine main system 1. It is a figure which shows the whole circuit diagram of the management game machine main system 1. It is a figure which shows the whole circuit diagram of the management game machine main system 1. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine main system 2. It is a figure which shows the whole circuit diagram of the management game machine sub system. It is a figure which shows the whole circuit diagram of the management game machine sub system. It is a figure which shows the whole circuit diagram of the management game machine sub system. It is a figure which shows the whole circuit diagram of the management game machine sub system. It is a figure which shows the whole circuit diagram of the management game machine sub system. It is a figure which shows the whole circuit diagram of the management game machine game board main system. It is a figure which shows the whole circuit diagram of the management game machine game board main system. It is a figure which shows the whole circuit diagram of the management game machine game board main system. It is a figure which shows the whole circuit diagram of the management game machine game board main system. It is a figure which shows the whole circuit diagram of the management game machine game board main system. It is a figure which shows the whole circuit diagram of the management game machine game board main system. It is a figure which shows the connector pin arrangement specification. It is a figure which shows the reset signal. It is a figure which shows the circuit structure in the case of connecting the FG of a management game machine game board from a main drawer board without passing through a main control board. It is a figure which shows the circuit structure in the case of connecting the FG of a management game machine game board from a main drawer board via a main control board. It is a figure which shows the connector pin arrangement specification. It is a figure which shows the circuit structure of the interface between an effect control board and other effect devices. It is a figure which shows the block diagram including various switches and the like. It is a figure which shows the specification outline of the illumination part of the front decoration and the dot display part. It is a figure which shows the LED arrangement and the system diagram of the front decoration illumination part. It is a figure which shows the LED arrangement and the system diagram of the front decoration dot display part. It is a figure which shows the block diagram of the illumination part of the front decoration and the dot display part. It is a figure which shows the block diagram of the illumination part of the front decoration and the dot display part. It is a figure which shows the schematic specification of the main control CPU. It is a figure which shows the main control CPU terminal connection diagram. It is a figure which shows the terminal function list of the main control CPU. It is a figure which shows the terminal function list of the main control CPU. It is a figure which shows the schematic specification of the frame control CPU. It is a figure which shows the frame control CPU terminal connection diagram. It is a figure which shows the terminal function list of the frame control CPU. It is a figure which shows the terminal function list of the frame control CPU. It is a figure which shows the structure of the main control program. It is a figure which shows the structure of the frame control program. It is a figure which shows the communication condition of the main control board-frame control board interface. It is a figure which shows the block diagram of the user program interface. It is a figure which shows the detail of the game information. It is a figure which shows the detail of the type information. It is a figure which shows the detail of the count information. It is a figure which shows the detail of the game state information. It is a figure which shows the detail of the management game machine frame information. It is a flowchart which shows the procedure example of the process at power-on. It is a flowchart which shows the procedure example of the pause process. It is a flowchart which shows the procedure example of the return process from a pause. It is a figure which shows the procedure example of the process at the time of communication abnormality detection. It is a figure which shows the procedure example of the recovery process from a communication abnormality. It is a figure which shows the game board size. It is a figure which shows the game area. It is a figure which shows the main dimension of the game machine frame. It is a figure which shows the dimension of the discharge passage. It is a figure which shows the mechanism of the return ball detection. It is a figure which shows the mechanism of power-off. It is a figure which shows the mechanism of a ball pulling out. It is a figure which shows the speaker. It is a figure which shows the launcher. It is a figure which shows the polishing machine. It is a figure which shows the mechanism of iron ball detection. It is a figure which shows the system block diagram of the management game machine. It is a figure which shows the communication condition. It is a figure which shows the outline of the data structure. It is a figure which shows the detail of a data structure. It is a figure which shows the list of the message between the main control board and the frame control board. It is a figure which shows the detail of the game machine installation information notification. It is a figure which shows the code system (1 byte) of a game machine type. It is a figure which shows an example of the game machine type list. It is a figure which shows the method of generating the main control chip ID number (in the case of the 1st chip). It is a figure which shows the method of generating the main control chip ID number (in the case of the 2nd chip). It is a figure which shows the identification code of the main control chip ID number. It is a figure which shows the detail of a game machine installation information response. It is a figure which shows the detail of the game machine information notification (1/2). It is a figure which shows the detail of the game machine information notification (2/2). It is a figure which shows the main control state 1. It is a figure which shows the main control state 2. It is a figure which shows the fraud detection state. It is a figure which shows the detail of the game information. It is a figure which shows the detail of the type information. It is a figure which shows the detail of the data type of the type information. It is a figure which shows the data number of the type information (1/2). It is a figure which shows the data number of the type information (2/2). It is a figure which shows the data number of the external terminal board pulse output. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where 2 prizes are made to the start opening 1 of 3 prize balls in 1 = start opening prize. (Example 2) 2 = It is a figure which shows the example of the case where 3 prizes are won in the big prize opening 2 of 15 prize balls in the big prize opening prize by the operation of a special electric accessory. (Example 3) 3 = It is a figure which shows the example of the case where one prize is won in the prize opening 2 of one prize ball in the prize opening prize. (Example 4) 4 = It is a figure which shows the example of the case where the passing gate 1 is passed once when passing through the gate. (Example 5) 4 = FIG. 5 is a diagram showing an example in which one prize is won in the normal drawing operating opening 2 of three prize balls in the normal drawing operating opening winning. (Example 6) 5 = FIG. 5 is a diagram showing an example in which one prize is won in the winning opening of three prize balls by operating the ordinary electric accessory in the starting opening winning by operating the ordinary electric accessory. (Example 7) 6 = FIG. 6 is a diagram showing an example in which one prize is won in the large prize opening 1 of 15 prize balls by operating the accessory continuous operating device in the large winning opening winning by operating the accessory continuous operating device. (Example 8) 7 = It is a figure which shows the example of the case where one prize is won in the winning opening 2 of 10 prize balls by the normal electric accessory operation in the prize by the ordinary electric accessory operation. (Example 9) 8 = It is a figure which shows the example of the case where 1 prize is won in the winning opening 1 of 10 prize balls by the other accessory operation in the prize by the other accessory operation. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the special symbol 1 is stopped once in the symbol fixed number of times. (Example 2) It is a figure which shows the example of the case where the normal symbol 1 is stopped once in the symbol fixed number of times. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the accessory continuous operation device is operated once (big hit) while the accessory continuous operation device is operated (big hit). (Example 2) When the accessory continuous operation device is not activated, the special electric accessory is activated (small hit), and when the accessory continuous activator is not activated, the special electric accessory is activated once (small hit). It is a figure which shows the example of the case. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the normal symbol hit occurs once in the normal symbol hit. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example in the case where the accessory 1 is opened once in the number of accessories. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the specific area 1 is passed once in the specific area passage. It is a figure which shows the detail of the count information. (Example 1) In the external terminal plate pulse output, it is a figure which shows the example of the case where the pulse is output once from the external terminal plate pulse output signal terminal 1 of a dedicated unit. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the state changes to the high base in the performance information state notification. It is a figure which shows the detail of a game machine information response. It is a figure which shows the communication procedure from power-on. It is a figure which shows the communication procedure at the time of setting change or setting confirmation. It is a figure which shows the procedure of communication line disconnection detection 1. It is a figure which shows the procedure of communication line disconnection detection 2. It is a figure which shows the procedure of the ball-pulling state. It is a figure which shows the output block diagram. It is a figure which shows the standard 20 port (1/2). It is a figure which shows the standard 20 port (2/2). It is a figure which shows the expansion port. It is a figure which shows the system block diagram of the management game machine. It is a figure which shows the frame control-CM communication condition. It is a figure which shows the detail of the frame control-CM data structure. It is a figure which shows the frame control-CM message list. It is a figure which shows the detail of the game machine information notification. It is a figure which shows the code system (1 byte) of a game machine type. It is a figure which shows an example of the game machine type list. It is a figure which shows the telegram when "0x00: game machine performance information" is set as a game machine information type. It is a figure which shows the telegram when "0x01: game machine installation information" is set as a game machine information type. It is a figure which shows the method of generating the frame control chip ID number (in the case of the 1st chip). It is a figure which shows the method of generating the frame control chip ID number (in the case of the 2nd chip). It is a figure which shows the telegram when "0x02: hall control, fraud monitoring information" is set as a game machine information type (1/3). It is a figure which shows the telegram when "0x02: hall control, fraud monitoring information" is set as a game machine information type (2/3). It is a figure which shows the telegram when "0x02: hall control, fraud monitoring information" is set as a game machine information type (3/3). It is a figure which shows the fraud detection state 1. It is a figure which shows the fraud detection state 2. It is a figure which shows the fraud detection state 3. It is a figure which shows the detail of a data type (upper 4 Bit). It is a figure which shows the detail of the data number (lower 4 Bit) set for each data type. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where two prizes are won in the start opening 1 of three prize balls in the start opening prize. (Example 2) It is a figure which shows the example of the case where 3 pieces are won in the big prize opening 2 of 15 prize balls in the big prize opening prize. (Example 3) It is a figure which shows the example of the case where one prize is won in the prize opening 2 of one prize ball in the prize opening prize. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the passing gate 1 is passed once in passing through the gate. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the special symbol 1 is stopped once in the symbol fixed number of times. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the accessory continuous operation device is operated once (big hit) while the accessory continuous operation device is operated (big hit). (Example 2) When the accessory continuous operation device is not activated, the special electric accessory is activated (small hit), and when the accessory continuous activator is not activated, the special electric accessory is activated once (small hit). It is a figure which shows the example of the case. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example in the case where the accessory 1 is opened once in the number of accessories. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example of the case where the specific area passage 1 is passed once in the specific area passage. It is a figure which shows the detail of the count information. (Example 1) It is a figure which shows the example when the spare 1 occurs once in the spare. It is a figure which shows the detail of the count notification. It is a figure which shows the detail of the loan notice. It is a figure which shows the detail of the loan notification receipt result response. It is a figure which shows the basic communication sequence. It is a figure which shows the sequence when the gaming machine is started first. It is a figure which shows the sequence when CM is started first. It is a figure which shows the notification condition applied in the game machine information notification sequence. It is a figure which shows the basic sequence (no game information) of a game machine information notification. It is a figure which shows the sequence when the hall control / fraud monitoring information (with game information) and the game machine installation information / game machine performance information overlap (1/2). It is a figure which shows the sequence when the hall control / fraud monitoring information (with game information) and the game machine installation information / game machine performance information overlap (2/2). It is a figure which shows the count notification sequence (1/2). It is a figure which shows the count notification sequence (2/2). It is a figure which shows the lending notification sequence. It is a figure which shows the recovery sequence at the time of disconnection of a dedicated cable (1/2). It is a figure which shows the recovery sequence at the time of disconnection of a dedicated cable (2/2). It is a figure which shows the communication abnormality during counting (1/2). It is a figure which shows the communication abnormality during counting (2/2). It is a figure which shows the communication abnormality at the time of lending. It is a figure which shows the external dimension and weight of a power supply unit. It is a figure which shows the input power supply specification of a power supply unit. It is a figure which shows the input signal specification of a power supply unit. It is a figure which shows the output power supply specification of a power supply unit (1/2). It is a figure which shows the output power supply specification of a power supply unit (1/2). It is a figure which shows the power-source and the signal timing chart. It is a figure which shows the rise-up characteristic (when the power supply is started). It is a figure which shows the falling-down characteristic (when the power supply is cut off). It is a figure which shows the momentary power failure-2 (when DC36V-1 cannot be lowered completely in 25ms or more and DC5V-1 is held). CN1: It is a figure which shows the specification of the connection part 1. CN2: It is a figure which shows the specification of the connection part 2. CN3: It is a figure which shows the specification of the connection part 3. CN4: It is a figure which shows the specification of the connection part 4. CN5: It is a figure which shows the specification of the connection part 5. CN6: It is a figure which shows the specification of the connection part 6. CN7: It is a figure which shows the specification of the connection part 7. It is a figure which shows the insulation specification of a power supply unit. It is a figure which shows the environmental specification of a power supply unit. It is a figure which shows the standard of a power supply unit. It is a figure which shows the power supply block diagram of a power supply unit. It is a figure which shows the component arrangement drawing of the connector and the switch of a power supply unit. It is a figure which shows the connector pin arrangement specification of the drawer connector 36 pin. It is a figure which shows the circuit structure of the interface between a main control board and a frame control board. It is a figure which shows the constant and the model name of the component used in the circuit structure of the interface between a main control board and a frame control board. It is a figure which shows the connector pin arrangement specification of the drawer connector 40 pin. It is a figure which shows the circuit structure of the interface between an effect control board and other effect devices. It is a figure which shows the constant and the model name of the component used in the circuit composition of the interface between an effect control board and other effect devices. It is a figure which shows the outline of the pull-down process at the time of not using and the time of using. It is a figure which shows the block diagram including the adjustment switch and the like. It is a figure which shows the block diagram including the effect switch unit and the like. It is a figure which shows the list of LED and control specifications. It is a figure which shows the block diagram of the LED control of the front frame. It is a figure which shows the LED arrangement and the system diagram. It is a figure which shows the correspondence between the LED system diagram and the LED driver. It is a figure which shows the specification of the lower speaker. It is a figure which shows the specification of the left speaker and the right speaker. It is a figure which shows the block diagram which includes the upper speaker, the left speaker, the right speaker and the like. It is a figure which shows the whole circuit diagram of the management game machine (1/25). It is a figure which shows the whole circuit diagram of the management game machine (2/25). It is a figure which shows the whole circuit diagram of the management game machine (3/25). It is a figure which shows the whole circuit diagram of the management game machine (4/25). It is a figure which shows the whole circuit diagram of the management game machine (5/25). It is a figure which shows the whole circuit diagram of the management game machine (6/25). It is a figure which shows the whole circuit diagram of the management game machine (7/25). It is a figure which shows the whole circuit diagram of the management game machine (8/25). It is a figure which shows the whole circuit diagram of the management game machine (9/25). It is a figure which shows the whole circuit diagram of the management game machine (10/25). It is a figure which shows the whole circuit diagram of the management game machine (11/25). It is a figure which shows the whole circuit diagram of the management game machine (12/25). It is a figure which shows the whole circuit diagram of the management game machine (13/25). It is a figure which shows the whole circuit diagram of the management game machine (14/25). It is a figure which shows the whole circuit diagram of the management game machine (15/25). It is a figure which shows the whole circuit diagram of the management game machine (16/25). It is a figure which shows the whole circuit diagram of the management game machine (17/25). It is a figure which shows the whole circuit diagram of the management game machine (18/25). It is a figure which shows the whole circuit diagram of the management game machine (19/25). It is a figure which shows the whole circuit diagram of the management game machine (20/25). It is a figure which shows the whole circuit diagram of the management game machine (21/25). It is a figure which shows the whole circuit diagram of the management game machine (22/25). It is a figure which shows the whole circuit diagram of the management game machine (23/25). It is a figure which shows the whole circuit diagram of the management game machine (24/25). It is a figure which shows the whole circuit diagram of the management game machine (25/25). It is a figure which shows the design unit exchange range of the management game machine. It is a figure which shows the design unit. It is a figure which shows the attachment / detachment method of a design unit. It is a figure which shows the electrical connection method of a design unit (1/2). It is a figure which shows the electrical connection method of a design unit (2/2). It is a figure which shows the relay board for expansion. It is a perspective view which shows the slot machine 1 which is an example of a rotating body type gaming machine. It is a figure which shows the internal structure of the slot machine 1. It is a block diagram which shows various electronic devices equipped in a slot machine 1. It is a block diagram which shows the internal functional structure of an effect control device 124. It is a flowchart which shows the procedure of a main process. It is a figure which shows the production example of a normal production and a special production. It is a figure which shows the production example of a normal production. It is a figure which shows the production example of a special production (1/2). It is a figure which shows the production example of a special production (2/2). It is a flowchart which shows the procedure example of the CPU initialization process which is executed by an effect control device. It is a flowchart which shows the procedure example of various timer interrupt processing. It is a flowchart which shows the procedure example of the effect control processing. It is a flowchart which shows the procedure example of the upper control part management process. It is a flowchart which shows the procedure example of the lower control part management process. It is a flowchart which shows the procedure example of the drawing completion interrupt processing. It is a figure which shows the system block diagram of the medalless gaming machine. It is a figure which shows the connector pin assignment of the dedicated interface input / output connector. It is a figure which shows the connection example of a dedicated cable. It is a figure which shows the connector diagram of the dedicated cable. It is a figure which shows the logic of the transmission signal and the reception signal on the connector of a dedicated cable. It is a figure which shows the example of the input / output circuit of a dedicated unit and a gaming machine. It is a figure which shows the circuit resistance constant of the interface on the gaming machine side. It is a figure which shows the circuit resistance constant of the interface on the dedicated unit side. It is a figure which shows the communication condition between a game machine-dedicated unit. It is a figure which shows the data structure between a game machine-dedicated unit. It is a figure which shows the detail of the data structure between a game machine-dedicated unit. It is a figure which shows the list of the message message between a game machine-dedicated unit. It is a figure which shows the detail of the game machine information notification. It is a figure which shows the code system (1 byte) of a game machine type. It is a figure which shows an example of the game machine type list. It is a figure which shows the telegram when "0x00: game machine performance information" is set as a game machine information type. It is a figure which shows the telegram when "0x01: game machine installation information" is set as a game machine information type. It is a figure which shows the method of generating the main control chip ID number (in the case of the 1st chip). It is a figure which shows the method of generating the main control chip ID number (in the case of the 2nd chip). It is a figure which shows the method of generating the medal number control chip ID number (in the case of the 1st chip). It is a figure which shows the method of generating the medal number control chip ID number (in the case of the 2nd chip). It is a figure which shows the method of generating the medal number control chip ID number (when the medal number control is not installed). It is a figure which shows the identification code of the main control / medal number control chip ID number. It is a figure which shows the telegram when "0x02: hall control, fraud monitoring information" is set as a game machine information type (1/3). It is a figure which shows the telegram when "0x02: hall control, fraud monitoring information" is set as a game machine information type (2/3). It is a figure which shows the telegram when "0x02: hall control, fraud monitoring information" is set as a game machine information type (3/3). It is a figure which shows the detail of each bit of the main control state 1. FIG. It is a figure which shows the detail of each bit of the main control state 2. It is a figure which shows the detail of a game machine fraud 1. It is a figure which shows the detail of a game machine fraud 2. It is a figure which shows the detail of a game machine fraud 3. It is a figure which shows the detail of the game information. It is a figure which shows the detail of the type information. It is a figure which shows the detail of a data type (upper 4 Bit). It is a figure which shows the detail of the data number (lower 4 Bit) set for each data type. It is a figure which shows the detail of the count information when the data type is a specified number. It is a figure which shows the specific example of the game information in the case of the specified number three-card game. It is a figure which shows the detail of the count information when the data type is the number of payouts. It is a figure which shows the specific example of the game information in the case where 10 medals are paid out by winning a prize. It is a figure which shows the detail of the count notification. It is a figure which shows the detail of the loan notice. It is a figure which shows the detail of the loan receipt result response. It is a figure which shows the basic communication sequence. It is a figure which shows the sequence when the gaming machine is started first. It is a figure which shows the sequence when the dedicated unit is started first. It is a figure which shows the notification condition applied in the game machine information notification sequence. It is a figure which shows the basic sequence of game machine information notification. It is a figure which shows the count notification sequence (1/2). It is a figure which shows the count notification sequence (2/2). It is a figure which shows the lending notification sequence. It is a figure which shows the recovery sequence at the time of disconnection of a dedicated cable (1/2). It is a figure which shows the recovery sequence at the time of disconnection of a dedicated cable (2/2). It is a figure which shows the communication abnormality during counting (1/2). It is a figure which shows the communication abnormality during counting (2/2). It is a figure which shows the communication abnormality at the time of lending. It is a figure which shows the detail of a game machine performance information. It is a figure which shows the simple block diagram of the medalless gaming machine. It is a figure which shows the list of the processing performed outside the use area of a main control ROM. It is a figure which shows the list of the processing performed outside the use area of the medal number control ROM. It is a figure which shows the block diagram including the count button. It is a flowchart which shows the processing procedure which invalidates a count button. It is a figure which shows the block diagram of the game machine (medalless game machine) which mounted the medal number control board. It is a figure which shows the block diagram of the game machine (medalless game machine) equipped with the medal number control board which can execute the game medal insertion process. It is a figure which shows the communication timing chart between a medalless gaming machine and a dedicated unit. It is a figure which shows the type of a signal. It is a figure which shows the structure of a communication port. It is a figure which shows the communication timing chart when the dedicated unit is not connected to the rental device connection terminal board such as a game ball. It is a figure which shows the operation after error and fraud detection (1/4). It is a figure which shows the operation after error and fraud detection (2/4). It is a figure which shows the operation after error and fraud detection (3/4). It is a figure which shows the operation after error and fraud detection (4/4).

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a front view of a pachinko gaming machine (hereinafter, abbreviated as “pachinko machine”) 1. Further, FIG. 2 is a rear view of the pachinko machine 1. The pachinko machine 1 uses a game ball as a game medium, and the player borrows the game ball from the game hall operator and plays the game with the pachinko machine 1. In the game of the pachinko machine 1, each of the game balls is a medium having a game value, and the privilege (profit) that the player enjoys as a result of the game is, for example, the game ball acquired by the player. It can be converted into a game value based on the number of. Hereinafter, the overall configuration of the pachinko machine 1 will be described with reference to FIGS. 1 and 2.

Here, in the present specification, the left side is the left side when viewed from the player who is seated so as to face the pachinko machine 1, the right side is the right side when viewed from the player, and the upper side is the top side when viewed from the player. The explanation is that the lower side is the lower side when viewed from the player, the front side is the front side when viewed from the player, and the back side is the rear side when viewed from the player.

〔overall structure〕
The pachinko machine 1 mainly includes an outer frame unit 2, an integrated door unit 4, and an inner frame assembly 7 (plastic frame, game machine frame) as its main body. The integrated door unit 4 is located on the frontmost side thereof when viewed from the front facing the player. The inner frame assembly 7 is located on the back side (back side) of the integrated door unit 4, and the outer frame unit 2 is arranged so as to surround the outside of the inner frame assembly 7.

The outer frame unit 2 is a structure in which wood and metal materials are combined in a vertically long rectangular shape, and the outer frame unit 2 provides fasteners such as screws to island equipment (not shown) in the amusement park. It is fixed using. In the vertically long rectangular outer frame unit 2, wood is used for the parts corresponding to the upper and lower short sides, and metal material is used for the parts corresponding to the left and right long sides.

The integrated door unit 4 has a structure in which the saucer unit 6 is integrated at the lower position thereof. The integrated door unit 4 and the inner frame assembly 7 are attached to the island equipment via the outer frame unit 2, and each of them operates in an openable and closable manner via a hinge mechanism (not shown). The opening / closing axis of the hinge mechanism (not shown) extends in the vertical direction along the left end portion when viewed from the front of the pachinko machine 1.

A unified lock unit 9 is provided inside the right edge portion (left edge portion in FIG. 2) of the inner frame assembly 7 when viewed from the front in FIG. 1. Correspondingly, locking tools (not shown) are also provided on the right side edges (back side) of the integrated door unit 4 and the outer frame unit 2. As shown in FIG. 1, with the integrated door unit 4 and the inner frame assembly 7 closed to the outer frame unit 2, the unified lock unit 9 on the back side thereof together with the locking tool is the integrated door unit 4 and the inner frame assembly. It makes it impossible to open 7.

A cylinder lock 6a with a keyhole is provided on the right edge of the saucer unit 6. For example, when the manager of the amusement park inserts the dedicated key into the keyhole and twists the cylinder lock 6a clockwise, the unified lock unit 9 operates and the integrated door unit 4 can be opened together with the inner frame assembly 7. .. When all of these are opened from the outer frame unit 2 to the front side (moved like a door), the back side of the pachinko machine 1 is exposed on the front side.

On the other hand, when the cylinder lock 6a is twisted counterclockwise, only the lock of the integrated door unit 4 is released while the inner frame assembly 7 is locked, and the integrated door unit 4 can be opened. When the integrated door unit 4 is opened to the front side, the game board unit 8 is directly exposed, and in this state, the manager of the game field can remove obstacles such as ball clogging in the board surface. Further, when the integrated door unit 4 is opened, the saucer unit 6 is also opened to the front side.

Further, the pachinko machine 1 includes the above-mentioned game board unit 8 as a game unit. The game board unit 8 is supported by the inner frame assembly 7 above behind (inside) the integrated door unit 4. The game board unit 8 can be attached to and detached from the inner frame assembly 7 with the integrated door unit 4 opened to the front side, for example. A vertically elongated circular window 4a is formed in the central portion of the integrated door unit 4, and a glass unit (without reference numeral) is mounted in the window 4a. The glass unit is, for example, a combination of two transparent plates (glass plates) cut according to the shape of the window 4a. The glass unit is attached to the back side of the integrated door unit 4 via a fixture (not shown). A game area 8a (board surface, game board) is formed on the front surface of the game board unit 8, and the game area 8a is visible to the player from the front side through the window 4a. When the integrated door unit 4 is closed, a space is formed between the inner surface of the glass unit and the board surface so that the game ball can flow down.

The saucer unit 6 has a shape that protrudes from the integrated door unit 4 to the front side as a whole, and an upper plate 6b is formed on the upper surface thereof. The upper plate 6b can store a game ball (rental ball) lent to the player and a game ball (prize ball) acquired by winning a prize. Further, in the plate receiving unit 6, a lower plate 6c is formed at a lower position of the upper plate 6b. In the lower plate 6c, a game ball further paid out with the upper plate 6b full is stored. The pachinko machine 1 of the present embodiment is a so-called CR machine (a model connected to the CR unit), and the game ball borrowed by the player is a plate unit 6 (upper) from the payout device unit 172 on the back side separately from the prize ball. It is paid out to the plate 6b or the lower plate 6c).

A lending operation unit 14 is provided on the upper surface of the saucer unit 6, and a ball lending button 10 and a return button 12 are arranged on the lending operation unit 14. When the player operates the ball lending button 10 with a valuable medium (for example, a magnetic recording medium, a medium with a built-in storage IC, etc.) inserted in a CR unit (not shown), the number corresponding to a predetermined frequency unit (for example, 5 frequencies). (For example, 125) of game balls are rented out. Therefore, a frequency display unit (not shown) is arranged on the upper surface of the lending operation unit 14, and the frequency display unit displays the residual frequency of the valuable medium loaded in the CR unit. By operating the return button 12, the player can receive the return of the valuable medium having the remaining frequency. In the present embodiment, the CR machine is taken as an example, but the pachinko machine 1 may be a cash machine (a model not connected to the CR unit) different from the CR machine.

Further, on the upper surface of the saucer unit 6, an upper plate ball removing button 6d is installed in front of the upper plate 6b at the upper stage position, and a lower plate ball removing lever 6e is installed in the center thereof in front of the lower plate 6c. Is installed. The player can push the upper plate ball removal button 6d, for example, to cause the game ball stored in the upper plate 6b to flow down to the lower plate 6c. Further, the player can slide the lower plate ball removing lever 6e to the left, for example, to drop the game ball stored in the lower plate 6c downward and discharge it. The discharged game balls are received, for example, in a ball receiving box (not shown).

A grip unit 16 is installed at the lower right of the saucer unit 6. By operating the grip unit 16, the player can operate the launch control board set 174 and launch (launch) the game ball toward the game area 8a (ball launcher). The launched game ball rises from the lower edge of the game board unit 8 along the left edge, is guided by an outer band (not shown), and is thrown into the game area 8a. A large number of obstacle nails (game nails), windmills (without reference symbols in the figure), etc. are arranged in the game area 8a, and the thrown game ball is guided and guided by the obstacle nails and the windmill in the game area 8a. Flow down. The configuration of the game area 8a (board surface, game board) will be described later with reference to another drawing.

[Structure on the front of the frame]
The integrated door unit 4 is provided with a left top lens unit 47 and an upper right illumination unit 49 as components for directing. Of these, the left top lens unit 47 incorporates a glass frame top lamp 46 and a left glass frame decorative lamp 48, and the upper right lighting unit 49 incorporates a right glass frame decorative lamp 50. In addition, the integrated door unit 4 is provided with left and right glass frame decorative lamps 52 so as to be connected below the left top lens unit 47 and the upper right illumination unit 49, respectively. It extends from the left and right edges of the integrated door unit 4 to the front surface of the saucer unit 6. In the integrated door unit 4, the glass frame top lamp 46, the left and right glass frame decorative lamps 50, 52, and the like are arranged so as to surround the glass unit.

The various lamps 46, 48, 50, and 52 described above execute the effect by, for example, emitting light from the built-in LED (lighting or blinking, change in luminance gradation, change in color tone, etc.). Further, in the upper part of the integrated door unit 4, the speakers 54 and 55 on the glass frame are incorporated in the left top lens unit 47 and the upper right illumination unit 49, respectively. On the other hand, the outer frame speaker 56 is incorporated in the lower left position of the outer frame unit 2. These speakers 54, 55, and 56 output sound effects, BGM, voice, and the like (general sound) to execute the effect.

Further, in the center of the plate receiving unit 6, an effect switching button 45 (operation input receiving means) is installed at a position in front of the upper plate 6b. The effect switching button 45 can perform a plurality of types of operations (press once, press multiple times, repeatedly hit, long press, etc.) and accept operation input. The player can switch the effect content (for example, the background screen displayed on the liquid crystal display 42) by pressing the effect switching button 45 (operation input), for example, while the symbol is changing or the jackpot is confirmed. Alternatively, some kind of effect (notice effect, probabilistic promotion effect, promotion effect during a major role, etc.) can be generated during the jackpot game.

Further, a jog dial 45a is installed around the effect switching button 45 so as to surround the effect switching button 45 (operation input receiving means, rotary selector). By rotating the jog dial 45a, the player can change the effect content displayed on the liquid crystal display 42, for example.

[Backside configuration]
As shown in FIG. 2, on the back side of the pachinko machine 1, there are a power supply control unit 162, a main control board unit 170, a payout device unit 172, a flow path unit 173, a launch control board set 174, and a payout control board unit 176. , The back cover unit 178 and the like are installed. In addition to this, on the back side of the pachinko machine 1, various electronic devices (including a control computer (not shown), which constitute the power supply system and control system of the pachinko machine 1, an external terminal board 160, a power cord (power plug) 164, A ground wire (ground terminal) 166, connection wiring (not shown), etc. are installed.

The main control board unit 170 has a built-in main control device, and a performance display monitor 200 is connected to the main control device.
The performance display monitor 200 is arranged in the main control device so that the pachinko machine 1 can be seen in the upper left region of the main control board unit 170 when viewed from the back side, and includes four 7-segment LEDs 201 to 204. ..

The performance display monitor 200 (base display device) displays the base. Further, the performance display monitor 200 displays a set value (set value).

The four 7-segment LEDs 201 to 204 are arranged side by side in the left-right direction, and each of the 7-segment LEDs has seven segments capable of displaying decimal Arabic numerals and a dot segment located at the lower right of the seven segments. It is composed of.
The performance display monitor 200 is visible through a transparent case that covers the main control board unit 170.

Further, the main control device is provided with a RAM clear switch 304 and a setting key keyhole 306. The RAM clear switch 304 is a switch used for clearing the RAM (initializing the RAM 76), that is, initializing the RAM (RWM) installed in the main control unit. Further, the setting key keyhole 306 is a keyhole for inserting a setting key required for changing a setting or referencing a setting.

The RAM clear switch 304 is provided so as to be pressable through a through hole formed in a transparent case covering the main control board unit 170. The RAM clear switch 304 may be arranged outside the transparent case. Further, the keyhole 306 for the setting key is provided in a state where the key cylinder penetrates the transparent case (a state in which the transparent case surrounds the periphery of the key cylinder). Therefore, it is possible to insert and rotate the setting key while the transparent case is still sealed.

The RAM clear switch 304 is a switch for clearing the RAM, and when the power is turned on while the RAM clear switch 304 is pressed, the RAM clear signal is input to the main control device 70 and the payout control device 92, and the RAM clear process is performed. Is executed. The RAM clear switch 304 may be provided in the power supply control unit 162. Further, when the RAM clear signal is not input to the payout control device 92 and the main control device 70 receives the input of the RAM clear signal, the main control device 70 transmits a RAM clear command to the payout control device 92. May be good.

The arrangement positions of the performance display monitor 200, the RAM clear switch 304, and the setting key keyhole 306 shown in FIG. 2 are merely examples, and can be arranged at any position. Further, the performance display monitor 200, the RAM clear switch 304, and the setting key keyhole 306 may be provided outside the main control device and connected to the main control device.

The payout device unit 172 has, for example, a prize ball tank 172a and a prize ball case (without a reference symbol), of which the prize ball tank 172a is installed on the upper edge (back side) of the inner frame assembly 7. In the state, the game balls replenished from the replenishment route (not shown) can be stored. The game balls stored in the prize ball tank 172a are guided to the prize ball case through an upper prize ball gutter (not shown). The flow path unit 173 guides the game ball sent out from the payout device unit 172 toward the tray unit 6 on the front side.

Further, the above-mentioned external terminal plate 160 is for connecting the pachinko machine 1 to an external electronic device (for example, a data display device, a hall computer, etc.), and from the external terminal plate 160, a game of the pachinko machine 1 is performed. Various external information signals (for example, prize ball information, door opening information, symbol confirmation count information, jackpot information, starting port information, etc.) indicating the progress status, maintenance status, etc. are output to external electronic devices. ing.

The power cord 164 secures the power supply (electric power) required for the operation of the pachinko machine 1 by being connected to, for example, a power supply device (for example, AC24V) installed in the island equipment of the amusement park. Further, the ground wire 166 is connected to the ground terminal also installed in the island equipment to secure the ground (ground) of the pachinko machine 1.

FIG. 3 is a front view showing the game board unit 8 alone. The game board unit 8 includes a game board 8b as a base, and a game area 8a is formed on the front side of the game board 8b. The game board 8b is made of, for example, a transparent resin plate, and the front surface of the game board 8b is parallel to the glass unit in a state where the game board unit 8 is fixed to the inner frame assembly 7. On the front surface of the game plate 8b, the above-mentioned game area 8a is formed inside a launch rail (without reference numeral) installed in a substantially circular shape.

In the game area 8a, a relatively large effect unit 40 is arranged at the center position thereof, and the game area 8a is largely divided into a left side portion, a right side portion, and a lower portion centering on the effect unit 40. The left side portion of the game area 8a is a first game area (left-handed area) used in a normal game state (low probability non-time reduction state) or a latent probability change state (high probability non-time reduction state), and is a game area 8a. The right part of is a second game area (right-handed area, specific area) used in an advantageous game state (big hit game state, small hit game state, low probability time shortened state, high probability time shortened state, etc.). .. Further, in the game area 8a, a medium start winning opening 26, a starting gate 20, a normal winning opening 22, 24, a variable starting winning device 28, a first variable winning device 30, and a second variable winning device are placed around the effect unit 40. 31 etc. are distributed and installed.

Of these, the middle start winning opening 26 is arranged in the center of the lower portion of the game area 8a.
Further, the second variable winning device 31, the starting gate 20, the first variable winning device 30, and the variable starting winning device 28 are arranged in this order from the top on the right side portion of the game area 8a.

The three ordinary winning openings 22 on the left side are arranged on the left side portion of the game area 8a, and one ordinary winning opening 24 (predetermined winning opening) on the right side is located between the starting gate 20 and the first variable winning device 30. Have been placed.

The game ball thrown into the game area 8a enters the middle start winning opening 26, the normal winning opening 22, 24, or enters the second variable winning device 31 at the time of opening operation in the process of its flow down. , Passing through the starting gate 20, entering the first variable winning device 30 during the opening operation, and entering the variable starting winning device 28 during the opening operation.

Here, the game ball flowing down the left side area of the game area 8a may mainly enter the middle start winning opening 26 or the normal winning opening 22. On the other hand, the game ball flowing down the right side area of the game area 8a mainly enters the second variable winning device 31 at the time of opening operation, passes through the starting gate 20, or enters the normal winning opening 24. Alternatively, there is a possibility of entering the first variable winning device 30 during the opening operation or entering the variable starting winning device 28 during the opening operation.

The game ball that has passed through the start gate 20 continuously flows down in the game area 8a, but the middle start winning opening 26, the normal winning opening 22, 24, the variable starting winning device 28, the first variable winning device 30, and the second variable winning opening The game ball that has entered the device 31 is collected to the back side of the game board unit 8 through a through hole formed in the game board (plywood material, transparent plate, etc. constituting the game board unit 8).

Here, in the present embodiment, due to the configuration of the game area 8a (board surface), when the game ball is to be inserted into the middle start winning opening 26 or the normal winning opening 22, the area on the left side in the game area 8a (left-handed). It is necessary to hit a game ball into the area) (perform a so-called "left-handed").

On the other hand, when a game ball is to be entered into the variable start winning device 28, the first variable winning device 30, the second variable winning device 31, and the normal winning opening 24, the area on the right side in the game area 8a (right-handed area). ) Needs to hit a game ball (perform a so-called "right hit").

The variable start winning device 28 operates when a predetermined operating condition is satisfied (when the normal symbol is stopped and displayed in a hit manner), and accordingly, the right starting winning opening 28a (starting winning opening) is entered. Enables a ball (ordinary electric accessory). The variable start winning device 28 has one opening / closing member 28b, and the opening / closing member 28b reciprocates in the left-right direction along the board surface by the action of a link mechanism using a solenoid (not shown), for example. The opening / closing member 28b is in the closed position with the tip facing upward, and at this time, it is impossible to enter the right starting winning opening 28a (there is no gap for the game ball to enter). On the other hand, when the variable start winning device 28 is activated, the opening / closing member 28b is displaced from the closed position toward the open position (falls down to the right) to open the right start winning opening 28a. During this time, the variable start winning device 28 is in a state where the game ball can be entered, and the right starting winning opening 28a can be generated (variable starting winning means). At this time, the opening / closing member 28b also functions as a member for guiding the entry of the game ball into the starting winning opening 28a.

The first variable winning device 30 is used when the specified conditions are satisfied (for example, when the first special symbol is stopped and displayed in the big hit mode, when the special symbol is stopped and displayed in the small hit mode, the second special symbol is stopped and displayed. It operates when the special symbol is stopped and displayed in the mode of "5-round normal symbol" or "5-round probability variation symbol"), and enables winning to the 1st grand prize opening 30b (upper grand prize opening) (special). Electric accessory, first special prize event generation means).

The first variable winning device 30 has one opening / closing member 30a, and the opening / closing member 30a reciprocates in the left-right direction along the board surface by, for example, the action of a link mechanism using a solenoid (not shown). The opening / closing member 30a is in the closed position with the tip facing upward, and at this time, it is impossible to enter the first large winning opening 30b (a state in which there is no gap through which the game ball can enter). On the other hand, when the first variable winning device 30 is activated, the opening / closing member 30a is displaced from the closed position toward the open position (falls down to the left) to open the first large winning opening 30b. During this time, the first variable winning device 30 is in a state where the game ball can be entered, and the first large winning opening 30b can be generated. At this time, the opening / closing member 30a also functions as a member for guiding the entry of the game ball into the first large winning opening 30b.

The second variable winning device 31 is used when a special condition is satisfied (for example, when the second special symbol is stopped and displayed in a jackpot mode (for example, the second special symbol is a "5-round normal symbol" or a "5-round probability change". (Except when the display is stopped in the form of "design".)), It is possible to win a prize in the second special winning opening 31b (lower big winning opening) (special electric accessory, second special winning event occurrence). means).

The second variable winning device 31 has one opening / closing member 31a, and the opening / closing member 31a reciprocates in the left-right direction along the board surface by the action of a link mechanism using, for example, a solenoid (not shown). The opening / closing member 31a is in the closed position with the tip facing upward, and at this time, it is impossible to enter the second large winning opening 31b (a state in which there is no gap through which the game ball can enter). On the other hand, when the second variable winning device 31 is activated, the opening / closing member 31a is displaced from the closed position toward the open position (falls down to the left) to open the second large winning opening 31b. During this time, the second variable winning device 31 is in a state where the game ball can be entered, and the second large winning opening 31b can be generated. At this time, the opening / closing member 31a also functions as a member for guiding the entry of the game ball into the second large winning opening 31b.

The arrangement of the obstacle nails and the shape of the structure installed in the game board unit 8 are basically the variable starting winning device 28 (right starting winning opening 28a at the time of opening) and the first variable winning device 30 (the first variable starting winning device 30 at the time of opening). The mode does not extremely obstruct the flow of the game ball toward the 1 large winning opening 30b) and the 2nd variable winning device 31 (the 2nd large winning opening 31b at the time of opening), but the variable start while the game ball is open. The winning device 28 (right start winning opening 28a), the first variable winning device 30 (first large winning opening 30b), and the second variable winning device 31 (second large winning opening 31b) are not always entered. Balls are randomly entered.

The above-mentioned effect unit 40 is installed in the game board unit 8 from the central position to the right side portion thereof. The effect unit 40 is provided with various decorative parts 40b and 40c inside the effect unit 40, in addition to the upper edge portion 40a functioning as a guide member for changing the flow direction of the game ball. The decorative parts 40b and 40c can enhance the decorativeness of the game board unit 8 by its three-dimensional modeling, and can perform a dramatic operation by emitting transmitted light by, for example, a built-in light emitting device (LED or the like). .. In addition, a liquid crystal display 42 (image display) is installed inside the effect unit 40, and various effect images including an effect symbol corresponding to a special symbol are displayed on the liquid crystal display 42. .. As described above, the game board unit 8 impresses the player with the characteristics of the pachinko machine 1 based on the structure of the board surface and the decorativeness of the effect unit 40. Further, when the game board 8b is a transparent resin board (for example, an acrylic board), decorativeness is added by various decorative bodies (including movable bodies and light emitting bodies) arranged not only on the front side but also behind the game board 8b. can do.

In addition, a drive source (for example, a motor, a solenoid, etc.) is attached to the inside of the effect unit 40 together with a movable body 40f (for example, an animal character) for effect. The movable body 40f for the effect can perform an effect accompanied by the operation of a tangible object in addition to the effect using the image by the liquid crystal display 42 and the effect by the light emitter. By the effect using these movable bodies 40f, it is possible to exert an appealing power different from the effect using the two-dimensional image.

Further, a ball guide passage 40d is formed on the left edge portion of the effect unit 40, and a rolling stage 40e is formed on the lower edge portion thereof. The ball guide passage 40d opens diagonally upward to the left in the game area 8a, and when a game ball flowing down in the game area 8a randomly flows into the ball guide passage 40d, it passes through the inside and rolls. It is released onto the stage 40e. The upper surface of the rolling stage 40e has a smooth curved surface, where the game ball can roll freely in the left-right direction. The game ball rolled on the rolling stage 40e eventually flows down into the lower game area 8a. A ball release path 40k is formed at the center position of the rolling stage 40e, and the game ball guided from the rolling stage 40e to the ball release path 40k easily flows into the middle start winning opening 26 directly below the ball release path 40e. ..

In addition, an out opening 32 is formed in the game area 8a, and the game balls that have not entered (winned) in various winning openings are finally collected to the back side of the game board unit 8 through the out opening 32. In addition, the game balls that have entered the normal winning openings 22 and 24, the middle starting winning opening 26, the right starting winning opening 28a, the first variable winning device 30, and the second variable winning device 31 are also driven into the game area 8a. All the game balls that have been released are collected on the back side of the game board unit 8. The collected game balls are discharged from the back side of the pachinko machine 1 to the outside of the frame through an out-passage assembly (not shown), and further join the replenishment route of the island facility (not shown).

FIG. 4 is an enlarged front view showing a part of the game board unit 8 (position on the right side in the window 4a). That is, the game board unit 8 is provided with, for example, a normal symbol display device 33 and a normal symbol operation memory lamp 33a at a position on the right side in the window 4a, as well as a first special symbol display device 34 and a second special symbol display device 35. And a game state display device 38 is provided. Of these, the ordinary symbol display device 33, for example, alternately lights two lamps (LEDs) to display the ordinary symbol in a variable manner, and turns on or off the lamps to stop and display the ordinary symbol. The normal symbol operation storage lamp 33a displays 0 to 4 storage numbers by, for example, a combination of turning off, turning on, and blinking two lamps (LEDs). For example, in the display mode in which both of the two lamps are turned off, the number of stored items is 0, in the display mode in which one lamp is turned on, the number of stored items is displayed, and in the display mode in which the same one lamp is blinked. Two memorized numbers are displayed, three memorized numbers are displayed in the display mode in which one lamp is lit in addition to the blinking one lamp, and four memorized numbers are displayed in the display mode in which the two lamps are blinked together. The individual is displayed, and so on. Although two lamps (LEDs) are used here, four lamps (LEDs) may be used to form the normal symbol operation memory lamp 33a. In this case, the number of working memories can be displayed by the number of lamps that are lit.

The normal symbol operation memory lamp 33a changes to the display mode after increasing one by one in the sense that each time the game ball passes through the start gate 20, the passage that triggers the operation lottery occurs. Then, each time the fluctuation of the normal symbol is started with the passage of the symbol (up to 4), the display mode is changed by one. In the present embodiment, when the normal symbol operation storage lamp 33a is not lit (the number of stored items is 0), the game ball passes through the start gate 20 in a state where the normal symbol can already start changing (when the stop is displayed). However, the display mode does not change. That is, the number of storages (up to 4) represented by the display mode of the normal symbol operation storage lamp 33a represents the number of passages in which the fluctuation of the normal symbol has not yet started at that time.

Further, the first special symbol display device 34 and the second special symbol display device 35 each display, for example, a variable state and a stopped state of the corresponding first special symbol or the second special symbol by a 7-segment LED (with dots). (Design display means). The first special symbol display device 34 and the second special symbol display device 35 may have a form in which a plurality of dot LEDs are arranged geometrically (for example, in a circular shape).

Further, the first special symbol operation storage lamp 34a and the second special symbol operation storage lamp 35a are each 0 to 4 depending on the display mode composed of, for example, a combination of turning off or lighting the two lamps (LEDs) and blinking. (Memory number display means). For example, in the display mode in which both of the two lamps are turned off, the number of stored items is 0, in the display mode in which one lamp is turned on, the number of stored items is displayed, and in the display mode in which the same one lamp is blinked. Two memorized numbers are displayed, three memorized numbers are displayed in the display mode in which one lamp is lit in addition to the blinking one lamp, and four memorized numbers are displayed in the display mode in which the two lamps are blinked together. The individual is displayed, and so on.

The first special symbol operation memory lamp 34a is displayed after increasing by one in the sense that each time a game ball enters the middle start winning opening 26, the game ball enters the middle starting winning opening 26. It changes to the mode (up to 4), and each time the special symbol starts to change with the ball entering, the display mode changes to the reduced one by one. Further, the second special symbol operation memory lamp 35a is increased by one in the sense that each time a game ball enters the variable start winning device 28, the game ball enters the right start winning opening 28a. (Up to 4 pieces), and each time the change of the special symbol is started with the entry of the ball as a trigger, the display state is changed by 1 piece. In the present embodiment, when the first special symbol operation storage lamp 34a is not lit (the number of stored items is 0), the first special symbol is already in a state where the fluctuation can be started (when the stop is displayed), and the middle start winning opening 26 The display mode does not change even if the game ball enters the ball. Further, when the second special symbol operation memory lamp 35a is not lit (the number of stored items is 0), the game ball is inserted into the variable start winning device 28 in a state where the second special symbol can already start changing (when the stop is displayed). The display mode does not change even if the ball is used. That is, the number of storages (maximum of 4) represented by the display modes of the special symbol operation memory lamps 34a and 35a is that of the incoming ball for which the first special symbol or the second special symbol has not yet started to change. It represents the number of times.

Further, the game state display device 38 includes, for example, LEDs corresponding to the jackpot type display lamps 38a, 38b, 38c, the probability fluctuation state display lamp 38d, the time saving state display lamp 38e, and the launch position designation lamp 38f, respectively. In the present embodiment, the above-mentioned ordinary symbol display device 33, ordinary symbol operation storage lamp 33a, first special symbol display device 34, second special symbol display device 35, first special symbol operation storage lamp 34a, second special The symbol operation memory lamp 35a and the game status display device 38 are mounted on the game board unit 8 in a state of being mounted on one integrated display board 89.

[Control configuration]
Next, the configuration related to the control of the pachinko machine 1 will be described.
FIG. 5 is a block diagram showing various electronic devices mounted on the pachinko machine 1. The pachinko machine 1 includes a main control device 70 (main control computer) that is the center of control operation, and the main control device 70 mainly functions to control the progress (contents) of the game in the pachinko machine 1. Have. The main control device 70 is built in the main control board unit 170.

Further, the main control device 70 is equipped with a circuit board (main control board) on which a main control CPU 72, which is a central arithmetic processing unit, is mounted, and the main control CPU 72 includes a ROM 74 and a RAM (main control board) together with a CPU core and registers (not shown). It is configured as an LSI in which semiconductor memories such as RWM) 76 are integrated. Further, the main controller 70 is equipped with a random number circuit (random number generator) 75, an interrupt controller (interrupt CTR) 192, a parallel I / O port 79, a timer circuit (PTC) 194, and a serial communication circuit (SCU) 196. ing. Of these, the random number circuit 75 generates hardware random numbers (for example, 0 to 65535 in decimal notation) for the jackpot determination of the special symbol lottery and the hit determination of the ordinary symbol lottery, and the random numbers generated here are It is input to the main control CPU 72. Further, the interrupt controller 192 receives each interrupt request (XINT interrupt, PTC interrupt, SCU interrupt) from the parallel I / O port 79, the timer circuit 194, and the serial communication circuit 196, and controls these interrupt requests based on the priority. .. In addition, the main controller 70 monitors a RAM clear switch 71 for initializing the RAM 76, changing settings, etc., a parallel I / O port 79, a clock generation circuit (not shown), and various states. Peripheral ICs such as a reset controller that generates a reset as needed are equipped, and these are mounted on the circuit board together with the main control CPU 72. A signal transmission path, a power supply path, a control bus, and the like are formed as wiring patterns on the circuit board (or inner layer portion). The I / O port of the main control device 70 may be of a serial type.

Further, the main control device 70 is provided with a setting changing device 300, a setting key switch 302, and a RAM clear switch 304. The main control device 70 (main control CPU 72) changes the setting by operating the setting changing device 300. The setting changing device 300 is a device for switching the setting (at least the setting related to the winning probability of the special symbol lottery), and is operated by operating the RAM clear switch 304 or the like provided in the pachinko machine 1 (setting changing means). Further, the setting means a combination of operation probabilities. Further, the operation probability means the probability that the combination of special symbols that the condition device is activated (the jackpot game is executed) is displayed. The setting key switch 302 is an input device that inputs a signal (ON / OFF) indicating the rotation state as the setting key, which is indispensable for switching the setting, rotates. Various methods can be adopted for the procedure for changing the setting, and for example, the procedure can be performed as follows.

(1) First, the power of the pachinko machine 1 is turned off. (2) Next, open the door of the pachinko machine 1 with the dedicated key (door key). Specifically, the dedicated key is inserted into the keyhole of the cylinder lock 6a and rotated to the right to open the integrated door unit 4 together with the inner frame assembly 7. (3) Since the setting key keyhole for inserting the setting key and the RAM clear switch 304 are provided inside the pachinko machine 1, insert the setting key into the setting key keyhole and press the setting key. Rotate to the right. (4) Then, the power of the pachinko machine 1 is turned on.

(5) As a result, a signal (ON) indicating that the setting key has been rotated to the change position is input by the setting key switch 302, and the setting can be changed based on this input signal. At this time, a safety lock is applied by a lock mechanism (not shown). Therefore, the setting key cannot be removed unless it is returned to its original position.

Here, when the power is turned on while the RAM clear switch 304 is turned on while the setting key is rotated to the right, the set value can be changed (setting change state). On the other hand, when the power is turned on without turning on the RAM clear switch 304 while the setting key is rotated to the right, the set value can be confirmed (setting confirmation state, setting reference state).

(6) By pressing the RAM clear switch 304 an arbitrary number of times in a state where the setting can be changed, the setting can be changed to any one of the six stages, for example. The set value can be displayed on, for example, a performance display monitor 200, a dedicated 7-segment segment LED, or a game status display device 38 (special symbol display device, etc.).

(7) In the case of a slot machine, when the desired setting is reached, the lever ON process is required, but since the pachinko machine 1 does not have a lever, an alternative process (for example, the setting key is left) instead of the lever ON process. The process of rotating in the direction, the process of turning on the setting change confirmation button (not shown, etc.) may be executed, or the lever ON process may be omitted. In the present embodiment, when the target setting is reached, the setting key is rotated counterclockwise to return to the original position. By this operation, a signal (OFF) indicating that the setting key has been returned to the original position is input by the setting key switch 302, and the setting change is confirmed based on this input signal.

(8) Then, when the change of the setting is confirmed, the setting key can be pulled out from the keyhole for the setting key. By this operation, when the set value is displayed on the performance display monitor 200, the dedicated 7-segment segment LED, and the game status display device 38, the display disappears. (9) Finally, close the door of the pachinko machine 1. This completes the setting change. When the setting change is completed, the normal game starts.

When the setting is changed, the main control CPU 72 stores the changed setting value in the setting value buffer of the RAM 76. The setting value buffer can be a memory area to be backed up.

[Summary of setting change] The outline of setting change is as follows. When the power is turned on with the "setting key ON", "inner frame open state", and "RAM clear switch pressed state", the setting is being changed (setting change mode) after the RAM is cleared. In the state where the setting is being changed, the main display (various lamps included in the game status display device 38) is not displayed, and the game ball cannot be fired or the game ball prize ball cannot be fired at all.

In this case, "rn." Is displayed on the two 7-segment LEDs (identification segment) on the left side of the performance display monitor 200, and the set value such as "-1" is displayed on the two 7-segment LEDs (ratio segment) on the right side. LED. When the RAM clear switch is pressed, the set value changes in the range of 1 to 6.

Then, when the "setting key is turned off", the setting is confirmed, and the "-" segment is turned off (hidden) as in the "blank (non-display) 1" display of the ratio segment. In this state, if the inner frame is closed (actually, if the closed state continues for 100 ms), the state in which the setting is being changed ends, and once the state is changed to the state before the power was turned off, the game is ready for play. Transition.

In the present embodiment, the example in which the RAM clear switch 304 and the setting change switch are also used is described, but the setting change switch may be provided separately from the RAM clear switch 304.

[Summary of setting confirmation] The outline of setting confirmation (see setting) is as follows. When the power is turned on with the "setting key ON", "inner frame open state", and "RAM clear switch not pressed", the setting is being confirmed (setting confirmation mode). Similar to the state in which the setting is being changed, in the state in which the setting is being confirmed, the main display is not displayed, and the game ball cannot be fired or the game ball prize ball cannot be fired at all.

In this case, "rn." Is displayed on the two 7-segment LEDs (identification segment) on the left side of the performance display monitor, and a set value such as "blank (hidden) 1" is displayed on the two 7-segment LEDs (ratio segment) on the right side. Is displayed. Further, in the state where the setting is being confirmed, the set value does not change even if the RAM clear switch is pressed.

In this state, if the "setting key is OFF" and the "inner frame is closed" (actually, the closed state continues for 100 ms), the state of checking the setting is terminated, and once before the power is turned off. After shifting to the state, it shifts to the playable state. In the present embodiment, the setting confirmation cannot be performed in the game-enabled state, but the setting confirmation may be executed in the game-enabled state.

The start gate 20 described above is integrally provided with a gate switch 78 for detecting the passage of the game ball. Further, the game board unit 8 has a middle start winning opening switch 80 and a right starting winning opening corresponding to the middle starting winning opening 26, the variable starting winning device 28, the first variable winning device 30, and the second variable winning device 31, respectively. A switch 82, a first count switch 84 and a second count switch 85 are provided. The starting winning opening switches 80 and 82 are for detecting the entry of a game ball into the middle starting winning opening 26 and the variable starting winning device 28 (right starting winning opening 28a). Further, the first count switch 84 is for detecting the entry of a game ball into the first variable winning device 30 (first large winning opening) and counting the number of balls. Further, the second count switch 85 is for detecting the entry of the game ball into the second variable winning device 31 (second large winning opening 31b) and counting the number of the game balls.

Similarly, the game board unit 8 has a first winning opening switch 86 that detects the entry of a game ball into the ordinary winning opening 22, and a second winning opening switch that detects the entry of a game ball into the ordinary winning opening 24. It is equipped with 81. Regarding the three ordinary winning openings 22 on the left side, a configuration in which a common winning opening switch 86 is used is given as an example. For example, three winning opening switches are installed to play a game ball for each ordinary winning opening 22. The incoming ball may be detected individually.

In any case, the winning detection signals of these switches are input to the main control CPU 72 via an input / output driver (not shown). Due to the configuration of the game board unit 8, in the present embodiment, the winning detection signals from the gate switch 78, the first count switch 84, the second count switch 85, the first winning opening switch 86, and the second winning opening switch 81 are It is transmitted via the panel relay terminal board 87, and the panel relay terminal board 87 is provided with a wiring pattern, connection terminals, and the like for relaying each winning detection signal.

Further, the game board unit 8 is provided with an out switch 99. The game board unit 8 joins the game balls that have passed through the normal winning openings 22 and 24, the middle starting winning opening 26, the right starting winning opening 28a, the first large winning opening 30b, the second major winning opening 31b, and the out opening 32. A confluence passage is formed, and an out switch 99 is provided in this confluence passage. The out switch 99 detects a game ball passing through the confluence passage, and each time the game ball is detected, a detection signal is input to the main control device 70. The main control device 70 counts the number of out balls based on the detection signal input from the out switch 99. Here, since the game balls launched into the game area 8a always pass through the confluence passage and are discharged to the outside of the pachinko machine 1, the out switch 99 determines the number of launch balls launched into the game area 8a. That is, the number of discharges (the number of out balls) discharged from the game area 8a is counted.

The above-mentioned ordinary symbol display device 33, ordinary symbol operation memory lamp 33a, first special symbol display device 34, second special symbol display device 35, first special symbol operation memory lamp 34a, second special symbol operation memory lamp 35a, and game. The status display device 38 controls the display operation based on the control signal from the main control CPU 72. The main control CPU 72 outputs control signals for the display devices 33, 34, 35, 38 and the lamps 33a, 34a, 35a according to the progress of the game, and controls the lighting state of each LED. Further, these display devices 33, 34, 35, 38 and lamps 33a, 34a, 35a are installed in the game board unit 8 in a state of being mounted on one integrated display board 89 as described above, and the integrated display devices 33, 34, 35, 38 and lamps 33a, 34a, 35a are installed in the game board unit 8. A control signal is transmitted from the main control CPU 72 via the panel relay terminal board 87 to the display board 89.

Further, a performance display monitor 200 is connected to the main control device 70 via a panel relay terminal plate 87. The display operation of the performance display monitor 200 is controlled based on the control signal from the main control CPU 72. The main control CPU 72 outputs a control signal to the performance display monitor 200 according to the calculation status of the base, and controls the lighting state of the 7 segments 201 to 204. Although the performance display monitor 200 is described in the example of connecting to the main control device 70 via the panel relay terminal plate 87, the performance display monitor 200 may be connected to the main control device 70 without passing through the panel relay terminal plate 87. The performance display monitor 200 may be arranged as an internal configuration of the main control device 70.

Further, the game board unit 8 corresponds to the variable start winning device 28, the first variable winning device 30, and the second variable winning device 31, respectively, and corresponds to the ordinary electric accessory solenoid 88, the first large winning opening solenoid 90, and the first large winning opening solenoid 90. Two major winning opening solenoids 97 are provided. These solenoids 88, 90, and 97 operate (excite) based on the control signal from the main control CPU 72, and open / close (operate) the variable start winning device 28, the first variable winning device 30, and the second variable winning device 31, respectively. Let me. The solenoids 88, 90, and 97 are also relayed by the panel relay terminal plate 87, and control signals are transmitted from the main control CPU 72.

In addition, a glass frame opening switch 91 is installed in the integrated door unit 4, and a plastic frame opening switch 93 is installed in the inner frame assembly 7. When the integrated door unit 4 is independently opened, a contact signal from the glass frame opening switch 91 is input to the main control device 70 (main control CPU 72), and the inner frame assembly 7 is released from the outer frame unit 2. Then, the contact signal from the plastic frame release switch 93 is input to the main control device 70 (main control CPU 72). The main control CPU 72 can detect the open state of the integrated door unit 4 and the inner frame assembly 7 from these contact signals. When the main control CPU 72 detects the open state of the integrated door unit 4 and the inner frame assembly 7, it generates a door open information signal as an external information signal.

A payout control device 92 is mounted on the back side of the pachinko machine 1. The payout control device 92 (payout control computer) controls the operation of the payout device unit 172 described above. The payout control device 92 is equipped with a circuit board (payout control board) on which the payout control CPU 94 is mounted, and the payout control CPU 94 also includes semiconductor memories such as ROM 96 and RAM (RAM) 98 together with a CPU core (not shown). It is configured as an integrated LSI. The payout control device 92 (payout control CPU 94) controls the operation of the payout device unit 172 based on the prize ball instruction command from the main control CPU 72, and executes the payout operation of the requested number of game balls. The main control CPU 72 generates a prize ball information signal as an external information signal together with the prize ball instruction command.

The payout control device 92 can communicate with the main control device 70, and pays out the game ball based on the payout command transmitted from the main control device 70.

A payout device board 100 is installed together with a payout motor 102 (for example, a stepping motor) in a prize ball case (not shown) of the payout device unit 172, and the payout device board 100 is provided with a drive circuit for the payout motor 102. There is. The payout device board 100 specifically controls the rotation angle of the payout motor 102 based on the payout number instruction signal from the payout control device 92 (payout control CPU 94), and pays the instructed number of game balls from the prize ball case. Let me put it out. The paid-out game ball is sent to the saucer unit 6 through the payout flow path in the flow path unit 173.

Further, for example, a payout path ball out switch 104 is installed at an upstream position of the prize ball case, and a payout counting switch 106 is installed at a downstream position of the payout motor 102. When each prize ball is actually paid out by driving the payout motor 102, a counting signal from the payout counting switch 106 is input to the payout device board 100. Further, when the ball is broken at the upstream position of the prize ball case, the contact signal from the payout path ball out switch 104 is input to the payout device board 100. The payout device board 100 transmits the input counting signal and contact signal to the payout control device 92 (payout control CPU 94). The payout control CPU 94 can detect the actual number of payouts and the out-of-ball state based on the signal received from the payout device board 100.

Further, in the pachinko machine 1, for example, a full tank switch 161 is installed inside the lower plate 6c (the position of the back when viewed from the front of the pachinko machine 1). The prize balls (game balls) actually paid out are discharged to the upper plate 6b through the flow path unit 173, but when the upper plate 6b is full of game balls, the game balls paid out more than that are described above. It flows into the lower plate 6c as described above. Further, when the lower plate 6c is filled with the game balls, the full tank switch 161 is turned on, and the full tank detection signal is input to the payout control device 92 (payout control CPU 94). In response to this, the payout control CPU 94 temporarily suspends further prize ball operations even if it receives a prize ball instruction command from the main control CPU 72, and stores the remaining number of unpaid prize balls in the RAM 98. The memory of the RAM 98 can be backed up even when the power is turned off, and even if a power failure (including a momentary power failure) occurs during the game, the information on the remaining number of unpaid prize balls will not be lost. ..

Further, on the back side of the pachinko machine 1, a firing solenoid 110 is installed together with a firing control board 108. Further, a ball feed solenoid 111 is provided in the saucer unit 6. The launch control board 108, the launch solenoid 110, and the ball feed solenoid 111 constitute the launch control board set 174 described above. Among them, the launch control board 108 is provided with a drive circuit for the launch solenoid 110 and the ball feed solenoid 111. ing. Of these, the ball feed solenoid 111 performs an operation of feeding the game balls stored in the saucer unit 6 one by one to a predetermined launch position in the launcher case. Further, the launch solenoid 110 strikes the game balls sent to the launch position, and continuously (intermittently) launches the game balls one by one toward the game area 8a as described above. The firing interval of the game balls is, for example, an interval of about 0.6 seconds (within 100 balls in 1 minute).

On the other hand, the grip unit 16 located on the front side of the pachinko machine 1 is provided with a firing lever volume 112, a touch sensor 114, and a firing stop switch 116. Of these, the firing lever volume 112 generates an analog signal proportional to the amount of operation (so-called stroke) of the firing handle by the player. Further, the touch sensor 114 detects that the player's body is touching the grip unit 16 (launching handle, ball launching device) from the change in capacitance, and outputs the detection signal. Then, the launch stop switch 116 generates a launch stop signal (contact signal) according to the operation of the player.

A launch relay terminal plate 118 is installed in the saucer unit 6, and each signal from the launch lever volume 112, the touch sensor 114, and the launch stop switch 116 is transmitted to the launch control board 108 via the launch relay terminal plate 118. Will be done. Further, the drive signal from the launch control board 108 is applied to the ball feed solenoid 111 via the launch relay terminal plate 118. When the player operates the firing handle, an analog signal (which may be an encoded digital signal) is generated by the firing lever volume 112 according to the amount of operation, and the firing solenoid 110 is driven based on the signal at this time. As a result, the strength with which the game ball is launched is adjusted according to the amount of operation by the player. The drive circuit of the launch control board 108 stops driving the launch solenoid 110 when the detection signal from the touch sensor 114 is off (low level) or when the launch stop signal is input from the launch stop switch 116. To do. In addition to this, when the game ball rental device connection terminal plate 120 is connected to the launch relay terminal plate 118 and the CR unit is not connected to the game ball rental device connection terminal plate 120, the launch control board is also used. The drive circuit of 108 stops driving the firing solenoid 110.

Further, the saucer unit 6 contains a frequency display board 122 and a lending / returning switch board 123. Of these, the frequency display board 122 is provided with a display (7-segment LED for 3 digits) of the frequency display unit. Further, a switch module connected to the ball lending button 10 and the return button 12 is mounted on the lending / returning switch board 123, and when the ball lending button 10 or the return button 12 is operated, the operation signal is lent out. And, it is transmitted from the return switch board 123 to the CR unit via the game ball rental device connection terminal board 120. Further, from the CR unit, a frequency signal representing the remaining frequency of the valuable medium is transmitted to the frequency display board 122 via the game ball or the like lending device connection terminal plate 120. A display circuit (not shown) on the frequency display board 122 drives the display based on the frequency signal and numerically displays the remaining frequency of the valuable medium. Further, when the valuable medium is not loaded into the CR unit or the remaining frequency of the loaded valuable medium becomes 0, the display circuit of the frequency display board 122 drives the display to display a demo (valuable medium). It is also possible to perform a display prompting the input of.

Further, the pachinko machine 1 is provided with an effect control device 124 (effect control computer) as a control configuration. The effect control device 124 is provided at a position covered by the back cover unit 178 on the back side of the pachinko machine 1. The effect control device 124 controls the effect as the game progresses in the pachinko machine 1. The effect control device 124 is also equipped with an effect control CPU 126, which is a central arithmetic processing unit, on a circuit board (composite sub-control board). The effect control CPU 126 is configured as an LSI in which a semiconductor memory such as a RAM (RWM) 130 or an eRAM 131 is built in together with a CPU core (not shown). The effect control device 124 is equipped with various functions required to realize the effect in the pachinko machine 1. For example, to control devices such as VDP152 for drawing an effect screen reproduced on the screen of the liquid crystal display 42, lamps 46 to 52 for producing visual effects, a board lamp 53, a movable body motor 57, and a status LED 58. The driver IC 132 of the above, the voice IC 134 for controlling the speakers 54, 55, 56 that output voice, and the like are equipped. The internal functional configuration of the effect control device 124 will be described in detail later with reference to another figure.

The effect control device 124 and the main control device 70 are connected to each other via, for example, a communication harness (not shown). However, communication between them is performed in only one direction from the main control device 70 to the effect control device 124, and communication in the opposite direction is not performed. It should be noted that the communication harness depends on the bus width of various effects commands (hereinafter, referred to as "sub-commands" or "effect commands") transmitted from the main control device 70 to the effect control device 124. The parallel format may be adopted, or the serial format may be adopted according to the hardware configuration of each driver (I / O).

In the present embodiment, the sub-connection board 136 is installed on the inner surface of the integrated door unit 4, and the drive signals from the driver IC 132 and the voice IC 134 pass through the sub-connection board 136 to various lamps 46 to 52 and the speakers 54, 55. It is applied to 56. Further, an effect changeover button 45 and a volume adjustment switch (not shown) are connected to the sub-connection board 136, and when the player operates the effect changeover button 45 and the volume adjustment switch, their contact signals are transmitted through the sub-connection board 136. It is input to the effect control device 124. Further, a jog dial 45a is connected to the sub-connection board 136, and when the player rotates the jog dial 45a, the rotation signal is input to the effect control device 124 through the sub-connection board 136. Although an example in which the effect switching button 45 and the jog dial 45a are connected to the sub-connection board 136 is given here, when the saucer illumination board is installed, the effect switching button 45 and the jog dial 45a are connected to the saucer illumination board. It may be.

In addition, a driver board 138 is installed on the game board unit 8, and a movable motor 57 and a status LED 58 are connected to the driver board 138 in addition to the board lamp 53. The movable body motor 57 drives the movable body 40f via, for example, a link mechanism (not shown). The drive signal from the driver IC 132 is applied to the board lamp 53, the movable motor 57, and the status LED 58 via the driver board 138, respectively.

The liquid crystal display 42 is installed on the back side of the game board unit 8, and its display screen can be visually recognized through a substantially rectangular opening formed in the game board unit 8. Further, an inverter board 158 is installed on the back side of the game board unit 8, and the inverter board 158 generates an AC power supply applied to the backlight (for example, a cold cathode tube) of the liquid crystal display 42.

In addition, a power supply control unit 162 is mounted on the back side of the inner frame assembly 7. The power supply control unit 162 has a built-in switching power supply circuit, and when external power (for example, AC24V, etc.) is taken from the island equipment through the power cord 164, necessary power (for example, DC + 34V, + 12V, etc.) can be generated from the external power. The electric power generated by the power supply control unit 162 is distributed to the main control device 70, the payout control device 92, the effect control device 124, and the inverter board 158. Further, electric power is supplied to the launch control board 108 via the payout control device 92, and electric power is supplied to the CR unit via the game ball or the like rental device connection terminal plate 120. The low-voltage power for logic (for example, DC + 5V) is generated by a power supply IC (3-terminal regulator or the like) built in each device. Further, as described above, the power supply control unit 162 is grounded (grounded) to the island equipment through the ground wire 166.

The external terminal board 160 is connected to the payout control device 92, and various external information signals generated by the main control device 70 (main control CPU 72) are external from the external terminal board 160 via the payout control device 92. It is output to. The main control device 70 (main control CPU 72) and the payout control device 92 (payout control CPU 94) can output an external information signal to the outside of the pachinko machine 1 through the external terminal plate 160. The signals output from the external terminal board 160 are aggregated by, for example, a hall computer (not shown) in the amusement park. Although the configuration via the payout control device 92 is given as an example here, the configuration may be such that the external information signal is directly output from the main control device 70 to the external terminal plate 160.

[Internal configuration of production control device]
FIG. 6 is a block diagram showing an internal functional configuration of the effect control device 124.
As described above, the effect control device 124 has a role as an effect control processor that controls the effect as the game progresses. Therefore, in addition to the effect control CPU 126, the effect control device 124 is equipped with a control ROM 180 and a watchdog timer IC (WDTIC) 188, which are necessary for the effect control device 124 to function as the effect control processor. The control ROM 180 stores a basic program for controlling the effect. The effect control CPU 126 controls the effect by accessing the control ROM 180 via a CPU bus (not shown) and executing a program stored in the control ROM 180. The watchdog timer IC188 is a timer that monitors whether the control executed by the effect control device 124 is normally performed (whether the process is completed within the estimated time), and is connected to the reset terminal of the effect control CPU 126. There is. If the signal (clear pulse) for clearing the monitoring timer of the watchdog timer IC188 is not input within a predetermined time, the watchdog timer IC188 outputs a signal (reset pulse) for resetting and activating the effect control CPU 126. To do. As a result, the effect control device 124 is forcibly reset and activated.

In addition to these, the effect control device 124 has SRAM 182, which is a storage area for backup data, a crystal oscillator 181 that generates a clock signal of a predetermined frequency, and a real-time clock (RTC) 184 that manages time. , A lithium battery 186 that supplies backup power to the SRAM 182 and RTC 184, peripheral ICs such as an input / output driver and a counter / timer circuit (not shown) are provided. The lithium battery 186 stores the electric power and charges itself while the driving electric power is being supplied from the power supply control unit 162 to the effect control device 124. The SRAM 182 and the RTC 184 are connected to the lithium battery 186, and can be driven by the lithium battery 186 when the supply of the driving power from the power supply control unit 162 to the effect control device 124 is cut off. Therefore, even if the power supply from the power supply control unit 162 is cut off, the SRAM 182 and the RTC 184 continue to operate for a period until the lithium battery 186 is depleted (for example, about one and a half months). , The stored information can be retained for a while even when the power is turned off.

The effect control program is configured to store information on security, monitoring, defects, and the like that should not be easily erased in the SRAM 182. As a result, for example, when some trouble occurs in the effect control device 124, the pachinko machine 1 is collected (or inspected in the installed state), and the information held in the SRAM 182 is analyzed to proceed with the investigation of the cause of the trouble. It becomes possible.

The effect control device 124 is a device that controls the content of the effect related to the game.
The RTC184 is a device that can communicate with the effect control device 124 by serial communication or the like and holds the current time information (predetermined information). Further, the RTC 184 is a device that measures the current time and updates the current time information regardless of whether or not the gaming machine is in a power-off state.

By the way, as described above, the liquid crystal display 42, various lamps 46 to 53, the speakers 54, 55, 56, the status LED 58, etc. are used to control the effect executed by the effect control CPU 126 according to the program stored in the control ROM 180. Includes control of production using devices. The flow of this effect control can be roughly divided into two stages, "overall control (reproduction instruction)" and "individual control (reproduction control)". The effect control CPU 126 first receives an effect command transmitted from the main control device 70, and indirectly instructs each device to reproduce the effect according to the content of the effect command (overall control). Next, the effect control CPU 126 generates instruction data obtained by converting the instruction content into a more specific expression suitable for each device, and relays between the effect control CPU 126 and each device. Send to (individual control). As a result, each control device 134, 152, 198, 199 controls each device based on the instruction data, and the effect reproduction (screen display, voice output, lamp emission, movable body displacement) using each device in the pachinko machine 1 is performed. Etc.) are realized.

As described above, the effect control CPU 126 has different functions depending on the stage of the effect control, and these functions are realized by properly using the resources of the effect control CPU 126. At the stage of overall control, the effect control unit 210 in the effect control CPU 126 becomes the main operator. Further, in the stage of individual control, the display control unit 220, the voice control unit 222, the lamp control unit 224, the motor control unit 226, or the sensor control unit 228 in the effect control CPU 126 are the main operating units according to the device to be controlled. It becomes. The effect control unit 210 may be configured to directly control the control devices 134, 152, 198, and 199.

The effect control device 124 functions as an effect control processor at the stage of overall control, whereas it functions as an effect reproduction processor at the stage of individual control. Therefore, in addition to the circuit board (effect display control board) and CGROM (image / audio ROM) 190 on which the VDP 152 is mounted, the effect control device 124 also includes an audio IC 134 for controlling various devices used for reproducing the effect. It is equipped with an LED driver 198, an SMC (serial control controller) 199, and a driver IC 132.

The CGROM 190 stores the drawing material (moving image data) constituting the effect screen and the audio material (audio data) output as the effect progresses in a state of being compressed by a predetermined compression algorithm. The CGROM 190 is connected to the VDP 152 and the voice IC 134 via a CG bus (not shown).

The VDP152 is a processor dedicated to drawing an effect image, and is integrated into one chip together with the effect control CPU 126. Further, the VDP 152 has a built-in VRAM 156 mainly used when developing a drawing material and a drawing material decoder 157 for decompressing (decoding) the drawn drawing material in a compressed state. The VDP 152 first analyzes the instruction content transmitted from the display control unit 220, reads the necessary drawing material from the CG ROM 190 via the CG bus, and transfers it to the VRAM 156. Then, the read drawing material is decoded by the drawing material decoder 157, the effect image is drawn on the VRAM 156, and the effect image is expanded in the frame buffer for each frame (still image per unit time). By individually driving each pixel (full-color pixel) of the liquid crystal display 42 based on the image data buffered here, the reproduction of the effect screen is realized.

The audio IC 134 is a sound generator that generates sound effects such as sound effects and BGM that are reproduced during the execution of the effect, and is connected to an amplifier, an external DRAM, or a CG bus (not shown). Further, the audio IC 134 has a built-in audio material decoder 135 that decompresses (decodes) the compressed audio material. The voice IC 134 first analyzes the instruction content transmitted from the voice control unit 222, and reads out the necessary voice material from the CGROM 190 via the CG bus. Then, the read audio material is decoded on the external DRAM using the audio material decoder 135. By outputting the decoded audio to the speakers 54 and 55 on the glass frame and the outer frame speaker 56 via the amplifier, stereo 2ch or monaural 2ch audio reproduction (may be a larger number of channels) is realized. Further, the voice IC 134 adjusts the output volume of each speaker 54, 55, 56 based on the contact signal input when the volume adjustment switch is operated.

The LED driver 198 controls the lighting pattern and the brightness pattern of various lamps 46 to 53 and the status LED 58 provided on the front side of the pachinko machine 1. In the LED driver 198, an address designation synchronous serial system is adopted. The LED driver 198 first controls the lighting pattern and the brightness pattern based on the instruction content transmitted from the lamp control unit 224, and transfers the drive data corresponding to the control to the driver IC 132.

The SMC 199 controls the drive pattern of the movable body motor 57, which is a drive source for the movable body 40f for effect provided inside the effect unit 40. In SMC199, a clock synchronous serial system is adopted. The SMC 199 first generates a drive pattern based on the instruction content transmitted from the motor control unit 226, and transfers this to the driver IC 132. Although the SMC 199 is used only for generating the drive pattern of the motor here, since the SMC 199 can generate not only the motor but also the lighting pattern and the brightness pattern of the lamp, the SMC 199 is applied instead of the LED driver 198 described above. However, it is also possible that the SMC 199 is configured to generate data patterns for both lamps and motors.

The driver IC 132 controls the drive voltage applied to the lamp or the motor based on the drive data transferred from the LED driver 198 or the SMC 199. The driver IC 132 includes switching elements such as PWM (pulse width modulation) ICs and MOSFETs (not shown), and switches (or duty switches) the drive voltage applied to various lamps 46 to 53, the movable motor 57, and the status LED 58. Then, by managing the operation, the effect reproduction using the lamp or the movable body is realized. Of the various lamps 46 to 53, the board lamp 53 is an LED built in the effect unit 40, an LED built in the variable start winning device 28, the first variable winning device 30, the second variable winning device 31, and the like. It is equivalent. The status LED 58 is composed of one or a plurality of LEDs, and is a lamp that indicates the status state of the effect control device (for example, the state before system initialization, the state after system initialization, the normal state, etc.) by a lighting pattern. Further, although an example in which the glass frame decorative lamp 52 is connected to the sub-connection board 136 is given here, the saucer illumination board is installed in the saucer unit 6, and the saucer illumination board is attached to the glass frame decoration lamp 52. It may be configured to be connected to the driver IC 132 via the driver IC 132.

In addition to this, the driver IC 132 transfers the contact signal input when the effect switching button 45 or the jog dial 45a is operated to the effect control unit 210 via the sensor control unit 228. The effect control unit 210 appropriately changes the effect content to be reproduced based on the content of the transferred contact signal.

FIG. 7 is a diagram showing a memory map of the memory area used by the main control CPU 72. The memory area used by the main control CPU 72 includes a memory area (0000H to 2FFFH) allocated to the ROM 74 and a memory area (F000H to F3FFH) allocated to the RAM 76.

The area (first area) of addresses 0000H to 0BFFH is an area in which the program code (program) of the used area can be stored. The program code of the used area is the first information (for controlling the progress of the game) necessary for executing the game.

The area (first area) of addresses 0000H to 0BFFH is a part of the program code (first information) of the used area and the program code (second information) that is not necessary for executing the game. Contains special program code (special information).

The area of addresses 0C00H to 0FFFH is an unused area.

The area (first area) of the addresses 1000H to 1BFFH is an area in which the program data (data) of the used area can be stored. The program data of the used area is the first information necessary for executing the game. The area (first area) of addresses 1000H to 1BFFH is a part of the program data (first information) of the used area and the program data (second information) that is not necessary for executing the game. Special program data (special information) is stored.

The area of addresses 1C00H to 1FFFH is an unused area.

The area (second area) of the addresses 2000H to 2FFFH is an area in which the program code / program data outside the area can be stored. The program code / program data outside the area is the second information that is not necessary for executing the game (for example, regarding the process for performing the test specified by the game machine rules and the process related to the performance display monitor). In the area (second area) of addresses 2000H to 2FFFH, the non-special program code / non-special program data (non-special program code) which is the remaining information of the program code / program data (second information) not required for executing the game. Special information) is stored.

The area of addresses 3000H to EFFFH is an unused area.

The areas of addresses F000H to F1FFH are used as a work area of a used area and a stack RAM. The areas of addresses F200H to F3FFH are used as a work area outside the area and a stack RAM. These areas are used as stack areas for temporarily saving areas and data that are temporarily used when a program in the used area is being executed or a program outside the area is being executed.

The area of addresses F400H to FFFFH is an unused area.

In the memory area of the ROM 74, in addition to the used area and the area outside the area, an area in which arbitrary data such as the title and version of the program is stored, and a program in which the information necessary for the main control CPU 72 to execute the program is stored. A management area may be provided.

As described above, the ROM 74 and the RAM 76 (storage means) of the present embodiment have a used area (first area) capable of storing the program code / program data (first information) required for executing the game, and the game. It has an area outside (second area) that can store program code and program data (second information) that are not required for execution.

Here, the usable area is an area in which the capacity that can be used to control the progress of the game is defined by the game machine rules, and the outside of the area is an area that is not included in the calculation of the usable capacity. ..

The main control device 70 (main control CPU 72) pachinko based on the program code program data (first information) required for executing the game and the program code program data (second information) not required for executing the game. Control the machine 1 (game machine) (control means).

The used area (first area) includes the program code / program data (first information) required for executing the game and the program code / program data (second information) not required for executing the game. Some information such as special program code and special program data (special information) is stored.

Outside the area (second area), non-special program code / non-special program data (non-special information), which is the remaining information of the program code / program data (second information) that is not necessary for executing the game, is present. It is stored.

The special program code / special program data (special information) is information different for each model in multiple types of models with different game contents, and the non-special program code / non-special program data (non-special information) is the game contents. This is information common to each model in multiple types of models with different values.

Therefore, when changing the specifications of the gaming machine, it is necessary to change the special program code and special program data. On the other hand, the non-special program code and the non-special program data do not need to be changed even when the specifications of the gaming machine are changed.

In the special program code / special program data (special information), among the processes for calculating the base, the judgment process for determining whether or not to calculate the base based on the game state, and the value of the number of prize balls are confirmed. It contains information about at least one of the confirmation processes. Either the determination process or the confirmation process may be non-special program code / non-special program data (non-special information).

In the present embodiment, due to the performance of the main control CPU 72, even when the same instruction (program code) is used, the processing speed may differ depending on whether the instruction (program code) is used in the used area or outside the area. is there. For example, when the LDQ instruction (special load instruction) is used in the used area, the processing speed is increased, but when the LDQ instruction is used outside the area, the processing speed is not increased. Therefore, the LD instruction (normal load instruction) whose processing speed is slow must be used outside the area. The reason for this is that when the LDQ instruction is used outside the area, it is necessary to add stack pointer, Q register save, reset, and return processing, so that the processing speed becomes rather slow. Therefore, in the present embodiment, the processing speed is faster when the process related to the used area is executed than when the process related to the outside of the area is executed.

The main control CPU 72 uses (by executing) the program code / program data stored in the used area (first area) to process the used area (first process) required for executing the game. It can be executed (first processing execution means).

Further, the main control CPU 72 uses (by executing) the program code / program data stored outside the area (second area) to perform processing outside the area (second processing) that is not necessary for executing the game. ) Can be executed (second processing execution means). The above is a configuration example relating to the control of the pachinko machine 1.

FIG. 8 is a diagram showing the relationship between the set value and the winning probability of the special symbol lottery. When the set value is "1", the winning probability (low probability state) of the special symbol lottery is "1/319". When the set value is "2", the winning probability (low probability state) of the special symbol lottery is "1/299". When the set value is "3", the winning probability (low probability state) of the special symbol lottery is "1/279". When the set value is "4", the winning probability (low probability state) of the special symbol lottery is "1/259". When the set value is "5", the winning probability (low probability state) of the special symbol lottery is "1/239". When the set value is "6", the winning probability (low probability state) of the special symbol lottery is "1/199".

When the set value is "1" to "6", the winning probability (high probability state) of the special symbol lottery is "1/32".

As described above, the larger the set value, the larger the winning probability (low probability state) of the special symbol lottery, which is advantageous for the player.

In the illustrated example, the winning probability of the special symbol lottery has been described in the example in which the setting difference is provided only in the low probability state, but the setting difference may be provided even in the high probability state. Further, regarding the setting, not only the big hit probability but also the small hit probability may be set differently. Further, setting differences may be provided for other items (for example, the transition rate to the high probability state, the transition rate to the time reduction state, the number of probability changes, the number of time reductions, the number of special fluctuations, etc.).

FIG. 9 is a diagram showing the state of the setting key, whether or not the setting can be changed, and whether or not the setting can be inserted / removed. When the state of the setting key is ON (when it is rotating to the right, when the input signal from the setting key switch 302 is ON), the setting can be changed (including setting confirmation), and the setting key can be pressed. It is impossible to pull it out. In other words, the setting key cannot be removed while changing the setting or checking the setting.

On the other hand, when the state of the setting key is OFF (when it is rotated to the left, when the input signal from the setting key switch 302 is OFF), the setting cannot be changed (including the setting confirmation), and the setting is made. It is possible to remove the key. In other words, the setting key can be removed unless the setting is being changed or the setting is being confirmed.

For setting change and setting confirmation, if it is possible to shift to the setting change state or setting confirmation state without using the "setting key", for example, only by operating a button, a person who does not have the authority to change the setting (for example, hall staff or malicious intent) It is possible for a certain player, etc.) to change the settings and check the settings, and there is a risk of setting leaks. Therefore, the use of the "setting key" is an indispensable condition for changing the setting and confirming the setting.

There are two states of the "setting key", ON and OFF. The state of the "setting key" can be confirmed by a signal from the setting key switch 302. Maintain the ON state and OFF state by operating the "setting key".

The "setting key" can be inserted and removed only when the state of the "setting key" is OFF. The "setting key" can be inserted into the setting key keyhole 306. The setting key keyhole 306 exists in a transparent case that covers the main control board unit 170, and can be operated without opening the transparent case.

For example, the following conditional branch is included in the program code of the main controller 70. Include that the setting key is ON in the transition condition to changing the setting or confirming the setting. The transition condition to the playable state includes the fact that the setting key is turned from ON to OFF. Alternatively, simply include "the setting key is in the OFF state". Include that the setting key is OFF in the end condition during setting change or setting confirmation.

As a result, without the "setting key", it is not possible to move during the setting change or setting confirmation, and the setting value cannot be confirmed. Therefore, the hall manager may not intend to change the setting or leak the setting. Can be prevented.

Subsequently, the control processing executed by the main control CPU 72 of the main control device 70 will be described.

[CPU initialization (main) processing in the main controller]
When the power is turned on to the pachinko machine 1, the main control CPU 72 starts the CPU initialization process in the main control device 70. The CPU initialization process restores the game state (so-called power recovery) based on the backup information saved when the power was cut off last time, or conversely clears the backup information to restore the initial state of the pachinko machine 1. It is a process for adjusting. Further, the CPU initialization process is positioned as a main process (main control program) for guaranteeing stable gaming operation of the pachinko machine 1 after adjusting the initial state.

10 and 11 are flowcharts showing an example of the first procedure of the CPU initialization process. Hereinafter, the processing performed by the main control CPU 72 will be described step by step.

Step S100: The main control CPU 72 first sets the start address of the stack area in the stack pointer.

Step S102: Subsequently, the main control CPU 72 sets the interrupt vector table. In this process, the main control CPU 72 sets the address of the interrupt vector table in the I register (interrupt vector register) used for interrupt control. The interrupt vector table defines the priority required to control the interrupt request generated during the execution of the CPU initialization process, and the main control CPU 72 has a plurality of priorities based on the priority defined in the interrupt vector table. Execute interrupt requests in order.

Step S104: The main control CPU 72 has a RAM clear signal (input signal from the RAM clear switch 304), a setting key switch signal (input signal from the setting key switch 302), and an inner frame opening signal (contact from the plastic frame opening switch 93). Signal) is saved. More specifically, the values of the input ports to which these signals are input are acquired twice in succession, and the logical product of the acquired values (logical sum for negative logic signals) is the input port value at power-on. And save it as. The opening of the inner frame may be confirmed by a contact signal from the glass frame opening switch 91 or another inner frame opening switch (not shown).

Step S106: The main control CPU 72 executes the standby process here. This process is a process of waiting for the power supply to stabilize and a process of waiting for the activation of the effect control device 124. The main control CPU 72 secures a certain amount of standby time (for example, about several thousand ms, about 3.1 seconds) after the power is turned on, and during that time, a power off warning signal (a signal indicating that the power is being cut off). ) Is checked. Specifically, when the main control CPU 72 sets the loop counter for the standby time, it bit-checks the input port of the power cutoff warning signal while decrementing the value of the loop counter. The power supply cutoff warning signal is input by an IC that monitors the voltage level of the drive voltage. Then, if the input of the power off warning signal is confirmed before the loop counter becomes 0, the main control CPU 72 restarts the process from the beginning. Thereby, for example, it is possible to protect the system when the operation of turning on and off the main power switch (not shown) is repeatedly performed within a short time (about 1 to 2 seconds).

Step S108: Next, the main control CPU 72 permits access to the work area of the RAM 76. Specifically, the RAM protect setting value of the work area is reset (00H). As a result, after that, access to the work area of the RAM 76 is permitted.

Step S109: The main control CPU 72 checks whether or not the inner frame is open and the setting key is ON by checking the specific bit of the input port value saved in the previous step S104.

As a result, when it is confirmed that the inner frame is open and the setting key is ON (Yes), the main control CPU 72 executes step S110. On the other hand, when the inner frame is opened and it cannot be confirmed that the setting key is ON (No), the main control CPU 72 executes step S113 (in-page combiner 1 → 1).

Step S110: The main control CPU 72 refers to the RAM clear signal by checking the specific bit of the input port value saved in the previous step S104, and confirms whether or not the RAM clear switch 304 has been pressed.

As a result, when it is confirmed that the RAM clear switch 304 has been pressed (Yes), the main control CPU 72 executes step S112. On the other hand, when it cannot be confirmed that the RAM clear switch 304 has been pressed (No), the main control CPU 72 executes step S111a.

Step S111a: The main control CPU 72 confirms whether or not the value of the gaming machine status flag is “00H (gamable state)”.

The gaming machine status flag is stored in the setting value buffer of the RAM 76, "00H" indicates that the game is available, "01H" indicates that the setting is being changed, and "02H" indicates that the setting is being confirmed. Shows inside.

The setting value is also stored in the setting value buffer, and the setting value buffer is not cleared even when the RAM clear is started. The reason for this is that "even if the power is turned off during the setting change and the RAM is cleared and started, the state during the setting change is continued" and "when the setting confirmation condition is satisfied, the gaming machine status flag is changed. However, it does not affect the value of the checksum. "

As a result, when it is confirmed that the value of the gaming machine state flag is "00H (gamable state)" (Yes), the main control CPU 72 executes step S111b. On the other hand, when it cannot be confirmed that the value of the gaming machine state flag is "00H (gamable state)" (No), the main control CPU 72 executes step S114 (in-page coupler 2 → 2).

Step S111b: The main control CPU 72 executes a process of setting "02H (setting is being confirmed)" in the gaming machine status flag. Next, the main control CPU 72 executes step S114 (in-page combiner 2 → 2).

By executing such a process, the main control CPU 72 can confirm the set value when a special condition is satisfied (when the setting key switch is ON and the RAM clear switch is OFF and the power is turned on). It is possible to shift to the setting confirmation state (setting confirmation state transition means).

Step S112: The main control CPU 72 executes a process of setting "01H (setting is being changed)" in the gaming machine status flag. Next, the main control CPU 72 executes step S120 (in-page combiner 3 → 3).

Then, by executing the process of step S112 and then executing the process of step S120 described later, the main control CPU 72 is determined when a special condition is satisfied (the setting key switch is ON and the RAM clear switch). When the power is turned on when is ON), the RAM clear process that clears the specified RAM value can be executed, and the setting value can be shifted to the changeable setting change state (setting change state transition means). ..

Step S113: The main control CPU 72 confirms whether or not the RAM clear switch 304 has been pressed.

As a result, when it is confirmed that the RAM clear switch 304 has been pressed (Yes), the main control CPU 72 executes step S120 (in-page combiner 3 → 3). On the other hand, when it cannot be confirmed that the RAM clear switch 304 has been pressed (No), the main control CPU 72 executes step S114.

Step S114: The main control CPU 72 executes a process of confirming whether the backup flag and the checksum are normal.

Regarding the backup flag, the main control CPU 72 confirms whether or not the backup flag is set (whether or not the backup information is stored in the RAM 76). If the backup is normally completed by the process executed at the time of the previous power cutoff and a specific value (for example, "01H") is set in the backup flag, it is determined that the backup flag is normal. The backup flag is set to a specific value when a normal backup process is executed.

Regarding the checksum, the main control CPU 72 executes the checksum for the backup information of the RAM 76. Specifically, the main control CPU 72 checkssums all the work areas of the RAM 76 except the backup flag and the checksum buffer. If the checksum result is normal, the main control CPU 72 determines that the checksum is normal.

As a result, when it is confirmed that the backup flag and the checksum are normal (Yes), the main control CPU 72 executes step S116. On the other hand, when it cannot be confirmed that the backup flag and the checksum are normal (No), the main control CPU 72 executes step S120.

Step S116: The main control CPU 72 executes an initialization process when the power is restored. Specifically, the main control CPU 72 clears the stored contents of a part of the RAM 76. The partial area of the RAM 76 is a memory area to be cleared when the power is restored.

Step S117: The main control CPU 72 executes a backup restoration process. The main control CPU 72 restores the stored valid backup information. As a result, the main control CPU 72 can restore the state when the power is cut off.

Step S118: The main control CPU 72 sends a command to be transmitted to the effect control device 124 when the power is restored (for example, a power restoration designation command indicating that the power is restored from the power cutoff and started) and a payout command (to the issue control device 92). Set the command to be sent). When this process is completed, the main control CPU 72 then executes step S125.

Step S120: The main control CPU 72 executes an initialization process (RAM clear process) at the time of RAM clear. Specifically, the main control CPU 72 clears the stored contents of the used area of the RAM 76 to be cleared when the RAM is cleared. As a result, the work area and the stack area of the RAM 76 are initialized, and even if valid backup information is saved, the contents are erased. The stored contents outside the area of the RAM 76 may or may not be cleared. The value of the gaming machine status flag may or may not be cleared. If the value of the gaming machine status flag is cleared, the determination of step S131a described later will always be negative (No). Therefore, when the determination of step S131a described later is performed based on the state before clearing the RAM, the gaming machine It is preferable not to clear the value of the state flag. Further, the main control CPU 72 performs the initial setting of the RAM 76.

Step S122: The main control CPU 72 executes a process of saving the output time (for example, 128 ms) in the security signal output timer (special information transmission process execution means). By saving the output time in the security signal output timer, the security signal is output to the hall computer in the external information management process (step S217a in FIG. 24).

By executing such a process, even if a situation occurs in which the setting change state ends in less than 128 ms, a special transmission process for continuously transmitting a security signal to the hall computer for at least 128 ms is executed. can do.

Step S124: The main control CPU 71 sets a command to be transmitted to the effect control device 124 at the time of RAM clear (for example, a RAM clear designation command indicating that the RAM clear has been started) and a payout command (command to the payout control device 92). ..

Step S125: The main control CPU 71 executes a common initialization process when the RAM is cleared and when the power is restored.

Step S126: Next, the main control CPU 72 executes the payout control output process. In this process, the main control CPU 72 outputs the payout command (power recovery designation command) set in step S118 or the payout command (RAM clear designation command) set in step S124 to the payout command buffer.

Step S128: The main control CPU 72 executes the subcommand output process. In this process, the main control CPU 72 first outputs the effect command (power return designation command) set in step S118 or the effect command (RAM clear designation command) set in step S124 to the subcommand transmission buffer. Further, the main control CPU 72 has various other effect commands (for example, a model designation command, a state specification command, a special figure destination determination effect command, an operation memory number increase effect command, and an operation memory number decrease effect) required for the effect control. Set commands, count-cut counter value commands, normal game management phase commands, special game management phase commands, launch position specification commands, etc.) and output these to the subcommand transmission buffer. At this time, the main control CPU 72 can set different values for these effect commands when the power is restored and when the RAM is cleared.

For example, when the power is restored, the value of each effect command is set based on the backup information. By transmitting these effect commands to the effect control device 124 in the subsequent subcommand transmission process (step S144), the effect control device 124 is in the effect state (for example, the effect state) that was being executed when the power was cut off last time. The internal probability state, the display mode of the effect symbol, the effect display mode of the number of working memories, the sound output content, the light emitting state of various lamps, etc.) can be restored.

Step S130: The main control CPU 72 executes input port processing. In this process, the main control CPU 72 acquires the contents of each input port and stores the result of performing a predetermined operation on the value in the state flag of each input port. When this process is completed, the main control CPU 72 then proceeds to step S131 (out-of-page coupler A → A).

Step S131: The main control CPU 72 executes a process of resetting the main command permission signal (communication permission signal). The main command permission signal is a signal that can be independently set by the main control CPU 72 (main control device 70) and the payout control CPU 94 (payout control device 92). The main control device 70 and the payout control device 92 are connected by two lines, the first line is a signal line and the second line is a command line.

For example, when the main control CPU 72 sets the main command permission signal, the payout control CPU 94 can transmit a command. On the other hand, when the payout control CPU 94 sets the main command permission signal, the main control CPU 72 can transmit the command.

Here, since the main control CPU 72 is executing the process of resetting the main command permission signal, the payout control CPU 94 is in a state where the command cannot be transmitted.

If the payout command permission signal on the payout control device 92 side has not been reset, the main control device 70 can transmit the command. However, since the payout command (prize ball command) is not generated while the setting is being changed or the setting is being confirmed, the game ball is not paid out by the payout control device 92. When the main command permission signal can be set in the payout control device 92, the payout command permission signal on the payout control device 92 side may be the main command permission signal on the payout control device 92 side.

Here, if the main command permission signal on the main control device 70 side is reset, the payout control device 92 causes a communication error. In order to avoid a communication error, a method of communicating with the payout control device 92 and transmitting a command indicating that the setting is being changed may be adopted.

An advantage of adopting a method in which the main command permission signal on the main control device 70 side is not set and communication with the payout control device 92 is not performed is that it is not necessary to change the software of the payout control device 92. It is also possible to prevent the game ball from being fired by resetting the firing permission signal.

In the present embodiment, the main command permission signal is described as being a signal that can be independently set by the main control CPU 72 (main control device 70) and the payout control CPU 94 (payout control device 92). The command permission signal can be set only by the main control device 70, and can be a signal that cannot be set by the payout control device 92. In this case, the payout control device 92 uses the payout command permission signal (communication permission signal) instead of the main command permission signal. Then, when the payout control device 92 sets the payout command permission signal, the main control device 70 is in a state where the command can be transmitted to the payout control device 92, and the payout control device 92 resets the payout command permission signal. As a result, the main control device 70 becomes unable to send a command to the payout control device 92. The main command permission signal and the launch permission signal may be set by the dynamic port output process. Since the dynamic port output process is called from the timer interrupt once every 4 ms, if the main command permission signal etc. is set in the dynamic port output process, the main command is based on the latest game machine status flag value. You can set the command permission signal and so on.

Step S131a: The main control CPU 72 confirms whether or not it is in a game-enabled state. Specifically, it is confirmed whether or not the value of the gaming machine status flag is "00H".

As a result, when it is confirmed that the game is possible (Yes), the main control CPU 72 executes step S131b. On the other hand, when it cannot be confirmed that the game is playable (No), the main control CPU 72 executes step S132 without executing step S131b.

Step S131b: The main control CPU 72 executes a process of setting a main command permission signal in a specific bit of the output port. As a result, the payout control device 92 is in a state where a command can be transmitted to the main control device 70. As a result, if the game is playable, the game ball can be paid out.

By executing such a process, the main control CPU 72 sets a predetermined prohibited state while the setting is being changed or the setting is being confirmed (when the setting-related process is being executed and the game is not available), thereby controlling the payout. It is possible to execute a prohibition process that does not cause the device 92 to execute the payout of the game ball (prohibition process execution means).

The payout control device 92 transmits a payout start command (startup command) to the main control device 70, receives a start confirmation command for the payout start command, and is in a payout available state. Pay out the game ball based on the payout command sent.

Further, by executing such a process, the main control CPU 72 prohibits the payout start command from being transmitted from the payout control device 92 to the main control device 70 by setting a predetermined prohibition state. , It is possible to prohibit the payout control device 92 from being in the payout enable state and prevent the payout control device 92 from executing the payout of the game ball (prohibition processing execution means).

Further, by executing such a process, the main control CPU 72 sets the main command permission signal (communication permission signal) on the main control device 70 side to OFF (communication disallowance), thereby setting a predetermined prohibition state (communication disallowance). The main command permission signal on the main control device 70 side can be set to OFF (a state in which the main command permission signal is OFF) (prohibition processing execution means).

Step S132: The main control CPU 72 resets (OFF) the specific bit of the output port to clear the emission permission signal. The launch permission signal is included in the backup target when the power is cut off. Therefore, when the power of the main control device 70 (pachinko machine 1) is restored, the launch permission signal is also returned to the state when the power is cut off.

The emission permission signal is set in a specific bit (for example, bit 0) of the specific output port buffer (for example, the buffer for the output port 3) stored in the RAM 76.

Step S133: The main control CPU 72 sets the timer interrupt cycle. More specifically, the main control CPU 72 sets a value corresponding to a predetermined timer interrupt cycle (for example, 4 ms) in the counter setting register of the timer circuit 194.

Step S134: The main control CPU 72 resets the interrupt daisy chain. Specifically, the main control CPU 72 executes the RETI instruction after backing up the start address of the main loop processing described later as a preliminary preparation for the interrupt processing. By performing this processing, it is possible to normally start the interrupt processing that occurs thereafter, and to continue the processing from the main loop processing after the interrupt processing is executed.

When the above procedure is executed in the CPU initialization process, the main control CPU 72 starts executing the main loop process in step S135. As long as the power supply from the power control unit 162 is maintained, the main control CPU 72 repeatedly executes the main loop process from beginning to end.

When the setting function (setting changing device 300) is added to the pachinko machine 1, the state at the time of turning on the power increases. At this time, by some operations, "normal recovery (recovery)", "RAM clear recovery (initialization)", "setting confirmation mode (setting confirmation)", "setting change mode (setting change mode)", which is the state when the power is turned on, It is necessary to separate "setting change)".

In the present embodiment, in order to divide the state at the time of power-on into four, the transition determination is performed using two input devices such as the setting key switch 302 and the RAM clear switch 304.

The conditions for transition to the four states are as follows. (1) Normal recovery RAM clear switch: OFF Setting key switch: OFF (2) RAM clear return RAM clear switch: ON Setting key switch: OFF (3) Setting confirmation mode RAM clear switch: OFF Setting key switch: ON (4) ) Setting change mode RAM clear switch: ON Setting key switch: ON

In this way, the four states can be separated by operating the setting key switch 302 and the RAM clear switch 304.

FIG. 12 is a diagram showing a command transmission timing of the first procedure example of the CPU initialization process.

[Main control device] When the power is turned on, the main control device 70 waits for [A01] 3.1 seconds, and [A02] determines the activation method.

Depending on the determination of the activation method, the main control device 70 is activated by [A03] initialization (RAM clear), [A04] restoration (recovery of backup information), or [A05] setting change. Or, it can be started by checking the [A06] settings.

Then, when the processing of [A03] initialization, [A04] power recovery, [A05] setting change, or [A06] setting confirmation is completed, the main control device 70 sets the [A07] main command permission signal to ON. [A08] The game shifts to the playable state. After the main command permission signal is set to ON, the command from the payout control device 92 can be received.

[Payout control device] When the power is turned on, the payout control device 92 waits for [B01] 0.1 seconds and executes [B02] power-on processing. In the power-on processing, the payout control device 92 can set the main command permission signal on the payout control device 92 side to ON.

Next, the payout control device 92 sets the [B03] payout command permission signal to ON, and shifts to the [B04] start command transmission waiting state. The start command transmission waiting state is a state in which the main control device 70 is waiting for the main command permission signal to be set to ON, and a command cannot be transmitted to the main control device 70 (). Command transmission impossible state to the main control device 70).

Then, when the main command permission signal is set to ON in the main control device 70 ([A07]), the payout control device 92 is in a state where a command can be transmitted to the main control device 70 (main control). The command can be transmitted to the device 70), [C01] The payout control device 92 transmits a payout start command to the main control device 70.

Upon receiving the payout start command, the main control device 70 transmits a [C02] start confirmation command to the payout control device 92 as a command in response to the command. As a result, the payout control device 92 shifts to the [B05] game-enabled state, and the game ball can be paid out.

Since the game can be stopped while the setting is being changed or the setting is being confirmed, it is desired to prohibit the command transmission from the payout control device 92.

In order to prohibit the command transmission from the payout control device 92 while the setting is being changed or the setting is being confirmed, the following method is adopted in the first procedure example of the CPU initialization process. The commands transmitted from the payout control device 92 to the main control device 70 are classified as follows.

(1) Payout start command (confirmation of payout operation permission) (2) Error-related commands (notify the payout error (full tank error, failure error, etc.) with the effect control device)

The operation of the main control device 70 at the time of receiving each command is as follows. (3) After receiving the command of (1) above, the main control device 70 returns a command (start confirmation command) for permitting the payout operation to the payout control device 92. (4) After receiving the command in (2) above, an error command is transmitted to the effect control device 124.

Here, there is no problem even if the above (4) is executed, but in the above (3), there is a possibility that the payout operation is performed while the setting is being changed or the setting is being confirmed. Therefore, in order not to perform the above (3), a method of using the "main command permission signal" and not transmitting the command is adopted.

The usage of the main command permission signal is as follows. The payout control device 92 confirms the "main command permission signal" on the main control device 70 side before transmitting the command. The "main command permission signal" on the main control device 70 side is a signal indicating a command reception ready state of the main control device 70. In the present embodiment, the "main command permission signal" is set to the off state on the main control device 70 side while the setting is being changed or the setting is being confirmed, so that the payout control device 92 does not transmit the command.

In the main control device 70, it is possible to make the payout impossible state only by setting the main command permission signal to OFF, and software modification is not required on the payout control device 92 side. Further, the main control device 70 side can be designed without considering the occurrence of command reception during setting change or setting confirmation.

FIG. 13 is a diagram showing a list of gaming machine states.
The gaming machine states include (1) playable state, (2) setting change state, (3) setting confirmation state, (4) setting abnormal state, (5) RAM abnormal state, and (6) checksum abnormal state. There are six states.

These states can be identified by the gaming machine status flag.
The gaming machine status flag is stored in the gaming machine status flag storage buffer of the RAM 76, and the gaming machine status flag storage buffer is a backup target.

Any one of the values "00H" to "05H" is stored in the gaming machine status flag. The states corresponding to each value are as follows.
Game machine status flag = 00H: Gameable status Game machine status flag = 01H: Setting change status Game machine status flag = 02H: Setting confirmation status Game machine status flag = 03H: Setting error status Game machine status flag = 04H: RAM error status Pachinko machine status flag = 05H: Checksum abnormal status

[(1) Playable state]
In the playable state, the game is possible (possible) and the setting cannot be changed (impossible). The playable state corresponds to a state in which normal games can be played. Here, when a normal game is possible, a special symbol lottery, a normal symbol lottery, a big hit game, etc. can be executed, and when a normal game is impossible, a special symbol lottery, a normal symbol lottery, a big hit game, etc. It is in an infeasible state.

[(2) Setting change status]
In the setting change state, the game is impossible and the setting can be changed. The setting change state is a state in which the setting can be changed.

[(3) Setting confirmation status]
In the setting confirmation state, the game is impossible and the setting cannot be changed. The setting confirmation state is a state in which the setting can be confirmed.

[(4) Abnormal setting status]
In the abnormal setting state, the game cannot be played and the setting cannot be changed. The setting abnormal state is a state in which the set value is out of the range (for example, when the set value is neither "0 (setting 1)" to "5 (setting 6)").

[(5) RAM abnormal state]
In the RAM abnormal state, the game is impossible and the setting cannot be changed. The RAM abnormal state is a state in which the RAM is broken.

Whether or not the RAM is in an abnormal state is determined as follows. For each RAM, after writing 00H, it is read as it is, and it is confirmed whether or not 00H is acquired, and after writing FFH, it is read as it is, and it is confirmed whether or not FFH is acquired. That is, 0 and 1 are written to each bit of the RAM to check whether or not there is a problem. Then, when there is a bit fixed to 0 or 1, it is determined that the RAM is abnormal.

The RAM to be checked may be a part of the RAM or the whole RAM. When using a part of the RAM, it can be F000H to F1FFH in the area (512 bytes that can be used according to the rules of the gaming machine) and F300H to F31AH outside the area (only the part actually used).

The determination of whether or not the RAM is in an abnormal state can be executed in the process of the initialization process (step S120 in FIG. 10) at the time of clearing the RAM. When the RAM to be checked is a part of the RAM, the memory area outside the area may be checked first, and then the memory area inside the area may be checked, and the memory area inside the area may be checked first. A memory area check may be performed, and then a memory area check outside the area may be performed. When determining whether or not the RAM is in an abnormal state, the FFH may be written first and then read as it is, and then 00H may be written and then read as it is. In this case, if there is no abnormality in the RAM, all the checked RAM will be 00H, so that it is not necessary to clear the RAM separately, and the control process can be simplified.

[(6) Checksum abnormal state]
In the checksum abnormal state, the game is impossible and the setting cannot be changed. The checksum abnormal state is a state in which the checksums before the power is turned off and when the power is turned on do not match.

FIG. 14 is a diagram showing the distribution of processing when the power is turned on. When checking the settings on a gaming machine that has a setting change function, it is necessary to turn on the power while satisfying special conditions. The following is the distribution of processing when the power is turned on.

When the RAM clear switch is pressed, the inner frame is open, and the setting key is ON when the power is turned on, the main control CPU 72 clears the RAM and then changes the setting (shifts to the setting change state). ..

When the RAM clear switch is pressed and the inner frame is closed or the setting key is OFF when the power is turned on, the main control CPU 72 clears the RAM and then shifts to the game-enabled state.

When the RAM clear switch is not pressed (not pressed) when the power is turned on, the inner frame is open, and the setting key is ON, the main control CPU 72 confirms the setting (shifts to the setting confirmation state). When confirming the setting, the state before the power is turned off may be limited to the case where the game is possible.

When the RAM clear switch is not pressed (not pressed) when the power is turned on, the inner frame is closed, or the setting key is OFF, the main control CPU 72 continues the state before the power is turned off.

15 and 16 are flowcharts showing an example of the second procedure of the CPU initialization process. The difference between the first procedure example of the CPU initialization process and the second procedure example of the CPU initialization process is that steps S131 to S131b in FIG. 11 are changed to steps S181 to S181b in FIG. is there. The off-page combiner has also been changed to B. Therefore, in the following description, steps S181 to S181b of FIG. 16 will be described, and description of other points will be omitted.

Step S1811: The main control CPU 72 executes a process of setting a main command permission signal (communication permission signal) in a specific bit of the output port. As a result, the payout control device 92 is in a state where a command can be transmitted to the main control device 70.

Step S181a: The main control CPU 72 confirms whether or not it is in a game-enabled state. Specifically, it is confirmed whether or not the value of the gaming machine status flag is "00H".

As a result, when it is confirmed that the game is playable (Yes), the main control CPU 72 executes step S132 without executing step S181b. On the other hand, if it cannot be confirmed that the game is playable (No), the main control CPU 72 executes step S181b.

Step S181b: The main control CPU 72 executes a process of setting a payout operation stop command. When the payout control device 92 receives the payout operation stop command, the payout control device 92 is in a state in which the game ball cannot be paid out. In this case, the payout control device 92 may shift to a state in which the command cannot be transmitted to the main control device 70.

The payout operation stop command is transmitted in the timer interrupt processing after shifting to the main loop processing. The timer interrupt processing is executed even during the setting change or the setting change, but the processing route different from the game enable state is executed. This point is the same in the first procedure example of the CPU initialization process. The payout operation start command can be set in the power recovery initialization process (CPU initialization process) or the RAM clear initialization process (CPU initialization process). After completing the above processing, the main control CPU 72 executes step S132.

By executing such a process, the main control CPU 72 pays out the game ball to the payout control device 92 while the setting is being changed or the setting is being confirmed (when the setting-related processing is being executed and the game is not available). By transmitting the prohibition payout operation stop command (prohibition command), it is possible to execute the prohibition process that prevents the payout control device 92 from executing the payout of the game ball (prohibition process execution means).

The payout control device 92 transmits a payout start command (start command) to the main control device 70, and receives a start confirmation command for the payout start command to shift from the non-payable state to the payable state, and the payout possible state. The game ball is paid out based on the payout command transmitted from the main control device 70.

Further, by executing such a process, the main control CPU 72 shifts the payout control device 92 to the payout impossible state by transmitting a payout operation stop command (prohibition command) to the payout control device 92. It is possible to prevent the payout control device 92 from executing the payout of the game ball (prohibition processing execution means).

FIG. 17 is a diagram showing a command transmission timing of a second procedure example of the CPU initialization process. The dotted line in the figure indicates the time when the timer interrupt is possible.

[Main control device] When the power is turned on, the main control device 70 waits for [D01] 3.1 seconds, and [D02] determines the activation method.

Depending on the determination of the activation method, the main control device 70 is activated by [D03] initialization (RAM clear) or by [D04] power recovery (recovery of backup information), and [D05] main command is permitted. Set the signal to ON. After the main command permission signal is set to ON, the command from the payout control device 92 can be received. Further, depending on the determination of the activation method, the main control device 70 may be activated by changing the [D06] setting or by confirming the [D07] setting.

Then, when the processing of [D03] initialization, [D04] power recovery, [D06] setting change, or [D07] setting confirmation is completed, the main control device 70 shifts to the [D08] playable state.

When the timer interrupt process becomes executable, the main control device 70 executes [D09] setting change, [D10] setting confirmation, or [D11] game enable state processing in the timer interrupt process.

[Payout control device] When the power is turned on, the payout control device 92 waits for [E01] 0.1 seconds and executes [E02] power-on processing. In the power-on processing, the payout control device 92 can set the main command permission signal on the payout control device 92 side to ON.

Next, the payout control device 92 sets the [E03] payout command permission signal to ON, and shifts to the [E04] start command transmission waiting state. The start command transmission waiting state is a state in which the main control device 70 is waiting for the main command permission signal to be set to ON, and a command cannot be transmitted to the main control device 70 (). Command transmission impossible state to the main control device 70).

[F01] The main control device 70 confirms the main command permission signal on the payout control device 92 side, and when the main command permission signal on the payout control device 92 side is set to ON, the payout control device 92 is referred to. And send a start command.

Then, when the main command permission signal is set to ON in the main control device 70 ([D05]), the payout control device 92 is in a state where a command can be transmitted to the main control device 70 (main control). The command can be transmitted to the device 70), [F02] The payout control device 92 transmits a payout start command to the main control device 70. The order of sending the start command of [F01] and sending the payout start command of [F02] may change.

The main control device 70 that has received the payout start command transmits a [F03] start confirmation command to the payout control device 92 as a command in response to the command. As a result, the payout control device 92 is in a state where the game ball can be paid out.

[F04] When the main control device 70 is activated by changing the setting or confirming the setting ([D06] or [D07]), the main control device 70 transmits a payout operation stop command to the payout control device 92. As a result, the payout control device 92 becomes unable to pay out the game ball.

[F05] When the process related to the setting change or the setting confirmation is completed, the main control device 70 transmits a payout operation start command to the payout control device 92. As a result, the payout control device 92 is in a state where the game ball can be paid out. Then, the payout control device 92 shifts to the [E05] playable state.

When the payout control device 92 becomes in a state where the timer interrupt process can be executed, the payout control device 92 executes the process related to [E06] waiting for payout permission or [E07] playable state in the timer interrupt process.

[G01] In the payout control device 92, the payout operation is disabled for 5 seconds after receiving the activation confirmation command. Therefore, by receiving the payout operation stop command during that time, the payout of the payout control device 92 is prohibited. That is, the payout is permitted for a moment, but since there is a weight of 5 seconds, the game ball is not paid out during this period. Then, since the payout operation stop command is transmitted before the 5-second weight is completed, the game ball is not paid out. Then, in this state, the setting change or the setting confirmation is executed. For the payout operation start command, a weight of 2 seconds is set after reception.

In this way, the payout control device 92 shifts from the non-payable state to the payable state after a certain period of time has elapsed (after 5 seconds have passed and after the time of G01 has elapsed) after receiving the activation confirmation command. Then, the main control device 70 transmits a payout operation stop command (prohibition command) before a certain time elapses (before the elapse of 5 seconds, before the elapse of the G01 time) after the start confirmation command is transmitted, and the payout control device 92 Restricts the transition from the non-payable state to the payable state (prohibited processing execution means).

Since the game can be stopped while the setting is being changed or the setting is being confirmed, it is desired to prohibit the payout operation of the payout control device 92.

In order to prohibit the payout operation of the payout control device 92 while the setting is being changed or the setting is being confirmed, the following method is adopted in the second procedure example of the CPU initialization process. The commands transmitted from the payout control device 92 to the main control device 70 are classified as follows.

(1) Payout start command (confirmation of payout operation permission) (2) Error-related command (notify the error related to payout with the effect control device)

The operation of the main control device 70 at the time of receiving each command is as follows. (3) After receiving the command of (1) above, the main control device 70 returns a command (start confirmation command) for permitting the payout operation to the payout control device 92. (4) After receiving the command of (1) above, an error command is transmitted to the effect control device 124.

Here, there is no problem even if the above (4) is executed, but in the above (3), there is a possibility that the payout operation is performed while the setting is being changed or the setting is being confirmed. Therefore, after the activation confirmation command of (3) above is transmitted and before the game ball is actually paid out, a "setting change / confirmation start command" is transmitted to the payout control device 92, and the payout control device 92 sends the game ball. Adopt a method to prevent payout.

The operation on the payout control device 92 side after receiving the setting change / confirmation start command is as follows. The payout control device 92 that has received the setting change / confirmation start command is put into the payout stop state. The cancellation of the payout suspension state is triggered by the setting change / confirmation end command.

Here, the "setting change / confirmation start command" and the "setting change / confirmation end command" may be prepared as new commands, but the "payout operation start command" and "payout operation stop command" may also be used. it can. In this case, "setting change / confirmation start command" = "payout operation stop command", and "setting change / confirmation end command" = "payout operation start command".

As a result, unintended payout can be prevented while the setting is being changed or the setting is confirmed, and by using the "payout operation start command" or the "payout operation stop command", it is not necessary to modify the software of the payout control device 92. ..

FIG. 18 is a flowchart showing a procedure example of the main loop processing. Each procedure will be described below. In the main loop processing, while updating random numbers (stirring random numbers, etc.), the following three types of interrupts are waited for. (1) Serial communication reception interrupt (when receiving a command from the payout control device) (2) Timer interrupt (when the timer time is up once every 4 ms) (3) Interrupt when power is cut off (when the input voltage drops due to power off) Then, most of the processing related to the game is executed by the timer interrupt processing.

Step S1411: The main control CPU 72 executes interrupt prohibition processing.
Step S142: The main control CPU 72 executes the initial value random number update process. In this process, the main control CPU 72 increments random numbers for updating (changing) the initial values of various software random numbers. In the present embodiment, various random numbers (for example, a jackpot symbol random number for determining the winning type, reach determination) other than a jackpot determination random number (hardware random number) and a hit determination random number (hardware random number) corresponding to a normal symbol are used. Random numbers, fluctuation pattern determination random numbers, etc.) are generated on the program. These software random numbers are updated by the loop counter within a predetermined range in another timer interrupt process (step S205 in FIG. 24), and the initial values of the loop counter (all) are updated every time the random number value makes a round in this process. Random numbers do not have to be the target).

The initial value update random number is used to randomly change the initial value, and in step S142, the initial value update random number is updated. In this process, the initial value of the jackpot symbol random number is updated. The reason why step S142 is executed after disabling interrupts in step S141 is that the same processing is executed in another timer interrupt process (step S205 in FIG. 24), so that duplication (conflict) with this is prevented. Because. The jackpot-determined random number and the hit-determined random number are hardware random numbers generated by the random number circuit 75, and their update cycle is even faster (for example, several μs) than the timer interrupt cycle (for example, several ms), so that the jackpot is determined. It is not necessary to update the initial values of the determined random number and the winning determined random number.

Step S143: The main control CPU 72 executes the main command analysis process. In this process, when there is a command from the payout control device 92 saved by the serial communication reception interrupt, the data received from the payout control device 92 is analyzed, and the process is performed according to the result. Specifically, the main control CPU 72 outputs the payout start confirmation specification command to the payout command buffer when the received main command is the payout start designation command, while the received main command is not the payout start designation command. After checking whether the value is within the specified range (whether it is an appropriate value as the main command), if it is out of the range, the payout error specification command is output to the subcommand transmission buffer, and the payout radio wave is further determined according to the situation. Set the error flag.

Step S144: The main control CPU 72 executes the subcommand transmission process. In this process, when an untransmitted subcommand (effect command) remains in the subcommand transmission buffer, the main control CPU 72 sends the effect control device 124 to the subcommand stored in the subcommand transmission buffer. To send.

Step S145: The main control CPU 72 executes the performance display monitor aggregation / division process. This process is a process outside the region. In this process, the main control CPU 72 executes a process of calculating the base to be displayed on the performance display monitor 200. In this process, the main control CPU 72 uses the division task to determine the number of prize balls to be paid out when the game balls enter each winning opening (starting winning opening, normal winning opening, large winning opening). The base is calculated by dividing by the number of outs (the number of game balls detected by the out switch) indicating the number of game balls fired in the area (base calculation means, base-related processing execution means). The performance display monitor aggregation division process is a base-related process.

The base-related process is a process related to control of the base, and includes at least one of a base calculation process executed when calculating the base and a base display process executed when displaying the base on the performance display monitor 200.

Here, it is not necessary to clearly distinguish between the base calculation process and the base display process, the process focusing on the base calculation is the base calculation process, and the process focusing on the base display is the base display. It is a process. Therefore, a part of the base calculation process may be regarded as a part of the base display process, and a part of the base display process may be regarded as a part of the base calculation process. The details of the performance display monitor aggregation division processing will be described later.

Step S146, Step S147: The main control CPU 72 permits interrupts and executes other random number update processing. The random numbers updated by this process are random numbers (reach determination random numbers, fluctuation pattern determination random numbers, etc.) that are not related to the determination of the winning type (winning type) among the software random numbers.

Then, these series of processes are performed in the remaining time when an interrupt request is generated during the execution of the main loop process and the main control CPU 72 executes various interrupt processes.

FIG. 19 is a diagram showing the contents of processing executed when a serial communication reception interrupt occurs.
When a serial communication reception interrupt occurs, the main control CPU 72 executes serial communication reception interrupt processing (step S136). The serial communication reception interrupt is generated when a command is received from the payout control device 92.

FIG. 20 is a diagram showing the contents of processing executed when a timer interrupt occurs.
When a timer interrupt occurs, the main control CPU 72 executes timer interrupt processing (step S137). The timer interrupt occurs when the timer time is up once in the timer interrupt cycle (for example, 4 ms).

FIG. 21 is a diagram showing the contents of processing executed when an interrupt occurs at the time of power failure notification.
When an interrupt at the time of power off warning occurs, the main control CPU 72 executes interrupt processing at the time of power off notification (step S138). The interrupt when the power is turned off is generated when the input voltage drops due to the power cut.

The interrupt priority is "high" for "serial communication reception interrupt", "medium" for "timer interrupt", and "low" for "interrupt at power failure notice".
Therefore, if a "serial communication receive interrupt" occurs while a "timer interrupt" is generated and the "timer interrupt processing" is being executed, the "serial communication reception interrupt processing" is performed unless the interrupt is disabled. To execute.
On the other hand, even if a "timer interrupt" occurs and "timer interrupt processing" is being executed, even if a "power interruption warning" occurs, "power interruption warning processing" is executed at that time. Instead, the "interrupt processing at the time of power failure notification" is executed after the "timer interrupt processing" is completed.

When various interrupt processing such as serial communication reception interrupt processing (main command reception interrupt processing) and timer interrupt processing is completed, the system returns to the interrupt source (program address indicated by the stack pointer).
Since the interrupt processing at the time of power cut notification is a special process, it does not return to the interrupt source in principle. Normally, after performing evacuation processing (calculation of checksum, RWM (RAM) access protection, etc.), a reset occurrence due to a voltage drop is waited on the spot. If the power supply is restored in the middle, the process returns to the beginning of the program (for example, CPU initialization processing). Note that the interrupt source may be returned at the beginning of the process, but this is an exceptional process.

[Serial communication reception interrupt processing]
FIG. 22 is a flowchart showing a procedure example of serial communication reception interrupt processing.
The serial communication reception interrupt process is executed when a command is received from the payout control device 92. The payout control device 92 transmits a command for specifying payout activation indicating that it has been activated to the main control device 70, and also various devices related to payout of prize balls as the game progresses (for example, the payout device board 100 and the like. A command (error command, etc.) transmitted from the full tank switch 161 or the like to the main control device 70 is relay-transmitted. These commands transmitted by the payout control device 92 are received by the receive data register of the specific channel of the serial communication circuit 196 of the main control device 70. The main control CPU 72 executes serial communication reception interrupt processing (SCU interrupt processing) triggered by this command reception (SCU interrupt). Hereinafter, each procedure of serial communication reception interrupt processing will be described later.

Step S180: First, the main control CPU 72 saves the values of the A register (accumulator) and the F register (flag register) used during the execution of the main loop process in the save area of the RAM 76. Another value can be written to each register after the value is saved while the data reception interrupt processing is being executed.

Step S182: The main control CPU 72 confirms whether or not there is a reception error. Specifically, the main control CPU 72 checks a specific bit of the status register to confirm whether or not there is data in the reception data register (reception FIFO), and if there is data, whether or not the data is normal. Check if. Then, when there is no data, or when there is data but the data is not normal, the main control CPU 72 determines that a reception error has occurred.

If it is determined that a reception error has occurred (Yes), the main control CPU 72 does not execute step S184. On the other hand, if it is determined that there is no reception error (No), the main control CPU 72 executes step S184.

Step S184: The main control CPU 72 executes a process of storing a receive command (main command) in a buffer (receive command buffer). The saved main command is analyzed by the main command analysis process of the main loop process.

This process is a process of rewriting the buffer of the used area of the RAM 76. Therefore, if a serial communication receive interrupt occurs while processing related to the outside of the area is being executed, the buffer of the used area will be rewritten even though the processing related to the outside of the area is being executed. There is a possibility of violating the game machine rules.

Therefore, in the present embodiment, when the serial communication reception interrupt processing is executed, the serial communication reception interrupt processing is executed after the interrupt is disabled (after the serial communication reception interrupt is prohibited).

Steps S186 and S188: The main control CPU 72 restores the values of the A and F registers saved in step S180 to each register, permits interrupts, and then ends serial communication reception interrupt processing to perform main loop processing (FIG. 18). ) Returns to the interrupt source.

[Interrupt processing when power is cut off]
FIG. 23 is a flowchart showing an example of a procedure for interrupt processing at the time of power failure notification.
The interrupt process at the time of power cutoff is executed when the power supply is cut off (hereinafter, abbreviated as "power cutoff").
In the main controller 70, the occurrence of power failure and the occurrence of reset are monitored by the same monitoring IC (for example, an IC mounted on a reset controller (not shown)). This monitoring IC monitors the drive voltage supplied from the power supply control unit 162, and outputs a power supply cutoff warning signal to the XINT terminal of the parallel I / O port 79 when the voltage level falls below the reference voltage. The main control CPU 72 executes interrupt processing (XINT interrupt processing) at the time of power cutoff warning, triggered by input of a power cutoff warning signal to the XINT terminal (XINT interrupt).

Steps S151 and S152: The main control CPU 72 reads the power cutoff detection switch input port of the parallel I / O port 79, checks a specific bit, and confirms whether or not a power cutoff warning signal has been detected. If it cannot be confirmed that the power cutoff warning signal has been detected (No), the main control CPU 72 ends the interrupt processing at the time of power cutoff warning and returns to the interrupt source of the main loop processing (FIG. 18). On the other hand, when it is confirmed that the power cutoff warning signal has been detected (Yes), the main control CPU 72 executes the next step S153.

Step S153: The main control CPU 72 executes a process of clearing all output ports. Specifically, the main control CPU 72 corresponds to a test signal terminal and a command control signal in addition to the output ports corresponding to the ordinary electric accessory solenoid 88, the first special winning opening solenoid 90, and the second special winning opening solenoid 97. Clear the output port buffer.

The process of step S153 is a process executed when it is determined to be affirmative (Yes) in step S152 or when the setting change is completed (by executing step S330 of FIG. 29).

Step S154: The main control CPU 72 executes a process of calculating and saving the checksum. Specifically, the main control CPU 72 adds the entire contents of the backup target area of the RAM 76 excluding the backup flag and the checksum buffer in 1-byte units, and repeats the addition for the entire area until the addition is completed. Then, when the calculation of the sum for the entire area is completed, the main control CPU 72 saves the sum result value in the checksum buffer.

Step S155: The main control CPU 72 stores a valid value (for example, “01”) in the backup flag area.

Step S156: The main control CPU 72 executes a RAM (RWM) access prohibition process. Specifically, the main control CPU 72 stores "00H" indicating access prohibition in the protect value of the RAM 76, and prohibits access to the work area (including the used area and the outside of the area) of the RAM 76.

Step S157: The main control CPU 72 confirms whether or not the power cutoff warning signal has been detected. The method of confirming the power off warning signal is the same as the method in step S152 described above.
When it is confirmed that the power cutoff warning signal has been detected (Yes), the main control CPU 72 executes step S157 again. On the other hand, when it cannot be confirmed that the power cutoff warning signal has been detected (No), the main control CPU 72 executes the next step S158.

Step S158: The main control CPU 72 confirms whether or not a predetermined time (for example, 10 ms) has elapsed in a state (off state) in which the power off warning signal is not detected. When it is confirmed that the predetermined time has elapsed without detecting the power off warning signal (Yes), the main control CPU 72 returns to the beginning of the program. Since a program related to the CPU initialization process is arranged at the beginning of the program, returning to the beginning of the program means executing the CPU initialization process. On the other hand, when it cannot be confirmed that the predetermined time has elapsed without detecting the power off warning signal (No), the main control CPU 72 returns to step S157 and repeatedly executes the previous processes. By executing such a process, when the power supply is restored (the power cutoff warning signal is turned off for 10 ms continuously), it is possible to return to the beginning of the program for interrupt processing at the time of power cutoff notice.

Further, the processes of steps S157 and S158 are standby processes executed in preparation for shutting off the power supply from the power supply control unit 162. If the power off warning signal is continuously detected, step S157 and step S158 are repeatedly executed, so that the standby state is continued as long as the power supply is continued. In this way, the main control CPU 72 first calculates the checksum and saves the result before the power supply is completely cut off, and enters the standby state, and in a situation where the power supply is being cut off, other The standby state is maintained without executing any processing, and the upcoming power supply is cut off in a safe state (waiting for reset due to voltage drop).

When the power supply from the power supply control unit 162 is cut off, the power supply source to the main control device 70 is automatically switched to the backup power supply. Since the main control device 70 is supplied with backup power from a backup power supply circuit (for example, a circuit including a capacitive element mounted on the main control device 70) (for example, a circuit including a capacitive element mounted on the main control device 70) after a power failure occurs, the main control device 70 is a backup target of the RAM 76. The contents of the memory are retained without being lost even after the power is turned off. The backup power supply circuit may be built in the power supply control unit 162.

Through the above processing, all the information stored in the work area of the RAM 76, which is the backup target (sum addition target), is stored in the RAM 76 even after the power is turned off. Further, the retained memory is restored as backup information when a power failure occurs after confirming the normality of the checksum in the previous CPU initialization process.

[Timer interrupt processing]
FIG. 24 is a flowchart showing a procedure example of timer interrupt processing.
The main control CPU 72 executes timer interrupt processing (PTC interrupt processing) at predetermined time (for example, several ms) based on the interrupt request (PTC interrupt) output by the timer circuit 194. Hereinafter, each procedure of timer interrupt processing will be described later.

Step S200: First, the main control CPU 72 sets the values of the AF register (accumulator / flag register pair), BC, DE, and HL register (general purpose register pair) used during the execution of the main loop processing into the save area of the RAM 76. Evacuate to. Another value can be written to each register after the value is saved while the timer interrupt processing is being executed.

Step S201: The main control CPU 72 executes the interrupt flag initialization process. In this process, a process of clearing the timer interrupt flag (= 0) is executed. The reason for clearing the timer interrupt flag is that the timer interrupt occurs in a predetermined timer interrupt cycle (for example, 4 ms), but the timer interrupt flag is set (= 1) in the predetermined timer interrupt cycle. When the timer interrupt flag is set, the timer interrupt is not allowed to occur.

Step S201a: The main control CPU 72 executes interrupt enable processing. By allowing interrupts here, it is possible to generate other interrupts while executing the next and subsequent steps of timer interrupt processing.

Step S202: The main control CPU 72 executes the dynamic port output process. In this process, in order to control the lighting of each lamp mounted on the integrated display board 89 and the performance display monitor 200 by the dynamic lighting method, port output is performed in common units. Specifically, after clearing the output port, the main control CPU 72 outputs the generated common output data to the port output buffer for the common corresponding to the selected common. The output content is the content set in the previous timer interrupt.

Here, the data output to the port output buffer for each common is sequentially port-output by one common in this dynamic port output processing each time the timer interrupt processing occurs. For example, in the timer interrupt processing executed next time, the data stored for common 1 is output to the port, and in the timer interrupt processing executed one after another, the data stored for common 2 is output to the port. The data stored in the port output buffer for each common is processed one by one in order. As a result, each lamp constituting a predetermined display mode (a mode in which a symbol variation display, a stop display, an operation memory number display, a game status display, etc.) and a performance display monitor are sequentially driven in a common unit, and a dynamic lighting method is used. The lighting is controlled by.

Step S203: The main control CPU 72 executes the port input process. In this process, in order to accurately acquire the latest switch state based on the input port information, the main control CPU 72 logically sets the input value of various switch signals from the parallel I / O port 79 and the inversion result value of the previous input value. Store the product in the input port-on detection flag. As a result, it is possible to grasp the accurate input state based on the change from the previous time of various switch signals by the value (ON / OFF) of the input port on detection flag. Various switch signals include a passage detection signal from the gate switch 78, a middle start winning opening switch 80, a right starting winning opening switch 82, a first count switch 84, a second count switch 85, a first winning opening switch 86, and a first. 2. The winning detection signal from the winning port switch 81, the detection signal from the fraud detection switch (magnetic detection switch, radio wave detection switch, vibration detection switch, etc.) (not shown) and the like are included.

Step S203a: The main control CPU 72 confirms whether or not the gaming machine status flag is “00H (gamable state)”.

As a result, when it is confirmed that the gaming machine status flag is "00H (gamable state)" (Yes), the main control CPU 72 executes step S204. On the other hand, when it cannot be confirmed that the gaming machine status flag is "00H (gamable state)" (No), the main control CPU 72 executes step S203b.

The reason for executing such a determination process is to prevent the process related to the normal game from being executed when the setting is being changed or the setting is being confirmed. Then, the load on the program of the main control device 70 can be reduced by not executing the process related to the normal game in the timer interrupt process during the setting change or the setting confirmation.

Step S203b: The main control CPU 72 confirms whether or not the gaming machine status flag is "03H or higher (fatal error status)".

As a result, when it is confirmed that the gaming machine state flag is "03H or higher (fatal error state)" (Yes), the main control CPU 72 executes step S217a without executing step S203c. On the other hand, when it cannot be confirmed that the gaming machine status flag is "03H or higher (fatal error status)" (No), the main control CPU 72 executes step S203c.

The reason why such a judgment process is executed is that when a fatal error state occurs, it is not transferred during setting change or setting confirmation.

Step S203c: The main control CPU 72 executes a setting change process (setting-related process). By executing this process, the main control CPU 72 includes a setting-related process including at least one of a setting change process executed when changing the setting value or a setting confirmation process executed when confirming the setting value. Can be executed (setting-related processing execution means). The details of the process will be described later. The setting-related processing includes processing executed during setting change or setting confirmation. Then, when the setting change process is completed, the main control CPU 72 executes step S217a. The reason for shifting to step S217a is to output an external signal (security signal) in the external information management process.

By executing such a process, the main control CPU 72 may restrict the execution of at least a part of the other process during the execution of one of the setting-related process and the base-related process. Yes (restriction means). That is, when the setting is being changed or the setting is being confirmed (step S203; Yes), the main control CPU 72 does not execute at least a part of the base-related processing (step S204 to step S217, particularly step S208). can do.

Step S204: The main control CPU 72 executes the timer update process (special information continuous transmission process execution means). In this process, the main control CPU 72 includes various timers used for the game (timers that manage the fluctuation time / stop time of the symbol, the opening time / closing time of the electric accessory, etc.), various timers for external information, and security signals. Execute a process (subtraction process, etc.) to update the counter such as the output timer.

Step S205: The main control CPU 72 executes the initial value random number update process. The content of the process is the same as the initial value random number update process (step S142 in FIG. 18) of the main loop process.

Step S206: The main control CPU 72 executes the hit symbol random number update process. In this process, the main control CPU 72 updates the value of the counter for generating various random numbers for lottery of special symbols and ordinary symbols. The value of each counter is incremented in the counter area of the RAM 76, and each loops within a specified range. The various random numbers include, for example, a jackpot symbol random number and the like.

Step S207: The main control CPU 72 executes the switch management process. In this process, among the switch signals input in the previous port input process (step S203), the gate switch 78, the middle start winning opening switch 80, the right starting winning opening switch 82, the first count switch 84, and the second count switch 85. , The event that occurred during the game is determined based on the winning detection signals from the first winning opening switch 86 and the second winning opening switch 81, and the processing corresponding to each occurrence event is executed. The details of the process will be described later.

In the present embodiment, when a winning detection signal (ON) is input from the middle start winning opening switch 80 or the right starting winning opening switch 82, the main control CPU 72 performs an internal lottery corresponding to the first special symbol or the second special symbol, respectively. It is determined that an event that triggers (lottery trigger) has occurred. Further, when the passage detection signal (ON) is input from the gate switch 78, the main control CPU 72 determines that an event that triggers a lottery corresponding to the normal symbol has occurred.

Step S208: The main control CPU 72 executes the addition number calculation process (base-related process execution means). The addition number calculation process is a base-related process. This process is a process of the used area. In this process, the main control CPU 72 determines the game state and each switch (out switch 99, middle start winning opening switch 80, right starting winning opening switch 82, first winning opening switch 86, second winning opening switch 81, first Check the status of the count switch 84, the second count switch 85, etc.), and for the base calculation, "value to be added to the RAM outside the area (the number of prize balls generated during 4 ms, the number of outs, etc.)" Is calculated. Specifically, the main control CPU 72 executes a process of determining the values of the number of launched balls A (normal out addition number), the launch ball number B (total out addition number), and the acquired ball number (normal prize ball addition number). To do. The details of the process will be described later.

Step S209, Step S210: The main control CPU 72 executes the special game management process and the normal game management process. These processes are for specifically advancing the game in the pachinko machine 1.

In the special game management process (step S209), the main control CPU 72 controls the execution of the internal lottery corresponding to the first special symbol or the second special symbol, or the first special symbol display device 34 and the second special symbol display device. The fluctuation display and the stop display by 35 are determined, and the operation of the first variable winning device 30 and the second variable winning device 31 is controlled according to the display result. The details of the process will be described later.

Further, in the normal game management process (step S210), the main control CPU 72 determines the variation display and the stop display by the normal symbol display device 33, and controls the operation of the variable start winning device 28 according to the display result. To do. For example, the main control CPU 72 stores a random number (normal symbol hit determination random number) acquired in the previous switch management process (step S207) triggered by the passage of the start gate 20, and in this normal game management process. A random number value is read from the memory, and it is determined whether or not the value falls within a predetermined hit range. When the random number value falls within the hit range, the normal symbol display device 33 fluctuates the normal symbol to display the stop display of the normal symbol in a predetermined hit mode, and then the main control CPU 72 presses the normal electric accessory solenoid 88. The variable start winning device 28 is activated by excitation. On the other hand, if the random number value is out of the hit range, the main control CPU 72 performs a stop display of the normal symbol in a disengaged manner after the fluctuation display.

Step S211: The main control CPU 72 executes the state management process. In this process, the main control CPU 72 is collected to an abnormal winning frequency (a state in which the number of balls entered into the middle starting winning opening 26 and the normal winning openings 22 and 24 is abnormally large) and a base abnormality (to the back side of the game board unit 8). An error condition such as the number of game balls, that is, the total number of prize balls in each of the winning openings 22, 24, 26, 28a, 30b, and 31b is larger than the number of game balls driven into the game area 8a). Check if it has occurred. When an error state is detected, the main control CPU 72 has caused an abnormality by outputting a security signal to the hall computer of the amusement park and by transmitting a predetermined error command to the effect control device 124. Notify. In this process, the main control CPU 72 may execute error processing related to door opening and fraud detection (magnet, radio wave, vibration, etc.).

Step S212: The main control CPU 72 executes the winning opening switch process. In this process, when each input port on detection flag stored based on the winning detection signals input from the various switches 80, 81, 82, 84, 85, 86 in the previous port input process (step S203) is ON, The prize ball control counters for each target are added by 1 and updated.

Step S213: The main control CPU 72 executes the payout control management process. In this process, the main control CPU 72 first checks whether the payout command buffer is not empty (whether the payout command to be transmitted is set), and if it is not empty (the payout command is set), the payout command is set. Various payout commands output to the buffer are transmitted to the payout control device 92. For example, a payout command indicating a start mode at power-on is set in the process of CPU initialization processing, output to a payout command buffer, and a payout command indicating this start mode is transmitted in this process. On the other hand, if the payout command buffer is empty, the process proceeds to the process for instructing the payout of the prize ball. The main control CPU 72 confirms whether or not the prize ball control counter is 0, and if the prize ball control counter is not 0, the payout control device 92 issues a prize ball designation payout command indicating the number of prize balls corresponding to this counter. Send to. More specifically, a prize ball designation payout command corresponding to each prize ball control counter is transmitted in this process. To transmit the payout command, the payout command permission signal is input from the payout control device 92 to the main control device 70, and the number of payout commands set in the transmission data register (transmission FIFA) is a predetermined number. If less than (more specifically, if the payout command set in the transmit FIFA has been transmitted, or is currently being transmitted and there is space in the transmit FIFA), it is executed.

Further, especially when the power is turned on, when the payout command set in the process of CPU initialization processing is normally transmitted, the main control CPU 72 turns on the launch permission signal with this as an opportunity. Specifically, the main control CPU 72 clears the payout command buffer output when the power is turned on, and turns on the emission permission signal by setting a specific bit of the output port. As a result, the launch of the game ball is permitted after confirming the normal operation after the power is turned on, and the launch permission signal is sent to the launch control board 108 via the payout control device 92, so that the game ball can be launched. It becomes a state.

Further, the main control CPU 72 outputs a prize ball content command for transmitting the content of the number of prize balls to the effect control device 124 in the payout control management process. When a winning detection signal is input from the first count switch 84 or the second count switch 85 corresponding to the first variable winning device 30 or the second variable winning device 31, the first profit (for example, 15 game balls) is obtained. Generate the corresponding prize ball content command. Note that generating a command means storing the command in a buffer for sending a subcommand (hereinafter, the same applies). Further, when the winning detection signal is input from the second winning opening switch 81 corresponding to the normal winning opening 24, the prize ball content command corresponding to the second profit (for example, 10 game balls) is generated. The prize ball content command is transmitted to the effect control device 124 in the subcommand transmission process (step S144 in FIG. 18) of the main loop process.

[About the number of prize balls and the number of game balls won]
The number of prize balls at the start port of the first special symbol and the number of prize balls at the start port of the second special symbol are set to a specified number of one or more, respectively. Further, the number of prize balls may be different between the starting port of the first special symbol and the starting port of the second special symbol. Furthermore, the minimum number of prize balls is set based on the winning probability of the special symbol and the expected value of the total number of game balls acquired (the average number of balls to be obtained in a series of periods from the first hit to the end of the time reduction state). You may. Furthermore, the winning probability of the special symbol, the expected value of the total number of game balls won, the number of opening of the big winning opening, the opening time of the big winning opening, the maximum number of winning of the big winning opening, the number of winning balls of the big winning opening are predetermined. If the conditions are met, a jackpot may be set in which the number of game balls acquired by one jackpot is less than 1/4 of the maximum number of acquired game balls.

Step S215: The main control CPU 72 executes the test signal management process. This process can be a process outside the region. In this process, the main control CPU 72 has its own internal state (for example, normal symbol game management state, special symbol game management state, launch position designation state, big hit, small hit, probability fluctuation function operating, time shortening function operating, etc. ) Is generated and stored in the port output request buffer. With this test signal, for example, the internal state of the main control CPU 72 can be tested outside the main control device 70.

Step S216: The main control CPU 72 executes the LED display setting process. In this process, the main control CPU 72 includes a normal symbol display device 33, a normal symbol operation storage lamp 33a, a first special symbol display device 34, a second special symbol display device 35, a first special symbol operation storage lamp 34a, and a second special. A process of generating common output data for controlling the lighting of the LEDs included in the symbol operation storage lamp 35a, the game status display device 38, and the like is executed. The process related to the performance display monitor 200 is executed in the performance display monitor control process.

More specifically, the main control CPU 72 is based on a symbol variation display, a stop display, an operation memory number display, a game state display, and the like determined in the special game management process (step S209) and the normal game management process (step S210). Therefore, a drive signal for lighting each lamp in the corresponding manner is generated as common output data.

Step S217: The main control CPU 72 executes the solenoid data setting process. In this process, the main control CPU 72 has the ordinary electric accessory solenoid 88, the first grand prize opening solenoid 90, and the second grand prize generated in the special game management process (step S209), the normal game management process (step S210), and the like. Each drive signal, test signal, etc. of the port solenoid 97 are combined (combined) and stored in the port output buffer. After that, the main control CPU 72 executes the solenoid data port output process. In this process, the main control CPU 72 confirms whether the value is stored in each output buffer (port output buffer), and if the value is stored, outputs the port. For example, each drive signal of each solenoid 88, 90, 97 stored in the port output buffer is output to the port. In this case, each drive signal is transmitted to the corresponding solenoids 88, 90, 97, and each solenoid executes an operation according to the drive signal.

Step S217a: Next, the main control CPU 72 executes the external information management process. In this process, the main control CPU 72 sends an external information signal (for example, prize ball information, door opening information, symbol confirmation count information, jackpot information, starting port information, security signal, etc.) to the hall computer of the amusement park through the external terminal plate 160. Is stored in the port output request buffer.
In the external information management process, an external signal (security signal) is output when the setting is being changed or the setting is being confirmed.

More specifically, the main control CPU 72 is used as a hall computer (external device) in a setting change state (setting change), a setting confirmation state (setting confirmation), a setting abnormality state, a RAM abnormality state, a checksum abnormality state, and the like. A security signal transmission process (special information transmission process) for transmitting a security signal (special information) is executed (special information transmission process execution means). The security signal can be transmitted to the hall computer by storing the data corresponding to the security signal in the port output request buffer.

Here, the security signal is a signal that is output when some kind of abnormal state occurs, or when the state shifts to the setting change state or the setting confirmation state.

The main control CPU 72 determines whether or not to transmit the security signal by referring to the value stored in the gaming machine status flag (game machine status information) (special information transmission processing execution means). For example, when the game machine status flag stores a value (00H) corresponding to the game-enabled state, it is determined that the security signal is not transmitted, and a value (01H ~) other than the value (00H) corresponding to the game-enabled state is determined. If 05H) is stored, it is determined that a security signal is transmitted.

In the present embodiment, among various external information signals, for example, by outputting "big hit 1" to "big hit 5" as big hit information to the outside, an external electronic device (data display) connected to the pachinko machine 1 It is possible to provide various jackpot information to a vessel or a hall computer (external information signal output means). That is, by outputting the jackpot information by dividing it into a plurality of "big hit 1" to "big hit 5", the jackpot type (winning type) can be aggregated and managed by a hall computer (not shown) from these combinations, or internally. Occurrence of small hits (hits where the condition device does not operate) that are not classified as "big hits" even if they recognize changes in the probability state (low probability state or high probability state) and the shortened state of the symbol fluctuation time Can be aggregated and managed. In addition, based on the jackpot information, for example, a data display device (not shown) counts and displays the number of jackpot occurrences within the past several business days for each pachinko machine 1, and recognizes whether or not each machine is currently hit. Or, it is possible to recognize whether or not the symbol fluctuation time is currently shortened for each machine. In this external information management process, the main control CPU 72 controls in detail each output state (ON or OFF set) of "big hit 1" to "big hit 5".

Step S218: The main control CPU 72 executes interrupt prohibition processing.

Step S218a: The main control CPU 72 executes the register save process.

Step S219: The main control CPU 72 executes the performance display monitor control process (base-related process execution means). The performance display monitor control process is a base-related process. This process is a process outside the area. In this process, the main control CPU 72 executes a process such as switching the display contents of the performance display monitor 200, or a base value calculated in the performance display monitor aggregation division process (step S145 in FIG. 18) of the main loop process. Is generated as common output data for displaying the drive signal on the performance display monitor 200. The details of the processing will be described later.

Step S219a: The main control CPU 72 executes the register return process. As a result, the value of the register saved in the process of step S218a is restored.

Step S220: The main control CPU 72 executes interrupt enable processing. By allowing interrupts here, it is possible to generate other interrupts while executing the next and subsequent steps of timer interrupt processing. As described above, multiple interrupts are permitted for timer interrupt processing.
The interrupt controller 192 executes the reception of interrupt request signals, priority control of multiple interrupts, and the like.

Step S221: The main control CPU 72 executes the firing position management process. In this process, the main control CPU 72 executes a process of determining the launch position of the game ball according to the progress of the game (launch position determining means). Note that this process may be executed in the special game management process. The details of the processing will be described later.

Step S222: The main control CPU 72 returns the values of the HL, DE, BC, and AF registers saved in step S200 to each register, ends the timer interrupt processing, and returns to the main loop processing of the CPU initialization processing.

[Interrupt management by interrupt controller]
In the main control device 70, during execution of the CPU initialization process, which is the main control program, an XINT interrupt (an interrupt request output by the parallel I / O port 79 that is the source of the interrupt process at the time of power failure notification) and an SCU interrupt. (Interrupt request output by the serial communication circuit 196 which is the source of serial communication reception interrupt processing) and PTC interrupt (interrupt request output by the timer circuit 194 which is the source of timer interrupt processing) may occur. These interrupt requests are managed and controlled by the interrupt controller 192 mounted on the main controller 70. The interrupt controller 192 performs control (so-called masqueradable interrupt control) in which the interrupt permission instruction (EI instruction) of the main control CPU 72 permits the reception of the interrupt request, and the interrupt prohibition instruction (DI instruction) prohibits the reception of the interrupt request. ing.

Since the XINT interrupt, the SCU interrupt, and the PTC interrupt are all generated based on independent generation factors having no interdependence, it is naturally conceivable that a plurality of interrupt requests occur at the same time. Therefore, the interrupt controller 192 controls each interrupt request according to a predetermined priority of the interrupt request in consideration of the importance of interrupt processing, processing efficiency, and the like.

More specifically, the priority of interrupt request (interrupt processing) is defined in the interrupt vector table, the priority of XINT interrupt (interrupt processing at the time of power failure notification) is the lowest, and that of PTC interrupt (timer interrupt processing). The priority is the next highest, and the priority of the SCU interrupt (serial communication reception interrupt processing) is set to the highest (see FIGS. 19 to 21).

By setting the interrupt vector table at the beginning of the CPU initialization process, the interrupt controller 192 can perform priority control of interrupt requests generated at subsequent timings. Actually, if any interrupt request occurs between the time when the interrupt is enabled and the time when the interrupt is disabled after the CPU initialization process transitions to the main loop process, the interrupt controller 192 receives the interrupt request. Control is performed based on the priority set in the interrupt vector table. For example, when the XINT interrupt and the PTC interrupt are received at the same time, the PTC interrupt (timer interrupt processing) having a higher priority is processed first. While the timer interrupt processing is being executed, the XINT interrupt is in an interrupt waiting state, and after the timer interrupt processing is completed, the XINT interrupt (interrupt processing at the time of power failure warning) is executed.

By controlling the interrupt request based on the priority in this way, the interrupt controller 192 enables execution of multiple interrupts in the main controller 70.

[Dynamic Port Output Processing] FIG. 25 is a flowchart showing a procedure example of the dynamic port output processing. Hereinafter, each procedure will be described step by step.

Step S160: The main control CPU 72 executes a process of clearing the output port 0. This clears the display on the main display. Output port 0 is a port that outputs data related to the main display.

Step S161: The main control CPU 72 executes a process of clearing the output port 2. As a result, the display of the performance display monitor 200 is cleared. The output port 2 is a port that outputs data related to the performance display monitor 200.

The reason for executing the processes of steps S160 and S161 is that in the case of the dynamic lighting method, if the display is not erased, the control process may run out of control when referring to the common data.

After the processing of step S160 and step S161, the processing of waiting for the end of the blanking time can be executed. Due to this waiting time, the display data can be erased and the data can be output after a certain period of time has elapsed. This waiting time is also a waiting time for avoiding the runaway of the control process. During this waiting time, the following processes of step S162 and step S163 may be executed.

Step S162: The main control CPU 72 executes a process of updating the common counter in the range of 0 to 3. As a result, the common number of the output target is updated.

Step S163: The main control CPU 72 executes a process of acquiring common data corresponding to the common counter. As a result, the data corresponding to the common output target can be acquired.

Step S164: The main control CPU 72 executes a process of outputting common data to the output port 1. By outputting the common data to the output port 1, the common data can be output while switching the common. The output port 1 is a port that outputs data that specifies a common number (common 0 to 3) corresponding to a common counter.

Step S165: The main control CPU 72 executes a process of acquiring display data corresponding to the common counter. The display data is stored in the RAM of the used area.

The display data to be acquired is roughly divided into two types, the first data is the data for the main display and the second data is the data for the performance display monitor 200.

The data for the first main display is generated as common output data in the LED display setting process (FIG. 63).

The data for the second performance display monitor 200 may be generated as data for displaying the base in the performance display monitor display process (step S646) of the performance display monitor control process (FIG. 69), and the setting is changed. It may be generated as data for displaying the set value in steps S334 to S346 of the process (FIG. 30).

Here, regarding the data for the second performance display monitor 200, since the display data is set in the common common 0 to 3 buffers both when displaying the base and when displaying the set value, the past The data will be overwritten.

The process of step S169 of FIG. 25 and the process of step S173 of FIG. 26 are the same processes, but when the process of step S169 of FIG. 25 is executed, the common commons 0 to 3 are used. Since the data related to the set value is stored in the buffer, the content related to the set value is displayed on the performance display monitor 200. On the other hand, when the process of step S173 of FIG. 26 is executed, since the data related to the base is stored in the common common 0 to 3 buffers, the content related to the base is displayed on the performance display monitor 200.

Step S166: The main control CPU 72 confirms whether or not it is in a game-enabled state. Specifically, it is confirmed whether or not the value of the gaming machine status flag is "00H".

As a result, when it is confirmed that the game is playable (Yes), the main control CPU 72 executes step S167a. On the other hand, if it cannot be confirmed that the game is playable (No), the main control CPU 72 executes step S169.

Step S167a: The main control CPU 72 executes a process of outputting to the output port 0. Specifically, the process of setting the display of the main display is executed. As a result, the data specified by the specified common is output. The data output here is the common output data generated by the LED display setting process, and by setting the common output data in the common port output buffer, each lamp mounted on the integrated display board 89 The lighting of the can be controlled by the dynamic lighting method.

Step S167b: The main control CPU 72 executes interrupt prohibition processing. Step S167c: The main control CPU 72 executes the register save process.

Step S168a: The main control CPU 72 executes the performance display monitor output process (base-related process execution means). The performance display monitor output process is a base-related process. This process is a process outside the area. Therefore, this process is executed after the interrupt prohibition process is executed. By executing this process, the data specified by the specified common is output. The details of the processing will be described later.

By executing such a process, the main control CPU 72 can execute a process of displaying the base on the performance display monitor 200 (base-related process) as a process included in the process outside the area (second process). Yes (second processing execution means).

Step S168b: The main control CPU 72 executes the register return process. Step S168c: The main control CPU 72 executes interrupt enable processing.

Step S169: The main control CPU 72 executes a process of outputting to the output port 2. Specifically, a process of setting the display of the performance display monitor 200 (a process of outputting the display data acquired in the process of step S165 to the output port 2) is executed. This process is a process of the used area. By executing this process, the set value is displayed on the performance display monitor 200 while the setting is being changed or the setting is being confirmed (when the game is not available). The processing other than the processing in step S168a can be the processing of the used area.

By executing such processing, the buffer contents of the used area can be output to the main display and the buffer contents outside the area can be output to the performance display monitor 200 in the game-enabled state. On the other hand, while the settings are being changed and the settings are being confirmed (when the game is not available), the buffer contents of the used area can be output to the performance display monitor 200, and all the main indicators are cleared so that nothing is displayed. can do.

In the pachinko machine 1, there is a case where the 7-segment LED does not exist in the main display (a case where a plurality of dot LEDs are geometrically arranged). In such a situation, in order to display the set value in an easy-to-understand manner, it is necessary to use the 7-segment LED of the performance display monitor 200. At this time, there is a regular concern that the processing is performed outside the area (concern that the processing is not performed in the used area even though the processing is related to the game).

Since the processing related to the performance display monitor 200 is permitted to be executed outside the area, basically, the display processing of the performance display monitor 200 is executed outside the area. However, among the display processes of the 7-segment LED of the performance display monitor, the process of displaying the set value may correspond to the process related to the game, so the process is executed in the used area.

As a result, the process of displaying the set value on the performance display monitor 200 can be executed in the used area, and regular concerns can be avoided.

By executing such a process, the main control CPU 72 can execute a process of displaying the set value on the performance display monitor 200 as a process included in the process of the used area (first process) (first process). Processing execution means).

When the above processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

[Performance Display Monitor Output Processing] FIG. 26 is a flowchart showing a procedure example of the performance display monitor output processing. Hereinafter, each procedure will be described step by step.

Step S170: The main control CPU 72 executes the stack pointer save process. By this process, the stack pointer of the used area is saved.

Step S171: The main control CPU 72 executes a process of setting a stack pointer outside the area.

Step S172: The main control CPU 72 executes the register save process. To save the register, use the stack pointer outside the area.

Step S173: The main control CPU 72 executes a process of outputting data. Specifically, a process of setting the display of the performance display monitor 200 (a process of outputting the display data acquired in the process of step S165 of FIG. 25 to the output port 2) is executed. By executing this process, the base is displayed on the performance display monitor 200 in the game-enabled state.

This process is the same as step S169 in FIG. 25, but the content of the data output to the output port 2 (content displayed on the performance display monitor 200) is different. In this process (step S173), since the data related to the base is acquired in step S165 of FIG. 25, the data related to the base is output to the output port 2, and the content related to the base is displayed on the performance display monitor 200. On the other hand, in step S169 of FIG. 25, since the data related to the set value is acquired in step S165 of FIG. 25, the data related to the set value is output to the output port 2, and the content related to the set value is displayed on the performance display monitor 200. ..

Since the common output is executed in the process related to the used area (because the common common number is used; see step S164 in FIG. 25), in this process, only the data is output. As a result, the data specified by the specified common is output. The data output here is the common output data generated by the performance display monitor display processing, and by setting the common output data (base display data) in the common port output buffer, the performance display monitor The lighting of each lamp mounted on the 200 can be controlled by a dynamic lighting method.

Specifically, the main control CPU 72 switches either the previous base or the current base together with the corresponding identifiers “bL.” Or “b6.” At preset intervals to display the performance display monitor 200. Executes the process of setting the common output data for display in the port output buffer. The display content on the performance display monitor 200 is controlled based on the common output data (drive signal) set here.

Step S166: The main control CPU 72 executes the register return process.

Step S167: The main control CPU 72 executes the stack pointer return process. By executing this process, after returning to the stack pointer of the used area, the process returns to the process related to the used area. When the above processing is completed, the main control CPU 72 returns to the dynamic port output processing (FIG. 25).

FIG. 27 is a diagram showing the relationship between timer interrupt processing and dynamic port output processing. The timer interrupt is an interrupt having a lower interrupt priority than the serial communication reception interrupt (see FIGS. 19 to 21). Here, the bold dotted arrows in the figure indicate the interrupt prohibited section (dotted line arrows A1 to A3), and the bold solid line arrows in the figure indicate the interrupt permitted section (solid line arrows B1 to B3).

In the timer interrupt process, first, the register save process (S200) and the interrupt flag initialization process (S201) are executed. This section is an interrupt disabled section (see the dotted arrow A1).

When an interrupt occurs, the main control CPU 72 (program, assembler) of the present embodiment automatically enters the same state as when the instruction to disable interrupt is used. Therefore, when the timer interrupt processing is started, the interrupt is disabled internally (as hardware). Therefore, in order to allow interrupts, it is necessary to execute interrupt enable processing.

Therefore, in the timer interrupt process, the interrupt enable process (S201a) is next executed. By executing this process, the interrupt enable section is started (see the solid line arrow B1).

When the dynamic port output process (S202) is called from the timer interrupt process, the dynamic port output process executes a process of clearing the output port 0, a process of clearing the output port 2, and the like (S160, S161). This section is an interrupt enabled section (see solid arrow B1).

In the dynamic port output process, the interrupt disable process (S167b) is then executed. By executing this process, the interrupt disabled section is started (see the dotted arrow A2).

In the dynamic port output process, the register save process (S167c), the performance display monitor output process (S168a), and the register return process (S168b) are further executed. This section is an interrupt disabled section (see the dotted arrow A2).

In the dynamic port output process, the interrupt enable process (S168c) is finally executed. By executing this process, the interrupt enable section is started (see the solid line arrow B2).

The dynamic port output processing returns to the timer interrupt processing, and various processing is executed. This section is an interrupt enabled section (see solid arrow B2).

In the timer interrupt process, the interrupt disable process (S218) is then executed. By executing this process, the interrupt disabled section is started (see the dotted arrow A3). In the timer interrupt process, the register save process (S218a), the performance display monitor control process (S219), and the register return process (S219a) are further executed. This section is an interrupt disabled section (see the dotted arrow A3).

Then, in the timer interrupt process, the interrupt enable process (S220) is executed. By executing this process, the interrupt enable section is started (see the solid line arrow B3).

As described above, in the present embodiment, since the "serial communication reception interrupt processing" having a higher interrupt priority than the "timer interrupt processing" is set, the "performance display monitor control processing (S219)" and the "performance display monitor output" are set. "Processing (S165)" executes processing after disabling interrupts.

Therefore, during the execution of the "performance display monitor control process (S219)" and the "performance display monitor output process (S165)", even if a "serial communication reception interrupt" having a high interrupt priority occurs, it is not interrupted. The "performance display monitor control process (S219)" and the "performance display monitor output process (S165)" are continuously executed. In this case, the "performance display monitor control process" and the "performance display monitor output process" are completed, and the "serial communication reception interrupt process" is executed at the timing when the interrupt is permitted. Since the received data related to the interrupt is stored in the receive buffer, even if the timing of fetching the received data is delayed, the process related to the received data is executed after that, so that no problem occurs.

[Processing content of the main control CPU 72] The main control CPU 72 executes timer interrupt processing (first processing) (first processing execution means). Further, when a serial communication reception interrupt (predetermined interrupt) occurs during execution of the timer interrupt processing, the main control CPU 72 interrupts the execution of the timer interrupt processing and performs serial communication reception interrupt processing (separate from the timer interrupt processing). The second process) is executed (second process execution means).

The timer interrupt process (first process) includes an interrupt enable process that permits the serial communication receive interrupt and an interrupt disallow process that monitors the exit history and does not allow the serial communication receive interrupt.

The interrupt permission process is a process related to the used area, for example, a process (special game management process, etc.) excluding the “performance display monitor control process (S219)” and the “performance display monitor output process (S165)”. The interrupt non-permission process is a process related to the outside of the area, for example, "performance display monitor control process (S219)" and "performance display monitor output process (S165)".

When executing the interrupt disallowed process, the main control CPU 72 executes the interrupt disallowed process in a state where the serial communication reception interrupt is disabled (first process executing means).

Further, when executing the interrupt disallowed processing, the main control CPU 72 executes a process of disabling the serial communication reception interrupt before executing the interrupt disallowed process, executes the interrupt disallowed process, and performs the interrupt disallowed process. After execution, a process that allows serial communication reception interrupts is executed (first process execution means).

The interrupt non-permission process is a part of the process for calculating the base. Some of the processes for calculating the base are "performance display monitor control process (S219)" and "performance display monitor output process (S165)".

FIG. 28 is a diagram showing a modified form of timer interrupt processing. Although the timer interrupt processing has been described in the order of the processing shown in FIG. 24, it can be modified as follows.

The processing order of the timer interrupt processing is as follows: [1] dynamic port output processing, [2] addition number calculation processing (at least prize detection and prize ball number calculation), and [3] performance display monitor control processing.

[1] The reason why the dynamic port output processing is given the highest priority is to make the common switching timing and the data display time constant. Therefore, [1] dynamic port output processing is performed in the first half (early stage) of timer interrupt processing.

[2] The reason why the addition number calculation process is given the next priority is that in the performance display monitor control process, the number of prize balls and the number of outs to be used are calculated in advance within the usage area, so the addition number calculation process is performed. This is because it is necessary to perform it before the display monitor control process.

[3] The reason why the performance display monitor control process is set as the final priority is that the performance display monitor control process needs to be executed after the completion of the addition number calculation process.

The process of inserting into [A], [B] or [C] in the figure is not limited to the arrangement example of FIG. 24, and is an arbitrary process (input port update process, input port edge detection process, winning opening). Judgment processing, processing related to special symbols, processing related to ordinary symbols, processing related to errors, processing related to external output, processing related to test signal output, port output processing, etc.) can be inserted.

At this time, the calculated base value will be different depending on whether the processing related to the special symbol (special game management processing) is performed before or after the addition number calculation processing. The reason for this is that since it is determined whether or not a jackpot is being hit in the addition number calculation process, there are cases where the number of outs, which is the denominator of the base value, is counted and cases where it is not counted.

Specifically, if the processing related to the special symbol is before the addition number calculation processing, it is out if the processing related to the special symbol is a big hit and the out switch is detected within one interrupt. The number is not counted (outswitch detection is judged to be a jackpot and excluded from the base calculation).

On the other hand, when the processing related to the special symbol is after the addition number calculation processing, the number of outs is counted when the processing related to the special symbol is a big hit and the out switch is detected within one interrupt. (Because it has not been a big hit yet at the time of the addition number calculation process, outswitch detection is valid and is not excluded from the base calculation).

In this way, the base value changes depending on whether the processing related to the special symbol is arranged before or after the addition number calculation processing, but the processing related to the special symbol is the game specification or the base to be calculated. It can be placed at any place in the timer interrupt processing according to the contents of.

29 and 30 are flowcharts showing a procedure example of the setting change process. Step S300: The main control CPU 72 executes a process of loading the set value buffer. As a result, the main control CPU 72 can acquire the current set value.

Step S302: The main control CPU 72 confirms whether or not the gaming machine status flag is “01H (setting change status)”.

As a result, when it is confirmed that the gaming machine status flag is "01H (setting change status)" (Yes), the main control CPU 72 executes step S304. On the other hand, when it cannot be confirmed that the gaming machine status flag is "01H (setting change status)" (No), the main control CPU 72 executes step S308.

Step S304: The main control CPU 72 confirms whether or not the RAM clear switch 304 is pressed. In this embodiment, since the RAM clear switch 304 and the setting change switch are also used, the pressing of the RAM clear switch 304 is confirmed here, but the RAM clear switch 304 and the setting change switch are also used. If the setting change switch is not provided separately, it is confirmed whether or not the setting change switch is pressed in this process.

As a result, when it is confirmed that the RAM clear switch 304 is pressed (Yes), the main control CPU 72 executes step S306. On the other hand, when it cannot be confirmed that the RAM clear switch 304 has been pressed (No), the main control CPU 72 executes step S308.

Step S306: The main control CPU 72 executes a process of adding 1 to the set value. For example, when the set value loaded in step S300 is "0 (setting 1)", when this process is executed, the set value becomes "1 (setting 2)". Further, when the set value loaded in step S300 is "1 (setting 2)", when this process is executed, the set value becomes "2 (setting 3)". If the set value loaded in step S300 is "5 (setting 6)", when this process is executed, the set value returns to the original value and becomes "0 (setting 1)".

Here, when the set value loaded in step S300 is "5 (setting 6)", by executing this process, the set value is set to "6 (out of range)" without returning to the original value, and the next The process of correcting to "0 (setting 1)" may be performed in step S308 and step S310.

Step S308: The main control CPU 72 confirms whether or not the set value is in the range of “0 (setting 1)” to “5 (setting 6)”. This process is a process for avoiding that an unintended setting value is set.

As a result, when it is confirmed that the set value is in the range of "0 (setting 1)" to "5 (setting 6)" (Yes), the main control CPU 72 executes step S312. On the other hand, when it cannot be confirmed that the set value is in the range of "0 (setting 1)" to "5 (setting 6)" (No), the main control CPU 72 executes step S310.

Step S310: The main control CPU 72 executes a process of setting “0 (setting 1)”. As a result, "0 (setting 1)" can be set when an unintended setting value is set.

Step S312: The main control CPU 72 confirms whether or not the gaming machine status flag is “01H (setting change status)”.

As a result, when it is confirmed that the gaming machine status flag is "01H (setting change status)" (Yes), the main control CPU 72 executes step S314. On the other hand, when it cannot be confirmed that the gaming machine status flag is "01H (setting change status)" (No), the main control CPU 72 executes step S322 (in-page combiner 1 → 1).

Step S314: The main control CPU 72 confirms whether or not the setting key has changed from ON to OFF. When the input signal from the setting key switch 302 changes from ON to OFF, the main control CPU 72 can determine that the setting key has changed from ON to OFF.
The determination process may be a determination process for determining whether the setting key (setting key switch 302) is OFF.

As a result, when it is confirmed that the setting key has changed from ON to OFF (Yes), the main control CPU 72 executes step S316. On the other hand, when it cannot be confirmed that the setting key has changed from ON to OFF (No), the main control CPU 72 executes step S334 (off-page combiner C → C).

Step S316: The main control CPU 72 executes a process of generating a “setting-related end designation command” as a subcommand. The "setting-related end specification command" can include information that the setting-related processing (processing related to setting change or processing related to setting confirmation) has been completed and information on the setting value.

Step S317: The main control CPU 72 executes the subcommand group set process. By executing this process, various commands including the "setting-related end specification command" are set in the subcommand transmission buffer. The various commands can be the same commands as the commands sent when the power is turned on. The command set here is transmitted to the effect control device 124 in the subcommand transmission process.

Step S318: The main control CPU 72 executes a process of saving the output time (for example, 128 ms) in the security signal output timer (special information continuous transmission process execution means). By saving the output time in the security signal output timer, the security signal is output to the hall computer in the external information management process (step S217a in FIG. 24).

This process is a part of the special information continuous transmission process (process for setting a timer). The main control CPU 72 executes this process not only at the end of the setting confirmation state but also at the end of the setting change state (special information continuous transmission processing execution means).

In this process, in order to guarantee that the security signal output time at the time of setting confirmation is 128 ms or more, a 128 ms security signal output timer is set at the end of the setting confirmation.

When the setting confirmation is completed, the security signal output timer is set and the gaming machine status flag is cleared. As a result, the setting change process (setting-related process) is not called from the next timer interrupt. Then, the security signal continues to be transmitted until the timer for outputting the security signal expires. In order to reduce the program code, the security signal output timer is set even at the end of the setting change, but it is left as it is because there is no problem even if the security signal output time becomes long.

It is also possible to arrange a branch process of whether the setting confirmation state is completed or the setting confirmation state is completed before the main process so that the main process is executed only when the setting confirmation state is completed.

Step S319: The main control CPU 72 executes a process of clearing the gaming machine status flag. Specifically, the main control CPU 72 executes a process of setting "00H" in the gaming machine status flag. As a result, the state of the gaming machine shifts to the playable state. When this process is completed, the main control CPU 72 then executes step S332 (in-page combiner 2 → 2).

Step S322: The main control CPU 72 confirms whether or not the setting key is ON or the inner frame is open.

As a result, when it is confirmed that the setting key is ON or the inner frame is open (Yes), the main control CPU 72 executes step S332 (in-page combiner 2 → 2). On the other hand, when it cannot be confirmed that the setting key is ON or the inner frame is open (No), the main control CPU 72 executes step S324.

Step S324: The main control CPU 72 executes a process of updating the inner frame closing timer.
In this process, the main control CPU 72 sets an initial value in the inner frame closing timer when the inner frame (for example, the inner frame assembly 7) is closed, and then counts down the timer (for each call of this module) with the passage of time. To do.

Step S324: The main control CPU 72 confirms whether or not the inner frame closing timer has timed up. Specifically, if the value of the inner frame closing timer is not yet 0, the main control CPU 72 determines that the inner frame closing timer has not timed up (No). In this case, the main control CPU 72 executes step S334 (out-of-page coupler C → C).

After that, when the value of the inner frame closing timer becomes 0 with the passage of time, the main control CPU 72 determines that the inner frame closing timer has timed up (Yes), and executes step S328.

Step S328: The main control CPU 72 executes a process of clearing the gaming machine status flag. Specifically, the main control CPU 72 executes a process of setting "00H" in the gaming machine status flag. As a result, the state of the gaming machine shifts to the playable state.

Step S330: The main control CPU 72 executes a process of shifting to the process when the setting change is completed. Specifically, the process of shifting to step S152a (step S153) of FIG. 23 is executed by the jump command (off-page combiner “shift to process when setting change is completed” → “when setting change is completed”).

By executing such a process, when the setting change and the setting confirmation are completed, the reset state is entered. Specifically, it jumps to the evacuation process when the power is turned off. Then, at the jump destination, after the checksum calculation, the power supply is confirmed, and the program returns to the beginning (CPU initialization process). As a result, the program configuration changes from "initialization-> setting change or setting confirmation (temporary main loop)-> initialization after setting change-> original main loop" to "initialization-> main loop (playable state)". , Setting change and setting confirmation) ”.

Here, when adding a setting function (setting change device 300) to the pachinko machine 1, the processing at power-on is (1) initialization processing, (2) main loop processing during setting change, and (3) setting. It is necessary to configure the configuration to reinitialize after the change (clearing the display, reclearing the RAM, shifting to the game-enabled state, etc.), and (4) main loop processing during the game.
In this way, when the setting function is added, in addition to the setting change processing itself, processing before and after the setting change processing is required, so that the amount of program code increases significantly.

Therefore, in the present embodiment, the processing at the time of power-on (at least a part of the CPU initialization processing) and the evacuation processing at the time of power-off notice (at least a part of the power-off warning interrupt processing) are performed. It is also used as a process after the setting change is completed.

Specifically, in the setting change processing called during the timer interrupt, when the end condition of the setting change or the setting confirmation is satisfied, the timer interrupt processing is not returned and the evacuation processing at the time of power cut notification (interrupt processing at the time of power cut notification). (In the middle of).

In the save process when the power is turned off, all output ports are cleared, the checksum is calculated and saved, and since the power remains ON after that, the program returns to the beginning (CPU initialization process) and the power is restored. It shifts to the normal game state through the same initialization process as above.

In this way, by combining the processing when the power is turned on and the evacuation processing when the power is turned off, the processing after the setting change is completed is compared with the case where the processing after the setting change is performed by a dedicated program. The amount of increase can be suppressed.

Step S332: The main control CPU 72 executes a process of clearing the inner frame closing timer. Then, when this process is completed, the main control CPU 72 then executes step S334 (out-of-page combiner C → C).

Step S334: The main control CPU 72 executes a process of setting the display data “rn.” In the common 0, 1 buffer.

Step S336: The main control CPU 72 confirms whether or not the gaming machine status flag is “01H (setting change status)”.

As a result, when it is confirmed that the gaming machine status flag is "01H (setting change status)" (Yes), the main control CPU 72 executes step S338. On the other hand, when it cannot be confirmed that the gaming machine status flag is "01H (setting change status)" (No), the main control CPU 72 executes step S340.

Step S338: The main control CPU 72 executes a process of setting data corresponding to “−” as display data in the common 2 buffer. The main control CPU 72 then executes step S342.

Step S340: The main control CPU 72 executes a process of setting data corresponding to “blank (non-display)” as display data in the common 2 buffer. The main control CPU 72 then executes step S342.

Step S342: The main control CPU 72 executes a process of loading the set value buffer. As a result, the main control CPU 72 can acquire the set value after the setting is changed.

Step S344: The main control CPU 72 executes a process of converting the set value into display data.

Step S346: The main control CPU 72 executes a process of setting the display data converted by the process of step S344 as display data in the common 3 buffer.

For example, when the setting value is "5 (setting 6)" and the setting is being changed, the four 7-segment LEDs 201 to 204 of the performance display monitor 200 are displayed in order from the left side, "r", "n.", " -"" 6 "is displayed. When the set value is "0 (setting 1)" and the setting is being confirmed, the four 7-segment LEDs 201 to 204 of the performance display monitor 200 are displayed in order from the left side with "r", "n.", "N." Blank (hidden) "and" 1 "are displayed.

That is, the display modes "r", "n.", "-", And "set value" of the performance display monitor 200 are the display modes (first display mode) during which the settings are being changed, and the "r", "n." The display modes of "n.", "blank (non-display)", and "set value" are the display modes (second display mode) during setting confirmation.

By executing such a process, the performance display monitor 200 displays the set value in different display modes depending on whether the setting is being changed or the setting is being confirmed, and when the set value is displayed, the base is displayed. It can be hidden.

Further, by executing such a process, the performance display monitor 200 can display the set value or the base, that is, the main control CPU 72 causes the performance display monitor 200 to display the set value or the base. The base is not displayed when the performance display monitor 200 is displaying the set value, and the set value is not displayed when the performance display monitor 200 is displaying the base.
When the above processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

[Switch management process]
FIG. 31 is a flowchart showing a procedure example of the switch management process. Hereinafter, each procedure will be described step by step.

Step S10: The main control CPU 72 confirms whether or not a winning detection signal has been input (a lottery trigger has occurred) from the middle start winning opening switch 80 corresponding to the first special symbol. When the input of the winning detection signal is confirmed (Yes), the main control CPU 72 proceeds to the next step S12 to execute the first special symbol storage update process. The specific contents of the processing will be described later using another flowchart. On the other hand, if there is no input of the winning detection signal (No), the main control CPU 72 proceeds to step S14.

Step S14: Next, the main control CPU 72 confirms whether or not a winning detection signal has been input (a lottery trigger has occurred) from the right-starting winning opening switch 82 corresponding to the second special symbol. When the input of the winning detection signal is confirmed (Yes), the main control CPU 72 proceeds to the next step S16 to execute the second special symbol storage update process. Similarly, the specific contents of the processing will be described later with reference to another flowchart. On the other hand, when there is no input of the winning detection signal (No), the main control CPU 72 proceeds to step S18.

Step S18: The main control CPU 72 confirms whether or not the winning detection signal has been input from the first count switch 84 corresponding to the first major winning opening of the first variable winning device 30. When the input of the winning detection signal is confirmed (Yes), the main control CPU 72 proceeds to the next step S20 to execute the first large winning opening counting process. In the first big winning opening counting process, the main control CPU 72 counts the number of winning balls to the first variable winning device 30 for each round during the big hit game. On the other hand, when there is no input of the winning detection signal (No), the main control CPU 72 proceeds to step S21a.

Step S21a: The main control CPU 72 confirms whether or not the winning detection signal has been input from the second count switch 85 corresponding to the second major winning opening of the second variable winning device 31. When the input of the winning detection signal is confirmed (Yes), the main control CPU 72 proceeds to the next step S21b to execute the second major winning opening counting process. In the second big winning opening counting process, the main control CPU 72 counts the number of winning balls to the second variable winning device 31 during the big hit game. On the other hand, if there is no input of the winning detection signal (No), the main control CPU 72 proceeds to step S22.

Step S22: The main control CPU 72 confirms whether or not a passage detection signal has been input from the gate switch 78 corresponding to the normal symbol. When the input of the passage detection signal is confirmed (Yes), the main control CPU 72 proceeds to the next step S24 to execute the normal symbol storage update process. In the normal symbol memory update process, the main control CPU 72 confirms whether or not the current number of normal symbol operation memories is less than the upper limit (for example, 4), and if it does not reach the upper limit, acquires a random number per normal symbol. To do. Further, the main control CPU 72 increments the number of normal symbol operation memories by one. Then, the main control CPU 72 stores the acquired random number value per normal symbol in the random number storage area of the RAM 76. On the other hand, when there is no input of the winning detection signal (No), the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

[1st special symbol memory update process]
FIG. 32 is a flowchart showing a procedure example of the first special symbol memory update process (step S12 in FIG. 31). Hereinafter, the procedure of the first special symbol memory update process will be described step by step.

Step S30: Here, first, the main control CPU 72 refers to the value of the first special symbol operation memory number counter, and confirms whether or not the operation memory number is less than the maximum value (for example, 4). The working memory number counter represents the number (number of sets) of the big hit determination random number, the big hit symbol random number, etc. stored in the random number storage area of the RAM 76. Here, the random number storage area of the RAM 76 is divided into eight sections (for example, 2 bytes each) commonly used in the first special symbol and the second special symbol, and each section contains a jackpot determined random number and a jackpot symbol. Random numbers can be stored one by one as a set. At this time, if the value of the working memory counter corresponding to the first special symbol reaches the maximum value (No), the main control CPU 72 returns to the switch management process (FIG. 31). On the other hand, if the value of the working memory counter is less than the maximum value (Yes), the main control CPU 72 proceeds to the next step S31.

Step S31: The main control CPU 72 adds one first special symbol operation memory number. The first special symbol operation storage number counter is stored in, for example, the operation storage number area of the RAM 76, and the main control CPU 72 increments (+1) the value. The lighting state of the first special symbol operation memory lamp 34a is controlled based on the value of the counter added here.

Step S32: Then, the main control CPU 72 acquires the jackpot determination random number value corresponding to the first special symbol from the random number circuit 75 through the sampling circuit 77 (acquisition of the first lottery element, lottery element acquisition means). The random number value is acquired by designating the pin address of the random number circuit 75. When the main control CPU 72 performs 8-bit processing, the address is specified twice for each byte at the upper and lower levels. When the main control CPU 72 reads the jackpot determination random number value from the designated address, it saves this as the jackpot determination random number corresponding to the first special symbol at the transfer destination address.

Step S33: Next, the main control CPU 72 acquires the jackpot symbol random number value corresponding to the first special symbol from the jackpot symbol random number counter area of the RAM 76. The acquisition of this random number value is also performed by designating the address of the jackpot symbol random number counter area. When the main control CPU 72 reads the jackpot symbol random number value from the designated address, it saves this as a jackpot symbol random number corresponding to the first special symbol at the transfer destination address.

Step S34: Further, the main control CPU 72 sequentially acquires a reach determination random number and a variation pattern determination random number as random numbers related to the variation condition of the first special symbol from the variation random number counter area of the RAM 76 (acquisition of variation pattern determination element). means). Similarly, the acquisition of these random number values is performed by designating the address of the random number counter area for fluctuation. Then, when the main control CPU 72 acquires the reach determination random number and the variation pattern determination random number from the designated address, they save them at the transfer destination address.

Step S35: The main control CPU 72 transfers the saved jackpot determination random number, jackpot symbol random number, reach determination random number, and fluctuation pattern determination random number to the random number storage area corresponding to the first special symbol, and transfers these random numbers to an empty section in the area. (Memory means, lottery element storage means). An order (for example, first to fourth) is set for the plurality of sections, and if all the first to fourth sections are empty at this stage, each random number is stored in order from the first section. Alternatively, if the first section is already filled and the other second to fourth sections are empty, each random number is stored in order from the second section. The random number storage area is read out in a FIFO (First In First Out) format.

Step S36: Next, the main control CPU 72 confirms whether or not the current special game management status (game state) is a big hit. If it is not during the jackpot (No), the main control CPU 72 executes the following steps S37 and S38. If the jackpot is in progress (Yes), the main control CPU 72 skips steps S37 and S38 and proceeds to step S38a. The reason why this determination is made in the present embodiment is that the pre-reading effect is not performed for the ball entering during the big hit.

Step S37: When it is not during the jackpot (step S36: No), the main control CPU 72 executes the acquisition-time effect determination process for the first special symbol. In this process, the result of the internal lottery is determined in advance (before the start of fluctuation) based on the big hit determination random number and the big hit symbol random number of the first special symbol acquired in the previous steps S32 to S34, respectively, and the effect content is determined accordingly. It is for making a judgment (so-called "look-ahead"). The specific contents of the processing will be described later with reference to another flowchart.

Step S38: After returning from the acquisition-time effect determination process, the main control CPU 72 then sets the upper byte (for example, “B8H”) of the special figure destination determination effect command for the first special symbol. This high-order byte data describes that the command type is "for special figure destination determination effect regarding the first special symbol". Since the lower byte of the special figure destination determination effect command is set in the previous acquisition effect determination process (step S37), here, by synthesizing the upper byte with the lower byte, for example, a command having a length of one word. Will be generated.

Step S38a: Next, the main control CPU 72 sets an effect command when the number of operating memories increases with respect to the first special symbol. Specifically, the one-word length obtained by adding the increased working memory number (for example, "01H" to "04H") to the lower byte with respect to the preceding value (for example, "BBH") of the upper byte indicating the type of the command. Generate a production command. At this time, for the lower byte, by setting the second digit to "0" by default, the value indicates that the value is "the result (change information) due to the increase in the number of working memories". That is, if the lower byte is "01H", it means that the number of working memories this time is "01H" as a result of increasing by one from the number of working memories "00H" up to the previous time. Similarly, if the lower byte is "02H" to "04H", it is increased by one from the previous working memory numbers "01H" to "03H", and as a result, the working memory number this time is "02H" to "04H". It means that it became "04H". The preceding value "BBH" is a value indicating that the effect command this time is a working memory number command for the first special symbol.

Step S39: Then, the main control CPU 72 executes the effect command output setting process with respect to the first special symbol. This process is for transmitting the special figure destination determination effect command generated in step S38, the operation memory increase effect command generated in step S38a, and the start opening winning sound control command to the effect control device 124. It is a thing (memory number notification means).

When the above procedure is completed or the number of first special symbol operation memories has reached 4 (step S30: No), the main control CPU 72 returns to the switch management process (FIG. 31).

[Second special symbol memory update process]
FIG. 33 is a flowchart showing a procedure example of the second special symbol memory update process (step S16 in FIG. 31). Hereinafter, the procedure of the second special symbol memory update process will be described step by step.

Step S40: The main control CPU 72 refers to the value of the second special symbol operation memory number counter, and confirms whether or not the operation memory number is less than the maximum value. Similarly to the above, the second special symbol operation storage number counter represents the number (number of sets) of the jackpot determination random number, the jackpot symbol random number, etc. stored in the random number storage area of the RAM 76. At this time, if the value of the second special symbol operation memory counter reaches the maximum value (for example, 4) (No), the main control CPU 72 returns to the switch management process (FIG. 31). On the other hand, if the value of the second special symbol operation memory counter is still less than the maximum value (Yes), the main control CPU 72 proceeds to the next step S41 or later.

Step S41: The main control CPU 72 adds one second special symbol operation memory number (increments the value of the second special symbol operation memory number counter). Similar to the previous step S31 (FIG. 32), the lighting state of the second special symbol operation storage lamp 35a is controlled based on the value of the counter added here.

Step S42: Then, the main control CPU 72 acquires the jackpot determination random number value corresponding to the second special symbol from the random number circuit 75 through the sampling circuit 77 (acquisition of the second lottery element, lottery element acquisition means). The method of acquiring the random number value is the same as that of step S32 (FIG. 32) described above.

Step S43: Next, the main control CPU 72 acquires the jackpot symbol random number value corresponding to the second special symbol from the jackpot symbol random number counter area of the RAM 76. The method of acquiring the random number value is the same as that of step S33 (FIG. 32) described above.

Step S44: Further, the main control CPU 72 sequentially acquires the reach determination random number and the variation pattern determination random number related to the variation condition of the second special symbol from the variation random number counter area of the RAM 76 (variation pattern determination element acquisition means). The acquisition of these random numbers is also performed in the same manner as in step S34 (FIG. 32) described above.

Step S45: The main control CPU 72 transfers the saved jackpot determination random number, jackpot symbol random number, reach determination random number, and fluctuation pattern determination random number to the random number storage area corresponding to the second special symbol, and transfers these random numbers to an empty section in the area. To memorize as a set (memory means). The storage method is the same as in step S35 (FIG. 32) described above.

Step S45a: Next, the main control CPU 72 confirms whether or not the current game management status (game state) is a big hit. Then, if it is not during the jackpot (No), the main control CPU 72 executes the following steps S46 and S47. On the contrary, if the jackpot is in progress (Yes), the main control CPU 72 skips steps S46 and S47 and proceeds to step S48. The reason why this judgment is made in the present embodiment is that the effect of pre-reading is not performed for the incoming ball that also occurs during the big hit.

Step S46: When it is not during the jackpot (step S45a: No), the main control CPU 72 then executes the acquisition-time effect determination process for the second special symbol. In this process, the result of the internal lottery is determined in advance (before the start of fluctuation) based on the big hit determination random number and the big hit symbol random number of the second special symbol acquired in the previous steps S42 to S44, respectively, and the effect content is determined accordingly. It is for judging. The details of the specific processing will be described later.

Step S47: After returning from the acquisition-time effect determination process, the main control CPU 72 then sets the upper byte (for example, “B9H”) of the special figure destination determination effect command. This high-order byte data describes that the command type is "for special figure destination determination effect regarding the second special symbol". Similarly, since the lower byte of the special figure destination determination effect command is set in the previous acquisition effect determination process (step S46), here, for example, one word is combined with the lower byte. A long command will be generated.

Step S48: Next, the main control CPU 72 sets an effect command when the number of operating memories increases with respect to the second special symbol. Here, a one-word length production command in which the number of operating memories after the increase (for example, "01H" to "04H") is added to the lower byte with respect to the preceding value (for example, "BCH") of the upper byte indicating the type of the command. To generate. Similarly, for the second special symbol, by setting the second digit of the lower byte to "0" by default, it is possible to indicate that the value is "the result (change information) due to the increase in the number of working memories". it can. The preceding value "BCH" is a value indicating that the current effect command is a working memory number command for the second special symbol.

Step S49: Then, the main control CPU 72 executes the effect command output setting process with respect to the second special symbol. As a result, preparations are made for transmitting the special figure destination determination effect command, the operation memory number increase effect command, the start opening winning sound control command, and the like to the effect control device 124 with respect to the second special symbol (memory number notification means). .. When the above procedure is completed, the main control CPU 72 returns to the switch management process (FIG. 31).

[Production judgment processing at the time of acquisition]
FIG. 34 is a flowchart showing a procedure example of the effect determination process at the time of acquisition. The main control CPU 72 executes this acquisition-time effect determination process in the first first special symbol memory update process and the second special symbol memory update process (step S37 in FIG. 32, step S46 in FIG. 33) (first determination). Execution means, look-ahead processing execution means). As described above, this process is executed for each of the first special symbol (when the ball enters the middle start winning opening 26) and the second special symbol (when the ball enters the variable start winning device 28). Therefore, the following description may correspond to the process related to the first special symbol or the process related to the second special symbol. Hereinafter, the content of the process will be described according to each procedure.

Step S50: The main control CPU 72 sets the lower bytes (for example, “00H”) of the special figure destination determination effect command (first determination information). The byte data set here represents the standard value (at the time of deviation) of the command.

Step S52: Next, the main control CPU 72 loads the jackpot determination random number as the first determination random number value. The random number to be loaded here is stored in the RAM 76 in the first special symbol memory update process (step S35 in FIG. 32) or the second special symbol memory update process (step S45 in FIG. 33). ..

Step S54: Then, the main control CPU 72 determines whether or not the loaded random number is outside the range of the hit value (here, the lower limit value or less) (lottery result destination determination means). Specifically, the main control CPU 72 sets a comparison value (lower limit value) in the A register, and subtracts the loaded random number value from this comparison value. The comparison value (lower limit value) is set according to the winning probability of the internal lottery in the pachinko machine 1 (the winning probability according to the set value). Next, the main control CPU 72 determines whether or not the calculation result is 0 or a positive value from the value of the flag register, for example. As a result, if the loaded random number is out of the range of the hit value (Yes), the main control CPU 72 proceeds to step S80.

Step S80: Next, the main control CPU 72 executes the deviation pattern information pre-determination process (variation pattern destination determination means). In this process, the main control CPU 72 generates a fluctuation pattern destination determination command for the fluctuation time at the time of disconnection. The fluctuation pattern destination determination command generated here reflects prior determination information regarding the fluctuation time (or fluctuation pattern number) when the "time reduction function" is activated. For example, if the current state is when the "time reduction function" is activated, the main control CPU 72 corresponds to the "out-of-reach variation (non-reduction variation time)" based on the loaded reach determination random number. Determine if it exists. As a result, when the fluctuation time corresponds to the "out-of-reach fluctuation (non-shortening fluctuation time)", the main control CPU 72 generates a fluctuation pattern destination determination command corresponding to the "time reduction / medium non-shortening fluctuation time". In the case of reach variation, the "reach group (type of reach)" may also be determined from the reach mode random number, and the variation pattern destination determination command may be generated from the result. On the other hand, when the fluctuation time does not correspond to the "out-of-reach fluctuation (non-shortening fluctuation time)", the main control CPU 72 generates a fluctuation pattern destination determination command corresponding to the "time reduction / medium reduction fluctuation time". Alternatively, if the current state is when the "time reduction function" is not operating (low probability state), the main control CPU 72 corresponds to the "normally out-of-reach fluctuation" based on the loaded reach determination random number. Judge whether or not. As a result, when the fluctuation time corresponds to the "normally out of reach fluctuation", the main control CPU 72 generates a fluctuation pattern destination determination command corresponding to the "normally out of reach fluctuation time". On the other hand, when the fluctuation time does not correspond to the "normal deviation reach fluctuation", the main control CPU 72 generates a fluctuation pattern destination determination command corresponding to the "normal deviation fluctuation time". Further, the fluctuation pattern destination determination command generated here is set in the transmission buffer in the effect command output setting process (steps S39 and S49) as described above. In this process, the main control CPU 72 may generate a variation pattern destination determination command for the variation pattern at the time of small hit, in the same manner as the above-described processing at the time of loss.

When the above procedure is executed, the main control CPU 72 ends the acquisition-time effect determination process and returns to the caller's first special symbol memory update process (FIG. 31) or the second special symbol memory update process (FIG. 32). On the other hand, in the determination in step S54 above, if the loaded random number is not outside the range of the hit value but within the range (step S54: No), the main control CPU 72 then proceeds to step S56.

Step S56: The main control CPU 72 confirms whether or not the probability state schedule flag based on the first determination result is set. The probability state schedule flag based on the pre-determination result is set when the winning value is among the jackpot determination random numbers stored so far, although the fluctuation has not been started yet. Specifically, if there is a winning value in the jackpot determination random numbers that have been memorized so far, and if the jackpot symbol random number that is paired with this random number corresponds to "one of the probabilistic symbols", the probability state is planned. For example, "A0H" is set in the flag. This value represents a flag value for setting a high probability state as a schedule in the preliminary determination (pre-reading determination) of the jackpot determination random number acquired after the jackpot determination random number. On the other hand, if there is a winning value in the jackpot determination random numbers stored so far, and the jackpot symbol random number that is paired with this random number corresponds to "one of the normal symbols", the probability state is planned. For example, "01H" is set in the flag. This value represents a flag value for setting a normal (low) probability state as a schedule in the pre-determination (pre-reading determination) of the jackpot-determined random number acquired after the jackpot-determined random number. If the winning value does not yet exist in the jackpot determination random numbers stored so far, the flag value is reset (00H). Further, the value of the probability state schedule flag is stored in the flag area of the RAM 76, for example. In addition, although an example in which the advance hit determination is strictly performed using the "probability state schedule flag" is given here, when the advance hit determination is simply performed based on the current probability state, this step S56 and subsequent steps. Step S58, step S60, step S62, step S76 and the like may be omitted.

If the probability state schedule flag is not yet set (step S56: No), the main control CPU 72 then executes step S66.

Step S66: In this case, the main control CPU 72 then sets the low probability (normal time) comparison value in the A register. The low-probability comparison value is also set according to the low-probability winning probability (winning probability according to the set value) in the pachinko machine 1.

Step S68: Next, the main control CPU 72 loads the “current probability state flag”. This probability state flag indicates whether or not the current internal state has a high probability (during probability change), and is stored in the flag area of the RAM 76. If the current probability state is high probability (during probability change), the value "01H" is set as the state flag, and if the current probability state is low probability (normal), the value of the state flag is reset ("00H"). ").

Step S70: Then, the main control CPU 72 confirms whether or not the loaded current special symbol probability state flag represents a high probability (≠ 01H), and as a result, if it represents a high probability (No). ), Then step S64 is executed.

Step S64: The main control CPU 72 sets a comparison value for high probability. As a result, the low-probability comparison value set in step S66 above is rewritten. The high-probability comparison value is set according to the high-probability winning probability (winning probability according to the set value) in the pachinko machine 1.

In this way, when the probability state schedule flag based on the previous determination result has not been set yet and the current internal state has a high probability, the comparison value is rewritten for the high probability time, and then the next step S72. Will be executed. On the other hand, when it is confirmed in the previous step S70 that the current probability state flag does not represent a high probability (Yes), the main control CPU 72 skips step S64 and executes the next step S72.

Step S72: The main control CPU 72 determines whether or not the random number loaded in the previous step S52 is out of the range of the winning value (lottery result destination determination means). That is, the main control CPU 72 subtracts the jackpot determination random number value from the comparison value set for each state. Then, the main control CPU 72 similarly determines from the value of the flag register whether or not the calculation result is a negative value (<0), and as a result, if the loaded random number is out of the range of the hit value (Yes). ), The main control CPU 72 executes the above-mentioned pre-determination process (step S80) of the variation pattern information at the time of deviation. On the other hand, if the loaded random number is not outside the range of the hit value but within the range (No), the main control CPU 72 then proceeds to step S74.

Step S74: The main control CPU 72 executes the jackpot symbol type determination process. This process is for determining the jackpot type (winning type) at that time based on the jackpot symbol random number that is paired with the jackpot determination random number. For example, the main control CPU 72 loads the jackpot symbol random numbers for each symbol stored in the first special symbol storage update process (step S35 in FIG. 32) or the second special symbol memory update process (step S45 in FIG. 33). Then, the calculation using the comparison value is executed in the same manner as in step S54 above, and from the result, it is determined whether the jackpot type corresponds to the "probability variation symbol" or the "normal symbol". The main control CPU 72 stores the determination result at this time as a special symbol destination determination value, and proceeds to the next step S76.

Step S76: Then, the main control CPU 72 sets the value of the probability state schedule flag based on the first determination result. Specifically, when the special symbol destination determination value stored in the previous step S74 represents a "normal symbol", the main control CPU 72 sets the value "01H" in the probability state schedule flag. On the other hand, when the special symbol destination determination value represents the "probability variation symbol", the main control CPU 72 sets the value "A0H" in the probability state schedule flag. As a result, in the next and subsequent processes, it is determined that "flag set has been completed" in step S56.

Step S78: The main control CPU 72 sets the special symbol destination determination value stored in the previous step S74 as a lower byte of the special symbol destination determination effect command. For the special symbol destination determination value, for example, "01H" is set when it corresponds to "normal symbol", and "A0H" is set when it corresponds to "probability variation symbol". In any case, by setting the data for the lower byte here, the standard lower byte data "00H" set in the previous step S50 is rewritten.

Step S79: Next, the main control CPU 72 executes the jackpot variation pattern information pre-determination process (variation pattern destination determination means). In this process, the main control CPU 72 generates a fluctuation pattern destination determination command for the fluctuation time at the time of a big hit. The fluctuation pattern destination determination command generated here reflects, for example, prior determination information regarding the reach variation time (or variation pattern number) at the time of a big hit. Further, the fluctuation pattern destination determination command generated here is set in the transmission buffer in the effect command output setting process (steps S39 and S49) as described above.

The above is the procedure before the probability state schedule flag is set based on the first determination result (before the internal first hit). On the other hand, when the probability state schedule flag is set through the previous step S76, the following procedure is executed. However, when the advance hit determination is performed only by the current probability state as described above, it is not necessary to execute the following steps S56, S58, step S60, step S62, and step S76.

Step S56: When the main control CPU 72 confirms that the value has already been set in the probability state schedule flag (Yes), the main control CPU 72 then executes step S58.

Step S58: The main control CPU 72 first sets the comparison value for low probability (normal time) in the A register.

Step S60: Next, the main control CPU 72 loads the “probability state schedule flag”. As described above, the probability state schedule flag is for setting the probability state in a planned manner in the subsequent subsequent determination based on the immediately preceding determination result, and is stored in the flag area of the RAM 76. .. If the probability state based on the previous judgment result is scheduled to shift to a high probability (probability change), "A0H" is set as the value of the probability state schedule flag as described above, and conversely, the previous judgment result immediately before. If the probability state based on is scheduled to return to a low probability (normal), "01H" is set as the value of the probability state schedule flag.

Step S62: Then, the main control CPU 72 confirms whether or not the loaded probability state schedule flag represents a high-probability schedule (≠ 01H), and as a result, if the loaded probability state schedule flag represents a high-probability schedule (≠ 01H). No), then step S64 is executed, and the comparison value for high probability is set.

In this way, if the probability state schedule flag based on the first determination result is already set and the value is for a high probability, the comparison value is rewritten for the high probability time, and then the next step S72 or later. Will be executed. On the other hand, when it is confirmed in the previous step S62 that the probability state schedule flag does not represent a high-probability schedule but represents a normal (low) probability schedule (Yes), the main control CPU 72 steps. S64 is skipped and the next step S72 and subsequent steps are executed. As a result, in the present embodiment, the jackpot determination in advance can be performed in consideration of the subsequent changes in the internal state (normal probability state → high probability state, high probability state → normal probability state) based on the first determination result. ..

When the above procedure is completed, the main control CPU 72 returns to the first special symbol memory update process (FIG. 32) or the second special symbol memory update process (FIG. 33).

[Special game management process]
FIG. 35 is a flowchart showing a configuration example of the special game management process.
The special game management process includes execution selection process (step S1000), special symbol change pre-process (step S2000), special symbol change process (step S3000), special symbol stop display process (step S4000), and variable winning device at the time of big hit. The configuration includes a group of subroutines (program modules) for the management process (step S5000) and the small hit variable winning device management process (step S6000). Here, first, the basic flow of the special game management process will be described along with each process.

Step S1000: In the execution selection process, the main control CPU 72 selects the jump destination of the process to be executed next (any of steps S2000 to S5000) from the “jump table”. For example, the main control CPU 72 sets the program address of the process to be executed next as the jump destination address, and sets the end of the special game management process in the stack pointer as the return destination address.

Which process is selected as the next jump destination depends on the progress of the processes performed so far (special symbol game management status). For example, if the special symbol has not yet started the variation display (special symbol game management status: 00H), the main control CPU 72 selects the special symbol variation preprocessing (step S2000) as the next jump destination. On the other hand, if the special symbol change preprocessing has already been completed (special symbol game management status: 01H), the main control CPU 72 selects the special symbol changing process (step S3000) as the next jump destination, and the special symbol is changing. If the processing is completed (special symbol game management status: 02H), the processing during display of special symbol stop display (step S4000) is selected as the next jump destination. In the present embodiment, the jump destination address is specified in the "jump table" to select the process, but apart from such a selection method, a "process flag", a "process selection flag", or the like is used. There is also a known programming example in which the CPU selects the process to be executed next. In such a programming example, the CPU performs each process as a whole, and in the first step thereof, the flag is referred to one by one for conditional branching (continuation / return). However, in the selection method of the present embodiment, the main control is performed. There is no need for the CPU 72 to call each process one by one.

Step S2000: In the special symbol variation preprocessing, the main control CPU 72 performs an operation of adjusting the conditions for starting the variation display of the special symbol. The specific contents of the processing will be described later using another flowchart.

Step S3000: In the special symbol changing process, the main control CPU 72 performs drive control of the first special symbol display device 34 or the second special symbol display device 35 while counting the fluctuation timer. Specifically, an ON or OFF drive signal (1 byte data) is generated for each segment and dots (Nos. 0 to 7) of the 7-segment LED. The pattern of the drive signal changes with the passage of time, thereby displaying the variation of the special symbol.

Step S4000: In the process during special symbol stop display, the main control CPU 72 controls the drive of the first special symbol display device 34 or the second special symbol display device 35. Here as well, an ON or OFF drive signal is generated for each segment and dot of the 7-segment LED, but the pattern of the drive signal is constant, and a stop display of a special symbol is performed.

Step S5000: The jackpot variable winning device management process is selected when the special symbol is stopped and displayed in the jackpot mode in the previous special symbol stop display processing. For example, when the special symbol is stopped and displayed in the form of a big hit, an opportunity occurs to shift from the normal state up to that point to the big hit gaming state (a special gaming state advantageous for the player). During the jackpot game, the jump destination is set in the jackpot variable winning device management process in the previous execution selection process (step S1000), and the variable display of the special symbol is not performed. In the jackpot variable winning device management process, until the first winning opening solenoid 90 or the second winning opening solenoid 97 counts the number of balls entered for a certain period of time (for example, 29 seconds or 0.1 seconds or 10 game balls). ), Excited over a preset number of continuous operations (for example, 15 times), whereby the first variable winning device 30 or the second variable winning device 31 opens and closes in a predetermined pattern (continuous operation of the special electric accessory). .. During this period, by intensively winning the game balls to the first variable winning device 30 and the second variable winning device 31, the player is given an opportunity to collectively win a large number of prize balls (special game). Execution means). The opening and closing operation of the first variable winning device 30 and the second variable winning device 31 at the time of a big hit is called a "round", and if the number of continuous operations is 15 times in total, these are called "15 rounds". May be generically referred to.

Further, when the main control CPU 72 sets the big winning opening opening pattern (number of rounds, number of opening / closing operations per round, opening time, etc.) in the big hit variable winning device management process, the first variable winning device 30 for one round Alternatively, the value of the round number counter is incremented by 1 each time the opening / closing operation of the second variable winning device 31 is completed. The value of the round number counter is stored in the count area of the RAM 76, for example, with the initial value set to 0. Further, the main control CPU 72 generates a round number command indicating the value of the round number counter. The round number command is transmitted to the effect control device 124 in the subcommand transmission process (step S144 in FIG. 18). When the value of the round number counter reaches the set number of continuous operations, the main control CPU 72 ends the jackpot game (major role) only for that round.

Then, when the jackpot game is completed, the main control CPU 72 hits the jackpot based on the game status flag (probability fluctuation function activation flag, time reduction function activation flag) related to the internal state different from the gaming machine status flag used when changing the setting or the like. Change the state after the end of the game (high probability state, time reduction state) (high probability time reduction state transition means, advantageous game state transition means). In the "high probability state", the probability fluctuation function is activated, and the winning probability in the internal lottery becomes, for example, about 10 times higher than usual (specific game state transition means, high probability state transition means, high probability state setting means). Further, in the "time reduction state", the time reduction function is activated, the operation lottery of the normal symbol becomes high probability as described above, the fluctuation time of the normal symbol is shortened, and the opening time of the variable start winning device 28 is reduced. Is extended and the number of times of opening increases (so-called electric chew support is performed). It should be noted that the "high probability state" and the "time reduction state" may be shifted to only one of them in terms of control, or may be shifted according to both of them.

Step S6000: The variable winning device management process at the time of a small hit is selected when the special symbol is stopped and displayed in the small hit mode in the previous process during the special symbol stop display. For example, when the special symbol is stopped and displayed in the mode of small hit, an opportunity occurs to shift from the normal state up to that point to the small hit game state. During the small hit game, the jump destination is set in the small hit variable winning device management process in the previous execution selection process (step S1000), and the variable display of the special symbol is not performed. In the small hit game, although the first variable winning device 30 opens and closes a predetermined number of times (for example, twice) in a predetermined opening time (for example, 0.1 seconds), most of the winnings in the first big winning opening occur. do not.

[Multiple winning types]
In the present embodiment, for example, the following winning types are provided as a plurality of winning types.
(1) "11 round probability variation jackpot 1-11"
(2) "15 rounds probability variation jackpot 1-6"
(3) "8 round probability change jackpot"
(4) "6 round probability change jackpot"
(5) "11 rounds normal jackpot"
(6) "3 round probability change jackpot"
(7) "5 round probability change jackpot"
(8) "5 rounds normal jackpot"

The above-mentioned winning types correspond to the types of the first special symbol or the second special symbol that are stopped and displayed at the time of winning. For example, "11 round probability variation jackpot 1 to 11" corresponds to the jackpot of "11 round probability variation symbol 1 to 11", and "11 round normal jackpot" corresponds to the jackpot of "11 round normal symbol". Therefore, in the following, the "winning type" will be appropriately referred to as the "winning symbol".

[11 round probability variation symbols 1 to 11]
In the above-mentioned special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "11 round probability variation symbols 1 to 11", the jackpot game is executed (special game execution means). In this case, the first large winning opening of the first variable winning device 30 is opened once, and this continues until the eleventh round. When it corresponds to "11 round probability variation symbols 1 to 11", it shifts to the "high probability time reduction state" by activating the "probability fluctuation function" and the "time reduction function" after the end of the big hit game.

Here, the first major winning opening of the first variable winning device 30 is closed without waiting for the lapse of the longest opening time when a specified number of winnings (for example, 10 times = 10 game balls) occur in one round. Will be done. Similarly, when the second large winning opening of the second variable winning device 31 wins a specified number of times (for example, 10 times = 10 game balls) in one round, the longest opening time does not have to wait. It will be closed.

[15 round probability variation symbols 1 to 7] In the above processing during the special symbol stop display, when the special symbol is stopped and displayed in the mode of "15 round probability variation symbols 1 to 7", the jackpot game is executed (special game execution). means). In this case, the first large winning opening 30b of the first variable winning device 30 or the second large winning opening 31b of the second variable winning device 31 is opened once, and this continues until the 15th round. When it corresponds to "15 round probability variation symbols 1 to 7", it shifts to the "high probability time reduction state" by activating the "probability fluctuation function" and the "time reduction function" after the jackpot game is completed.

[8-round probability variation symbol] In the above-mentioned special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "8-round probability variation symbol", the jackpot game is executed (special game execution means). In this case, the first large winning opening 30b of the first variable winning device 30 is opened once, and this continues until the eighth round. When it corresponds to the "8-round probability variation symbol", it shifts to the "high probability time reduction state" by activating the "probability fluctuation function" and the "time reduction function" after the jackpot game is completed.

[6 round probability variation symbol] In the above special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "6 round probability variation symbol", the jackpot game is executed (special game execution means). In this case, the first large winning opening 30b of the first variable winning device 30 is opened once, and this continues until the sixth round. When it corresponds to the "6 round probability variation symbol", it shifts to the "high probability time reduction state" by activating the "probability fluctuation function" and the "time reduction function" after the jackpot game is completed.

[11-round normal symbol] In the above-mentioned special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "11-round normal symbol", the jackpot game is executed (special game execution means). In this case, the first large winning opening 30b of the first variable winning device 30 is opened once, and this continues until the 11th round. If it corresponds to "11 rounds normal", the "low probability time reduction state" is entered by activating the "time reduction function" after the jackpot game is completed.

[Three-round probability variation symbol] In the above-mentioned special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "three-round probability variation symbol", the jackpot game is executed (special game execution means). In this case, the second large winning opening 31b of the second variable winning device 31 is opened once, and this continues until the third round. When it corresponds to the "three-round probability variation symbol", it shifts to the "high probability time reduction state" by activating the "probability fluctuation function" and the "time reduction function" after the jackpot game is completed.

[5-round probability variation symbol] In the above-mentioned special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "5-round probability variation symbol", the jackpot game is executed (special game execution means). In this case, the second large winning opening 31b of the second variable winning device 31 is opened once, and this continues until the fifth round. When it corresponds to the "5-round probability variation symbol", it shifts to the "high probability time reduction state" by activating the "probability fluctuation function" and the "time reduction function" after the jackpot game is completed.

[5-round normal symbol] In the above-mentioned special symbol stop display processing, when the special symbol is stopped and displayed in the mode of "5-round normal symbol", the jackpot game is executed (special game execution means). In this case, the second large winning opening 31b of the second variable winning device 31 is opened once, and this continues until the fifth round. If it corresponds to "5 rounds normal", the "low probability time reduction state" is entered by activating the "time reduction function" after the jackpot game is completed.

In any case, if the winning symbol corresponds to any of the "probability variation symbols", the player is given the privilege of shifting the internal state to the "high probability time shortened state" after the jackpot game ends. On the other hand, if the winning symbol corresponds to any of the "normal symbols", the internal state shifts to the "low probability time shortened state" after the jackpot game ends.

The opening time, inter-round interval time, and ending time during the jackpot game are the same "5.0 seconds", "1.5 seconds", and "7.0 seconds", respectively. The opening time is the waiting time from the start of the big hit game to the opening of the big winning opening, and the inter-round interval time is the waiting time set between the rounds and the ending. The time is a waiting time set after the final round of the jackpot game is completed.

[Small hit]
Further, in the present embodiment, a small hit is provided as a winning type other than the non-winning. When a small hit is won, a small hit game is performed separately from the big hit game, and the first variable winning device 30 opens and closes (special game execution means). That is, in the above processing during the special symbol stop display, when the first special symbol is stopped and displayed in the small hit mode, the small hit game (the first variable winning device 30 operates) in the normal probability state or the high probability state. The game to be played) is executed. In such a small hit game, the first variable winning device 30 opens and closes a predetermined number of times (for example, twice), but the winning of the first large winning opening is hardly generated. In addition, even if the small hit game is completed, the "probability fluctuation function" does not operate and the "time reduction function" does not operate, so that the state shifts to the "high probability state" or the "time reduction state". No benefits are granted (it is not a prerequisite for this). Also, even if you win a small hit in the "high probability state", the "high probability state" does not end after the end of the small hit game, and even if you win the small hit in the "time reduction state", the small hit The "time reduction state" does not end after the winning game ends (except when the maximum number of times is reached). In the present embodiment, the game specification is such that a small hit is set, but it is also possible to use a game specification in which a small hit is not set.

[Special symbol change pre-processing]
FIG. 36 is a flowchart showing a procedure example of the special symbol change preprocessing. Hereinafter, each procedure will be described.

Step S2100: First, the main control CPU 72 confirms whether or not the first special symbol operation memory number or the second special symbol operation memory number remains (is greater than 0). This confirmation can be performed by referring to the value of the working memory counter stored in the RAM 76. When the number of working memories of both the first special symbol and the second special symbol is 0 (No), the main control CPU 72 executes the demo setting process of step S2500.

Step S2500: In this process, the main control CPU 72 generates a demo effect command. The demo effect command is output to the effect control device 124 in the subcommand transmission process (step S144 in FIG. 18). When the demo setting process is executed, the main control CPU 72 returns to the special game management process. When returning, it returns to the end address as described above (the same applies thereafter).

On the other hand, if the value of the working memory counter of either the first special symbol or the second special symbol is larger than 0 (Yes), the main control CPU 72 then executes step S2200.

Step S2200: The main control CPU 72 executes the special symbol storage area shift process. In this process, the main control CPU 72 preferentially reads out the lottery random numbers (big hit determination random number, big hit symbol random number) stored in the random number storage area of the RAM 76, which corresponds to the second special symbol. At this time, if random numbers are stored in two or more sections, the main control CPU 72 reads the random numbers in order from the first section, erases (consumes) them, and then moves (shifts) the remaining random numbers one by one to the previous section. ). The read random number is stored in another temporary storage area, for example. When the random number corresponding to the second special symbol is not stored, the main control CPU 72 reads out the random number corresponding to the first special symbol and stores it in the temporary storage area. Each random number stored in the temporary storage area is used for the internal lottery in the next jackpot determination process. As a result, in the present embodiment, the variable display of the second special symbol is given priority over the first special symbol. It should be noted that the program may simply read out random numbers in the order in which they are stored, without setting priorities for each special symbol. Further, in this process, the main control CPU 72 subtracts and subtracts one value of the working memory counter (the first special symbol or the second special symbol that shifts the random number) stored in the RAM 76. The latter value is set to "the number of working memories at the start of fluctuation". As a result, the display mode of the number of stored numbers by the first special symbol operation storage lamp 34a or the second special symbol operation storage lamp 35a is changed (decreased by 1). After completing the steps up to this point, the main control CPU 72 then executes step S2300.

Step S2300: The main control CPU 72 executes a jackpot determination process (internal lottery). In this process, the main control CPU 72 first sets a range of jackpot values, and determines whether or not the read random value is included in this range (lottery execution means). The jackpot value range set at this time differs between the normal probability state and the high probability state (when the probability fluctuation function is activated), and in the high probability state, the jackpot value range is expanded by about 10 times compared to the normal probability state. To. Then, if the random number value read at this time is included in the range of the jackpot value, the main control CPU 72 sets the jackpot flag (01H), and then proceeds to step S2400. Here, the range of the jackpot value is set according to the set value. Therefore, the range of the jackpot value is wider in the high setting than in the low setting.

When the above jackpot flag is not set, the main control CPU 72 next sets a range of small hit values in the same jackpot determination process, and determines whether or not the read random value is included in this range (lottery execution). means). The "small hit" here is something other than non-winning (missing), but has a different property from the "big hit". That is, the "big hit" generates an opportunity (a turning point of the game) to shift to the above-mentioned "high probability state" or "time reduction state", but the "small hit" does not generate such an opportunity. However, the "small hit" is positioned as satisfying the condition for operating the first variable winning device 30 as in the "big hit". The range of the small hit value set at this time may be different or the same between the normal probability state and the high probability state (when the probability fluctuation function is activated). In any case, if the read random number value is included in the small hit value range, the main control CPU 72 sets the small hit flag, and then proceeds to step S2400. As described above, in the present embodiment, the range of the big hit value and the small hit value is defined in advance in the program as the hit range corresponding to other than the non-winning, but the big hit judgment table and the small hit judgment table for each state are previously defined. Each of them may be written in the ROM 74, read out, and the big hit determination may be performed while comparing with the random number value. When a setting difference is provided for the winning probability of a small hit, the range of the small hit value is set according to the set value. Therefore, the range of the small hit value is wider in the high setting than in the low setting.

Step S2400: The main control CPU 72 determines whether or not a value (01H) has been set in the jackpot flag in the previous jackpot determination process. If the value (01H) is not set in the jackpot flag (No), the main control CPU 72 then executes step S2402.

Step S2402: The main control CPU 72 determines whether or not a value (01H) has been set in the small hit flag in the previous big hit determination process. If the small hit flag is not set to the value (01H) (No), the main control CPU 72 then executes step S2404. The main control CPU 72 may determine a big hit (for example, 01H is set) or a small hit (for example, 0AH is set) according to the value of the common hit flag without preparing the big hit flag and the small hit flag separately.

Step S2404: The main control CPU 72 executes a stop symbol determination process at the time of disconnection. In this process, the main control CPU 72 sets the stop symbol number data at the time of disconnection by the first special symbol display device 34 or the second special symbol display device 35. Further, the main control CPU 72 generates a stop symbol command and a lottery result command (at the time of loss) for transmission to the effect control device 124. These commands are transmitted to the effect control device 124 in the subcommand transmission process (step S144 in FIG. 18).

In this embodiment, since the 7-segment LED is used for the first special symbol display device 34 and the second special symbol display device 35, for example, the display mode of the stop symbol at the time of disconnection is always one segment (center). Only the lighting display of the bar "-") can be set, and the stop symbol number data can be fixed to one value (for example, 64H). In this case, the storage capacity used in the program can be reduced, the processing load of the main control CPU 72 can be reduced, and the processing speed can be improved.

Step S2405: Next, the main control CPU 72 executes the disconnection pattern determination process. In this process, the main control CPU 72 determines the variation pattern number at the time of disconnection for the special symbol (variation pattern selection means). The fluctuation pattern number distinguishes the type (pattern) of the fluctuation display of the special symbol, and corresponds to the fluctuation time required for the fluctuation display. Since the fluctuation time at the time of disconnection differs depending on whether or not it is in the above-mentioned "time reduction state", the main control CPU 72 loads the game state flag in this process, and the current state is in the "time reduction state". Check if it exists. In the "time shortened state", the fluctuation time at the time of disconnection is basically set to the shortened time (for example, about 2.0 seconds) except when the reach fluctuation is performed (reduced fluctuation time determining means). ). Further, even if it is not in the "time shortened state", the fluctuation time at the time of disconnection is based on, for example, the "number of working memories at the start of fluctuation display (0 to 3)" set in step S2200, except when the reach fluctuation is performed. It may be shortened (for example, the number of working memories at the start of variable display is 0 → about 12.5 seconds, the number of working memories at the start of variable display is about 1 → about 8 seconds, the number of working memories at the start of variable display is 2 → 5). About seconds, the number of working memories at the start of fluctuation display is 3 → about 2.5 seconds). It should be noted that the stop display time of the symbol at the time of detachment is constant (for example, about 0.5 seconds) regardless of the fluctuation pattern. The main control CPU 72 sets the value of the determined fluctuation time (at the time of disconnection) in the fluctuation timer, and sets the value of the stop display time at the time of disconnection in the stop symbol display timer. Information about the fluctuation pattern of the selected special symbol is transmitted to the effect control device as a fluctuation pattern command (the same applies at the time of winning).

In the present embodiment, when a non-winning result is obtained as a result of the internal lottery, control is performed such that, for example, a "reach effect" is generated and the result is lost, or a "reach effect" is not generated and the player is lost. It is supposed to be. Then, in the "difference pattern selection table at the time of loss", fluctuation patterns corresponding to a plurality of types of effects, for example, "non-reach effect" and "reach effect", are defined in advance, and if non-winning is applicable, the variation pattern is defined in advance. One of the fluctuation patterns will be selected from the inside. The reach production includes various reach productions such as a normal reach production, a long reach production, and a super reach production.

[Example of variation pattern selection table at the time of loss]
FIG. 37 is a diagram showing an example of a variation pattern selection table (low-probability / high-probability non-time reduction state) at the time of loss.
This selection table is a table used at the time of loss (when it corresponds to non-winning) in the low-probability or high-probability non-time reduction state (variation pattern defining means). Further, this selection table has a structure in which, for example, a "comparison value" and a "variation pattern number" are stored as a set of 1 byte each in order from the start address. The "comparison value" includes, for example, eight stepwise different values "101", "201", "211", "221", "231", "241", "251", and "255 (FFH)". It is provided, and "1" to "8" of "variation pattern number" are assigned to each "comparison value".

The fluctuation pattern numbers "1" to "5" correspond to the fluctuation patterns that are out of reach without the reach effect being performed, and the fluctuation pattern numbers "6" and "7" are the fluctuation patterns that are out of reach after reach. Corresponding, the fluctuation pattern number "8" corresponds to the fluctuation pattern that is out of alignment after super reach. The fluctuation pattern selection table may have different table contents depending on the number of working memories at the start of fluctuation (hereinafter, the same applies).

Here, the length of the set fluctuation time differs greatly between the non-reach fluctuation pattern and the reach fluctuation pattern. That is, the "non-reach fluctuation pattern" basically corresponds to a short fluctuation time (for example, about 3.0 seconds to 12.0 seconds depending on the number of working memories), whereas the "reach fluctuation pattern" is It corresponds to a long fluctuation time (for example, about 30 seconds to 150 seconds) that is more than twice that.

Then, the main control CPU 72 compares the acquired fluctuation pattern determination random number value with the "comparison value" in the above fluctuation pattern selection table in order, and if the random number value is equal to or less than the comparison value, the comparison value is used. Select the corresponding variation pattern number (variation pattern determination means). For example, if the fluctuation pattern determination random number value at that time is "190", the main control CPU 72 has the next comparison value "101" because the random number value exceeds the comparison value when compared with the first comparison value "101". 201 ”and the random value are compared. In this case, since the random number value is equal to or less than the comparison value, the main control CPU 72 selects “2” as the corresponding variation pattern number.

FIG. 38 is a diagram showing an example of a variation pattern selection table (low probability time shortened state) at the time of disconnection.
This selection table is a table used at the time of loss (when non-winning is applicable) in the low probability time shortened state (variation pattern defining means). Further, this selection table has a structure in which, for example, a "comparison value" and a "variation pattern number" are stored as a set of 1 byte each in order from the start address. The "comparison value" includes, for example, eight stepwise different values "101", "201", "211", "221", "231", "241", "251", and "255 (FFH)". It is provided, and "21" to "28" of "variation pattern number" are assigned to each "comparison value".

The fluctuation pattern numbers "21" to "25" correspond to the fluctuation patterns that are out of reach without the reach effect being performed, and the fluctuation pattern numbers "26" to "28" are the fluctuation patterns that are out of reach after reach. It corresponds. However, since the fluctuation pattern numbers "21" to "25" are non-reach fluctuations due to time-shortening fluctuations, a shortened fluctuation time (for example, about 2.0 seconds) is set as the fluctuation time in the normal state. ..

The main control CPU 72 compares the acquired fluctuation pattern determination random number value with the “comparison value” in the above fluctuation pattern selection table in order, and if the random number value is equal to or less than the comparison value, it corresponds to the comparison value. Select the variation pattern number (variation pattern determination means). For example, if the fluctuation pattern determination random number value at that time is "190", the main control CPU 72 has the next comparison value "101" because the random number value exceeds the comparison value when compared with the first comparison value "101". 201 ”and the random value are compared. In this case, since the random number value is equal to or less than the comparison value, the main control CPU 72 selects “22” as the corresponding variation pattern number.

FIG. 39 is a diagram showing an example of a variation pattern selection table (high probability time shortened state) at the time of disconnection.
This selection table is a table used at the time of loss (when it corresponds to non-winning) in the high probability time shortened state (variation pattern defining means). Further, this selection table has a structure in which, for example, a "comparison value" and a "variation pattern number" are stored as a set of 1 byte each in order from the start address. The "comparison value" includes, for example, eight stepwise different values "101", "201", "211", "221", "231", "241", "251", and "255 (FFH)". It is provided, and "41" to "48" of "variation pattern number" are assigned to each "comparison value".

The fluctuation pattern numbers "41" to "45" correspond to the fluctuation patterns that are out of reach without the reach effect being performed, and the fluctuation pattern numbers "46" to "48" are the fluctuation patterns that are out of reach after reach. It corresponds. However, the fluctuation pattern numbers "41" to "45" are extremely shortened fluctuation times (for example, about 0.5 seconds) as the fluctuation time in the normal state in order to realize high-speed fluctuation in the high probability time shortened state. Is set.

The main control CPU 72 compares the acquired fluctuation pattern determination random number value with the “comparison value” in the above fluctuation pattern selection table in order, and if the random number value is equal to or less than the comparison value, it corresponds to the comparison value. Select the variation pattern number (variation pattern determination means). For example, if the fluctuation pattern determination random number value at that time is "190", the main control CPU 72 has the next comparison value "101" because the random number value exceeds the comparison value when compared with the first comparison value "101". 201 ”and the random value are compared. In this case, since the random number value is equal to or less than the comparison value, the main control CPU 72 selects “42” as the corresponding variation pattern number.

FIG. 40 is a diagram showing an example of a variation pattern selection table (special section) at the time of disconnection.
This selection table is a table used when a non-winning is applicable in a special section in a high probability time shortened state or a low probability time shortened state (variation pattern defining means). The special section is a section that shifts after the end of the big hit game when it corresponds to "11 round probability variation symbols 1 to 11" or "11 round normal symbol", and when the counter value for variation pattern selection is 1 or more. This is the section that shifts to.

Here, the fluctuation patterns at the time of deviation in the special section of the high probability time shortened state or the low probability time shortened state are all the same fluctuation pattern (the fluctuation time is, for example, about 20 seconds) in order to realize the treasure challenge effect described later. Is set, and in this selection table, one predetermined variation pattern (non-reach special variation pattern 50) is selected.

Therefore, the main control CPU 72 selects “50” as the variation pattern number regardless of the acquired variation pattern determination random number value. The non-reach special fluctuation pattern 50 is a special fluctuation pattern in which the fluctuation time is fixed, and the fluctuation time is not shortened by the number of stored devices.

[See FIG. 36: Special symbol change preprocessing]
The above steps S2404 and S2405 are control procedures when the jackpot determination result is missed (when other than non-winning), but when the determination result is a jackpot (step S2400: Yes) or a small hit (step S2402: Yes). , The main control CPU 72 executes the following procedure. First, the case of a big hit will be described.

Step S2410: The main control CPU 72 executes a jackpot stop symbol determination process (winning type determination means). In this process, the main control CPU 72 determines the type of the winning symbol (stop symbol number at the time of jackpot) for each special symbol (first special symbol or second special symbol) based on the jackpot symbol random number. The relationship between the jackpot symbol random value and the type of winning symbol is defined in advance in the special symbol determination data table (winning type determining means). Therefore, the main control CPU 72 can refer to the jackpot stop symbol selection table in the jackpot stop symbol determination process and determine the type of the winning symbol based on the jackpot symbol random number from the stored contents.

[Winning symbol at the time of big hit]
In this embodiment, as the winning symbols selected at the time of big hit, "11 round probability variation symbols 1 to 11", "15 round probability variation symbols 1 to 6", "8 round probability variation symbol", "6 round probability variation symbol", "11 rounds""Normalsymbol","3 round probability variation symbol", "5 round probability variation symbol", and "5 round probability variation symbol" are prepared. In addition, each winning symbol may further include a plurality of winning symbols. For example, in the case of "11 round probability variation symbol 1", "11 round probability variation symbol 1a", "11 round probability variation symbol 1b", "11 round probability variation symbol 1c", and so on.

Further, in the present embodiment, the selection ratio of the winning symbols selected at the time of the big hit of the internal lottery corresponding to each of the first special symbol and the second special symbol is different. Therefore, the main control CPU 72 distinguishes the winning symbol to be selected depending on whether the result of the jackpot this time corresponds to the first special symbol or the second special symbol.

[First special symbol jackpot stop symbol selection table]
FIG. 41 is a diagram showing a configuration example of the first special symbol jackpot stop symbol selection table. When the result of the current jackpot corresponds to the first special symbol, the main control CPU 72 determines the type of the winning symbol with reference to the first special symbol jackpot stop symbol selection table (winning type defining means).

In the first special symbol jackpot stop symbol selection table, the left column shows the distribution values for each winning symbol, and each distribution value "2", "3", "31", "1", " "10", "2", and "35" correspond to the ratio when the denominator is 100. In the second column from the left, "11 round probability variation symbols 1 to 11", "15 round probability variation symbol 1", "8 round probability variation symbol", "6 round probability variation symbol", corresponding to each distribution value, "11 round normal design" is shown. That is, at the time of the big hit corresponding to the first special symbol, the ratio of selecting "11 round probability variation symbols 1 to 9" is 2/100 (= 2%), and "11 round probability variation symbol 10" is selected. The ratio is 3/100 (= 3%), the ratio of selecting "11 round probability variation symbol 11" is 31/100 (= 31%), and "15 round probability variation symbol 1" is selected. The ratio is 1/100 (= 1%), the ratio of selecting "8 round probability variation symbol" is 10/100 (= 10%), and the ratio of selecting "6 round probability variation symbol". Is 2/100 (= 2%), and the ratio of selecting "11 round normal symbol" is 35/100 (= 35%). The size of each distribution value corresponds to the selection ratio for each winning symbol using the jackpot symbol random number.

Here, the "substantial" in the figure is the number of round games that are long-opened in a big hit game that includes a round game in which the big winning opening is short-opened and a round game in which the big winning opening is long-opened. Is shown. The round game may be executed using the first large winning opening, or may be executed using the second large winning opening. Further, "next time" in the figure means that "10000 times" is set as the probability variation number. A big hit in which the number of rounds and the actual number match indicates that there is no round game that is opened short (only a round game that is opened long).

In any case, when the result of the current jackpot corresponds to the first special symbol, the main control CPU 72 performs a selection lottery based on the jackpot symbol random number, and the selection ratio shown in the first special symbol jackpot stop symbol selection table. Selectively determine the winning symbol with. Further, in the first special symbol jackpot stop symbol selection table, for example, 2-byte command data is defined as a stop symbol command at the time of winning as shown in the third column from the left. The stop symbol command is described by, for example, a combination of MODE value and EVENT value, and among them, the MODE value "B1H" of the upper byte means that the winning symbol this time is selected at the time of the big hit of the first special symbol. Represents. Further, the EVENT values "01H" to "0FH" of the lower byte represent the types of winning symbols corresponding in the selection table, respectively. Therefore, for example, when the result of this big hit corresponds to the first special symbol and "11 round probability variation symbol 1" is selected as the winning symbol, the stop symbol command at the time of winning is described by "B1H01H". Will be.

As described above, when the main control CPU 72 selects the winning symbol from the stop symbol selection table at the time of the first special symbol jackpot, the main control CPU 72 generates the stop symbol command at that time. The generated stop symbol command is transmitted to the effect control device 124 in the subcommand transmission process. Further, the main control CPU 72 determines the jackpot stop symbol number for the first special symbol based on the selected winning symbol.

In the three columns on the right side of the first special symbol big hit stop symbol selection table, the values of the probability variation number, the time reduction number, and the special variation number given after the end of the jackpot game are shown.

[Probability change count]
In the present embodiment, when any of the probabilistic symbols is applicable, the number of probabilistic changes is given 10,000 times (next time of probabilistic change). On the other hand, if any of the normal symbols is applicable, the probability variation number is not given.

[Time reduction number]
In the present embodiment, when "11 round probability variation symbols 1 to 10", "15 round probability variation symbol 1", "8 round probability variation symbol", and "6 round probability variation symbol" are applicable, the number of time reductions is given 10,000 times ( Probability change next time). In addition, when it corresponds to "11 round probability variation symbol 11", the number of time reductions is given 10 times. In this case, when the probability change for 10 fluctuations (high probability time reduction state) is completed, the state shifts to the latent probability change state (high probability non-time reduction state). In addition, when it corresponds to "11 round probability variation symbol 11" in the latent probability variation state, the time reduction number of times may be given 10000 times (so-called latent continuation is not performed). Further, in the case of corresponding to "11 round normal symbol", the number of time reductions is given 10 times. In this case, when the time reduction for 10 fluctuations (low probability time reduction state) is completed, the state shifts to the normal state (low probability non-time reduction state).

[Number of special fluctuations]
In the present embodiment, when "11 round probability variation symbols 1 to 11" and "11 round normal symbols" are applicable, the number of special fluctuations is set. Specifically, when it corresponds to "11 round probability variation symbol 1", "1 time" is set as the special variation number, and when it corresponds to "11 round probability variation symbol 2", it corresponds to "2 times" as the special variation number. Is set, and such a setting continues until "11 round probability variation symbol 10", and when it corresponds to "11 round probability variation symbol 11" and "11 round normal symbol", "10 times" is set as the number of special fluctuations. Set. In addition, when it corresponds to "15 round probability variation symbol 1", "8 round probability variation symbol", and "6 round probability variation symbol", the number of special fluctuations is not set.

[Second special symbol jackpot stop symbol selection table]
FIG. 42 is a diagram showing a configuration example of the second special symbol jackpot stop symbol selection table. When the result of the current jackpot corresponds to the second special symbol, the main control CPU 72 determines the type of the winning symbol with reference to the second special symbol jackpot stop symbol selection table (winning type defining means).

Also in the second special symbol jackpot stop symbol selection table, the distribution values for each winning symbol are shown in the left column, and the distribution values "33", "4", "3", "6" are shown. , "8", "3", "5", "35" correspond to the ratio when the denominator is 100. Similarly, in the second column from the left, "15 round probability variation symbols 2-7", "3 round probability variation symbol", "5 round probability variation symbol", and "5 round normal symbol" corresponding to the distribution value are shown. ing. That is, at the time of a big hit corresponding to the second special symbol, the ratio of selecting "15 round probability variation symbol 2" is 33/100 (= 33%), and "15 round probability variation symbol 4, 5" is selected. The ratio of each is 3/100 (= 3%), the ratio of selecting "15 round probability variation symbol 6" is 6/100 (= 6%), and the ratio of "15 round probability variation symbol 7" is The selected ratio is 8/100 (= 8%), the ratio of selecting "3 round probability variation symbol" is 3/100 (= 3%), and "5 round probability variation symbol" is selected. The ratio is 5/100 (= 5%), and the ratio of selecting "5 round normal symbol" is 35/100 (= 35%).

When the result of this big hit corresponds to the second special symbol, the main control CPU 72 performs a selection lottery based on the big hit symbol random number, and selects the winning symbol by the selection ratio shown in the second special symbol jackpot stop symbol selection table. To decide. Similarly, in the second special symbol jackpot stop symbol selection table, for example, 2-byte command data is defined as the stop symbol command at the time of winning as shown in the third column from the left. Here, too, the stop symbol command is described by the combination of the above MODE value-EVENT value, and the MODE value "B2H" of the upper byte is the one selected when the winning symbol of this time is the big hit of the second special symbol. It represents that. Further, the EVENT values "01H" to "09H" of the lower byte represent the types of winning symbols corresponding in the selection table, respectively. Therefore, for example, when the result of this big hit corresponds to the second special symbol and "15 round probability variation symbol 2" is selected as the winning symbol, the stop symbol command is described by "B2H01H". Become.

As described above, when the main control CPU 72 selects the winning symbol from the second special symbol jackpot stop symbol selection table, the main control CPU 72 generates a stop symbol command at that time. The generated stop symbol command is transmitted to the effect control device 124 in the subcommand transmission process. Further, the main control CPU 72 determines the jackpot stop symbol number for the second special symbol based on the selected winning symbol.

In the three columns on the right side of the second special symbol big hit stop symbol selection table, the values of the probability variation number, the time reduction number, and the special variation number given after the end of the jackpot game are shown.

[Probability change count]
In the present embodiment, when any of the probabilistic symbols is applicable, the number of probabilistic changes is given 10,000 times (next time of probabilistic change). On the other hand, if any of the normal symbols is applicable, the probability variation number is not given.

[Time reduction number]
In the present embodiment, when the "15 round probability variation symbol 2-7", the "3 round probability variation symbol", and the "5 round probability variation symbol" are applicable, the number of time reductions is given 10,000 times (probability variation next time). On the other hand, if it corresponds to the "5-round normal symbol", the number of time reductions is 100 times (100 times of time reduction). In this case, when the time reduction for 100 fluctuations (low probability time reduction state) is completed, the state shifts to the normal state (low probability non-time reduction state).

[Number of special fluctuations]
In the present embodiment, the number of special fluctuations is not set in the case of winning with the second special symbol.

[See FIG. 36: Special symbol change preprocessing]
Step S2412: Next, the main control CPU 72 executes the jackpot variation pattern determination process. In this process, the main control CPU 72 determines the variation pattern (variation time and stop display time) of the first special symbol or the second special symbol based on the variation pattern determination random number shifted in the previous step S2200. Further, the main control CPU 72 sets the determined value of the fluctuation time in the fluctuation timer, and sets the value of the stop display time in the stop symbol display timer. Generally, in the case of jackpot reach fluctuation, a fluctuation time longer than that at the time of loss is determined.

In the present embodiment, when a big hit is hit as a result of the internal lottery, for example, a "reach effect" is generated in the production to control the big hit. Then, in the "big hit fluctuation pattern selection table", fluctuation patterns corresponding to a plurality of types of "reach effects" are defined, and when a jackpot is hit, one of the fluctuation patterns is selected from among them. It will be. The reach production includes various reach productions such as a normal reach production, a long reach production, and a super reach production. Basically, the super reach production has a longer fluctuation time and the expectation of winning is higher than the reach production such as the normal reach production and the long reach production. Further, at the time of winning in the state where the time reduction function is activated, even if the fluctuation pattern having a short fluctuation time (the fluctuation pattern without the reach effect) is selected without selecting the fluctuation pattern having a long fluctuation time. Good.

[Example of jackpot fluctuation pattern selection table]
FIG. 43 is a diagram showing an example of a jackpot fluctuation pattern selection table (low probability / high probability non-time reduction state).
This selection table is a table used at the time of winning in a low-probability or high-probability non-time reduction state (variation pattern defining means). In the present embodiment, the fluctuation pattern is not distinguished according to the type of jackpot (winning symbol), but a dedicated fluctuation pattern selection table may be used for each jackpot (hereinafter, the same applies). Further, this selection table has a structure in which, for example, a "comparison value" and a "variation pattern number" are stored as a set of 1 byte each in order from the start address. The "comparison value" includes, for example, eight stepwise different values "101", "201", "211", "221", "231", "241", "251", and "255 (FFH)". It is provided, and "61" to "68" of "variation pattern number" are assigned to each "comparison value".

The fluctuation pattern numbers "61" to "66" correspond to the fluctuation patterns that are hit by the super reach effect, and the variation pattern numbers "67" and "68" are the reach effects (other than the super reach effect). Reach production) is performed and it corresponds to the fluctuation pattern that becomes a hit.

The main control CPU 72 compares the acquired fluctuation pattern determination random number value with the “comparison value” in the above fluctuation pattern selection table in order, and if the random number value is equal to or less than the comparison value, it corresponds to the comparison value. Select the variation pattern number (variation pattern determination means). For example, if the fluctuation pattern determination random number value at that time is "190", the main control CPU 72 has the next comparison value "101" because the random number value exceeds the comparison value when compared with the first comparison value "101". 201 ”and the random value are compared. In this case, since the random number value is equal to or less than the comparison value, the main control CPU 72 selects “62” as the corresponding variation pattern number.

FIG. 44 is a diagram showing an example of a jackpot fluctuation pattern selection table (low probability time shortened state).
This selection table is a table used at the time of winning in the low probability time shortened state (variation pattern defining means). Further, this selection table has a structure in which, for example, a "comparison value" and a "variation pattern number" are stored as a set of 1 byte each in order from the start address. The "comparison value" includes, for example, eight stepwise different values "101", "201", "211", "221", "231", "241", "251", and "255 (FFH)". It is provided, and "81" to "88" of "variation pattern number" are assigned to each "comparison value".

The fluctuation pattern numbers "81" to "88" all correspond to fluctuation patterns that are hit by the reach effect.

The main control CPU 72 compares the acquired fluctuation pattern determination random number value with the “comparison value” in the above fluctuation pattern selection table in order, and if the random number value is equal to or less than the comparison value, it corresponds to the comparison value. Select the variation pattern number (variation pattern determination means). For example, if the fluctuation pattern determination random number value at that time is "190", the main control CPU 72 has the next comparison value "101" because the random number value exceeds the comparison value when compared with the first comparison value "101". 201 ”and the random value are compared. In this case, since the random number value is equal to or less than the comparison value, the main control CPU 72 selects “82” as the corresponding variation pattern number.

FIG. 45 is a diagram showing an example of a jackpot fluctuation pattern selection table (high probability time shortened state).
This selection table is a table used at the time of winning in the high probability time shortened state (variation pattern defining means). Further, this selection table has a structure in which, for example, a "comparison value" and a "variation pattern number" are stored as a set of 1 byte each in order from the start address. The "comparison value" includes, for example, eight stepwise different values "101", "201", "211", "221", "231", "241", "251", and "255 (FFH)". It is provided, and "101" to "108" of "variation pattern number" are assigned to each "comparison value".

The fluctuation pattern numbers "101" to "108" all correspond to fluctuation patterns that are hit by the reach effect. It should be noted that, at the time of winning in the high probability time shortened state, a fluctuation pattern that is a hit without the reach effect may be set.

The main control CPU 72 compares the acquired fluctuation pattern determination random number value with the “comparison value” in the above fluctuation pattern selection table in order, and if the random number value is equal to or less than the comparison value, it corresponds to the comparison value. Select the variation pattern number (variation pattern determination means). For example, if the fluctuation pattern determination random number value at that time is "190", the main control CPU 72 has the next comparison value "101" because the random number value exceeds the comparison value when compared with the first comparison value "101". 201 ”and the random value are compared. In this case, since the random number value is equal to or less than the comparison value, the main control CPU 72 selects “102” as the corresponding variation pattern number.

FIG. 46 is a diagram showing an example of a jackpot fluctuation pattern selection table (special section).
This selection table is a table used when a big hit is hit in a special section in a high probability time shortened state or a low probability time shortened state (variation pattern defining means).

Here, the fluctuation patterns at the time of big hit in the special section in the high probability time shortened state or the low probability time shortened state are all the same fluctuation pattern (in order to realize the special winning effect in the treasure challenge production described later). The fluctuation time is set (for example, about 30 seconds), and this selection table has a table configuration for selecting one predetermined fluctuation pattern (special fluctuation pattern 170 per non-reach).

Therefore, the main control CPU 72 selects “170” as the variation pattern number regardless of the acquired variation pattern determination random number value. The special variation pattern 170 per non-reach is a special variation pattern in which the variation time is fixed, and the variation time is not shortened by the number of stored items.

[See FIG. 36: Special symbol change preprocessing]
Step S2414: Next, the main control CPU 72 executes other setting processing at the time of a big hit. In this process, when the type of the winning symbol (stop symbol number at the time of big hit) determined in the previous step S2410 is "any probability variation symbol", the main control CPU 72 sets the value of the probability variation function operation flag as the game state flag ( 01H) is set in the flag area of the RAM 76 (high probability state transition means, probability fluctuation function operating means). Further, when the type of the winning symbol determined in the previous step S2410 is "any of the normal symbols", the main control CPU 72 resets the value of the probability variation function operation flag as the game state flag (low probability state setting means). , Low probability state transition means, probability state setting means).

Further, in the main control CPU 72, even if the type of the winning symbol (stop symbol number at the time of big hit) determined in the previous step S2410 is "any winning symbol", the main control CPU 72 serves as a game state flag and a time reduction function operation flag. (01H) is set in the flag area of the RAM 76 (time reduction state transition means, time reduction function operating means).

Further, in the process of step S2414, the main control CPU 72 determines the display mode of the stop symbol (big hit symbol) by the first special symbol display device 34 or the second special symbol display device 35 based on the jackpot stop symbol number. At the same time, the main control CPU 72 generates a lottery result command (at the time of big hit) together with the above-mentioned stop symbol command (at the time of big hit). These stop symbol commands and lottery result commands are transmitted to the effect control device 124 in the subcommand transmission process.

Next, the processing at the time of a small hit will be described.
Step S2407: The main control CPU 72 executes a small hit stop symbol determination process. In this process, the main control CPU 72 determines the type of winning symbol at the time of small hit (stop symbol number at the time of small hit) based on the random number of the big hit symbol. Here as well, the relationship between the big hit symbol random value and the type of winning symbol at the time of small hit is defined in advance in the special symbol selection table at the time of small hit (winning type defining means). In the present embodiment, the winning symbol at the time of small hit is determined by using the big hit symbol random number in order to reduce the load on the main control CPU 72, but a dedicated random number may be used separately.

[Winning symbol at the time of small hit]
In the present embodiment, there is only one type of winning symbol at the time of small hit, "double open small hit symbol". However, in addition to this, another type such as "1 time open small hit symbol" or "3 times open small hit symbol" may be prepared. As mentioned above, the "small hit" as a result of the internal lottery does not trigger the subsequent state to change to the "high probability state" or the "time reduction state", so it is essential for this type of pachinko machine. It is possible to provide a "one-time open small hit symbol" without being bound by the "two rounds (two-time opening) or more" rule.

Step S2408: Next, the main control CPU 72 executes the small hit time variation pattern determination process. In this process, the main control CPU 72 determines the variation pattern (variation time and stop display time) of the first special symbol or the second special symbol based on the variation pattern determination random number shifted in the previous step S2200 (variation pattern selection means). ). Further, the main control CPU 72 sets the determined value of the fluctuation time in the fluctuation timer, and sets the value of the stop display time in the stop symbol display timer. In the present embodiment, the reach fluctuation pattern can be selected in the case of a small hit, or the fluctuation pattern equivalent to that in the case of a normal fluctuation can be selected.

Step S2409: Next, the main control CPU 72 executes other setting processing at the time of small hit. In this process, the main control CPU 72 determines the display mode of the stop symbol (small hit symbol) by the first special symbol display device 34 or the second special symbol display device 35 based on the small hit stop symbol number. At the same time, the main control CPU 72 generates a stop symbol command and a lottery result command (at the time of small hit) to be transmitted to the effect control device 124. These stop symbol commands and lottery result commands are transmitted to the effect control device 124 in the subcommand transmission process.

Step S2415: Next, the main control CPU 72 executes a special symbol variation start process. In this process, the main control CPU 72 selects fluctuation pattern data based on the fluctuation pattern number (at the time of loss / at the time of hit). At the same time, the main control CPU 72 sets the fluctuation start flag of the special symbol in the flag area of the RAM 76. Then, the main control CPU 72 generates a fluctuation start command to be transmitted to the effect control device 124. This fluctuation start command is transmitted to the effect control device 124 in the subcommand transmission process. When the above procedure is completed, the main control CPU 72 sets the special symbol changing process (step S3000) as the next jump destination, and returns to the special game management process.

[Fig. 35: Processing during special symbol change, processing during special symbol stop display]
In the special symbol fluctuation processing, the main control CPU 72 loads the value of the fluctuation timer from the register to the timer counter as described above, and then the timer counter according to the passage of time (the count number of clock pulses or the value of the interrupt counter). Decrement the value of. Then, the main control CPU 72 controls the fluctuation display of the special symbol as described above until the value becomes 0 while referring to the value of the timer counter. Then, when the value of the timer counter becomes 0, the main control CPU 72 sets the special symbol stop display process (step S4000) as the next jump destination.

Further, in the special symbol stop display processing, the main control CPU 72 controls the stop display of the special symbol based on the stop symbol determined in the stop symbol determination process (step S2404, step S2407, step S2410 in FIG. 36). Further, the main control CPU 72 generates a symbol stop command to be transmitted to the effect control device 124. The symbol stop command is transmitted to the effect control device 124 in the subcommand transmission process. When the stopped symbol is displayed for a predetermined time in the special symbol stop display processing, the main control CPU 72 erases the symbol changing flag.

[Disappearance fluctuation pattern determination processing]
FIG. 47 is a flowchart showing a procedure example of the deviation pattern determination process. Hereinafter, each procedure will be described.

Step S2600: The main control CPU 72 loads the fluctuation pattern selection counter value from the RAM 76, and confirms whether or not the fluctuation pattern selection counter value is larger than “0”. The “counter value for selecting a fluctuation pattern” is a counter value managed by the main control CPU 72, and is a variable to be referred to when executing a special fluctuation. The fluctuation pattern selection counter value is set in the special fluctuation number setting process (FIG. 57) described later.

As a result, when it is confirmed that the fluctuation pattern selection counter value is larger than "0" (Yes), the main control CPU 72 executes step S2606. On the other hand, when it is confirmed that the fluctuation pattern selection counter value is not larger than "0", that is, when it is confirmed that the fluctuation pattern selection counter value is "0" (No), the main control The CPU 72 executes step S2602.

Note that when the fluctuation pattern selection counter value is larger than "0", it means that special fluctuation is executed, and when the fluctuation pattern selection counter value is "0", special fluctuation is performed. It means not to do it.

Step S2602: The main control CPU 72 confirms whether or not the internal state is a high probability time shortened state. The internal state can be confirmed by the probability fluctuation function operation flag and the time reduction function operation flag (hereinafter, the same applies).

As a result, when it is confirmed that the internal state is the high probability time shortened state (Yes), the main control CPU 72 executes step S2608. On the other hand, when it cannot be confirmed that the internal state is the high probability time shortened state, the main control CPU 72 executes step S2604.

Step S2604: The main control CPU 72 confirms whether or not the internal state is the low probability time shortened state.

As a result, when it is confirmed that the internal state is the low probability time shortened state (Yes), the main control CPU 72 executes step S2610. On the other hand, when it cannot be confirmed that the internal state is the low probability time shortened state, the main control CPU 72 executes step S2612.

Step S2606: The main control CPU 72 executes a process of determining the fluctuation pattern with reference to the deviation pattern selection table (FIG. 40) for the special section.
Step S2608: The main control CPU 72 executes a process of determining the fluctuation pattern with reference to the out-of-time fluctuation pattern selection table (FIG. 39) for the high probability time shortened state.

Step S2610: The main control CPU 72 executes a process of determining the variation pattern with reference to the out-of-date variation pattern selection table (FIG. 38) for the low probability time shortened state.
Step S2612: The main control CPU 72 executes a process of determining the variation pattern with reference to the out-of-time variation pattern selection table (FIG. 37) for the non-time reduction state (low probability / high probability non-time reduction state).
When the above procedure is completed, the main control CPU 72 returns to the special symbol change preprocessing (FIG. 36).

[Big hit fluctuation pattern determination process]
FIG. 48 is a flowchart showing a procedure example of the jackpot fluctuation pattern determination process. Hereinafter, each procedure will be described.

Step S2710: The main control CPU 72 loads the fluctuation pattern selection counter value from the RAM 76, and confirms whether or not the fluctuation pattern selection counter value is larger than “0”.

As a result, when it is confirmed that the fluctuation pattern selection counter value is larger than "0" (Yes), the main control CPU 72 executes step S2716. On the other hand, when it is confirmed that the fluctuation pattern selection counter value is not larger than "0", that is, when it is confirmed that the fluctuation pattern selection counter value is "0" (No), the main control The CPU 72 executes step S2712.

Step S2712: The main control CPU 72 confirms whether or not the internal state is the high probability time shortened state.

As a result, when it is confirmed that the internal state is the high probability time shortened state (Yes), the main control CPU 72 executes step S2718. On the other hand, when it cannot be confirmed that the internal state is the high probability time shortened state, the main control CPU 72 executes step S2714.

Step S2714: The main control CPU 72 confirms whether or not the internal state is the low probability time shortened state.

As a result, when it is confirmed that the internal state is the low probability time shortened state (Yes), the main control CPU 72 executes step S2720. On the other hand, when it cannot be confirmed that the internal state is the low probability time shortened state, the main control CPU 72 executes step S2722.

Step S2716: The main control CPU 72 executes a process of determining the fluctuation pattern with reference to the jackpot fluctuation pattern selection table (FIG. 46) for the special section.
Step S2718: The main control CPU 72 executes a process of determining the fluctuation pattern with reference to the jackpot fluctuation pattern selection table (FIG. 45) for the high probability time shortened state.

Step S2720: The main control CPU 72 executes a process of determining the fluctuation pattern with reference to the jackpot fluctuation pattern selection table (FIG. 44) for the low probability time shortened state.
Step S2720: The main control CPU 72 refers to the jackpot variation pattern selection table (FIG. 43) for the non-time reduction state, and executes a process of determining the variation pattern.

When the above procedure is completed, the main control CPU 72 returns to the special symbol change preprocessing (FIG. 36).

[Special symbol storage area shift processing]
FIG. 49 is a flowchart showing a procedure example of the special symbol storage area shift process. In the previous special symbol change preprocessing, when the value of the operation storage counter corresponding to the first special symbol or the second special symbol is larger than "0" (step S2100: Yes in FIG. 36), the main control CPU 72 Executes this special symbol storage area shift process. Hereinafter, each procedure will be described.

Step S2210: The main control CPU 72 confirms whether or not the operation memory corresponding to the second special symbol remains. This confirmation can be performed by referring to the value of the second special symbol operation storage number counter stored in the RAM 76. When the value of the working memory counter corresponding to the second special symbol is 1 or more (Yes), the main control CPU 72 then proceeds to step S2212.

Step S2212: The main control CPU 72 designates a second special symbol as a special symbol to be shifted in the storage area. This designation is performed, for example, by setting "02H" as the target symbol designation value.

Step S2214: On the other hand, when the value of the working memory counter corresponding to the second special symbol is 0 (step S2210: No), the main control CPU 72 designates the first special symbol as the special symbol to be shifted in the storage area. To do. The designation in this case is performed, for example, by setting "01H" as the target symbol designation value.

Step S2216: The main control CPU 72 shifts the random number storage area of the RAM 76 with respect to the target special symbol specified in either step S2212 or step S2214. The specific contents of the processing are as described in the previous special symbol change preprocessing.

Step S2218: Next, the main control CPU 72 subtracts the value of the working memory counter for the target special symbol. For example, if the target for shifting the storage area this time is the second special symbol, the main control CPU 72 subtracts (-1) the value of the working memory counter corresponding to the second special symbol.

Step S2220: Then, the main control CPU 72 sets the “number of working memories at the start of fluctuation” from the value of the working memory counter after subtraction. Here, for both the first special symbol and the second special symbol, the "working memory number at the start of fluctuation" may be set after adding the values of the working memory counters.

Step S2222: Further, the main control CPU 72 confirms whether or not the special symbol to be shifted the storage area this time is the second special symbol.
Step S2224: When the target is the second special symbol (step S2222: Yes), the main control CPU 72 sets the operation memory number reduction effect command for the second special symbol. The effect command set here is also generated as a one-word length command, but its configuration is in contrast to the above-mentioned "effect command when the number of working memories is increased". That is, the effect command when the number of working memories is reduced is the value of the lower byte (for example, "00H" to "03H") indicating the number of working memories after the reduction with respect to the preceding value (for example, "BCH") of the upper byte indicating the command type. ”) Is added, and the value of the lower byte is further added (logically) with an additional value (for example,“ 10H ”) meaning “decrease in the number of working memories due to consumption”. Therefore, for the lower byte, the second digit becomes "1" by ORing the added value "10H", and this value indicates that it is the "result (change information) due to the decrease in the number of working memories". It becomes a thing. In other words, if the lower byte of the command is "13H", it means that the number of working memories "4" (command notation is "14H") up to the previous time is reduced by one, and as a result, the number of working memories this time is "3" (command). The notation indicates that it has become "13H"). Similarly, if the lower byte is "12H" to "10H", it is the result of one decrease in the number of working memories "3" to "1" (command notation is "13H" to "11H") up to the previous time. , It means that the number of working memories this time is "2" to "0" (command notation is "12H" to "10H"). The above-mentioned preceding value "BCH" is a value indicating that the current effect command is a working memory number command for the second special symbol.

Step S2226: When the target of this time is the first special symbol (step S2222: No), the main control CPU 72 sets the operation memory number reduction effect command for the first special symbol. The command in this case is the same as the above except that the preceding value is a value (for example, "BBH") indicating that it is a working memory number command for the first special symbol.

Step S2228: Then, the main control CPU 72 executes the effect command output process. This process is for transmitting the operation memory number reduction effect command set in step S2224 or step S2226 to the effect control device 124 (memory number notification means).
When the above procedure is completed, the main control CPU 72 returns to the special symbol change preprocessing (FIG. 36).

[Processing during special symbol stop display]
FIG. 50 is a flowchart showing an example of a procedure for processing during special symbol stop display. Hereinafter, each procedure will be described.

Step S4100: The main control CPU 72 subtracts the value of the stop symbol display timer (decrements by the interrupt cycle).

Step S4200: Then, the main control CPU 72 determines whether or not the stop display time has expired based on the value of the stop symbol display timer subtracted this time. Specifically, if the value of the stop symbol display timer is not 0 or less, the main control CPU 72 determines that the stop display time has not ended (No). In this case, the main control CPU 72 returns to the special game management process, jumps from the execution selection process (step S1000 in FIG. 35) in the next interrupt cycle, and repeatedly executes the process during the special symbol stop display.

On the other hand, if the value of the stop symbol display timer is 0 or less, the main control CPU 72 determines that the stop display time has ended (Yes). In this case, the main control CPU 72 then executes step S4250.

Step S4250: The main control CPU 72 generates a symbol stop command and a stop display time end command. The symbol stop command and the stop display time end command are transmitted to the effect control device 124 in the subcommand transmission process. Further, the main control CPU 72 erases the symbol changing flag here. The "stop display time end command" is a command indicating that the stop display time of the special symbol has ended (elapsed).

Step S4300: Here, the main control CPU 72 confirms whether or not the value of the jackpot flag (01H) is set. When the value of the jackpot flag (01H) is set (Yes), the main control CPU 72 then executes step S4350.

[At the time of winning]
Step S4350: The main control CPU 72 sets the jump destination of the jump table to the "big hit variable winning device management process". The main control CPU 72 executes a process of setting various functions to be inactive in this process. Specifically, the probability fluctuation function is deactivated and the time saving function is deactivated. As a result, before the special game (major role) is started, the state is shifted to the low probability non-time reduction state.

Step S4400: Then, the main control CPU 72 sets "start of big win (during big hit game)" as an internal state flag on control. Further, the main control CPU 72 sets the value of the continuous operation number status according to the type of the jackpot symbol. For example, when the type of jackpot is "15 round jackpot", the value corresponding to "15 rounds" is set in the continuous operation count status. When the type of jackpot is "3 round jackpot", a value representing "3 rounds" is set in the continuous operation count status. In addition, the main control CPU 72 generates a state command indicating that the jackpot is in progress. The state command indicating that the jackpot is in progress is transmitted to the effect control device 124 in the subcommand transmission process.

Step S4500: Then, the main control CPU 72 generates a continuous operation number command. The continuous operation number command can be generated based on the type (stop symbol number) of the jackpot symbol determined in the previous jackpot stop symbol determination process (step S2410 in FIG. 36). For example, when the type of jackpot is "15 rounds jackpot", the continuous operation count command is generated as a value representing "15 rounds". When the jackpot type is "3 round jackpot", the continuous operation count command is generated as a value representing "3 rounds". The generated continuous operation number command is transmitted to the effect control device 124 in the subcommand transmission process.

When the above procedure is completed at the time of the jackpot, the main control CPU 72 returns to the special game management process.

[When not winning]
On the other hand, the following procedure is executed except at the time of big hit.
That is, when the main control CPU 72 determines in step S4300 that the value of the jackpot flag (01H) is not set (No), the main control CPU 72 then executes step S4600.

Step S4600: The main control CPU 72 next confirms whether or not the value of the small hit flag (01H) is set. Then, when the value of the small hit flag (01H) is not set and it is simply out of alignment (No), the main control CPU 72 then executes step S4602.

Step S4602: The main control CPU 72 sets the address of the special symbol change preprocessing as the jump destination address of the jump table.

Step S4605: On the other hand, when the value of the small hit flag (01H) is set (step S4600: Yes), the main control CPU 72 sets the address of the small hit variable winning device management process as the jump destination address of the jump table. set.

Step S4606: Then, the main control CPU 72 sets "small hit start (small hit in progress)" as an internal state flag on the control. In addition, the main control CPU 72 generates a state command indicating that a small hit is in progress. The state command indicating that the small hit is in progress is transmitted to the effect control device 124 in the subcommand transmission process.

Step S4608: The main control CPU 72 executes the special variation management process. Specifically, the main control CPU 72 executes a process of managing special fluctuations executed after the end of the jackpot game. The details of the special fluctuation management process will be described later with reference to another drawing.

Step S4610: Next, the main control CPU 72 loads the value of the number-cutting counter. In the "count cut counter", the counter values are set in the probability variation count area and the time reduction count area of the RAM 76 in the "high probability state" and the "time reduction state", respectively. Although "cutting the number of times" is used here, the value of the number cutting counter in the "high probability state" can be set to an extremely huge value (for example, 10,000 times or more). By setting such a huge value, it is possible to stochastically guarantee that the "high probability state" will continue until the next winning is obtained. A value (for example, 10 times, 100 times, 10000 times, etc.) is set for the number-of-times cut counter related to the "time reduction state" according to the winning symbol.

Step S4620: The main control CPU 72 confirms whether or not the loaded counter value is 0. At this time, if the number-of-count counter value is already 0 (Yes), the main control CPU 72 returns to the special game management process. On the other hand, if the number-of-times counter value is not 0 (No), the main control CPU 72 then executes step S4630 after generating the number-of-times counter value command.

Step S4630: The main control CPU 72 decrements (1 subtracts) the number-of-times counter value.
Step S4640: Then, the main control CPU 72 determines whether or not the subtraction result is not 0. As a result of the subtraction, if the value of the number-cut counter is not 0 (Yes), the main control CPU 72 returns to the special game management process. On the other hand, when the value of the number-cut counter becomes 0 (No), the main control CPU 72 proceeds to step S4650.

Step S4650: Here, the main control CPU 72 resets the flag when the number-cutting function is activated. It is the probability fluctuation function activation flag or the time reduction function activation flag that is reset, but since the value of the count-off counter that counts the high probability state in the "high probability state" does not substantially become 0. , It is the time saving function activation flag that is actually reset. As a result, the time reduction state and the high probability state end after the stop display of the special symbol. After completing the above procedure, the process returns to the special game management process.

[Special fluctuation management process]
FIG. 51 is a flowchart showing a procedure example of the special fluctuation management process. Hereinafter, each procedure will be described.

Step S4660: The main control CPU 72 loads the fluctuation pattern selection counter value from the RAM 76, and confirms whether or not the fluctuation pattern selection counter value is larger than “0”.

As a result, when it is confirmed that the fluctuation pattern selection counter value is larger than "0" (Yes), the main control CPU 72 executes step S4662. On the other hand, when it is confirmed that the fluctuation pattern selection counter value is not larger than "0", that is, when the fluctuation pattern selection counter value is "0" (No), the main control CPU 72 has a special symbol. The process returns to the process during stop display (FIG. 50).

Step S4662: The main control CPU 72 executes a process of decrementing (1 subtracting) the fluctuation pattern selection counter value. As a result, the number of times the special variation is executed (the number of times the special variation can be executed) is reduced by one.
When the above procedure is completed, the main control CPU 72 returns to the special symbol stop display processing (FIG. 50).

[Variable winning device management process at the time of big hit]
FIG. 52 is a flowchart showing a configuration example of the variable winning device management process at the time of a big hit.
The jackpot variable winning device management process includes a jackpot game process selection process (step S5100), a jackpot opening pattern setting process (step S5200), a jackpot opening / closing operation process (step S5300), and a jackpot jackpot opening / closing operation process (step S5300). The configuration includes a group of subroutines for the winning opening closing process (step S5400) and the jackpot end processing (step S5500).

Step S5100: In the jackpot game process selection process, the main control CPU 72 selects the jump destination of the process to be executed next (any of step S5200 to step S5500). That is, the main control CPU 72 selects the program address of the process to be executed next from the jump table as the jump destination address, and sets the end of the jackpot variable winning device management process as the return destination address in the stack pointer. Which process is selected as the next jump destination depends on the progress of the processes performed so far. For example, if the operation (opening / closing operation) of the first variable winning device 30 or the second variable winning device 31 has not yet started, the main control CPU 72 sets the big winning opening pattern setting process at the time of a big hit as the next jump destination. (Step S5200) is selected. On the other hand, if the jackpot opening pattern setting process has already been completed, the main control CPU 72 selects the jackpot opening / closing operation process (step S5300) as the next jump destination, and opens / closes the jackpot opening / closing at the time of the jackpot. If the operation process is completed, the jackpot closing process (step S5400) at the time of a big hit is selected as the next jump destination. Further, when the jackpot opening / closing operation processing and the jackpot closing processing are repeatedly executed over the set number of continuous operations (the number of rounds), the main control CPU 72 performs the jackpot end processing as the next jump destination ( Step S5500) is selected. Hereinafter, each process will be described in more detail.

[Large winning opening pattern setting process at the time of big hit]
FIG. 53 is a flowchart showing a procedure example of the large winning opening opening pattern setting process at the time of a big hit. This process is for setting conditions such as the number of times the first variable winning device 30 or the second variable winning device 31 is opened and closed at the time of a big hit and the opening time of each. Hereinafter, each procedure will be described.

Step S5204: The main control CPU 72 executes a symbol-specific open pattern setting process. In this process, the main control CPU 72 determines the opening pattern of the winning opening (the number of opening for each round and the opening time for each round), the interval time between rounds, and the number of counts in one round (maximum) according to the corresponding winning symbol this time. Set the number of winnings), opening time, ending time, etc. The number of counts (maximum number of winnings) in one round is basically about 10, but winnings rarely occur during opening for an extremely short time (about 0.1 seconds) (impossible). It's not, but it's extremely difficult).

Step S5206: The main control CPU 72 sets the number of execution rounds in the current jackpot game based on the winning symbol at the time of the jackpot selected in the previous jackpot stop symbol determination process (step S2410 in FIG. 36). Specifically, if "15 rounds jackpot" is selected as the jackpot type, the main control CPU 72 sets the number of execution rounds to 15. If "3 rounds jackpot" is selected as the jackpot type, the main control CPU 72 sets the number of execution rounds to 3. The number of execution rounds set here is stored in, for example, the buffer area of the RAM 76.

Step S5208: Next, the main control CPU 72 sets the opening timer at the time of a big hit based on the big winning opening opening pattern set in the previous step S5204. The value of the timer set here is the opening time of the first variable winning device 30 or the second variable winning device 31. If a value of about 29.0 seconds is set as the value of the jackpot opening timer, the opening time is a sufficient time for the ball to easily enter the winning opening during one opening (for example, firing control). The time for firing 10 or more game balls by the board set 174, preferably 6 seconds or more). On the other hand, if 0.1 second is set as the value of the timer, the opening time is a short time that hardly occurs (becomes difficult) even if it is not impossible to enter the big winning opening during one opening. (For example, a time shorter than 1 second, preferably a time shorter than the firing interval of the game ball by the firing control board set 174).

Step S5210: Then, the main control CPU 72 sets the large winning opening interval timer based on the large winning opening opening pattern set in the previous step S5204. The value of the timer set here is the waiting time between rounds during the big hit.

Step S5212: When the above procedure is completed, the main control CPU 72 sets the next jump destination to the jackpot opening / closing operation process, and returns to the jackpot variable winning device management process (FIG. 52).

[Large Hit Big Winning Door Opening / Closing Operation Process] FIG. 54 is a flowchart showing a procedure example of the big hit big winning opening opening / closing operation process. This process is for controlling the opening / closing operation of the first variable winning device 30 or the second variable winning device 31 at the time of a big hit. Hereinafter, the procedure will be described.

Step S5301: The main control CPU 72 confirms whether or not the large winning opening interval timer is counting down. Specifically, it is possible to confirm whether or not the large winning opening interval timer is counting down by confirming whether or not the large winning opening interval timer set in the following step S5314 is already operating. it can.

As a result, when it is confirmed that the large winning opening interval timer is counting down (Yes), the main control CPU 72 executes step S5314. On the other hand, when it cannot be confirmed that the large winning opening interval timer is counting down (No), the main control CPU 72 executes step S5302.

Step S5302: The main control CPU 72 opens the first special winning opening or the second special winning opening. Specifically, a drive signal to be applied to the first special winning opening solenoid 90 or the second special winning opening solenoid 97 is generated based on the operation pattern of the variable winning device during the big hit. As a result, the first variable winning device 30 or the second variable winning device 31 operates to shift from the closed state to the open state.

When the first large winning opening or the second large winning opening is opened, the main control CPU 72 generates a first large winning opening opening command or a second large winning opening opening command. The first special winning opening opening command and the second winning opening opening command are transmitted to the effect control device 124.

Step S5303: Next, the main control CPU 72 executes the release timer countdown process. In this process, the countdown of the release timer set in the previous jackpot opening pattern setting process (step S5208 in FIG. 53) is executed.

Step S5306: Subsequently, the main control CPU 72 confirms whether or not the opening time of the large winning opening has expired. Specifically, it is confirmed whether or not the value of the release timer after the countdown process is 0 or less, and if the value of the release timer is not yet 0 or less (No), the main control CPU 72 next steps S5308. To execute.

Step S5308: The main control CPU 72 executes the winning ball number counting process. In this process, the number of game balls that have won the first variable winning device 30 or the second variable winning device 31 (the first large winning opening or the second large winning opening that is open) within the opening time is counted. Specifically, the main control CPU 72 increments the value of the count number based on the winning detection signal input from the first count switch 84 or the second count switch 85 within the opening time.

Step S5310: Next, the main control CPU 72 confirms whether or not the current count number is less than a predetermined number (10). As described above, this predetermined number defines the upper limit of the number of winning balls (the upper limit of the number of winning balls) allowed per opening (one round during the big hit). If the count number has not yet reached the predetermined number (Yes), the main control CPU 72 returns to the jackpot variable winning device management process. Then, when the variable winning device management process at the time of a big hit is executed, the jump destination is set to the opening / closing operation process of the big winning opening at the time of a big hit at this stage. Execute repeatedly.

When it is determined in step S5306 above that the opening time of the large winning opening has ended (Yes), or when it is confirmed in step S5310 that the number of counts has reached a predetermined number (No), the main control CPU 72 then performs step S5312. Execute.

Step S5312: The main control CPU 72 closes the first grand prize opening or the second grand prize opening. Specifically, the generation of the drive signal for applying to the first special winning opening solenoid 90 or the second special winning opening solenoid 97 is completed. As a result, the first variable winning device 30 or the second variable winning device 31 shifts from the open state to the closed state.

When the first large winning opening or the second large winning opening is closed, the main control CPU 72 generates a first large winning opening closing command or a second large winning opening closing command. The first grand prize opening closing command and the second winning opening closing command are transmitted to the effect control device 124.

Step S5314: Next, the main control CPU 72 executes the interval timer countdown process. In this process, the main control CPU 72 executes the countdown of the big winning opening interval timer set in the above-mentioned big winning opening opening pattern setting process (step S5210 in FIG. 53).

Step S5315: The main control CPU 72 confirms whether or not the grand winning opening interval time has expired. Specifically, it is confirmed whether or not the value of the large winning opening interval timer after the countdown process is 0 or less, and if the value of the large winning opening interval timer is not still 0 or less (No), the main control The CPU 72 returns to the end address of the variable winning device management process (FIG. 52) at the time of a big hit. Then, when the big hit big winning opening opening / closing operation process is executed in the next call, the step S5314 is directly executed by jumping from the first step S5301. On the other hand, when it is confirmed that the value of the large winning opening interval timer after the countdown process is 0 or less (Yes), the main control CPU 72 executes step S5318.

Step S5318: The main control CPU 72 increments the value of the open count counter. The value of the open count counter is stored in the count area of the RAM 76, for example, with the initial value set to 0.

Step S5320: The main control CPU 72 confirms whether or not the value of the open count counter after the increment has reached the number of times set in the current round. Here, the "number of times set in the current round" is determined, for example, "the first variable winning device 30 or the second variable winning device 31 is opened a plurality of times in one round during the big hit". This is to correspond to the open pattern.

When the pattern of repeating the opening / closing operation a plurality of times in one round is not adopted, the "number of times set in the current round" in each round is set once in each round. Therefore, in each round, since the counter value reaches the set number of times in one opening / closing operation (Yes), the main control CPU 72 then proceeds to step S5322.

On the other hand, when a pattern in which the opening / closing operation is repeated a plurality of times in one round is adopted, the counter value has not yet reached the set number of times at the end of one opening (No).

In this case, when the main control CPU 72 returns to the jackpot variable winning device management process, the jump destination is set to the jackpot opening / closing operation process at the present stage. Execute repeatedly. As a result, the increment of the open count counter proceeds in step S5318, and when the counter value reaches the set number of times (Yes), the main control CPU 72 then proceeds to step S5322.

Step S5322: The main control CPU 72 sets the next jump destination to the big hit big winning opening closing process, and returns to the big hit variable winning device management process. Then, when the jackpot variable winning device management process is executed next, the main control CPU 72 then executes the jackpot jackpot closing process.

[Closed the big prize opening at the time of big hit]
FIG. 55 is a flowchart showing an example of a procedure for closing the big winning opening at the time of a big hit. This big hit big winning opening closing process is for continuing the operation of the first variable winning device 30 or the second variable winning device 31 or ending the operation. Hereinafter, the procedure will be described.

Step S5402: The main control CPU 72 increments the round number counter. As a result, for example, the value of the round number counter is "1" at the stage where the first round is completed and the second round is approached.

Step S5404: The main control CPU 72 confirms whether or not the value of the round number counter after increment has reached the set number of execution rounds. Specifically, the main control CPU 72 refers to the value (1 to 15) of the round number counter after incrementing, and if the value is less than the set number of execution rounds (1 to 15 after subtracting 1), (No). Then, step S5405 is executed.

Step S5405: The main control CPU 72 generates a round number command from the value of the current round number counter. The round number command is transmitted to the effect control device 124 in the subcommand transmission process. The effect control device 124 can confirm the current number of rounds based on the received round number command.

Step S5406: The main control CPU 72 sets the next jump destination to the jackpot opening / closing operation process at the time of a big hit.

Step S5408: Then, the main control CPU 72 resets the winning ball number counter and returns to the variable winning device management process at the time of big hit.

When the main control CPU 72 next executes the jackpot variable winning device management process, the main control CPU 72 performs the jackpot opening / closing operation process, which is the next jump destination, in the jackpot game process selection process (step S5100 in FIG. 52). To execute. Then, after executing the jackpot opening / closing operation process at the time of a big hit, the main control CPU 72 executes the jackpot closing process at the time of a big hit again after executing the jackpot closing process at the time of a jackpot, and performs steps S5402 to S5408 above. Execute repeatedly. As a result, the opening / closing operation of the first variable winning device 30 or the second variable winning device 31 is continuously executed until the actual number of rounds reaches the set number of execution rounds (15 times, etc.).

When the actual number of rounds reaches the set number of execution rounds (step S5404: Yes), the main control CPU 72 then executes step S5410.

Step S5410, Step S5412: In this case, when the main control CPU 72 resets (= 0) the round number counter, the next jump destination is set to the jackpot end process.

Step S5408: Then, the main control CPU 72 resets the winning ball number counter and returns to the variable winning device management process at the time of big hit. As a result, when the main control CPU 72 next executes the jackpot variable winning device management process, the jackpot end process is selected this time.

[End processing at the time of big hit]
FIG. 56 is a flowchart showing a procedure example of the jackpot end processing. This big hit end process is for adjusting the conditions for ending the operation of the first variable winning device 30 or the second variable winning device 31 at the time of big hit. Hereinafter, a procedure example will be described.

Step S5501: The main control CPU 72 executes the jackpot end time timer countdown process. In this process, the main control CPU 72 sets an initial value in the jackpot end time timer, and then counts down the timer (for each call of this module) with the passage of time.

Step S5502: Next, the main control CPU 72 confirms whether or not the end time at the time of jackpot has elapsed. Specifically, if the value of the jackpot end time timer is not yet 0, the main control CPU 72 determines that the jackpot end time has not elapsed (No). In this case, the main control CPU 72 ends this module and returns to the jackpot variable winning device management process (FIG. 52).

After that, when the value of the jackpot end time timer becomes 0 with the passage of time, the main control CPU 72 determines that the jackpot end time has elapsed (Yes), and executes step S5503 and subsequent steps.

Step S5503, Step S5504: The main control CPU 72 resets the jackpot flag (00H). As a result, the jackpot game state ends on the control process of the main control CPU 72. Further, the main control CPU 72 erases "big hit" from the internal state flag here, and declares the end of the major role as the internal state in the control process. The main control CPU 72 resets the value of the continuous operation count status.

Step S5506: Next, the main control CPU 72 confirms whether or not the value (01H) of the probability variation function operation flag is set. This flag is set in the big hit other setting process (step S2414 in FIG. 36) during the above-mentioned special symbol change preprocessing.

Step S5508: When the value of the probability fluctuation function operation flag is set (step S5506: Yes), the main control CPU 72 sets the number of probability fluctuations (for example, 10000 times). The set value of the number of probability fluctuations is stored in, for example, the probability variation counter area of the RAM 76 and becomes the above-mentioned number-cut counter value. The probability fluctuation number set here is the upper limit number of times that the special symbol variation (internal lottery) is performed in a high probability state in the subsequent games. However, if a huge number of times of about 10,000 is set as described above, there is almost no chance that non-winning will continue to that extent (the winning probability at high probability is, for example, 1/32 to 1/100). (Degree), in effect, the high probability state will continue until the next winning. On the contrary, when a practical upper limit is set in the high probability state, the number of probability fluctuations is set to a realistic number (for example, about 70 times) (so-called number cut probability change). If the value of the probability fluctuation function operation flag is not set (step S5506: No), the main control CPU 72 does not execute step S5508.

Step S5510: Next, the main control CPU 72 confirms whether or not the value (01H) of the time reduction function operation flag is set. This flag is set in the big hit other setting process (step S2414 in FIG. 36) during the above-mentioned special symbol change preprocessing.

Step S5512: Then, when the value of the time reduction function operation flag is set (step S5510: Yes), the main control CPU 72 sets the time reduction number of times (for example, 10, 100 times or 10000 times). The value of the set time reduction number is stored in the time reduction count area of the RAM 76 as described above. The time reduction number set here is the upper limit number of times for shortening the fluctuation time of the special symbol in the subsequent games. If the value of the time reduction function operation flag is not set (step S5510: No), the main control CPU 72 does not execute step S5512.

Step S5514: Then, the main control CPU 72 generates a state specification command based on various flags. Specifically, when the jackpot flag is reset or the major winning combination ends, a state specification command indicating "normal" is generated as the game state. If the probability fluctuation function operation flag is set, a state specification command indicating "high probability is in progress" is generated as the internal state, and if the time reduction function operation flag is set, the internal state is "time reduction in progress". Generates a state specification command that represents. These state designation commands are transmitted to the effect control device 124 in the subcommand transmission process.

Step S5515: The main control CPU 72 executes the special variation number setting process. Specifically, the main control CPU 72 executes a process of setting a variation pattern selection counter value based on the type of winning symbol. The details of the special fluctuation number setting process will be described later with reference to another drawing.

Step S5516: After the above procedure, the main control CPU 72 sets the next jump destination to the jackpot opening pattern setting process at the time of a jackpot.

Step S5518: Then, the main control CPU 72 sets the jump destination in the execution selection process (step S1000 in FIG. 35) in the special game management process to the special symbol change pre-process. When the above procedure is completed, the main control CPU 72 returns to the variable winning device management process at the time of a big hit.

[Special fluctuation count setting process]
FIG. 57 is a flowchart showing a procedure example of the special fluctuation number setting process. Hereinafter, each procedure will be described.

Step S5600: The main control CPU 72 confirms whether or not the current winning corresponds to either "11 round probability variation symbols 1 to 11" or "11 round normal symbols".

As a result, when it is confirmed that the current winning corresponds to either "11 round probability variation symbols 1 to 11" or "11 round normal symbols" (Yes), the main control CPU 72 executes step S5602. On the other hand, if it cannot be confirmed that the current winning corresponds to either "11 round probability variation symbols 1 to 11" or "11 round normal symbols", the main control CPU 72 performs the jackpot end process (FIG. 56). Return.

Step S5602: The main control CPU 72 sets the fluctuation pattern selection counter value to a value corresponding to the winning symbol. The value according to the winning symbol is set according to the value of the number of special fluctuations in FIG. 41. As a result, after the jackpot game is completed, the special variation is executed 1 to 10 times. The set fluctuation pattern selection counter value is subtracted by 1 each time the special symbol is stopped and displayed once. Then, through such processing, the main control CPU 72 can make the selected variation pattern a normal variation or a special variation.
When the above procedure is completed, the main control CPU 72 returns to the jackpot end process (FIG. 56).

[Variable winning device management process for small hits]
FIG. 58 is a flowchart showing a configuration example of the variable winning device management process at the time of small hit.
The small hit variable winning device management process includes a small hit game process selection process (step S6100), a small hit large winning opening opening pattern setting process (step S6200), and a small hit large winning opening opening / closing operation process (step S6300). , The configuration includes a group of subroutines for the small hit large winning opening closing process (step S6400) and the small hit ending process (step S6500).

Step S6100: In the small hit game process selection process, the main control CPU 72 selects the jump destination of the process to be executed next (any of step S6200 to step S6500). That is, the main control CPU 72 selects the program address of the process to be executed next from the jump table as the jump destination address, and sets the end of the small hit variable winning device management process as the return destination address in the stack pointer. .. Which process is selected as the next jump destination depends on the progress of the processes performed so far. For example, if the operation (opening / closing operation) of the first variable winning device 30 has not been started yet, the main control CPU 72 selects the small hit large winning opening opening pattern setting process (step S6200) as the next jump destination. To do. On the other hand, if the small hit large winning opening opening pattern setting process has already been completed, the main control CPU 72 selects the small hit large winning opening opening / closing operation process (step S6300) as the next jump destination, and the small hit large winning opening opening / closing operation process (step S6300). If the opening / closing operation process of the winning opening is completed, the large winning opening closing process (step S6400) at the time of a small hit is selected as the next jump destination. Further, when the small hit large winning opening opening / closing operation processing and the small hit large winning opening closing processing are repeatedly executed over the set continuous operation number, the main control CPU 72 performs the small hit end processing (step) as the next jump destination. S6500) is selected. Hereinafter, each process will be described in more detail.

[Large winning opening pattern setting process for small hits]
FIG. 59 is a flowchart showing a procedure example of the large winning opening opening pattern setting process at the time of a small hit. This process is for setting conditions such as the number of times the first variable winning device 30 is opened and closed at the time of a small hit and the time for each opening. Hereinafter, each procedure will be described.

Step S6212: The main control CPU 72 sets the “small hit opening pattern”. In the case of the present embodiment, for the "small hit opening pattern", for example, the opening pattern of "0.1 second opening" is set for the first time and the second time, respectively. Since there is no concept of "round" for "small hit", "opening pattern" is also described as "first opening" and "second opening".

Step S6214: The main control CPU 72 sets the number of times the large winning opening is opened to, for example, two, based on the large winning opening opening pattern set in the previous step S6212. The number of releases set here is stored in, for example, the buffer area of the RAM 76.

Step S6216: Next, the main control CPU 72 sets the small hit release timer. The value of the timer set here is the opening time for each operation when the first variable winning device 30 is operated. In addition, in this embodiment, 0.1 second is set as the value of the small hit opening timer as described above, and in such an opening time, most of the prizes to the large winning opening occur during one opening. It is not (difficult) for a short time (for example, a time shorter than 1 second, preferably a time shorter than the firing interval of the game ball by the launcher unit).

Step S6218: The main control CPU 72 sets the small hit interval timer. The value of the timer set here is the waiting time for each time when the first variable winning device 30 is opened and closed a plurality of times at the time of a small hit, and this timer value is set to, for example, about 2 seconds.

Step S6220: When the above procedure is completed, the main control CPU 72 sets the next jump destination to the small hit large winning opening opening / closing operation process, and returns to the small hit variable winning device management process (FIG. 58). Then, the main control CPU 72 then executes the small hit large winning opening opening / closing operation process (step S6300).

[Large winning opening opening / closing operation processing at the time of small hit]
FIG. 60 is a flowchart showing a procedure example of a large winning opening opening / closing operation process at the time of a small hit. This process is for controlling the opening / closing operation of the first variable winning device 30 at the time of a small hit. Hereinafter, the procedure will be described.

Step S6301: The main control CPU 72 confirms whether or not the interval timer is counting down. Specifically, by confirming whether or not the interval timer set in step S6314 below is already in operation, it is possible to confirm whether or not the interval timer is in the countdown.

As a result, when it is confirmed that the interval timer is in the countdown (Yes), the main control CPU 72 executes step S6314. On the other hand, if it cannot be confirmed that the interval timer is counting down (No), the main control CPU 72 executes step S6302.

Step S6302: The main control CPU 72 opens the first grand prize opening. Specifically, a drive signal applied to the first special winning opening solenoid 90 is generated. As a result, the first variable winning device 30 operates to shift from the closed state to the open state.

Step S6304: Next, the main control CPU 72 executes the release timer countdown process. In this process, the countdown of the release timer set in the previous small hit large winning opening opening pattern setting process (step S6216 in FIG. 59) is executed.

Step S6306: Subsequently, the main control CPU 72 confirms whether or not the opening time has expired. Specifically, it is confirmed whether or not the value of the release timer after the countdown process is 0 or less, and if the value of the release timer is not yet 0 or less (No), the main control CPU 72 next steps S6308. To execute.

Step S6308: The main control CPU 72 executes the winning ball number counting process. In this process, the number of game balls that have won a prize in the first variable winning device 30 (the first major winning opening being opened) within the opening time is counted. Specifically, the main control CPU 72 increments the value of the count number based on the winning detection signal input from the first count switch 84 within the opening time.

Step S6310: Next, the main control CPU 72 confirms whether or not the current count number is less than a predetermined number (10). As described above, this predetermined number defines the upper limit of the number of winning balls (the upper limit of the number of winning balls) allowed per opening (one opening at the time of a small hit). If the count number has not yet reached the predetermined number (Yes), the main control CPU 72 returns to the small hit variable winning device management process (FIG. 58). Then, when the variable winning device management process at the time of small hit is executed next, the jump destination is set to the opening / closing operation process of the large winning opening at the time of small hit at this stage, so that the main control CPU 72 is in step S6301 to step S6310 described above. Repeat the procedure.

If it is determined in step S6306 that the opening time has ended (Yes), or if it is confirmed in step S6310 that the number of counts has reached a predetermined number (No), the main control CPU 72 then executes step S6312. Here, since the value of the release timer is set for a short time for the release at the time of a small hit, the main control CPU 72 normally steps before confirming that the count number has reached a predetermined number in step S6310. In most cases, it is determined that the opening time has ended in S6306.

Step S6312: The main control CPU 72 closes the first grand prize opening. Specifically, the generation of the drive signal for applying to the first grand prize opening solenoid 90 is completed. As a result, the first variable winning device 30 returns from the open state to the closed state.

Step S6314: Next, the main control CPU 72 executes the interval timer countdown process. In this process, the main control CPU 72 executes the countdown of the interval timer set in the above-mentioned small hit large winning opening opening pattern setting process (step S6218 in FIG. 59).

Step S6315: The main control CPU 72 confirms whether or not the interval time has expired. Specifically, it is confirmed whether or not the value of the interval timer after the countdown process is 0 or less, and if the value of the interval timer is not yet 0 or less (No), the main control CPU 72 is variable at the time of small hit. It returns to the end address of the winning device management process (FIG. 58). Then, when the small hit large winning opening opening / closing operation process is executed in the next call, the step S6314 is directly executed by jumping from the first step S6301. On the other hand, when it is confirmed that the value of the interval timer after the countdown process is 0 or less (Yes), the main control CPU 72 executes step S6316.

Step S6316: The main control CPU 72 sets the next jump destination to the small hit large winning opening closing process, and returns to the small hit variable winning device management process. Then, when the small hit variable winning device management process is executed next, the main control CPU 72 then executes the small hit large winning opening closing process.

[Large winning opening closing process at the time of small hit]
FIG. 61 is a flowchart showing an example of a procedure for closing the large winning opening at the time of a small hit. This small hit large winning opening closing process is for continuing the operation of the first variable winning device 30 or ending the operation. Hereinafter, the procedure will be described.

Step S6412: The main control CPU 72 increments the value of the open count counter.

Step S6414: Next, the main control CPU 72 confirms whether or not the value of the release count counter after the increment has reached the set release count. The number of times of opening is set in the previous large winning opening opening pattern setting process (step S6214 in FIG. 59). If the value of the open count counter has not reached the set open count (No), the main control CPU 72 executes step S6416.

Step S6416: The main control CPU 72 sets the next jump destination to the large winning opening opening / closing operation process at the time of a small hit.
Step S6430: Then, the main control CPU 72 resets the winning ball number counter and returns to the variable winning device management process (FIG. 58) at the time of small hit.

When the main control CPU 72 next executes the variable winning device management process, the main control CPU 72 performs the small hit large winning opening opening / closing operation process which is the next jump destination in the small hit game process selection process (step S6100 in FIG. 58). To execute. Then, after executing the small hit large winning opening opening / closing operation process, the main control CPU 72 again executes the small hit large winning opening closing process until the actual number of opening reaches the set opening number (2 times). , The opening / closing operation of the first variable winning device 30 is repeatedly executed.

When the actual number of times of opening at the time of a small hit reaches the set number of times of opening (step S6414: Yes), the main control CPU 72 then executes step S6418.

Step S6418, Step S6420: In this case, when the main control CPU 72 resets (= 0) the open count counter, the next jump destination is set to the small hit end process.

Step S6430: Then, the main control CPU 72 resets the winning ball number counter and returns to the variable winning device management process (FIG. 58) at the time of small hit. As a result, when the main control CPU 72 next executes the variable winning device management process, the small hit end process is selected this time.

[End processing at the time of small hit]
FIG. 62 is a flowchart showing a procedure example of the end processing at the time of small hit. This small hit end process is for adjusting the conditions for ending the operation of the first variable winning device 30 at the time of a small hit. Hereinafter, a procedure example will be described.

Step S6502: The main control CPU 72 executes a small hit end time timer countdown process. In this process, the main control CPU 72 sets an initial value in the small hit end time timer, and then counts down the timer (for each call of this module) with the passage of time.

Step S6504: Next, the main control CPU 72 confirms whether or not the end time at the time of small hit has elapsed. Specifically, if the value of the small hit end time timer is not yet 0, the main control CPU 72 determines that the small hit end time has not elapsed (No). In this case, the main control CPU 72 ends this module and returns to the small hit variable winning device management process (FIG. 58).

After that, when the value of the small hit end time timer becomes 0 with the passage of time, the main control CPU 72 determines that the small hit end time has elapsed (Yes), and executes step S6506 and subsequent steps.

Step S6506, Step S6508: The main control CPU 72 resets the value of the small hit flag (00H), and erases "small hit in progress" from the internal state flag to end the small hit game. In the case of a big hit, the internal condition device operates (for example, the flag corresponding to the condition device is turned ON), but in the case of a small hit, the internal condition device does not operate, so this is the case. The procedure is solely for the purpose of clearing the flag.

Step S6510: After the above procedure, the main control CPU 72 sets the next jump destination to the small hit large winning opening opening pattern setting process.

Step S6512: Then, the main control CPU 72 sets the jump destination in the execution selection process (step S1000 in FIG. 35) in the special game management process to the special symbol change pre-process. When the above procedure is completed, the main control CPU 72 returns to the variable winning device management process at the time of small hit.

[LED display setting process]
FIG. 63 is a flowchart showing a configuration example of the LED display setting process.
The LED display setting process includes a special symbol display setting process (step S1200), a normal symbol display setting process (step S1210), a status display setting process (step S1220), an operation memory display setting process (step S1230), and a continuous operation number display setting. The configuration includes a group of subroutines for processing (step S1240).

Of these, the special symbol display setting process (step S1200), the normal symbol display setting process (step S1210), and the working memory display setting process (step S1230) include the first special symbol display device 34, the second special symbol display device 35, and the normal symbol display device 35. In the process of generating a drive signal (common output data) applied to each LED of the symbol display device 33, the normal symbol operation storage lamp 33a, the first special symbol operation storage lamp 34a, and the second special symbol operation storage lamp 35a. is there. The generated common output data (display data) is stored in the RAM of the used area and output in the dynamic port output process (hereinafter, the same applies).

The state display setting process (step S1220) and the continuous operation number display setting process (step S1240) are processes for generating a drive signal (common output data) to be applied to each LED of the game state display device 38. First, in the state display setting process, the main control CPU 72 controls the lighting of the probability fluctuation state display lamp 38d and the time saving state display lamp 38e according to the values of the probability fluctuation function operation flag or the time reduction function operation flag, respectively. For example, if a value (01H) is set in the probability fluctuation function operation flag when the power of the pachinko machine 1 is turned on, the main control CPU 72 emits a lighting signal (common output data) for the LED corresponding to the probability fluctuation state display lamp 38d. To generate. The probability fluctuation state display lamp 38d keeps lighting until the jackpot game related to the special symbol is started, or until the probability fluctuation function is turned off after the fluctuation display of the special symbol is performed a specified number of times, and then the lamp is not lit. The display can be switched (off). Further, the probability fluctuation state display lamp 38d does not light when the state shifts to the latent probability change state (high probability non-time shortening state), but the power is turned off in the latent probability change state, and the power is turned on without clearing the RAM. Lights up when restored. On the other hand, if the value (01H) is set in the time reduction function operation flag, the main control CPU 72 gives a lighting signal (common) to the LED corresponding to the time reduction status indicator lamp 38e, regardless of whether or not the power is turned on. Output data) is generated. Further, the main control CPU 72 controls the lighting of the launch position designation lamp 38f according to the launch position designation status. For example, when the first variable winning device 30 or the second variable winning device 31 is activated by the big hit game or the small hit game (when "1" is set in the firing position designation status), the main control CPU 72 fires. A lighting signal (common output data) for LED corresponding to the position designation lamp 38f is generated. On the other hand, when the normal game is in progress in the low probability non-time shortened state (when "0" is set in the firing position designation status), the main control CPU 72 emits a lighting signal (lighting signal) for the LED corresponding to the firing position designation lamp 38f. Common output data) is not generated. Further, if a value (01H) is set in the time reduction function operation flag, the main control CPU 72 outputs a lighting signal (for common output) to the LED corresponding to the firing position designation lamp 38f in addition to the time saving state display lamp 38e described above. Data) is generated. When the launch position designation lamp 38f shifts to the "time reduction state" after the jackpot game, it lights up from the start of the jackpot game until the "time reduction state" ends, and does not light up when the "time reduction state" ends. OFF).

The probability fluctuation state display lamp 38d can adopt any of the following lighting methods.
(1) The first lighting method is a method mainly used for models equipped with a latent probability change function, and does not light even in a probability fluctuation state (high probability state), and is in a probability fluctuation state when the power is turned on. It is a method to turn on when it is. For example, when the latent probability change state exists, the probability fluctuation state display lamp 38d can be prevented from lighting when the state shifts to the latent probability change state, and it lights even during the probability change (high probability time shortened state). You can avoid it.
(2) The second lighting method is a method mainly used for models that are not equipped with the latent probability change function, and is a lighting method that lights when the probability is in a fluctuating state.
One of these lighting methods can be adopted depending on the specifications of the gaming machine model and the like.

Further, the main control CPU 72 controls the lighting of the jackpot type display lamps 38a, 38b, and 38c in the continuous operation number display setting process. Specifically, the main control CPU 72 generates lighting signals (common output data) for the jackpot type indicator lamps 38a, 38b, and 38c based on the value of the continuous operation number status. At this time, the target for outputting the lighting signal is the combination of the indicator lamps 38a, 38b, and 38c corresponding to the jackpot symbol specified by the value of the continuous operation count status. For example, if the value of the continuous operation count status specifies "15 rounds", the main control CPU 72 has all the lamps corresponding to the lighting pattern representing "15 rounds" (for example, all the lamps 38a, 38b, 38c). Generates a lighting signal (common output data) for the lamp. Further, if the value of the continuous operation count status specifies "3 rounds", the main control CPU 72 gives a lighting signal (common output) to the lamp (for example, only the lamp 38a) corresponding to the lighting pattern representing "3 rounds". Data) is generated. Since the three indicator lamps 38a, 38b, and 38c can display six lighting patterns, it is possible to correspond to the six types of jackpots of the present embodiment. The details of the lighting pattern corresponding to the number of rounds are preferably displayed around the indicator lamps 38a, 38b, and 38c in order to clearly convey the details to the player.

FIG. 64 is a flowchart showing a procedure example of the external information management process. Hereinafter, a procedure example will be described.

Step S1250: The main control CPU 72 executes the security signal management process. In this process, the main control CPU 72 executes a process of transmitting a security signal to the hall computer as needed. The details of the process will be described later.

Step S1260: The main control CPU 72 executes other signal management processing. In this process, the main control CPU 72 transmits external signals other than the security signal (for example, prize ball information, door opening information, symbol confirmation count information, jackpot information, starting port information, etc.) to the hall computer as necessary. Execute the process to be performed. When the above processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

FIG. 65 is a flowchart showing a procedure example of the security signal management process. Hereinafter, a procedure example will be described.

Step S1271: The main control CPU 72 executes a process of confirming whether or not a switch abnormality has occurred. The main control CPU 72 monitors signals from various switches arranged on the board, and determines that a switch abnormality has occurred when the on state continues for a certain period of time or longer.

As a result, when it is confirmed that a switch abnormality has occurred (Yes), the main control CPU 72 executes step S1278. On the other hand, when it cannot be confirmed that the switch abnormality has occurred (No), the main control CPU 72 executes step S1272.

Step S1271: The main control CPU 72 executes a process of confirming whether or not magnetism or radio waves have been detected. The main control CPU 72 monitors the signal from the magnetic detection switch or the radio wave detection switch, and determines that the magnetism or the radio wave has been detected when the ON state continues for a certain period of time or longer.

As a result, when it is confirmed that magnetism or radio waves have been detected (Yes), the main control CPU 72 executes step S1278. On the other hand, if it cannot be confirmed that magnetism or radio waves have been detected (No), the main control CPU 72 executes step S1273.

Step S1273: The main control CPU 72 executes a process of confirming whether or not the security signal output timer is 0. The security signal output timer is set at the end of the RAM clearing process (step S122 in FIG. 10) or at the end of the setting-related processing (step S318 in FIG. 29). Further, the security signal output timer is updated with the passage of time in the timer update process.

As a result, when it is confirmed that the security signal output timer is 0 (Yes), the main control CPU 72 executes step S1274. On the other hand, when it cannot be confirmed that the security signal output timer is 0 (No), that is, when the security signal output timer has not timed up, the main control CPU 72 executes step S1278.

Step S1274: The main control CPU 72 confirms whether or not the gaming machine status flag is “00H (gamable state)”.

As a result, when it is confirmed that the gaming machine status flag is "00H (gamable state)" (Yes), the main control CPU 72 executes step S1275. On the other hand, when it cannot be confirmed that the gaming machine status flag is "00H (playable status)" (No), for example, when it is "01H (setting change status)" or "02H (setting confirmation status)". The main control CPU 72 executes step S1278.

Step S1275: The main control CPU 72 executes a process of confirming whether or not an area abnormal passage has occurred. Here, the region is, for example, a probabilistic region that shifts to a high probability state when the game ball passes, a specific region where a big hit occurs when the game ball passes, and the like. When the game ball passes through the area (for example, when the game ball passes through the probability variation area while the short opening of the probability variation area is open, the main control CPU 72 is not in the small hit game, but the game is played. When the sphere passes through a specific area, etc.), it can be determined that an abnormal area passage has occurred.

As a result, when it is confirmed that the region abnormal passage has occurred (Yes), the main control CPU 72 executes step S1278. On the other hand, when it cannot be confirmed that the region abnormal passage has occurred (No), the main control CPU 72 executes step S1276.

Step S1276: The main control CPU 72 executes a process of confirming whether or not an illegal winning has occurred. Here, the illegal winning means an illegal winning. When the main control CPU 72 wins a predetermined number or more of game balls in the large winning opening other than when the special electric accessory is operating, the main control CPU 72 wins a specified number or more of the game balls in the right-starting winning opening in addition to the hitting operation of the normal electric accessory. In some cases, it can be determined that an illegal prize has occurred.

As a result, when it is confirmed that an illegal winning has occurred (Yes), the main control CPU 72 executes step S1278. On the other hand, when it cannot be confirmed that the illegal winning has occurred (No), the main control CPU 72 executes step S1277.

Step S1277: The main control CPU 72 executes a process of confirming whether or not another abnormality related to the game has occurred. Here, the other abnormalities related to the game mean, for example, a vibration error, a large winning opening abnormal discharge error, a large winning opening entry / exit ball mismatch error, a door opening error, and the like.

As a result, when it is confirmed that another abnormality related to the game has occurred (Yes), the main control CPU 72 executes step S1278. On the other hand, when it cannot be confirmed that another abnormality related to the game has occurred (No), the main control CPU 72 returns to the external information management process (FIG. 64).

Step S1278: The main control CPU 72 executes the security signal output process. Specifically, the process of storing the data corresponding to the security signal in the port output request buffer is executed. As a result, a security signal is output to the hall computer.

While the setting is being changed or the setting is being confirmed, a security signal is output because it corresponds to "when the game is not available" (step S1274; No). When the RAM is cleared, the value corresponding to 128 ms is set in the security signal output timer regardless of whether or not the setting is changed. Therefore, even if the setting change is completed in less than 128 ms, the output time of the security signal is secured at least 128 ms. On the other hand, if the setting confirmation is completed in less than 128 ms, the RAM clear is not executed, so that the security signal output time is less than 128 ms. In the present embodiment, the security signal output timer is set at the end of the setting confirmation in order to prevent the security signal output time from becoming less than 128 ms at the time of setting confirmation.

By executing the processes of steps S1274 and S1278, the main control CPU 72 performs a special information transmission process of transmitting a security signal (special information) to the hall computer (external device) in the setting change state or the setting confirmation state. It can be executed (special information transmission processing execution means).

By executing the processes of step S1273, step S1278, step S204 of FIG. 24, and step S318 of FIG. 29, the main control CPU 72 ends in a setting confirmation state of less than 128 ms (less than a certain time). Even in this case, the special information continuous transmission process for continuously transmitting the security signal to the hall computer for at least 128 ms (fixed time) can be executed (special information continuous transmission process execution means).

Further, by executing processing such as step S1273, step S1278, step S204 of FIG. 24, and step S318 of FIG. 29, the main control CPU 72 keeps the setting confirmation state constant when the setting confirmation state ends. Regardless of whether the time is completed in less than the time, the time is started by the security signal output timer (predetermined timer) corresponding to a certain time, and the whole computer is used until the security signal output timer is timed up. It is possible to transmit a security signal (special information continuous transmission processing execution means).

Further, by executing the processes of step S1273, step S1278, step S122 of FIG. 10, step S204 of FIG. 24, step S318 of FIG. 29, and the like, the main control CPU 72 causes the hall computer to execute the RAM clear process. On the other hand, the security signal can be continuously transmitted for at least 128 ms (special information transmission processing execution means).

Furthermore, by executing the processes of step S1273, step S1278, step S122 of FIG. 10, step S204 of FIG. 24, step S318 of FIG. 29, and the like, the main control CPU 72 performs the special information continuous transmission process (setting confirmation). It is a process different from the process of setting the security signal output timer at the end of the process and transmitting the security signal until the security signal output timer times out), and the setting change state ends in less than 128 ms. Even if this is the case, the special transmission process that continuously transmits the security signal to the hall computer for at least 128 ms (the security signal output timer is set at the end of the RAM clear process, and the security signal output timer times out. When the setting change state ends after that, the special information continuous transmission process (particularly, the process of setting the security signal output timer in step S318 of FIG. 29) is avoided. (Special information continuous transmission processing execution means). When the above processing is completed, the main control CPU 72 returns to the external information management processing (FIG. 64).

FIG. 66 is a flowchart showing an example of the first procedure of the addition number calculation process. Hereinafter, a procedure example will be described.

Step S602: The main control CPU 72 executes a process of clearing the normal prize ball addition number, the normal out addition number, and the total out addition number. The normal prize ball addition number is a variable indicating a value to be added to the normal prize ball addition number. The normal out addition number is a variable indicating a value to be added to the normal out number. The total out addition number is a variable indicating a value to be added to the total out addition number.

Step S604: The main control CPU 72 confirms whether or not the detection signal is input from the out switch 99.

As a result, when it is confirmed that the detection signal has been input (Yes), the main control CPU 72 executes step S606. On the other hand, if it cannot be confirmed that the detection signal has been input (No), the main control CPU 72 executes step S608.

Step S606: The main control CPU 72 executes a process of adding 1 to the total out addition number. For example, when the value of the total out addition number is "0", the value of the total out addition number is "1".

Step S608: The main control CPU 72 executes a process of loading the special game management phase. The value of the special game management phase will be described later.

Step S610: The main control CPU 72 confirms whether or not the jackpot is in progress. Whether or not the jackpot is being hit can be confirmed by the value of the special game management phase (during the jackpot: special game management phase = "03H" to "07H").

As a result, when it is confirmed that the jackpot is in progress (Yes), the main control CPU 72 returns to the timer interrupt processing (FIG. 24). On the other hand, if it cannot be confirmed that the jackpot is in progress (No), the main control CPU 72 executes step S612.

Step S612: The main control CPU 72 confirms whether or not the time is being shortened. Whether or not the time is shortened can be confirmed by the time reduction function operation flag.

As a result, when it is confirmed that the time is being shortened (Yes), the main control CPU 72 returns to the timer interrupt processing (FIG. 24). On the other hand, if it cannot be confirmed that the time is being shortened (No), the main control CPU 72 executes step S614.

Step S614: The main control CPU 72 confirms whether or not the right-handed instruction is being given. Whether or not a right-handed strike is being instructed can be confirmed by the launch position designation status.

As a result, when it is confirmed that the right-handed instruction is being performed (Yes), the main control CPU 72 returns to the timer interrupt processing (FIG. 24). On the other hand, if it cannot be confirmed that the right-handed instruction is being performed (No), the main control CPU 72 executes step S616.

By executing the process of step S614, the main control CPU 72 can determine whether or not to calculate the base based on the content of the launch position designation status (based on the content determined by the launch position determining means). (Means for determining whether or not base calculation can be executed).

Further, by executing the processes of steps S610 to S614, the main control CPU 72 should launch the game ball into the second game area when the jackpot game is being executed, when the time is shortened, or when the game ball is in the second game area. If it is one of the cases where it is determined to be present, it can be determined not to calculate the base (base calculation execution enablement determination means).

Further, by executing the processes of steps S610 to S614, the main control CPU 72 should launch the game ball into the first game area when the jackpot game is not being executed, when the time is shortened, or when the game is in a non-time shortened state. If it is one of the cases where it is determined to be present, it can be determined by calculating the base (base calculation execution enablement determination means).

Step S616: The main control CPU 72 confirms whether or not a detection signal has been input from the out switch 99.

As a result, when it is confirmed that the detection signal has been input (Yes), the main control CPU 72 executes step S618. On the other hand, if it cannot be confirmed that the detection signal has been input (No), the main control CPU 72 executes step S620.

Step S618: The main control CPU 72 executes a process of adding 1 to the normal out addition number. For example, when the value of the normal out addition number is "0", the value of the normal out addition number is "1".

Step S620: Has the main control CPU 72 input a detection signal from each winning opening switch (for example, middle starting winning opening switch 80, right starting winning opening switch 82, first winning opening switch 86, second winning opening switch 81)? Check if it is not.

As a result, when it is confirmed that the detection signal has been input (Yes), the main control CPU 72 executes step S622. On the other hand, when it cannot be confirmed that the detection signal has been input (No), the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

Step S622: The main control CPU 72 executes a process of adding all the prize balls generated by this interrupt to the normal prize ball addition number. For example, the value of the normal out addition number is "0", and with this interruption, the middle start winning opening 26 (middle starting winning opening switch 80: number of prize balls = 4), the right starting winning opening 28a (right starting winning opening) When one game ball is inserted into each of the mouth switch 82: the number of prize balls = 1) and the normal prize opening 22 (first prize opening switch 86: the number of prize balls = 3), the value of the normal out addition number Is "8 (= 4 + 1 + 3)". The switch for the prize ball and the number of prize balls are determined based on the prize ball number data stored in the used area. Since the switch for the prize ball and the number of prize balls may differ depending on the model, this process depends on the model.

When the above processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

FIG. 67 is a flowchart showing an example of the second procedure of the addition number calculation process. Hereinafter, a procedure example will be described. As for the first procedure example and the second procedure example, either one of the procedure examples can be adopted.

Step S630: The main control CPU 72 confirms whether or not the detection signal is input from the out switch 99.

As a result, when it is confirmed that the detection signal has been input from the out switch 99 (Yes), the main control CPU 72 executes step S631. On the other hand, when it cannot be confirmed that the detection signal has been input from the out switch 99 (No), the main control CPU 72 executes step S632.

Step S631: When the main control CPU 72 confirms that the detection signal has been input from the out switch 99, the main control CPU 72 sets “1” in the number of shot balls B (total out addition number).

Step S632: When the main control CPU 72 cannot confirm that the detection signal has been input from the out switch 99, the main control CPU 72 sets “0” in the number of shot balls B (total out addition number).

Step S633: The main control CPU 72 confirms whether or not the gaming state is a specific gaming state. The reason for determining whether or not the player is in a specific game state is that, in the specific game state, the number of launched balls A and the number of acquired balls, which are the basis of the calculation of the base, are not counted.

Here, the specific gaming state can include at least one of (1) big hit, (2) time saving, and (3) right-handed instruction. In addition, the reason for including "(3) Right-handed instruction" is that the specific game state includes "during the small hit rush state (while adopting the simultaneous rotation of the first special symbol and the second special symbol, the second". This is because it includes "in a state where small hits frequently occur due to fluctuations in special symbols, that is, in a high-probability non-time shortening state)" and does not include "in latent probability change (in a high-probability non-time shortening state)". ..

As a result, when it is confirmed that the gaming state is a specific gaming state (Yes), the main control CPU 72 executes step S634. On the other hand, when it cannot be confirmed that the gaming state is a specific gaming state (No), the main control CPU 72 executes step S635.

Step S634: The main control CPU 72 executes a process of setting the number of launched balls A (normal out addition number) to “0” and setting the number of acquired balls (normal prize ball addition number) to “0”. Then, when this processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

Step S635: The main control CPU 72 executes a process of copying (substituting) the value of the number of launching balls B (total out addition number) to the number of launching balls A (normal out addition number).

Step S636: The main control CPU 72 executes a process of setting the total number of prize balls by the game balls that have won the winning opening to the number of acquired balls (normal prize ball addition number). The switch for the prize ball and the number of prize balls are determined based on the prize ball number data stored in the used area. Since the switch for the prize ball and the number of prize balls may differ depending on the model, this process depends on the model. Here, regarding the big prize opening, it is not necessary to calculate the number of prize balls because the big hit is excluded from the calculation of the base, but when you want to include the number of prize balls in the normal small hit in the base. Can also calculate the number of prize balls for the big prize opening.

The "acquired ball number", "launched ball number A", and "launched ball number B" are all variables stored in the used area of the RAM 76. Then, when this processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

FIG. 68 is a diagram showing the relationship between the gaming state and the number of launched balls. When the "game state" is "during big hit", "during time saving", or "during right-handed instruction", the value of the number of shot balls is the value shown below.

At the time of "out switch detection", the "number of launched balls A" becomes "0" and the "number of launched balls B" becomes "1". In "when the out switch is not detected", the "number of launched balls A" becomes "0" and the "number of launched balls B" becomes "0".

When the "gaming state" is "normal" or "latent (latent probability variation state)", the value of the number of launched balls is the value shown below.

At the time of "out switch detection", the "number of launched balls A" is "1" and the "number of launched balls B" is "1". In "when the out switch is not detected", the "number of launched balls A" becomes "0" and the "number of launched balls B" becomes "0".

FIG. 69 is a flowchart showing a procedure example of the performance display monitor control process. Hereinafter, a procedure example will be described.

Step S640: The main control CPU 72 executes a process of saving the stack pointer and all the registers.

Step S642: The main control CPU 72 executes the out-of-area RAM clear check process. This process is a process outside the region. Specifically, the main control CPU 72 determines whether or not the RAM used outside the area has been initialized, and executes a process of initializing if it has not been initialized.

Step S643: The main control CPU 72 confirms whether or not it is in a game-enabled state. Specifically, it is confirmed whether or not the value of the gaming machine status flag is "00H".

As a result, when it is confirmed that the game is possible (Yes), the main control CPU 72 executes step S644. On the other hand, if it cannot be confirmed that the game is playable (No), the main control CPU 72 executes step S648.

By executing such a process, the process related to the original performance display monitor 200 can be performed when the setting is being changed or the setting is being confirmed (when the game is not possible), as in the process outside the area called in the main loop. You can prevent it from running.

While the setting is being changed or the setting is being confirmed, the game can be stopped. In this case, the original processing related to the performance display monitor 200 is not performed. Therefore, it may be set that "the processing outside the area is not called while the setting is being changed or the setting is being confirmed", but this is not adopted in the present embodiment because the amount of code in the used area increases. That is, the amount of code in the used area can be reduced by executing the process of determining whether the setting is being changed or the setting is being confirmed outside the area. In this way, the load on the main program can be reduced by not executing the processing related to the performance display monitor 200 during the setting change or the setting confirmation.

By executing such a process, the main control CPU 72 may restrict the execution of at least a part of the other process during the execution of one of the setting-related process and the base-related process. Yes (restriction means). That is, the main control CPU 72 executes at least a part of the base-related processes (steps S644 and S646) when the settings are being changed or the settings are being confirmed, that is, when the game is not available (step S643; No). You can avoid it.

Further, by executing such a process, the main control CPU 72 determines whether or not the setting is being changed or the setting is being confirmed (whether or not one of the processes is being executed), and the determination result is affirmative. If, it is determined to limit the execution of at least a part of the base-related processing (the other processing), and if the judgment result is negative, at least a part of the base-related processing (the other processing) is processed. The determination process (determination process of step S643) for determining not to restrict the execution of the above can be executed (restriction means). That is, the main control CPU 72 determines whether or not the game is playable (whether or not one of the processes is being executed), and if the determination result is negative, the base-related process (the other process). Judgment process (step S643) that determines that the execution of at least a part of the processes is restricted, and if the determination result is affirmative, determines that the execution of at least a part of the base-related processes (the other process) is not restricted. Judgment processing) can be executed (restriction means).

Further, by executing such a process, the main control CPU 72 can execute a determination process (determination process in step S643) as a process included in the process outside the area (second process) (second process). Processing execution means).

Step S644: Main control CPU 72
Executes the ball number addition process. This process is a process outside the region. Specifically, the main control CPU 72 calculates the number of launch balls A (normal out addition number), the launch ball number B (total out addition number), and the acquisition number calculated by the "addition number calculation process" executed as the processing of the used area. A process of adding the number of balls (normal prize ball addition number) to various counters arranged outside the area of the RAM 76 is executed.

Specifically, the main control CPU 72 performs a process of adding the number of fired balls A (normal out addition number) to the normal out number (normal out counter), and the number of fired balls B (total out counter) to the total out number (total out counter). The process of adding the number of added balls, the process of adding the number of acquired balls (the number of added normal prize balls) to the number of normal prize balls (the number of normal prize balls counter), and the like are executed. The details of the processing will be described later.

Step S646: The main control CPU 72 executes the performance display monitor display process. This process is a process outside the region. Specifically, the main control CPU 72 blinks the performance display monitor 200, changes the display contents, and sets the display data. The display content is changed, for example, by repeating "turning on for 0.3 seconds, turning on for 0.3 seconds, or turning off (when blinking)" eight times (after a total of 4.8 seconds have passed). The contents to be switched are "the base currently being measured" and "the base of the section for the previous 60,000 shots".

Then, the start of the division task (division process) is set at the timing of the eighth "lighting or extinguishing" (when 4.5 seconds have passed from the start of display). After that, the division task is executed through the performance display monitor aggregation division process called from the main loop process. The calculation in the division task is a process that ends at the latest when the display content is changed (4.8 seconds after the start of the display, 0.3 seconds after the start of the division task).

Further, in this process, the main control CPU 72 executes a process of generating common output data for controlling lighting of the LED included in the performance display monitor 200 based on the base value.

For example, when "the base of the current section is 30%", the main control CPU 72 sets the data corresponding to "bL." As the common output data (display data) in the common 0, 1 buffer, and sets the common 2 , 3 Executes the process of setting the data corresponding to "30" as the common output data (display data) in the buffer.

Step S648: The main control CPU 72 executes a process of returning the stack pointer and all the registers. When the above processing is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

FIG. 70 is a flowchart showing a procedure example of the ball number addition process. The ball number addition process is a process outside the region. The ball number addition process is called by the performance display monitor control process called by the timer interrupt process. Hereinafter, a procedure example will be described.

Step S650: The main control CPU 72 executes a process of adding the number of acquired balls (normal prize ball addition number) to the normal prize ball number counter (normal prize ball number). For example, when the value of the normal prize ball counter is "100" and the value of the acquired ball number is "8", the value of the normal prize ball counter is "108".

Step S652: The main control CPU 72 executes a process of adding the number of shot balls A (normal out addition number) to the normal out counter (normal out number). For example, when the value of the normal out counter is "299" and the value of the number of launched balls A is "0", the value of the normal out counter is "299".

Step S654: The main control CPU 72 executes a process of adding the number of shot balls B (total out addition number) to the total out counter (total out number). For example, when the value of the total out counter is "299" and the value of the number of launched balls B is "1", the value of the total out counter is "300".

The "normal prize ball number counter", "normal out counter", and "total out counter" are variables stored in the RAM outside the area. In addition, the values of the "normal prize ball counter" and the "normal out counter" are used for the base calculation, and the values of the "total out counter" are used for updating the aggregation section. When the above processing is completed, the main control CPU 72 returns to the performance display monitor control processing (FIG. 69).

FIG. 71 is a flowchart showing a procedure example of the performance display monitor aggregation division processing. The performance display monitor aggregation division process is a process outside the area. The performance display monitor aggregation division process is called from the main loop process.

Step S660: The main control CPU 72 executes a process of saving the stack pointer and all the registers.

Step S6611: The main control CPU 72 executes the out-of-area RAM clear check process. This process is a process outside the region. Specifically, the main control CPU 72 determines whether or not the RAM used outside the area has been initialized, and executes a process of initializing if it has not been initialized.

Step S662a: The main control CPU 72 confirms whether or not it is in a game-enabled state. Specifically, it is confirmed whether or not the value of the gaming machine status flag is "00H".

As a result, when it is confirmed that the game is possible (Yes), the main control CPU 72 executes step S663. On the other hand, if it cannot be confirmed that the game is playable (No), the main control CPU 72 executes step S668.

While the setting is being changed or the setting is being confirmed (when the game is not possible), the game can be stopped. In this case, the original processing related to the performance display monitor 200 is not performed. Therefore, it may be set that "the processing outside the area is not called while the setting is being changed or the setting is being confirmed", but this is not adopted in the present embodiment because the amount of code in the used area increases. That is, the amount of code in the used area can be reduced by executing the process of determining whether the setting is being changed or the setting is being confirmed outside the area. In this way, the load on the main program can be reduced by not executing the processing related to the performance display monitor 200 during the setting change or the setting confirmation.

In the game stop state, the "game stop flag", which is installed in so-called two-type models (game machines with a specific area), is also adopted for one-type models, and the game is being played while the settings are being changed or the settings are being confirmed. It can be migrated by setting the stop flag.

By executing such a process, the main control CPU 72 may restrict the execution of at least a part of the other process during the execution of one of the setting-related process and the base-related process. Yes (restriction means). That is, the main control CPU 72 executes at least a part of the base-related processes (steps S663 to S667) when the settings are being changed or the settings are being confirmed, that is, when the game is not available (step S662a; No). You can avoid it.

Further, by executing such a process, the main control CPU 72 determines whether or not the setting is being changed or the setting is being confirmed (whether or not one of the processes is being executed), and the determination result is affirmative. If, it is determined to limit the execution of at least a part of the base-related processing (the other processing), and if the judgment result is negative, at least a part of the base-related processing (the other processing) is processed. The determination process (determination process of step S662a) for determining not to restrict the execution of the above can be executed (restriction means). That is, the main control CPU 72 determines whether or not the game is playable (whether or not one of the processes is being executed), and if the determination result is negative, the base-related process (the other process). Judgment process (step S662a) that determines that the execution of at least a part of the processes is restricted, and if the determination result is affirmative, determines that the execution of at least a part of the base-related processes (the other process) is not restricted. Judgment processing) can be executed (restriction means).

Further, by executing such a process, the main control CPU 72 can execute a determination process (determination process in step S662a) as a process included in the process outside the area (second process) (second process). Processing execution means).

Step S663: In the main control CPU 72, whether or not the section is changed (whether or not the section for displaying the base has shifted to a new section), that is, the value of the total number of outs (total out counter) is 60,000. Is multiplied by n (integer) and 300 is added to confirm whether or not the value is larger than the value obtained by adding 300. Note that n is a value indicating the current section, and 1 is set as an initial value.

As a result, when it is confirmed that the section is changed (Yes), the main control CPU 72 executes step S664. On the other hand, if it cannot be confirmed that the section has been changed (No), the main control CPU 72 executes step S666.

Step S664: The main control CPU 72 executes a process of storing the value of the normal prize ball number (normal prize ball number counter) and the value of the normal out number (normal out counter) in the dedicated buffer. Further, the main control CPU 72 executes a process of adding 1 to the value n indicating the current section and updating it.

In this process, it is preferable not to save the base value. The reason for this is that when the total number of outs reaches a certain value (60,000) and the base display section is switched, "normal prize balls ÷ normal outs x 100 rounded" is calculated and the result is saved. However, it takes too much time for the main control CPU 72 to perform this calculation. Therefore, in this process, the optimum calculation method is to execute only the process of saving the normal number of prize balls and the normal number of outs, and then perform the calculation at an appropriate timing. This is a calculation method based on the idea of "shortening the processing time in the worst case", and is an important matter for the stable operation of gaming machines, especially pachinko machines. However, in this process, the main control CPU 72 executes a process of saving the base value (for example, a process of storing the base value calculated in step S667 described later as the base value of the previous section). May be good.

Step S665: The main control CPU 72 executes a process of clearing the value of the number of normal prize balls and the value of the number of normal outs. When this process is completed, the main control CPU 72 then executes the process of step S668.

Step S666: The main control CPU 72 executes a process of calculating the start address of the division task. By executing this process, the main control CPU 72 can execute an operation (processing such as division, subtraction, etc.) for calculating the base in the division task by a predetermined amount of processing (for example, 1 bit).

As described above, since it takes time to execute the division process on the main control CPU 72, in the present embodiment, the division process is executed in several times. Specifically, by preparing a table that stores the start address shown below, calculating the start address of the module to be executed this time, and setting that address in the program counter (PC), the division process can be performed a little. It is executed one by one (divided into small pieces).

(1) Wait processing before execution of division (starting address) (2) Division preparation processing (starting address) (3) Processing for finding the 64th place of the quotient (starting address) (4) 32 of the quotient Process to find the place (first address) (5) Process to find the 16th place of the quotient (first address) (6) Process to find the 8th place of the quotient (first address) (7) 4th place of the quotient Finding process (starting address) (8) Finding the 2nd place of the quotient (starting address) (9) Finding the 1st place of the quotient (starting address) (10) Rounding processing (starting address) ) (11) Wait processing after the end of division (start address) For example, in the "wait processing before division execution" in (1) above, "0" is set for the next task (next task determination status). If "1" is set for the next task, the "division preparation process" of (2) above is executed. By such control processing, the contents of the following division tasks can be executed little by little. The initial value of the next task is 0.

Step S667: The main control CPU 72 executes a process of executing (calling) a division task. This process is a process outside the region. The division task includes 11 tasks (division task 0 to division task 10), and the division task 0 to the division task 10 are called in order. The content of the division task will be described later.

By executing such a process, the main control CPU 72 executes a process (base-related process) for calculating the base to be displayed on the performance display monitor 200 as a process included in the process outside the area (second process). (Second processing execution means). The base-related processing includes at least one of the processing required to calculate the base and the processing required to display the base.

Step S668: The main control CPU 72 executes a process of returning the stack pointer and all the registers. When the above processing is completed, the main control CPU 72 returns to the main loop processing (FIG. 18).

FIG. 72 is a flowchart showing a procedure example of the processing of the division task 1. FIG. 73 is a flowchart showing a procedure example of the processing of the division tasks 2 to 8. FIG. 74 is a flowchart showing a procedure example of the processing of the division task 9. There are 0 to 10 division tasks, and the value of the next task is referred to in the process of calculating the start address of the division task (S666), and the start address of the division task to be actually executed is specified. Hereinafter, a procedure example will be described.

Here, the content of the division task processing described below is described in an example in which the operation of calculating the base is performed bit by bit in one call, but the operation of calculating the base is completed in one call. You may let me.

Further, after the completion of the base calculation, it may be monitored whether the value of the RAM outside the area is abnormal. The start of the division task (start of the base calculation) may be set in the performance display monitor display process.

If "0" is set for the next task, the division task 0 is executed. Although the content of the division task 0 is not particularly shown, the standby process before the division is executed is executed. In the final process of the division task 0, "1" is set for the next task.

When "1" is set for the next task, the division task 1 shown in FIG. 72 is executed. Hereinafter, the processing flow of the division task 1 will be described.

Step S730: The main control CPU 72 initializes an integer (variable) to “128 (2 × 64)” and executes a process of saving “128” in the integer buffer.

Step S732: The main control CPU 72 loads the value of the normal out number, multiplies the loaded value of the normal out number by an integer "128", and executes a process of saving the multiplied value as a divisor in the divisor buffer.

Step S734: The main control CPU 72 loads the value of the normal prize balls, multiplies the loaded value of the normal prize balls by "2" and "100", and saves the multiplied value as a division in the division buffer. To execute.

Step S736: The main control CPU 72 initializes the quotient to “0” and executes a process of saving “0” in the quotient buffer.

Step S738: The main control CPU 72 sets “2” for the next task.

When the above processing is completed, the main control CPU 72 returns to the performance display monitor aggregation division processing (FIG. 71).

When "2" to "8" are set for the next task, the division tasks 2 to 8 shown in FIG. 73 are executed. Hereinafter, the processing flow of the division tasks 2 to 8 will be described.

Step S740: The main control CPU 72 confirms whether or not the divisor saved in the divisor buffer is equal to or greater than the divisor saved in the divisor buffer.

As a result, when it is confirmed that the divisor saved in the divisor buffer is equal to or greater than the divisor saved in the divisor buffer (Yes), the main control CPU 72 executes step S742. On the other hand, when it cannot be confirmed that the divisor saved in the divisor buffer is equal to or greater than the divisor saved in the divisor buffer (No), the main control CPU 72 executes step S746.

Step S742: The main control CPU 72 subtracts the divisor saved in the divisor buffer from the divisor saved in the divisor buffer, and executes a process of saving the subtraction result as a new divisor in the divisor buffer.

Step S744: The main control CPU 72 adds a integer stored in the integer buffer to the quotient saved in the quotient buffer, and executes a process of saving the addition result as a new quotient in the quotient buffer.

Step S746: The main control CPU 72 divides the divisor saved in the divisor buffer by “2” (shifts by 1 bit to the right), and executes a process of saving the division result as a new divisor in the divisor buffer.

Step S748: The main control CPU 72 divides the integer saved in the integer buffer by "2" (shifts by 1 bit to the right), and executes a process of saving the division result as a new integer in the integer buffer.

Step S750: The main control CPU 72 sets the value obtained by adding 1 to the current task (the value of the current next task) in the next task.

When the above processing is completed, the main control CPU 72 returns to the performance display monitor aggregation division processing (FIG. 71).

When "9" is set for the next task, the division task 9 shown in FIG. 74 is executed. Hereinafter, the processing flow of the division task 9 will be described.

Step S752: The main control CPU 72 executes a process of confirming whether or not the value of the least significant bit of the quotient saved in the quotient buffer is “1”.

As a result, when it is confirmed that the value of the least significant bit of the quotient saved in the quotient buffer is "1" (Yes), the main control CPU 72 executes step S754. On the other hand, when it cannot be confirmed that the value of the least significant bit of the quotient saved in the quotient buffer is "1" (No), the main control CPU 72 executes step S756.

Step S754: The main control CPU 72 divides the quotient stored in the quotient buffer by "2" (shifts by 1 bit to the right), adds "1" to the division result, and executes a process of storing the quotient in the base buffer. ..

Step S756: The main control CPU 72 divides the quotient stored in the quotient buffer by "2" (shifts by 1 bit to the right), and executes a process of storing the division result in the base buffer.

Step S758: The main control CPU 72 sets “10 (value corresponding to standby processing)” for the next task.

When the above processing is completed, the main control CPU 72 returns to the performance display monitor aggregation division processing (FIG. 71).

If "10" is set for the next task, the division task 10 is executed. Although the content of the division task 10 is not particularly shown, the standby process after the division is executed is executed. In the final process of the division task 10, "0" is set for the next task.

Next, the display mode of the performance display monitor 200 and the calculation method of the base (base ratio) displayed on the performance display monitor 200 will be described.

FIG. 75 is a diagram illustrating a display mode of the performance display monitor 200. The main control device 70 displays on the performance display monitor 200 the base when the gaming state is the low-probability non-time shortening state, the high-probability non-time shortening state, and the left-handed instruction. Here, the base is calculated for each preset section (for example, every 60,000 total outs). The base (percentage:%) can be calculated by base = number of normal prize balls ÷ number of normal outs × 100.

As shown in FIGS. 75A and 75B, the performance display monitor 200 switches between the base of the current section and the base of the previous section at preset intervals (for example, several seconds). Is displayed.

In the performance display monitor 200, the identifiers "bL." Or "b6." For identifying whether it is the base of the current section or the base of the previous section are displayed by the 7 segments 201 and 202. Further, in the performance display monitor 200, the base corresponding to the identifier "bL." Or "b6." Is displayed as two-digit numerical information by the seven segments 203 and 204.

For example, assuming that the base of the current section is 30%, when displaying the base of the current section, "bL." Is displayed in the 7 segments 201 and 202 as shown in FIG. 75 (A). Then, "30" is displayed in the 7 segments 203 and 204. Further, assuming that the base of the previous section is 38%, when displaying the base of the previous section, "b6." Is displayed in the 7 segments 201 and 202 as shown in FIG. 75 (B). Then, "38" is displayed in the 7-segments 203 and 204.

FIG. 76 is a diagram illustrating a base section displayed on the performance display monitor 200. Here, between the time when the pachinko machine 1 is manufactured and the time when the pachinko machine 1 is installed in the hall (game hall) and the game is played by the player, inspections at the time of manufacturing, test runs (operation checks) in the hall, etc. are performed. Will be. Game balls will be fired and ejected during such inspections during manufacturing and test runs in halls, but if the number of out balls and the number of ejects during this period are counted, the game will be played by the player. There is a risk that the base cannot be calculated accurately during the period.

Therefore, as shown in FIG. 76 (A), the first section (non-target section) in which the total number of out balls detected by the out switch 99 is 0 to 300 is inspected at the time of manufacturing. It is excluded from the target for which the base is calculated by regarding the number of out balls detected before the game by the player, such as a test run in a hall.

Similarly, the number of payouts paid out in the section where the number of out balls is 0 to 300 is also excluded from the target for calculating the base. In this non-target section, as shown in FIG. 76 (B), when displaying the base of the current section, the identifier "bL." Is blinked and "---" is displayed as the base value. Lights up and displays. Further, since the previous section does not exist, when the base of the previous section is displayed, the identifier "b6." Is blinked and "---" is lit as the base value.

Then, the number of out balls from 301 to 60300 is set as the first section, and in the first section, the base is calculated at any time (in real time), and when the base of the current section is displayed, the identifier "bL." Is displayed, and the calculated base value is lit up. At this time, while the number of out balls is from 301 to 6299 (while the number of out balls in the section is 5999 or less), the identifier "bL." Is displayed in blinking to calculate the base of the current section. Notify that the sample is small and the base is not stable. After that, when the number of out balls becomes 6300 or more (the number of out balls in the section becomes 6000 or more), there are many samples for calculating the base of the current section by lighting and displaying the identifier "bL.". , Notifies that the base is stable.

In addition, since the previous section does not exist in the first section, when displaying the base of the previous section, the identifier "b6." Is blinked and "---" is lit as the base value. indicate.

Further, in the second section where the number of out balls is 60301 to 120300, the base is calculated at any time (in real time) as in the first section, and when the base of the current section is displayed, the number of out balls is displayed. The identifier "bL." Is lit or blinking according to the above, and the calculated base is displayed. Further, in the second section, when displaying the base of the previous section, the identifier "b6." Is lit and displayed, and the final base of the first section is lit and displayed.

In this way, every 60,000 out balls (every nth section) excluding the first 300 out balls, the base calculated in real time is displayed as the base of the current section, and the n-1th section. The final base of is displayed as the base of the previous section.

As a result, the number of out balls and the number of discharged balls before the game by the player, such as inspection at the time of manufacturing and test run (operation check) in the hall, can be excluded from the target for calculating the base, and the base can be excluded. It can be calculated (displayed) accurately.

When calculating the base, the base may temporarily exceed 100%. For example, when the first ball in the section enters the middle-starting winning opening 26, the number of out balls is 1, while the number of payouts is the winning ball obtained by entering the middle-starting winning opening 26. It will be a number (eg 4) and the base will be 400%. In such a case, since the performance display monitor 200 can display the base only with two-digit numerical information, it is notified that the base exceeds 100% by lighting and displaying "99.".

FIG. 77 is a diagram illustrating a base calculation method. Here, a method of calculating the base assuming that the normal number of prize balls is "3456" and the normal number of outs is "10000" will be described.

As described above, the base is a value obtained by finally converting the number of emissions with respect to the number of out balls for each section into a percentage. Then, when displaying such a percentage, only two digits after the decimal point are required for the result of division.

Then, the process of calculating the value of such a percentage (the process of "converting to%") corresponds to multiplying by the multiplicand "100". Therefore, it can be expressed by the formula of base = number of normal prize balls ÷ number of normal outs × 100. However, when the number of normal prize balls ≤ the number of normal outs, if the calculation is performed in the order of this formula, the value will be a value after the decimal point, and for example, the main controller 70 cannot calculate.

Therefore, the calculation order is changed, and the calculation is performed in the order of base = normal prize ball number × 100 ÷ normal out number (first, the normal prize ball number is multiplied by the multiplicand, and then divided by the normal out number). By doing so, it is possible to complete the operation result only with an integer without performing the operation after the decimal point.

Further, in the present embodiment, the value after the decimal point when converted to a percentage is rounded off. However, since the main controller 70 cannot handle numbers after the decimal point and the calculation is performed in binary, the number of normal prize balls x the number of multiplicands "100" and the number of normal outs are doubled first to make the base 2 Find a double value. Then, if the least significant bit (corresponding to the value after the decimal point) of twice the value (binary number) of the obtained base is "1" (if the value after the decimal point is 0.5 or more), the calculated base After adding "1" to the doubled value, the value is halved (shifted by 1 bit to the right) to round up the decimal point, and the lowest bit (corresponding to the value after the decimal point) of the doubled value of the obtained base. ) Is "0" (if the number after the decimal point is less than 0.5), the value after the decimal point is rounded down by halving the value of the obtained base as it is (shifting to the right). As a result, the value after the decimal point can be rounded off.

Specifically, in the main control device 70 (main control CPU 72), the division is replaced with a subtraction, and the division "691200" which is 2 x the number of normal prize balls (3456) x 100 is changed to the integer "10000" which is the normal out number. Is multiplied by a predetermined integer "128 (2 x 2 to the 6th power)" which is a product of 2 to the power of 2, and then the integer is changed from "64 (2 x 2 to the 5th power)" → "32". (2x2 to the 4th power) "→" 16 (2x2 to the 3rd power) "→" 8 (2x2 to the 4th power) "→" 4 (2x2 to the 1st power) "→" 2 (2) Change in the order of "x2 to the 0th power)" → "1 (2 x 2 to the -1st power)" (shift 1 bit to the right), multiply by the divisor, and subtract from the dividend. Here, the integer to be multiplied by the divisor starts from 2 × 64 because the display of the base is in the range of 0 to 99, and when the base is 100% or more, "99.9" is displayed. Therefore, it is not necessary to subtract a numerical value of "2 x 128 (2 to the 7th power)" or more.

Specifically, as shown in FIG. 77, in the first calculation, the division <division, so the process proceeds to the next. Then, in the second calculation, since the divisor ≥ divisor, the divisor "64 (2 x 32) x 10000" is subtracted from the divisor "691200" to update the divisor to "51200" and the quotient "0" to "64". Is added to update the quotient to "64 (1000000B in binary)". In the third to fifth operations, the division is less than the divisor, so the process proceeds to the next step. In the sixth calculation, the division ≥ divisor, so the divisor "4 (2 x 2) x 10000" is subtracted from the division "51200" to update the division to "11200" and the quotient "64" to "4". In addition, the quotient is updated to "68 (1000100B in binary)". In the seventh operation, the division <division, so the process proceeds to the next. In the 8th calculation, since the division ≥ divisor, the division "1 (2 x 0.5) x 10000" is subtracted from the division "11200" to update the division to "1200" and the quotient "68" to "1". Is added to update the quotient to "69 (1000101B in binary)".

After that, in the ninth operation, the updated quotient "69 (1000101B in binary)" is divided by 2 (shifted by 1 bit to the right) to obtain the final base. At this time, if the quotient is simply divided by 2, the quotient becomes "34.5". However, since the main controller 70 cannot handle the decimal point as described above, the case where the least significant bit of the quotient is "1B". , After shifting the quotient "69" by 1 bit to the right, add "1" to make the quotient "35 (0100011B in binary)".

According to such an operation example, division can be realized only by simple operations such as addition, subtraction, and multiplication, and by only integers. Further, here, since it is sufficient to repeat the calculation nine times, the calculation process can be performed quickly. In addition, the base decimal point can be rounded off.

[Basic operation of setting-related processing] FIGS. 78 to 80 are timing charts showing the basic operation of setting-related processing.

FIG. 78 shows an example when a process related to setting confirmation (mode for confirming the setting) is executed. FIG. 79 shows an example when a process related to setting change (mode for changing setting) is executed. FIG. 80 shows an example when an abnormality occurs in the RAM.

Further, (A) in each figure shows an ON or OFF state of the power supply. In each figure (B), the ON or OFF state of the setting key is shown. In each figure (C), the ON or OFF state of the RAM clear switch 304 is shown. In each figure (D), the ON or OFF state of the setting switch is shown. When the RAM clear switch 304 and the setting change switch are also used, either one of (C) or (D) in each figure may be omitted, or (C) and each in each figure may be omitted. (D) in the figure can be combined.

In each figure (E), the contents displayed on the performance display monitor 200 are shown. In each figure, (F) shows an ON or OFF state of external information (for example, a security signal). In each figure (G), the content to be displayed on the error display (for example, the liquid crystal display 42) is shown. In each figure (H), the change of the gaming state is shown. In each figure, (I) shows the state of the switch.

[Confirmation of setting] In FIG. 78 (A): The power is turned off at time t1, and the power is turned on at time t3.

In FIG. 78 (B): The setting key is turned on at time t2, and the setting key is turned off at time t6. From time t6 to time t7, the setting key needs to be OFF, but after time t7, the setting key may be ON or OFF.

In FIG. 78 (C): The RAM clear switch is OFF from time t1 to time t5. After the time t5, the RAM clear switch may be ON or OFF.

In FIG. 78 (D): The setting switch is OFF from time t1 to time t3. After the time t3, the setting switch may be ON or OFF.

In FIG. 78 (E): The performance display monitor 200 is hidden from time t1 to time t5. From time t5 to time t7, the performance display monitor 200 displays the set value. After time t7, the performance display monitor 200 displays the base.

In FIG. 78 (F): External information is OFF from time t1 to time t3. The external information is ON from the time t3 to the time t6. The external information is OFF after the time t6. The ON state of the external information may be extended until the time t7. The external information may be output for at least a certain period of time (50 ms) or longer.

In FIG. 78 (G): The error display is hidden from time t1 to time t5. From time t5 to time t6, the error display is a setting confirmation display. The setting confirmation display is, for example, displaying the character information "setting confirmation in progress" on the liquid crystal display 42. The error display is hidden after time t6. The display during setting confirmation may be extended to time t7. The period of external information and error display is the same as the period of completion of setting confirmation, but it is not necessary to match. The period of the setting confirmation end is the processing time required for the transition from the setting confirmation end to the game-enabled state. The shortest time to complete the setting confirmation can be 0 ms.

In FIG. 78 (H): The gaming state is power failure from time t1 to time t3. The gaming state is activated from time t3 to time t4. From time t4 to time t5, the game state is switch confirmation. From time t5 to time t6, the game state is a setting confirmation. From time t6 to time t7, the game state is the end of setting confirmation. After the time t7, the gaming state is the playable state.

In FIG. 78 (I): All switches are invalid from the time t1 to the time t4. From time t4 to time t7, the state of the switch is invalid except for the switch related to the setting change device. After time t7, all switches are valid.

[Change of setting] In FIG. 79 (A): The power is turned off at time t1, and the power is turned on at time t3.

In FIG. 79 (B): The setting key is turned on at time t2, and the setting key is turned off at time t6. From time t6 to time t7, the setting key needs to be OFF, but after time t7, the setting key may be ON or OFF.

In FIG. 79 (C): The RAM clear switch is OFF from time t1 to time t3. The RAM clear switch is ON from time t3 to time t5. After the time t5, the RAM clear switch may be ON or OFF. The RAM clear switch may be turned on (or pressed) at time t2 in the same manner as the setting key.

In FIG. 79 (D): The setting switch is OFF from time t1 to time t3. From time t3 to time t5, the setting switch may be ON or OFF. Every time the setting switch is pressed from time t5 to time t6, the setting switch is turned on. After time t6, the setting switch may be ON or OFF.

In FIG. 79 (E): The performance display monitor 200 is hidden from time t1 to time t5. From time t5 to time t7, the performance display monitor 200 displays the set value. After time t7, the performance display monitor 200 displays the base.

In FIG. 79 (F): External information is OFF from time t1 to time t3. The external information is ON from the time t3 to the time t6. External information is OFF from time t6 to time t8. The ON state of the external information may be extended until the time t7. The external information is ON from the time t8 to the time t9. The external information is OFF after the time t9. The external information may be output for at least a certain period of time (50 ms) or longer. The external information (security / initialization) to be output from time t8 to time t9 may be output for a certain period of time (50 ms) or more, and external information may be continuously output depending on the output timing of the external information. ..

In FIG. 79 (G): The error display is hidden from time t1 to time t5. From time t5 to time t6, the error display is a setting changing display. The setting changing display is, for example, displaying the character information "setting is being changed" on the liquid crystal display 42. The error display is hidden from time t6 to time t7. The display during setting change may be extended to time t7. From time t7 to time t10, the error display is an initialization display. The initialization display is, for example, displaying the character information "Initialization completed" on the liquid crystal display 42. The error display is hidden after time t10. The period of external information and error display is the same as the period of setting change end, but it is not necessary to match. The setting change end period is the processing time required for the transition from the setting change end to the game-enabled state. The shortest time to complete the setting change can be 0 ms.

In FIG. 79 (H): The gaming state is power failure from time t1 to time t3. The gaming state is activated from time t3 to time t4. From time t4 to time t5, the game state is switch confirmation. From time t5 to time t6, the game state is a setting change. From time t6 to time t7, the game state is the end of setting change. After the time t7, the gaming state is the playable state.

In FIG. 79 (I): All switches are invalid from the time t1 to the time t4. From time t4 to time t7, the state of the switch is invalid except for the switch related to the setting change device. After time t7, all switches are valid. It is preferable to execute the RAM clear from the time t5 to the time t7.

[When RAM is abnormal] In FIG. 80 (A): The power is turned off at time t1 and turned on at time t3.

In FIG. 80 (B): The setting key is OFF at time t1. After the time t1, the setting key may be ON or OFF.

In FIG. 80 (C): The RAM clear switch is OFF at time t1. After time t1, the RAM clear switch may be ON or OFF. The setting key and the RAM clear switch may be shifted to the setting change state when the transition condition for changing the setting is satisfied.

In FIG. 80 (D): The setting switch is OFF at time t1. After the time t1, the setting switch may be ON or OFF.

In FIG. 80 (E): The performance display monitor 200 is hidden from time t1 to time t5. After time t5, the performance display monitor 200 displays the content corresponding to the error.

In FIG. 80 (F): External information is OFF from time t1 to time t5. The external information is ON after the time t5.

In FIG. 80 (G): The error display is hidden from time t1 to time t5. After the time t5, the error display is a game stopped display. The game stopped display is, for example, displaying the character information such as "an error is occurring" or "the game is stopped" on the liquid crystal display 42.

In FIG. 80 (H): The gaming state is power failure from time t1 to time t3. The gaming state is activated from time t3 to time t4. From time t4 to time t5, the game state is switch confirmation. After the time t5, the game state is the game stopped.

In FIG. 80 (I): All switches are invalid from the time t1 to the time t4. From time t4 to time t7, the state of the switch is invalid except for the switch related to the setting change device. After time t5, all switches are invalid.

In addition to the above basic configuration of the timing chart, the following modification examples are also possible. (1) As a transition condition to the setting change state (setting change mode) or the setting confirmation state (setting confirmation mode), the condition that "the inner frame is being opened" is also set, and "the setting key is OFF and inside". The setting change state or setting confirmation state ends when the frame closure continues for a certain period of time (100 ms continuation). (1a) The setting key OFF state continues for a certain period of time (for example, 100 ms continuation) without considering the state of the inner frame. Depending on the situation, the setting change state or the setting confirmation state may be terminated.

(2) When the RAM clear switch is pressed while the setting key is OFF, the setting change state or the setting confirmation state ends.

(3) Before starting the setting confirmation, the power restoration process is performed. If there is an abnormality such as a checksum, the RAM is cleared. Even in this case, the gaming machine status flag, set value, and outside the area are not cleared. (3a) When the checksum is abnormal, the gaming machine state flag, the set value, and the memory outside the area may be cleared to set the RAM abnormal error state.

(4) When the setting change or setting confirmation condition is satisfied, the gaming machine status flag is set. In this case, the gaming machine status flag is set in the initial flow (for example, CPU initialization processing), and the setting is changed or changed based on the content of the gaming machine status flag during execution of the timer interrupt processing after shifting to the main loop. Executes the setting confirmation process.

(5) When the setting change is completed, the program jumps to the beginning of the program (for example, CPU initialization processing), a checksum error is generated, and RAM other than the set value is cleared.

(6) Immediately after the setting change process is completed, the game is ready for play. That is, it is not a condition that the RAM clear is executed again after the setting change process is completed, or that a predetermined time elapses before the game is changed to the playable state. (6a) For reasons such as preparation of the effect control device, only the elapse of a predetermined time may be a condition.

(7) While the setting is being changed, the game stop flag is set so that the processing related to the game is not performed. (8) The common main loop processing and the common timer interrupt processing are used in the playable state, the setting change state, and the setting confirmation state.

(9) The timer interrupt common to the game available state, the setting change state, and the setting confirmation state is at least one of the dynamic port output process, the port input process, the external information management process, and the port output process.

(10) Separate main loop processing and separate timer interrupt processing are used in the playable state, the setting change state, and the setting confirmation state. (11) In the playable state, the timer interrupt by the first timer (timer 0) is used, and in the setting change state or the setting confirmation state, the timer interrupt by the second timer (timer 1) is used. The interrupt period may be the same or different.

(12) Use the same RAM clear switch and setting change switch (also used). (13) Use separate RAM clear switch and setting change switch (do not use them together).

The following is a modification of the security signal. (14) A security signal is output only while the setting is being changed, and is not output while the setting is being confirmed. (15) A security signal is output during setting change and setting confirmation, and the output time is different. For example, a security signal is output for 30 seconds while the setting is being changed, and a security signal is output for 5 seconds while the setting is being confirmed.

(16) While the setting is being changed, both the security signal and the out signal are output. (17) A "setting change signal" is newly added, and the newly added "setting change signal" is output during the setting change.

(18) One of the existing signals (big hit signal 4, etc.) is used as a setting change signal and is not used in conventional applications. (19) During the setting change, the "security signal" and the "setting change signal" are output.

(20) A security signal is output each time the setting change switch (RAM clear switch) is pressed during the setting change. (21) When the setting change is completed and the setting is confirmed, the output of the security signal is started. When the setting change is completed and the setting is confirmed, the security signal output is terminated.

(22) When the setting change is completed and the setting is confirmed, the pulse of the setting change signal is sent for the number of times of setting (for example, the number of times the setting change switch is pressed and the number of times corresponding to the set value after confirmation). Output. (23) When the setting key is ON (when the setting key is turned) in the game-enabled state, a security signal is output.

[Example of processing at power-on] FIGS. 81 to 83 are diagrams showing an example of processing at power-on.

FIG. 81 shows an example of the first processing in the case where the previous power off is in the game-enabled state and the RAM is normal (the backup flag is normal) when the power is restored. FIG. 82 shows an example of the second processing when the previous power off is in the process of confirming the setting and the RAM is normal when the power is restored. FIG. 83 shows an example of the third processing in the case where the RAM is abnormal (the backup flag is abnormal) when the power is restored, regardless of the state of the previous power off.

As shown in FIG. 81, when the setting key is ON and the RAM clear switch is ON, (1) the contents of the memory (RAM76) clear data other than the data related to the setting-related processing and the performance display monitor-related processing. Then, (2) the state shifts to the setting change state after the power is turned on, and (3) the performance display monitor 200 displays the set value.

If the setting key is ON and the RAM clear switch is OFF, (4) the contents of the memory are not changed, (5) the setting confirmation state is entered after the power is turned on, and (6) the performance display. The monitor 200 displays the set value.

Further, when the setting key is OFF and the RAM clear switch is ON, (7) the contents of the memory clear the data other than the data related to the setting-related processing and the performance display monitor-related processing, and (8) after the power is turned on. Shifts to the playable state, and (9) the performance display monitor 200 displays the base.

Furthermore, when the setting key is OFF and the RAM clear switch is OFF, (10) the contents of the memory are not changed, (11) the game shifts to the playable state after the power is turned on, and (12) the performance. The display monitor 200 displays the base.

As shown in FIG. 82, when the setting key is ON and the RAM clear switch is ON, (1) the contents of the memory (RAM76) clear data other than the data related to the setting-related processing and the performance display monitor-related processing. Then, (2) the state shifts to the setting change state after the power is turned on, and (3) the performance display monitor 200 displays the set value.

If the setting key is ON and the RAM clear switch is OFF, (4) the contents of the memory are not changed, (5) the setting confirmation state is entered after the power is turned on, and (6) the performance display. The monitor 200 displays the set value.

Further, when the setting key is OFF and the RAM clear switch is ON, (7) the contents of the memory clear the data other than the data related to the setting-related processing and the performance display monitor-related processing, and (8) after the power is turned on. Shifts to the playable state, and (9) the performance display monitor 200 displays the base.

Furthermore, when the setting key is OFF and the RAM clear switch is OFF, (10) the contents of the memory are not changed, and (11) after the power is turned on, the state shifts to the setting confirmation state or the playable state. (12) The performance display monitor 200 displays a set value or a base. In addition, when shifting to the setting confirmation state in the above (11), it is preferable to display the set value in the above (12), and when shifting to the playable state in the above (11), the base in the above (12). Is preferably displayed.

As shown in FIG. 83, when the setting key is ON and the RAM clear switch is ON, (1) the contents of the memory (RAM76) clear the data other than the data related to the performance display monitor related processing, and (2). ) After the power is turned on, the setting shift state is entered, and (3) the performance display monitor 200 displays the set value. In the above (1), when the RAM is an abnormal value, the data related to the performance display monitor related processing may be cleared.

If the setting key is ON and the RAM clear switch is OFF, (4) the contents of the memory are not changed, (5) the game is stopped after the power is turned on, and (6) the performance display. The monitor 200 displays an error code (for example, "E" is displayed).

Furthermore, when the setting key is OFF and the RAM clear switch is ON, (7) the contents of the memory are not changed, (8) the game shifts to the game stop state after the power is turned on, and (9) the performance display. The monitor 200 displays an error code.

Furthermore, when the setting key is OFF and the RAM clear switch is OFF, (10) the contents of the memory are not changed, (11) the game is stopped after the power is turned on, and (12) performance. The display monitor 200 displays an error code.

Then, the pachinko machine 1 of the present embodiment can execute the processing of the contents shown in FIGS. 78 to 83 by the main control device 70 or the effect control device 124. The contents of the processes shown in FIGS. 78 to 83 may not be executed depending on the model.

[Launch Position Management Process] FIG. 84 is a flowchart showing a procedure example of the launch position management process. Hereinafter, each procedure will be described.

Step S1100: The main control CPU 72 confirms whether or not the value of the normal game management phase is “03H” to “07H”.

[Normal game management phase] The main control CPU 72 sets the value (inside the key brackets) of the normal game management phase according to the progress status (1) to (8) of the game corresponding to the normal symbol as follows. (1) Normal symbol change waiting state: "00H" (2) Normal symbol change display state: "01H" (3) Normal symbol stop symbol display state: "02H" (4) Variable start winning device (normal electric combination) (Things) Waiting for opening: "03H" (5) Variable start winning device (ordinary electric accessory) Opening state: "04H" (7) Variable starting winning device (ordinary electric accessory) Closed state: "05H" (8) Variable start winning device (ordinary electric accessory) During operation end time State: "06H" (9) Variable start winning device (ordinary electric accessory) Effective state after closing: "07H"

Here, when the value of the normal game management phase is set or updated, the main control CPU 72 generates a normal game management phase command that reflects the value. The normal game management phase command is transmitted to the effect control device 124 in the subcommand transmission process.

As a result, when it is confirmed that the value of the normal game management phase is "03H" to "07H" (Yes), the main control CPU 72 executes step S1140. On the other hand, when it cannot be confirmed that the value of the normal game management phase is "03H" to "07H" (No), the main control CPU 72 executes step S1110.

Step S1110: The main control CPU 72 confirms whether or not the value of the special game management phase is “03H” to “07H”.

[Special Game Management Phase] The main control CPU 72 sets the value (inside the key brackets) of the special game management phase according to the progress status (1) to (8) of the game corresponding to the special symbol, for example, as follows. (1) Special symbol change waiting state: "00H" (2) Special symbol change display state: "01H" (3) Special symbol stop symbol display state: "02H" (4) Variable winning device (special electric accessory) ) Waiting for opening: "03H" (5) Variable winning device (special electric accessory) Opening state: "04H" (6) Variable winning device (special electric accessory) Closed state: "05H" (7) Variable winning device (Special electric accessory) State during operation end time: "06H" (8) Variable winning device (special electric accessory) Effective state after closing: "07H"

Here, when the value of the special game management phase is set or updated, the main control CPU 72 generates a special game management phase command that reflects the value. The special game management phase command is transmitted to the effect control device 124 in the subcommand transmission process.

As a result, when it is confirmed that the value of the special game management phase is "03H" to "07H", that is, during the big hit game or the small hit game (Yes), the main control CPU 72 executes step S1140. On the other hand, when it cannot be confirmed that the value of the special game management phase is "03H" to "07H" (No), that is, when it cannot be confirmed that the big hit game or the small hit game is in progress, the main control CPU 72 steps. Execute S1120.

Step S1120: The main control CPU 72 confirms whether or not the internal state is the time shortened state. Whether or not the time is shortened can be confirmed by the time reduction function operation flag.

As a result, when it is confirmed that the internal state is the time shortened state (Yes), the main control CPU 72 executes step S1140. On the other hand, when it cannot be confirmed that the internal state is the time shortened state (No), the main control CPU 72 executes step S1130.

Step S1130: The main control CPU 72 sets the firing position designation status to a value (0) corresponding to left-handed striking.

Here, the "launch position designation status" is a variable that holds whether the current gaming state is a gaming state corresponding to left-handed hitting or a gaming state corresponding to right-handed hitting. Specifically, if "0" is set in the launch position designation status, it indicates that the current gaming state is the gaming state corresponding to left-handed (left-handed state), and the launch position designation status is "1". If is set, it indicates that the current gaming state is the gaming state corresponding to right-handed hitting (right-handed hitting state).

Therefore, the main control CPU 72 can confirm whether the current gaming state is the gaming state corresponding to left-handed hitting or the gaming state corresponding to right-handed hitting by referring to the value of the firing position designation status. it can. Further, the value of the firing position designation status is stored in the RAM 76, and when a power off state occurs, the value is backed up.

Step S1140: The main control CPU 72 sets the firing position designation status to the value (1) corresponding to right-handed striking.

Step S1150: When the launch position designation status is set in step S1130 or step S1140, the main control CPU 72 next generates a launch position designation command (launch position designation information notification means). Here, the main control CPU 72 generates a command that reflects the value of the launch position designation status as the launch position designation command. Specifically, when the value of the launch position designation status is the value (0) indicating left-handedness, the main control CPU 72 generates a launch position designation command indicating left-handed strike. On the other hand, when the value of the launch position designation status is the value (1) indicating a right-handed strike, the main control CPU 72 generates a launch position designation command indicating a right-handed strike. The launch position designation command generated here is output to the effect control device 124 in the subcommand transmission process.

When the above procedure is completed, the main control CPU 72 returns to the timer interrupt processing (FIG. 24).

[Game flow in non-time saving state]
FIG. 85 is a diagram illustrating a game flow in a non-time shortened state.

When starting a game with a pachinko machine, the game is started from the [F1] normal mode in the [F0] non-time shortened state. In the "normal mode", the winning probability of the special symbol lottery is the "low probability state", and the winning probability of the normal symbol lottery is the "low probability state". In this way, the [F1] normal mode is in the "low probability non-time shortened state". Therefore, by inserting the game ball into the middle start winning opening 26, the first special symbol starts to fluctuate and the game is started. proceed.

As the [F0] non-time reduction state, there is a [F2] festival mode in addition to the [F1] normal mode. [F2] The festival mode is a low-probability or high-probability non-time reduction state.

In the [F2] festival mode, when the [F3] specified condition (for example, the condition that the special symbol fluctuates 10 times in the low probability non-time shortened state) is satisfied, the mode shifts to the [F1] normal mode.

In [F1] normal mode or [F2] festival mode, if [F4] "11 round normal symbol" or "11 round probability variation symbol 11" is applicable, [F5] 11 round jackpot game (challenge bonus) is executed. In the [F6] treasure challenge production, the [F7] failure production is executed, and the mode shifts to the [F2] festival mode.

[F6] The treasure challenge production is a probabilistic promotion judge production that is executed using the first to tenth fluctuations after the end of the jackpot game.

In [F1] normal mode or [F2] festival mode, if [F8] "11 round probability variation symbols 1 to 10" is applicable, [F5] 14 round jackpot game (challenge bonus) is executed, and [F6] treasure challenge. In the production, the [F9] success production is executed, and the process shifts to the [F10] fireworks rush. [F10] The fireworks rush is in a state of shortening the time with high probability.

In [F1] normal mode or [F2] festival mode, if [F11] "15 round probability variation symbol 1" is applicable, [F12] 15 round jackpot game (special bonus) is executed, and [F10] fireworks rush as it is. Transition. In this case, the [F6] treasure challenge effect is not executed.

In [F1] normal mode or [F2] festival mode, if [F13] "6 round probability variation symbol" or "8 round probability variation symbol" is applicable, the mode transition effect is executed together with the 6 round jackpot game or the 8 round jackpot game. , As it is, shift to [F10] fireworks rush.

[Game flow in a time-saving state]
FIG. 86 is a diagram illustrating a game flow in a time-reduced state.

The [G0] time reduction state is roughly divided into [G1] fireworks rush (high probability time reduction state) and [G2] coast mode (low probability time reduction state).

In [G1] fireworks rush or [G2] coast mode, if [G3] "15 round probability variation symbol 2-7" or "3 round probability variation symbol" is applicable, [G4] battle reach effect executed during variable display In [G5] victory production is executed, and after the end of the [G6] 15 round jackpot game (fireworks bonus), the game shifts to [G1] fireworks rush.

On the other hand, in [G1] fireworks rush or [G2] coast mode, if [G7] "5 round normal symbol" is applicable, [G8] defeat effect is executed in the battle reach effect executed during [G4] variable display. Then, after the end of the [G9] 5-round jackpot game (normal bonus), the mode shifts to the [G2] coast mode.

In addition, in [G1] fireworks rush or [G2] coast mode, if [G10] "5 round probability variation symbol" is applicable, [G8] defeat effect is executed in the battle reach effect executed during [G4] fluctuation display. However, during the execution of the [G9] 5-round jackpot game (normal bonus), the [G11] major role promotion effect (reversal effect, revival effect, and probability change promotion effect are executed), and after the end of the jackpot game, [G1] Move to fireworks rush.
It should be noted that the above game flow shows an example of a typical game flow and does not cover all the game flows.

[Example of production image]
Next, the effect image actually displayed on the liquid crystal display 42 in the pachinko machine 1 will be described with some examples. As described above, when the internal lottery of the jackpot is performed in the pachinko machine 1, the fluctuation pattern (variation time) is determined under the control of the main control CPU 72, and the fluctuation display by the first special symbol and the second special symbol is performed. (Design display means). However, as described above, since the first special symbol and the second special symbol itself are lit / blinking by the 7-segment LED, they lack the apparent appealing power. Therefore, in the pachinko machine 1, the variable display effect using the effect pattern is performed as described above.

The effect symbols include, for example, a left effect symbol, a middle effect symbol, and a right effect symbol, which are displayed side by side on the screen of the liquid crystal display 42 (see FIG. 1). ). Each production pattern is, for example, a design of a picture card with a character attached to the numbers "1" to "9". Here, the left effect symbol, the middle effect symbol, and the right effect symbol all form a symbol sequence in which the numbers are arranged in descending order of "9" to "1". Such a symbol sequence is displayed in a variable manner so as to flow (scroll) in the vertical direction in each of the left area, the middle area, and the right area on the screen.

FIG. 87 is a continuous view showing an example of an effect image corresponding to the variable display and the stop display of the special symbol. It should be noted that here, regarding the fluctuation of the special symbol at the time of non-winning (missing), an example of the variation display effect and the stop display effect (result display effect) performed by using the effect symbol is shown. This variable display effect is performed between the time when the special symbol (here, the first special symbol is used, but the second special symbol may be used) starts the variable display and the time when the stop display (including the fixed stop) is performed. It corresponds to a series of productions. Further, the stop display effect is an effect of expressing the stop display of the special symbol and the result of the internal lottery at that time as a combination of the effect symbols. Here, first, before explaining the specific contents of the control process, the basic flow of the variation display effect and the stop display effect for each variation adopted in the present embodiment will be described.

[Before fluctuation display]
In FIG. 87 (A): For example, in a state before the first special symbol starts to fluctuate (a state in which the demonstration effect is not in progress), a large row of three effect symbols is displayed on the screen of the liquid crystal display 42. ing. At this time, the effect symbol is also stopped and displayed in accordance with the stop display of the first special symbol or the second special symbol.

[Memory number display effect]
Further, in the pre-variation display area X1 at the lower part of the screen of the liquid crystal display 42, markers (reference numerals M1 and M2 are added in the drawings) indicating the operating memory numbers of the first special symbol and the second special symbol are displayed. ing. Each of the markers M1 and M2 represents the number of working memories of the first special symbol and the second special symbol (the number of displayed numbers of the first special symbol operating memory lamp 34a and the second special symbol operating memory lamp 35a). Therefore, the number of displayed items increases or decreases in accordance with the change in the number of working memories during the game.

Further, in the markers M1 and M2, the marker M1 corresponding to the first special symbol is displayed as, for example, a circle (○) in order to facilitate visual discrimination, and the marker M2 corresponding to the second special symbol is, for example, a heart. It is displayed as a figure of. In the illustrated example, all four markers M1 are lit and displayed to indicate that the number of working memories of the first special symbol is four, and all the markers M2 are hidden (indicated by a broken line). Indicates that the number of working memories of the second special symbol is 0.

Further, during the variable display of the effect symbols, for example, the fourth symbol (reference numerals Z1 and Z2 are attached in the figure) is displayed on the upper right of the screen of the liquid crystal display 42. The fourth symbols Z1 and Z2 are "fourth effect symbols" following the left, middle, and right effect symbols, and are displayed in a variable manner in synchronization with the change display of the effect symbols. It should be noted that the fourth symbols Z1 and Z2 are merely colored simple marks (for example, a figure of "□"), and for example, a variable display can be expressed by changing the display color. The fourth symbol Z1 corresponds to the first special symbol, and the fourth symbol Z2 corresponds to the second special symbol.

Further, the fourth symbols Z1 and Z2 are stopped and displayed in a mode corresponding to the detachment (for example, a white display color). This is for objectively clarifying that the stop display effect is correctly performed and that the pachinko machine 1 is operating normally. Therefore, if the result of the internal lottery is actually, for example, "15 round jackpot" instead of "missing", the fourth symbols Z1 and Z2 are stopped and displayed in a mode corresponding to them (for example, red display color). The fourth symbols Z1 and Z2 may be displayed by LEDs arranged on the board instead of being displayed on the liquid crystal screen.

[Start of variable display production]
In FIG. 87 (B): For example, in synchronization with the start of fluctuation of the first special symbol, the variation display effect is started by scrolling the three symbol strings on the display screen of the liquid crystal display 42 (effect execution). means). That is, in synchronization with the start of fluctuation of the first special symbol, the row of the left effect symbol, the middle effect symbol, and the right effect symbol scrolls (flows) in the vertical direction on the display screen of the liquid crystal display 42 to display the variation. The production starts. Further, the markers M1 and M2 are displayed in the pre-variation display area X1 of the band-shaped portion in the lower portion of the liquid crystal display 42 before the start of the fluctuation, but are displayed in the lower left portion of the liquid crystal display 42 after the start of the fluctuation. It moves to the changing display area X2 by the pedestal image, and continues to be displayed until the change of the special symbol (effect symbol) is stopped and displayed (the changing memory display effect). In the figure, the variable display of the effect symbol is simply indicated by a downward arrow. In addition, during the variable display, each effect symbol is displayed in a transparent state (transparent display), so that the background image (background image) of the effect symbol is displayed in an easily visible state on the display screen at this time. Has been done.

The background image in this case represents, for example, a landscape in which a female character dressed in a yukata sits on a chaise longue and relaxes as if it were cool in the evening. Such a background image expresses that the stay mode in the production is, for example, a "normal mode". In the present embodiment, the "normal mode" corresponds to a normal state in which the time saving function is inactive and the probability variation function is also inactive. In addition to this, various modes are provided for the production, and background images with different landscapes and scenes are prepared for each mode (state display production execution means). The difference between these modes may correspond to an internal "time reduction state" or a "high probability state". Although not particularly shown here, the advance notice effect may be performed by displaying an image of a character, an item, or the like on the display screen, for example.

Further, during the variable display of the effect symbol, the fourth symbol Z1 is variablely displayed on the upper right of the screen of the liquid crystal display 42, and the fourth symbol Z1 expresses the variable display by changing the display color.

[Stop the left symbol]
In FIG. 87 (C): For example, when a certain amount of time (about half of the fluctuation time) elapses, the left effect symbol first stops fluctuating. In this example, it means that the effect symbol representing the number "8" has stopped at the left side position of the screen. Note that the background image is not shown here (the same applies thereafter).

[Example of production when the number of working memories decreases]
Here, as shown in FIG. 87 (B) above, the number of working memories of the first special symbol decreases by one as the fluctuation starts, so that the number of markers M1 displayed is increased accordingly. It has been reduced by one. For example, if there are four working memory numbers by then, only one of the earliest (oldest) memory number displays in the marker M1 is moved to the changing display area X2, and the effect consumed by the internal lottery is also combined. Will be done. As a result, it is possible to teach the player that the working memory number has been consumed for the first special symbol in terms of production.

Then, in the example of FIG. 87 (C), the marker M1 at the head in the storage order moves to the changing display area X2, so that the remaining three displays in the pre-changing display area X1 are displayed. The three markers M1 remaining on the screen are shifted in one direction (to the left in this case) by one each. As a result, the context of the change in the number of working memories is accurately expressed in the production, and the player is told that "the working memory is consumed and reduced by one" and "the working memory is consumed and the special symbol is displayed." Can be taught intuitively and in an easy-to-understand manner.

[Right production pattern stop]
In FIG. 87 (D): Following the left effect symbol, the right effect symbol stops fluctuating thereafter. In this example, it means that the effect symbol representing the number "3" has stopped at the middle position of the screen. Since it has already been confirmed that the reach state does not occur at this point, it is almost clear from the appearance that this fluctuation is a non-reach (normal) fluctuation. Here, reach fluctuations due to slip patterns, etc. are excluded. The "slip pattern" is, for example, once the production symbol representing the number "7" is stopped, then the symbol row slides by one symbol and the production symbol representing the number "8" is stopped, thereby developing into reach. It is to do. Alternatively, once the effect symbol representing the number "9" is stopped, the effect symbol representing the number "8" is stopped by sliding the symbol sequence in the opposite direction by one symbol, and as a result, a pattern that develops into reach is also possible. is there. In addition, when a character appears on the screen and the right effect symbol sequence is changed again after the effect symbol representing a completely distant number such as "5" is temporarily stopped, the number "8" is displayed. There is also a pattern in which the production pattern stops and develops into reach.

[Stop display effect]
In FIG. 87 (E): The last middle effect symbol is stopped in synchronization with the stop display of the first special symbol. If the result of this internal lottery is non-winning and the first special symbol is stopped and displayed in the non-winning (missing) mode, the production symbol is also stopped and displayed in the non-winning (missing) mode. Will be That is, in the illustrated example, it means that the effect symbol representing the number "1" has stopped at the middle position of the screen. In this case, the combination of the effect symbols is "8"-"1"-"3". Since it is an outlier, it is expressed in the production that this change corresponds to the usual "outlier". At this time, the fourth symbol Z1 is stopped and displayed in a mode corresponding to the detachment (for example, a white display color).

Further, when the stop display effect is performed, the marker M1 that has moved to the changing display area X2 and continued to display is also hidden. Therefore, it is possible to intuitively and easily teach the player that "the change of the special symbol has been completed".

The above is an example of a variable display effect and a stop display effect (at the time of non-winning) performed by using the effect symbol for each change. Through such an effect, the player can have a sense of expectation for winning, and finally, the result of the internal lottery can be clearly taught in the effect.

Further, although the above-mentioned example is for a non-winning case, at the time of a big hit (winning), after the reach effect is executed during the variable display effect, the effect symbol is stopped and displayed in the mode of the big hit in the stop display effect. At this time, the stop display mode of the effect symbol basically corresponds to the winning symbol (stop display mode of the first special symbol display device 34 or the second special symbol display device 35) internally selected by the main control CPU 72. Is selected.

[Example of production at the time of big hit]
FIG. 88 is a continuous diagram showing the flow of the reach effect executed at the time of a big hit (winning). At the time of a big hit, different effects can be executed according to the winning symbol. Here, in addition to the reach effect, a variable display effect, a stop display effect, and a notice effect are included. In addition, an example of the advance notice effect (pre-reach advance notice effect, post-reach advance notice effect) executed during the variable display effect will be described.

In the following reach effect, for example, after the first special symbol display device 34 performs the fluctuation display according to the fluctuation pattern at the time of the jackpot, the first special symbol is the mode of the jackpot (for example, "self", "yo" of the 7-segment LED. , "Mouth", "Snake", "F", "E", "L", "Γ", etc.) is executed until it is stopped and displayed (reach effect execution means). In FIG. 88, each effect symbol is shown simply by a number. Further, the above markers M1 and M2 and the fourth symbols Z1 and Z2 are not shown here. Hereinafter, the explanation will be given along with the flow of the production. Further, the following reach effect is a normal reach effect, but a super reach effect (not shown) different from the following reach effect may be executed according to the selected fluctuation pattern.

[Variable display effect]
In FIG. 88 (A): For example, in substantially synchronization with the start of fluctuation of the first special symbol, the rows of the left effect symbol, the middle effect symbol, and the right effect symbol are arranged in the vertical direction (for example, from above) on the screen of the liquid crystal display 42. The variable display effect is started by scrolling to the bottom).

[Preliminary notice before reach occurs (1st stage)]
In FIG. 88 (B): Next, in the relatively early stage of the variable display effect, the first stage pre-reach advance notice effect using the character's picture image (picture card) is performed. This pre-reach advance notice effect is a notice effect in which the mode changes stepwise from one stage to a plurality of stages (for example, 2 to 5 stages) according to a predetermined order. The pattern image used in this pre-reach advance notice effect is located in front of the effect pattern that is variablely displayed on the screen, and is displayed so as to appear from the left edge of the screen, for example (other modes of appearance). It may be.). In addition, the "pre-reach notice" here means to give a notice of the possibility of reach or the possibility of a big hit before any of the effect symbols is stopped and displayed. By executing such a "pre-reach advance notice effect", it is possible to obtain an effect that gives the player a sense of expectation that "it may develop into reach = the possibility of a big hit increases".

[Pre-reach notice production (second stage)]
In FIG. 88 (C): After the first stage mode of the pre-reach advance notice effect is executed, the change of the pre-reach advance notice effect mode is subsequently advanced to the second stage. Here, as the second stage notice effect before the occurrence of reach, an effect using a picture image of a character different from the previous one is performed. Specifically, another picture image additionally appears from the right edge of the screen, and is displayed so as to overlap the front of the previously displayed picture image. Further, the pattern image displayed at this time is larger in size than the previously displayed pattern image. Then, the character represented by the picture image emits a line (for example, "become a reach"), which is also produced by acoustic output.

The pre-reach advance notice effect (second stage) using such a second pattern image goes one step further from the pre-reach advance notice effect (first stage) performed in FIG. 88 (B) above. It's an advanced type. The mode of "pre-reach notice production" that develops in this way is generally referred to as "step-up notice" or the like. Here, an example is given in which the second-stage pattern image appears in the pre-reach advance notice effect, but in an effect mode in which the third-stage, fourth-stage, and fifth-stage pattern images appear one after another and are displayed. There may be. Further, for example, each time the third-stage, fourth-stage, and fifth-stage picture images appear and are displayed one after another, the size may be expanded. Even at this stage, the variable display of the effect pattern is continued. In any case, it is possible to suggest to the player that there is a high possibility (expectation) of a big hit due to this change by advancing the change of the mode of the pre-reach advance notice effect to more stages. (For example, progressing to the 5th stage suggests the maximum degree of expectation, etc.).

[Stop of left effect design]
In FIG. 88 (D): The variable display of the left effect symbol is stopped in the middle of the variable display effect. At this point, the effect symbol representing the number "5" is stopped at the position on the left side of the screen.

[Occurrence of reach state]
In FIG. 88 (E): Then, following the left effect symbol, for example, the variable display of the right effect symbol is stopped. At this point, since the effect symbol representing the number "5" is stopped at the position on the right side of the screen, the reach state of "5"-"changing"-"5" has occurred. Then, an image emphasizing one line in the reach state is also displayed on the screen. In addition, a production such as "reach!" Is output at the same time.

After the reach state occurs, the reach effect at the time of winning is executed (however, the result of winning has not been displayed yet at this point). In the reach effect, only the effect symbols corresponding to the tempered numbers (here, "5") are displayed on the screen, and the others are not displayed. At this time, the effect symbols may be displayed in a reduced state at each of the four corners of the screen.

[Notice production after reach occurs (1st time)]
In FIG. 88 (F): After a while after the reach state occurs, for example, a post-reach notice effect (first time) is performed in which images representing "heart" figures form a group and pass diagonally on the screen. .. In this case, since the image of the "heart group" is suddenly displayed on the screen as if flowing, it is possible to enhance the visual appeal to the player. By executing the advance notice effect after the occurrence of such a visually lively reach notice, it is possible to obtain an effect of giving the player a greater sense of expectation.

[Progress of reach production]
In FIG. 88 (G): Following the advance notice effect after the first reach occurs, for example, images representing the numbers "2" to "6" are displayed on the screen in a three-dimensional row. From the beginning (front), the images of numbers are erased from the screen in the order of "2", "3", "4", and so on. Such an effect is also performed for the purpose of suggesting (implying) or reminding the player that the number "5" is a "big hit" if it remains unerased until the end. Further, when the number "4" is erased and "5" remains in front of the screen, it means a "big hit", and when the number "5" is also erased, it means "off". In the case of deviation, for example, the number "6" is displayed on the screen after the number "5" is erased. Therefore, during this period, as the images are erased in the order of the numbers "2", "3", and "4", the player's sense of tension and expectation also increases. Then, if the number "4" is actually erased on the screen and the production progresses with the number "5" remaining on the screen, the possibility of a "big hit" increases, so the player feels nervous. Also increases at once.

[Notice production after reach occurs (second time)]
In FIG. 88 (H): When the reach production is approaching the final stage, the image of the character is suddenly displayed on the screen as if it were split into a large copy, and the character utters some kind of dialogue (or silently). After the reach occurs, a notice production (second time) will be performed. At this point, for example, the content of the reach effect is that "if the number" 5 "remains unerased, the possibility of a big hit of" 5 "-" 5 "-" 5 "increases". Therefore, by making a large image of the character appear at this timing, it is possible to obtain an effect that gives the player a sense of expectation that "it may be a big hit".

As a reach effect different from the above, for example, there is a development that "the numbers" 2 "to" 4 "are erased, and if the number" 5 "is left unerased at the end, it becomes a big hit". When the image of the character appears at such a timing, the effect of giving the player a sense of expectation that "the big hit may finally be near" can be obtained.

[Stop the middle production design]
In FIG. 88 (I): The last middle effect symbol is stopped. In this example, the effect symbol representing "5" is stopped and displayed in the center of the screen.

In FIG. 88 (J): Then, for example, in substantially synchronization with the stop display of the first special symbol, the stop display is also performed for the stop display effect as the effect symbol. The stop display effect of the effect symbol is performed, for example, in a state where the left, middle, and right effect symbols are restored to their initial sizes. By performing such a stop display effect, it is possible to teach the player that the final winning type has been determined in the effect.

Further, if the result of the internal lottery is non-winning, the first special symbol, which is the object of this change, is stopped and displayed as a missed symbol, so that the effect symbol is also stopped and displayed in the same manner. In this case, by displaying numbers "4" and "6" other than "5" in the center of the screen, unfortunately, an effect is performed to inform that the change did not result in a big hit. It should be noted that such an effect is executed as an "outlier reach effect".

[Challenge bonus production (directing during a major role)]
FIG. 89 is a diagram showing an example of a challenge bonus effect.
The challenge bonus effect is executed during the jackpot game when "11 round probability variation symbols 1 to 11" or "11 round normal symbol" is applicable.

[1 round]
In FIG. 89 (A): When the first round of the big hit game is started, the big hit production of the content corresponding to the progress of the game called "big hit" is executed. In the big role production, for example, character information corresponding to the number of rounds of "ROUND1" is displayed on the screen. Further, in the lower right corner position of the screen, an effect symbol (here, the number "1") corresponding to the winning symbol is displayed. In this way, by continuously displaying the winning symbol (so-called “remaining eye”) even during the big hit game, it is possible to continue to teach the player the information that “the winning symbol was won with 1 production symbol”. In addition, the characters "Challenge Bonus" are displayed in the lower area of the display screen, and an image of a horse character is displayed around the screen.

Further, during the big hit game (during the special game), the character information of "right-handed" is displayed, and the arrow symbol indicating the right side portion in the game area 8a is displayed (launch position designation effect).

[5 rounds]
In FIG. 89 (B): After that, when the jackpot game progresses smoothly and shifts to 5 rounds, character information corresponding to the number of rounds of "ROUND5" is displayed on the screen and is unique to the jackpot game. The production image of is displayed. The actual jackpot game continues until the 11th round, but after the 6th round, the jackpot is short-opened (for example, 0.1 seconds open) in each round. Therefore, this fifth round is the actual final round.

[At the end of the big role]
In FIG. 89 (C): At the timing when the jackpot game ends, the major winning combination end effect that conveys the effect content to be executed after that is executed. In this example, the text information "Treasure challenge rush!" Is displayed on the screen.

[Example of treasure challenge production]
FIG. 90 is a continuous diagram partially showing an example of the treasure challenge production.
The treasure challenge production is a probabilistic promotion judge production that is executed using the 1st to 10th fluctuations after the end of the jackpot game when it corresponds to "11th round probabilistic symbols 1 to 11" or "11th round normal symbol". is there. In the treasure challenge production, the horse character searches for the treasure, and if the treasure can be found, it will enter the fireworks rush. The flow of the production will be explained step by step below.

In FIG. 90 (A): "Treasure challenge production" by performing the first variation display after the end of the jackpot game in the case of corresponding to "11 round probability variation symbols 1 to 11" or "11 round normal symbol". Is started. The effect symbol is executed in a variable display effect in a reduced state at the upper left corner position of the screen ("changing"-"changing"-"changing"). Further, the fourth symbol Z1 is variablely displayed on the upper right of the screen of the liquid crystal display 42.

[Game explanation production]
When the treasure challenge production is started, the game explanation production is first executed. In the illustrated example, a hermit character is displayed on the left side of the screen, and the hermit character is performing a production that utters the line "If you can find the treasure, it's time to rush into the fireworks rush!".

In addition, during the treasure challenge (during time reduction / probabilistic change), the character information of "right-handed" is displayed, and the arrow symbol indicating the right side portion in the game area 8a is displayed (launch position designation effect). If the treasure challenge is successful, the launch position designation effect will continue to be executed as it is because the right-handed state will continue (see (C) and (E) in the figure), but the treasure challenge has failed. In that case, it will be in a left-handed state, so it will end (see (F) in the figure).

[At the time of winning the 11th round probability variation symbol 1]
In FIG. 90 (B): When the previous jackpot corresponds to "11 round probability variation symbol 1", the number of special fluctuations is one, so the success effect is executed in the first treasure challenge effect. Specifically, a production in which a horse character finds a treasure is executed. Then, the word "success" is displayed at the top of the screen, and the hermit character utters the line "superb!"

[At the end of fluctuation]
In FIG. 90 (C): All the production symbols are stopped and displayed because the first fluctuation (at the time of non-winning) after the end of the big hit game is completed ("1"-"2"-"3"). .. Further, the fourth symbol Z1 is stopped and displayed in a non-winning mode (for example, a white display color).

Further, at this timing, an effect of teaching the player the internal state to be transferred after that is executed. In the illustrated example, the text information "Fireworks rush rush!" Is displayed on the screen. By executing such an effect, it is possible to teach the player to shift to the fireworks rush in the "high probability time shortened state".

[11 round probability variation symbol 2-11 or 11 round normal symbol winning]
In FIG. 90 (D): On the other hand, in the case of winning in either "11 round probability variation symbol 2-11" or "11 round normal symbol", a failure effect is executed in the first treasure challenge effect. Then, the word "failure" is displayed at the top of the screen, and the hermit character utters the line "sorry".

[At the end of fluctuation]
In FIG. 90 (E): All the production symbols are stopped and displayed because the first fluctuation (at the time of non-winning) after the end of the big hit game is completed ("4"-"5"-"6"). .. Further, the fourth symbol Z1 is stopped and displayed in a non-winning mode (for example, a white display color).

In addition, at this timing, an effect of instructing the player that the treasure challenge effect will continue is executed. In the illustrated example, the text information "Treasure challenge continues!" Is displayed on the screen. Then, in the case of corresponding to "11 round probability variation symbols 2 to 10", the treasure challenge production is continued until the special variation set for each winning symbol is completed, and finally, in the treasure challenge production. Success production is executed.

[At the end of fluctuation]
In FIG. 90 (F): On the other hand, when it corresponds to "11 round normal symbol" or "11 round probability variation symbol 11", the failure effect is executed even in the 10th fluctuation (when not winning) after the end of the big hit game. Will be done. Further, at this timing, an effect of teaching the player the internal state to be transferred after that is executed. In the illustrated example, the text information "Enter the festival mode!" Is displayed on the screen. By executing such an effect, it is possible to teach the player to shift to the festival mode of "low probability or high probability non-time reduction state". In addition, when it corresponds to "11 round probability variation symbol 11" in the high probability non-time shortened state, the number of time reductions is set to 10000 times, so that the success effect is executed in the 10th fluctuation after the end of the big hit game. be able to.

[Example of fireworks rush production]
FIG. 91 is a continuous view showing an example of producing a fireworks rush.
The fireworks rush is in a state of shortening the time with high probability, and continues until the special symbol fluctuates 10,000 times unless a winning result is obtained after the big hit game. The flow of the production will be explained step by step below.

In FIG. 91 (A): The variable display of the effect symbol is performed in the state of "fireworks rush". The background image of the fireworks rush is a background image that expresses "a scene where fireworks are launched in the night sky" in order to deeply impress the player with the motif of fireworks. Further, the fourth symbol Z2 is variablely displayed in the upper right portion of the screen of the liquid crystal display 42.

Further, during the probability change (during the high probability time shortening state), the character information of "right-handed" is displayed, and the arrow symbol indicating the right side portion in the game area 8a is displayed (launch position designation effect).

In FIG. 91 (B): Then, due to the end of the first fluctuation (at the time of non-winning) after the end of the big hit game, all the production symbols are stopped and displayed ("3"-"1"-"7". "). Further, the fourth symbol Z2 is stopped and displayed in a non-winning mode (for example, a white display color).

In FIG. 91 (C): When the next fluctuation is started, the second fluctuation display is performed after the jackpot game is completed. In the high probability time shortened state, the variable start winning device 28 is operated with high frequency, so as long as the player continues to hit the right side, the variation display of the effect symbol accompanying the variation display of the second special symbol is performed. Often referred to.

[Fireworks bonus production]
FIG. 92 is a continuous view partially showing an example of the fireworks bonus effect.
The fireworks bonus effect is an effect executed during the jackpot game when it corresponds to "15 round probability variation symbol 2-7" or "3 round probability variation symbol".

[1 round]
In FIG. 92 (A): When the first round of the big hit game is started, the big hit production of the content corresponding to the progress of the game called "big hit" is executed. In the big role production, for example, character information corresponding to the number of rounds of "ROUND1" is displayed on the screen. In addition, the characters "fireworks bonus" are displayed in the upper right area of the display screen, and an image of an animal character straddling a horse is displayed in the center of the screen.

Further, during the big hit game (during the special game), the character information of "right-handed" is displayed, and the arrow symbol indicating the right side portion in the game area 8a is displayed (launch position designation effect).

[Final round]
In FIG. 92 (B): After that, the jackpot game progresses smoothly, and the game shifts to the final round. For example, when a 15-round jackpot is executed, character information corresponding to the number of rounds of "ROUND 15" is displayed on the screen.

[At the end of the big role]
In FIG. 92 (C): At the timing when the big hit game ends, the big winning combination end effect of the content that teaches the internal state to be shifted after this is executed. In the illustrated example, the text information "Fireworks rush rush!" Is displayed on the screen. By executing such a big role end effect, it is possible to teach the player to shift to the fireworks rush in the "high probability time shortened state" as a privilege after the big hit game ends.

[Normal Bonus Effect] FIG. 93 is a continuous diagram partially showing an example of the effect of the normal bonus effect. The normal bonus effect is an effect executed during the jackpot game when the "5-round normal symbol" or the "5-round probability variation symbol" is applicable.

[1 round] In FIG. 93 (A): When the first round of the jackpot game in the normal bonus effect is started, the character information corresponding to the number of rounds of "ROUND1" is displayed on the screen. In addition, the characters "normal bonus" are displayed in the upper left of the screen, and the image of the dog character is displayed in the center of the screen.

Further, during the big hit game (during the special game), the character information of "right-handed" is displayed, and the arrow symbol indicating the right side portion in the game area 8a is displayed (launch position designation effect).

[5 rounds] In FIG. 93 (B): After that, when the jackpot game progresses smoothly and shifts to the final 5 rounds, character information corresponding to the number of rounds of "ROUND 5" is displayed on the screen. , A unique production image is displayed during the jackpot game.

[At the end of the big role] In FIG. 93 (C): At the timing (during the ending time) when the big hit game corresponding to the "5-round normal symbol" ends, the big role end effect of the content that teaches the internal state to be transferred after that. Is executed. In the illustrated example, the text information "Enter coastal mode!" Is displayed on the screen. By executing such a big role end effect, it is possible to teach the player to shift to the coast mode of the "low probability time shortened state" as a privilege after the big hit game ends. If it corresponds to the "5-round probability variation symbol", the major role promotion effect is executed during the execution of the normal bonus effect, and the process shifts to the fireworks rush.

[Example of coastal mode production]
FIG. 94 is a continuous view showing an example of the production of the coast mode.
The coast mode is shifted after the jackpot game is completed when the time is shortened and the "5-round normal symbol" is applied. The coastal mode is a "low probability time reduction state". The flow of the production will be explained step by step below.

In FIG. 94 (A): The variation display of the effect symbol is performed in the state of "coast mode". The background image of the coast mode is a background image with images such as "sandy beach", "sea", and "mountain" as motifs in order to express the healing impression which is the concept of the coast mode. Further, the fourth symbol Z2 is variablely displayed on the upper right of the screen of the liquid crystal display 42.

Further, during the time reduction (during the low probability time reduction state), the character information of "right-handed" is displayed, and the arrow symbol indicating the right side portion in the game area 8a is displayed (launch position designation effect).

In FIG. 94 (B): Then, due to the end of this change (at the time of non-winning), all the production symbols are stopped and displayed ("1"-"1"-"5"). Further, the fourth symbol Z2 is stopped and displayed in a non-winning mode (for example, a white display color).

In FIG. 94 (C): Then, the next fluctuation is started. This coastal mode ends when the special symbol fluctuates 100 times without a winning result. When the coastal mode ends, it shifts to the normal mode with a low probability of non-time reduction. If the winning result is obtained in the coastal mode, the reach effect is executed and a big hit is obtained.

Next, an example of a control method for concretely realizing the above effect will be described. The above-mentioned variable display effect, reach effect, pre-reach advance notice effect, memory number display effect, major role effect, etc. are all controlled through the following control processes.

[Production control processing]
FIG. 95 is a flowchart showing a procedure example of the effect control process executed by the effect control CPU 126. This effect control process is executed in the timer interrupt process separately from the reset start process of the effect control device (not shown), for example. The effect control CPU 126 generates a timer interrupt at a predetermined interrupt cycle (for example, a period of several tens of μs to several ms) during the execution of the reset start process of the effect control device, and executes the timer interrupt process.

In the reset start process of the effect control device, the initialization process of the effect control device is executed. The initialization process of the effect control device is executed for a predetermined time (for example, a time of about several seconds), and the command from the main control device may not be accepted during the execution of the initialization process.

The effect control process includes command reception process (step S400), working memory effect management process (step S401), effect symbol management process (step S402), firing position designation effect management process (step S403), and display output process (step S404). , Ramp drive processing (step S406), acoustic drive processing (step S408), effect random number update processing (step S410), and other processing (step S412). Hereinafter, the basic flow of the effect control process will be described along with each process.

Step S400: In the command reception process, the effect control CPU 126 receives the effect command transmitted from the main control CPU 72. Further, the effect control CPU 126 analyzes the received commands and stores them in the command buffer area of the RAM 130 for each type. The command for effect transmitted from the main control CPU 72 includes, for example, a special symbol destination determination effect command, a (special symbol) operation memory increase effect command, a (special symbol) operation memory decrease effect command, and a start port. Winning sound control command, demo production command, lottery result command, fluctuation pattern command, fluctuation start command, stop symbol command, symbol stop command, status specification command, round number command, error notification command, jackpot end production command, number cut Counter value command, fluctuation pattern destination judgment command, stop display time end command, prize ball content command, launch position specification command, normal game management phase command, special game management phase command, power return specification command, RAM clear specification command, setting related There is an end specification command, etc.

Step S401: In the operation memory effect management process, the effect control CPU 126 controls the execution of the storage number display effect and the pre-reading advance notice effect using the markers M1 and M2. The contents of the working memory effect management process will be described later with reference to another drawing.

Step S402: In the effect symbol management process, the effect control CPU 126 controls the contents of the variable display effect and the stop display effect using the effect symbol, and when the first variable winning device 30 or the second variable winning device 31 is opened and closed. Control the content of the production. Further, in this process, the effect control CPU 126 selects an effect pattern of various advance notice effects (pre-reach advance notice effect, post-reach advance notice effect, etc.). The contents of the effect symbol management process will be described later with reference to another drawing.

Step S403: In the launch position designation effect management process, the effect control CPU 126 controls the content of the launch position designation effect (launch position designation effect execution means). Specifically, when the content of the launch position designation command is a value indicated by right-handedness, the effect control CPU 126 executes a process of selecting the launch position designation effect.

Step S404: In the display output process, the effect control CPU 126 refers to the VDP 152 with basic control information of the effect content (for example, the number of operation memories of each of the first special symbol and the second special symbol, the operation memory effect pattern number, and the look-ahead notice. The effect pattern number, the variation effect pattern number, the change notice effect number, the background pattern number, etc.) are instructed. As a result, the VDP 152 controls the display operation by the liquid crystal display 42 based on the instructed effect content (effect execution means).

Step S406: In the lamp drive process, the effect control CPU 126 outputs a control signal to the driver IC 132. In response to this, the driver IC 132 drives various lamps 46 to 52, board lamp 53, and the like (lighting or extinguishing, blinking, change in luminance gradation, etc.) based on the control signal.

Step S408: In the next acoustic drive process, the effect control CPU 126 instructs the voice IC 134 of the effect contents (for example, BGM during the variable display effect, the reach effect, the mode transition effect, the jackpot effect, etc.). .. As a result, the speakers 54, 55, and 56 output sounds according to the content of the effect.

Step S410: In the effect random number update process, the effect control CPU 126 updates various effect random numbers in the counter area of the RAM 130. The production random numbers include, for example, random numbers used for advance notice selection, random numbers used for a normal background change lottery (production lottery), and the like.

Step S412: In other processing, for example, the effect control CPU 126 outputs a control signal to the driving IC of the movable body 40f. The movable body 40f operates by using the movable body motor 57 as a drive source, and produces an effect in synchronization with the display of the image by the liquid crystal display 42 or independently.

Through the above-mentioned effect control process, the effect control CPU 126 can comprehensively control the effect content in the pachinko machine 1. Next, the contents of the working memory effect management process executed in the effect control process will be described.

[Working memory production management process]
FIG. 96 is a flowchart showing a procedure example of the working memory effect management process. Hereinafter, the contents will be described with reference to a procedure example.

Step S700: First, the effect control CPU 126 confirms whether or not a effect command for increasing the number of operating memories has been received from the main control CPU 72. Specifically, the effect control CPU 126 accesses the command buffer area of the RAM 130 and confirms whether or not the effect command is saved when the number of working memories increases. When it is confirmed that the effect command for increasing the number of working memories is saved (step S700: Yes), the effect control CPU 126 executes steps S702 and S703. If it cannot be confirmed that the effect command for increasing the number of working memories is saved (step S700: No), the effect control CPU 126 does not execute steps S702 and S703.

Step S702: The effect control CPU 126 executes the effect selection process when the number of working memories increases. In this process, the effect control CPU 126 selects an effect for displaying the first special symbol and the markers M1 and M2 corresponding to the second special symbol.

Step S703: The effect control CPU 126 executes the look-ahead effect management process (look-ahead effect execution means). In this process, the effect control CPU 126 executes a determination process as to whether or not to execute the look-ahead effect (marker change effect, zone effect, continuous effect, etc.), and if it is determined to execute the look-ahead effect, the look-ahead effect Executes the process of determining the specific contents of.

By executing such a process, the effect control CPU 126 is executed over a plurality of times of fluctuation of the special symbol when the execution condition of the look-ahead effect is satisfied (when the special effect execution condition is satisfied). It is possible to execute a look-ahead effect (pre-reading effect execution means).

Step S704: The effect control CPU 126 confirms whether or not the effect control CPU 126 has received the effect command when the number of operating memories is reduced. Specifically, the effect control CPU 126 accesses the command buffer area of the RAM 130 and confirms whether or not the effect command is saved when the number of working memories is reduced. When it is confirmed that the effect command when the number of working memories is reduced is saved (step S704: Yes), the effect control CPU 126 executes step S706. If it cannot be confirmed that the effect command for reducing the number of working memories is saved (step S704: No), the effect control CPU 126 does not execute step S706.

Step S706: The effect control CPU 126 executes the effect selection process when the number of working memories is reduced. In this process, the effect control CPU 126 slides the markers M1 and M2 corresponding to the first special symbol and the second special symbol, and the marker corresponding to the lottery element consumed by the internal lottery is being changed from the pre-variation display area X1. Select the effect to be moved to the display area X2. The storage marker moved to the variable display area X2 selects an effect to be erased at the end of the fluctuation.
When the above procedure is completed, the effect control CPU 126 returns to the effect control process (FIG. 95).

[Production design management process]
FIG. 97 is a flowchart showing a procedure example of the effect symbol management process. The effect symbol management process (effect execution means), execution selection process (step S500), effect symbol change pre-process (step S502), effect symbol change process (step S504), effect symbol stop display process (step S506), and This configuration includes a group of subroutines for processing when the variable winning device is activated (step S508). Hereinafter, the basic flow of the effect symbol management process will be described along with each process.

Step S500: In the execution selection process, the effect control CPU 126 selects the jump destination of the process to be executed next (any of steps S502 to S508). For example, the effect control CPU 126 sets the program address of the process to be executed next as the jump destination address, and sets the end of the effect symbol management process in the "jump table" as the return destination address. Which process is selected as the next jump destination depends on the progress of the processes performed so far. For example, if the variation display effect has not been started yet, the effect control CPU 126 selects the effect symbol variation preprocessing (step S502) as the next jump destination. On the other hand, if the effect symbol change pre-processing has already been completed, the effect control CPU 126 selects the effect symbol change process (step S504) as the next jump destination, and if the effect symbol change process has been completed, the next step. Select the effect symbol stop display processing (step S506) as the jump destination of. Further, the variable winning device operation process (step S508) includes a case where the large hit variable winning device management process (step S5000 in FIG. 35) is selected in the main control CPU 72 or a small hit variable winning device management process (FIG. 35). When step S6000) in the middle is selected, it is selected as the jump destination. In this case, steps S502 to S506 are not executed.

Step S502: In the effect symbol variation preprocessing, the effect control CPU 126 performs an operation of adjusting the conditions for starting the variation display effect using the effect symbol. Further, in this process, the effect control CPU 126 selects the content of the reach effect according to various conditions (lottery result, winning type, fluctuation pattern, etc.), and the effect pattern for the advance notice effect (reach other than the look-ahead advance notice effect pattern). Select a pre-occurrence notice pattern, a post-occurrence notice pattern, etc.). In addition, the effect control CPU 126 also controls the demonstration effect when the pachinko machine 1 is in a so-called customer waiting state. The specific contents of the processing will be described later using another flowchart.

Step S504: In the effect symbol changing process, the effect control CPU 126 generates control information instructed to the VDP 152 as needed. For example, when performing an effect using the effect switching button 45 during execution of a variable display effect using an effect symbol, the effect control CPU 126 monitors whether or not the effect button is operated by the player, and an effect according to the result. The control information of the content (button effect) is instructed to the VDP 152.

Step S506: In the process of displaying the stop display of the effect symbol, the effect control CPU 126 controls the content of the stop display effect using the effect symbol and the moving image in an manner according to the result of the internal lottery. That is, the effect control CPU 126 instructs the VDP 152 to end the variable display effect and execute the stop display effect. In response to this, the VDP 152 actually ends the variable display effect that has been executed so far in the display screen of the liquid crystal display 42, and executes the stop display effect. As a result, the stop display effect is executed substantially in synchronization with the stop display of the special symbol, and the result of the internal lottery can be instructed (disclosure, notification, notification, etc.) to the player in an effect (effect execution means). ). At the time of a small hit, the stop display effect can be executed in the same manner as or similar to the loss.

Step S508: In the process when the variable winning device is operated, the effect control CPU 126 controls the effect content during the small hit or the big hit. In this process, the effect control CPU 126 selects the content of the effect during the big role according to various conditions (for example, the winning type). For example, in the case of a 15-round big hit, the effect control CPU 126 selects a 15-round large-duty effect pattern as the effect content to be displayed on the liquid crystal display 42, and instructs the VDP 152 of this. As a result, the display screen of the liquid crystal display 42 displays an image of the effect during the important role, and the content of the effect changes as the round progresses.

[Pre-processing for effect pattern fluctuation]
FIG. 98 is a flowchart showing a procedure example of the above-mentioned effect symbol change preprocessing. Hereinafter, a procedure example will be described.

Step S600: The effect control CPU 126 confirms whether or not a demo effect command has been received from the main control CPU 72. Specifically, the effect control CPU 126 accesses the command buffer area of the RAM 130 and confirms whether or not the demo effect command is stored. As a result, when it is confirmed that the demo effect command is saved (Yes), the effect control CPU 126 executes step S602.

Step S602: The effect control CPU 126 executes the demo selection process. In this process, the effect control CPU 126 selects a demo effect pattern. The demo effect pattern defines the content of the effect indicating that the pachinko machine 1 is in a so-called customer waiting state.

When the above procedure is completed, the effect control CPU 126 returns to the address at the end of the effect symbol management process. Then, the effect control CPU 126 returns to the effect control process as it is, and controls the content of the demo effect based on the demo effect pattern in the subsequent display output process (step S404 in FIG. 95) and the lamp drive process (step S406 in FIG. 95). To do.

On the other hand, if it is confirmed in step S600 that the demo effect command is not saved (No), the effect control CPU 126 next executes step S604.

Step S604: The effect control CPU 126 confirms whether or not the fluctuation this time is out of order (non-winning). Specifically, the effect control CPU 126 accesses the command buffer area of the RAM 130 and confirms whether or not the lottery result command at the time of non-winning is saved. As a result, when it is confirmed that the lottery result command at the time of non-winning is saved (Yes), the effect control CPU 126 executes step S612. On the contrary, when it is confirmed that the lottery result command at the time of non-winning is not saved (No), the effect control CPU 126 executes step S606. It is also possible to confirm whether or not the fluctuation this time is out of order based on the fluctuation pattern command and the stop symbol command in addition to the lottery result command. That is, if the current fluctuation pattern command corresponds to the outlier normal variation or the outlier reach variation, it can be determined that the current variation is out of order. Alternatively, if the stop symbol command this time specifies a non-winning symbol, it can be determined that the fluctuation this time is out of order.

Step S606: If the lottery result command is other than non-winning (missing) (step S604: No), then the effect control CPU 126 confirms whether or not this fluctuation is a big hit. Specifically, the effect control CPU 126 accesses the command buffer area of the RAM 130 and confirms whether or not the lottery result command at the time of a big hit is saved. As a result, when it is confirmed that the lottery result command at the time of the big hit is saved (Yes), the effect control CPU 126 executes step S610. On the contrary, when it is confirmed that the lottery result command at the time of big hit is not saved (No), only the lottery result command at the time of small hit remains. In this case, the effect control CPU 126 executes step S608. It is also possible to confirm whether or not the current fluctuation is a big hit based on the fluctuation pattern command or the stop symbol command. That is, if the current fluctuation pattern command corresponds to the jackpot fluctuation, it can be determined that the current fluctuation is a jackpot. Further, if the stop symbol command of this time corresponds to the jackpot symbol, it can be determined that the fluctuation of this time is a jackpot.

Step S608: The effect control CPU 126 executes the small hit time variation effect pattern selection process. In this process, the effect control CPU 126 determines the effect pattern number at that time based on the variation pattern commands (for example, “C0H00H” to “D0H7FH”) received from the main control CPU 72. The effect pattern number is prepared in advance corresponding to the variation pattern command, and the effect control CPU 126 can refer to the effect pattern selection table (not shown) and select the effect pattern number corresponding to the variation pattern command at that time. it can. The effect pattern number may be prepared as a pair with the variation pattern command, or a plurality of effect pattern numbers may be prepared for one variation pattern command.

Further, when the effect pattern number is selected, the effect control CPU 126 refers to an effect table (not shown), and the variation schedule (variation time, reach type and reach occurrence timing) of the effect symbol corresponding to the variation effect pattern number at that time, and stop. Determine the display mode and the like. In addition, all the types of effect symbols determined here correspond to "combination of symbols at the time of small hit".

The above procedure corresponds to a "small hit", but when it corresponds to a big hit, the effect control CPU 126 confirms that it is a "big hit" in step S606 (Yes). In this case, the effect control CPU 126 executes step S610.

Step S610: The effect control CPU 126 executes the jackpot variation effect pattern selection process. In this process, the effect control CPU 126 determines the effect pattern number at that time based on the variation pattern commands (for example, "E0H00H" to "F0H7FH") received from the main control CPU 72. In the jackpot effect pattern selection process, the process may be further branched according to the jackpot stop symbol. The specific contents of the processing will be described later using another flowchart.

In the case of non-winning, the following procedure is executed. That is, when the effect control CPU 126 confirms that it is out of alignment in step S604 (Yes), it then executes step S612.

Step S612: The effect control CPU 126 executes the effect time variation effect pattern selection process. In this process, the effect control CPU 126 determines the effect pattern number at the time of disconnection based on the variation pattern commands (for example, "A0H00H" to "A6H7FH") received from the main control CPU 72. The effect pattern numbers at the time of disconnection are classified into "outlier normal fluctuation", "time saving outlier variation", "outlier reach variation", etc., and further, a fine reach variation pattern is defined in "outlier reach variation". Which effect pattern number the effect control CPU 126 selects is determined by the variation pattern command transmitted from the main control CPU 72.

When the effect pattern number at the time of disconnection is selected, the effect control CPU 126 refers to an effect table (not shown), and the variation schedule of the effect symbol corresponding to the variation effect pattern number at that time (variation time, presence / absence of reach occurrence, case of reach occurrence). Determines the reach type and reach occurrence timing) and the mode of stop display (for example, "7"-"2"-"4", etc.). The specific contents of the processing will be described later using another flowchart.

When any of the above steps S608, S610, and S612 is executed, the effect control CPU 126 next executes step S614.

Step S614: The effect control CPU 126 executes the advance notice selection process (notice effect execution means). In this process, the effect control CPU 126 selects the content of the advance notice effect to be executed during the variable display effect this time by lottery. The content of the advance notice effect is determined based on, for example, the result of the internal lottery (winning or non-winning) and the current internal state (normal state, high probability state, time reduction state). As described above, the advance notice effect is to give a notice to the player that a reach state may occur during the variable display effect, or to give a notice that there is a possibility of a big hit in the end. Therefore, the selection ratio of the advance notice effect is set low at the time of non-winning, but the selection ratio of the advance notice effect is set relatively high in order to raise the expectation of the player at the time of winning.

In this way, when the effect control CPU 126 wins the lottery for whether or not to execute the advance notice effect (when the specified effect execution condition is satisfied), the effect control CPU 126 is elected during the execution of the variable display effect (predetermined effect). The advance notice effect (related to the predetermined effect, which suggests the success or failure of the predetermined effect) suggesting that the effect symbol is stopped and displayed in the mode is executed (preliminary effect execution means).

Further, when the effect control CPU 126 determines in the advance notice selection process that the advance notice effect is to be executed, the effect control CPU 126 executes a process of determining at which timing during the variable display the advance notice effect is to be started. In addition, various notice effects (step-up notice effect, conversation notice effect, cut-in notice effect, group notice effect, character drop effect, next notice effect, title color change effect) executed during the variable display are included in the notice effect. ), Pseudo continuous advance notice effect, look-ahead advance notice effect, memory marker change advance notice effect, etc. are also included.

Step S616: The effect control CPU 126 executes the mode effect management process. In this process, the effect control CPU 126 executes a process of selecting a background image according to the stay mode. For example, when the stay mode is the "normal mode (low probability non-time reduction state)", the effect control CPU 126 executes a process of selecting a background image in which a female character is sitting on a chaise longue. Further, when the stay mode is "fireworks rush (high probability time shortened state)", the effect control CPU 126 executes a process of selecting a background image with a fireworks motif. Further, when the stay mode is the "coastal mode (low probability time shortened state)", the effect control CPU 126 executes a process of selecting a background image with the coast as a motif.

When the above procedure is completed, the effect control CPU 126 returns to the effect symbol management process (end address). As a result, in the subsequent processing during effect symbol variation (step S504 in FIG. 97), the variation display effect and the stop display effect are executed based on the actually selected variation effect pattern (effect execution means), and various types are executed. The advance notice effect is executed based on the advance notice effect pattern.

[Variation effect pattern selection process at the time of big hit]
FIG. 99 is a flowchart showing a procedure example of the jackpot variation effect pattern selection process. Hereinafter, a procedure example will be described.

Step S800: The effect control CPU 126 accesses the command buffer area of the RAM 130 and loads the variation pattern command. This makes it possible to confirm what kind of jackpot fluctuation pattern this fluctuation is.

Step S802: The effect control CPU 126 confirms whether or not the loaded fluctuation pattern is a special fluctuation pattern.

As a result, when it is confirmed that the current fluctuation pattern is a special fluctuation pattern (Yes), the effect control CPU 126 executes step S804, and when it cannot be confirmed that the current fluctuation pattern is a special fluctuation pattern (No). , The effect control CPU 126 executes step S806.

Step S804: The effect control CPU 126 executes the effect selection process for each special variation pattern. In this process, the effect control CPU 126 determines the effect pattern number at that time based on the variation pattern command received from the main control CPU 72. Specifically, the effect control CPU 126 selects an effect pattern that is a big hit in the treasure challenge effect.

Step S806: The effect control CPU 126 executes the effect selection process after reaching. In this process, the effect control CPU 126 determines the effect pattern number at that time based on the variation pattern command received from the main control CPU 72. Specifically, the effect control CPU 126 selects an effect pattern such as a normal reach effect or a super reach effect according to the type of variation pattern (long or short of the variation time).

Then, when the process of step S804 or step S806 is completed, the effect control CPU 126 returns to the effect symbol change pre-process (FIG. 98).

[Variation effect pattern selection process at the time of disconnection]
FIG. 100 is a flowchart showing a procedure example of the deviation effect variation effect pattern selection process. Hereinafter, a procedure example will be described.

Step S820: The effect control CPU 126 accesses the command buffer area of the RAM 130 and loads the variation pattern command. This makes it possible to confirm what kind of out-of-range fluctuation pattern this fluctuation is.

Step S822: The effect control CPU 126 confirms whether or not the loaded fluctuation pattern is a special fluctuation pattern.

As a result, when it is confirmed that the current fluctuation pattern is a special fluctuation pattern (Yes), the effect control CPU 126 executes step S826, and when it cannot be confirmed that the current fluctuation pattern is a special fluctuation pattern (No). , The effect control CPU 126 executes step S824.

Step S824: The effect control CPU 126 confirms whether or not the loaded fluctuation pattern is an out-of-reach fluctuation pattern.

As a result, when it is confirmed that the current fluctuation pattern is the out-of-reach fluctuation pattern (Yes), the effect control CPU 126 executes step S828, and it cannot be confirmed that the current fluctuation pattern is the out-of-reach fluctuation pattern. In the case (No), the effect control CPU 126 executes step S830.

Step S826: The effect control CPU 126 executes the special variation pattern deviation effect selection process. Specifically, the effect control CPU 126 executes the treasure challenge effect during the fluctuation of the special symbol, continues the treasure challenge effect based on the type of the previous winning symbol, shifts to the fireworks rush, or shifts to the festival mode. Select the effect pattern to be transferred.

Step S828: The effect control CPU 126 executes the out-of-reach effect selection process after the reach. Specifically, the effect control CPU 126 executes the reach effect and selects an effect pattern that is out of alignment based on the variation pattern command received from the main control CPU 72.

Step S830: The effect control CPU 126 executes the non-reach off effect selection process. Specifically, the effect control CPU 126 selects an effect pattern that would be out of alignment without executing the reach effect, based on the variation pattern command received from the main control CPU 72.

Then, when any of the processes of step S826, step S828, or step S830 is completed, the effect control CPU 126 returns to the effect symbol change pre-process (FIG. 98).

[Mode production management process]
FIG. 101 is a flowchart showing a procedure example of the mode effect management process. Hereinafter, a procedure example will be described.

Step S850: The effect control CPU 126 confirms whether or not the internal state is a time shortened state (low probability time shortened state or high probability time shortened state). Specifically, the effect control CPU 126 accesses the command buffer area of the RAM 130, confirms the state specification command, and confirms whether or not the internal state is the time-reduced state.

As a result, when it cannot be confirmed that the internal state is the time shortened state (No), the effect control CPU 126 executes step S856. On the other hand, when it is confirmed that the internal state is the time shortened state (Yes), the effect control CPU 126 executes step S852.

Step S852: The effect control CPU 126 confirms whether or not the current variation is a variation pattern corresponding to the special variation pattern. This confirmation can be performed by confirming the variation pattern command.

As a result, when it is confirmed that the current variation is a variation pattern corresponding to the special variation pattern (Yes), the effect control CPU 126 executes step S858. On the other hand, when it cannot be confirmed that the current variation is a variation pattern corresponding to the special variation pattern (No), the effect control CPU 126 executes step S854.

Step S854: The effect control CPU 126 confirms whether or not the previous winning symbol is the “5-round normal symbol”. To confirm which symbol the previous winning symbol corresponds to and which state the previous internal state was, the RAM 130 stores information on the winning symbol and information on the internal state at the time of the previous winning. It can be realized by this.

As a result, when it cannot be confirmed that the previous winning symbol is the "5-round normal symbol" (No), the effect control CPU 126 executes step S860. On the other hand, when it is confirmed that the previous winning symbol is the "5-round normal symbol" (Yes), the effect control CPU 126 executes step S862.

Step S856: The effect control CPU 126 executes a process of selecting a background image corresponding to the non-time reduction state. Specifically, the effect control CPU 126 executes a process of selecting a background image in the "normal mode" or a background image in the "festival mode". For example, the effect control CPU 126 basically executes a process of selecting a background image in the “normal mode” in a low-probability non-time reduction state. Further, the effect control CPU 126 selects the background image of the "festival mode" after the treasure challenge effect, and when the special symbol fluctuates a specified number of times (for example, 10 times) in the low probability non-time shortened state, the "normal mode" ”, The process of selecting the background image is executed.

Step S858: The effect control CPU 126 executes a process of selecting a background image for the treasure challenge effect.

Step S860: The effect control CPU 126 executes a process of selecting a background image for the fireworks rush.

Step S862: The effect control CPU 126 executes a process of selecting a background image for the coast mode.

Then, when any of the processes of steps S856 to S862 is completed, the effect control CPU 126 returns to the effect symbol change pre-process (FIG. 98).

[Processing at the time of operating the variable winning device] FIG. 102 is a flowchart showing a configuration example of processing at the time of operating the variable winning device. The variable winning device operating time processing is a subroutine of execution selection processing (step S902), variable winning device operation pre-processing (step S904), variable winning device operating processing (step S906), and variable winning device operation post-processing (step S908). It is a configuration including a (program module) group. Here, first, the basic flow of the processing at the time of operating the variable winning device will be described along with each processing.

Step S902: In the execution selection process, the effect control CPU 126 selects the jump destination of the process to be executed next (any of steps S904 to S908) from the “jump table”. For example, the effect control CPU 126 sets the program address of the process to be executed next as the jump destination address, and sets the end of the variable winning device operating process as the return destination address in the stack pointer.

Which process is selected as the next jump destination depends on the progress of the processes performed so far. For example, if the variable winning device operation pre-processing has not been started yet, the effect control CPU 126 selects the variable winning device operation pre-processing (step S904) as the next jump destination. If the variable winning device operation pre-processing has already been completed, the effect control CPU 126 selects the variable winning device operating process (step S906) as the next jump destination. Further, if the process during operation of the variable winning device is completed, the effect control CPU 126 selects the post-processing after operating the variable winning device (step S908) as the next jump destination.

Step S904: In the variable winning device operation pre-processing, the effect control CPU 126 executes a process of selecting the content of the effect to be executed during the big hit game or the small hit game.

For example, when it corresponds to "11 round normal symbol" and "11 round probability variation symbol 1 to 11", a process of selecting a challenge bonus effect is executed. In addition, when it corresponds to "15 round probability variation symbol 1", the process of selecting the special bonus effect is executed. Further, when it corresponds to the "6 round probability variation symbol" or the "8 round probability variation symbol", the process of selecting the large role medium effect (mode transition effect) that suddenly shifts to the fireworks rush is executed.

On the other hand, when it corresponds to "15 round probability variation symbol 2-7" or "3 round probability variation symbol", the process of selecting the fireworks bonus effect is executed. In addition, when it corresponds to the "5-round probability variation symbol", the process of selecting the effect to execute the big role promotion effect is executed during the execution of the normal bonus effect (5-round big hit effect). Further, when it corresponds to the "5-round normal symbol", the process of selecting the effect to execute the normal bonus effect (5-round jackpot effect) is executed.

Step S906: In the process during operation of the variable winning device, the effect control CPU 126 generates control information instructed to the VDP 152 as needed. For example, when performing an effect using the effect switching button 45 during the execution of the jackpot effect, the effect control CPU 126 monitors whether or not the effect button is operated by the player, and the effect content (button effect) according to the result. The control information is instructed to the VDP 152.

Step S908: In the post-operation processing of the variable winning device, the effect control CPU 126 executes an effect of transmitting the mode of the transition destination to the player during the end time of the variable winning device.

The effect control CPU 126 executes the coast mode rush effect or the fireworks rush rush effect according to the winning symbol. Specifically, if it corresponds to "11 round normal symbol" or "11 round probability variation symbol 1 to 11" at the time of winning, a process of selecting an effect indicating that the player is entering the "treasure challenge" is executed. , "15 round probability variation symbol 1", "15 round probability variation symbol 2-7", "3 round probability variation symbol", "5 round probability variation symbol", an effect indicating that the fireworks rush is entered. Is executed, and if it corresponds to the "5-round normal symbol", the process of selecting the effect indicating that the coastal mode is entered is executed.

As described above, according to the present embodiment, there are the following effects. (1) According to the present embodiment, even if the setting confirmation state ends in less than 128 ms, the special information continuous transmission process for continuously transmitting the security signal to the hall computer for 128 ms is executed. Even if the setting confirmation state ends immediately, the security signal can be continuously transmitted for 128 ms. As a result, it is possible to avoid the situation where the security signal is transmitted (output) for a time shorter than 128 ms, and as a result, efficient control processing related to the setting can be executed.

(2) According to the present embodiment, regardless of whether the setting confirmation state is completed in less than 128 ms, the time counting by the security signal output timer is started, so whether the setting confirmation state is completed in less than 128 ms. The process of determining whether or not to use is unnecessary, and the amount of the program can be reduced as compared with the method of starting the time counting by the security signal output timer only when the setting confirmation state ends in less than 128 ms.

(3) According to the present embodiment, since the security signal is transmitted to the hall computer until the time of the security signal output timer is up, at least even if the setting confirmation state is immediately terminated in less than 128 ms. 128ms can reliably transmit a security signal to the hall computer.

(4) In the present embodiment, when the setting change state ends, a process of setting the security signal output timer is executed in the same manner as when the setting confirmation state ends. As a result, the process of determining whether the setting change state has ended or the setting confirmation state has ended becomes unnecessary, and the amount of the program can be reduced.

(5) When confirming the settings, it is necessary to output a security signal for a certain period of time. The fixed time is preferably 50 ms or more, more preferably 128 ms or more. A security signal is output during setting confirmation, but if the setting confirmation process is completed in the shortest time (immediate end), the security signal output time will be less than a certain period of time. If the setting key is turned off during the setting confirmation, the setting confirmation ends and the game becomes playable. At this time, the security signal output timer corresponding to a certain period of time is set. Then, the security signal continues to be output until the timer for outputting the security signal expires. As a result, even if the setting confirmation is completed in the shortest time, the output time of the security signal becomes a certain time or more.

The present invention can be variously modified and implemented without being limited to the above-described embodiment. The mode of effect given in one embodiment is an example, and is not limited to the mode of effect described above.

In the above-described embodiment, the present invention has been described as an example of applying the present invention to a so-called loop type (a type in which a substantial upper limit is not set for the probability variation number), but an ST type (a substantial upper limit is set for the probability variation number). The present invention may be applied to a gaming machine of type).

In the above-described embodiment, the present invention has been described as an example of applying the present invention to a gaming machine having no probability variation region, but the present invention may be applied to a gaming machine having a probability variation region.

In the above-described embodiment, the first process is the timer interrupt process and the second process is the serial communication receive interrupt process. However, the first process may not be the interrupt process. For example, the first process may be the main loop process, and the second process may be a timer interrupt process or a serial communication receive interrupt process.

In the above-described embodiment, when the interrupt disallowed process is executed, the interrupt disallowed process is executed before the interrupt disallowed process is executed. However, when the interrupt is already disabled, the interrupt is disabled. Interrupt non-permission processing may be executed without executing interrupt prohibition processing.
For example, the interrupt enable process (step S201a) and the interrupt disable process (step S163) may not be executed.

In the above-described embodiment, among the processes for calculating the base as special information (special program code / special program data) to be arranged in the used area, a determination process for determining whether or not to calculate the base based on the gaming state, In addition, the example of including information related to at least one of the confirmation processes for confirming the value of the number of prize balls has been described, but the special information includes processes other than the determination process and the confirmation process among the processes for calculating the base. May be included, and the special information may include only information related to the determination process or only information related to the confirmation process.

In the above-described embodiment, the present invention has been described as an example of applying the present invention to a gaming machine that does not employ "simultaneous rotation of the first special symbol and the second special symbol". However, the present invention can be applied. In this case, it is also possible to add the playability of the small hit rush (the game property in which the small hit is frequently won in the second special symbol lottery).

When the simultaneous rotation is adopted, for example, a gaming machine having at least one of the following configurations can be used.
(1) During the period when the first special symbol is changing, the second special symbol can also be changed.
(2) The average fluctuation time of the first special symbol or the second special symbol can be set to a long time or a short time according to the game state.
(3) In the latent probability change state (high probability non-time reduction state), the average fluctuation time of the second special symbol can be set to a shorter time than in other gaming states (for example, normal state, low probability non-time reduction state, etc.). In addition, the probability of winning a small hit in the second special symbol lottery is set high (if it is not a big hit, the probability of winning a small hit is approximately 100% or close to it), and a prize is won in the large winning opening during the small hit game. Therefore, it is possible to set the number of balls to be ejected to increase even if the jackpot game is not executed in the latent probability change state.
(4) In the latent probability change state, the game proceeds in the right-handed state.

In the above-described embodiment, the example of the gaming machine including the performance display monitor and the setting changing device has been described, but in this case, the gaming machine can be provided with at least one of the following configurations.
(1) When setting is provided, the set value can be displayed on the performance display monitor.
(2) A plurality of types of winning probabilities of special symbol lottery (for example, winning probabilities of big hit lottery) are stored, and any probability can be set by operating a predetermined operating member or the like.
(3) Which probability is set (which setting is set) can be displayed on the performance display monitor 200. In this case, for example, after displaying the base value, the display of the set value is periodically switched to, a place where the LED is lit according to the set value (a place where the LED is lit according to the set value) is provided, or the set value is set. Information to be identified can be displayed.

The following modifications can be made to the out switch 99 (out sensor).
(1) Although one out switch 99 has been described in the example of being arranged in the confluence passage (total discharge passage) of the game board unit 8, it may be arranged in the total discharge passage on the main body frame side instead of the game board unit 8. .. In this way, the main body frame may be used as it is even if the game board unit 8 is replaced (because it may be reused), so that the cost is higher than that of mounting the out switch 99 on the game board unit 8. It can lead to reduction.

(2) Even if the number of out balls is calculated by providing out switches on the game board unit 8 side at or near each winning opening and each out opening and adding up the values detected by each out switch. Good.

(3) On the game board unit 8, an out sensor is provided near the exit of the launch rail and the entrance to the right-handed area, and the out-ball is detected by detecting the game ball hit in the game area before winning or out. You may find the number. Further, a plurality of out switches 99 may be provided instead of one, or may be provided on the game board unit 8 (on the game area) like a gate.

In the above-described embodiment, whether or not the jackpot game is being executed, whether or not the time is shortened, and whether or not the value of the launch position designation status is "1" (whether or not the right-handed instruction is being given). I explained in the example of deciding whether to calculate the base by three items such as (?), But whether or not the value of the launch position designation status is "1" (whether or not the right-handed instruction is being given). It may be decided whether or not to calculate the base only by one item such as.

Further, depending on the game specifications, the combination can be freely set, such as determining only any two items or one of the above three items. For example, in the case of a game specification in which there is no time reduction state or right-handed state, it is possible to judge only one item of "whether or not the jackpot game is being executed", and it is also possible to judge the time reduction state or right-handed state. Even if the state is provided, it is possible to determine whether or not to calculate the base based on only one item of "whether or not the jackpot game is being executed".

In the above-described embodiment, the example of displaying the value obtained by dividing the normal number of prize balls by the normal out number is described as the base to be displayed on the performance display monitor 200. For example, the number of prize balls acquired during the big hit game is a big hit. A value divided by the number of outs during the game may be displayed.

In the above-described embodiment, as a calculation method for calculating the base, the base is calculated by obtaining a value (quotient) twice the normal number of outs and then shifting the quotient by 1 bit to the right. The base may be calculated by the method of.

In the above-described embodiment, when the final base is obtained, if the lowest bit of the quotient is "1B", the quotient is shifted to the right by 1 bit, and then "1" is added to calculate the base. However, when the lowest bit of the quotient is "1B", the base may be calculated by adding "1" to the quotient and then shifting it by 1 bit to the right.

The main control device 70 may cause the performance display monitor 200 to perform a power-on operation when the power is turned on. In the power-on operation, from the time the power is turned on to the start of the base display, four 7-segment LEDs 201 to 204 (may include dot segments) of the performance display monitor 200 are set in a predetermined pattern for checking the operation. It is an operation of lighting for a predetermined time by (all blinking, all lighting, sequential lighting, etc.).

Further, the lighting in such a predetermined pattern may be performed before the base is displayed, before the set value is displayed, or after the set value is displayed. Then, when lighting in a predetermined pattern before displaying the set value, the set value cannot be displayed until the lighting in the predetermined pattern is completed, but when lighting in the predetermined pattern after displaying the set value, , There is an advantage that the set value can be confirmed at an early stage.

The performance display monitor 200 has been described with an example of switching between the base of the current section and the base of the previous section when displaying the base, but the display pattern is not limited to this, and the current display pattern is not limited to this. You may store the bases of more than two sections, such as the base of the section, the base of the previous section, and the base of the section two times before, and switch and display them.

The images given in the other production examples are just examples, and these can be appropriately deformed. Further, the structure, board surface configuration, specific numerical values, etc. of the pachinko machine 1 are preferable examples including those shown in the figure, and it goes without saying that these can be appropriately deformed.

The following technical ideas can be extracted from the above-described embodiments.
(1) The first technical idea is a configuration in which one of "normal return", "RAM clear return", "setting confirmation mode", and "setting change mode" is performed by operation.
The gaming machine is provided with a setting change device and two input devices (switches), and shifts to one of four states (normal return, RAM clear return, setting confirmation mode, setting change mode) when the power is restored. The four states are determined by a combination of two input devices (four combinations of ON and OFF).

One input device is preferably a setting key switch. The other input device can be applied with a setting switch, a RAM clear switch, other switches, and the like.
If one of the input devices is turned off while the setting is being changed, the setting is confirmed. In the conventional technique, since the setting is fixed when the lever is turned on, there is no technique that the setting is fixed when one of the input devices is turned off.
The setting during the setting change may be confirmed by another operation (for example, pressing a separately provided confirmation switch or other processing).

The game machine has a first input device (a switch that detects the operation state of the setting key) that can be turned ON / OFF related to setting changes, and a second input device (a state in which the RAM clear switch is pressed) that can be turned ON / OFF related to setting changes. A switch) and a means for setting four states (normal recovery state, RAM clear recovery state, setting confirmation mode state, setting change mode state) by combining the first input device and the second input device.

(2) The second technical idea is that when the set value is displayed on the performance display monitor, it is displayed within the used area.
The gaming machine includes a performance display monitor capable of displaying the base and a setting changing device capable of changing the set value, and displays the set value on the performance display monitor.
In addition, the process of displaying the set value on the performance display monitor is executed outside the area.

(3) The third technical idea is a configuration in which the original processing related to the performance display monitor is not performed during the setting change (setting confirmation).
The gaming machine executes the first process related to the performance display monitor and the second process related to the setting change, and while the one process is being executed, at least a part of the execution of the other process is restricted.
In addition, the process of determining whether or not to limit is executed outside the area.

(4) The fourth technical idea is the reset process of the main command permission.
During the setting change or setting confirmation, the gaming machine does not set the main command permission signal on the main control device 70 side so that the command is not received from the payout control device 92 and the payout control device 92 is prohibited from paying out. doing.

(5) The fifth technical idea is a configuration in which a command indicating that the setting is being changed is transmitted from the main control to the payout control.
The gaming machine transmits a payout operation stop command from the main control device 70 side while the setting is being changed or the setting is being confirmed, and the payout control device 92 is prohibited from paying out.

(6) The sixth technical idea is that when the setting change is completed, the process shifts to the evacuation process at the time of power failure.
The gaming machine executes a first process not related to the setting change and a second process related to the setting change, and after the second process is completed, at least a part of the first process is executed.
In addition, the gaming machine includes means for executing the process at the time of power restoration and means for executing the setting-related processing related to setting change or setting confirmation, and after executing the setting-related processing, at least one of the processes at the time of power restoration is performed. Run the part.

(7) The seventh technical idea is a configuration relating to a setting key as a switch for shifting to a "setting change state" or a "setting confirmation state".
The game machine can change the setting using the setting key, there is an insertion part to insert the setting key, the setting key has ON / OFF, and when the setting key is ON, the setting key is from the insertion part. The setting can be changed without pulling out, and when the setting key is OFF, the setting key is pulled out from the insertion portion and the setting cannot be changed.
Further, in the gaming machine, if the setting key is turned off while the setting is being changed, the setting is confirmed.

The above-described embodiment can be modified as follows. (1) When the setting key is turned off, the setting change / setting confirmation may be completed. (2) When the setting change / setting confirmation is completed regardless of the state of the inner frame, the inner frame closing timer may be abolished so that the processing related to the inner frame closing timer is not executed. That is, regardless of the state of the inner frame, when the setting key is turned off, the setting change / setting confirmation may be terminated immediately, and the game may be started with the setting displayed on the performance display monitor.

(3) "Settings are being changed" may be divided into different states such as "settings are being changed / before confirmation" and "settings are being changed / after confirmation". (4) The game may be started as it is, instead of shifting (jumping) to the evacuation process when the power is turned off at the end of the setting change.

In the above-described embodiment, the security signal output timer is set at the end of the setting confirmation state. However, the security signal output timer may be set at the start of the setting confirmation state. In this case, the execution location of the timer update process can be moved to the location where the timer update process is executed even while the setting is being changed or the setting is being confirmed.

In the above-described embodiment, the security signal output timer is set at the end of the setting confirmation state. However, if a situation occurs in which the setting confirmation state ends within a certain period of time, the setting is made at that time. It is also possible to end the setting confirmation state (delay the end of the setting confirmation state) at that time or after a certain period of time has elapsed from the start of the setting confirmation state without ending the confirmation state.

The external device may be a device other than the hall computer (test device, effect control device, payout control device, etc.). The special information may be information other than the security signal (test signal, subcommand, etc.).

The above-mentioned pachinko machine 1 is a normal gaming machine, but it is also possible to transform the above-mentioned pachinko machine 1 into a management gaming machine described below. Hereinafter, the contents of the managed gaming machine will be described in Chapters 1 to 9.

In Chapters 1 to 9 described below, the contents described in each chapter can be used alone, or the contents described in each chapter can be used in combination. In addition, the contents described in each chapter can be used in combination with a normal gaming machine (unmanaged gaming machine). In each of the following chapters, even parts having the same function may be described with different reference numerals for each chapter. Further, regardless of whether or not it has the same function as the above-mentioned ordinary gaming machine, the description may be given with the same reference numerals as those of the above-mentioned ordinary gaming machine. If the content of one chapter is different from the content of the other chapter, the content of one of the chapters can be adopted, and if the content of each chapter lacks the content of the explanation, the content of another chapter Alternatively, it can be supplemented by the above-mentioned explanation of a normal gaming machine (non-managed gaming machine).
Hereinafter, Chapters 1 to 9 will be described in order.

[Chapter 1 Management game machine]
[Overview of the 1st management game system]
[1. Introduction]
[(1) Purpose of managed gaming machines]
The management game machine aims to bring a new pachinko machine to the market at a low price in response to market demands such as measures against fraud and environmental problems due to illegal dumping.

[(2) Overview of managed pachinko and pachislot machines]
A managed gaming machine is composed of a managed gaming machine frame and a managed gaming machine game board. A certain number of gaming balls are circulated within a single machine, and the gaming balls are directly paid out to the gaming balls and players used for the game. It is a gaming machine that does not require.

An IC card unit dedicated to a managed gaming machine (hereinafter referred to as a "dedicated unit") has a function of monitoring fraudulent monitoring of the managed gaming machine and a function of displaying game launch information to the player in an easy-to-understand manner in addition to the functions of the conventional IC card unit. ) And the management game machine, the game becomes possible.

[2. Overview of the game machine management system]
[(1) Overview of the game machine management system]
This system is configured as shown in FIG. 103 to achieve the purpose described later.
FIG. 103 is a diagram showing an overall outline of the gaming machine management system.

In the hall 400, a managed gaming machine 500 and a dedicated unit 700 are arranged in the amusement park.
A management computer 800 is arranged in the office 410 of the hall 400.

The management gaming machine 500 and the dedicated unit 700 are connected by a dedicated cable 600.
The dedicated unit 700 and the management computer 800 are connected by a LAN.
The management computer 800 is connected to the card company management center 420.

The gaming machine comprehensive management center 430 includes a security management system 440 and a machine history management system 450.
The game machine comprehensive management center 430 is a union 451 by a plurality of game machine manufacturing companies, a game machine manufacturing company 452, a control CPU supply company 453 for management game machines, a communication control IC supply company 454, a CM board supply company 455, and the first association. It is connected to 456, Second Association 457, and Pachinko Company Management Center 420. The first association 456 and the second association 457 authenticate game machines and parts, for example.

Here, the solid line (thick line) in the figure means the connection by VPN using the closed network, and the dotted line (thin line) in the figure means the connection by the network selected by each company.
The connection is a connection between computers (hereinafter, the same applies).

[(2) Management game machine]
(I) Belonging to the same classification as the above-mentioned pachinko machine 1, the player plays a game by launching the game ball onto the management game machine game board surface.
(Ii) Structurally, the upper and lower plates are eliminated, and the player does not directly touch the game ball.
(Iii) The minimum number of gaming balls required for launching the managed gaming machine is circulated in the managed gaming machine, and a launching device, a ball polishing device, and a gaming ball circulation device are provided in the middle of the circulation.
(Iv) The launching device has the launching performance of the current gaming machine.
(V) In the ball polishing device, a polishing cloth for removing dirt from the game ball is stored in the cassette, and the ball polishing device is replaced at regular intervals.
(Vi) The number of game balls and the number of acquired game balls are managed and displayed as numerical data by the management game machine.
(Vii) At the end of the game, the number of game balls managed by the managed gaming machine is transferred to the dedicated unit and managed by pressing the counting switch provided on the managed gaming machine.
(Viii) A new CPU is adopted for the main control board and the frame control board of the management game machine as a countermeasure against fraud, and the communication between the main boards is encrypted.
(Ix) The external information terminal board will be abolished in managed gaming machines.

[(3) Dedicated unit]
(I) The dedicated unit and the management game machine (particularly, the dedicated unit and the frame control board as an external unit) are connected by a dedicated cable, and the frame control board of the new management game machine frame-the dedicated unit interface (hereinafter referred to as "dedicated interface"). ) Is used to encrypt and communicate data related to the gaming machine. At least a part of the dedicated interface, the dedicated cable, and the devices, boards, circuits, CPUs, software, programs, etc. associated therewith are communication control means.

(Ii) Further, the dedicated unit is a touch panel type for displaying detailed display of data related to the game ball managed by the managed gaming machine, prevention of entanglement, alerting information to the player, and various information managed by the dedicated unit. Equipped with a liquid crystal display.

(Iii) The signal output from the external information terminal board is not output from the management gaming machine, but is received by the dedicated unit via the dedicated interface and output to the external device in the hall.

(Iv) A CM (security) board is provided in the dedicated unit, and security information of the main control CPU and the frame control CPU in the management game machine is received and transmitted to the game machine general management center.

(V) Management The game ball information is received from the game machine, the counting is managed, and the game ball is monitored.

[(4) Comprehensive Pachinko and Pachinko Machine Management Center]
The gaming machine comprehensive management center 430 is composed of a machine history management system 450 and a security management system 440. The game machine general management center installs business terminals in the union 451 and the first association 456 and the second association 457 so that the state of the equipment can be constantly monitored.

The machine history management system 450 and the security management system 440 register shipping information in connection with the game machine manufacturing company 452, the management game machine control CPU supply company 453, the communication control IC supply company 454, and the CM board supply company 455, respectively. ing.

Installation information of the management gaming machine 500 and the dedicated unit 700 installed in the hall 400 is transmitted to the gaming machine general management center 430 via the card company management center 420.
The gaming machine manufacturing company 452 connected to the gaming machine general management center 430, the management gaming machine control CPU supply company 453, the communication control IC supply company 454, the CM board supply company 455, and the union 451 use a closed network. It is connected by a VPN line.

[(I) Machine history management system]
FIG. 104 is a diagram showing a schematic view (flow of machine history management) of the gaming machine management system.
Here, the solid line in the figure shows the flow of objects, and the dotted line in the figure shows the flow of information and the flow of installation information (* 1 in the figure).
The machine history management system 450 has a function of managing the shipping information of the gaming machine manufacturing company 452 and the installation information of the management gaming machine 500 installed in the hall, and monitoring shipment, installation, movement, and disposal. ..
(A) Receive and register the shipping information and disposal information of the managed gaming machine 500 from the gaming machine manufacturing company 452 which is a member of the union 451.
(B) The control CPU information for the management gaming machine is received from the control CPU supply company 453 and registered.
(C) The installation information of the management game machine 500 and the dedicated unit 700 installed in the hall is temporarily stored in the security management system 440 via the card company management center 420, and then the authentication result information and the installation information are received. Then, it is managed and monitored by the business terminal of the union 451.

[(Ii) Security management system]
FIG. 105 is a diagram showing a schematic view (flow of security management) of the gaming machine management system.
Here, the solid line in the figure shows the flow of objects, and the dotted line in the figure shows the flow of information.
The security management system 440 has a function of receiving device authentication of the management game machine 500 and the dedicated unit 700 installed in the hall, receiving the state change information of the management game machine 500, monitoring the security, and transmitting the initial setting value. Have.

(A) Generate and distribute a key to encrypt / decrypt the communication between the management game machine 500, the dedicated unit 700, the management computer 800, the card company management center 420 and the security management system 440 installed in the hall. .. This delivery is done on a regular basis.

(B) Information such as the information received by the security management system 440 and the device authentication result is shared with the machine history management system 450 as necessary.

[(5) Management computer]
(I) The management computer 800 is installed in the hall and is connected to the dedicated unit 700 in the hall by encrypted communication by LAN.
(Ii) The management computer 800 is connected to the card company management center 420 via a network.
(Iii) The encrypted management game machine 500 and the dedicated unit 700 authentication information is received and transmitted to the card company management center 420.

FIG. 106 is a diagram showing a connection image between the management gaming machine and the dedicated unit.
The management gaming machine 500 and the dedicated unit 700 are connected by a dedicated cable 600.
The management game machine 500 includes a handle 510, a game ball number display device 520, a counting switch 530, and other production devices 540.

The dedicated unit 700 includes a bill insertion slot 711, a card insertion slot 720, a touch panel type liquid crystal display 730, and the like.
The touch panel type liquid crystal display 730 can display a ball lending / returning display 731, a balance display 732, and the like.

[4. About security]
[(1) Security enhancement items]
107 to 110 are diagrams showing security enhancement items.
The following security measures are taken for managed gaming machines and the like.

[No. 1]
Goto Name: Bringing in a ball Goto Goto Contents: An act of bringing a low-priced game ball to a high-priced management game machine and illegally ingesting a prize due to a difference in the amount of money Management game machine: (1) Adopting an enclosed type Unit: Not applicable

[No. 2]
Goto Name: Magnet Goto Goto Contents: The act of manipulating a game ball with a powerful magnet to illegally obtain the ball Management game machine: (1) Adopt a game ball made of austinite steel (special stainless steel) that does not stick to the magnet .. (2) Equipped with a function to detect a game ball that reacts with a magnet.
Dedicated unit: Not applicable

[No. 3]
Goto name: Sensor deception Goto (infrared rays, electromagnetic waves, electromagnetic induction, etc.)
Goto content: The act of illegally obtaining a ball by malfunctioning the sensor using an infrared strobe, radio, etc. Management game machine: (1) Monitoring function that compares the number of winning signals of the sensor with the number of actual balls after passing the sensor Is installed. (2) Management game machine Equipped with a function to monitor the difference between the ball launched on the game board and the ball that has passed through the out port. (3) As for electromagnetic wave countermeasures, an electromagnetic wave detection sensor is provided and an iron plate is used for protection. (4) Defend by using sensors of different principles together. (5) The proximity sensor is monitored by a dedicated monitoring IC to prevent replacement of sensors having different characteristics.
Dedicated unit: Not applicable

[No. 4]
Goto Name: Sergoto, Piano Wire Goto Goto Contents: The act of inserting a cell, piano wire through the gap of the management game machine, opening the big prize opening, electric tulip, etc., and illegally obtaining the ball Management game machine: (1 ) A rat guard structure is provided at the joint with the front decoration, operation part, and back mechanism part to protect it. (2) A rat guard structure is provided to protect the back mechanism and the outer frame. (3) Defend with a structure that fills the gap between the dedicated unit and the outer frame.
Dedicated unit: Not applicable

[No. 5]
Goto Name: Threading ball Goto, Large ball Goto, Small ball Goto Goto Contents: The act of attaching a thread to a ball, firing it, manipulating the thread, and illegally obtaining the ball. The act of firing a large ball, clogging the ball and illegally obtaining the ball. The act of firing a small ball to increase the winning rate and illegally obtain the ball.
Management game machine: (1) By adopting the enclosed type, the entrance and exit of the game ball is deleted. Dedicated unit: Not applicable

[No. 6]
Goto Name: Spoofing board Goto Goto Contents: The legitimate main board is moved for authentication, and the game is controlled by another board instead of the main board. Management game machine: (1) Main control CPU and frame control Equipped with a check function by CPU authentication. (2) Equipped with an encrypted communication function.
Dedicated unit: Not applicable

[No. 7]
Goto name: Communication interface with dedicated unit Deceived Goto Goto content: Act of falsifying the communication signal between the dedicated unit and the management game machine and illegally ingesting the rental ball Management game machine: (1) Authentication by adopting the mutual monitoring function Addition of functions and encrypted communication functions Dedicated unit: Not applicable

[No. 8]
Goto Name: Remote Control Goto Goto Contents: This is a fraudulent method performed by the hall to control the ball output by looking at the complexion of the player. The command signal to the management game machine is connected by modifying the information terminal board.
Management game machine: (1) Eliminate the wiring connected to the game management machine. (2) Game information is output from the dedicated unit side. A commercial power supply (100V) and a dedicated interface (only the communication line with the dedicated unit) are connected to the management gaming machine.
Dedicated unit: Not applicable

[No. 9]
Goto name: Guarantee of game ball (holding ball) Goto content: Securing memory when power is cut off Management game machine: (1) Adopting non-volatile memory for frame control CPU Dedicated unit: Not applicable

[No. 10]
Goto name: Goto while the power is cut off Goto content: The act of opening the back mechanism of the management game machine at night and attaching illegal parts Management game machine: (1) Memory and monitoring the opening and closing of the management game machine while the power is cut off Equipped with functions Dedicated unit: Not applicable

[No. 11]
Goto name: Alarm by self-diagnosis function in the management game machine Goto content: Output of errors that are being performed on the current machine, depending on the content of the game Management game machine: (1) Output of error information Dedicated unit: Not applicable

[No. 12]
Goto name: Hanging board Goto Goto content: Act of hanging an illegal board on the main control board or frame control board to control the ball exit Management game machine: (1) Decoding when hanging between the frame control board and the main control board Equipped with a function to notify the dedicated unit authentication unit of an abnormality or recognition abnormality Dedicated unit: (1) When hanging between the frame control board and the main control board, a decoding abnormality or recognition abnormality is detected, and communication is stopped or an abnormality is notified. Equipped with a function to

[No. 13]
Goto name: Illegal board, Illegal ROM exchange Goto Goto contents: Act of replacing the genuine ROM and controlling the illegal ball ejection Management game machine: (1) When the CPU is not a genuine product due to the self-recognition function between CPUs , Equipped with a function to stop communication and notify an abnormality. (2) When the dedicated unit authentication unit is replaced with an unauthorized product, the frame control CPU detects an authentication error, stops communication, and notifies the error.
Dedicated unit: (1) The dedicated unit authentication unit is equipped with a function to notify an abnormality when the CPU is not registered in the game machine general management center (machine history management system). (2) If the dedicated unit authentication unit is replaced with an illegal product, the dedicated unit control unit will have an authentication error, communication will stop, and a function to notify the error will be installed. (3) When an unauthorized unit control unit is connected, the dedicated unit authentication unit detects an authentication error and is equipped with a function to stop communication. (4) Unauthorized CPU-equipped management When a gaming machine is connected, the dedicated unit authentication unit detects a CPU authentication error, stops communication, and notifies the error.

[No. 14]
Goto name: Decryption of code Goto content: Control board of the management game machine and the act of deciphering the encrypted communication between the management game machine and the dedicated unit to illegally control the exit of the ball Management game machine: (1) Analysis time of the encryption key It takes millions of years or more in theory, so it is impossible to analyze and tamper with the message during the business hours of the hall. Dedicated unit: (1) Since the analysis time of the encryption key theoretically takes millions of years or more, the hall It is impossible to analyze and tamper with the message during business hours of

[No. 15]
Goto name: Unauthorized falsification of the number of game balls (attack on managed game machines)
Goto content: The act of illegally obtaining a ball as a result of the above fraudulent activity Management game machine: (1) Monitor the card insertion status, and if there is a ball lending (addition request) other than the insertion status, it will not be added. Notify an abnormality. (2) A non-volatile memory is adopted, the number of game balls is held in a plurality of areas, and matching is confirmed.
Dedicated unit: (1) The dedicated unit constantly monitors the number of game balls held and the number of game balls held by the managed gaming machine, and when there is a difference in the number of game balls, notifies the game ball abnormality and stops abnormally. It is equipped with a function to do. (2) The dedicated unit is equipped with a function to notify an abnormality and stop abnormally after the recovery if the difference in the number of game balls from that before the recovery is large. (3) When the ball lender continuously requests the management game machine to exceed the threshold value (number of instructions, number of ball lending) from the dedicated unit, the dedicated unit authentication unit is equipped with a function to notify the center of an abnormality.

[No. 16]
Goto name: Unauthorized falsification of the number of game balls (attack on a dedicated unit)
Goto contents: Number of balls sent from the game management machine and the act of falsifying on the dedicated unit side Management game machine: Not applicable Dedicated unit: (1) The dedicated unit is held by the number of game balls held and the management game machine Equipped with a function that constantly monitors the number of playing balls and notifies an abnormality in the number of holding balls when there is a difference in the number of playing balls.

[No. 17]
Goto name: Card fraud Goto content: Act of illegally writing the number of balls held directly on the card Management game machine: Not applicable Dedicated unit: (1) Defend by installing an IC that guarantees strong security. (2) If it is fraudulent, it will refer to the upper server and detect an abnormality by consistency check.

[No. 18]
Goto name: Dedicated cable fraud Goto content: Act of illegally obtaining a ball between the cables connecting the management game machine and the dedicated unit or by attaching an illegal board to the connector part Management game machine: Not applicable Dedicated unit: (1) For the dedicated cable When it is hung, the dedicated unit authentication unit detects a decryption error, stops communication, and is equipped with a function to notify the error. (2) When the cable is hung on the dedicated cable, the dedicated unit authentication unit detects an authentication error, stops communication, and notifies the error.

[(2) Flow of monitoring information]
FIG. 111 is a diagram showing a flow of monitoring information.
The game machine general management center 430 and the card company management center 420 are located outside the hall.
On the other hand, the management computer 800, the dedicated unit control board 710, the dedicated unit CM board 720, the frame control board 550 (management game machine frame control board), and the main control board 560 (management game machine main control board) are arranged in the hall. There is.

[Authentication phase]
The authentication phase (authentication process) is performed between the gaming machine general management center 430 and the dedicated unit CM board 720.
Further, the authentication phase is performed between the dedicated unit CM board 720 and the frame control board 550.
Further, the authentication phase is performed between the frame control board 550 and the main control board 560.

[Recovery phase]
The recovery phase (repair process) is executed by the dedicated unit control board 710 transmitting a recovery request to the frame control board 550.
The main control board 560 transmits a recovery notification to the frame control board 550.

[Status communication phase]
The status communication phase (process for notifying the status) is as follows.

(1) Regarding the unit status information, the dedicated unit control board 710 transmits a unit status notification to the frame control board 550.

(2) Regarding ball lending information, the dedicated unit control board 710 transmits the number of ball lending to the dedicated unit CM board 720, and the dedicated unit CM board 720 notifies the frame control board 550 of the number of ball lending. Send.

(3) Regarding the counting information, the frame control board 550 transmits the counting ball number notification to the dedicated unit CM board 720, and the dedicated unit CM board 720 transmits the counting ball number to the dedicated unit control board 710.

(4) Regarding the number of game balls, the frame control board 550 transmits a game ball number notification to the dedicated unit CM board 720, and the dedicated unit CM board 720 transmits the game ball number to the dedicated unit control board 710. ..

(5) Regarding the number of launched balls information, the frame control board 550 transmits a notification of the number of launched balls to the dedicated unit CM board 720, and the dedicated unit CM board 720 transmits the number of launched balls to the dedicated unit control board 710. To do.

(6) Regarding the information on the number of balls passing through the out port, the frame control board 550 transmits a notification of the number of balls passing through the out port to the dedicated unit CM board 720, and the dedicated unit CM board 720 is out to the dedicated unit control board 710. Send the number of balls passing through the mouth.

(7) Regarding the prize ball number information, the main control board 560 transmits a prize ball number notification to the frame control board 550, and the frame control board 550 transmits the prize ball number to the dedicated unit CM board 720. The dedicated unit CM board 720 transmits the number of prize balls to the dedicated unit control board 710.

(8) Regarding the launch intensity information, the frame control board 550 transmits a launch intensity notification to the dedicated unit CM board 720, and the dedicated unit CM board 720 transmits the launch intensity to the dedicated unit control board 710.

(9) Regarding the frame state information, the frame control board 550 transmits a frame state notification to the dedicated unit CM board 720, and the dedicated unit CM board 720 transmits the frame state to the dedicated unit control board 710.

(10) Regarding the outer edge information, the main control board 560 transmits the outer edge information to the dedicated unit control board 710, and the dedicated unit control board 710 transmits the outer edge information to the card company management center 420.

(11) Regarding error information, the main control board 560 transmits a game board error notification to the frame control board 550, and the frame control board 550 transmits a frame error and a game board error notification to the dedicated unit CM board 720. Then, the dedicated unit CM board 720 transmits a frame error and a game board error to the dedicated unit control board 710, and the dedicated unit control board 710 transmits error information to the game machine general management center 430.

(12) Regarding fraud detection information, the main control board 560 transmits a fraud detection information notification to the frame control board 550, and the frame control board 550 transmits fraud detection information to the dedicated unit CM board 720 for exclusive use. The unit CM board 720 transmits fraud detection information to the dedicated unit control board 710, the dedicated unit control board 710 transmits fraud detection information to the management computer 800, and the management computer 800 sends the fraud detection information to the gaming machine general management center 430. In response, fraud detection information is sent.

(13) Regarding the card insertion information, the dedicated unit control board 710 transmits a card insertion notification to the frame control board 550.

(14) Regarding the card return information, the dedicated unit control board 710 transmits a card return notification to the frame control board 550, and the frame control board 550 transmits a card forgetting notification request to the main control board 560. ..

[Basic configuration of the second managed gaming machine]
[1. About managed pachinko machines]
[(1) Overview of managed gaming machines]
A managed gaming machine is composed of a managed gaming machine frame and a managed gaming machine game board. A certain number of gaming balls are circulated within a single machine, and the gaming balls are directly paid out to the gaming balls and players used for the game. It is a gaming machine that does not require.
An IC card unit dedicated to a managed gaming machine (hereinafter referred to as a "dedicated unit") has a function of monitoring fraudulent monitoring of the managed gaming machine and a function of displaying game launch information to the player in an easy-to-understand manner in addition to the functions of the conventional IC card unit. ) And the management game machine, the game becomes possible.

[(2) Model example of managed gaming machine]
A model example of the managed gaming machine is realized by connecting the managed gaming machine 500 and the dedicated unit 700 (see FIG. 106).

[(3) Features of managed gaming machines]
(I) It is equipped with a function to circulate game balls in the managed game machine.
(Ii) There is no upper plate and lower plate of the conventional gaming machine.
(Iii) Equipped with advanced security functions.
(Iv) A non-magnetic game ball is used.
(V) It is equipped with a function to automatically polish the game ball.
(Vi) A lock mechanism is mounted on the handle.
(Vii) It is equipped with a power saving monitoring / notification function depending on the presence or absence of a player.
(Viii) The management gaming machine is not equipped with an external information terminal board, and the information output destination to the outside is only a dedicated unit.
(Ix) A commercial power supply (100V) is used as the power supply for the management gaming machine.
(X) The management gaming machine is connected to the dedicated unit with a dedicated cable.
(Xi) The ball held during the game has a function of being managed by a managed gaming machine and displaying the number of balls.
(Xii) The number of balls held has a function of transferring the management to a dedicated unit by pressing the counting switch.

[Structural diagram of managed gaming machines]
FIG. 112 is a diagram showing an exploded perspective view of the managed gaming machine.
In the management gaming machine 500, the front decoration 512 is arranged at the upper part on the frontmost side when viewed from the player, and the operation unit 511 is arranged at the lower part on the frontmost side when viewed from the player.

A glass plate 513 is arranged behind the front decoration 512, a management game machine game board 514 is placed behind the glass plate 513, and a back mechanism portion 515 is placed behind the management game machine game board 514. An outer frame 516 is arranged behind the mechanism portion 515.

FIG. 113 is a diagram showing a front view of the managed gaming machine.
A speaker 518 is arranged above the front decoration 512 of the management gaming machine 500.
In addition, other effect switches 540 (external input switches, push buttons, etc.) are arranged on the lower left side of the front decoration 512 of the management game machine 500.

On the other hand, on the right side of the operation unit 511 of the management game machine 500, a handle 510 for launching a game ball is arranged.
Further, in the upper center of the operation unit 511 of the management game machine 500, a game ball number display device 520 composed of a 6-digit 7-segment LED is arranged.
Further, a counting switch 530 is arranged on the upper left side of the operation unit 511 of the management game machine 500.

FIG. 114 is a diagram showing a perspective view of the managed gaming machine.
In the managed gaming machine 500, the front decoration 512 can be opened.
When the front decoration 512 is opened, the front decoration 512 and the glass plate 513 are opened, and the management game machine game board arranged behind the glass plate 513 is exposed.
A launching device for launching a game ball is arranged on the upper left of the back mechanism portion 515. In this case, the launching device 517 is arranged on the upper left side, but the launching device 517 may be arranged on the rear side of the operation unit 511 as a lower launch.

FIG. 115 is a view showing a back view (with a back cover) of the managed gaming machine.
The back mechanism portion 515 is arranged inside the outer frame 516, the launching device 517 is arranged on the upper left (upper right in the figure) of the back mechanism portion 515, and the left side of the back mechanism portion 515 (FIG. The game ball circulation device 551A is arranged on the right side).

The main control board 560 is arranged in the center of the management game machine 500, and the back cover 552A is arranged in the lower part of the management game machine 500.
The frame control board 550 is arranged in the center of the back cover 552A, and the sub connection board 553 and the game ball rental device connection terminal board 554 are arranged on the left side (right side in the drawing) of the frame control board 550. ing.

FIG. 116 is a view showing a back view (state without a back cover) of the managed gaming machine.
A power supply device 570 is arranged on the lower right side of the management game machine 500 (lower left side in the drawing), and an iron ball detection device 571 for detecting an iron game ball and an iron ball detection device 571 in the lower center of the management game machine 500. , A ball polishing device 572 for polishing a game ball is arranged.

[3. Basic specifications of managed gaming machines]
[(1) Equipment installed in managed gaming machines]
FIG. 117 is a diagram showing a device mounted on a managed gaming machine.
The management game machine 500 includes a management game machine game board 580 and a management game machine frame 590.
The managed gaming machine frame 590 is mainly composed of a back mechanism portion 515, an outer frame 516, and parts and devices associated therewith.

The management game machine game board 580 includes a game board (acrylic board), a symbol display device (special symbol display device, ordinary symbol display device), a prize detection mechanism (various switches), a windmill, a game nail, and other production devices (production). It is composed of a movable body, a liquid crystal display, an information display device, a production lamp, a speaker), a winning display device, a device that changes the direction of falling (movable member, lid member), and the like.

On the other hand, the management game machine frame 590 includes a game ball, a launching device, a power supply device, a ball polishing device, a game ball circulation device, a game ball number display device, a glass plate, a night monitoring device, other production devices, and an iron ball detection device. It is composed of etc.

The device mounted on the management gaming machine 500 has a configuration as shown in this figure.
The management game machine 500 does not require a function of paying out game balls, and a new device not found in conventional pachinko machines is mounted on the management game machine frame.

[Standards for devices mounted on managed gaming machine frames]
The standards of the devices mounted on the managed gaming machine frame are as follows.

(I) About the game ball (A) Performance (a) Must not be significantly affected by magnetic force.
(B) The shape does not change even after one million shots.

(B) Structure (a) The diameter of the game ball shall be 11 mm.
(B) The mass of the game ball shall be 5.4 g or more and 5.7 g or less.
(C) The material of the game ball shall be equivalent to SUS316 (hardening treatment).

(Ii) About the launching device (A) Performance (a) Being able to launch one game ball at a time.
(B) It is not possible to launch more than 100 game balls per minute.

(B) Structure (a) The number of launchers shall be one.
(B) The launching device shall have a structure that does not allow the gaming ball to be launched, except when the player directly operates the launching device.

(Iii) Power supply unit (A) Performance (a) Input power supply shall be AC100V ± 10%.

(B) Structure (a) The power supply device shall be covered with a resin case to maintain safety.

(Iv) About the ball polishing device (A) Performance (a) Automatically polishing dirt on the game ball.

(B) Structure (a) The structure shall be such that the automatic wiping part is wound up at the same time as polishing the game ball.
(B) The device should be easily replaced because it needs to be replaced due to its life.

(V) Game ball circulation device (A) Performance (a) Having a function to circulate a certain number of game balls.

(B) Structure (a) Having a function of sending game balls one by one to the launching device.
(B) The structure shall be such that the player cannot take out the game ball.

(Vi) Display device for the number of game balls, etc. (A) Performance (a) The number of game balls shall be able to be displayed in units of one.
(B) The number of digits shall be able to display up to 6 digits.

(B) Structure (a) The player can easily check the displayed contents.

(Vii) Glass plate (A) Performance (a) Colorless and transparent.

(B) Structure (a) Management game machine It is not possible to prevent the visibility of the entire structure of the game board.
(B) Management game machine The position of the game ball on the game board can be confirmed.

(Viii) Night monitoring device (A) Performance (a) Having a function to notify when the power is turned on that the back mechanism is opened while the power is off.
(B) Structure (a) The structure should be able to detect the opening of the back mechanism.

(Ix) Other production devices (A) Performance (a) In addition to production applications, it shall have a function to notify fraud by sound and lamp.

(B) Structure (a) The speaker shall have a structure that is not easily damaged from the outside.

(X) Iron ball detection device (A) Performance (a) Having a function to detect and notify the iron ball without circulating it.

(B) Structure (a) A structure that cannot be operated by the player.

[(3) Functions of managed gaming machines]
[(I) Main control function]
[(A) Block diagram]
FIG. 118 is a diagram showing a block diagram of the main control function.
The management gaming machine frame 590 includes a frame control board 550 having a communication control circuit 551.
The management game machine game board 580 includes a main control board 560 having a communication control circuit 561, a sensor detection circuit 562, and a winning display data transmission circuit 563.
Each winning opening sensor 564, fraud detection sensor 565, and winning display device 566 are connected to the main control board 560.

The frame control board 550 and the main control board 560 can communicate with each other via the communication control circuit 551 and the communication control circuit 561.

Information from each winning opening sensor 564 (winning opening corresponding to a normal symbol or a special symbol, a large winning opening, etc.) and fraud detection sensor 565 (magnetic sensor, radio wave sensor, vibration sensor, etc.) is transmitted via a sensor detection circuit 562. It can be transmitted to the main control board 560.
The information from the main control board 560 can be transmitted to the winning display device 566 via the winning display data transmission circuit 563.

[(B) Function description]
The main control board 560 detects the winning ball and transmits command data to the frame control board 550. Also, when fraud is detected, command data is sent in the same way.

[(A) Winning ball detection function]
The main control board 560 outputs the number of game balls won in each winning opening and the number of acquired game balls set for each winning opening to the frame control board 550 as a serial signal (command format) at regular intervals.

[(B) Winning display function]
When the game balls win and detect each winning opening, the main control board 560 displays the number of acquired game balls set for each winning opening on the winning display device 566.

[(C) Fraud detection function]
FIG. 119 is a diagram showing a list of frauds detected by the main control board of the management gaming machine.
The fraud detected by the main control board 560 is as follows.

Name: Illegal board 1
Contents: Board surface fraud 1 was detected.

Name: Board fraud 2
Contents: Board surface fraud 2 was detected.

Name: Board fraud 3
Contents: Board surface fraud 3 was detected.

Name: Board fraud 4
Contents: Board surface fraud 4 was detected.

Name: Board fraud 5
Contents: Board surface fraud 5 was detected.

[(Ii) Prize ball control function]
[(A) Block diagram]
FIG. 120 is a diagram showing a block diagram of the prize ball control function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
The management gaming machine frame 590 includes a frame control board 550 having a communication control circuit 551.

The information from the frame control board 550 can be transmitted to the gaming machine connection board 701 via the communication control circuit 551 and the communication control circuit 702.

The management game machine game board 580 includes a main control board 560 having a communication control circuit 561.
The information from each winning port sensor 564 can be transmitted to the frame control board 550 via the communication control circuit 561 and the communication control circuit 551.

The management game machine frame 590 includes an inner frame relay board 552, a launch relay board 553C, and an operation unit relay board 554C.
Information from the winning sensor 555 and the non-winning sensor 556 can be transmitted to the frame control board 550 via the inner frame relay board 552 and the communication control circuit 551.
Further, the information from the subtraction sensor 557 can be transmitted to the frame control board 550 via the launch relay board 553C and the communication control circuit 551.
Further, the information from the counting switch 530 can be transmitted to the frame control board 550 via the operation unit relay board 554C and the communication control circuit 551.
On the other hand, the information from the frame control board 550 can be transmitted to the game ball number display device 520 via the communication control circuit 551 and the operation unit relay board 554C.

[(B) Function description]
The prize ball control function controls the number of game balls by the following functions.
[(A) Acquisition game ball number reception function]
When the frame control board 550 receives a request for the number of acquired game balls from the main control board 560, the frame control board 550 adds the requested number of acquired game balls to the number of game balls and displays the number of acquired game balls on the display device 520 such as the number of game balls.

[(B) Launch ball detection function]
When the subtraction sensor detects the launch of the game ball, the number of game balls is subtracted by 1 and displayed on the display device such as the number of game balls.

[(C) Counting ball transmission function]
When the counting switch is pressed, the number of counting balls is transmitted to the dedicated unit, and the number of counting balls is subtracted from the number of game balls. The number of game balls after the subtraction is displayed on the game ball number display device 520.

[(D) Out ball detection function]
When the winning sensor 555 and the non-winning sensor 556 detect a game ball, it is added as the number of out balls. The ball circulation is managed according to the number of out balls and the number of launch balls.

[(E) Error detection function]
FIG. 121 is a diagram showing an error detected by the prize ball control function.
The errors detected by the prize ball control function are as follows.

Name: Game ball number display overflow Contents: The number of digits of the game ball number display device has exceeded (990,000 balls or more).

Name: Subtraction sensor error Description: When the subtraction sensor is detecting ball clogging or a failure of the subtraction sensor is detected.

Name: Abnormal discharge ball passage Description: A ball clogging was detected between the discharge ball passage and the ball polishing device.

Name: Abnormality in the winning ball passage Description: A ball clogging was detected between the ball polishing devices from the winning ball passage.

[(Iii) Ball currency control function]
[(A) Block diagram]
FIG. 122 is a diagram showing a block diagram of the ball coin control function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702 and a touch panel type liquid crystal display 730.
Further, the management game machine frame 590 includes a game ball rental device connection terminal plate 554, a frame control board 550 having a communication control circuit 551, an operation unit relay board 554C, a counting switch 530, and a game ball number display device 520. I have.

Information from the counting switch 530 can be transmitted to the game machine connection board 701 via the operation unit relay board 554C, the communication control circuit 551, the game ball rental device connection terminal board 554, and the communication control circuit 702.
Information from the game machine connection board 701 can be transmitted to the game ball number display device 520 via the communication control circuit 702, the game ball rental device connection terminal board 554, the communication control circuit 551, and the operation unit relay board 554C. ..
Information (information regarding ball lending and return) from the touch panel type liquid crystal display 730 can be transmitted to the gaming machine connection board 701 via the communication control circuit 702.

[(B) Function description]
The ball lending control function manages the number of game balls by the following functions.
(A) Game ball addition reception function When the frame control board 550 receives a request for addition of the number of balls to be rented from the dedicated unit 700, the requested number of balls to be rented is added to the number of games to be rented, and the frame control board 550 is displayed on the display device for the number of games to be rented. indicate.

(B) Error Detection Function FIG. 123 is a diagram showing a list of errors detected by the ball lending control function.
The errors detected by the ball lending control function are as follows.

Name: Illegal ball lending detection Details: Received a request to add the number of lending balls other than while inserting the card.

[(Iv) counting function]
[(A) Block diagram]
FIG. 124 is a diagram showing a block diagram of the counting function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
Further, the management game machine frame 590 includes a game ball rental device connection terminal plate 554, a frame control board 550 having a communication control circuit 551, an operation unit relay board 554C, and a counting switch 530.

Information from the counting switch 530 can be transmitted to the game machine connection board 701 via the operation unit relay board 554C, the communication control circuit 551, the game ball rental device connection terminal board 554, and the communication control circuit 702.

[(B) Function description]
The counting function transmits the game ball managed by the frame control board 550 to the dedicated unit 700 by the following functions.

[(A) Counting ball transmission function]
When the counting switch 530 is pressed, the specified (specified) number of counting balls is transmitted to the dedicated unit 700 and subtracted from the number of game balls.

FIG. 125 is a diagram showing the conditions for the number of counting balls.
The number of counting balls is determined by the following conditions.

[Condition] When the counting switch is pressed [Number of counting balls] The number of counting balls increases at an accelerating rate according to the length of the pressing time.

[(V) Display function for the number of game balls, etc.]
[(A) Block diagram]
FIG. 126 is a diagram showing a block diagram of a display function such as the number of game balls.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
Further, the management game machine frame 590 includes a game ball rental device connection terminal board 554, a frame control board 550 having a communication control circuit 551, an operation unit relay board 554C, and a game ball number display device 520.

Information from the game machine connection board 701 can be transmitted to the frame control board 550 via the communication control circuit 702 and the game ball rental device connection terminal board 554.
Information from the operation unit relay board 554C can be transmitted to the frame control board 550 via the communication control circuit 551.
The information from the operation unit relay board 554C can be transmitted to the game ball number display device 520.

[(B) Function description]
The game ball number display device 520 displays the game ball number and the like by the following functions.

(A) Game ball number display function The number of game balls received from the dedicated unit 700 is displayed.
In addition, the frame control board 550 displays the number of launched balls and the number of game balls obtained by adding or subtracting acquired balls.

(B) Error Display Function The frame control board 550 displays an error code prepared in advance according to an abnormality.

[(Vi) security function]
〔Block Diagram〕
FIG. 127 is a diagram showing a block diagram of a security function.
The dedicated unit 700 includes a gaming machine connection board 701 having an authentication / communication control circuit 702A.
Further, the management game machine frame 590 includes a game ball rental device connection terminal plate 554 and a frame control board 550 having an authentication / communication control circuit 551B.
Further, the management game machine game board 580 includes a main control board 560 having an authentication / communication control circuit 561A.

Information from the game machine connection board 701 can be transmitted to the frame control board 550 via the authentication / communication control circuit 702A, the game ball rental device connection terminal board 554, and the authentication / communication control circuit 551B.
The information from the main control board 560 can be transmitted to the frame control board 550 via the authentication / communication control circuit 561A and the authentication / communication control circuit 551B.

The information from the frame control board 550 can be transmitted to the main control board 560 via the authentication / communication control circuit 551B and the authentication / communication control circuit 561A.
The information from the frame control board 550 can be transmitted to the game machine connection board 701 via the authentication / communication control circuit 551B, the game machine rental device connection terminal board 554, and the authentication / communication control circuit 702A.

[(B) Function description]
Surveillance communication is performed between the management game machine and the dedicated unit, and the determination of the regular management game machine and the consistency of the communication data are confirmed. This makes it easier to find illegally modified management gaming machines, and makes it impossible to illegally target an interface with a dedicated unit.

[(A) Authentication function]
The unique ID information stored in the main control CPU and the frame control CPU of the management game machine is sent to the security management system 440 (see FIG. 103) via the communication network of the card unit, and the machine history management system 450 (FIG. 103). Refer to) to check the ID information registered in) to determine whether the machine is a legitimate management game machine. If the authentication fails, the management gaming machine does not operate and the information is output to the dedicated unit 700. All information at the time of authentication is transmitted and received by encryption.

[(B) Cryptographic function]
The encryption key used in the main control CPU of the management game machine, the frame control CPU, and the communication IC of the dedicated unit is automatically generated each time it is connected, and the generated key is different for each management game machine. Is unique (unique), and data analysis and falsification are impossible. A predetermined method is used for the encryption specifications.

[(C) Security data output function]
By performing authentication judgment and encrypted communication, the tamper resistance of data security is significantly improved. Since the generated encryption key is different for each managed gaming machine, the content of the telegram is unique and it is impossible to analyze or falsify the data.

[(Vii) information output function]
[(A) Block diagram]
FIG. 128 is a diagram showing a block diagram of the information output function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702 and an external terminal 558.
Further, the management gaming machine frame 590 includes a gaming ball rental device connection terminal plate 554 and a frame control board 550 having a communication control circuit 551.
Further, the management game machine game board 580 includes a main control board 560 having a communication control circuit 561.

The information from the main control board 560 can be transmitted to the hall computer HC via the communication control circuit 561, the communication control circuit 551, the game ball rental device connection terminal board 554, the communication control circuit 702, and the external terminal 558.

[(B) Function description]
The management gaming machine transmits the information output to the hall computer HC to the dedicated unit 700.
The dedicated unit 700 outputs the information transmitted from the management gaming machine to the hall computer HC.

[(A) Information output content]
FIG. 129 is a diagram showing the contents output by the dedicated unit to the hall computer.
The contents output by the dedicated unit to the hall computer based on the information from the management gaming machine are as follows.

[Order 1]
Name: Number of shots Contents: Outputs the number of shots.

[Order 2]
Name: Prize ball Contents: Output the total number of prize balls.

[Order 3]
Name: Illegal Content: Output when an illegality is detected.

[Order 4]
Name: Management game machine error Description: Output when a management game machine error occurs.

[Order 5]
Name: Number of symbol fluctuations 1
Contents: Output every time the special symbol 1 (first special symbol) is stopped.

[Order 6]
Name: Starting port 1
Contents: Output every time a prize is won in the starting port 1 (starting port corresponding to the first special symbol).

[Order 7]
Name: Big hit 1
Contents: Output during all jackpots.

[Order 8]
Name: Big hit 2
Contents: Output during big hit and small hit. It is normally output when the electric accessory is activated.

[Order 9]
Name: Big hit + time saving Contents: Output during big hit and time saving.

[Order 10]
Name: High probability Medium Contents: High probability medium (high probability non-time shortened state or high probability time shortened state) is output.

[Order 11]
Name: Time saving Medium Contents: Output during time saving medium (low probability time shortening state or high probability time shortening state).

[Order 12]
Name: Door open Contents: Output when the front decoration or back mechanism is open.

[Order 13]
Name: Number of symbol fluctuations 2
Contents: Output every time the special symbol 2 (second special symbol) stops.

[Order 14]
Name: Starting port 2
Contents: Output every time a prize is won in the starting port 2 (starting port corresponding to the second special symbol).

[Order 15]
Name: Passing Gate 1
Contents: Output each time the passage gate 1 (for example, the first start gate corresponding to a normal symbol) is passed.

[Order 16]
Name: Big hit 3
Contents: Output at the time of big hit that shortens the time (shortening the fluctuation time).

[Order 17]
Name: Passing Gate 2
Contents: Output each time a passing gate 2 (for example, a second starting gate corresponding to a normal symbol) is passed.

[Order 18]
Name: Number of characters (number of times the winning opening is opened)
Contents: Output every time the accessory (special electric accessory) is opened.

[Order 19]
Name: Number of prizes for prizes (number of prizes for large prizes)
Contents: Output every time a prize is won in a character (special electric character, big prize opening).

[Order 20]
Name: Passing through a specific area Contents: Output each time passing through a specific area (specific area or probabilistic area).

[(Viii) power supply function]
[(A) Block diagram]
FIG. 130 is a diagram showing a block diagram of the power supply function.
The management gaming machine frame 590 includes a power supply device 570, a frame control board 550, a front decoration 512, an operation unit 511, and a sub-connection board 553.
The power supply device 570 includes a main switch, 5V generation circuit 1, 12V generation circuit 1, 24V generation circuit 1, power supply disconnection detection circuit A, power supply disconnection detection circuit B, 12V generation circuit 2, 12V generation circuit 3, and 24V generation circuit 2. I have.

The frame control board 550 includes a 3.3V generation circuit, a game ball clear switch, and a RAM clear switch.

The management game machine game board 580 includes a main control board 560 having a backup power supply and an effect control board 900.

AC100V is supplied to the power supply device 570.
The power supply device 570 supplies DC5V-1, DC12V-1, and DC24V-1 to the frame control board 550 by using various circuits.
Further, the power supply device 570 transmits information regarding the power failure detection A and the power failure detection B to the frame control board 550.
Further, the power supply device 570 supplies DC12V-2, DC12V-3, and DC24V-2 to the sub-connection board 553 by using various circuits.

The frame control board 550 supplies DC5V-1, DC12V-1, and DC24V-1 to the main control board 560 (backup power supply) by using various circuits.
Further, the frame control board 550 transmits information regarding the power failure detection A and the RAM clear switch to the main control board 560.

The sub-connection board 553 supplies DC12V-3 to the front decoration 512 and the operation unit 511.
Further, the sub-connection board 553 supplies DC12V-2, DC12V-3, and DC24V-2 to the effect control board 900.

[(B) Function description]
The power supply required for the management gaming machine is generated from AC100V.

[(A) Main system power generation function]
A rectified and smoothed power supply is generated as a main power supply (DC24V, DC12V, DC5V) by a switching method. The generated power supply is supplied to the frame control board 550, and power is supplied to the main control board 560 via the frame control board 550. Further, DC 3.3V is generated inside the frame control board 550.

[(B) Sub system power generation function]
It is generated as a sub system power supply system (DC24V, DC12V) with a configuration that is separate from the main system power supply system. The DC12V produces two systems, a large capacity (mainly used in the managed gaming machine game board) and a small capacity (mainly used in the managed gaming machine frame).

The generated power supply is supplied to the front decoration 512, the operation unit 511, and the effect control board 900 via the sub-connection board 553.

[(C) Backup function]
The backup function is composed of a backup power supply and a power supply disconnection detection circuit, and stores the game state in the RAM of the main control board 560 and the frame control board 550 when the power is cut off.
The backup power supply for the main control is configured to be mounted on the management game machine game board 580.
Since the frame control board 550 uses a non-volatile raw RAM, a backup power supply is not used. The power failure detection circuit monitors AC100V in the power supply device. When the power is cut off, two power cutoff signals for the main control board and the frame control board are generated and output.

[(C) Switch function]
The main switch is mounted on the power supply device 570 and switches between supplying and shutting off AC100V.
The game ball clear switch and RAM clear switch are mounted on the frame control board.
The game ball clear switch initializes the data related to the game ball, and the RAM clear switch initializes the RAM data excluding the data related to the game ball.
Only the signal related to the RAM clear switch is output from the frame control board 550 to the main control board 560.

[(Ix) launch function]
〔Block Diagram〕
FIG. 131 is a diagram showing a block diagram of the firing function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
Further, the management game machine frame 590 includes a game ball rental device connection terminal plate 554, a frame control board 550 having a communication control circuit 551 and a launch control circuit 902, an operation unit relay board 554C, a polishing relay board 904, and a launch relay. It includes a substrate 906.

A handle volume 910, a launch stop switch 912, and a touch sensor 914 are connected to the operation unit relay board 554C.
A launch solenoid 916, a ball feed solenoid 918, a subtraction sensor 920, and a launch inlet sensor 922 are connected to the launch relay board 906.

Information from the handle volume 910, the launch stop switch 912, and the touch sensor 914 is transmitted via the operation unit relay board 554C, the launch control circuit 902, the communication control circuit 551, the game ball rental device connection terminal plate 554, and the communication control circuit 702. It can be transmitted to the game machine connection board 701.
Further, the information from the game machine connection board 701 is fired via the communication control circuit 702, the game ball rental device connection terminal board 554, the communication control circuit 551, the launch control circuit 902, the polishing relay board 904, and the launch relay board 906. It can be transmitted to the solenoid 916 or the ball feed solenoid 918.

Information from the launch control circuit 902 can be transmitted to the launch solenoid 916 or the ball feed solenoid 918 via the polishing relay board 904 and the launch relay board 906.
Further, the information from the subtraction sensor 920 or the launch inlet sensor 922 includes the launch relay board 906, the polishing relay board 904, the launch control circuit 902, the communication control circuit 551, the game ball rental device connection terminal plate 554, and the communication control circuit 702. It can be transmitted to the game machine connection board 701 via.

[(B) Function description]
The frame control board 550 launches a game ball by driving a launch solenoid 916 in the launch device.

[(A) Touch detection function]
The touch sensor 914 detects whether the player is touching the steering wheel.

[(B) Launch stop function]
When the touch sensor 914 does not detect the touch state, when the firing stop switch 912 is pressed, when the handle is not turned more than a certain angle, when an error is detected that the firing is stopped (the target error is the error detection function). In the case of), stop firing.

[(C) Launch strength adjustment function]
By operating the handle, the strength of the handle volume 910 provided inside the handle is adjusted, and the game ball is launched to an arbitrary position on the game board surface of the management game machine.

[(D) Ball feed function]
The ball feed solenoid 918 is operated to feed the game ball to the launch position. At that time, the number of game balls that can be launched is subtracted by 1 by the subtraction sensor 920 provided in the launching device unit.

[(X) Game ball circulation function]
[(A) Block diagram]
FIG. 132 is a diagram showing a block diagram of the game ball circulation function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
Further, the management game machine frame 590 includes a frame control board 550 having a game ball rental device connection terminal board 554, a communication control circuit 551, a motor control circuit 924 and a sensor circuit 926, a polishing relay board 904, and a lifting relay board 928. It includes a launch relay board 906 and an inner frame relay board 930.

A lifting motor 932, a lifting inlet sensor 934, and a lifting motor sensor 936 are connected to the lifting relay board 928.
A launch inlet sensor 922 is connected to the launch relay board 906.
A ball clogging sensor 938, a winning sensor 555, and a non-winning sensor 556 are connected to the inner frame relay board 930.

The information from the frame control board 550 can be transmitted to the game machine connection board 701 via the communication control circuit 551, the game ball rental device connection terminal board 554, and the communication control circuit 702.
Information from the game machine connection board 701 can be transmitted to the frame control board 550 via the communication control circuit 702, the game ball rental device connection terminal board 554, and the communication control circuit 551.

Information from the frame control board 550 can be transmitted to the lifting motor 932 via the communication control circuit 551, the motor control circuit 924, the polishing relay board 904, and the lifting relay board 928.
Further, the information from the lifting inlet sensor 934 and the lifting motor sensor 936 can be transmitted to the frame control board 550 via the lifting relay board 928, the polishing relay board 904, the sensor circuit 926, and the communication control circuit 551.
Further, the information from the launch inlet sensor 922 can be transmitted to the frame control board 550 via the launch relay board 906, the polishing relay board 904, the sensor circuit 926, and the communication control circuit 551.
Furthermore, the information from the ball clogging sensor 938, the winning sensor 555, and the non-winning sensor 556 can be transmitted to the frame control board 550 via the inner frame relay board 930, the sensor circuit 926, and the communication control circuit 551.

[(B) Function description]
The frame control board 550 operates the lifting motor 932 to move the game ball to the launch position and circulate the game ball.

[(A) Lifting function]
The frame control board 550 uses a lifting motor 932 to move the game ball to the launch unit.
The frame control board 550 detects whether or not a game ball exists at the inlet and the launch inlet of the lift motor 932 by the lift inlet sensor 934 and the launch inlet sensor 922, and drives and stops the lift motor 932.
Further, the lifting motor sensor 936 detects whether the lifting motor 932 is rotating normally.

[(B) Game ball management function]
The frame control board 550 manages the number of game balls required for circulation by the ball clogging sensor 938, the winning sensor 555, and the non-winning sensor 556, and notifies when there is excess or deficiency.

[(C) Error detection function]
FIG. 133 is a diagram showing an error detected by the game ball circulation function.
The errors detected by the game ball circulation function are as follows. After removing the error factor, the frame control board 550 cancels the error by pressing the error canceling switch.

Name: Game ball circulation device error Description: It was detected that the lifting motor did not rotate.

Name: Game ball circulation device passage abnormality Description: Ball clogging was detected in the game ball circulation device.

[(Xi)]
[(A) Block diagram]
FIG. 134 is a diagram showing a block diagram of the ball polishing function.
The management game machine frame 590 includes a frame control board 550 having a motor control circuit 924 and a sensor circuit 926, and a polishing relay board 904.

A cassette motor 940, a polishing motor 942, a cassette switch 944, and a polishing motor sensor 946 are connected to the polishing relay board 904.

Information from the frame control board 550 can be transmitted to the cassette motor 940 and the polishing motor 942 via the motor control circuit 924 and the polishing relay board 904.
Information from the cassette switch 944 and the polishing motor sensor 946 can be transmitted to the frame control board 550 via the polishing relay board 904 and the sensor circuit 926.

[(B) Function description]
The frame control board 550 uses a cassette on which a polishing cloth is mounted to polish the game ball. Further, the frame control board 550 detects the cassette on which the polishing pad is mounted.

[(A) Ball polishing function]
The polishing motor 942 is operated to push the game ball against the polishing cloth to polish the game ball. The polishing cloth has a structure mounted on a cassette and can be replaced, and a cassette motor 940 is used to move the cloth so as to wind it up at regular intervals.

[(B) Cassette detection function]
The cassette switch 944 detects the presence or absence of a cassette on which the polishing cloth is mounted.

[(C) Error detection function]
FIG. 135 is a diagram showing an error detected by the ball polishing function.
The errors detected by the ball polishing function are as follows. After removing the cause of the error, the frame control board 550 cancels the error by pressing the error canceling switch. When the cassette is installed at the end of the cassette, the error is automatically cleared when the cassette is installed.

Name: Ball polishing device error Description: It was detected that the polishing motor did not rotate.

Name: Ball polisher passage abnormality Description: Ball clogging was detected in the ball polisher.

Name: Cassette not installed Contents: Detected that the ball polishing device is not equipped with a cassette.

[(Xii)]
[(A) Block diagram]
FIG. 136 is a diagram showing a block diagram of the power saving function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
The management game machine frame 590 includes a game ball rental device connection terminal plate 554, a frame control board 550 having a communication control circuit 702 and a launch control circuit 902, and an operation unit relay board 554C.
A touch sensor 914 is connected to the operation unit relay board 554C.

The management game machine game board 580 includes a main control board 560 having a communication control circuit 561 and an effect control board 900 having a communication control circuit 901.
Another effect device 540A is connected to the effect control board 900.

Information from the main control board 560 can be transmitted to the game machine connection board 701 via the communication control circuit 561, the communication control circuit 551, the game ball rental device connection terminal board 554, and the communication control circuit 702.
Information from the game machine connection board 701 can be transmitted to the main control board 560 via the communication control circuit 702, the game ball rental device connection terminal board 554, the communication control circuit 551, and the communication control circuit 556.
The information from the main control board 560 can be transmitted to the effect control board 900 and the other effect device 540A via the communication control circuit 561 and the communication control circuit 901.
The information from the touch sensor 914 can be transmitted to the frame control board 550 via the operation unit relay board 554C, the launch control circuit 902, and the communication control circuit 551.

[(B) Function description]
The frame control board 550 determines the non-gaming state, notifies the main control board 560, and shifts the other effect device 540A to the power saving state.

[(A) Power saving function]
This is a function of urging the main control board 560 by the frame control board 550 to shift to the power saving state.

[(B) Power saving function operation request]
When the touch end is detected, the game ball "0", the IC card end is inserted, or the fluctuation is stopped, the frame control board 550 makes an operation request.

[(Xiii) Night monitoring function]
[(A) Block diagram]
FIG. 137 is a diagram showing a block diagram of the night monitoring function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
The management gaming machine frame 590 includes a frame control board 550 having a communication control circuit 551 and an inner frame relay board 930.
A night monitoring device 948 is connected to the inner frame relay board 930.

The management game machine game board 580 includes a main drawer board 950 and a main control board 560 having a communication control circuit 561.

Information from the main control board 560 can be transmitted to the dedicated unit 700 via the communication control circuit 561, the main drawer board 950, the communication control circuit 551, and the communication control circuit 702.
Information from the frame control board 550 can be transmitted to the main control board 560 via the communication control circuit 551, the main drawer board 950, and the communication control circuit 561.

The information from the frame control board 550 can be transmitted to the night monitoring device 948 via the communication control circuit 551 and the inner frame relay board 930.
The information from the night monitoring device 948 can be transmitted to the frame control board 550 via the inner frame relay board 930 and the communication control circuit 551.

[(B) Function description]
The night monitoring function suppresses fraud that accompanies opening the door at night by the following functions.

[(A) Back mechanism opening monitoring function]
The nighttime monitoring power supply mounted on the nighttime monitoring device 948 monitors the opening of the back mechanism even when the power is off.

[(B) Opening count storage function]
Even if the back mechanism portion is opened a plurality of times, the number of times of opening is stored.

[(C) Disconnection monitoring function]
The night monitoring power supply of the night monitoring device 948 is looped back between the night monitoring device 948 and the main control board 560, and when the board is replaced or the management game machine game board is removed, the night monitoring device 948 is used. It will be detected and notified the next time monitoring information is sent.

[(D) Open information output function]
When a transmission request is received from the frame control board 550, the opening information of the back mechanism portion is output.

[(Xiv) Iron ball detection function]
[(A) Block diagram]
FIG. 138 is a diagram showing a block diagram of the iron ball detection function.
The management game machine frame 590 includes a frame control board 550 having a sensor circuit 926, an inner frame relay board 930, and a polishing relay board 904.
A ball clogging sensor 938 is connected to the inner frame relay board 930, and a polishing inlet sensor 952 is connected to the polishing relay board 904.

The information from the ball clogging sensor 938 can be transmitted to the frame control board 550 via the inner frame relay board 930 and the sensor circuit 926.
Information from the polishing inlet sensor 952 can be transmitted to the frame control board 550 via the polishing relay board 904 and the sensor circuit 926.

[(B) Function description]
The iron ball detection function detects an iron ball by the following functions.

[(A) Iron ball detection function]
The detection magnet is set in the detection direction by operating the release lever at the entrance of the polishing device.
When iron balls are mixed in, they are attracted to the magnet and act as a stopper, and the supply of game balls to the polishing device is stopped.
The frame control board 550 detects the iron ball by monitoring the supply stop and the ball clogging sensor 938.

[(B) Detection cancellation function]
The detection magnet is set in the non-detection direction by operating the release lever at the entrance of the polishing device. As a result, the adsorption to the detection magnet is released, and the detection is released.

[(Xv) ball removal function]
[(A) Block diagram]
FIG. 139 is a diagram showing a block diagram of the ball pulling function.
The management gaming machine frame 590 includes a frame control board 550 having a launch control circuit 902, a motor control circuit 924, and a sensor circuit 926.
A launch device 517 is connected to the launch control circuit 902.
A ball polishing device 572 and a game ball circulation device 551A are connected to the motor control circuit 924.
A ball removal switch 954 is connected to the sensor circuit 926.

The information from the frame control board 550 can be transmitted to the launch device 517 via the launch control circuit 902.
The information from the launch device 517 can be transmitted to the frame control board 550 via the launch control circuit 902.

The information from the frame control board 550 can be transmitted to the ball polishing device 572 and the game ball circulation device 551A via the motor control circuit 924.
Information from the ball polishing device 572 and the game ball circulation device 551A can be transmitted to the frame control board 550 via the motor control circuit 924.

The information from the ball removal switch 954 can be transmitted to the frame control board 550 via the sensor circuit 926.

[(B) Function description]
The ball removal function ejects the game balls used in the managed gaming machine.

[(A) Transition to ball removal function]
When the number of game balls is "0", the back mechanism is opened and the power is turned on while pressing the ball removal switch to shift to the ball removal function.
During the operation of this function, communication with the dedicated unit and the management game machine game board is not performed.
If the number of game balls is other than "0", the function does not shift to the ball removal function.

[(B) Game ball discharge function]
Set the ball pulling lever of the polishing device in the discharge direction.
By firing the game ball, the game ball circulates, and all the game balls are discharged from the discharge port.

[(Xvi) Pause function]
[(A) Block diagram]
FIG. 140 is a diagram showing a block diagram of the pause function.
The dedicated unit 700 includes a gaming machine connection board 701 having a communication control circuit 702.
Further, the management gaming machine frame 590 includes a frame control board 550 having a communication control circuit 551.
An error release switch 956 is connected to the communication control circuit 551.

The management game machine game board 580 includes a main control board 560 having a communication control circuit 561.

The information from the frame control board 550 can be transmitted to the gaming machine connection board 701 via the communication control circuit 551 and the communication control circuit 702.
Information (information such as a pause request) from the frame control board 550 can be transmitted to the main control board 560 via the communication control circuit 551 and the communication control circuit 561.
The information from the error release switch 956 can be transmitted to the frame control board 550 via the communication control circuit 551.

[(B) Function description]
The pause function determines that the frame control board 550 cannot continue the game and shifts the main control board 560 to the pause state.

[(A) Pause function]
When an error that the game cannot be continued occurs, the frame control board 550 stops firing and outputs a pause request to the main control board 560.
The main control board 560 detects the pause request and pauses the game in the case of a big hit state.
The pause request is notified to the main control board 560 by storing the data related to the pause request in the management game machine frame information register.

[(B) Pause release function]
After removing the cause of the error, the frame control board 550 releases the pause request by pressing the error release switch 956.

[(Xvii) error detection function]
FIGS. 141 to 146 are diagrams showing an error detection function.
Error detection is performed according to the contents shown in this figure.

[No. 1]
Error code: H01
Error name: Inconsistent certification in managed gaming machine Error detection content: Inconsistency in authentication between managed gaming machine frame and managed gaming machine game board was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON (Error is canceled by shutting off the power and turning it on again)
In the figure, "○ (circle)" means that the item is executed, and "x (cross)" means that the item is not executed.

[No. 2]
Error code: H02
Error name: Authentication mismatch between managed gaming machine and dedicated unit Error detection content: Authentication mismatch between managed gaming machine frame and dedicated unit control unit was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON

[No. 3]
Error code: H03
Error name: Authentication inconsistency in the dedicated unit Error detection content: Authentication inconsistency inside the dedicated unit control unit was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON

[No. 4]
Error code: H04
Error name: Dedicated cable disconnection Error detection content: A non-connection between the dedicated unit and the management gaming machine frame was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 5]
Error code: H05
Error name: No response for communication between the management game machine and dedicated unit Error detection content: No response for communication between the dedicated unit and the management game machine frame was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 6]
Error code: H06
Error name: Communication error in the management game machine Error detection content: Communication between the management game machine game board and the management game machine frame No response or no connection was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 7]
Error code: H07
Error name: Main control board startup error Error detection content: It was detected that the main control board did not start even after the specified time had passed.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 8]
Error code: H08
Error name: Serial number inconsistency Error detection content: Command communication between the dedicated unit and the management gaming machine frame Inconsistent serial number was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON

[No. 9]
Error code: H09
Error name: Addition serial number inconsistency Error detection content: An addition serial number inconsistency of the addition request command was detected when lending a ball from a dedicated unit.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error clearing: Automatic recovery

[No. 10]
Error code: H14
Error name: Subtraction sensor error Error detection content: When the subtraction sensor is detecting ball clogging or a failure of the subtraction sensor is detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 11]
Error code: H15
Error name: Abnormality of display device such as number of game balls Error detection content: Abnormality of display unit of display device such as number of game balls was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ×
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 12]
Error code: H16
Error name: Ball polishing device error Error detection content: It was detected that the polishing motor did not rotate.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 13]
Error code: H17
Error name: Game ball circulation device error Detection content: It was detected that the lifting motor did not rotate.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 14]
Error code: H18
Error name: Abnormal discharge ball passage Error detection content: A ball clogging was detected between the discharge ball passage and the ball polishing device.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 15]
Error code: H19
Error name: Winning ball passage abnormality Error detection content: Ball clogging was detected between the winning ball passage and the ball polishing device.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 16]
Error code: H20
Error name: Ball polishing device passage abnormality Error detection content: Ball clogging was detected in the ball polishing device.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 17]
Error code: H21
Error name: Game ball circulation device Error detection content: Ball clogging was detected in the game ball circulation device.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error release: Release switch

[No. 18]
Error code: H22
Error name: Cassette not installed Error detection content: A cassette not installed in the ball polishing device was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 19]
Error code: H23
Error name: Game ball number display overflow Error detection content: The number of digits of the game ball number display device has exceeded (990,000 or more)

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ○
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 20]
Error code: H24
Error name: Insufficient number of circulating balls Error detection content: Insufficient number of circulating balls was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 21]
Error code: H25
Error name: Excessive number of circulating spheres Error detection content: Excessive number of circulating spheres detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error clearing: Automatic recovery

[No. 22]
Error code: H64
Error name: Front decoration release Error detection content: Front decoration release detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error clearing: Automatic recovery

[No. 23]
Error code: H65
Error name: Back mechanism open Error detection content: Back mechanism open was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error clearing: Automatic recovery

[No. 24]
Error code: H66
Error name: Illegal radio wave detection Error detection content: An abnormal radio wave was detected in the management game machine frame.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 25]
Error code: H67
Error name: Proximity sensor error of managed gaming machine frame Error detection content: Proximity sensor abnormality of managed gaming machine frame was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 26]
Error code: H68
Error name: Abnormal number of winning balls 1
Error detection content: The difference between the number of winning balls detected by the main control board and the number of winning balls detected by the frame control board was 100 or more.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 27]
Error code: H69
Error name: Abnormal number of winning balls 2
Error detection content: The difference between the number of fired balls and the total return series (winning series + non-winning series) is 100 or more.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 28]
Error code: H70
Error name: Illegal ball lending detection Error detection content: A request to add the number of ball lending was received while the card was not being inserted.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ○
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 29]
Error code: H71
Error name: Nighttime back mechanism opening detection Error detection content: The back mechanism opening was detected while the power was off.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ×
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ×
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON

[No. 30]
Error code: H80
Error name: Remaining ball data detection Error detection content: Remaining ball data was detected when the store was moved and installed.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 31]
Error code: H82
Error name: Management game machine game board replacement detection Error detection content: The management game machine game board or night monitoring device replacement was detected while the power was off.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ×
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ×
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON

[No. 32]
Error code: H83
Error name: Night monitoring device battery shortage detection Error detection content: Night monitoring device battery low battery level (10% remaining) was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ×
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ×
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ×
Error cancellation: Power OFF / ON

[No. 33]
Error code: H84
Error name: Night monitoring device disconnection detection Error detection content: Night monitoring device disconnection detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stop playing the management game machine frame: ×
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ○
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 34]
Error code: H85
Error name: Small ball detection Error detection content: A ball of 10.7 mm or less was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 35]
Error code: H86
Error name: Iron ball detection Error detection content: Iron ball detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error cancellation: Power OFF / ON

[No. 36]
Error code: H89
Error name: Ball unit price inconsistency detection Error detection content: Connection of dedicated units with different ball unit prices was detected.

[Notification means]
Display device for the number of gaming balls in the management gaming machine frame: ○
Stopping games in the management game machine frame: ○
Audio output of the management game machine game board: ×
Illuminations on the management game machine game board: ×
Dedicated unit and hall computer dedicated unit: ○
Information output of dedicated unit and hall computer 1 (management game machine error): ×
Information output of dedicated unit and hall computer 2 (illegal): ○
Error clearing: Automatic recovery

[Notification means]
Game ball display: An error code is displayed on a display device such as the number of game balls.
Game stop: The ball feed function stops and the game cannot be played.
Information output: In order for the dedicated unit to output information (output to the call computer), the management gaming machine error and unauthorized information are notified to the dedicated unit. The information output 1 notifies as a management gaming machine error. The information output 2 notifies as invalid.

Audio output: Announcing the abnormal content from the speaker, which is another production device.
Illuminations: Illuminations, which are other production devices, are lit so that abnormalities can be easily recognized from the outside.
Dedicated unit: The touch panel type liquid crystal display of the dedicated unit displays the abnormal contents.

[(Xviii) light intensity / volume adjustment function]
[(A) Block diagram]
FIG. 147 is a diagram showing a block diagram of the light amount / volume adjustment function.
The management gaming machine frame 590 includes a sub-connection board 553 and an operation unit sub-connection board 553A.
A light amount adjusting switch 958, a volume adjusting switch 960A, an illumination board 962A, and a speaker 964 are connected to the operation unit sub-connection board 553A.
The management game machine game board 580 includes an effect control board 900 having a sub drawer board 966 and a control circuit 969.

The information from the sub-connection board 553 can be transmitted to the effect control board 900 via the sub-drawer board 966 and the control circuit 969.
The information from the effect control board 900 can be transmitted to the sub-connection board 553 via the control circuit 969 and the sub-drawer board 966.

The information from the sub-connection board 553 can be transmitted to the illumination board 962A and the speaker 964 via the operation unit sub-connection board 553A.
Information from the light amount adjusting switch 958 and the volume adjusting switch 960A can be transmitted to the sub-connecting board 553 via the operation unit sub-connecting board 553A.

[(B) Function description]
The light amount / volume adjustment function adjusts the light amount / volume of the managed gaming machine by the following functions.

[(A) Light intensity adjustment function]
The light intensity of the management gaming machine is adjusted (up or down) by pressing the light intensity adjustment switch mounted on the operation unit up or down.

[(B) Volume adjustment function]
The volume of the management gaming machine is adjusted (up or down) by pressing the volume adjustment switch mounted on the operation unit up or down.

[(4) Management game machine game board dimensions]
FIG. 148 is a diagram showing the outer shape of the gaming board and the alignment holes with the management gaming machine frame.
The vertical length L1 of the game board 8b is, for example, 530 mm.
The lateral length L2 of the game plate 8b is, for example, 479 mm.
The thickness L3 of the game plate 8b is, for example, 19.2 mm.

A first alignment hole H1 is formed at a position on the upper right side of the game plate 8b, and a second alignment hole H2 is formed at a position closer to the right of the lower center of the game plate 8b. The diameter R of each of the alignment holes is, for example, 8.1 mm.

The lateral length L4 of the first alignment hole H1 and the second alignment hole H2 is, for example, 110 mm.
The length L5 of the first alignment hole H1 and the second alignment hole H2 in the vertical direction is, for example, 505 mm.

The length L6 from the second alignment hole H2 to the left end of the game plate 8b is, for example, 286 mm.
The length L7 from the second alignment hole H2 to the lower end of the game plate 8b is, for example, 9 mm.

FIG. 149 is a diagram showing the dimensions of the game area.
The maximum length L10 of the game area 8a in the vertical direction is, for example, 499 mm.
The maximum lateral length L11 of the game area 8a is, for example, 471 mm.

FIG. 150 is a diagram showing the dimensions of the back surface effective region. Note that (A) in the figure shows a plan view of the game board 8b, and (B) in the figure shows a back view of the game board 8b.
As shown in (A) in the figure, the width L20 of the region where the game ball can flow down in front of the game board 8b is, for example, 18.5 mm.
The length L21 of the protruding portion of the right end portion (left end portion in the drawing) behind the game plate 8b in the front-rear direction is, for example, 68.9 mm.

As shown in (B) in the figure, the length L22 from the right end portion (left end portion in the figure) of the game plate 8b to the portion excluding the protruding portion of the left end portion (right end portion in the figure) of the game plate 8b. Is, for example, 442 mm.
The length L23 from the first alignment hole H1 to the upper end of the out port 32 of the game plate 8b is, for example, 475.5 mm.
The length L24 from the upper end of the out port 32 of the game board 8b to the lower end of the game board 8b is, for example, 37.5 mm.
The lateral length L25 of the protruding portion of the left end portion (right end portion in the drawing) of the game plate 8b is, for example, 36 mm.

[4. Operating principle of managed gaming machines]
[(1) Launcher]
FIG. 151 is a diagram showing the configuration of the launcher. In the figure, (A) shows a plan view, (B) in the figure shows a front view, (C) in the figure shows a right side view, and (D) in the figure shows a back view. ing.
The launching device 517 includes a launching solenoid 916, a punch 960, a launching platform 961, a ball passage 962, a subtraction sensor 920, a ball monitoring sensor 963, a launch relay board 906, a ball feed solenoid 918, a link 964, a fulcrum 965, and a launch inlet sensor 922. It includes an inlet 966A, a ring 967, a handle 510, a handle volume 910, a launch stop switch 912, a touch sensor 914 and a valve 968.

FIG. 152 is a diagram showing a configuration of a launching device (handle). In the figure (A) is a plan view, in the figure (B) is a front view, and in the figure (C) is a right side view.
The handle 510 includes a launch stop switch 912, a touch sensor 914 and a ring 967.

FIG. 153 is a diagram showing the operating principle of the launching device.
The frame control board 550 detects the touch sensor 914 by the player, the firing stop switch 912, and the value of the handle volume 910. The frame control board 550 that has detected the values of the touch sensor 914 and the handle volume 910 drives the ball feed solenoid 918 to send the game ball to the one-ball launch pad 961.

The game ball sent to the launch pad 961 passes through the subtraction sensor 920 in the ball passage 962. At this time, the frame control board 550 subtracts the number of balls held by the managed gaming machine.
The game ball stops at the launch pad 961, the frame control board 550 drives the launch solenoid 916, pulls the pestle 960 in the direction of arrow A in the figure, and launches the game ball. The launched game ball pushes up the valve 968 in the directions of arrow A-1 and arrow A-2. The valve 968 returns to its home position after the game ball has passed. The strength of firing is controlled by changing the suction force of the firing solenoid 916 according to the value of the handle volume 910.
Further, when the frame control board 550 detects the launch stop switch 912, the ball feed solenoid 918 and the launch solenoid 916 are stopped (turned off).

FIGS. 154 to 156 are diagrams for explaining the operating principle of the ball feed solenoid to pay out the game ball.

As shown in FIG. 154, the game ball enters from the entrance 966B and is aligned inside the ball passage 962. The ball feed solenoid 918 driven by the frame control board 550 sucks the link 964, and the link 964 rotates about the fulcrum 965 in the direction of arrow a in FIG. 154. When the link 964 is sucked by the ball feed solenoid 918, the game ball moves in the direction of arrow b. The link 964 has a shape in which one ball enters when the portion in contact with the game ball is sucked.
The game ball that has entered the inside of the link 964 is in the state shown in FIG. 155 when the frame control board 550 releases the drive of the ball feed solenoid 918. The link 964 rotates around the fulcrum 965 in the direction of arrow c, and the game ball moves in the direction of arrow d.

Then, the game ball that has moved in the direction of the arrow d moves to the launch pad 961 (see FIG. 151) and is launched by driving the launch solenoid 916.

[(I) Structure and operating principle of swing movement in the vertical and horizontal directions on the handle]
The handle body that constitutes the handle can be equipped with a mechanism that enables swing movement in the vertical and horizontal directions for the purpose of improving operability.
The swing movement mechanism can be composed of a plurality of rotating plates, a latch spring, a latch cover, a latch, a fixing guide, and the like.

Regarding the swing movement in the vertical direction, the handle body moves with the first fulcrum as the rotation axis. Further, regarding the swing movement in the left-right direction, the handle body moves with the second fulcrum as the rotation axis.
As the movement interval, including the normal state, there are a total of 9 movement points, one on the top, one on the bottom, one on the left, and one on the right. The nine movement points are (1) normal position, (2) upper position, (3) right position, (4) lower position, (5) left position, (6) upper right position, and (7) lower right position. (8) Lower left position, (9) Upper left position.

At each movement point, the latch fits into the fixed guide by the force of the latch spring, and the latch is hooked on the fixed guide.
When the handle body is swung by the force of releasing the latch, the latch is disengaged from the fixed guide and the handle body moves.
For areas other than each movement point, the latch cover hits the fixed guide and cannot be moved. In addition, the state is maintained after the movement.

[(Ii) Structure and operating principle of holding the handle lever position in the handle lever]
The handle levers that make up the handle can be equipped with a handle lever holding function for the purpose of improving operability.
The structure for holding the handle lever is composed of a holding lever and a holding link. At the handle, when starting firing, the handle lever is rotated clockwise to adjust the firing intensity and launch.
When you release the handle lever, the handle lever automatically rotates counterclockwise due to the reaction force of the handle lever spring, the handle returns to the normal position, and firing stops.
When the holding lever is moved in a predetermined direction, the holding lever rotates around the first fulcrum, and the holding link to be joined rotates in the specified direction around the second fulcrum. When the holding link rotates, the holding link and the handle lever come into contact with each other, and the holding link deforms in the elastic region to give a force to the handle lever. Due to this force, when the handle is rotated, a frictional force is generated at the contact portion between the handle lever and the holding link, and a force that hinders the rotation acts on the operation of rotating the handle. By making this force equal to or greater than the reaction force of the handle lever spring, when the hand is released, the handle lever maintains that state and does not return to the normal position. At this time, in manual rotation, the firing strength can be adjusted with a force equal to or greater than the frictional force.
When the holding lever is rotated in the opposite direction to the predetermined direction, the holding lever rotates around the first fulcrum, and the holding link to be joined rotates in the opposite direction to the specified direction around the second fulcrum, and the handle It returns to the state where there is a gap with the lever.

[(2) Power supply unit]
〔Schematic〕
FIG. 157 is a schematic view showing a configuration of a power supply device used in a managed gaming machine used in a managed gaming machine.
The electric power from the commercial power supply (AC100V) passes through the rectifier circuit 1 and the smoothing circuit 1, (1) DC24V generation circuit 1, (2) DC12V generation circuit 1, (3) DC5V generation circuit, and (4) power off. It is distributed to the detection circuits (A) and (5) power failure detection circuit (B), and passes through the rectifier circuit 2 and the smoothing circuit 2, (9) DC24V generation circuit 2, (10) DC12V generation circuit 2, (11). ) It is distributed to the DC12V generation circuit 3.

The electric power and signals of the above (1) to (5) are transmitted to the frame control board 550. The transmitted power is distributed to (6) a RAM clear switch circuit, (7) a game ball clear switch circuit, and (8) a DC 3.3V generation circuit.
The electric power (1) to (4) and the signal (6) are transmitted to the main control board 560.

The electric powers (9) to (11) above are transmitted to the sub-connection board 553 and the operation unit sub-connection board 553A. The transmitted electric powers (9) to (11) are transmitted to the effect control board 900, and the electric powers (9) to (11) are transmitted to the front decoration 512 and the operation unit 511.

FIG. 158 is a diagram showing usage of the power supply and the signal.
The uses of the power supplies and signals described by the numbers (1) to (11) in FIG. 157 are as follows.

Number: (1)
Signal name: DC24V-1
Usage (managed game machine frame): polishing motor, cassette motor Usage (managed game machine game board): motor, solenoid

Number: (2)
Signal name: DC12V-1
Usage (managed game machine frame): sensor, lifting motor, launch solenoid, ball feed solenoid Usage (managed game machine game board): sensor, motor, solenoid

Number: (3)
Signal name: DC5V-1
Usage (managed game machine frame): IC power supply Usage (managed game machine game board): IC power supply, CPU power supply

Number: (4)
Signal name: Power failure detection signal A
Usage (managed gaming machine frame): None Usage (managed gaming machine game board): Power failure detection

Number: (5)
Signal name: Power failure detection signal B
Usage (managed gaming machine frame): Power failure detection Usage (managed gaming machine game board): None

Number: (6)
Signal name: RAM clear switch signal Usage (managed game machine frame): RAM clear Usage (managed game machine game board): RAM clear

Number: (7)
Signal name: Game ball clear switch signal Usage (managed game machine frame): Game ball clear Usage (managed game machine game board): None

Number: (8)
Signal name: DC 3.3V
Usage (managed gaming machine frame): CPU power supply Usage (managed gaming machine game board): None

Number: (9)
Signal name: DC24V-2
Usage (managed game machine frame): None Usage (managed game machine game board): Illuminations, motors, and other power generation

Number: (10)
Signal name: DC12V-2
Usage (managed game machine frame): None Usage (managed game machine game board): Illuminations, motors, and other power generation

Number: (11)
Signal name: DC12V-3
Usage (managed game machine frame): Illuminations, other power generation Generation Usage (managed game machine game board): Illuminations, motor, other power generation

[(I) Power supply specifications]
[(A) Connector and pin layout specifications]
FIG. 159 is a diagram showing connector and pin arrangement specifications.
(A) Details of the main system output are as follows.
[Pins Nos. 1 and 2]
Signal: GND
Contents: GND

[Pins Nos. 3 and 4]
Signal: DC24V-1
Contents: 24V power supply

[Pins Nos. 5 and 6]
Signal: GND
Contents: GND

[Pins Nos. 7, 8, 9, 10]
Signal: DC12V-1
Contents: 12V power supply

[Pins Nos. 11 and 12]
Signal: GND
Contents: GND

[Pins Nos. 13 and 14]
Signal: DC15V-1
Contents: 5V power supply

[Pins Nos. 15 and 16]
Signal: GND
Contents: GND

[Pin No17]
Signal: Power failure detection signal A
Contents: Power failure detection signal for main control board

[Pin No. 18]
Signal: Power failure detection signal B
Contents: Power failure detection signal for frame control board

[Pins No. 19 and 20]
Signal: GND
Contents: GND

(B) Details of the sub system output are as follows.
[Pins Nos. 1 and 2]
Signal: GND
Contents: GND

[Pins Nos. 3, 4, 5, 6]
Signal: DC24V-2
Contents: 24V power supply

[Pins Nos. 7, 8, 9, 10]
Signal: GND
Contents: GND

[Pins No. 11-16]
Signal: DC12V-2
Contents: 12V power supply (Large capacity: For management game machines and game boards)

[Pins No. 17 to 20]
Signal: GND
Contents: GND

[Pins No. 21-24]
Signal: DC12V-3
Contents: 12V power supply (small capacity: for managed gaming machine frame)

[Pins No. 25, 26]
Signal: GND
Contents: GND

(C) Details of FG (frame ground) are as follows.
The signal is FG and the content is frame GND.

[(B) Output power supply specifications]
[(A) Main system output]
Three types of three systems (DC5V-1, DC12V-1, DC24V-1) are output as the main power supply, and the output power supply voltage and the number of systems are selected in consideration of the voltage that is frequently used.

The individual maximum current value of each power supply is 3A for DC5V-1, 6A for DCl2V-1, and 3.5A for DC24V-1. However, it is necessary to use the main system with a total output of 90 VA or less and a power supply unit with a total output of 180 VA or less.

The maximum current value is the total value of the managed gaming machine game board and the managed gaming machine frame, and the values of each power supply used in the managed gaming machine frame are DC24V-1 with an average current of 0.70A and a maximum current. 1.82A and DC12V-1 have an average current of 0.91A and a maximum current of 3.20A, and DC5V-1 has an average current of 0.50A and a maximum current of 0.90A.

FIG. 160 is a diagram showing specifications of a main system power supply capacity.
[DC24V-1]
Maximum continuous rated load current: 3.5A
Overcurrent operation: 5.5A
Accuracy: ± 10%
Ripple noise: 250 mV

[DC12V-1]
Maximum continuous rated load current: 6.0A
Overcurrent operation: 8.0A
Accuracy: ± 10%
Ripple noise: 200 mV

[DC5V-1]
Maximum continuous rated load current: 3.0A
Overcurrent operation: 4.0A
Accuracy: ± 5%
Ripple noise: 150 mV

[(B) Sub system output]
Two types of three systems (DC12V-2, DC12V-3, DC24V-2) are output as sub-system power supplies, and the output power supply voltage and the number of systems are selected in consideration of the voltage that is frequently used.
Two systems of DC12V are provided, and DC24V-2 and DC12V-2 are used in the management game machine game board, and DC12V-3 is used in the management game machine frame.
However, DC12V is also supplied to the management game machine game board, and can be used on the management game machine game board side within the capacity range.
Further, by not providing the DC5V generation circuit in the power supply device, it is possible to increase the output capacity of each power supply.
The maximum current value of each power supply is 8A for DC12V-2, 2A for DC12V-3, and 5A for DC24V-2, and these voltages can be used alone or in combination within a total range of 120VA or less. It can be used.

FIG. 161 is a diagram showing specifications of a sub system power supply capacity.
[DC24V-2]
Continuous rated load (ambient temperature 50 ° C): 5.0A
Overcurrent operation: 8.0A
Accuracy: ± 10%
Ripple noise: 250 mV

[DC12V-2]
Continuous rated load (ambient temperature 50 ° C): 8.0A
Overcurrent operation: 11.0A
Accuracy: ± 10%
Ripple noise: 200 mV

[DC12V-3]
Continuous rated load (ambient temperature 50 ° C): 2.0A
Overcurrent operation: 4.0A
Accuracy: ± 10%
Ripple noise: 200 mV

[(Ii) Backup]
(A) The backup power supply for the main control board is mounted on the main control board. Since the frame control board uses non-volatile RAM, it does not use a backup power supply.
(B) The power supply device monitors the AC power supply, and when it detects a drop in power supply, it transmits a power supply disconnection detection signal to the main control board and the frame control board.

(C) When the power cutoff signal is received, the main control board and the frame control board store the game state in the RAM.
(D) When the power is turned on, the recovery process is performed according to the pressed state of the game ball clear switch and the RAM clear switch mounted on the frame control board. Only the RAM clear switch signal is output from the frame control board to the main control board.

FIG. 162 is a diagram showing items to be backed up.
[Game ball clear switch]
When pressed: Initializes the game ball number information and card information.
When not pressed: The game ball number information is returned to the state before the power was cut off by the information stored in the RAM.

[RAM clear switch]
When pressed: Initializes the managed gaming machine (excluding gaming machine information and card information).
When not pressed: The game state is returned to the state before the power was cut off by the information stored in the RAM.

[Main control board backup items]
(A) Big hit state (including the number of rounds)
(B) High probability / time saving state (c) Random value of reserved memory (special symbol, normal symbol) (d) Error status (e) Untransmitted command (f) Normal electric accessory, type 1 special electric accessory

[Back-up items for frame control board]
(A) Game ball number information (b) Movable information (c) Game information (see interface specifications)
(D) Card information

[(3) Ball polishing device]
FIG. 163 is a diagram showing the structure of the ball polishing device.
The ball polishing device 572 includes a polishing motor 970, a cassette motor 971, a polishing cassette 972, a ball inlet 973, a ball outlet 974, a cassette switch 944, a polishing motor sensor 946, a polishing relay board 904, a movable piece 975, a ball pulling lever 976, and a discharge. It is provided with a passage 977 and a ball discharge port 978.

The frame control board controls the polishing motor 970 and the cassette motor 940 connected to the polishing relay board 904, and detects information from the cassette switch 944 and the polishing motor sensor 946.
When the game ball enters from the ball entrance 973, the polishing inlet sensor 952 detects the game ball and drives the polishing motor 942.
Further, when the push plate 979 pushes the cassette switch 944, it is detected that the polishing cassette 972 is attached.

164 to 167 are diagrams showing the operating principle of the ball polishing device.
As shown in FIG. 164, when the polishing motor 942 is driven by the frame control substrate 550, the motor gear 980 provided in the polishing motor 942 rotates in the direction of arrow A. The gear 1 is a two-stage gear, and the gear 1-1 connected to the motor gear is rotated in the direction of arrow B, and the gear 1-2 is rotated in the direction of arrow C by the gear 1-2. A screw 981 is provided on the rotation axis of the gear 2, and by rotating in the direction of arrow C, the game ball is conveyed in the direction of arrow D. Further, a rotating plate 982 is provided on the rotating shaft of the gear 2, and the polishing motor sensor 946 detects the drive of the polishing motor 942.

As shown in FIG. 165, when the cassette motor 940 is driven by the frame control board 550, the motor gear A provided on the cassette motor 940 rotates in the direction of the arrow a. The motor gear A and the gear B are connected by a worm gear. When the motor gear A rotates in the direction of the arrow a, the gear B rotates in the direction of the arrow b. When the gear B rotates, the gear C provided on the rotation shaft interlocks and rotates in the direction of the arrow b. As the gear C rotates, the connected cassette gear 983 rotates in the direction of arrow c.

As shown in FIG. 166, the cassette gear 983 rotated in the arrow c direction by the cassette motor 940 rotates the cloth feed gear G1 fixed on the rotation axis in the arrow d direction. The cloth feed gear 1 is connected to the cloth feed gear 2 with a polishing pad 984 enclosed inside the polishing cassette 972 interposed therebetween. When the cloth feed gear 1 rotates in the direction of the arrow d, the cloth feed gear 2 rotates in the direction of the arrow e, and the polishing cloth moves in the direction of the arrow f. Since the polishing pad 984 is connected without a cut, it circulates in the cassette.
Then, by rotating the screw 981 shown in FIG. 164, the game ball is polished by being conveyed while being rubbed against the polishing pad 984 in the polishing region of the polishing cassette 972.

As shown in FIG. 167, when the ball pulling lever 976 is rotated in the direction of the arrow α, the game ball is guided to the discharge passage 977 by the movable piece 975 and discharged from the ball discharge port 978.

[(4) Game ball circulation device]
FIG. 168 is a diagram showing a configuration of a game ball circulation device.
The game ball circulation device 551A includes a ball inlet 985, a lifting inlet sensor 934, a lifting motor 986A, a screw 981, a lifting relay board 928, a lifting motor sensor board 929, and a ball outlet 930A.

169 to 171 are diagrams showing the operating principle of the game ball circulation device.
The frame control board 550 controls the lifting motor 932 connected to the lifting relay board 928, and detects the lifting motor sensor board 929 and the lifting inlet sensor 934. When the game ball enters from the ball entrance, the lifting entrance sensor 934 is detected and the lifting motor 932 is driven. When the lifting motor 932 rotates, the lifting motor sensor substrate 929 detects the rotation of the motor by the slit S of the gear G2.

When the lifting motor 932 is driven, the motor gear MG provided in the lifting motor 932 rotates in the direction of arrow A.
When the motor gear MG rotates, the gear G2 rotates in the direction opposite to the arrow A, and the screw gear SG rotates in the direction of the arrow A. The screw gear SG is provided with a screw 981, and when the screw gear SG rotates, the screw 981 rotates in the direction of arrow A. The game ball is conveyed in the direction of arrow B (upper part of the managed game machine) by rotating the screw 981. After being conveyed in the direction of arrow B, the game ball is discharged by the discharge port and delivered to the launching device.

The game balls entered from the ball entrance 985 roll and align as shown by arrow A as shown in FIG. 170. By driving the lifting motor 932, the ball feed cam rotates in the direction of arrow B.
When the ball feed cam 931 rotates to the position shown in FIG. 171, the game ball is taken into the ball feed cam 931 and conveyed in the direction of arrow C. The conveyed game ball is delivered to the screw 981 shown in FIG. 169.

[(5) Ball lending and returning device]
FIG. 172 is a diagram showing a touch panel type liquid crystal display.
The ball lending and returning of the managed gaming machine is operated by the ball lending and returning device (operation unit device) provided in the dedicated unit 700.
The operation unit device of the dedicated unit is composed of a touch panel type liquid crystal display 730.
The touch panel type liquid crystal display has a ball lending function / return function in addition to a function of displaying game console information and the like.

[(I) When touching the ball rental display area]
By touching the ball lending display portion A1, the number information of the number of lending balls is transmitted from the dedicated unit, and the frame control board displays the number of game balls, etc. by adding the number information and the number of game balls as the number of game balls. Display on the device.
In addition, the balance information is also received and displayed in the balance display area A2 in the touch panel type liquid crystal display.
The display portion of the ball lending display portion A1 is lit when the ball lending is possible, and dark when the ball lending is not possible.

[(Ii) When the return display area is touched]
By touching the return display portion A3, the game end information is transmitted from the dedicated unit, and the frame control board transmits the game ball number information to the dedicated unit.

[(6) Outer frame security device]
173 and 174 are views showing an outer frame security device.
The outer frame security device 985A is a structure that prevents foreign matter from being inserted through a gap between a managed gaming machine and a dedicated unit.
The outer frame security device 985A includes a right plate 986, a left plate 987, a right security plate 988, a left security plate 989, and a fixing screw N in the outer frame.
Loosen the fixing screw N and move the right security plate 988 and the left security plate 989 to an adjustable range in the direction of the arrow shown in FIG. 174. At this time, it can be moved to the movement range in the holes of the right security plate 988 and the left security plate 989 by hitting the surrounding environment. After the movement, the fixing screw N is tightened to fix the right security plate 988 and the left security plate 989.

[(7) Iron ball detector]
FIG. 175 is a diagram showing an iron ball detection device.
The iron ball detection device 571 includes a ball passage 962, a ball clogging sensor 938, a release lever 990, and a magnet 991.
When an iron ball is mixed in the management game machine, the iron ball is held by the magnet 991 attached to the tip of the release lever 990.
The game ball and the iron ball in the ball passage stay in the ball passage 962, and the frame control board 550 detects it by the ball clogging sensor 938.
By moving the release lever 990 in the arrow release direction A, the iron ball is separated from the magnet 991, and the ball jam state is released.

[5. Hardware configuration]
[(1) Overall block diagram]
176 to 178 are diagrams showing a block diagram of a managed gaming machine.
The power supply 570 includes a main switch 310.
The frame control board 550 (managed game machine frame control board) has a 7-segment display of the number of game balls, a ball removal switch 954, an error release switch 956, a game ball clear switch 312, a RAM clear switch 304, a firing intensity volume 313, and a handle start. The rotation angle adjustment volume 314 is provided.

On the frame control board 550, a radio wave sensor 315 for the management game machine frame, a front decoration opening switch 316, a night monitoring device 948, a ball clogging sensor 938, a winning sensor 555, a non-winning sensor 556, a handle volume 910, a launch stop switch 912, A touch sensor 914, a ball monitoring sensor 963, a launch inlet sensor 922, a subtraction sensor 920, a lifting inlet sensor 934, a lifting motor sensor substrate 929, a cassette switch 944, a polishing motor sensor 946, and a polishing inlet sensor 952 are connected.
From these members, a SW signal (switch signal) or a VL signal (volume signal, connection confirmation power supply) is transmitted to the frame control board 550.

Further, a ball feed solenoid 918, a launch solenoid 916, a lifting motor 932, a cassette motor 940, a polishing motor 942, and a game ball number display device 520 are connected to the frame control board 550.
The frame control board 550 transmits a solenoid control signal, a motor control signal, and an LED control signal to these members.

Further, a counting switch 530 is connected to the frame control board 550.
A SW signal is transmitted from the counting switch 530 to the frame control board 550.
The frame control board 550 transmits an LED control signal to the counting switch 530.

Furthermore, a game ball or the like rental device connection terminal board 554 is connected to the frame control board 550.
The frame control board 550 and the game ball rental device connection terminal board 554 can transmit and receive encrypted control commands.

The frame control board 550 and the main control board 560 (managed game machine main control board) can send and receive encrypted control commands.
Each winning sensor 555, a magnet sensor 317, and a radio wave sensor 318 are connected to the main control board 560.
A SW signal is transmitted from these members to the main control board 560.
The main control board 560 transmits a control command to the effect control board 900.

A light amount / volume adjustment board 319, other effect switches 320, and a management game machine game board effect sensor 321 are connected to the effect control board 900.
A SW signal is transmitted from these members to the effect control board 900.
Further, a liquid crystal display 42 for a management game machine game board is connected to the effect control board 900.
The effect control board 900 transmits an LED control signal to the liquid crystal display 42 for the management game machine game board.

An LED board 322 for producing a management game machine frame is connected to the effect control board 900.
The effect control board 900 transmits an LED signal to the management game machine frame effect LED board 322.

A speaker 964 is connected to the effect control board 900.
The effect control board 900 transmits an audio output signal to the speaker 964.

The LED board 323 for the production of the management game machine game board is connected to the effect control board 900.
The effect control board 900 transmits an LED signal to the LED board 323 for the effect of the management game machine game board.

A management game machine game board game actuator 324 is connected to the effect control board 900.
The effect control board 900 transmits an actuator control signal to the actuator 324 for the management game machine game board game.

An ordinary electric accessory solenoid 88 and a large winning opening solenoid 90, 97 are connected to the main control board 560.
The main control board 560 transmits a solenoid control signal to these members.

The main display / winning display board 325 is connected to the main control board 560.
The main control board 560 transmits an LED control signal to the main display / winning display board 325.

A dedicated unit 700 is connected to the terminal plate 554 for renting a game ball or the like.
The game ball rental device connection terminal plate 554 and the dedicated unit 700 can send and receive encrypted control commands.

The main power supply is supplied from the power supply device 570 to the frame control board 550 and the effect control board 900. Further, the main power supply is supplied from the frame control board 550 to the main control board 560.

[(2) Overall circuit diagram]
[Management game machine main system 1]
179 to 184 are diagrams showing an overall circuit diagram of the management gaming machine main system 1.
[Fig. 179]
The game ball rental device connection terminal board 554 and the frame control board 550 are connected by a board-to-board connection connector. The contents of the board-to-board connection connector are as follows.

[Board-to-board connector]
Pin No1: GND
Pin No2: GND
Pin No3: DC5V-1
Pin No4: DC5V-1
Pin No5: Cryptographic transmission (+)
Pin No6: Cryptographic transmission (-)
Pin No7: Cryptographic reception (+)
Pin No8: Cryptographic reception (-)
Pin No9: Connection confirmation signal

The game ball rental device connection terminal plate 554 also includes a 9-pin connector. The contents of the 9-pin connector are as follows.

[9-pin connector]
Pin No1: GND
Pin No2: Cryptographic transmission (-)
Pin No3: Encryption reception (-)
Pin No4: PSI
Pin No5: GND
Pin No6: Cryptographic transmission (+)
Pin No7: Cryptographic reception (+)
Pin No8: 5V
Pin No9: 5V

The game ball rental device connection terminal plate 554 and the power supply device 570 are connected by a back mechanism portion earth harness. Further, the power supply device 570 and the polishing relay board 904 are connected by a back mechanism portion earth harness. The contents of the back mechanism earth harness are as follows. The harness may be other connecting parts (connecting wires, etc.) (hereinafter, the same applies).

[Back mechanism earth harness]
Pin No1: FG
Pin No2: FG

The power supply device 570 and the management game machine frame 590 are connected by a power supply ground harness. The contents of the power supply ground harness are as follows.

[Power supply ground harness]
Pin No1: FG

The power supply 570 and the commercial power supply are connected by a main power harness. The contents of the main power harness are as follows.

[Main power harness]
Pin No1: AC100VA
Pin No2: AC100VB
Pin No3: FG

[Fig. 180]
The power supply device 570 and the frame control board 550 are connected by a frame control harness. The contents of the frame control harness are as follows.

[Frame control harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-1
Pin No4: DC24V-1
Pin No5: GND
Pin No6: GND
Pin No7: DC12V-1
Pin No8: DC12V-1
Pin No9: DC12V-1
Pin No10: DC12V-1
Pin No11: GND
Pin No12: GND
Pin No13: DC5V-1
Pin No14: DC5V-1
Pin No15: GND
Pin No16: GND
Pin No17: Power failure detection signal A
Pin No18: Power failure detection signal B
Pin No19: GND
Pin No20: GND

[Fig. 181]
The power supply device 570 and the sub-connection board 553 are connected by a sub-connection harness. The contents of the sub connection harness are as follows.

[Sub-connection harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-2
Pin No4: DC24V-2
Pin No5: DC24V-2
Pin No6: DC24V-2
Pin No7: GND
Pin No8: GND
Pin No9: GND
Pin No10: GND
Pin No11: DC12V-2
Pin No12: DC12V-2
Pin No13: DC12V-2
Pin No14: DC12V-2
Pin No15: DC12V-2
Pin No16: DC12V-2
Pin No17: GND
Pin No18: GND
Pin No19: GND
Pin No20: GND
Pin No21: DC12V-3
Pin No22: DC12V-3
Pin No23: DC12V-3
Pin No24: DC12V-3
Pin No25: GND
Pin No26: GND

[Fig. 182]
The frame control board 550 and the operation unit relay board 554C are connected by an operation unit relay harness. The contents of the operation unit relay harness are as follows.

[Operation unit relay harness]
Pin No1: GND
Pin No2: DC5V-1
Pin No3: DC5V-1
Pin No4: UART transmission Pin No5: UART reception Pin No6: Counting check Pin No7: Counting LEDR data Pin No8: Counting LEDG data Pin No9: Counting LEDB data Pin No10: Radio sensor for management game machine frame Pin No11: Launch stop switch Pin No12: Touch sensor pin No13: VR1
Pin No14: VR2
Pin No15: VR3 (GND)
Pin No16: DC12V-1

[Fig. 183]
The frame control board 550 and the main drawer board 950 are connected by a main drawer connector harness. The contents of the main drawer connector harness are as follows.

[Main drawer connector harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-1
Pin No4: DC24V-1
Pin No5: DC24V-1
Pin No6: DC24V-1
Pin No7: DC5V-1
Pin No8: DC5V-1
Pin No9: GND
Pin No10: GND
Pin No11: CEX1 (+)
Pin No12: CTX1 (+)
Pin No13: CRX1 (-)
Pin No14: CTX1 (-)
Pin No15: GND
Pin No16: RAM clear signal Pin No17: Power failure detection signal A
Pin No18: Power failure detection signal A
Pin No19: Night monitoring device power supply B
Pin No20: Night monitoring device power supply B
Pin No21: Night monitoring device power supply A
Pin No22: Night monitoring device power supply A
Pin No23: GND
Pin No24: GND

The power supply device 570 and the main drawer board 950 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: FG
Pin No2: FG

[Fig. 184]
The operation unit relay board 554C and the pipe management game machine frame radio wave sensor 315 are connected by a radio wave sensor harness. The contents of the radio wave sensor harness are as follows.

[Radio sensor harness]
Pin No1: DC12V-1
Pin No2: Radio wave sensor for the frame for managed pachinko machines Pin No3: GND

The operation unit relay board 554C and the game ball number display device 520 are connected by a game ball number display device harness. The contents of the game ball number display device harness are as follows.

[Radio sensor harness]
Pin No1: GND
Pin No2: DC5V-1
Pin No3: DC5V-1
Pin No4: UART transmission Pin No5: UART reception Pin No6: GND

The operation unit relay board 554C and the counting switch 530 are connected by a counting switch harness. The contents of the counting switch harness are as follows.

[Counting switch harness]
Pin No1: GND
Pin No2: DC5V-1
Pin No3: Counting switch Pin No4: Counting LEDR data Pin No5: Counting LEDG data Pin No6: Counting LEDB data Pin No7: DC12V-1

The operation unit relay board 554C, the launch stop switch 912, the touch sensor 914, and the handle volume 910 are connected by a handle relay harness. The contents of the handle relay harness are as follows.

[Handle relay harness]
Pin No1: GND
Pin No2: Fire stop switch Pin No3 (Pin No1): GND
Pin No4 (Pin No2): Touch sensor Pin No5 (Pin No3): DC12V-1
Pin No6 (Pin No1): VR1
Pin No7 (Pin No2): VR2
Pin No8 (Pin No3): VR3

[Management game machine main system 2]
18 to 192 are diagrams showing an overall circuit diagram of the management gaming machine main system 2.
[Fig. 185]
The front decoration release switch 316 and the inner frame relay board 930 are connected by a radio wave sensor harness. The contents of the radio wave sensor harness are as follows.

[Radio sensor harness]
Pin No1: GND
Pin No2: Front decoration release switch

The night monitoring device 948 and the inner frame relay board 930 are connected by a night monitoring device harness. The contents of the night monitoring device harness are as follows.

[Night monitoring device harness]
Pin No1: DC5V-1
Pin No2: Night monitoring device power supply B
Pin No3: Back mechanism open switch Pin No4: Night monitoring CS
Pin No5: Night monitoring CLK
Pin No6: Night monitoring DATA
Pin No7: Night monitoring device power supply A
Pin No8: GND

The non-winning sensor 556 and the inner frame relay board 930 are connected by a non-winning sensor harness. The contents of the non-winning sensor harness are as follows.

[Non-winning sensor harness]
Pin No1: GND
Pin No2: Non-winning sensor

The winning sensor 555 and the inner frame relay board 930 are connected by a winning sensor harness. The contents of the winning sensor harness are as follows.

[Prize sensor harness]
Pin No1: GND
Pin No2: Winning sensor

The ball jam sensor 938 and the inner frame relay board 930 are connected by a ball jam sensor harness. The contents of the ball jam sensor harness are as follows.

[Ball jam sensor harness]
Pin No1: GND
Pin No2: Ball jam sensor

[Fig. 186]
The inner frame relay board 930 and the frame control board 550 are connected by an inner frame relay harness. The contents of the inner frame relay harness are as follows.

[Inner frame relay harness]
Pin No1: GND
Pin No2: Night monitoring device power supply B
Pin No3: Night monitoring device power supply A
Pin No4: DC5V-1
Pin No5: Front decoration release switch Pin No6: Back mechanism opening switch Pin No7: Night monitoring CS
Pin No8: Night monitoring CLK
Pin No9: Night monitoring DATA
Pin No10: Non-winning sensor Pin No11: Winning sensor Pin No12: Ball jam sensor

The frame control board 550 also includes a 4-pin connector and a 10-pin connector. The contents of the 4-pin connector and the 10-pin connector are as follows.

[4-pin connector]
Pin No1: GND
Pin No2: Inquiry synchronization signal Pin No3: Inquiry data signal Pin No4: GND

[10-pin connector]
Pin No1: Test data of test firing test 1
Pin No2: Test data 2 of the test firing test
Pin No3: Test data of test firing test 3
Pin No4: Test data of test firing test 4
Pin No5: Test data of test firing test 5
Pin No6: Test data of test firing test 6
Pin No7: Test data of test firing test 7
Pin No8: Test data 8 of the test firing test
Pin No9: GND
Pin No10: GND

[Fig. 187]
The inner frame relay board 930 and the polishing relay board 904 are connected by a polishing relay harness. The contents of the polishing relay harness are as follows.

[Polishing relay harness]
Pin No1: GND
Pin No2: GND
Pin No3: GND_B
Pin No4: DC5V-1
Pin No5: DC12V-1A
Pin No6: DC12V-1A
Pin No7: DC12V-1B
Pin No8: Polishing inlet sensor Pin No9: Cassette switch Pin No10: Polishing motor sensor Pin No11: Lifting motor sensor Pin No12: Lifting inlet sensor Pin No13: Launch inlet sensor Pin No14: Subtraction sensor Pin No15: Ball monitoring sensor Pin No16 : Polishing motor A phase (+)
Pin No17: Polishing motor A phase (-)
Pin No18: Polishing motor B phase (+)
Pin No19: Polishing motor B phase (-)
Pin No20: Cassette motor A phase (+)
Pin No21: Cassette motor A phase (-)
Pin No22: Cassette motor B phase (+)
Pin No23: Cassette motor B phase (-)
Pin No24: Lifting motor A phase Pin No25: Lifting motor B phase Pin No26: Lifting motor C phase Pin No27: Lifting motor D phase Pin No28: Ball feed solenoid Pin No29: Launch solenoid (+)
Pin No30: Launch solenoid (+)
Pin No31: Launch solenoid (-)
Pin No32: Launch solenoid (-)

[Fig. 188]
The polishing inlet sensor 952 and the polishing relay board 904 are connected by a polishing inlet sensor harness. The contents of the polishing inlet sensor harness are as follows.

[Polishing inlet sensor harness]
Pin No1: GND
Pin No2: Polishing inlet sensor

The cassette switch 944 and the polishing relay board 904 are connected by a cassette switch harness. The contents of the cassette switch harness are as follows.

[Cassette switch harness]
Pin No1: GND
Pin No2: Cassette switch

The polishing motor sensor 946 and the polishing relay board 904 are connected by a polishing motor sensor harness. The contents of the polishing motor sensor harness are as follows.

[Abrasive motor sensor harness]
Pin No1: DC5V-1
Pin No2: GND
Pin No3: Polishing motor sensor

The power supply device 570 and the polishing relay board 904 are connected by a back mechanism portion earth harness. The contents of the back mechanism earth harness are as follows.

[Back mechanism earth harness]
Pin No1: FG

[Fig. 189]
The polishing relay board 904 and the firing relay board 906 are connected by a firing relay harness. The contents of the launch relay harness are as follows.

[Launch relay harness]
Pin No1: GND_B
Pin No2: Launch inlet sensor Pin No3: Subtraction sensor Pin No4: Ball monitoring sensor Pin No5: DC12V-1A
Pin No6: DC12V-1B
Pin No7: Ball feed solenoid Pin No8: Launch solenoid (+)
Pin No9: Launch solenoid (-)

The polishing relay board 904 and the lifting relay board 928 are connected by a lifting relay harness. The contents of the lifting relay harness are as follows.

[Lifting relay harness]
Pin No1: GND
Pin No2: Lifting inlet sensor Pin No3: Lifting motor sensor Pin No4: DC5V-1
Pin No5: Lifting motor D phase Pin No6: Lifting motor C phase Pin No7: DC12V-1A
Pin No8: DC12V-1A
Pin No9: Lifting motor B phase Pin No10: Lifting motor A phase

The polishing relay board 904 and the cassette motor 940 are connected by a cassette motor harness. The contents of the cassette motor harness are as follows.

[Cassette motor harness]
Pin No1: Cassette motor A phase (+)
Pin No2: Cassette motor A phase (-)
Pin No3: Cassette motor B phase (+)
Pin No4: Cassette motor B phase (-)

The polishing relay board 904 and the polishing motor 942 are connected by a polishing motor harness. The contents of the polishing motor harness are as follows.

[Abrasive motor harness]
Pin No1: Polishing motor A phase (+)
Pin No2: Polishing motor A phase (-)
Pin No3: Polishing motor B phase (+)
Pin No4: Polishing motor B phase (-)

The polishing relay board 904 and the polishing motor 942 are connected by a polishing earth harness. The contents of the polished earth harness are as follows.

[Polished ground harness]
Pin No1: FG (Connected to the board retaining screw)

[Fig. 191]
The launch relay board 906 and the launch inlet sensor 922 are connected by a launch inlet sensor harness. The contents of the launch inlet sensor harness are as follows.

[Launch inlet sensor harness]
Pin No1: DC12V-1B
Pin No2: Launch inlet sensor Pin No3: GND_B

The launch relay board 906 and the ball monitoring sensor 963 are connected by a ball monitoring sensor harness. The contents of the ball monitoring sensor harness are as follows.

[Ball monitoring sensor harness]
Pin No1: DC12V-1B
Pin No2: Sphere monitoring sensor Pin No3: GND_B

The launch relay board 906 and the subtraction sensor 920 are connected by a subtraction sensor harness. The contents of the subtraction sensor harness are as follows.

[Subtraction sensor harness]
Pin No1: DC12V-1B
Pin No2: Subtraction sensor Pin No3: GND_B

The launch relay board 906 and the ball feed solenoid 918 are connected by a ball feed solenoid harness. The contents of the ball feed solenoid harness are as follows.

[Ball feed solenoid harness]
Pin No1: DC12V-1A
Pin No2: Ball feed solenoid

The launch relay board 906 and the launch solenoid 916 are connected by a launch solenoid harness. The contents of the firing solenoid harness are as follows.

[Launch solenoid harness]
Pin No1: Launch solenoid (+)
Pin No2: Launch solenoid (-)

[Fig. 192]
The lifting relay board 928 and the lifting inlet sensor 934 are connected by a lifting inlet sensor harness. The contents of the lifting entrance sensor harness are as follows.

[Lifting entrance sensor harness]
Pin No1: DC12V-1B
Pin No2: Lifting inlet sensor

The lifting relay board 928 and the lifting motor sensor board 929 are connected by a lifting motor sensor board harness. The contents of the lifting motor sensor board harness are as follows.

[Lift motor sensor board harness]
Pin No1: DC5V-1
Pin No2: Lifting motor sensor Pin No3: GND

The lifting relay board 928 and the lifting motor 932 are connected by a lifting motor harness. The contents of the lifting motor harness are as follows.

[Lift motor harness]
Pin No1: Lifting motor A phase Pin No2: Lifting motor B phase Pin No3: DC12V-1A
Pin No4: DC12V-1A
Pin No5: Lifting motor C phase Pin No6: Lifting motor D phase

The lifting relay board 928 and the lifting motor 932 are connected by a lifting earth harness. The contents of the lifting earth harness are as follows.

[Lifting Earth Harness]
Pin No1: FG (Connected to the board retaining screw)

[Sub system]
193 to 197 are diagrams showing an overall circuit diagram of a managed gaming machine sub system.
[Fig. 193]
The main control board 560 and the effect control board 900 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Production control signal TXB
Pin No3: GND

The effect control board 900 and the management game machine game board illumination and speaker 326 (other production devices) are connected by the management game machine game board illumination and speaker harness.

The effect control board 900 and the management game machine game board liquid crystal display 42 (other production devices) are connected by a management game machine game board liquid crystal display harness (other production devices).

The effect control board 900 and the sub-drawer board 966 are connected by a sub-drawer harness.

[Fig. 194]
The power supply device 570 and the sub-connection board 553 are connected by a sub-connection harness. The contents of the sub connection harness are as follows.

[Sub-connection harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-2
Pin No4: DC24V-2
Pin No5: DC24V-2
Pin No6: DC24V-2
Pin No7: GND
Pin No8: GND
Pin No9: GND
Pin No10: GND
Pin No11: DC12V-2
Pin No12: DC12V-2
Pin No13: DC12V-2
Pin No14: DC12V-2
Pin No15: DC12V-2
Pin No16: DC12V-2
Pin No17: GND
Pin No18: GND
Pin No19: GND
Pin No20: GND
Pin No21: DC12V-3
Pin No22: DC12V-3
Pin No23: DC12V-3
Pin No24: DC12V-3
Pin No25: GND
Pin No26: GND

[Fig. 195]
The sub drawer board 966 and the sub connection board 553 are connected by a sub drawer connector harness. The contents of the sub drawer connector harness are as follows.

[Sub-drawer connector harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-2
Pin No4: DC24V-2
Pin No5: DC24V-2
Pin No6: DC24V-2
Pin No7: GND
Pin No8: GND
Pin No9: DC12V-2
Pin No10: DC12V-2
Pin No11: DC12V-2
Pin No12: DC12V-2
Pin No13: DC12V-2
Pin No14: DC12V-2
Pin No15: GND
Pin No16: GND
Pin No17: DC12V-3
Pin No18: DC12V-3
Pin No19: GND
Pin No20: GND
Pin No21: GND
Pin No22: CS1
Pin No23: SCK1
Pin No24: SOD1
Pin No25: GND
Pin No26: CS2
Pin No27: SCK2
Pin No28: SOD2
Pin No29: GND
Pin No30: CLK
Pin No31: RXD
Pin No32: LOAD
Pin No33: SP3 (+)
Pin No34: SP3 (-)
Pin No35: SP2 (+)
Pin No36: SP2 (-)
Pin No37: SP1 (+)
Pin No38: SP1 (-)
Pin No39: GND
Pin No40: GND

[Fig. 196]
The sub-connection board 553 and the operation unit sub-connection board 553A are connected by the operation unit sub-connection harness. The contents of the operation unit sub-connection harness are as follows.

[Operation unit sub-connection harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC12V-3
Pin No4: DC12V-3
Pin No5: GND
Pin No6: GND
Pin No7: GND
Pin No8: CS1
Pin No9: SCK1
Pin No10: SOD1
Pin No11: GND
Pin No12: CS2
Pin No13: SCK2
Pin No14: SOD2
Pin No15: GND
Pin No16: CLK
Pin No17: RXD
Pin No18: LOAD
Pin No19: SP3 (+)
Pin No20: SP3 (-)
Pin No21: SP2 (+)
Pin No22: SP2 (-)
Pin No23: SP1 (+)
Pin No24: SP1 (-)
Pin No25: GND
Pin No26: GND
Pin No27: GND
Pin No28: GND

[Fig. 197]
The operation unit sub-connection board 553A and the front decoration illumination, dots, and the speaker 327 (other production devices) are connected by the front decoration illumination harness.

The operation unit sub-connection board 553A and the light amount / volume adjustment board 319 are connected by a light amount / volume adjustment harness.

The operation unit sub-connection board 553A and the other effect switch 328 (other effect device) are connected by the other effect switch harness.

[Management game machine game board main system]
198 to 203 are diagrams showing an overall circuit diagram of a main system of a managed gaming machine game board.

[Fig. 198]
The count switch 1 and the switch relay board 330 are connected by a count switch 1 harness. The contents of the count switch 1 harness are as follows.

[Count switch 1 harness]
Pin No1: GND
Pin No2: Count switch 1

The count switch 2 and the switch relay board 330 are connected by a count switch 2 harness. The contents of the count switch 2 harness are as follows.

[Count switch 2 harness]
Pin No1: GND
Pin No2: Count switch 2

The gate switch 1 and the switch relay board 330 are connected by a gate switch 1 harness. The contents of the gate switch 1 harness are as follows.

[Gate switch 1 harness]
Pin No1: GND
Pin No2: Gate switch 1

The ordinary winning opening switch 1 and the switch relay board 330 are connected by the ordinary winning opening switch 1 harness. The contents of the normal winning opening switch 1 harness are as follows.

[Normal winning opening switch 1 harness]
Pin No1: GND
Pin No2: Normal winning opening switch 1
Pin No3: DC5V-1

The normal winning opening switch 2 and the switch relay board 330 are connected by a normal winning opening switch 2 harness. The contents of the normal winning opening switch 2 harness are as follows.

[Normal winning opening switch 2 harness]
Pin No1: GND
Pin No2: Normal winning opening switch 2
Pin No3: DC5V-1

[Fig. 199]
The magnetic sensor and the switch relay board 330 are connected by a magnetic sensor 1 harness. The contents of the magnetic sensor 1 harness are as follows.

[Magnetic sensor 1 harness]
Pin No1: DC5V-1
Pin No2: Magnetic sensor signal 1
Pin No3: SELECT1
Pin No4: SELECT2
Pin No5: GND

The radio wave sensor 1 and the switch relay board 330 are connected by a radio wave sensor signal 1 harness. The contents of the radio wave sensor signal 1 harness are as follows.

[Radio wave sensor signal 1 harness]
Pin No1: GND
Pin No2: Radio wave sensor signal 1

The grand prize opening solenoid and the switch relay board 330 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: Large winning opening solenoid Pin No2: DC12V-1

The normal electric accessory solenoid and the switch relay board 330 are connected by a specified harness. The contents of the specified harness are as follows.

[Prescribed harness]
Pin No1: Ordinary electric accessory solenoid Pin No2: DC12V-1

[Fig. 200]
The start port switch 1 and the main control board 560 are connected by a start port switch 1 harness. The contents of the start port switch 1 harness are as follows.

[Starting port switch 1 harness]
Pin No1: Start port switch 1
Pin No2: DC5V-1

The start port switch 2 and the main control board 560 are connected by a start port switch 2 harness. The contents of the start port switch 2 harness are as follows.

[Starting port switch 2 harness]
Pin No1: Start port switch 2
Pin No2: DC5V-1

The switch relay board 330 and the main control board 560 are connected by a switch relay harness. The contents of the switch relay harness are as follows.

[Switch relay harness]
Pin No1: DC5V-1
Pin No2: Count switch 1
Pin No3: Count switch 2
Pin No4: Gate switch 1
Pin No5: Normal winning opening switch 1
Pin No6: Normal winning opening switch 2
Pin No7: DC12V-1
Pin No8: Ordinary electric accessory solenoid Pin No9: Grand prize opening solenoid Pin No10: Magnet sensor signal 1
Pin No11: Radio wave sensor signal 1
Pin No12: GND

FIG. 201.
The main control board 560 and the effect control board 900 are connected by an effect command harness. The contents of the production command harness are as follows.

[Direction command harness]
Pin No1: GND
Pin No2: Production control signal TXB
Pin No3: GND

The main control board 560 and the main display / winning display board 325 are connected by a main display / winning display harness. The contents of the main display / winning display harness are as follows.

[Main display / winning display harness]
Pin No1: Main display data 0
Pin No2: Main display data 1
Pin No3: Main display data 2
Pin No4: Main display data 3
Pin No5: Main display data 4
Pin No6: Main display data 5
Pin No7: Main display data 6
Pin No8: Main display data 7
Pin No9: Main display common 0
Pin No10: Main display common 1
Pin No11: Main display common 2
Pin No12: Main display common 3
Pin No13: Winning display data 1
Pin No14: Winning display data 2
Pin No15: Winning display data 3
Pin No16: DC12V-1

FIG. 202.
The main control board 560 and the main drawer board 950 are connected by a main control harness. The contents of the main control harness are as follows.

[Main control harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-1
Pin No4: DC24V-1
Pin No5: DC12V-1
Pin No6: DC12V-1
Pin No7: DC5V-1
Pin No8: DC5V-1
Pin No9: GND
Pin No10: GND
Pin No11: CRX1 (+)
Pin No12: CTX1 (+)
Pin No13: CRX1 (-)
Pin No14: CTX1 (-)
Pin No15: GND
Pin No16: RAM clear signal Pin No17: Power failure detection signal A
Pin No18: Power failure detection signal A
Pin No19: Night monitoring device power supply B
Pin No20: Night monitoring device power supply B
Pin No21: Night monitoring device power supply A
Pin No22: Night monitoring device power supply A
Pin No23: GND
Pin No24: GND

FIG. 203.
The main drawer board 950 and the main drawer connector 326 are connected by a main drawer harness. The contents of the main drawer harness are as follows.

[Main drawer harness]
Pin No1: GND
Pin No2: GND
Pin No3: DC24V-1
Pin No4: DC24V-1
Pin No5: DC12V-1
Pin No6: DC12V-1
Pin No7: DC5V-1
Pin No8: DC5V-1
Pin No9: GND
Pin No10: GND
Pin No11: CRX1 (+)
Pin No12: CTX1 (+)
Pin No13: CRX1 (-)
Pin No14: CTX1 (-)
Pin No15: GND
Pin No16: RAM clear signal Pin No17: Power failure detection signal A
Pin No18: Power failure detection signal A
Pin No19: Night monitoring device power supply B
Pin No20: Night monitoring device power supply B
Pin No21: Night monitoring device power supply A
Pin No22: Night monitoring device power supply A
Pin No23: GND
Pin No24: GND

The management game machine game board 580 and the main drawer connector 326 are connected by a management game machine game board ground harness.

[(3) Interface specifications]
[(I) Main control board-frame control board interface]
The main control board and the frame control board, which are the main systems of the management game machine game board and the management game machine frame, are connected by a 26-pin drawer connector. The pin layout specifications and configurations of the connector are as follows.

[(A) Connector pin layout specifications]
FIG. 204 is a diagram showing connector pin arrangement specifications.
[Pins Nos. 1 and 2]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pins Nos. 3 and 4]
Signal: DC24V-1
Contents: 24V power supply Active:-
Specifications:-

[Pins Nos. 5 and 6]
Signal: DC12V-1
Contents: 12V power supply Active:-
Specifications:-

[Pins Nos. 7 and 8]
Signal: DC5V-1
Contents: 5V power supply Active:-
Specifications:-

[Pins Nos. 9 and 10]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pin No11]
Signal: CRX1 (+) (* 1)
Contents: Positive phase signal transmitted from the main control board to the frame control board Active: L (* 2)
Specifications: Pull up to 5V with 4.7KΩ

[Pin No12]
Signal: CTX1 (+) (* 1)
Contents: Positive phase signal transmitted from the frame control board to the main control board Active: L (* 2)
Specifications: Open collector output (* 5)

[Pin No13]
Signal: CRX1 (-) (* 1)
Contents: Reversed phase signal transmitted from the main control board to the frame control board Active: H (* 2)
Specifications: Pull up to 5V with 4.7KΩ

[Pin No14]
Signal: CTX1 (-) (* 1)
Contents: Reversed phase signal transmitted from the frame control board to the main control board Active: H (* 2)
Specifications: Open collector output (* 5)

[Pin No15]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pin No16]
Signal: RAM clear signal Contents: RAM clear signal for main control Active: L (* 2)
Specifications: Open collector output (* 5)

[Pins Nos. 17 and 18]
Signal: Power off output signal A (* 4)
Contents: Power failure detection signal for main control board Active: L
Specifications: 5V CMOS output

[Pins No. 19 and 20]
Signal: Night monitoring device power supply B (* 3)
Contents: Management game machine Return from game machine board to management game machine frame Night monitoring device Power supply Active:-
Specifications:-

[Pins Nos. 21 and 22]
Signal: Night monitoring device power supply A (* 3)
Contents: Management game machine Night monitoring device sent from the game machine board to the management game machine frame Power supply Active:-
Specifications:-

[Pins No. 23, 24]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pins No. 25, 26]
Signal: FG
Contents: Frame GND
Active:-
Specifications:-

(* 1) The active rule is the frame control board input section (pull-up resistor).
(* 2) The active rule is the main control board input section.
(* 3) The power supply for the night monitoring device is a loop connection on the management game machine game board (main control board side). The power supply for the night monitoring device cannot be used in the management game machine game board.

(* 4) CRX1 (+), CTX1 (+), CRX1 (1), and CTX1 (-) use a differential interface built into the CPU.
The differential signal at the CPU output terminal must be pulled down or open on at least one side.
The deviation of the differential signal at the CPU input terminal portion needs to be less than 20% of the communication speed (38461.53 bps).
(* 5) When pulling up on the main control board side, the power supply voltage needs to be 5V, and the pull-up resistance needs to be 1KΩ or more.

FIG. 205 is a diagram showing a reset signal.
When the power failure detection signal B of the frame control board is turned on at time t, the frame control CPU reset signal is turned on after a predetermined time T1 (minimum: 150 ms, maximum: 250 ms) has elapsed.
At time t, when the power failure detection signal A of the main control board is turned ON, the main control CPU reset signal is turned ON after a predetermined time T2 (minimum: 300 ms, maximum: 600 ms) has elapsed.

(* 6) It is necessary to release the reset of the main control CPU within 300 ms to 600 ms from the rise of the power failure detection signal. Due to CPU restrictions, the reset release timing of the main control CPU needs to be less than 500 ms from the reset release timing of the frame control CPU. The frame control CPU reset signal is generated 150 ms to 250 ms after the power failure detection signal.

[(B) Circuit configuration]
The configuration of the interface between the main control board and the frame control board is as follows.
FIG. 206 is a diagram showing a circuit configuration when the FG of the management game machine game board is connected from the main drawer board without passing through the main control board.
The main control board 560 transmits CRX1 (+) and CRX1 (−) to the CPU of the frame control board 550 via the main drawer board 950, a predetermined resistor, and a forward rotation buffer by the open collector output.

The CPU of the frame control board 550 transmits CTX1 (+) and CTX1 (−) to the main control board 560 via a predetermined circuit (amplifier or the like), a predetermined circuit, and the main drawer board 950.

The RAM clear signal from the RAM clear switch 304 of the frame control board 550 is transmitted to the main control board 560 via a predetermined resistor, a predetermined circuit, and the main drawer board 950.

The night monitoring device A and the night monitoring device B from the night monitoring device power supply 949 of the night monitoring device 948 are transmitted to the main control board 560 via the main drawer board 950, and are transmitted to the main control board 560 via the main drawer board 950 at night. It is transmitted to the monitoring device 948.

The power supply device 570 transmits a power supply disconnection detection signal to the main control board 560 via the main drawer board 950 by means of a forward rotation buffer and a predetermined resistor.
The power supply device 570 transmits DC24V-1 to the main control board 560 via the main drawer board 950.
The power supply device 570 transmits DC12V-1 to the main control board 560 via the main drawer board 950.
The power supply device 570 transmits DC5V-1 to the main control board 560 via the main drawer board 950.
The power supply device 570, the main drawer board 950, and the main control board 560 are connected by a GND.
The power supply device 570, the main drawer board 950, and the management game machine game board FG connection unit 568 are connected by FG.
The management game machine game board FG connection portion 568 and the main drawer board 950 are connected by an FG harness.
The FG connection between the management game machine game board and the management game machine frame may be a harness connection or a configuration that can be connected by a structure other than the harness connection.

FIG. 207 is a diagram showing a circuit configuration when the FG of the management game machine game board is connected from the main drawer board via the main control board.
The main control board 560 transmits CRX1 (+) and CRX1 (−) to the CPU of the frame control board 550 via the main drawer board 950, a predetermined resistor, and a forward rotation buffer by the open collector output.

The CPU of the frame control board 550 transfers CTX1 (+) and CTX1 (-) to the main control board 560 via a predetermined circuit (amplifier or the like), a predetermined circuit, a circuit equivalent to HC07, and a main drawer board 950. Send.

The RAM clear signal from the RAM clear switch 304 of the frame control board 550 is transmitted to the main control board 560 via a predetermined resistor, a circuit corresponding to HC07, and a main drawer board 950.

The night monitoring device A and the night monitoring device B from the night monitoring device power supply 949 of the night monitoring device 948 are transmitted to the main control board 560 via the main drawer board 950, and are transmitted to the main control board 560 via the main drawer board 950 at night. It is transmitted to the monitoring device 948.

The power supply device 570 transmits a power supply disconnection detection signal to the main control board 560 via the main drawer board 950 by means of a forward rotation buffer and a predetermined resistor.
The power supply device 570 transmits DC24V-1 to the main control board 560 via the main drawer board 950.
The power supply device 570 transmits DC12V-1 to the main control board 560 via the main drawer board 950.
The power supply device 570 transmits DC5V-1 to the main control board 560 via the main drawer board 950.
The power supply device 570, the main drawer board 950, and the main control board 560 are connected by a GND.
The power supply device 570, the main drawer board 950, the main control board 560, and the management game machine game board FG connection unit 568 are connected by FG.
The power supply device 570 and the main drawer board 950 are connected to the management game machine game board FG connection unit 568 by the main control board 560.
The FG connection between the management game machine game board and the management game machine frame may be a harness connection or a configuration that can be connected by a structure other than the harness connection.

[(Ii) Production control board-Other production device interface]
The management game machine game board and the production control board, which is a sub system of the management game machine frame, and other production devices are connected by a 40-pin drawer connector. The pin layout specifications and configurations of the connector on the management game machine frame side are as follows.

[(A) Connector pin layout specifications]
FIG. 208 is a diagram showing connector pin arrangement specifications.
[Pins Nos. 1 and 2]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pins Nos. 3, 4, 5, 6]
Signal: DC24V-2
Contents: 24V power supply Active:-
Specifications:-

[Pins Nos. 7 and 8]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pins No. 9, 10, 11, 12, 13, 14]
Signal: DC12V-2
Contents: 12V power supply (Large capacity: For managed pachinko and pachislot machines)
Active:-
Specifications:-

[Pins Nos. 15 and 16]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pins Nos. 17 and 18]
Signal: DC12V-3
Contents: 12V power supply (small capacity: for managed gaming machine frame)
Active:-
Specifications:-

[Pins No. 19 and 20]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pin No21]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pin No22]
Signal: CS1
Contents: Chip select signal for front decoration lighting Active: L
Specifications: 5VCMOS

[Pin No23]
Signal: SCK1
Contents: Clock signal for front decoration lighting Active: L
Specifications: 5VCMOS

[Pin No. 24]
Signal: SOD1
Contents: Data signal for front decoration lighting Active: L
Specifications: 5VCMOS

[Pin No25]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pin No26]
Signal: CS2
Contents: Chip select signal for front decoration dot Active: L
Specifications: 5VCMOS

[Pin No27]
Signal: SCK2
Contents: Clock signal for front decoration dot Active: L
Specifications: 5VCMOS

[Pin No28]
Signal: SOD2
Contents: Data signal for front decoration dot Active: L
Specifications: 5VCMOS

[Pin No29]
Signal: GND
Contents: GND
Active:-
Specifications:-

[Pin No30]
Signal: CLK
Contents: Other production equipment Clock signal Active: H
Specifications: 5VCMOS

[Pin No31]
Signal: RXD
Contents: Other production equipment Received signal Active: H
Specifications: 5VCMOS

[Pin No32]
Signal: LOAD
Contents: Other production equipment Load signal Active: H
Specifications: 5VCMOS

[Pin No33]
Signal: SP3 (+) (* 1)
Contents: Spare terminal (voice)
Active:-
Specifications:-

[Pin No34]
Signal: SP3 (-) (* 1)
Contents: Spare terminal (voice)
Active:-
Specifications:-

[Pin No35]
Signal: SP2 (+) (* 2)
Contents: Other production equipment Audio signal left (+ side)
Active:-
Specifications:-

[Pin No36]
Signal: SP2 (-) (* 2)
Contents: Other production equipment Audio signal left (-side)
Active:-
Specifications:-

[Pin No37]
Signal: SP1 (+) (* 2)
Contents: Other production equipment Audio signal right (+ side)
Active:-
Specifications:-

[Pin No38]
Signal: SP1 (-) (* 2)
Contents: Other production equipment Audio signal right (-side)
Active:-
Specifications:-

[Pins No. 39, 40]
Signal: GND
Contents: GND
Active:-
Specifications:-

(* 1) If it is prepared for expansion, it may be unused. In this case, empty terminal processing is required on the management game machine game board side.
(* 2) SP1 is the voice on the right and SP2 is the voice on the left.

[(B) Circuit configuration]
FIG. 209 is a diagram showing a circuit configuration of an interface between the effect control board and other effect devices.
The configuration of the interface between the effect control board and other effect devices is as follows.
The circuit of the audio amplifier of the effect control board 900 transmits SP1 + and SP1- to the speaker 1 of the front decoration 512 and the operation unit 511 via the drawer connector relay board 280 and the management game machine frame sub system relay board 281. ..

The circuit of the audio amplifier of the effect control board 900 transmits SP2 + and SP2- to the speaker 2 of the front decoration 512 and the operation unit 511 via the drawer connector relay board 280 and the management game machine frame sub system relay board 281. ..

The predetermined circuit of the effect control board 900 transmits SOD1, SCK1, and CS1 to the LED driver of the front decoration 512 and the operation unit 511 via the drawer connector relay board 280 and the management game machine frame sub system relay board 281. ..

The predetermined circuit of the effect control board 900 passes the SOD2, SCK2, and CS2 via the drawer connector relay board 280 and the management game machine frame sub system relay board 281 to the front decoration 512 and the dot display unit (LED) of the operation unit 511. Send to driver).

A predetermined circuit of the effect control board 900 passes LOAD, RXD, and CLK via the drawer connector relay board 280 and the management game machine frame sub system relay board 281 to the front decoration 512 and other effect switches of the operation unit 511, and the amount of light. -Send to the volume control switch.

The power supply device 570 transmits the DC12V-3 to the front decoration 512 and the operation unit 511 via the management game machine frame sub-system relay board 281.
The power supply device 570 transmits the DC12V-3 to the effect control board 900 via the management game machine frame sub system relay board 281 and the drawer connector relay board 280.
The power supply device 570 transmits DC12V-2 to the effect control board 900 via the management game machine frame sub system relay board 281 and the drawer connector relay board 280.
The power supply device 570 transmits DC24V-2 to the effect control board 900 via the management game machine frame sub system relay board 281 and the drawer connector relay board 280.
The effect control board 900, the drawer connector relay board 280, the management game machine frame sub system relay board 281 and the power supply device 570 are connected by GND.

[(C) Outline of switch function for light intensity, volume adjustment and other effects]
(A) Specifications Light intensity, volume control, and other effects switches correspond to 30-pin (CLK), 31-pin (RXD), and 32-pin (LOAD) signals of the connector pin layout specifications of the effect control board-other effect device interface. doing.

The parallel / serial conversion IC in the operation unit sub-connection board converts the four push switches for increasing the amount of light, decreasing the volume, increasing the amount of light, and decreasing the volume, and other production switches into serial signals, and converts the production control board via the sub-drawer board. Sending to.

As for the operation outline, when RXD = "L", the state of the light amount up, the volume down, the light amount up, the volume down, and other production switches is stored in the register of the parallel / serial conversion IC. On the other hand, when RXD = "H", register information is sequentially output from LOAD at the rising edge of CLK. Details such as electrical characteristics and timing depend on the parallel / serial conversion IC (TC74VHC165). The order of the serial data is from the MSB side to the light amount up, volume down, light amount up, volume down, and other effect switches, and the remaining 3 bits are unused.

(B) Block diagram FIG. 210 is a diagram showing a block diagram including various switches and the like.
The management gaming machine frame 590 includes an operation unit sub-connection board 553A having a sub-connection board 553 and a parallel-serial conversion circuit 553B.
A light amount up switch 291, a volume up switch 292, a light amount down switch 293, a volume down switch 294, and other production switches 295 are connected to the operation unit sub-connection board 553A.

The management game machine game board 580 includes an effect control board 900 having a sub drawer board 966 and a control circuit 969 (CPU).

The signal (switch input) from the light amount up switch 291, the volume up switch 292, the light amount down switch 293, the volume down switch 294, and the other production switch 295 is the operation unit sub connection board 553A, the sub connection board 553, and the sub drawer board 966. It is transmitted to the effect control board 900 via the control board 900.

[(D) Outline of front decoration illuminated LED control]
(A) Specifications The front decoration of the management game machine is equipped with 58 full-color LEDs for the illumination unit, 192 for the dot display unit, and 240 for the total. The full-color LED can control RGB independently, and the number of systems is 114 for the illumination unit and 576 for the dot display unit.

The LED control is performed by the LED driver IC whose address can be set, and the LED driver IC is used with 6 illumination units and 4 dot display units.

The illumination part is 22 pins (CS1), 23 pins (SCK1), 24 pins (SOD1) of the connector pin specifications of the effect control board-other production device interface, and the dot display part is 26 pins (CS2), 27 pins ( It corresponds to SCK2) and 28-pin (SOD2) signals.

FIG. 211 is a diagram showing an outline of specifications of the illuminated portion and the dot display portion of the front decoration.
The total number of mounted LEDs is 240 (full-color LEDs).
Of these, 58 (full-color LEDs) are arranged in the illumination unit, and 192 (full-color LEDs: 8 rows vertically and 24 rows horizontally) are arranged in the dot display unit.

The number of LED systems is 114 for the illumination unit (38 systems x 3 systems) and 576 for the dot display unit (8 systems x 72 systems: dynamic control).

The number of LED drivers used is 6 for the illumination unit and 4 for the dot display unit (1 source, 3 sinks).

As for the communication method, the illumination unit and the dot display unit use SPI communication (with sleeming address setting).

The address value and LED system are as follows.
[Illuminations]
11H, center left, 1- (1)-(8)
12H, upper left and right, 2- (1)-(4)
13H, upper center, 3- (1)-(8)
14H, center right, 4- (1)-(8)
15H, lower center, 5- (1)-(2)
16H, lower left, 6- (1)-(8)

[Dot display]
21H, source side, 11- (1)-(8)
22H, sink side left, 12- (1)-(24)
23H, on the sink side, 13- (1)-(24)
24H, sink side right, 14- (1)-(24)
The numbers shown in the figure (Example 1- (1)) correspond to (b) LED arrangement, system diagram, etc., which will be described later.

(* 1) The LED driver output is assigned in the order of low-order bit to BGR, such as LED0 for 1- (1) B, LED1 for 1- (1) G, and LED2 for 1- (1) R.
(* 2) The LED driver output is assigned in the order of BRG from the lower bits, such as 12- (1) B for LED0, 12- (2) R for LED1, and 12- (3) G for LED2.

[(B) LED arrangement and system diagram]
FIG. 212 is a diagram showing an LED arrangement and a system diagram of the front decorative illumination section.
The LED arrangement and system diagram of the front decoration illumination part are as follows.
The numbers shown on each LED (Example 1- (1)) correspond to "Address A direct and LED system" in the table of specifications (a).

LEDs 1- (1) to (8) are arranged on the left member 461 of the front decoration illumination portion.

LEDs2- (1) (2) and LEDs3- (1) to (8) are arranged on the upper left member 462 of the front decoration illumination portion.
LEDs2- (3) and (4) are arranged on the upper right member 463 of the front decoration illumination portion.
LEDs 4- (1) to (8) are arranged on the right member 464 of the front decoration illumination portion.

LEDs 5- (1) and (2) are arranged on the lower right member 465 of the front decoration illumination portion.
LEDs 6- (1) to (8) are arranged on the lower right member 466 of the front decoration illumination portion.
The LED arrangement and system diagram of the front decorative dot display unit 467 will be described later.

FIG. 213 is a diagram showing an LED arrangement and a system diagram of the front decorative dot display unit.
The LED arrangement and system of the front decoration dot display unit are as follows.
The arrangement of the LEDs is such that the front decoration is viewed from the front.
The numbers shown in the system diagram (Example 11- (1)) correspond to the "address value and LED system" in the table of specifications (A).

In the front decorative dot display unit 467, LEDs 1 to LED 8 are arranged in the leftmost column, and LEDs 9 to LED 16 are arranged in the next column. LEDs 185 to LED 192 are arranged in the rightmost column (see (A) and (B) in the figure).

As shown in (C) in the figure, for example, when it is desired to light the LED1, the LED1 is specified by the combination of the address value and the LED system (11- (1) and 12- (2)). .. Further, for example, when it is desired to light the LED 192, the LED 192 is specified by the combination of the address value and the LED system (11- (8) and 14- (24)).

(C) Block Diagram FIGS. 214 and 215 are diagrams showing a block diagram of an illuminated portion and a dot display portion of the front decoration.
The numbers shown in the figure (Example 1- (1)) correspond to the "address value and LED system" in the table of the specifications (A).

The management game machine game board 580 includes an effect control CPU 126.
The management gaming machine frame 590 (front decoration 512) includes various LED drivers, an illumination unit 468, and a dot display unit 467.

The CS1, SCK1, and SOD1 from the effect control CPU 126 are transmitted to the LED driver 1 (sink driver, CS address (11H)). The LED driver 1 controls the LED systems 1- (1) to (8) to light the LED of the illumination unit 468.

The CS1, SCK1, and SOD1 from the effect control CPU 126 are transmitted to the LED driver 2 (sink driver, CS address (12H)). The LED driver 2 controls the LED systems 1- (1) to (4) to light the LED of the illumination unit 468.

The CS1, SCK1, and SOD1 from the effect control CPU 126 are transmitted to the LED driver 3 (sink driver, CS address (13H)). The LED driver 3 controls the LED systems 1- (1) to (4) to light the LED of the illumination unit 468.

The CS1, SCK1, and SOD1 from the effect control CPU 126 are transmitted to the LED driver 4 (sink driver, CS address (14H)). The LED driver 4 controls the LED systems 1- (1) to (8) to light the LED of the illumination unit 468.

The CS1, SCK1, and SOD1 from the effect control CPU 126 are transmitted to the LED driver 5 (sink driver, CS address (15H)). The LED driver 5 controls the LED systems 1- (1) to (2) to light the LED of the illumination unit 468.

The CS1, SCK1, and SOD1 from the effect control CPU 126 are transmitted to the LED driver 6 (sink driver, CS address (16H)). The LED driver 6 controls the LED systems 1- (1) to (8) to light the LED of the illumination unit 468.

The CS2, SCK2, and SOD2 from the effect control CPU 126 are transmitted to the LED driver 1 (predetermined driver + FET buffer, source driver, CS address (21H)). The LED driver 1 controls the LED systems 11- (1) to (8) to light the LED of the dot display unit 467.

The CS2, SCK2, and SOD2 from the effect control CPU 126 are transmitted to the LED driver 2 (sink driver, CS address (22H)). The LED driver 2 controls the LED systems 12- (1) to (24) to light the LED of the dot display unit 467.

The CS2, SCK2, and SOD2 from the effect control CPU 126 are transmitted to the LED driver 3 (sink driver, CS address (23H)). The LED driver 3 controls the LED systems 13- (1) to (24) to light the LED of the dot display unit 467.

The CS2, SCK2, and SOD2 from the effect control CPU 126 are transmitted to the LED driver 4 (sink driver, CS address (24H)). The LED driver 4 controls the LED systems 13- (1) to (24) to light the LED of the dot display unit 467.

[(4) CPU specifications]
[(I) Main control CPU]
[(A) Outline specifications of main control CPU]
FIG. 216 is a diagram showing a schematic specification of a main control CPU.
[No1]
Item: Processor Details: Prescribed processor

[No2]
Item: Package Details: 71 pins

[No3]
Item: Power supply voltage Details: 5V (4.0V to 5.5V)

[No4]
Item: Memory Details: User ROM: 12Kbyte, User RAM: 1KBbyte (backup)

[No5]
Item: Timer Details: 8-bit timer (PTC): 3ch, watchdog timer: 1ch

[No6]
Item: Communication port Details: Asynchronous serial: Send 2ch, Receive 1ch, Synchronous serial: Send 1ch, Receive 1ch, Cryptographic Asynchronous serial: Send 1ch, Receive 1ch

[No7]
Item: I / O port Details: Input port: 6 bits, Output port: 8 bits

[No8]
Item: External chip select Details: Individual: 12 pieces, Expansion: 2 pieces

[No9]
Item: Interrupt Details: Maskable interrupt: 10 (one of which is external XINT), non-maskable interrupt: 1 (external XNMI)

[No10]
Item: System lock Details: Maximum operating frequency: 16MHz (when external input clock is 32MHz)

[No11]
Item: External output clock Details: ESCK: 1, DCLK: 1

[No12]
Item: Free run counter Details: 8bit: 4ch

[No13]
Item: Random number circuit Details: 16-bit random number: 4ch, 8-bit random number: 6ch

[No14]
Item: Arithmetic circuit Details: Multiplication: 16 bits x 16 bits = 32 bits, Division: 32 bits ÷ 32 bits = 32 bits (quotient), Division: 32 bits ÷ 32 bits = 32 bits (surplus)

[No15]
Item: Unique information Details: ROM code: 4Byte x 4, Chip individual number: 4Byte, ID number: 8Byte

[No16]
Item: Other Details: Backup power supply terminal: Yes, security mode time can be extended

[(B) Main control CPU terminal connection diagram]
FIG. 217 is a diagram showing a main control CPU terminal connection diagram.
The details of each terminal are as follows.
Terminal 1: Outputs A8.
Terminal 2: Outputs TX0 / XCS7.
Terminal 3: Outputs A9.
Terminal 4: Outputs DCLK / XCS6.
Terminal 5: Outputs A10.
Terminal 6: Outputs ESCK / XCS5.
Terminal 7: Outputs A11.
Terminal 8: Corresponds to VDD3.
Terminal 9: Outputs A12.
Terminal 10: Outputs CTX_N.
Terminal 11: Outputs A13.
Terminal 12: Outputs CTX_P.
Terminal 13: Outputs A14.
Terminal 14: CRX_N is input.
Terminal 15: Outputs A15.
Terminal 16: CRX_P is input.
Terminal 17: Corresponds to VSS1.

Terminal 18: EX is input.
Terminal 19: Corresponds to VDD1.
Terminal 20: Corresponds to VBB.
Terminal 21: RCK is input.
Terminal 22: Outputs TX1 / XCS4.
Terminal 23: Outputs XM1.
Terminal 24: Outputs P05 / XCS3.
Terminal 25: Outputs XMREF.
Terminal 26: Outputs P04 / XCS2.
Terminal 27: Outputs XIORQ.
Terminal 28: Outputs P03 / XCS1.
Terminal 29: Outputs XRD.
Terminal 30: Outputs P02 / XCS0.
Terminal 31: Outputs XWR.
Terminal 32: Outputs P01 / XCSE1.
Terminal 33: Outputs P00 / XCSE0.
Terminal 34: XSRST is input.
Terminal 35: Corresponds to VSS2.

Terminal 71: Corresponds to VSS5.
Terminal 70: PI0 / RX0 is input.
Terminal 69: Outputs A0.
Terminal 68: PI1 / XNMI is input.
Terminal 67: Outputs A1.
Terminal 66: PI2 / XINT is input.
Terminal 65: Outputs A2.
Terminal 64: PI3 / SDI is input.
Terminal 63: Outputs A3.
Terminal 62: PI4 is input.
Terminal 61: Outputs A4.
Terminal 60: PI5 is input.
Terminal 59: Outputs A5.
Terminal 58: Outputs P07 / XCS11.
Terminal 57: Outputs A6.
Terminal 56: Outputs P06 / XCS10.
Terminal 55: Outputs A7.
Terminal 54: Corresponds to VSS4.

Terminal 53: Corresponds to VDD25.
Terminal 52: Corresponds to VDD2.
Terminal 51: BRC is input.
Terminal 50: Outputs XRST0.
Terminal 49: SC is input.
Terminal 48: Outputs SD0 / XCS9.
Terminal 47: PRG is input.
Terminal 46: Outputs SCK / XCS8.
Terminal 45: Outputs CLK0.
Terminal 44: Corresponds to VSS3.
Terminal 43: Sends and receives D0.
Terminal 42: Sends and receives D1.
Terminal 41: Sends and receives D2.
Terminal 40: Sends and receives D3.
Terminal 39: Sends and receives D4.
Terminal 38: Sends and receives D5.
Terminal 37: Sends and receives D6.
Terminal 36: Sends and receives D7.
This figure is a terminal connection diagram in the user mode.
VDD25 is the monitor output of the internal power supply.

[(C) Main control CPU terminal function list]
218 and 219 are diagrams showing a list of terminal functions of the main control CPU.
Terminal name: A0-A15
I / O: Output Description: 16-bit address bus

Terminal name: D0-D7
Input / output: Input / output Description: 8-bit data input / output bus

Terminal name: XM1
Input / output: Output Description: Output terminal indicating machine cycle 1 (M1 cycle)

Terminal name: XMRQ
Input / output: Output Description: Request signal output terminal to memory space

Terminal name: XIORQ
Input / output: Output Description: Request signal output terminal to I / O space

Terminal name: XRD
Input / output: Output Description: Output terminal indicating read cycle

Terminal name: XWR
Input / output: Output Description: Output terminal indicating that it is a write cycle

Terminal name: RCK
Input / output: Input Description: External clock input terminal for random numbers

Terminal name: PI0 / RX0, PI1 / XNMI, PI2 / XINT, PI3 / SDI, PI4-PI5
Input / output: Input Description: 6-bit parallel input port terminal. However, the next 4 bits are function-combined terminals. The PI0 / RX0 terminal is also used as an input port and asynchronous serial communication ch0 reception terminal. The PI1 / XNMI terminal is also used as an input port and non-maskable interrupt request input. The PI2 / XINT terminal is also used as an input port and an external masqueradable interrupt request input. The PI3 / SDI terminal is also used as an input port and a synchronous serial communication reception terminal.

Terminal names: P00 / XCSE0, P01 / XCSE1, P02 / XCS0, P03 / XCS1, P04 / XCS2, P05 / XCS3, P06 / XCS10, P07 / XCS11
Input / output: Output Description: 8-bit parallel output port terminal. However, since it is a function-combined terminal, the function can be selected between the output port and the chip select output to an external device.

Terminal name: TX0 / XCS7, TX1 / XCS4
Input / output: Output Description: Transmission terminal of asynchronous serial communication ch0-1. However, since it is a function-combined terminal, the function can be selected between the asynchronous serial terminal and the chip select output to an external device.

Terminal name: SCK / XCS8, SD0 / XCS9
Input / output: Output Description: Synchronous serial communication terminal. However, since it is a function-combined terminal, the function can be selected between synchronous serial transmission and chip select output of an external device.

Terminal name: ESCK / XCS5, DCLK / XCS6
Input / output: Output Description: Clock output terminal to the outside. However, since it is a function-combined terminal, the function can be selected between the clock output and the chip select output to an external device.

Terminal name: CTX_N, CTX_P
Input / output: Output Description: Asynchronous serial encrypted communication transmission terminal

Terminal name: CRX_N, CRX_P
Input / output: Input Description: Receiving terminal for asynchronous serial encrypted communication

Terminal name: XSRST
Input / output: Input Description: System reset input terminal

Terminal name: XRST0
Input / output: Output Description: Reset output terminal

Terminal name: PRG
Input / output: Input Description: Input terminal for setting to PROM mode

Terminal name: EX
Input / output: Input Description: Clock input terminal

Terminal name: CLK0
Input / output: Output Description: System clock output terminal

Terminal names: VDD1, VDD2, VDD3
Input / output:-
Description: Positive power supply terminal

Terminal name: VDD25
Input / output:-
Description: Internal power terminal

Terminal name: VBB
Input / output:-
Description: Power supply terminal for backup of internal RAM

Terminal name: VSS1, VSS2, VSS3, VSS4, VSS5
Input / output:-
Description: Ground potential terminal

Terminal name: SC
Input / output: Input / output Description: Matching terminal

Terminal name: BRC
Input / output: Input Description: Collation terminal The operation may differ between the mass production CPU and the development CPU.

[(Ii) Frame control CPU]
[(A) Frame control CPU schematic specifications]
FIG. 220 is a diagram showing a schematic specification of a frame control CPU.
[No1]
Item: Processor Details: Prescribed processor

[No2]
Item: Package Details: 71 pins

[No3]
Item: Power supply voltage Details: 2.85V to 3.6V

[No4]
Item: Memory Details: User ROM: 8Kbyte, User RAM: 1KBbyte (nonvolatile RAM)

[No5]
Item: Timer Details: 8-bit timer (PTC): 3ch, watchdog timer: 1ch

[No6]
Item: Communication port Details: Asynchronous serial: Send 2ch, Receive 2ch, Synchronous serial: Send 1ch, Receive 1ch, Cryptographic Asynchronous serial: Send 1ch, Receive 1ch

[No7]
Item: I / O port Details: Input port: 4 bits, Output port: 4 bits

[No8]
Item: External chip select Details: Individual: 10 pieces, Expansion: 2 pieces

[No9]
Item: Interrupt Details: Maskable interrupt: 11 (one of which is an external XINT), non-maskable interrupt: 1 (external XNMI)

[No10]
Item: System lock Details: Maximum operating frequency: 16MHz (when external input clock is 32MHz)

[No11]
Item: External output clock Details: ESCK: 3 pcs, DCLK: 1 pcs

[No12]
Item: Arithmetic circuit Details: Addition: 32bit + 32bit = 32bit, Subtraction: 32bit-32bit = 32bit, Multiplication: 16bit x 16bit = 32bit, Division: 32bit ÷ 32bit = 32bit (quotient), Division: 32bit ÷ 32bit = 32bit (surplus)

[No13]
Item: Unique information Details: ROM code: 4Byte x 4, Chip individual number: 4Byte, ID number: 8Byte

[No16]
Item: Other Details: Backup power supply terminal: None

[(B) Frame control CPU terminal connection diagram]
FIG. 221 is a diagram showing a frame control CPU terminal connection diagram.
The details of each terminal are as follows.
Terminal 1: Outputs A8.
Terminal 2: Outputs TX0 / XCS7.
Terminal 3: Outputs A9.
Terminal 4: Outputs DCLK / XCS6.
Terminal 5: Outputs A10.
Terminal 6: Outputs ESCK / XCS5.
Terminal 7: Outputs A11.
Terminal 8: Corresponds to VDD3.
Terminal 9: Outputs A12.
Terminal 10: Outputs CTX_N.
Terminal 11: Outputs A13.
Terminal 12: Outputs CTX_P.
Terminal 13: Outputs A14.
Terminal 14: CRX_N is input.
Terminal 15: Outputs A15.
Terminal 16: CRX_P is input.
Terminal 17: Corresponds to VSS1.

Terminal 18: EX is input.
Terminal 19: Corresponds to VDD1.
Terminal 20: Corresponds to NC.
Terminal 21: RX1 is input.
Terminal 22: Outputs TX1 / XCS4.
Terminal 23: Outputs XM1.
Terminal 24: Outputs P05 / XCS3.
Terminal 25: Outputs XMREF.
Terminal 26: Outputs P04 / XCS2.
Terminal 27: Outputs XIORQ.
Terminal 28: Outputs P03 / XCS1.
Terminal 29: Outputs XRD.
Terminal 30: Outputs P02 / XCS0.
Terminal 31: Outputs XWR.
Terminal 32: Outputs P01 / XCSE1.
Terminal 33: Outputs P00 / XCSE0.
Terminal 34: XSRST is input.
Terminal 35: Corresponds to VSS2.

Terminal 71: Corresponds to VSS5.
Terminal 70: PI0 / RX0 is input.
Terminal 69: Outputs A0.
Terminal 68: PI1 / XNMI is input.
Terminal 67: Outputs A1.
Terminal 66: PI2 / XINT is input.
Terminal 65: Outputs A2.
Terminal 64: PI3 / SDI is input.
Terminal 63: Outputs A3.
Terminal 62: CRX1_P is input.
Terminal 61: Outputs A4.
Terminal 60: CRX1_N is input.
Terminal 59: Outputs A5.
Terminal 58: Outputs CTX1_P.
Terminal 57: Outputs A6.
Terminal 56: Outputs CTX1_N.
Terminal 55: Outputs A7.
Terminal 54: Corresponds to VSS4.

Terminal 53: Corresponds to NC.
Terminal 52: Corresponds to VDD2.
Terminal 51: BRC is input.
Terminal 50: Outputs XRST0.
Terminal 49: SC is input.
Terminal 48: Outputs SD0 / XCS9.
Terminal 47: PRG is input.
Terminal 46: Outputs SCK / XCS8.
Terminal 45: Outputs CLK0.
Terminal 44: Corresponds to VSS3.
Terminal 43: Sends and receives D0.
Terminal 42: Sends and receives D1.
Terminal 41: Sends and receives D2.
Terminal 40: Sends and receives D3.
Terminal 39: Sends and receives D4.
Terminal 38: Sends and receives D5.
Terminal 37: Sends and receives D6.
Terminal 36: Sends and receives D7.
This figure is a terminal connection diagram in the user mode.

[(C) Frame control CPU terminal function list]
222 and 223 are diagrams showing a list of terminal functions of the frame control CPU.
Terminal name: A0-A15
I / O: Output Description: 16-bit address bus

Terminal name: D0-D7
Input / output: Input / output Description: 8-bit data input / output bus

Terminal name: XM1
Input / output: Output Description: Output terminal indicating machine cycle 1 (M1 cycle)

Terminal name: XMRQ
Input / output: Output Description: Request signal output terminal to memory space

Terminal name: XIORQ
Input / output: Output Description: Request signal output terminal to I / O space

Terminal name: XRD
Input / output: Output Description: Output terminal indicating read cycle

Terminal name: XWR
Input / output: Output Description: Output terminal indicating that it is a write cycle

Terminal name: PI0 / RX0, PI1 / XNMI, PI2 / XINT, PI3 / SDI
Input / output: Input Description: 4-bit parallel input port terminal. However, it is a function-combined terminal. The PI0 / RX0 terminal is also used as an input port and asynchronous serial communication ch0 reception terminal. The PI1 / XNMI terminal is also used as an input port and non-maskable interrupt request input. The PI2 / XINT terminal is also used as an input port and an external masqueradable interrupt request input. The PI3 / SDI terminal is also used as an input port and a synchronous serial communication reception terminal.

Terminal name: P00 / XCSE0, P01 / XCSE1, P02 / XCS0, P03 / XCS1
Input / output: Output Description: 4-bit parallel output port terminal. However, since it is a function-combined terminal, the function can be selected between the output port and the chip select output to an external device.

Terminal name: RX1
Input / output: Input Description: Receive terminal of asynchronous serial communication ch0-1

Terminal name: TX0 / XCS7, TX1 / XCS4
Input / output: Output Description: Transmission terminal of asynchronous serial communication ch0-1. However, since it is a function-combined terminal, the function can be selected between the asynchronous serial terminal and the chip select output to an external device.

Terminal name: SCK / XCS8, SD0 / XCS9
Input / output: Output Description: Synchronous serial communication terminal. However, since it is a function-combined terminal, the function can be selected between synchronous serial transmission and chip select output of an external device.

Terminal name: ESCK0 / XCS2, ESCK1 / XCS3, ESCK2 / XCS5, DCLK / XCS6
Input / output: Output Description: Clock output terminal to the outside. However, since it is a function-combined terminal, the function can be selected between the clock output and the chip select output to an external device.

Terminal name: CTX0_N, CTX1_N, CTX0_P, CTX1_P
Input / output: Output Description: Asynchronous serial encrypted communication ch0-1 transmission terminal

Terminal name: CRX0_N, CRX1_N, CRX0_P, CRX1_P
Input / output: Input Description: Receive terminal of asynchronous serial encrypted communication ch0-1

Terminal name: XSRST
Input / output: Input Description: System reset input terminal

Terminal name: XRST0
Input / output: Output Description: Reset output terminal

Terminal name: PRG
Input / output: Input Description: Input terminal for setting to PROM mode

Terminal name: EX
Input / output: Input Description: Clock input terminal

Terminal name: CLK0
Input / output: Output Description: System clock output terminal

Terminal names: VDD1, VDD2, VDD3
Input / output:-
Description: Positive power supply terminal

Terminal name: VSS1, VSS2, VSS3, VSS4, VSS5
Input / output:-
Description: Ground potential terminal

Terminal name: SC
Input / output: Input / output Description: Matching terminal

Terminal name: BRC
Input / output: Input Description: Matching terminal

Terminal name: NC
Input / output:-
Description: Non-connection terminal The operation may differ between the mass-produced CPU and the development CPU.

[6. Software configuration]
[(1) Main control program]
FIG. 224 is a diagram showing the configuration of the main control program.
The main control programs are system processing program P10, I / O processing program P20, random number update processing program P30, special symbol / special electric accessory processing program P40, ordinary symbol / ordinary electric accessory processing program P50, frame control processing program P60. It has. The main control program is executed by the main control CPU.

The system processing program P10 can execute the system processing program power cutoff process and the power failure recovery process initialization process.

The I / O processing program P20 includes switch input (start port switch input, gate switch input, count switch input, normal winning port switch input), solenoid output (solenoid control), dynamic lighting LED control (special symbol display control, ordinary symbol). Display control, special symbol operation hold ball number display control, normal symbol operation hold ball number display control, winning display control, game status display control, continuous operation number display control), test terminal signal output control, illegal game monitoring control (illegal winning) Processing related to (monitoring, radio wave monitoring, solenoid monitoring) can be executed.

The random number update processing program P30 can execute processing related to random number update for determination, random number update for initial value determination, and display symbol random number update.

The special symbol / special electric accessory processing program P40 can execute processing related to the special symbol / special electric accessory control, the special symbol control, and the special electric accessory control.

The ordinary symbol / ordinary electric accessory processing program P50 can execute processing related to ordinary symbol / ordinary electric accessory control, ordinary symbol control, and ordinary electric accessory control.

The frame control processing program P60 can execute processing related to frame control, transmission command editing, and reception command normality determination.

[(2) Frame control program]
FIG. 225 is a diagram showing a configuration of a frame control program.
The frame control program includes a system processing program P70, an I / O processing program P80, a communication processing program P90, and a device control program P100. The frame control program is executed by the frame control CPU.

The system processing program P70 can execute power cutoff processing, power failure recovery processing, and initialization processing.

The I / O processing program P80 includes motor control (polishing motor control, cassette motor control, lifting motor control), solenoid output (launch solenoid control, ball feed solenoid control), switch input (launch stop switch input, launch inlet sensor input). , Non-winning sensor input, winning sensor input, subtraction sensor input, ball jam sensor input, lifting motor sensor input, lifting inlet sensor input, polishing motor sensor input, polishing inlet sensor input, cassette switch input, radio wave sensor input, front It is possible to execute processing related to display output such as decoration / back mechanism opening switch, counting switch, ball removal switch, error release switch, night monitoring device), and the number of game balls.

The communication processing program P90 can execute processing related to main control board command transmission / reception and dedicated unit command transmission / reception.

The device control program P100 can execute processes related to launcher control, ball polishing device control, game ball circulation device control, game ball number display control, game ball number counting control, fraud monitoring, and ball removal control.

[(3) Interface specifications]
[(I) Main control board-frame control board interface]
[(A) Communication format]
[(A) Communication conditions]
FIG. 226 is a diagram showing communication conditions of the main control board-frame control board interface.
The signal level is an open collector.
The communication speed is 38461.53 BPS.
The bit configuration is "start bit: 1, data bit: 8, stop bit: 1, parity: none".
The communication method is mutual surveillance communication.
The communication control is half-duplex communication (command / response method), and the communication cycle is 200 ms.
The encryption control is "Yes".

[(B) Communication data]
[(A) Block diagram of user program interface]
FIG. 227 is a diagram showing a block diagram of the user program interface.
In the main control and frame control open communication, data is automatically transmitted and received by the main control CPU and the frame control CPU by the communication function inside the CPU.
The interface with the user program is performed by the CPU dedicated register.
The information handled by the register includes game information, game status information, and managed game machine frame information.

The main control CPU user program P200 of the main control CPU 72 authenticates with the cryptographic communication control unit P210 using the status register SL.

The main control CPU user program P200 of the main control CPU 72 transmits game information to the frame control CPU via the main control → frame control transmission data FIFO (128byte) and the encrypted communication control unit P210.

The main control CPU user program P200 of the main control CPU 72 transmits game state information to the frame control CPU via the game state information register L100 (registers 0 to 7) and the cryptographic communication control unit P210.

The frame control CPU transmits the management game machine frame information to the main control CPU user program P200 of the main control CPU 72 via the cryptographic communication control unit P210 and the management game machine frame information register L200 (registers 0 to 7).

The cryptographic communication control unit P210 transmits the recovery completion information to the main control CPU user program P200 of the main control CPU 72 via the recovery status register L300.

[(B) Game information (main control → frame control)]
The game information is operation information such as a prize ball and a symbol stop transmitted from the main control CPU to the frame control CPU.
The game information is transmitted using the main control → frame control transmission data FIFO.
After writing from the main control user program to the main control → frame control transmission data FIFO, data is transmitted to the frame control CPU by the internal communication function.
The game information is composed of 1 byte of type information and 1 byte of count information, for a total of 2 bytes, and is written every 2 bytes.

FIG. 228 is a diagram showing details of game information.
The game information is 2 bytes, and is composed of 1 byte type information and 1 byte count information.

FIG. 229 is a diagram showing details of the type information.
Bit4-7 of the type information indicates the data type.
The details of the data type of the game information are as follows.
0 = No information 1 = Start opening 2 = Large winning opening 3 = Winning opening 4 = Number of symbol stops 5 = Big hit 6 = Small hit 7 = Gate pass 8 = Number of accessories 9 = Pass through specific area

Bit0-3 of the type information indicates a data number.
The details of the data number for each game information data type are "1 to 15 = data number".

(* 1) The data number of the jackpot is "1 = large launch, 2 = small launch, 3 = during launch, 4-6 = reserve".
(* 2) The data number of the small hit is "1 = small hit, 2 to 15 = spare".
(* 3) Regarding the classification, the one that sends a command in a single shot is called a "command". The "state" is defined as the one that transmits the switching of the ON (1) and OFF (0) states (hereinafter, the same applies).

FIG. 230 is a diagram showing details of the count information.
The count information differs for each data type and shows details for each type.

[(A) When the data type is 1 = starting port, 2 = large winning opening, 3 = winning opening]
[Bit4-7]
Name: Number of prize balls Details: Number of prize balls at the time of winning for each game information / type information, 1 to 15 = Number of prize balls Category: Command

[Bit0-3]
Name: Number of prizes Details: Number of prizes (cumulative) for each game console information / type information, 1 to 15 = Number of prizes Category: Command

[(B) When the data type is 4 = number of symbol stops]
[Bit4-7]
Name: Preliminary Details: Fixed to 0 Category: Command

[Bit0-3]
Name: Number of symbol stops Details: 1 (times)
Category: Command

[(C) When the data type is 5 = big hit, 6 = small hit]
[Bit4-7]
Name: Preliminary Details: Fixed to 0 Category: Command

[Bit0-3]
Name: Number of hits Details: 1 (times)
Category: Command

[(D) When the data type is 7 = passing through the gate]
[Bit4-7]
Name: Preliminary Details: Fixed to 0 Category: Command

[Bit0-3]
Name: Number of times the gate has passed Details: 1 (times)
Category: Command

[(E) When the data type is 8 = the number of characters]
[Bit4-7]
Name: Preliminary Details: Fixed to 0 Category: Command

[Bit0-3]
Name: Number of characters Details: 1 (times)
Category: Command

[(F) When the data type is 9 = passing through a specific area]
[Bit4-7]
Name: Preliminary Details: Fixed to 0 Category: Command

[Bit0-3]
Name: Number of passes through a specific area Details: 1 (times)
Category: Command

[(C) Game status information (main control → frame control)]
FIG. 231 is a diagram showing details of game state information.
The game state information is state information transmitted from the main control CPU to the frame control CPU.
The game status information is transmitted using the game status information registers 0 to 7.
After the main control user program writes this register, data is transmitted to the frame control CPU by the internal communication function.
The bit arrangement of each register is shown below.

[No1]
Name: Game status information register 0
Details: D0: jackpot 1 (all jackpots), D1: jackpot 2 (specific hits, jackpots, small hits), D2: jackpot 3 (shorter jackpots), D3 to D7: preliminary classification: status

[No2]
Name: Game status information register 1
Details: D0: Big hit + Time saving, D1: High probability, D2: Time saving, D3: Fluctuation, D4 to D7: Preliminary classification: State

[No3]
Name: Game status information register 2
Details: D0: Illegal board 1, D1: Illegal board 2, D2: Illegal board 3, D3: Illegal board 4, D4: Illegal board 5, D5: Illegal board 6
Category: Status

[No4]
Name: Game status information register 3
Details: D0: Game stop, D1 to D7: Preliminary classification: Status

[No5]
Name: Game status information register 4
Details: D0: Game status information acquisition permission flag, D1 to D7: Preliminary classification: Status

[No6]
Name: Game status information register 5
Details: When an error occurs (D0 to D5: Error code (1-63), D6: Fixed to 1 when an error occurs, D7 = 1 (when outputting a hall controller)), When no error occurs (No error at D0 to D5: 0) To occur)
Category: Status

[No7]
Name: Game status information register 6
Details: Preliminary classification: Status

[No8]
Name: Game status information register 7
Details: Preliminary classification: Status

[(D) Management game machine frame information (frame control → main control)]
FIG. 232 is a diagram showing details of the managed gaming machine frame information.
The management game machine frame information is state information received by the main control CPU from the frame control CPU.
The management game machine frame information acquires the state by using the management game machine frame information registers 0 to 7.
After the frame control user program writes this register, data is transmitted to the main control CPU by the internal communication function.
The bit arrangement of each register is shown below.

[No1]
Name: Management game machine frame information register 0
Details: D0: Front decoration / back mechanism open, D1: Illegal radio wave detection, D2: Proximity sensor abnormality, D3: Winning number abnormality, D4: Illegal ball lending detection, D5: Abnormality detection by night monitoring function, D6 to D7: Preliminary classification: Condition

[No2]
Name: Management game machine frame information register 1
Details: D0: Game ball number display overflow, D1 to D7: Preliminary classification: Status

[No3]
Name: Management game machine frame information register 2
Details: D0: Power saving transition request, D1 to D7: Preliminary classification: Status

[No4]
Name: Management game machine frame information register 3
Details: D0: Card removal notification request, D1 to D7: Preliminary classification: Status

[No5]
Name: Management game machine frame information register 4
Details: D0: Pause request, D1 to D7: Preliminary classification: Status

[No6]
Name: Management game machine frame information register 5
Details: Preliminary classification: Status

[No7]
Name: Management game machine frame information register 6
Details: Preliminary classification: Status

[No8]
Name: Management game machine frame information register 7
Details: Preliminary classification: Status

[Processing flow]
[(A) Processing when the power is turned on]
FIG. 233 is a flowchart showing a procedure example of the power-on processing.
In the power-on processing, the RAM clear processing is performed, and after confirming the completion of authentication and recovery, the game status information is set and the game is started.
The operation flow is shown below.
The main control CPU confirms whether or not to execute the RAM clear (S7000), and if it determines to execute the RAM clear (S7000; Yes), executes the RAM clear (S7001). RAM clear is executed before confirmation of authentication completion.

When the main control CPU confirms the completion of authentication and recovery (S7002; Yes, S7003; Yes), the main control CPU sets the game information by setting the game state information registers 0 to 3 (S7004), and the game state information register 4 Set the game status information acquisition permission flag to (S7005), and shift to the game start state.

When the flag information from the status register of the CPU is authentication OK, it is determined that the authentication is completed.

[Judgment of authentication completion]
In the status register of the CPU, authentication is confirmed between the management game machine game board and the management game machine frame, and between the dedicated unit and the management game machine frame, and the communication status between the management game machine game board and the management game machine frame is further confirmed. Authentication is completed when communication is permitted.

When the flag information from the recovery status register of the CPU completes the recovery, it is determined that the recovery is complete.

〔recovery〕
Recovery is a function in which the CPU automatically retries untransmitted data when a communication abnormality such as power failure or communication disconnection occurs and there is untransmitted data.

[(B) Pause processing]
FIG. 234 is a flowchart showing a procedure example of the pause process.
The main control CPU detects the pause request (S7010; Yes), and in the case of a big hit state (S7011; Yes), suspends the game.
The pause request is notified by D0 (pause request) of the management game machine frame information register 4.

[(C) Restoration process from pause]
FIG. 235 is a flowchart showing an example of a procedure for returning from a pause.
To detect the return from the pause, the main control CPU starts the game after confirming that the pause request is OFF (S7020; Yes).

[(D) Processing when communication abnormality is detected]
FIG. 236 is a diagram showing an example of a procedure for processing when a communication abnormality is detected.
When the main control CPU detects a communication timeout (S7030; Yes), it confirms the progress of the winning protection weight (S7031; Yes), and if it is in a big hit state (S7032; Yes), it suspends the game as a communication abnormality. If it is not in the big hit state (S7032; No), the prize is invalidated as a communication abnormality.

When a timeout is notified from the flag information of the CPU status register, it is determined that the communication timeout is reached. The communication timeout time is an internal function of the CPU and is set to 3 seconds.
In order to protect the prizes, the weight is set for the specified time. Since the specified time differs depending on the configuration of the management game machine game board, it can be set to any time depending on the model. If a return is detected during the prize protection weight, the game can be continued.
In the case of a big hit state, the game is suspended, and in the case of a non-big hit state, the winning is invalidated.

[(E) Recovery process from communication error]
FIG. 237 is a diagram showing an example of a procedure for recovering from a communication abnormality.
The recovery detection from the communication abnormality starts the game after confirming the authentication completion, the recovery completion, and the pause request OFF (S7040; Yes, S7041; Yes, S7042; Yes).

When the flag information from the status register of the CPU is authentication OK, it is determined that the authentication is completed.
When the flag information from the recovery status register of the CPU completes the recovery, it is determined that the recovery is complete.
After confirming that the pause request is OFF, the game is started.

[Chapter 2 Lower launch management game machine]
[1. Game board specifications]
[1.1 Game board size]
FIG. 238 is a diagram showing the size of the game board.
The managed gaming machine has a vertical length L1 (length: 570 mm), a horizontal length L2 (width: 494 mm), a thickness L3 (thickness: 19 mm), and a length L4 (thickness: 19 mm) of the flow-down region. A game board 8b having a thickness of 18.5 mm) can be mounted.

[1.2 Game area]
FIG. 239 is a diagram showing a game area.
In the managed gaming machine, a gaming region 8a having a vertical length L11 (height 499 mm) and a horizontal length L12 (width: 467.5 mm) can be formed. This is the case of the model with the width of the left inner band of 2.5 mm. If the left inner band is made of 0.8 mm SUS plate, the game area of 1.7 mm is increased and the area of 469.2 mm can be taken.
In order not to affect the firing performance, it is preferable that the shape shown by the line X and the band shape are the same.

[2. Game machine frame specifications]
[2.1 Main dimensions]
FIG. 240 is a diagram showing the main dimensions of the gaming machine frame.
The vertical length L21 of the gaming machine frame 2000 is, for example, 809 mm.
The lateral length L22 of the gaming machine frame 2000 is, for example, 520 mm.
The length L23 of the thickness of the inner frame of the gaming machine frame 2000 is, for example, 91 mm.
The length L24 of the protruding portion at the rear of the gaming machine frame 2000 is, for example, 196 mm.
The length L25 of the front protruding portion of the gaming machine frame 2000 is, for example, 191.5 mm.

FIG. 241 is a diagram showing the dimensions of the discharge passage.
The dimensions of the discharge passage of the game ball discharged from the game board are as follows.
The lateral length L31 of the winning opening passage 2001 and the non-winning opening passage 2002 is, for example, 233 mm.
The length L32 of the winning opening passage 2001 and the non-winning opening passage 2002 in the front-rear direction is, for example, 13 mm.

[2.2 New functions]
[(1) Return ball detection]
FIG. 242 is a diagram showing a mechanism for detecting a return ball.
The ball that was launched from the launching unit 2003 of the launcher 2004 but returned to the launcher 2004 by the foul is collected on the back side by the collection hole 2005, detected by the foul ball sensor 2006, and displayed on the number of game balls, etc. It is added to the displayed value. The arrow A1 is the launch ball route, and the arrow A2 is the foul ball route.

[(2) Power cutoff (measures for inserting and removing the live wire of the game board)]
FIG. 243 is a diagram showing a mechanism for shutting off the power supply.
When the veneer holding down the game board 8b is released (F1), the power cutoff switch is activated (F2), and all power is cut off (F3).

[(3) Without ball]
FIG. 244 is a diagram showing a mechanism for removing balls.
In the absence of the game board, the launch cover 2007 closes the launch port 2008. If the ball is fired in this state, all the balls flow into the foul ball passage, and the processing time at the time of ball removal can be shortened. When the ball is pulled out, the game ball in the game machine flows into the ball receiver 2010 by moving the ball pulling lever 2009 to fire the ball.

[(4) Speaker]
FIG. 245 is a diagram showing a speaker.
The speaker 2011 is equipped with a total of three speakers, two at the top and one at the bottom. The impedance of the speaker 2011 is 8Ω.

[2.3 maintenance]
[(1) Launcher]
FIG. 246 is a diagram showing a launcher.
The launcher 2004 can open the cover 2012 and clean the tip of the launcher 2003 (pestle) from the opening 2014 near the tip of the launcher 2003 (pestle).

[(2) Polishing machine]
FIG. 247 is a diagram showing a polishing machine.
When the cover 2012 of the launcher 2004 is opened and the polishing lever 2015 is pulled up, the polishing agent 2016 can be taken out. A replacement material 2017 is attached to the abrasive 2016 with a single touch. The replacement material 2017 can be used a total of four times by refitting the upper and lower parts and refitting the front and back sides.

[(3) Iron ball detection]
FIG. 248 is a diagram showing a mechanism of iron ball detection.
A magnet is mounted inside the ball pulling lever 2009 to attract iron balls. When detecting an iron ball, the ball pulling lever 2009 is moved to remove it. The game balls aligned upstream from the magnet flow into the ball receiver 2010.

[Chapter 3]
[Specifications of the interface between the main control board and the frame control board]
[1. Glossary〕
The terms used in this chapter are explained below.

[No1]
The managed gaming machine is a gaming machine having a function of being able to output various information of the gaming machine to the gaming machine information center (hereinafter, may be simply referred to as a gaming machine).

[No2]
The main control CPU is a CPU mounted on the main control board of the gaming machine (hereinafter, may be simply referred to as main control).

[No3]
The frame control CPU is a CPU mounted on a frame control board of a gaming machine (hereinafter, may be simply referred to as frame control).

[No4]
The dedicated unit is a unit dedicated to a gaming machine.

[No5]
The dedicated unit main substrate is the main substrate of the dedicated unit (hereinafter, may be referred to as DM (Dedicated unit Main Substrate)).

[No6]
The control microcomputer is a dedicated unit control CPU (hereinafter, may be referred to as a DC (Dedicated unit control CPU)).

[No7]
The CM board (Communication security monitoring) is a security monitoring board mounted on the DM for communicating with the gaming machine and communicating with the gaming machine information center via the DM.

[No8]
The CM microcomputer is a security microcomputer mounted on a CM board (hereinafter, may be referred to as CM).

[No9]
The dedicated interface is an interface for defining communication specifications between the gaming machine and the dedicated unit.

[No10]
The gaming machine information center is a center that collects various information output from the gaming machine.

[No11]
The card company data center is a card company center connected to the gaming machine information center (hereinafter, may be referred to as a company center).

[No12]
The management computer is a computer that connects to a dedicated unit.

[No13]
A hall computer is a computer that collects various types of information output from a hall computer output BOX (hereinafter, may be referred to as HC).

[No14]
The Hallcon output BOX is a serial / pulse conversion device for outputting various information to the HC by connecting to a dedicated unit (hereinafter, may be referred to as an HC BOX).

[No15]
The main control chip ID number is the main control chip ID number of the gaming machine. The ID number has a different name depending on the manufacturer. For example, the name of the V5 generation chip may be a chip individual number or a chip code. The name of the V6 generation chip is an ID number.

[No16]
The frame control chip ID number is a frame control chip ID number of the gaming machine. The ID number has a different name depending on the manufacturer. For example, the name of the V5 generation chip may be a chip individual number or a chip code. The name of the V6 generation chip is an ID number.

[No17]
The number of gaming balls is the number of balls that can be launched by a gaming machine.

[No18]
The number of counting balls is the number of counting balls transmitted by the gaming machine.

[No19]
The number of rented balls is the number of rented balls transmitted by the dedicated unit.

[No20]
The number of balls held is the number of counting balls received by the dedicated unit and the number of balls managed by the card company.

[No21]
The gaming machine information is a general term for gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information.

[No22]
The gaming machine installation information is a gaming machine type, a main / frame control maker code, a product code, and a chip ID number.

[No23]
The gaming machine performance information is the number of game balls acquired per minute (base), the bonus ratio, the continuous bonus ratio, and the like.

[No24]
The hall control information includes big hits, probability fluctuations, shortening of fluctuation time, number of winning balls in each winning opening, and the like.

[No25]
The fraud monitoring information is information indicating the fraud detection state 1.

[No26]
The error information is information indicating a gaming machine error state.

[2. Scope of application〕
The configuration shown below is applicable to the specifications of the interface between the main control board and the frame control board (see A in FIG. 249).

[3. System Configuration〕
FIG. 249 is a diagram showing a system configuration diagram of the managed gaming machine.
The double line in the figure indicates the hard interface, and the solid line indicates the soft interface (communication telegram).

[Hard interface]
The gaming machine information center 3010, each company's center 3020, the management computer 3030, the dedicated unit 3040, the HCBOX3090, and the HC3100 are connected by a hard interface.
The dedicated unit 3040 and the gaming machine 3120 are connected by a hard interface.

The dedicated unit 3040 includes a DM3050.
The DM3050 includes a CM substrate 3070 having a DC3060 and a CM3072, and a dedicated circuit 3080.
The DC3060, CM3072, and dedicated circuit 3080 are connected by a hard interface.

The gaming machine 3120 includes a counting switch 3130, a dedicated circuit 3140, a frame control 3150, and a main control 3160.
The counting switch 3130, the dedicated circuit 3140, the frame control 3150, and the main control 3160 are connected by a hard interface.
The dedicated unit 3040 and the gaming machine 3120 are connected by a hard interface using a dedicated cable 3110 for connecting the dedicated circuit 3080 and the dedicated circuit 3140.

[Soft interface]
The management computer 3030, each company center 3020, and the gaming machine information center 3010 are connected by a software interface.
The management computer 3030 and the dedicated unit 3040 are connected by a soft interface.
The DC3060, HCBOX3090, and CM3072 are connected to the dedicated circuit 3080, the dedicated circuit 3140, the frame control 3150, and the main control 3160 by a soft interface.

[4. Overview〕
The interface between the main control board and the frame control board communicates the game machine installation information and the game machine information by the telegram method with the asynchronous serial port.
The gaming machine installation information is transmitted by one telegram when the power is turned on, with the gaming machine type, main control chip ID number, maker code, and product code.
As for the gaming machine information, hall control information, fraud monitoring information, and information for calculating the gaming machine performance are transmitted in one telegram at regular intervals.

[5. Communication conditions]
FIG. 250 is a diagram showing communication conditions.
The communication speed is 31250 bps.
The bit configuration is "start bit: 1", "data bit: 8", "stop bit: 1", and "parity: none".
The communication method is asynchronous serial communication.
The communication control is full-duplex communication, and the communication cycle is 108 ms.

[6. Data structure]
FIG. 251 is a diagram showing an outline of a data structure.
"Telegram length", "command", "serial number", "data section", and "checksum" are arranged in order from the beginning of the data. The telegram range is from the beginning to the end of the data.
It is preferable that the telegram is always completed in one frame and not divided and transmitted.
If the "checksum" cannot be received within 20 ms after receiving the "telegram length", the received data up to that point is canceled and the data is received from the "telegram length" again.

FIG. 252 is a diagram showing details of the data structure.
[No1]
Name: Telegram length Data length: 1 byte Data format: HEX (hexadecimal)
Meaning: Telegram length from telegram length to checksum (range: 5 to 25)

[No2]
Name: Command Data length: 1 byte Data format: HEX (hexadecimal)
Meaning: Telegram command code

[No3]
Name: Serial number Data length: 1 byte Data format: HEX (hexadecimal)
Meaning: Meaning a communication serial number. It is a serial number sequence number (range: 0 to 255 (cyclic)).

[No4]
Name: Data part Data length: 1-21 bytes Data format: HEX (hexadecimal)
Meaning: Telegram data

[No5]
Name: Checksum Data length: 1 byte Data format: HEX (hexadecimal)
Meaning: The result of adding from the telegram length to the data part

[6.1. Byte order between main control board and frame control board]
The byte order in this chapter defines B as big endian and L as little endian.

[7. Business message between main control board and frame control board]
[7.1. List of messages between main control board and frame control board]
FIG. 253 is a diagram showing a list of messages between the main control board and the frame control board.
[No1]
Telegram name: Game machine installation information notification Transmission direction: Main control board → Frame control board Command: 0x01
Summary: Notify game machine installation information.

[No2]
Telegram name: Game machine installation information response Transmission direction: Frame control board → Main control board Command: 0x11
Summary: Respond to the result of receiving game machine installation information.

[No3]
Telegram name: Game machine information notification Transmission direction: Main control board → Frame control board Command: 0x02
Summary: Notify game machine information.

[No4]
Telegram name: Game machine information response Transmission direction: Frame control board → Main control board Command: 0x12
Summary: Respond to the game machine information reception result and the frame control status.

[7.2. Details of telegram between main control board and frame control board]
[7.2.1. Notification of game machine installation information]
FIG. 254 is a diagram showing details of the gaming machine installation information notification.
Telegram name: Notification of gaming machine installation information Telegram direction: Main control board → Frame control board Telegram outline: The main control board notifies the frame control board of game machine installation information.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x19

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x01

[No3]
Data name: Communication serial number Data length: 1 byte Byte order:-
Contents: Fixed to 0

[No4]
Data name: Game machine type of game machine installation information Data length: 1 byte Byte order:-
Contents: (Note 1)

[No5]
Data name: Main control chip ID number of game machine installation information Data length: 9 bytes Byte order: B
Contents: (Note 2)

[No6]
Data name: Main control chip manufacturer code of game machine installation information Data length: 3 bytes Byte order: B
Contents: Manufacturer code written in the control area of the main control chip

[No7]
Data name: Main control chip for game machine installation information Product code Data length: 8 bytes Bytes Order: B
Contents: Product code written in the control area of the main control chip

[No8]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[7.2.1.1. Notification processing when the power is turned on]
The main control board notifies the gaming machine installation information when the power is turned on. It should be noted that the main control board disables normal games until it receives a game machine installation information response.

[About the behavior when the command of the main control board → frame control board is not a normal value due to noise influence etc.]
Examples of cases where the value is not normal include the following cases.
(1) When the content of the game machine type of the "game machine installation information notification" transmitted from the main control board to the frame control board indicates a spare (bits 4 to 6 are spare values of 2 to 7). If, if bits 0 to 3 are spare values of 5 to 15)
(2) When a value is entered in the unused part (bit7 in the main control state 1, bits 3 to 7 in the main control state 2, etc.) of the "game machine information notification" transmitted from the main control board to the frame control board ( 3) In the "game machine information notification" transmitted from the main control board to the frame control board, the main control state 1 indicates that the jackpot is in progress, but the main control state 2 does not indicate the jackpot in the middle + time reduction. If you receive a command that is not taken

In the above cases (1) to (3), the frame control board executes the same behavior as in the normal state. The game machine information receipt result of the "game machine information response" is also transmitted to the main control board with the value of "0x00 = receipt OK".
As a result, it is possible to prevent the command content check from being executed on the frame control board side, and it is possible to reduce the processing load on the frame control board.

Further, even if the frame control board side receives the above-mentioned erroneous command from the main control board, the frame control board transmits the gaming machine status notification from the frame control board to the CM based on the contents.
For example, as shown in (1) above, when the content of the gaming machine type of the "gaming machine installation information notification" transmitted from the main control board to the frame control board indicates a spare (bits 4 to 6 are 2). When the spare value of ~ 7 is set, when bits 0 to 3 are the spare value of 5 to 15), the contents of the gaming machine type of "game machine information notification" sent from the frame control board to the CM. Is also the content indicating the reserve (bits 4 to 6 are the reserve values of 2 to 7, and bits 0 to 3 are the reserve values of 5 to 15).
As a result, it is possible to leave the judgment of the inconsistency of the command contents to the CM side where the processing capacity is not specified (limit, upper limit).

FIG. 255 is a diagram showing (Note 1) a code system (1 byte) of a gaming machine type.
Bit7: Management medium (0 = game ball, 1 = game medal)
Bit6 to Bit4: Group classification (0 = A union, 1 = B union, 2-7 = reserve)
Bit3 to Bit0: Game machine type (1 = pachinko game machine, 2 = rotating body type game machine, 3 = arrange ball game machine, 4 = Jiyan ball game machine, 5 to 15 = spare, 0 = unused)

FIG. 256 is a diagram showing an example of a gaming machine type list.
Code: 0x01
Game machine: Pachinko game machine Group: A union Management medium: Game ball

Code: 0x82
Pachinko machine: Revolving pachinko machine Group: A union Management medium: Pachinko medal

Code: 0x83
Game machine: Arrange ball game machine Group: A union Management medium: Game medal

Code: 0x84
Game machine: Jiyan ball game machine Group: A union Management medium: Game medal

Code: 0x92
Pachinko machine: Revolving pachinko machine Group: B union Management medium: Pachinko medal

FIG. 257 is a diagram showing (Note 2) a method of generating the main control chip ID number (in the case of the first chip).
The individual chip numbers of the CPU are read in ascending order of address.
The upper 4 bytes of this number are padded with 0, and an identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip individual number is 0x12345678, 0 padding is 4 bytes (0x00000000000), the chip individual number is 4 bytes (0x12345678), and the identification code (*) is 1 byte (0x21).

FIG. 258 is a diagram showing (Note 2) a method of generating the main control chip ID number (in the case of the second chip).
The CPU chip code is read from the youngest address.
The upper 4 bytes of this code are padded with 0, and the identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip code is 0x34567812, 0 padding is 4 bytes (0x00000000000), the chip code is 4 bytes (0x34567812), and the identification code (*) is 1 byte (0x41).

FIG. 259 is a diagram showing an identification code of the (*) main control chip ID number.
The identification code is 1 byte.
The CPU maker identifies by Bits 5 to 7.
The CPU type is identified by Bits 0 to 4.
When Bits 5 to 7 are "1", the CPU maker is the "first maker".
When Bits 5 to 7 are "2", the CPU maker is "second maker".
When Bits 5 to 7 are "3 to 7, 0", it is unused and is a spare.

When Bits 5 to 7 are "1" and Bits 0 to 4 are "1", the CPU type is "first chip".
When Bits 5 to 7 are "1" and Bits 0 to 4 are "2 to 31, 0", it is unused and is a spare.

When Bits 5 to 7 are "2" and Bits 0 to 4 are "1", the CPU type is "second chip A".
When Bits 5 to 7 are "2" and Bits 0 to 4 are "2", the CPU type is "second chip B".
When Bits 5 to 7 are "2" and Bits 0 to 4 are "3", the CPU type is "second chip C".
When Bits 5 to 7 are "2" and Bits 0 to 4 are "4 to 31, 0", it is unused and is a spare.

When Bits 5 to 7 are "3 to 7" and Bits 0 to 4 are "1 to 3, 0", it is unused and is a spare.
Bits 5 to 7 = 0 and Bits 0 to 4 = 0 are unused.

[7.2.2.2. Game machine installation information response]
FIG. 260 is a diagram showing details of the gaming machine installation information response.
Telegram name: Game machine installation information response Telegram direction: Frame control board → Main control board Telegram outline: The frame control board responds to the main control board with the receipt result of the game machine installation information notification.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x05

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x11

[No3]
Data name: Communication serial number Data length: 1 byte Byte order:-
Contents: Fixed to 0. (* Note 1) The frame control board responds as it is to the communication serial number received in the game machine installation information notification. If a communication serial number other than 0 is received, no response is given.

[No4]
Data name: Game machine installation information reception result Data length: 1 byte Byte order:-
Contents: Receipt result. 0x00 = receipt OK, 0x01 = ball-free state.

[No5]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: The result of addition from the telegram length to the data part

[7.2.3. Game machine information notification]
261 and 262 are diagrams showing details of the gaming machine information notification.
Telegram name: Game machine information notification Telegram direction: Main control board → Frame control board Telegram outline: The main control board notifies the frame control board of game machine information (hall control information, fraud monitoring information). The gaming machine information notification can be transmitted at the time of setting confirmation (during setting confirmation). As a result, the backed up information about the prize balls and the like is transmitted from the main control board to the frame control board at the time of setting confirmation (during setting confirmation).

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x09 ~ 0x13

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x02

[No3]
Data name: Communication serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0 to 255) (Note 1)

[No4]
Data name: Main control state 1 (Note 2)
Data length: 1 byte Byte order:-
Contents: Bit0: jackpot 1, Bit1: jackpot 2, Bit2: jackpot 3, Bit3: gaming machine status signal 1, Bit4: gaming machine status signal 2, Bit5: gaming machine status signal 3, Bit6: gaming machine status signal 4, Bit7 :unused.

[No5]
Data name: Main control state 2 (Note 3)
Data length: 1 byte Byte order:-
Contents: Bit0: During big hit + time saving (shortening fluctuation time) or in advantageous state, Bit1: High probability, Bit2: Shortening time (shortening fluctuation time) or in advantageous state, Bit3: Unused, Bit4: Unused, Bit5: Unused, Bit6: Unused, Bit7: Unused.

[No6]
Data name: Game machine error status Data length: 1 byte Byte order:-
Description: Error code occurring on the gaming machine. Bit0-5: Error code (000000 (B) = No error), Bit6: 0 = Frame control, 1 = Main control, Bit7: 0 = Notification only, 1 = Notification + Hall control output, Bit0-7: 0 = No error has occurred.

[No7]
Data name: Fraud detection status 1 (Note 4)
Data length: 1 byte Byte order:-
Contents: Bit0: Setting changing signal, Bit1: Setting confirmation signal, Bit2: RWM clear signal, Bit3: Fraud detection signal 1, Bit4: Fraud detection signal 2, Bit5: Fraud detection signal 3, Bit6: Unused, Bit7: unused.

[No8]
Data name: Number of game information in game information (Note 5) Data length: 1 byte Byte order:-
Contents: Number of type information / count information (n), n = 0 to 5 (variable length)

[No9]
Data name: Game information type information 1
Data length: 1 byte Byte order:-
Contents: Type information 1

[No10]
Data name: Game information count information 1
Data length: 1 byte Byte order:-
Contents: Count 1

[No11]
Data name: Game information type information n
Data length: 1 byte Byte order:-
Contents: Type information n

[No12]
Data name: Game information count information n
Data length: 1 byte Byte order:-
Contents: Count information n

[No13]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: The result of addition from the telegram length to the data part

(Note 1) Communication serial number The main control board adds 1 to the communication serial number when the gaming machine information is notified. The communication serial number is set to 0 after 255.

FIG. 263 is a diagram showing (Note 2) main control state 1.
(Note 2) The main control state 1 is as follows.
Bit: 0
Name: Big hit 1
Details: Set "1" to 1 jackpot information, during the jackpot to be notified (during the jackpot that clearly notifies that the jackpot is being hit, during the predetermined jackpot)

Bit: 1
Name: Big hit 2
Details: 2 jackpot information, set "1" in all jackpots

Bit: 2
Name: Big hit 3
Details: Set "1" during jackpot 3 information, time reduction (shortening fluctuation time) or jackpot to shift to advantageous state

Bit: 3
Name: Pachinko machine status signal 1 (* 1)
Details: Set "1" while the gaming machine status signal and gaming machine status signal 1 are ON.

Bit: 4
Name: Pachinko machine status signal 2 (* 1)
Details: Set "1" while the gaming machine status signal and gaming machine status signal 2 are ON.

Bit: 5
Name: Pachinko machine status signal 3 (* 1)
Details: Set "1" while the gaming machine status signal and gaming machine status signal 3 are ON.

Bit: 6
Name: Game machine status signal 4 (* 1)
Details: Set "1" while the gaming machine status signal and gaming machine status signal 4 are ON.

Bit: 7
Name: Unused Details: Fixed to 0

(* 1) The gaming machine status signal is used to output the status from the extended external terminal board of the dedicated unit. Further, the gaming machine status signals 1 to 4 correspond to "external terminal plate status output signal terminals 1 to 4" output from the extended external terminal plate of the dedicated unit.

FIG. 264 is a diagram showing (Note 3) main control state 2.
(Note 3) The main control state 2 is as follows.
Bit: 0
Name: Big hit + time saving (shortening fluctuation time) or advantageous state Details: Game status information, big hit, and setting "1" during time saving (shortening fluctuation time) or advantageous state

Bit: 1
Name: High probability Medium (* 2)
Details: Game status information, set "1" during high probability

Bit: 2
Name: During time reduction (shortening fluctuation time) or in advantageous state Details: Set "1" during game status information, time reduction (shortening fluctuation time) or advantageous state

Bit: 3-7
Name: Unused Details: Fixed to 0 (* 2) Not output for gaming machines that do not notify that the probability fluctuation function is operating.

FIG. 265 is a diagram showing a fraud detection state (Note 4).
(Note 4) The fraud detection status is as follows.
Bit: 0
Name: Setting changing signal (* 1)
Details: Indicates that the settings are being changed. 0 = Normal, 1 = Setting is being changed.

Bit: 1
Name: Setting confirmation signal (* 1)
Details: Indicates that the settings are being confirmed. 0 = normal, 1 = setting is being confirmed.

Bit: 2
Name: RWM (RAM) clear signal Details: Indicates that the RWM has been initialized. 0 = normal, 1 = RWM clear occurred.

The main control board can hold the RWM clear signal information (Bit2 information) until the power is turned off. As a result, the processing load and the program capacity of the main control board can be reduced.

Bit: 3
Name: Fraud detection signal 1 (* 2)
Details: In addition to the above, it indicates that there is a risk of fraud. (Urgent degree: weak) (* 3) 0 = normal, 1 = abnormal occurrence.

Bit: 4
Name: Fraud detection signal 2 (* 2)
Details: In addition to the above, it indicates that there is a risk of fraud. (Urgent degree: Medium) (* 3) 0 = normal, 1 = abnormal occurrence.

Bit: 5
Name: Fraud detection signal 3 (* 2)
Details: In addition to the above, it indicates that there is a risk of fraud. (Urgent degree: strong) (* 3) 0 = normal, 1 = abnormal occurrence.

Bit: 6-7
Name: Unused Details: Fixed to 0

(* 1) The frame control board stores the signal, keeps the signal on until firing or counting, and then turns off the signal in 30 seconds.
(* 2) The content of fraud detected differs depending on the type of gaming machine. Also, it is limited to gaming machines that have a function to detect various frauds.
(* 3) Since the urgency level is the level notified by the machine history server, it is output as "weak", "medium", and "strong" in order from the lightest as fraudulent.

[About the contents of fraud detection signals 1, 2 and 3]
The fraud detection signals 1, 2, and 3 can correspond to the following information, for example.
(1) Fraud detection signal 1 (urgency: weak)
Unauthorized prize (winning when the normal electric accessory is not open, prize when the special electric accessory is not open)
Vibration error (weak because it may occur unintentionally)

(2) Fraud detection signal 2 (urgency: medium)
Radio wave error, abnormal passage in probabilistic area

(3) Fraud detection signal 3 (urgency: strong)
Game impossible state (RWM abnormality, set value abnormality (for example, when the set value is 7 or more))

FIG. 266 is a diagram showing details of (Note 5) game information.
The game information notifies the frame control board of the starting opening prize, the large winning opening winning, the number of times the symbol is confirmed, etc. generated on the main control board. The details of the game information are shown below.
The game information (2 bytes) is composed of (1) type information (upper 1 byte) and (2) count information (lower 1 byte), for a total of 2 bytes.

[(1) Type information]
FIG. 267 is a diagram showing details of type information.
The type information (1 byte) is composed of a data type (upper 4 bits, Bits 4 to 7) and a data number (lower 4 bits, Bits 0 to 3), and a data number is set for each data type.

FIG. 268 is a diagram showing details of the data type of the type information.
The data types (Bits 4 to 7) of the type information are as follows.
Bit 4-7: 0
Type name: Unused Contents:-

Bit 4-7: 1
Type name: Start-up opening prize Contents: Notify that the start-up opening has won a prize.

Bit 4-7: 2
Type name: Special electric accessory operation to win a big prize opening Contents: Notify that a prize has been won in the big prize opening.

Bit 4-7: 3
Type name: Winning opening Winning content: Notify that the winning opening has won a prize.

Bit 4-7: 4
Type name: Passing through the gate or winning a prize at the normal operation port Contents: Notifying that the player has passed through the gate or winning a prize at the normal drawing operation port.

Bit 4-7: 5
Type name: Start opening prize by operating ordinary electric accessory Contents: Notify that the starting port has won by operating ordinary electric accessory.

Bit 4-7: 6
Type name: Grand prize opening by operating the character continuous operation device Contents: Notifies that the prize has been won to the large prize opening by operating the character continuous operation device.

Bit 4-7: 7
Type name: Winning by operating the ordinary electric accessory Contents: Notifying the winning opening by operating the ordinary electric accessory.

Bit 4-7: 8
Type name: Other prizes due to the operation of the accessory Contents: Notify the winning opening by the operation of the non-electric accessory.

Bit 4-7: 9
Type name: Number of times the symbol is confirmed Contents: Notifies the number of changes of the special symbol or the normal symbol.

Bit 4-7: 10
Type name: Per special symbol Contents: Notifies that the special electric accessory is activated when the accessory continuous operation device is activated or the accessory continuous operation device is not activated.

Bit 4-7: 11
Type name: Normal symbol hit Contents: Normal symbol hit is notified.

Bit 4-7: 12
Type name: Number of characters (number of times the large winning opening is opened)
Contents: Notifies the opening of the big prize opening when the accessory continuous operation device is not operating.

Bit 4-7: 13
Type name: Passing through a specific area Contents: Notifying that the game ball has passed through a specific area.

Bit 4-7: 14
Type name: External terminal board Pulse output Contents: Instructs pulse output from the dedicated unit.

Bit 4-7: 15
Type name: Performance information status notification Contents: Notifies the status required for the frame control board to calculate performance information.

[About the priority of the data type of the gaming machine information notification]
For the data types 0 to 15 of Bits 4 to 7 in FIG. 268, the priority of transmission when information is stored at the same time may be set in advance.
The priorities are, for example, in the following order.
"15 (performance information status notification)">"1 (starting opening prize)">"2 (large winning opening winning due to special electric accessory operation)">"3 (winning opening winning)">>...>"14 (External terminal plate pulse output) "

Therefore, for example, when the starting port winning is generated 5 times, the winning opening is won twice, and the information that the normal symbol hit is also generated once is memorized, and if the power is cut off and returned, one gaming machine When sending information notifications
(15) Performance information status notification (1) Starting opening prize (1) Starting opening winning (1) Starting opening winning (1) Starting opening winning, etc., a game machine information notification including five data types is transmitted. .. In this example, the upper limit of the data type included in one transmission of the game status notification is five.

In addition, the remaining information is transmitted in the subsequent game machine information notification. In this case,
(1) Starting slot winning (3) Winning slot winning (3) Winning slot winning (11) Ordinary symbol hit The game machine information notification including the remaining four data types is transmitted.
Therefore, when the power is restored and when the gaming state is switched (for example, when shifting from the normal gaming state to the jackpot gaming state, when shifting from the high probability state to the low probability state, the time shortening state shifts to the non-time shortening state. In the case, etc.), the data type of the gaming machine information notification is always (15) the performance information status notification is transmitted first.

269 and 270 are diagrams showing data numbers of type information.
The data numbers (Bits 0 to 3) of the type information are as follows.
The type information (1 byte) includes a data type (Bits 4 to 7; type name) and a data number (Bits 0 to 3; contents).

Bit 4-7: 1
Type name: Starting port winning content: Indicates the starting port number. 1 = Starting port 1, 2 = Starting port 2, 3 = Starting port 3, 4 = Starting port by operating other accessories 1, 5 = Starting port by operating other accessories 2, 6 = Starting port by operating other accessories 3 , 0 and 7 to 15 are unused.

Bit 4-7: 2
Type name: Grand prize opening by operating a special electric accessory Contents: Indicates the large winning opening number. 1 = Large winning openings 1, 2 = Large winning openings 2, 0 and 3 to 15 are unused.

Bit 4-7: 3
Type name: Winning opening Winning content: Indicates the winning opening number. 1 to 15 = Winning openings 1 to 15, 0 are unused.

Bit 4-7: 4
Type name: Passing through the gate or winning a prize at the operating port of the general map Contents: Indicates the passing gate number or operating port number of the general map. 1 to 15 = Passing gates or normal operation ports 1 to 15, 0 are unused.

Bit 4-7: 5
Type name: Start opening prize by operating ordinary electric accessory Contents: Indicates the starting opening number. 1 = Starting port 1, 2 = Starting port 2, 3 = Starting port 3, 0 and 4 to 15 are unused.

Bit 4-7: 6
Type name: Grand prize opening by operating the accessory continuous operation device Contents: Indicates the large winning opening number. 1 = Large winning openings 1, 2 = Large winning openings 2, 0 and 3 to 15 are unused.

Bit 4-7: 7
Type name: Winning by operating ordinary electric accessory Contents: Shows the winning opening number. 1 to 15 = Winning openings 1 to 15, 0 are unused.

Bit 4-7: 8
Type name: Other prizes due to the operation of the accessory Contents: Shows the winning opening number. 1 to 15 = Winning openings 1 to 15, 0 are unused.

Bit 4-7: 9
Type name: Number of symbol confirmations Contents: Indicates the special figure number and normal figure number. 1 = special figure 1, 2 = special figure 2, 3 = normal figure 1, 4 = normal figure 2, 5 = normal figure 3, 6 = normal figure 4, 0 and 7 to 15 are unused.

Bit 4-7: 10
Type name: Per special symbol Contents: Per special symbol Indicates the type. 1 = The accessory continuous operation device is activated (big hit), 2 = The special electric accessory is activated when the accessory continuous operation device is not activated (small hit), and 0 and 3 to 15 are unused.

Bit 4-7: 11
Type name: Ordinary symbol per content: Per ordinary symbol number is shown. 1 = Fu-figure 1, 2 = Fu-figure 2, 3 = Fu-figure 3, 4 = Fu-figure 4, 0 and 5-15 are unused.

Bit 4-7: 12
Type name: Number of characters (number of times the large winning opening is opened)
Contents: Indicates the character number. 1 = Characters 1, 0 and 2 to 15 are unused.

Bit 4-7: 13
Type name: Passing through a specific area Contents: 1 = Specific areas 1, 0 and 2 to 15 are unused.

Bit 4-7: 14
Type name: External terminal board pulse output Contents: Indicates the external terminal board pulse output signal terminal of the dedicated unit (* 1).

Bit 4-7: 15
Type name: Performance information Status notification Contents: 1 fixed, 0 and 2 to 15 are unused.

FIG. 271 is a diagram showing (* 1) data numbers of external terminal board pulse outputs.
The external terminal board pulse output is used to instruct the pulse output from the extended external terminal board of the dedicated unit, and the output signal terminal of the dedicated unit is specified by the data number.
The data number and output signal terminal are as follows.

The type information includes a data type (Bits 4 to 7) and a data number (Bits 0 to 3).
Data type (Bit4 to 7): External terminal board pulse output (Bit4 to 7 = 14)
Data number (Bit0 to 3): 0
Dedicated unit External terminal board Pulse output signal terminal: Unused

Data type (Bit4 to 7): External terminal board pulse output (Bit4 to 7 = 14)
Data number (Bit0-3): 1
Dedicated unit External terminal plate Pulse output signal terminal: External terminal plate Pulse output signal terminal 1

Data type (Bit4 to 7): External terminal board pulse output (Bit4 to 7 = 14)
Data number (Bit0-3): 2
Dedicated unit External terminal plate Pulse output signal terminal: External terminal plate Pulse output signal terminal 2

Data type (Bit4 to 7): External terminal board pulse output (Bit4 to 7 = 14)
Data number (Bit0-3): 3
Dedicated unit External terminal plate Pulse output signal terminal: External terminal plate Pulse output signal terminal 3

Data type (Bit4 to 7): External terminal board pulse output (Bit4 to 7 = 14)
Data number (Bit0-3): 4
Dedicated unit External terminal plate Pulse output signal terminal: External terminal plate Pulse output signal terminal 4

Data type (Bit4 to 7): External terminal board pulse output (Bit4 to 7 = 14)
Data number (Bit0-3): 5-15
Dedicated unit External terminal board Pulse output signal terminal: Unused

[(2) Count information]
As the count information, different number of times information is set for each data type.
The details of the count information and the data storage example for each data type are shown below.

(A) Data type is 1 = Starting opening prize, 2 = Large winning opening prize by operating special electric accessory, 3 = Winning opening winning, 4 = Gate passing or normal drawing operating opening winning, 5 = By operating ordinary electric accessory In the case of starting opening prize, 6 = large winning opening prize by operating the accessory continuous operation device, 7 = winning by operating the ordinary electric accessory, 8 = winning by operating other accessories Figure 272 is a diagram showing the details of the count information. is there.
The count information is composed of the number of prize balls (top 4 Bits, Bits 4 to 7) and the number of prizes (bottom 4 Bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is 1 to 15 (pieces). 4 = The number of prize balls is set to 0 when passing through the gate. In addition, the number of prize balls is 1 to 15 (pieces) for winning the prize in the normal drawing operation port.
The number of winnings (Bits 0 to 3) is 1 (pieces), and 0 and 2 to 15 are unused.

FIG. 273 is a diagram showing an example in which two prizes are won in the start opening 1 of three prize balls in (Example 1) 1 = starting opening winning.
Game information: 0x1131
Data type of type information (1 byte) (Bit4 to 7): 1 = Start port Data number of type information (1 byte) (Bit0 to 3): 1 = Start port 1
Number of prize balls (Bit4 to 7) of count information (1 byte): 3 = 3 prize balls Number of prizes of count information (1 byte) (Bit0-3): 1 = 1 prize

Game information: 0x1131
Data type of type information (1 byte) (Bit4 to 7): 1 = Start port Data number of type information (1 byte) (Bit0 to 3): 1 = Start port 1
Number of prize balls (Bit4 to 7) in count information (1 byte): 3 = 3 prize balls Number of prizes in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x1131 is 2. It becomes data.

FIG. 274 is a diagram showing an example in which (Example 2) 2 = a large prize opening by operating a special electric accessory, and three prizes are won in the large winning opening 2 of 15 prize balls.

Game information: 0x22F1
Type information (1 byte) data type (Bit4-7): 2 = Grand prize opening Type information (1 byte) data number (Bit0-3): 2 = Large winning opening 2
Number of prize balls (Bit4 to 7) of count information (1 byte): 15 = 15 prize balls Number of prize balls of count information (1 byte) (Bit0-3): 1 = 1 prize

Game information: 0x22F1
Type information (1 byte) data type (Bit4-7): 2 = Grand prize opening Type information (1 byte) data number (Bit0-3): 2 = Large winning opening 2
Number of prize balls (Bit4 to 7) of count information (1 byte): 15 = 15 prize balls Number of prize balls of count information (1 byte) (Bit0-3): 1 = 1 prize

Game information: 0x22F1
Type information (1 byte) data type (Bit4-7): 2 = Grand prize opening Type information (1 byte) data number (Bit0-3): 2 = Large winning opening 2
Number of prize balls (Bit4 to 7) in count information (1 byte): 15 = 15 prize balls Number of prizes in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x22F1 is 3 It becomes data.

FIG. 275 is a diagram showing an example in which one prize is won in the winning opening 2 of one winning ball in (Example 3) 3 = winning opening winning.
Game information: 0x3211
Data type of type information (1 byte) (Bit4 to 7): 3 = Winning slot Data number of type information (1 byte) (Bit0 to 3): 2 = Winning slot 2
Number of prize balls in count information (1 byte) (Bit4 to 7): 1 = 1 prize balls Number of prize balls in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x3211 is 1 It becomes data.

FIG. 276 is a diagram showing an example in the case where (Example 4) 4 = passing through the gate, passing through the passing gate 1 once.
Game information: 0x4101
Data type of type information (1 byte) (Bit4 to 7): 4 = Gate passage or general drawing operation opening prize Type information (1 byte) data number (Bit0-3): 1 = Passing gate 1
Number of prize balls (Bit4 to 7) in count information (1 byte): 0 = 0 Number of prize balls in count information (1 byte) (Bit0-3): 1 = 1 times Passed in game information 0x4101 is 1 It becomes data.

FIG. 277 is a diagram showing an example in which one prize is won in the normal drawing operating opening 2 of three prize balls in (Example 5) 4 = normal drawing operating opening winning.
Game information: 0x4231
Type information (1 byte) data Type (Bit 4 to 7): 4 = Gate passage or general figure operation port winning Type information (1 byte) data number (Bit 0 to 3): 2 = Operation port 2
Number of prize balls (Bit4 to 7) in count information (1 byte): 3 = 3 prize balls Number of prizes in count information (1 byte) (Bit0-3): 1 = 1 prize 0x4231 is 1 for game information It becomes data.

FIG. 278 is a diagram showing an example in the case where (Example 6) 5 = starting opening winning by operating the ordinary electric accessory, one winning in the winning opening of three prize balls by operating the ordinary electric accessory.
Game information: 0x5131
Type information (1 byte) data Type (Bit 4 to 7): 5 = Start opening prize by operating ordinary electric accessory Type data (1 byte) data number (Bit 0-3): 1 = Start port 1
Number of prize balls (Bit4 to 7) in count information (1 byte): 3 = 3 prize balls Number of prizes in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x5131 is 1 It becomes data.

FIG. 279 is a diagram showing an example in which (Example 7) 6 = a large prize opening prize by operating the accessory continuous operating device, one prize is won in the large winning opening 1 of 15 prize balls by operating the accessory continuous operating device. Is.
Game information: 0x61F1
Type information (1 byte) data Type (Bit4 to 7): 6 = Grand prize opening by operating the accessory continuous operation device Winning prize of type information (1 byte) Data number (Bit0 to 3): 1 = Large winning opening 1
Number of prize balls (Bit4 to 7) of count information (1 byte): 15 = 15 prize balls Number of prizes of count information (1 byte) (Bit0-3): 1 = 1 prizes 0x61F1 is 1 for game information It becomes data.

FIG. 280 is a diagram showing an example in which (Example 8) 7 = winning a prize by operating a normal electric accessory, one prize is won in the winning opening 2 of 10 prize balls by operating the ordinary electric accessory.
Game information: 0x72A1
Type information (1 byte) data Type (Bit4 to 7): 7 = Winning by normal electric accessory operation Type information (1 byte) data number (Bit0-3): 2 = Winning opening 2
Number of prize balls (Bit4 to 7) in count information (1 byte): 10 = 10 prize balls Number of prizes in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x72A1 is 1 It becomes data.

FIG. 281 is a diagram showing an example in which (Example 9) 8 = winning a prize by operating another accessory, one prize is won in the winning opening 1 of 10 prize balls by operating the other accessory.
Game information: 0x81A1
Type information (1 byte) data Type (Bit4 to 7): 8 = Winning due to other accessory operation Type information (1 byte) data number (Bit0-3): 1 = Winning opening 1
Number of prize balls (Bit4 to 7) in count information (1 byte): 10 = 10 prize balls Number of prizes in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x81A1 is 1 It becomes data.

(B) When the data type is 9 = the number of times the symbol is confirmed FIG. 282 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of symbol confirmations (lower 4 bits, Bits 0 to 3).
Unused (Bits 4 to 7) is fixed at 0.
The number of times the symbol is fixed (Bits 0 to 3) is 1 (times), and 0 and 2 to 15 are unused.

FIG. 283 is a diagram showing an example in which the special symbol 1 is stopped once in the number of times the symbol is confirmed (Example 1).
Game information: 0x9101
Type information (1 byte) data type (Bit4 to 7): 9 = number of symbol confirmations Type information (1 byte) data number (Bit0 to 3): 1 = special symbol 1
Unused (Bit4 to 7): 0 fixed count information (1 byte) Number of symbol confirmations (Bit0 to 3): 1 = 1 stop of count information (1 byte) The game information is 0x9101.

FIG. 284 is a diagram showing an example in which the normal symbol 1 is stopped once in the number of times the symbol is confirmed (Example 2).
Game information: 0x9301
Type information (1 byte) data type (Bit4 to 7): 9 = number of symbol confirmations Type information (1 byte) data number (Bit0 to 3): 3 = normal symbol 1
Unused (Bit4 to 7): 0 fixed count information (1 byte) Number of symbol confirmations (Bit0 to 3): 1 = 1 stop of count information (1 byte) The game information is 0x9301.

(C) When the data type is 10 = per special symbol FIG. 285 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of hits (lower 4 bits, Bits 0 to 3).
Unused (Bits 4 to 7) is fixed at 0.
The number of hits (Bits 0 to 3) is 1 (times), and 0 and 2 to 15 are unused.

FIG. 286 is a diagram showing an example in the case where the accessory continuous operation device is operated (big hit) and the accessory continuous operation device is operated once (big hit).
Game information: 0xA101
Type information (1 byte) data type (Bit4 to 7): 10 = per special symbol Type information (1 byte) data number (Bit0 to 3): 1 = jackpot count information (1 byte) unused (Bit4 to) 7): 0 fixed count information (1 byte) hit count (Bit0 to 3): 1 = 1 occurrence The game information is 0xA101.

FIG. 287 shows (Example 2) that the special electric accessory is activated (small hit) when the accessory continuous operating device is not activated, and the special electric accessory is activated once when the accessory continuous operating device is not activated. It is a figure which shows the example in the case of (small hit).
Game information: 0xA201
Type information (1 byte) data type (Bit4 to 7): 10 = per special symbol Type information (1 byte) data number (Bit0 to 3): 2 = small hit count information (1 byte) unused (Bit4) ~ 7): 0 fixed count information (1 byte) hit count (Bit0-3): 1 = 1 occurrence The game information is 0xA201.

(D) When the data type is 11 = normal symbol. FIG. 288 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of hits (lower 4 bits, Bits 0 to 3).
Unused (Bits 4 to 7) is fixed at 0.
The number of hits (Bits 0 to 3) is 1 (times), and 0 and 2 to 15 are unused.

FIG. 289 is a diagram showing an example in which a normal symbol hit occurs once in (Example 1) normal symbol hit.
Game information: 0xB101
Data type of type information (1 byte) (Bit4 to 7): 11 = Data number of type information (1 byte) per normal symbol (Bit0-3): 1 = Normal symbol 1
Unused (Bit4 to 7): 0 fixed count information (1 byte) Number of hits (Bit0 to 3): 1 = 1 times of count information (1 byte) The game information is 0xB101.

(E) When the data type is 12 = the number of bonuses (the number of times the large winning opening is opened) FIG. 290 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 Bits, Bits 4 to 7) and the number of accessories (lower 4 Bits, Bits 0 to 3).
Unused (Bits 4 to 7) is fixed at 0.
The number of bonuses (Bits 0 to 3) is 1 (times), and 0 and 2 to 15 are unused.

FIG. 291 is a diagram showing an example in the case where the accessory 1 is opened once in the number of times of the accessory (Example 1).
Game information: 0xC101
Type information (1 byte) data type (Bit4 to 7): 12 = number of accessories Data number of type information (1 byte) (Bit0-3): 1 = accessory 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Number of count information (1 byte) (Bit0 to 3): 1 = 1 open The game information is 0xC101.

(F) When the data type is 13 = passing through a specific area FIG. 292 is a diagram showing details of count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of passages through a specific area (lower 4 bits, Bits 0 to 3).
Unused (Bits 4 to 7) is fixed at 0.
The number of passages through the specific area (Bits 0 to 3) is 1 (times), and 0 and 2 to 15 are unused.

FIG. 293 is a diagram showing an example in the case of passing through the specific area 1 once in the passage through the specific area (Example 1).
Game information: 0xD101
Data type of type information (1 byte) (Bit 4 to 7): 13 = Passing through specific area Data number of type information (1 byte) (Bit 0 to 3): 1 = Specific area 1
Unused (Bit4 to 7): 0 fixed count information (1 byte) Number of count information (1 byte) (Bit0 to 3): 1 = 1 pass The game information is 0xD101.

(G) When the data type is 14 = external terminal plate pulse output FIG. 294 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of pulse outputs (lower 4 bits, Bits 0 to 3).
Unused (Bits 4 to 7) is fixed at 0.
The number of pulse outputs (Bits 0 to 3) is 1 (times), and 0 and 2 to 15 are unused.

FIG. 295 is a diagram showing an example in the case of (Example 1) external terminal plate pulse output in which a pulse is output once from the external terminal plate pulse output signal terminal 1 of the dedicated unit.
Game information: 0xE101
Type information (1 byte) data type (Bit 4 to 7): 14 = External terminal board pulse output Type information (1 byte) data number (Bit 0 to 3): 1 = External terminal board pulse output signal terminal 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Number of count information (1 byte) (Bit0 to 3): 1 = 1 pulse output The game information is 0xE101.

(H) When the data type is 15 = performance information status notification FIG. 296 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and status flags (lower 4 bits, Bits 0 to 3).
This notification is given when the state changes during the game, when the power is turned on, and when the game shifts from the setting change or the setting confirmation.
Unused (Bits 4 to 7) is fixed at 0.
The status flags (Bit0 to 3) are Bit0: base (0 = low base, 1 = high base), Bit1: big hit (0 = normal time, 1 = big hit), Bit2: high probability (0 =). Low probability, 1 = high probability), Bit3: Not used.

FIG. 297 is a diagram showing an example in the case where the state is changed to the high base in (Example 1) performance information state notification.
Game information: 0xF101
Type information (1 byte) data type (Bit4 to 7): 15 = Performance information status notification Type information (1 byte) data number (Bit0 to 3): 1 Fixed Count information (1 byte) unused (Bit4 to) 7): 0 fixed count information (1 byte) status flag (Bit0 to 3): Bit0: base (1 = high base), Bit1: big hit (0 = normal time), Bit2: high probability (0 =) Low probability), Bit3: 0 fixed game information is 0xF101.

[7.2.4. Game machine information response]
FIG. 298 is a diagram showing details of the gaming machine information response.
Telegram name: Game machine information response Telegram direction: Frame control board → Main control board Telegram outline: The frame control board responds to the main control board with the reception result of the game machine information notification and the frame control status.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x05

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x12

[No3]
Data name: Communication number Data length: 1 byte Byte order:-
Contents: Communication sequence number (0 to 255). The frame control board responds as it is to the communication serial number received in the gaming machine information notification.

[No4]
Data name: Game machine information receipt result Data length: 1 byte Byte order:-
Contents: Receipt result (0x00 = receipt OK)

[No5]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: The result of addition from the telegram length to the data part.

[8. Communication procedure between the main control board and the frame control board]
[8.1. Communication procedure]
[8.1.1. Communication procedure from power-on]
FIG. 299 is a diagram showing a communication procedure from power-on.
[F100] Power is turned on to the main control board 560 and the frame control board 550.
[F101] The main control board 560 starts up in a start-up time of 3 minutes (* 1).

[F102] The main control board 560 transmits a game machine installation information notification (communication number = 0) to the frame control board 550.
[F103] The frame control board 550 transmits a game machine installation information response (communication number = 0) to the main control board 560. At this time, the main control board 560 permits firing.

[F104] The main control board 560 transmits a game machine information notification (communication number = 1) to the frame control board 550.
[F105] The frame control board 550 transmits a game machine information response (communication number = 1) to the main control board 560.

[F106] The main control board 560 transmits a game machine information notification (communication number = 2) to the frame control board 550.
[F107] The frame control board 550 transmits a game machine information response (communication number = 2) to the main control board 560.

[F108] The main control board 560 transmits a game machine information notification (communication number = 3) to the frame control board 550.
[F109] The frame control board 550 transmits a gaming machine information response (communication number = 3) to the main control board 560.
The interval at which the main control board 560 transmits each information is 108 ms.

(1) The main control board 560 notifies the gaming machine installation information after the power is turned on.
(2) When the main control board 560 normally receives the game machine installation information response and then becomes playable, the main control board 560 permits firing and notifies the game machine information at a fixed cycle (108 ms).
Since the frame control board 550 calculates (generates) the performance information (game machine performance information), the game machine information notification (communication serial number = 1) first notifies the performance information status notification (data type 15). Notify before the game information buffered when the power is restored.
(* 1) If the frame control board 550 cannot receive the gaming machine installation information notification within 3 minutes from the start-up, the frame control board 550 notifies an error as a communication line disconnection. If the game machine installation information notification is normally received after the communication line is disconnected, the error notification is canceled.

[8.1.2. Communication procedure when changing settings or checking settings]
FIG. 300 is a diagram showing a communication procedure at the time of setting change or setting confirmation.
[F110] Power is turned on to the main control board 560 and the frame control board 550.
[F111] The main control board 560 starts up in a start-up time of 3 minutes (* 1).

[F112] The main control board 560 transmits a game machine installation information notification (communication number = 0) to the frame control board 550.
[F113] The frame control board 550 transmits a game machine installation information response (communication number = 0) to the main control board 560.

[F114] The main control board 560 transmits a gaming machine information notification (communication number = 1) to the frame control board 550.
[F115] The frame control board 550 transmits a game machine information response (communication number = 1) to the main control board 560.

[F116] The main control board 560 transmits a game machine information notification (communication number = n) to the frame control board 550.
[F117] The frame control board 550 transmits a game machine information response (communication number = n) to the main control board 560. At this time, the main control board 560 permits firing.

[F118] The main control board 560 transmits a game machine information notification (communication number = n + 1) to the frame control board 550.
[F119] The frame control board 550 transmits a game machine information response (communication number = n + 1) to the main control board 560.
The interval at which the main control board 560 transmits each information is 108 ms.
In the figure, the part surrounded by the dotted line is the setting change state or the setting confirmation state.

(1) The main control board 560 notifies the gaming machine installation information after the power is turned on.
(2) After normally receiving the game machine installation information response, the main control board 560 shifts to the setting change state or the setting confirmation state, and notifies the game machine information at a fixed cycle (108 ms). For the gaming machine information, 0 is set in the main control state 1, the main control state 2, and the gaming machine error state, and only the fraud detection state 1 is notified by setting the corresponding flag.
(3) After the setting change or setting confirmation is completed, when the game becomes possible, the launch is permitted and the game machine information is notified.
Since the frame control board 550 calculates the performance information, the gaming machine information notification (communication serial number = n + 1) notifies the performance information status notification (data type 15) at the beginning. Notify before the game information buffered when the power is restored.
(* 1) If the frame control board 550 cannot receive the gaming machine installation information notification within 3 minutes from the start-up, the frame control board 550 notifies an error as a communication line disconnection.
If the game machine installation information notification is normally received after the communication line is disconnected, the error notification is canceled.

[8.2. Communication line disconnection detection 1]
FIG. 301 is a diagram showing the procedure of communication line disconnection detection 1.
[F120] The main control board 560 transmits a notification message (communication number = n) to the frame control board 550.
[F121] The frame control board 550 transmits a response message (communication number = n) to the main control board 560. However, it does not reach the main control board 560.

[F122] The main control board 560 transmits a notification message (communication number = n + 1) to the frame control board 550.
[F123] The frame control board 550 transmits a response message (communication number = n + 1) to the main control board 560. However, it does not reach the main control board 560.

[F124] The main control board 560 transmits a notification message (communication number = n + 2) to the frame control board 550.
[F125] The frame control board 550 transmits a response message (communication number = n + 2) to the main control board 560. However, it does not reach the main control board 560.

[F126] The main control board 560 determines that the communication line is disconnected when the response non-reception occurs 10 times.

In this way, when the main control board 560 cannot receive the response 10 times in total, the main control board 560 notifies the error as a communication line disconnection. After the communication line is disconnected, the communication line is restored by turning the power off / on.

[8.3. Communication line disconnection detection 2]
FIG. 302 is a diagram showing a procedure of communication line disconnection detection 2.
[F130] The main control board 560 transmits a notification message (communication number = n) to the frame control board 550.
[F131] The frame control board 550 transmits a response message (communication number = n) to the main control board 560.

[F132] The main control board 560 transmits a notification message (communication number = n + 1) to the frame control board 550. However, it does not reach the frame control board 550.

[F133] The main control board 560 transmits a notification message (communication number = n + 2) to the frame control board 550. However, it does not reach the frame control board 550.

[F134] If the frame control board 550 does not receive the notification message even after 100 ms has elapsed from the reception of the first notification message, it determines that the communication line is disconnected.

In this way, if the frame control board 550 cannot receive the next notification for 1000 ms after receiving the notification message, the frame control board 550 notifies the error as a communication line disconnection. If the notification message is normally received after the communication line is disconnected, the error notification is canceled.

[8.4. Ball out state]
FIG. 303 is a diagram showing a procedure in a ball-free state.
[F140] Power is turned on to the main control board 560 and the frame control board 550.
[F141] The main control board 560 transmits a game machine installation information notification (communication number = 0) to the frame control board 550.
[F103] The frame control board 550 transmits a game machine installation information response (communication number = 0) to the main control board 560 (* 1 in a ball-free state).

The frame control board 550 notifies the ball-out state by responding to the gaming machine installation information when the power is turned on.
(* 1) The main control board 560 and the frame control board 550 do not perform communication after transmitting and receiving in a ball-free state. In the "ball-free state", the operation is continued from the power-on to the power-off.

When the main control board 560 receives the game machine installation information response and the frame control board 550 receives OK, the main control board 560 permits firing and shifts to the normal game. In the case of the ball-free state, the firing is permitted and the process shifts to the infinite loop process. The infinite loop process is a game stop state in which the normal symbol or the special symbol is changed, or the normal electric accessory or the special electric accessory cannot be operated.

[Conditions for launching game balls]
The conditions for launching a game ball are as follows.
〔setting change〕
Ball-free state: Can be fired Not ball-free state: Can not be fired

[Check settings]
Ball-free state: Can be fired Not ball-free state: Can not be fired

[Normal game (playable state)]
Ball-free state: Can be fired Not ball-free state: Can be fired

[RWM (RAM) error]
Ball-free state: Can be fired Not ball-free state: Can not be fired

[9. External terminal board output]
[9.1. Output configuration diagram]
FIG. 304 is a diagram showing an output configuration diagram.
The main control board 560 selects a signal to be output from the game specifications of the game board, and outputs a signal from the external terminal board of the hall controller output BOX by the game information (command) and the state flag.

The main control board 560 of the game board is capable of pulse output (game information (command)) (number / number of times information). The main control board 560 outputs a pulse with game information (command).
Output examples are the number of times the symbol is fixed, the starting port, the external terminal plate pulse output signals 1 to 4, and the like.

Further, the main control board 560 of the game board can output a state (state flag) (ON / OFF signal). The main control board 560 sets the state in the main control state 1 and the main control state 2.
Output examples are jackpot 1, jackpot 2, external terminal board state output signals 1 to 4, and the like.

Serial communication is possible between the main control board 560 of the game board and the frame control board 550 of the game machine frame.
The pulse output (game information) and the state output (state flag) from the main control board 560 can be transmitted to the dedicated unit 3040, the hall controller output BOX 790, the hall computer, the data lamp 792, or the like.

Serial communication is possible between the frame control board 550 of the gaming machine frame and the dedicated unit 700.
Serial communication is possible between the dedicated unit 700 and the hall controller output BOX 790.

The Hallcon output BOX790 has status outputs (13 ports) such as jackpot 1, jackpot 2, and external terminal board status output signals 1 to 4 (expansion ports), symbol confirmation count, starting port, and external terminal board pulse output signal terminal 1. A pulse output (15 ports) such as ~ 4 (expansion port) can be transmitted to a hall computer, a data lamp 792, or the like.

[9.2. Hall control output BOX external terminal board output signal list]
[9.2.1 Standard 20 ports]
305 and 306 are diagrams showing standard 20 ports.
The standard 20 port outputs a signal from the external terminal board of the hall control output BOX by transmitting the game information (command) shown below and setting the status flag.

Item No .: 1
Hallcon output signal name: Number of shots Hallcon output signal content: Launch ball data 1 pulse output with 10 balls Game information (command) from the main control to be pulse output: (* 1)
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 2
Hallcon output signal name: Prize ball Hallcon output signal content: Prize ball data managed by frame control 1 pulse output with 10 balls Game information (command) from the main control to be pulse output: (* 1)
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 3
Hall control output signal name: Number of symbol confirmations 1
Hall control output signal content: Special figure 1 (1st special symbol) 1 pulse output with one stop. Game information (command) from the main control that is the target of pulse output: 9101H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 4
Hall control output signal name: Number of symbol confirmations 2
Hall control output signal content: Special figure 2 (2nd special symbol) 1 pulse output with one stop. Game information (command) from the main control to be pulse output target: 9201H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 5
Hall control output signal name: Starting port 1
Hall control output signal content: 1 pulse output with 1 ball passing through the start port Game information (command) from the main control that is the target of pulse output: 1111H to 11F1H, 1411H to 14F1H, 5111H to 51F1H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 6
Hall control output signal name: Starting port 2
Hall control output signal content: 1 pulse output with 1 ball passing through 2 start ports Game information (command) from the main control that is the target of pulse output: 1211H to 12F1H, 1511H to 15F1H, 5211H to 52F1H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 7
Hall control output signal name: Passing gate 1
Hall control output signal content: 1 pulse output with 1 ball passing through gate 1 Game information (command) from the main control targeted for pulse output: 4101H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 8
Hall control output signal name: Passing gate 2
Hall control output signal content: 1 pulse output with 1 ball passing through gate 2 Game information (command) from the main control to be pulse output: 4201H
Status flag from the main control to be output:-
Signal type: Pulse

Item No .: 9
Hallcon output signal name: Number of characters (number of times the winning opening is opened)
Hall control output signal content: 1 pulse output when the winning opening is opened once when the accessory continuous operation device is not operating Game information (command) from the main control that is the target of pulse output: C101H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 10
Hallcon output signal name: Number of prizes for prizes (number of prizes for large prizes)
Hall control output signal content: 1 pulse output for each ball passing through each count port in the accessory (large winning opening) Game information (command) from the main control to be pulse output: 2111H to 21F1H, 2211H to 22F1H, 6111H to 61F1H, 6211H to 62F1H
Status flag from the main control to be output:-
Signal type: Pulse

Item No .: 11
Hall control output signal name: Passing through a specific area Hall control output signal content: Passing through a specific area 1 pulse output with one ball Pulse output Game information (command) from the main control to be targeted: D101H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 12
Hall control output signal name: jackpot 1
Hall control output signal content: "ON" output at the time of a big hit to be notified Game information (command) from the main control that is the target of pulse output:-
State flag from the main control to be output: ON when Bit0 of the main control state 1 is "1"
Signal type: Status

Item number: 13
Hall control output signal name: jackpot 2
Hall control output signal content: "ON" output at all jackpots Game information (command) from the main control that is the target of pulse output:-
State flag from the main control to be output: ON when Bit1 of the main control state 1 is "1"
Signal type: Status

Item number: 14
Hall control output signal name: jackpot 3
Hall control output Signal content: "ON" output at the time of a big hit in a time saving or advantageous state Pulse output Game information (command) from the target main control:-
State flag from the main control to be output: ON when Bit2 of the main control state 1 is "1"
Signal type: Status

Item No .: 15
Hall control output signal name: Big hit medium + time saving Hall control output signal content: "ON" output during big hit, time saving or advantageous state Game information (command) from the main control to be pulse output:-
State flag from the main control to be output: ON when Bit0 of the main control state 2 is "1"
Signal type: Status

Item number: 16
Hall control output signal name: High probability Medium Hall control output signal content: "ON" output during high probability Pulse output Game information (command) from the target main control:-
State flag from the main control to be output: ON when Bit1 of the main control state 2 is "1"
Signal type: Status

Item No .: 17
Hall control output signal name: Time saving Medium Hall control output signal content: "ON" output during time saving or advantageous state Game information (command) from the main control to be pulse output:-
State flag from the main control to be output: ON when Bit2 of the main control state 2 is "1"
Signal type: Status

Item No .: 18
Hall control output signal name: Door open Hall control output signal content: "ON" output when the front decoration or back mechanism is open Game information (command) from the main control that is the target of pulse output:-
Status flag from the main control that is the target of status output: (* 1)
Signal type: Status

Item No .: 19
Hall control output signal name: Illegal Hall control output signal content: "ON" output when illegality is detected in main control and frame control Game information (command) from the main control that is the target of pulse output:-
Status flag from the main control to be output status: ON when any of Bit 0 to Bit 5 of fraud detection status 1 is "1"
Signal type: Status

Item number: 20
Hall control output signal name: Game machine error Hall control output signal content: "ON" output when an error is detected in the main control and frame control Game information (command) from the main control that is the target of pulse output:-
Status flag from the main control to be output: ON when the error code is set in the gaming machine error status and Bit7 is "1".
Signal type: Status

(* 1) Information notified from the frame control to the dedicated unit. It is not the information generated by the main control.

[9.2.2 expansion port]
FIG. 307 is a diagram showing an expansion port.
When outputting a signal other than the standard 20 ports, the expansion port is used and the signal is output from the external terminal board of the Hallcon output BOX.
A signal is output from the external terminal board of the Hallcon output BOX by transmitting the game information (command) and setting the status flag shown below.

Item No .: 21
Hall controller output signal name: External terminal board Pulse output signal terminal 1
Hall controller output signal content: 1 pulse output by command instruction of external terminal board pulse output signal terminal 1 Game information (command) from the main control to be pulse output target: E101H
Status flag from the main control to be output:-
Signal type: Pulse

Item No .: 22
Hall controller output signal name: External terminal board Pulse output signal terminal 2
Hall controller output signal content: 1 pulse output by command instruction of external terminal board pulse output signal terminal 2 Game information (command) from the main control to be pulse output target: E201H
Status flag from the main control to be output:-
Signal type: Pulse

Item No .: 23
Hall controller output signal name: External terminal board Pulse output signal terminal 3
Hall controller output signal content: 1 pulse output by command instruction of external terminal board pulse output signal terminal 3 Game information (command) from the main control to be pulse output target: E301H
Status flag from the main control to be output:-
Signal type: Pulse

Item number: 24
Hall controller output signal name: External terminal board Pulse output signal terminal 4
Hall controller output signal content: 1 pulse output by command instruction of external terminal board pulse output signal terminal 4 Game information (command) from the main control to be pulse output target: E401H
Status flag from the main control to be output:-
Signal type: Pulse

Item No .: 25
Hall controller output signal name: External terminal board state Output signal terminal 1
Hall controller output signal content: "ON" output when the gaming machine status signal 1 is "1" Game information (command) from the main control that is the target of pulse output:-
State flag from the main control to be output: ON when Bit3 of the main control state 1 is "1"
Signal type: Status

Item No .: 26
Hall controller output signal name: External terminal board state Output signal terminal 2
Hall controller output signal content: "ON" output when the gaming machine status signal 2 is "1" Game information (command) from the main control that is the target of pulse output:-
State flag from the main control to be output: ON when Bit4 of the main control state 1 is "1"
Signal type: Status

Item No .: 27
Hall controller output signal name: External terminal board state Output signal terminal 3
Hall controller output signal content: "ON" output when the gaming machine status signal 3 is "1" Game information (command) from the main control that is the target of pulse output:-
State flag from the main control to be output: ON when Bit5 of the main control state 1 is "1"
Signal type: Status

Item No .: 28
Hall controller output signal name: External terminal board state Output signal terminal 4
Hall controller output signal content: "ON" output when the game machine status signal 4 is "1" Game information (command) from the main control that is the target of pulse output:-
State flag from the main control to be output: ON when Bit6 of the main control state 1 is "1"
Signal type: Status

[Chapter 4]
[Dedicated interface specifications]
[1. Glossary〕
Basically, it is the same as the content explained in Chapter 3.
However, the following terms may be used with different meanings.
"Game machine information" is a general term for game machine installation information, game machine performance information, and hall control / fraud monitoring information.
The "game machine installation information" is a maker code, a product code, and a chip ID number for main / frame control.
The "fraud monitoring information" indicates the number of game balls, the fraud detection state 1, the fraud detection state 2, and the fraud detection state 3. Regarding the number of gaming balls, the CM monitors the number of gaming balls of the gaming machine and the number of counting balls transmitted by the gaming machine to detect fraud.

[2. Scope of application〕
The configuration shown below is applicable to the specifications of the dedicated interface of the gaming machine information network system (see B in FIG. 308).

[3. System Configuration〕
FIG. 308 is a diagram showing a system configuration diagram of the managed gaming machine.
Since the contents other than B in the drawing are the same as the contents in FIG. 249, the description thereof will be omitted.

[4. Overview〕
The dedicated interface communicates information on renting game balls, information on counting game balls, and game machine information by telegram using an asynchronous serial port.
Information for renting a game ball is transmitted and received between the CM and the frame control by a telegram in units of the number of balls.
The information for counting the game balls is transmitted by the frame control in a telegram in units of the number of balls.
There are three types of gaming machine information: gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information, and the frame control notifies one of them by telegram according to the notification conditions.

[5. Frame control-Communication conditions between CM]
FIG. 309 is a diagram showing the frame control-CM communication conditions.
The communication method is asynchronous serial communication.
The communication speed is 62,500 bps.
The bit configuration is "start bit: 1", "data bit: 8", "stop bit: 1", and "parity: none".
The communication control is full-duplex communication, the primary station is frame control, and the secondary station is CM.

[6. Frame control-CM data structure]
The frame control-CM data structure is the same as the structure shown in FIG. 251. Therefore, the description thereof will be omitted.

FIG. 310 is a diagram showing details of the frame control-CM data configuration.
[No1]
Name: Telegram length Data length: 1 byte Data format: HEX (hexadecimal)
Contents: Stores the length of the telegram from the telegram length to the checksum (range: 0x05-0x39 (5-57)).

[No2]
Name: Command Data length: 1 byte Data format: HEX (hexadecimal)
Contents: Stores the command code of the telegram.

[No3]
Name: Serial number Data length: 1 byte Data format: HEX (hexadecimal)
Contents: Stores serial numbers, counting serial numbers, and rental serial numbers. The range of sequence numbers for serial numbers is 0x00 to 0xFF (0 to 255).

[No4]
Name: Data part Data length: 1 to 53 bytes Data format: HEX (hexadecimal)
Contents: Stores telegram data.

[No5]
Name: Checksum Data length: 1 byte Data format: HEX (hexadecimal)
Meaning: Add the data from the telegram length to the data part and store the lower 1 byte of the total.

[6.1. Frame control-CM byte order]
The byte order in this chapter defines B as big endian and L as little endian.

[7. Frame control-Commercial telegram]
[7.1. Frame control-Commercial message list]
FIG. 311 is a diagram showing a list of message messages between frame control and CM.
[No1]
Telegram name: Game machine information notification Transmission direction: Frame control → CM
Command: 0x01
Outline: The frame control notifies the CM of the gaming machine information.

[No2]
Telegram name: Count notification Transmission direction: Frame control → CM
Command: 0x02
Summary: The frame control notifies the CM of the counting information.

[No3]
Telegram name: Lending notification Transmission direction: CM → Frame control command: 0x13
Summary: The CM notifies the frame control of the loan information.

[No4]
Telegram name: Lending receipt result response Transmission direction: Frame control → CM
Command: 0x03
Summary: The frame control responds to the CM with the receipt result of the loan information.

[7.2. Frame control-CM details]
[7.2.1. Game machine information notification]
FIG. 312 is a diagram showing details of the gaming machine information notification.
Telegram name: Game machine information notification Telegram length: 18 to 57 bytes (variable length)
Transmission direction: Frame control → CM
Telegram summary: The frame control notifies the CM of the gaming machine information by this telegram. There are three types of gaming machine information: gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information, and one of them is notified according to the notification conditions of each information.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x12 to 0x39

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x01

[No3]
Data name: Serial number Data length: 1 byte Byte order:-
Contents: Sequence number: 0x00 to 0xFF (0 to 255)

[No4]
Data name: Game machine type Data length: 1 byte Byte order:-
Contents: Indicates the type of gaming machine

[No5]
Data name: Game machine information type Data length: 1 byte Byte order:-
Contents: 0x00: Pachinko machine performance information, 0x01: Pachinko machine installation information, 0x02: Hall control / fraud monitoring information

[No6]
Data name: Gaming machine information Gaming machine performance information of gaming machine information (notifying one of the following set by the type code) (details are shown in 7.2.1.4)
Data length: 51 bytes Byte order:-
Contents: Total number of launched game balls, total number of acquired game balls, ball output rate, number of minutes acquired game balls (low base), character ratio, continuous character ratio, etc.

Data name: Gaming machine information Gaming machine installation information of gaming machine information (details are shown in 7.2.1.5)
Data length: 40 bytes Byte order:-
Contents: Manufacturer code, product code, chip ID number of main / frame control CPU

Data name: Pachinko machine information Hall control / fraud monitoring information for game machine information (details are shown in 7.2.1.6)
Data length: 12-42 bytes Byte order:-
Contents: Big hit, probability fluctuation, time reduction, number of winning balls at each winning opening, number of game balls, etc.

[No7]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[7.2.1.1. About serial number (7.2.1. No3)]
The frame control notifies the CM of the serial number by the following control.
(1) When the power is turned on, the serial number "0x00 (0)" is notified.
(2) After the power is turned on, the serial number is updated (+1) each time a notification is sent.
(3) The next value of the serial number "0xFF (255)" is updated (+2) to "0x01 (1)".

[7.2.1.2. About game machine type (7.2.1.No.No4)]
The code system and the list of game models are as shown below.
FIG. 313 is a diagram showing a code system (1 byte) of a gaming machine type.
Bit7: Management medium (0 = game ball, 1 = game medal)
Bit6 to Bit4: Group classification (0 = A union, 1 = B union, 2-7 = reserve)
Bit3 to Bit0: Game machine type (1 = pachinko game machine, 2 = rotating body type game machine, 3 = arrange ball game machine, 4 = Jiyan ball game machine, 5 to 15 = spare, 0 = unused)

FIG. 314 is a diagram showing an example of a gaming machine type list.
Code: 0x01
Game machine: Pachinko game machine Group: A union Management medium: Game ball

Code: 0x82
Pachinko machine: Revolving pachinko machine Group: A union Management medium: Pachinko medal

Code: 0x83
Game machine: Arrange ball game machine Group: A union Management medium: Game medal

Code: 0x84
Game machine: Jiyan ball game machine Group: A union Management medium: Game medal

Code: 0x92
Pachinko machine: Revolving pachinko machine Group: B union Management medium: Pachinko medal

[7.2.1.3. About game machine information type (7.2.1.No5)]
The frame control notifies the type of gaming machine information with the code shown below.
(1) Type code 0x00: Game machine performance information Notifies the total number of launched game balls, the total number of acquired game balls, the ball output rate, the number of game balls acquired per minute (low base), the bonus ratio, the continuous bonus ratio, and the like.
(2) Type code 0x01: Game machine installation information Notifies the manufacturer code, product code, and chip ID number of the main / frame control CPU.
(3) Type code 0x02: Hall control / fraud monitoring information Notifies jackpot, probability fluctuation, time reduction, number of winning balls, number of game balls, fraud monitoring information, etc. of each winning opening.

[7.2.1.4. Telegram when "0x00: Gaming machine performance information" is set for the gaming machine information type]
FIG. 315 is a diagram showing a telegram when "0x00: gaming machine performance information" is set as the gaming machine information type.

Data name: Total number of launched game balls in game machine information (game machine performance information) Data length: 3 bytes Byte order: L
Contents: 0x0000000 to 0xFFFFFF (0 balls to 16777215 balls). The storage example is 0x102700 when the total number of launching game balls is 10,000.

Data name: Total number of game balls acquired for game machine information (game machine performance information) Data length: 3 bytes Byte order: L
Contents: 0x0000000 to 0xFFFFFF (0 balls to 16777215 balls). The storage example is 0x102700 when the total number of acquired game balls is 10,000.

Data name: Game machine information (game machine performance information) ball output rate Data length: 2 bytes Byte order: L
Contents: 0x0000 to 0xFFFF (0% to 65535%) (rounded down to the nearest whole number). The storage example is 0x7D00 when the ball output rate is 125%.

Data name: Number of gaming balls acquired per minute for gaming machine information (gaming machine performance information) (low base)
Data length: 2 bytes Byte order: L
Contents: 0x00 to 0xFFFF (0 to 65535 balls) (rounded down to the nearest whole number). The storage example is 0x6400 when the number of game balls acquired per minute is 100 balls.

Data name: Character ratio of game machine information (game machine performance information) Data length: 1 byte Byte order:-
Contents: 0x00 to 0x64 (0% to 100%) (rounded down to the nearest whole number).

Data name: Continuous character ratio of game machine information (game machine performance information) Data length: 1 byte Byte order:-
Contents: 0x00 to 0x64 (0% to 100%) (rounded down to the nearest whole number).

Data name: Game machine information (game machine performance information) The number of times the continuous operation device is operated Data length: 2 bytes Byte order: L
Contents: 0x0000 to 0xFFFF (0 to 65535 times). The storage example is 0x6400 when the number of times of operation of the accessory continuous operation device is 100 times.

Data name: Maximum difference ball of game machine information (game machine performance information) Data length: 3 bytes Byte order: L
Contents: 0x0000000 to 0xFFFFFF (0 balls to 16777215 balls). The storage example is 0x102700 in the case of a maximum difference sphere of 10000 spheres.

Data name: Preliminary data length of game machine information (game machine performance information): 31 bytes Byte order:-
Contents: Spare (fixed to 0x00 when not in use).

Data name: Reservation of game machine information (game machine performance information) Data length: 3 bytes Byte order:-
Contents: Used in CM (game machine is fixed at 0x00) (maximum MY calculated by CM).

[7.2.1.5. Telegram when "0x01: Game machine installation information" is set for the game machine information type]
FIG. 316 is a diagram showing a telegram when "0x01: game machine installation information" is set as the game machine information type.
Data name: Main control chip ID number of game machine information (game machine installation information) Data length: 9 bytes Byte order: B
Contents: Main control chip ID number of the gaming machine

Data name: Main control chip maker code of game machine information (game machine installation information) Data length: 3 bytes Byte order: B
Contents: Manufacturer code written in the control area of the main control chip

Data name: Main control chip for game machine information (game machine installation information) Product code Data length: 8 bytes Byte order: B
Contents: Product code written in the control area of the main control chip

Data name: Frame control chip ID number of game machine information (game machine installation information) Data length: 9 bytes Byte order: B
Contents: Pachinko machine frame control chip ID number

Data name: Frame control chip maker code for game machine information (game machine installation information) Data length: 3 bytes Byte order: B
Contents: Described in the control area of the frame control chip and the manufacturer code

Data name: Frame control chip for game machine information (game machine installation information) Product code Data length: 8 bytes Byte order: B
Contents: Product code written in the control area of the frame control chip

[7.2.1.1.5.1. Main control chip ID number]
The method of generating the main control chip ID number is the same as that shown in FIGS. 258 and 259. Therefore, the description thereof will be omitted.

[7.2.1.1.5.2. Frame control chip ID number]
FIG. 317 is a diagram showing a method of generating a frame control chip ID number (in the case of the first chip).
The individual chip numbers of the CPU are read in ascending order of address.
The upper 4 bytes of this number are padded with 0, and an identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip individual number is 0x87654321, 0 padding is 4 bytes (0x00000000000), the chip individual number is 4 bytes (0x87654321), and the identification code (*) is 1 byte (0x21).

FIG. 318 is a diagram showing a method of generating a frame control chip ID number (in the case of the second chip).
The CPU chip code is read from the youngest address.
The upper 4 bytes of this code are padded with 0, and the identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip code is 0x21876543, 0 padding is 4 bytes (0x00000000000), the chip code is 4 bytes (0x21876543), and the identification code (*) is 1 byte (0x41).
(*) The content of the identification code is the same as that in FIG. 259. Therefore, the description thereof will be omitted.

[7.2.1.6. Telegram when "0x02: Hall control / fraud monitoring information" is set as the game machine information type]
FIGS. 319 to 321 are diagrams showing a telegram when "0x02: Hall control / fraud monitoring information" is set as the gaming machine information type.

Data name: Number of game balls in game machine information (hall control / fraud monitoring information) Data length: 3 bytes Byte order: L
Contents: Current number of game balls, 0x0000000 to 0x301B0F (0 to 990000 balls). The storage example is 0x102700 when the number of game balls is 10,000.

Data name: Number of balls launched for game machine information (hall control / fraud monitoring information) Data length: 1 byte Byte order:-
Contents: Number of fired balls: 0x80 to 0x7F (-128 to 127). The upper 1 bit is a code (+/-) bit. If there is a back ball, subtract the number of back balls (if there are multiple shot balls at the time of transmission, add them up).

Data name: Total number of winning balls in game machine information (hall control / fraud monitoring information) Data length: 1 byte Byte order:-
Contents: Game information / count information 1 to n number of prize balls x total number of prizes: 0x00 to 0xFF (0 to 255).

Data name: Main control status of gaming machine information (hall control / fraud monitoring information) 1
Data length: 1 byte Byte order:-
Contents: Bit0: jackpot 1, Bit1: jackpot 2, Bit2: jackpot 3, Bit3: gaming machine status signal 1, Bit4: gaming machine status signal 2, Bit5: gaming machine status signal 3, Bit6: gaming machine status signal 4, Bit7 :unused.

Data name: Main control status of gaming machine information (hall control / fraud monitoring information) 2
Data length: 1 byte Byte order:-
Contents: Bit0: During big hit + time saving (shortening fluctuation time) or in advantageous state, Bit1: High probability, Bit2: Shortening time (shortening fluctuation time) or in advantageous state, Bit3: Unused, Bit4: Unused, Bit5: Unused, Bit6: Unused, Bit7: Unused.

Data name: Game machine error status of game machine information (hall control / fraud monitoring information) Data length: 1 byte Byte order:-
Contents: Error code occurring in the gaming machine, Bit0-5: Error code, 0000000 = No error, Bit6: 0 = Frame control, 1 = Main control, Bit7: 0 = Notification only, 1 = Notification + Hall control Output, Bit0-7: 0 = No error occurred.

Data name: Fraud detection status 1 (main control) of gaming machine information (hall control / fraud monitoring information)
Data length: 1 byte Byte order:-
Contents: Bit0: Setting changing signal, Bit1: Setting confirmation signal, Bit2: RWM clear signal, Bit3: Fraud detection signal 1, Bit4: Fraud detection signal 2, Bit5: Fraud detection signal 3, Bit6: Unused, Bit7: unused.

Data name: Fraud detection status 2 (frame control) of gaming machine information (hall control / fraud monitoring information)
Data length: 1 byte Byte order:-
Contents: Bit0: Front decoration open, Bit1: Back mechanism open, Bit2: Unauthorized radio wave detection, Bit3: Game ball number clear detection, Bit4: Winning ball number abnormality 1 detection, Bit5: Winning ball number abnormality 2 detection, Bit6: Not yet Used, Bit7: Not used.

Data name: Fraud detection status 3 (frame control) of gaming machine information (hall control / fraud monitoring information)
Data length: 1 byte Byte order:-
Contents: Bit0: Small ball detection, Bit1: Iron ball detection, Bit2: Unused, Bit3: Unused, Bit4: Unused, Bit5: Unused, Bit6: Unused, Bit7: Unused.

Data name: Number of game information in game information Data length: 1 byte Byte order:-
Contents: Number of type information / count information (n), n = 0x00 to 0x0F (0 to 15).

Data name: Game information type information 1
Data length: 1 byte Byte order:-
Contents: Type information 1

Data name: Game information count information 1
Data length: 1 byte Byte order:-
Contents: Count information 1

Data name: Game information type information n
Data length: 1 byte Byte order:-
Contents: Type information n

Data name: Game information count information n
Data length: 1 byte Byte order:-
Contents: Count information n

[7.2.1.6.1 Main control state 1]
The details of each bit in the main control state 1 are the same as those shown in FIG. 263. Therefore, the description thereof will be omitted.
The gaming machine status signals 1 to 4 are used when setting a gaming machine state other than the jackpot 1, jackpot 2, and jackpot 3. The usage of the game machine status signals 1 to 4 differs depending on the model of the game machine.

[7.2.1.6.2 Main control state 2]
The details of each bit in the main control state 2 are the same as those shown in FIG. 264. Therefore, the description thereof will be omitted.

[7.2.11.6.3 Fraud detection state 1]
FIG. 322 is a diagram showing a fraud detection state 1.
The details of the fraud detection state 1 are as follows.
Bit: 0
Name: Setting changing signal Details: Indicates that the setting is being changed or the setting has been changed. It should be noted that the signal is continuously turned on from the setting change to the firing or counting after the setting change, and then the signal is turned off in 30 seconds. 0 = Normal, 1 = Setting change in progress and after setting change.

Bit: 1
Name: Setting confirmation signal Details: Indicates that the setting is being confirmed and the setting has been confirmed. It should be noted that the signal is continuously turned on from the setting confirmation to the firing or counting after the setting confirmation, and then the signal is turned off in 30 seconds. 0 = normal, 1 = during setting confirmation and after setting confirmation.

Bit: 2
Name: RWM clear signal Details: Indicates that RWM has been initialized. 0 = normal, 1 = RWM clear occurrence

Bit: 3
Name: Fraud detection signal 1 (*)
Details: In addition to the above, it indicates that there is a risk of fraud. 0 = normal, 1 = abnormal occurrence.

Bit: 4
Name: Fraud detection signal 2 (*)
Details: In addition to the above, it indicates that there is a risk of fraud. 0 = normal, 1 = abnormal occurrence.

Bit: 5
Name: Fraud detection signal 3 (*)
Details: In addition to the above, it indicates that there is a risk of fraud. 0 = normal, 1 = abnormal occurrence.

Bit: 6-7
Name: Unused Details: Fixed to 0

(*) The content of fraud detected differs depending on the type of gaming machine. Also, it is limited to gaming machines that have a function to detect various frauds.

[7.2.11.6.4 Fraud detection state 2]
FIG. 323 is a diagram showing a fraud detection state 2.
The details of the fraud detection state 2 are as follows.
Bit: 0
Name: Front decoration opening Details: Indicates that the front decoration opening has been detected. 0 = normal, 1 = front decoration open detection.

Bit: 1
Name: Opening of back mechanism Details: Indicates that opening of back mechanism has been detected. 0 = normal, 1 = back mechanism open detection.

Bit: 2
Name: Illegal radio wave detection Details: Indicates that an illegal radio wave was detected in the managed gaming machine frame. 0 = normal, 1 = illegal radio wave detection.

Bit: 3
Name: Game ball number clear detection Details: Indicates that the game ball number clear is detected. The signal is continuously turned on until the firing or counting after the number of game balls is cleared, and then the signal is turned off in 30 seconds. 0 = normal, 1 = clear detection of the number of game balls.

Bit: 4
Name: Abnormal number of winning balls 1 Detection Details: Indicates that the difference between the number of winnings detected by the main control and the number of winnings detected by the frame control is 100 or more. 0 = normal, 1 = abnormal number of winning balls 1 detected.

Bit: 5
Name: Abnormal number of winning balls 2 Detection Details: Indicates that the difference between the number of launched balls and the total number of returning balls (number of winning balls + number of non-winning balls) is 100 or more. 0 = normal, 1 = abnormal number of winning balls 2 detected

Bit: 6,7
Name: Unused Details: Fixed to 0

[7.2.1.6.5 Fraud detection state 3]
FIG. 324 is a diagram showing a fraud detection state 3.
The details of the fraud detection state 3 are as follows.
Bit: 0
Name: Small sphere detection Details: Indicates that a sphere of 10.7 mm or less was detected. 0 = normal, 1 = small ball detection.

Bit: 1
Name: Iron ball detection Details: Indicates that an iron ball has been detected. 0 = normal, 1 = iron ball detection.

Bit: 2-7
Name: Unused Details: Fixed to 0

[7.2.1.6.6 Game information]
The game information is composed of a total of 2 bytes of type information (upper 1 byte) and count information (lower 1 byte). The type information is information such as a winning opening winning a prize generated in a gaming machine. In addition, the count information is the number information generated in the type information.
The details of the game information are the same as the contents of FIG. 266. Therefore, the description thereof will be omitted.

[(1) Type information]
The details of the type information are the same as the contents of FIG. 267. Therefore, the description thereof will be omitted.

[(A) Details of data type (top 4 bits)]
FIG. 325 is a diagram showing details of data types (top 4 bits).
Bit 4-7: 0
Type name: Unused Contents:-

Bit 4-7: 1
Type name: Start-up opening prize Contents: Notify that the start-up opening has won a prize.

Bit 4-7: 2
Type name: Grand prize opening Winning content: Notify that the grand prize opening has been won.

Bit 4-7: 3
Type name: Winning opening Winning content: Notify that the winning opening has won a prize.

Bit 4-7: 4
Type name: Passing through the gate Contents: Notifying that the gate has passed.

Bit 4-7: 5-8
Type name: Unused Contents:-

Bit 4-7: 9
Type name: Number of times the symbol is confirmed Contents: Notifies the number of times the special symbol changes.

Bit 4-7: 10
Type name: Per special symbol Contents: Notifies that the special electric accessory is activated when the accessory continuous operation device is activated or the accessory continuous operation device is not activated.

Bit 4-7: 11
Type name: Unused Contents:-

Bit 4-7: 12
Type name: Number of characters (number of times the large winning opening is opened)
Contents: Notifies the opening of the big prize opening when the accessory continuous operation device is not operating.

Bit 4-7: 13
Type name: Passing through a specific area Contents: Notifying that a specific area has been passed.

Bit 4-7: 14
Type name: Preliminary content: Used when notifying data other than the data type "1-4, 9, 10, 12, 13". The usage of the spare differs depending on the model of the gaming machine.

Bit 4-7: 15
Type name: Unused Contents:-

[(B) Details of data number (lower 4 bits) set for each data type]
FIG. 326 is a diagram showing details of a data number (lower 4 bits) set for each data type.
The type information (1 byte) includes a data type (Bits 4 to 7) and a data number (Bits 0 to 3).

Data type (Bit4-7): 0 = unused Data number (Bit0-3): 0-15 = unused

Data type (Bits 4 to 7): 1 = Starting opening winning data number (Bits 0 to 3): Indicates a starting opening number. 1 = Starting port 1, 2 = Starting port 2, 3 = Starting port 3, 0 and 4 to 15 are unused.

Data type (Bits 4 to 7): 2 = Large winning opening winning data number (Bits 0 to 3): Indicates a large winning opening number. 1 = Large winning openings 1, 2 = Large winning openings 2, 0 and 3 to 15 = Unused.

Data type (Bits 4 to 7): 3 = Winning opening winning data number (Bits 0 to 3): Indicates a winning opening number. 1 to 15 = winning opening numbers 1 to 15, 0 = unused.

Data type (Bits 4 to 7): 4 = Gate passage data number (Bits 0 to 3): Indicates a passage gate number. 1 = Passing gate 1, 2 = Passing gate 2, 0 and 3 to 15 = Unused.

Data type (Bit4-7): 5-8 = Unused data number (Bit0-3):-

Data type (Bit4 to 7): 9 = Number of symbol confirmations Data number (Bit0 to 3): Indicates a special symbol number (special symbol number). 1 = special figure 1 (first special symbol), 2 = special figure 2 (second special symbol), 0 and 3 to 15 are unused.

Data type (Bit4 to 7): 10 = Data number per special symbol (Bit0 to 3): Indicates the type per special symbol. 1 = The accessory continuous operation device is activated (big hit), 2 = The special electric accessory is activated when the accessory continuous operation device is not activated (small hit), and 0 and 3 to 15 are unused.

Data type (Bit4 to 7): 11 = Unused data number (Bit0 to 3):-

Data type (Bit4 to 7): 12 = number of characters (number of times the large winning opening is opened)
Data number (Bits 0 to 3): Indicates a character number. 1 = Characters 1, 0 and 2 to 15 are unused.

Data type (Bit4 to 7): 13 = Passing through specific area Data number (Bit0 to 3): 1 = Specific area 1, 0 and 2 to 15 = Not used.

Data type (Bit4 to 7): 14 = Spare data number (Bit0 to 3): 1 to 4 = Spare number, 0 and 5 to 15 = Unused.

Data type (Bit4-7): 15 = unused Data number (Bit0-3): 0-15 = unused

[(2) Count information]
The setting contents of the count information differ depending on the data type.
The detailed contents and data storage example for each data type are shown below.

(A) When the data type is a start opening prize, a large winning opening winning, or a winning opening winning. FIG. 327 is a diagram showing details of count information.
The count information is composed of the number of prize balls (top 4 Bits, Bits 4 to 7) and the number of prizes (bottom 4 Bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) indicates the number of prize balls at the time of winning for each type information, and 1 to 15 = the number of prize balls (1 (pieces) to 15 (pieces)).
The number of prizes (Bits 0 to 3) indicates the number of prizes for each type information, and is fixed at 1 (pieces).

FIG. 328 is a diagram showing an example in the case where two prizes are won in the start opening 1 of the three prize balls in (Example 1) starting opening winning.
Game information: Game information 1
Data type of type information (1 byte) (Bit4 to 7): 1 = Starting opening prize Data number of type information (1 byte) (Bit0 to 3): 1 = Starting port 1
Number of prize balls (Bit4 to 7) of count information (1 byte): 3 = 3 prize balls Number of prizes of count information (1 byte) (Bit0-3): 1 = 1 prize

Game information: Game information 2
Data type of type information (1 byte) (Bit4 to 7): 1 = Starting opening prize Data number of type information (1 byte) (Bit0 to 3): 1 = Starting port 1
Number of prize balls (Bit4 to 7) of count information (1 byte): 3 = 3 prize balls Number of prizes of count information (1 byte) (Bit0-3): 1 = 1 prize Note that the game information is 0x1131. 2 data (game information 1, game information 2) are set.

FIG. 329 is a diagram showing an example in the case of (Example 2) winning a prize in the large winning opening 2 of 15 prize balls.

Game information: Game information 1
Type information (1 byte) data type (Bit4-7): 2 = Grand prize opening Type information (1 byte) data number (Bit0-3): 2 = Large winning opening 2
Number of prize balls (Bit4 to 7) of count information (1 byte): 15 = 15 prize balls Number of prize balls of count information (1 byte) (Bit0-3): 1 = 1 prize

Game information: Game information 2
Type information (1 byte) data type (Bit4-7): 2 = Grand prize opening Type information (1 byte) data number (Bit0-3): 2 = Large winning opening 2
Number of prize balls (Bit4 to 7) of count information (1 byte): 15 = 15 prize balls Number of prize balls of count information (1 byte) (Bit0-3): 1 = 1 prize

Game information: Game information 3
Type information (1 byte) data type (Bit4-7): 2 = Grand prize opening Type information (1 byte) data number (Bit0-3): 2 = Large winning opening 2
Number of prize balls (Bit4 to 7) of count information (1 byte): 15 = 15 prize balls Number of prize balls of count information (1 byte) (Bit0-3): 1 = 1 prize Note that the game information is 0x22F1. 3 data (game information 1, game information 2, game information 3) are set.

FIG. 330 is a diagram showing an example in which one prize is won in the winning opening 2 of one winning ball in (Example 3) winning opening winning.
Game information: Game information 1
Data type of type information (1 byte) (Bit4 to 7): 3 = Winning slot Data number of type information (1 byte) (Bit0 to 3): 2 = Winning slot 2
Number of prize balls in count information (1 byte) (Bit4 to 7): 1 = 1 prize balls Number of prize balls in count information (1 byte) (Bit0-3): 1 = 1 prize In game information, 0x3211 is 1 Data (game information 1) is set.

(B) When the data type passes through the gate FIG. 331 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and gate passage (lower 4 bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is unused and fixed at 0.
The number of winnings (Bits 0 to 3) indicates passing through the gate and is fixed at 1 (times).

FIG. 332 is a diagram showing an example in the case where the passage gate 1 is passed once in the passage through the gate (Example 1).
Game information: Game information 1
Data type of type information (1 byte) (Bit4 to 7): 4 = Gate passage Data number of type information (1 byte) (Bit0 to 3): 1 = Passage gate 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Passing through the gate of count information (1 byte) (Bit0 to 3): 1 = 1 times Passing game information 0x4101 is 1 data (game information 1) Set.

(C) When the data type is the number of times the symbol is confirmed FIG. 333 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of symbol confirmations (lower 4 bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is unused and fixed at 0.
The number of winnings (Bits 0 to 3) indicates the number of times the symbol is confirmed, and is fixed at 1 (times).

FIG. 334 is a diagram showing an example in which the special symbol 1 is stopped once in the number of times the symbol is confirmed (Example 1).
Game information: Game information 1
Type information (1 byte) data type (Bit4 to 7): 9 = number of symbol confirmations Type information (1 byte) data number (Bit0 to 3): 1 = special symbol 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Number of symbol confirmations of count information (1 byte) (Bit0 to 3): 1 = 1 stop Note that 0x9101 is 1 data (game). Information 1) Set.

(D) When the data type is per special symbol FIG. 335 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of hits (lower 4 bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is unused and fixed at 0.
The number of winnings (Bits 0 to 3) indicates the number of hits and is fixed at 1 (times).

FIG. 336 is a diagram showing an example in which (Example 1) the accessory continuous operation device is operated (big hit) and the accessory continuous operation device is operated once (big hit).
Game information: Game information 1
Type information (1 byte) data type (Bit4 to 7): 10 = per special symbol Type information (1 byte) data number (Bit0 to 3): 1 = jackpot count information (1 byte) unused (Bit4 to) 7): 0 fixed Count information (1 byte) hit count (Bit0 to 3): 1 = 1 occurrence Note that 0xA101 is set as 1 data (game information 1) for the game information.

FIG. 337 shows (Example 2) that the special electric accessory is activated (small hit) when the accessory continuous operating device is not activated, and the special electric accessory is activated once when the accessory continuous operating device is not activated. It is a figure which shows the example in the case of (small hit).
Game information: Game information 1
Type information (1 byte) data type (Bit4 to 7): 10 = per special symbol Type information (1 byte) data number (Bit0 to 3): 2 = small hit count information (1 byte) unused (Bit4) ~ 7): 0 fixed number of hits of count information (1 byte) (Bit0 to 3): 1 = 1 occurrence In the game information, 0xA201 is set as 1 data (game information 1).

(E) When the data type is the number of bonuses (the number of times the large winning opening is opened) FIG. 338 is a diagram showing the details of the count information.
The count information is composed of unused (upper 4 Bits, Bits 4 to 7) and the number of accessories (lower 4 Bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is unused and fixed at 0.
The number of winnings (Bits 0 to 3) indicates the number of bonuses, and is fixed at 1 (times).

FIG. 339 is a diagram showing an example in the case where the accessory 1 is opened once in the number of times of the accessory (Example 1).
Game information: Game information 1
Type information (1 byte) data type (Bit4 to 7): 12 = number of accessories Data number of type information (1 byte) (Bit0-3): 1 = accessory 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Number of bonuses (Bit0 to 3) of count information (1 byte): 1 = 1 times Opened Note that 0xC101 is 1 data (game) Information 1) Set.

(F) When the data type passes through a specific area FIG. 340 is a diagram showing details of count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and passage through a specific area (lower 4 bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is unused and fixed at 0.
The number of winnings (Bits 0 to 3) indicates passing through a specific area, and is fixed at 1 (times).

FIG. 341 is a diagram showing an example in the case of passing through the specific area passage 1 once in the passage through the specific area (Example 1).
Game information: Game information 1
Data type of type information (1 byte) (Bit 4 to 7): 13 = Passing through specific area Data number of type information (1 byte) (Bit 0 to 3): 1 = Specific area 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Number of bonuses (Bit0 to 3) of count information (1 byte): 1 = 1 pass In addition, 0xD101 is 1 data (game) in the game information. Information 1) Set.

(G) When the data type passes through a specific area FIG. 342 is a diagram showing details of count information.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and number of times (lower 4 bits, Bits 0 to 3).
The number of prize balls (Bits 4 to 7) is unused and fixed at 0.
The number of winnings (Bits 0 to 3) indicates the number of times and is fixed at 1 (times).

FIG. 343 is a diagram showing an example in the case where the spare 1 occurs once in the (example 1) spare.
Game information: Game information 1
Data type of type information (1 byte) (Bit4 to 7): 14 = Spare Data number of type information (1 byte) (Bit0 to 3): 1 = Spare 1
Unused count information (1 byte) (Bit4 to 7): Fixed to 0 Number of bonuses (Bit0 to 3) of count information (1 byte): 1 = 1 times In addition, 0xE101 is 1 data (game). Information 1) Set.

[7.2.2.2. Counting notification]
FIG. 344 is a diagram showing details of the count notification.
Telegram name: Count notification Telegram length: 7 bytes Transmission direction: Frame control → CM
Telegram summary: The frame control notifies the CM of the counting information by this telegram.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x07

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x02

[No3]
Data name: Total serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Number of counting balls Data length: 1 byte Byte order:-
Contents: Number of counting balls (0x00 to 0xFA (0 to 250 balls))

[No5]
Data name: Counting cumulative number of balls Data length: 2 bytes Byte order: L
Contents: Counting cumulative number of balls (0x00 to 0xFFFF (0 to 65535 balls)). The storage example is 0x1027 when the cumulative number of counting balls is 10,000.

[No6]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[7.2.2.1. Counting serial number (counting serial number 7.2.2.No3) notification)]
The frame control notifies the CM of the counting serial number (7.2.2.2 No3) by the following control.
(1) When the power is turned on, the serial number "0x00 (0)" is notified.
(2) After the power is turned on, the serial number is updated (+1) each time a notification is sent.
(3) The next value of the counting serial number "0xFF (255)" is updated (+2) to "0x01 (1)".

[7.2.2.2. Counting cumulative sphere (counting cumulative sphere (counting cumulative sphere (7.2.2.2 No5) notification)]
The frame control notifies the CM of the cumulative number of counting balls (7.2.2.2 No. 5) by the following control.
(1) The next value after the cumulative number of counting balls is "0xFFFF (65535 balls)" is updated to "0x0000 (0 balls)".
(2) When the power of the gaming machine is turned on, the cumulative number of balls counted is cleared to "0".

[7.2.3. Lending notice]
FIG. 345 is a diagram showing details of the loan notification.
Telegram name: Lending notification Telegram length: 5 bytes Transmission direction: CM → Frame control Telegram outline: CM notifies the frame control of lending information by this telegram.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x05

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x13

[No3]
Data name: Lending serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Number of rented balls Data length: 1 byte Byte order:-
Contents: Number of rented game balls (0x00 to 0xFF (0 to 255 balls))

[No5]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[About the behavior of frame control when the command "Lending notification" of "CM → Frame control" is received]
For example, when the number of game balls is 989999 and the number of rented balls of 10 balls is received, the number of balls is added up to 990000 and the information on the remaining number of balls is not discarded, and the number of game balls is 989999. It is possible to maintain the information up to and discard the information on the number of rented balls of 10 balls.
With this configuration, it is possible to respond to the frame control → CM with the result of receiving the number of loaned balls “abnormality (0x01)” and indicate that all the received information is not accepted.
If the process of adding 1 ball and discarding 9 balls is performed, the process becomes complicated because the information needs to be notified to the CM, but such complicated processing is complicated by discarding all the information. It is not necessary to provide processing.

[7.2.3.1. About loan notice (7.2.3.)]
When the CM receives the counting notification, the CM notifies the frame control of the lending notification.
However, if any of the following applies, the number of rented balls will be "0".
(1) When the gaming machine information notification has not been received (2) When the notification is made other than the gaming machine information type "0x02: Hall control / fraud monitoring information" (3) When the number of counting balls in the counting notification is "1" or more When notified The CM can notify the slot control of the number of rented balls "1" or more unless the above applies.

[7.2.3.2. About rental serial number (7.2.3.No3)]
The CM notifies the frame control of the lending serial number by the following control.
(1) At the time of frame control and communication start, the serial number is notified by "0".
(2) Update the loan serial number received in the loan receipt result response (+1) and notify in the next loan notification.
(3) The next value of the loan serial number "0xFF (255)" is updated (+2) to "0x01 (1)".

[7.2.4. Lending notification receipt result response]
FIG. 346 is a diagram showing details of the loan notification receipt result response.
Telegram name: Lending notification receipt result response Telegram length: 5 bytes Transmission direction: Frame control → CM
Telegram summary: The frame control responds to the CM with the receipt result of the loan information.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x05

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x03

[No3]
Data name: Lending serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Number of rented balls Received result Data length: 1 byte Byte order:-
Details: As a result of receiving the number of rented balls, 0x00 = normal, 0x01 = abnormal, and if a value other than the above is notified, it is considered abnormal.

[No5]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[7.2.4.1. About rental serial number (7.2.4.No3)]
The frame control responds to the CM with the following control.
(1) When the result of receiving the number of rented balls is normal (0x00), the rented serial number received from the CM is returned.
(2) When the loan receipt result is abnormal (0x01), the loan serial number received from the CM is returned when the loan receipt result is normal (0x00).
(3) When the power of the gaming machine is turned on, the rental serial number is cleared to "0".

[7.2.4.2. About the result of receiving the number of rented balls (7.2.4.No4)]
The frame control responds with the result of receiving the number of rented balls "abnormality (0x01)" in the following cases.
(1) When the lending serial number (7.2.3.No3) notified by the CM is not continuous (2) When the gaming machine is in the ball pulling operation (3) The number of lending balls is added to the number of gaming balls When the result exceeds 990000 balls

[8. Frame control and communication sequence between CMs]
[8.1. Basic communication sequence]
FIG. 347 is a diagram showing a basic communication sequence.
The frame control 3150 is the primary station, and the CM3072 is the secondary station.
[F200] The frame control 3150 transmits a gaming machine information notification (serial number = n) to CM3072.
[F201] The frame control 3150 transmits a counting notification (counting serial number = m) to CM3072.

[F202] CM3072 transmits a loan notification (lending serial number = k) to the frame control 3150.
[F203] The frame control 3150 transmits a loan receipt result response (lending serial number = k) to CM3072.
[F204] The frame control 3150 transmits a gaming machine information notification (serial number = n + 1) to CM3072.

The frame control 3150 notifies the CM 3072 of the gaming machine information notification (7.2.1.) At a cycle of 300ms (* 1), and from the gaming machine information notification (7.2.1.) To 100ms (* 2). ) After the lapse of time, a count notification (7.2.2.) Is notified.
The CM3072 notifies the frame control 3150 of the lending notification (7.2.3.) Within 170 ms after receiving the counting notification (7.2.2.).

The frame control 3150 responds to the loan notification (7.2.3.) From the CM3072 with a loan receipt result response (7.2.4.) Within 10 ms.

(* 1) The frame control 3150 notifies the gaming machine information notification within a range of 300 ms or more and 310 ms or less.
(* 2) The frame control 3150 notifies the counting notification within a range of 90 ms or more and 100 ms or less.

[8.2. Startup sequence]
[8.2.1. Sequence when the gaming machine is started first]
FIG. 348 is a diagram showing a sequence when the gaming machine is started first.
In the [F210] power off state, the VL of the [F211] frame control 3150 is OFF, and the VL and PSI of the [F212] CM3072 are OFF.

[F213] The power is turned on, and power is supplied to the frame control 3150 and CM3072.
[F214] The VL of the frame control 3150 is OFF, and the VL and PSI of the [F215] CM3072 are OFF. CM3072 sets VL = OFF until the start is completed.

[F216] The state in which the gaming machine is started is changed to the state in which the gaming machine is started [F217]. [F218] The frame control 3150 transmits a gaming machine information notification (serial number = 0) to CM3072. [F219] The frame control 3150 transmits a counting notification (counting serial number = 0) to CM3072. The gaming machine sends a telegram and updates the serial number to notify the CM3072 regardless of the completion of activation. However, since the CM 3072 is in the state where the [F220] CM is activated, the telegram from the gaming machine cannot be received.

[F221] The activation of CM3072 is completed.
As a result, [F222] the game ball can be launched (VL = ON), and the counting button becomes effective (PSI = ON).

[F223] The frame control 3150 transmits a gaming machine information notification (serial number = n) to CM3072.
[F224] The frame control 3150 transmits a counting notification (counting serial number = m) to CM3072.
The CM3072 that has been activated can receive these notifications.
After the activation is completed, the CM3072 starts receiving the telegram notified from the gaming machine. Manage from the notified serial number.

[8.2.2.2. Sequence when CM is started first]
FIG. 349 is a diagram showing a sequence when the CM is started first.
[F230] CM3072 is turned on while the frame control 3150 is turned off.
[F232] In CM3072, VL = OFF and PSI = OFF.
When the CM3072 shifts from the state in which the [F233] CM is started to the state in which the [F234] CM is started, VL = ON and PSI = ON in the [F235] CM3072. After that, the CM 3072 is in a state of waiting for the game machine connection [F236] until the game machine information notification is received.

When the power of the [F237] frame control 3150 is turned on and the state shifts from the state in which the [F238] gaming machine is started to the state in which the [F239] gaming machine is completed, VL = ON in the [F240] frame control 3150 and CM3072. PSI = ON.

[F241] The frame control 3150 transmits a gaming machine information notification (serial number = 0) to CM3072.
[F242] The frame control 3150 transmits a counting notification (counting serial number = 0) to CM3072.
The gaming machine notifies CM3072 of a telegram after the activation is completed. After the power is turned on, the serial number starts from 0.
The CM3072 starts receiving the telegram notified from the gaming machine. Manage from the notified serial number.

[F243] The frame control 3150 transmits a gaming machine information notification (serial number = n) to CM3072.
[F244] The frame control 3150 transmits a counting notification (counting serial number = m) to CM3072.

[8.3. Pachinko machine information notification sequence]
FIG. 350 is a diagram showing notification conditions applied in the gaming machine information notification sequence.
The frame control notifies the CM of the gaming machine information under the following notification conditions. If the notification conditions overlap, the notification will be given according to the priority.

Game machine information type: (1) Hall control / fraud monitoring information (with game information)
Notification condition: Notification is made at a cycle of 300 ms (* 1) from the completion of starting the gaming machine.
Priority: 1

Game machine information type: (2) Game machine installation information Notification condition: Notify after 60s (* 2) have passed since the start of the game machine was completed. After that, the notification is made in a cycle of 60s (* 2).
Priority: 2

Game machine information type: (3) Game machine performance information Notification condition: Notify after 180 s (* 3) have passed since the start of the game machine was completed. After that, the notification is made in a cycle of 180s (* 3).
Priority: 3

Game machine information type: (4) Hall control / fraud monitoring information (no game information)
Notification condition: Notifies every 300 ms (* 1) cycle from the completion of starting the gaming machine. After that, the notification is made in a cycle of 300 ms (* 1).
Priority: 4

[8.3.1. Basic sequence of game machine information notification (no game information)]
FIG. 351 is a diagram showing a basic sequence of game machine information notification (without game information).
When the activation of the [F250] gaming machine is completed, the [F251] frame control 3150 transmits the gaming machine information notification (hall control / fraud monitoring information (no game information)) to the CM3072.
Until this information is received, the CM3072 is in a state of waiting for the [F252] gaming machine connection.

[F253] The frame control 3150 transmits a counting notification to CM3072.
[F254] CM3072 transmits a loan notification to the frame control 3150.
[F255] The frame control 3150 transmits a loan receipt result response to CM3072.
[F256] The frame control 3150 transmits a gaming machine information notification (hall control / fraud monitoring information (no gaming information)) to CM3072.

[F257] The frame control 3150 transmits a gaming machine information notification (hall control / fraud monitoring information (no gaming information)) to CM3072.
[F258] The frame control 3150 transmits a counting notification to CM3072.
[F259] CM3072 transmits a loan notification to the frame control 3150.
[F260] The frame control 3150 transmits a loan receipt result response to CM3072.
[F261] The frame control 3150 transmits a game machine information notification (game machine installation information) to CM3072.

[F262] The frame control 3150 transmits a game machine information notification (game machine installation information) to CM3072. Here, since the notification timings of the gaming machine installation information and the gaming machine performance information overlap, the gaming machine installation information having a high priority is notified first.
[F263] The frame control 3150 transmits a counting notification to CM3072.
[F264] CM3072 transmits a loan notification to the frame control 3150.
[F265] The frame control 3150 transmits a loan receipt result response to CM3072.
[F266] The frame control 3150 transmits a gaming machine information notification (gaming machine performance information) to CM3072. Here, after notifying the gaming machine installation information, the gaming machine performance information is notified.

(* 1) The frame control 3150 notifies the hall control / fraud monitoring information within a range of 300 ms or more and 310 ms or less.
(* 2) The frame control 3150 notifies the gaming machine installation information within a range of 60s or more and 62s or less.
(* 3) The frame control 3150 notifies the gaming machine performance information within a range of 180s or more and 186s or less.

[8.3.2.2. When the hall control / fraud monitoring information (with game information) and the game machine installation information / game machine performance information overlap]
FIGS. 352 and 353 are diagrams showing a sequence when the hall controller / fraud monitoring information (with game information) and the game machine installation information / game machine performance information overlap.
When the activation of the [F270] gaming machine is completed, the [F271] frame control 3150 transmits the gaming machine information notification (hall control / fraud monitoring information (no game information)) to the CM3072.
Until this information is received, the CM3072 is in a state of waiting for the [F272] gaming machine connection.

[F273] The frame control 3150 transmits a counting notification to CM3072.
[F274] CM3072 transmits a loan notification to the frame control 3150.
[F275] The frame control 3150 transmits a loan receipt result response to CM3072.
[F276] The frame control 3150 transmits a gaming machine information notification (hall control / fraud monitoring information (no gaming information)) to CM3072.

[F277] The frame control 3150 transmits a gaming machine information notification (hall control / fraud monitoring information (with gaming information)) to CM3072. If the game information is retained at the timing of notifying the game machine installation information, the hall control / fraud monitoring information is notified first.
[F278] The frame control 3150 transmits a counting notification to CM3072.
[F279] CM3072 transmits a loan notification to the frame control 3150.
[F280] The frame control 3150 transmits a loan receipt result response to CM3072.
[F281] The frame control 3150 transmits a game machine information notification (game machine installation information) to CM3072. When the retained game information is exhausted, the game machine installation information is notified.

[F282] The frame control 3150 transmits a gaming machine information notification (hall control / fraud monitoring information (no gaming information)) to CM3072.
[F283] The frame control 3150 transmits a counting notification to CM3072.
[F284] CM3072 transmits a loan notification to the frame control 3150.
[F285] The frame control 3150 transmits a loan receipt result response to CM3072.
[F286] The frame control 3150 transmits a gaming machine information notification (hall control / fraud monitoring information (with gaming information)) to CM3072. If the game information is retained at the timing of notifying the game machine performance information, the hall control / fraud monitoring information is notified.

[F287] The frame control 3150 transmits a counting notification to CM3072.
[F288] CM3072 transmits a loan notification to the frame control 3150.
[F289] The frame control 3150 transmits a loan receipt result response to CM3072.
[F290] The frame control 3150 transmits a gaming machine information notification (gaming machine performance information) to CM3072. When the retained game information is exhausted, the game machine performance information is notified.

(* 1) The frame control 3150 notifies the hall control / fraud monitoring information within a range of 300 ms or more and 310 ms or less.
(* 2) The frame control 3150 notifies the gaming machine installation information within a range of 60s or more and 62s or less.
(* 3) The frame control 3150 notifies the gaming machine performance information within a range of 180s or more and 186s or less.

[8.4. Counting notification sequence]
354 and 355 are diagrams showing a count notification sequence.
[F300] It is assumed that the press of the count button is detected in the frame control 3150.
At this point, [F301] the number of game balls = 1000, and [F302] the number of balls held = 100.

[F303] The frame control 3150 transmits a gaming machine information notification (serial number = n, number of gaming balls = 1000) to CM3072.
[F304] The frame control 3150 transmits a counting notification (counting serial number = m, counting ball number = 250, counting cumulative ball number = 250) to CM3072. The frame control 3150 notifies the counting (counting serial number = m, number of counting balls = 250, cumulative number of counting balls = 250). The CM3072 adds the number of counting balls to the number of balls held (number of balls held = 100 + 250).
At this point, [F305] the number of game balls = 750, and [F306] the number of balls held = 350.

[F307] The CM3072 transmits a lending notification (lending serial number = k, number of lending balls = 0) to the frame control 3150.
[F308] The frame control 3150 transmits a loan receipt result response (loan serial number = k, loan ball number receipt result = normal) to CM3072.

[F309] The frame control 3150 transmits a gaming machine information notification (serial number = n + 1, number of gaming balls = 750) to CM3072.
[F310] The frame control 3150 transmits a counting notification (counting serial number = m + 1, number of counting balls = 250, cumulative number of counting balls = 500) to CM3072. The frame control 3150 notifies the counting (counting serial number = m + 1, number of counting balls = 250, cumulative number of counting balls = 500). The CM3072 adds the number of counting balls to the number of balls held (number of balls held = 350 + 250).
At this point, [F311] number of game balls = 500, and [F312] number of balls held = 600.

[F313] The CM3072 transmits a lending notification (lending serial number = k + 1, number of lending balls = 0) to the frame control 3150.
[F314] The frame control 3150 transmits a loan receipt result response (lending serial number = k + 1, loan ball number receipt result = normal) to CM3072.

[F315] It is assumed that the frame control 3150 detects that the counting button is released (not pressed).
[F316] The frame control 3150 transmits a gaming machine information notification (serial number = n + 2, number of gaming balls = 500) to CM3072.
[F317] The frame control 3150 transmits a counting notification (counting serial number = m + 2, number of counting balls = 0, cumulative number of counting balls = 500) to CM3072.
At this point, [F318] the number of game balls = 500, and [F319] the number of balls held = 600.

[F320] CM3072 transmits a lending notification (lending serial number = k + 2, number of lending balls = 0) to the frame control 3150.
[F321] The frame control 3150 transmits a loan receipt result response (lending serial number = k + 2, loan ball number receipt result = normal) to CM3072.
[F322] The frame control 3150 transmits a gaming machine information notification (serial number = n + 3, number of gaming balls = 500) to CM3072.
(* 1) The frame control 3150 notifies the counting notification within a range of 90 ms or more and 100 ms or less.

[8.5. Lending notification sequence]
FIG. 356 is a diagram showing a loan notification sequence.
[F330] It is assumed that the press of the lending button is detected in CM3072.
At this point, [F331] the number of game balls = 50. The lending button can be a ball lending button in the case of a managed gaming machine, and can be a medal lending button in the case of a medalless gaming machine.

[F332] The frame control 3150 transmits a gaming machine information notification (serial number = n, number of gaming balls = 50) to CM3072.
[F333] The frame control 3150 transmits a counting notification (counting serial number = m, counting number of balls = 0, counting cumulative number of balls = 0) to CM3072.

[F334] CM3072 transmits a lending notification (lending serial number = k, number of lending balls = 125) to the frame control 3150. CM3072 notifies the loan (lending serial number = k, number of rented balls = 125). DC notifies in the range of 1 ball to 125 balls.
[F335] The frame control 3150 transmits a loan receipt result response (loan serial number = k, loan ball number receipt result = normal) to CM3072. The frame control 3150 adds the number of rented balls to the number of game balls (number of game balls = 50 + 125) and responds with the result of receiving the number of rented balls (lending serial number = k, result of receiving the number of rented balls = normal). CM3072 confirms the result of receiving the number of rented balls.

[F336] The frame control 3150 transmits a gaming machine information notification (serial number = n + 1, number of gaming balls = 175) to CM3072.
At this point, [F337] number of game balls = 175.
(* 1) The frame control 3150 notifies the gaming machine information notification within a range of 300 ms or more and 310 ms or less.

[8.6. Recovery sequence when the dedicated cable is broken]
357 and 358 are diagrams showing a recovery sequence when the dedicated cable is broken.
At the first time point, [F340] number of game balls = 175.
[F341] The frame control 3150 transmits a gaming machine information notification (serial number = n, number of gaming balls = 1000) to CM3072.
[F342] The frame control 3150 transmits a counting notification (counting serial number = m, counting ball number = 0, counting cumulative ball number = 0) to CM3072.

[F343] The CM3072 transmits a lending notification (lending serial number = k, number of lending balls = 0) to the frame control 3150.
[F344] The frame control 3150 transmits a loan receipt result response (loan serial number = k, loan ball number receipt result = normal) to CM3072.
[F345] The frame control 3150 transmits a gaming machine information notification (serial number = n + 1, number of gaming balls = 1000) to CM3072.

[F346] Here, it is assumed that the dedicated cable 3110 is broken. The CM3072 notifies the DC of the disconnection of the dedicated cable and sets VL = OFF.

As a result, in the [F347] frame control 3150, VL = OFF (unable to fire), and in the [F348] CM3072, VL = OFF (unable to fire) and PSI = OFF (counting button disabled).

[F349] The frame control 3150 transmits a counting notification (counting serial number = m + 1, number of counting balls = 0, cumulative number of counting balls = 0) to CM3072. Since the counting button is invalid, the number of counting balls is 0, and the number of counting balls is notified (counting serial number = m + 1, number of counting balls = 0, cumulative number of counting balls = 0). However, this notification does not reach CM3072.

[F350] The frame control 3150 transmits a gaming machine information notification (serial number = n + 2, number of gaming balls = 1000) to CM3072. However, this notification does not reach CM3072.
At this point, [F351] the number of game balls = 1000.

[F351] The frame control 3150 transmits a counting notification (counting serial number = m + 2, number of counting balls = 0, cumulative number of counting balls = 0) to CM3072. However, this notification does not reach CM3072.

[F353] Here, it is assumed that the dedicated cable 3110 has been restored. In the frame control 3150 and CM3072, VL = ON (launching permission state of the game ball) and PSI = ON (counting button enabled state). Check the number of game balls by the clerk processing and recover the error. CM3072 confirms the dedicated cable connection status after VL = ON.

[F354] The frame control 3150 transmits a gaming machine information notification (serial number = n + 3, number of gaming balls = 1000) to CM3072.
[F355] The frame control 3150 transmits a counting notification (counting serial number = m + 3, number of counting balls = 0, cumulative number of counting balls = 0) to CM3072.

[F356] The CM3072 transmits a lending notification (lending serial number = 0, number of lending balls = 0) to the frame control 3150. When the connection with the gaming machine is started, the rental serial number 0 is notified.
At this point, [F357] the number of game balls = 1000.
[F358] The frame control 3150 transmits a loan receipt result response (lending serial number = k, loan ball number receipt result = abnormality) to CM3072.

[F359] The frame control 3150 transmits a gaming machine information notification (serial number = n + 4, number of gaming balls = 1000) to CM3072.
[F360] The frame control 3150 transmits a counting notification (counting serial number = m + 4, number of counting balls = 0, cumulative number of counting balls = 0) to CM3072.

[F361] CM3072 transmits a lending notification (lending serial number = k + 1 (= 1), number of lending balls = 0) to the frame control 3150. It is a loan in response to the loan receipt result. Update the serial number and notify.
[F362] The frame control 3150 transmits a loan receipt result response (lending serial number = k + 1, loan ball number receipt result = normal) to CM3072.

[8.7. Communication error during counting]
359 and 360 are diagrams showing communication abnormalities during counting.
[F370] It is assumed that the press of the count button is detected in the frame control 3150.
At this point, [F371] the number of game balls = 1000, and [F372] the number of balls held = 100.

[F373] The frame control 3150 transmits a gaming machine information notification (serial number = n, number of gaming balls = 1000) to CM3072.
[F374] The frame control 3150 transmits a counting notification (counting serial number = m, counting ball number = 250, counting cumulative ball number = 250) to CM3072. The frame control 3150 notifies the counting (counting serial number = m, counting ball number = 250). The CM3072 adds the number of counting balls to the number of balls held (number of balls held = 100 + 250).
At this point, [F375] the number of game balls = 750, and [F376] the number of balls held = 350.

[F377] CM3072 transmits a lending notification (lending serial number = k, number of lending balls = 0) to the frame control 3150.
[F378] The frame control 3150 transmits a loan receipt result response (loan serial number = k, loan ball number receipt result = normal) to CM3072.

[F379] The frame control 3150 transmits a gaming machine information notification (serial number = n + 1, number of gaming balls = 750) to CM3072.
[F380] The frame control 3150 transmits a counting notification (counting serial number = m + 1, number of counting balls = 250, cumulative number of counting balls = 500) to CM3072. The frame control 3150 notifies the counting (counting serial number = m + 1, counting ball number = 250). However, this notification does not reach CM3072.
At this point, [F381] the number of game balls = 500, and [F382] the number of balls held = 350.

[F383] The frame control 3150 transmits a gaming machine information notification (serial number = n + 2, number of gaming balls = 500) to CM3072. However, this notification does not reach CM3072. The CM3072 detects a communication abnormality in the gaming machine information notification, and sets VL = OFF after a maximum of 300 ms.

In the [F384] frame control 3150, VL = OFF (unable to fire), and in the [F385] CM3072, VL = OFF (unable to fire) and PSI = OFF (disabled count button).

At this point, [F386] number of game balls = 500.
[F387] The frame control 3150 transmits a counting notification (counting serial number = m + 2, number of counting balls = 0, cumulative number of counting balls = 500) to CM3072. Since the counting button is invalid, the number of counting balls is 0 (counting serial number = m + 2, the number of counting balls = 0, the cumulative number of counting balls = 500). However, this notification does not reach CM3072.

[F388] CM3072 is in a state of waiting for DC error recovery. Check the number of game balls and the number of balls you have by the clerk processing, and recover the error. The CM sets VL = ON after the DC recovers from the error.

(* 1) The frame control 3150 notifies the gaming machine information notification within a range of 300 ms or more and 310 ms or less.
(* 2) The frame control 3150 notifies the counting notification within a range of 90 ms or more and 100 ms or less.

[8.8. Communication error at the time of lending]
FIG. 361 is a diagram showing a communication abnormality at the time of lending.
[F400] It is assumed that the press of the lending button is detected in CM3072.
At this point, [F401] the number of game balls = 50.

[F402] The frame control 3150 transmits a gaming machine information notification (serial number = n, number of gaming balls = 50) to CM3072.
[F403] The frame control 3150 transmits a counting notification (counting serial number = m, counting ball number = 0, counting cumulative ball number = 0) to CM3072.

[F404] The CM3072 transmits a lending notification (lending serial number = k, number of lending balls = 125) to the frame control 3150. CM3072 notifies the loan (lending serial number = k, number of rented balls = 125). DC will notify in the range of 1 ball to 125 balls depending on the ball rental unit price and loan amount. The loan notification is preferably transmitted within 170 ms after receiving the count notification.
At this point, [F405] the number of game balls = 175.

[F406] The frame control 3150 transmits a loan receipt result response (loan serial number = k, loan ball number receipt result = normal) to CM3072. However, this response does not reach CM3072. CM3072 determines that the loan has not been completed because the response to the loan receipt result has not been received within a predetermined time (for example, within 10 ms).

[F407] The frame control 3150 transmits a gaming machine information notification (serial number = n + 1, number of gaming balls = 175) to CM3072.
[F408] The frame control 3150 transmits a counting notification (counting serial number = m + 1, number of counting balls = 0, cumulative number of counting balls = 0) to CM3072.

[F409] CM3072 transmits a lending notification (lending serial number = k, number of lending balls = 125) to the frame control 3150. I don't know if the loan notification I notified last time has reached the frame control, so I will resend it. The loan notification is preferably transmitted within 170 ms after receiving the count notification.
At this point, [F410] number of game balls = 175.

[F411] The frame control 3150 transmits a loan receipt result response (lending serial number = k, loan ball number receipt result = abnormality) to CM3072. The frame control 3150 checks the continuity of the lending serial number of the lending notification, and if it is not continuous, responds with an abnormality. If the serial number matches the previous lending notice, the CM3072 determines that the lending notice has reached the frame control and completes the lending.

At this point, [F412] number of game balls = 175.
[F413] The frame control 3150 transmits a gaming machine information notification (serial number = n + 2, number of gaming balls = 175) to CM3072.
(* 1) The frame control 3150 notifies the gaming machine information notification within a range of 300 ms or more and 310 ms or less.

[Chapter 5]
[Power supply unit for lower launch management game machines]
[1 Outline / Scope of application]
This chapter describes the performance and functions of the power supply unit of the lower launch management gaming machine.
The power supply unit uses a colored resin case provided with heat dissipation holes.

[2 External dimensions / weight]
FIG. 362 is a diagram showing the external dimensions and weight of the power supply unit.
The external dimensions of the power supply unit product (whole including the case) are Y mm in length, X mm in width, and Z mm in height, and the substrate of the power supply unit is 162 mm in length and 179 mm in width. XYZ is at least a value that can accommodate the substrate. (Note 1) It is variable depending on the case design.
The weight is Ag (Agram). A is the weight of the product including the case.

[3 input specifications]
[3.1 Input power supply specifications]
FIG. 363 is a diagram showing input power supply specifications of the power supply unit.
The input voltage is AC85V to 115V.
The frequency is 47 Hz to 63 Hz.
The inrush current is 28A.
The efficiency is 86% or more.

(Note 1) AC200V input protection function is available.
When the protection function is operating, there is a concern that the protective parts will deteriorate, so the parts will be replaced instead of automatic recovery.
(Note 2) AC100V input, 100% duty rated load (200VA at the output of the DC36V generator), cold start values.
The power re-on (OFF / ON) is specified by an ON time of 3 seconds and an OFF time of 1 second.
(Note 3) AC100V input, 100% duty rated load (200VA at the output section of the DC36V generator). Efficiency (%) = total output power ÷ active power x 100.

[3.2 Input signal specifications]
FIG. 364 is a diagram showing input signal specifications of the power supply unit.
The power cutoff switch stops all power output when it detects a cutoff. After that, even if the cutoff release is detected, the power is not output and the power OFF state is maintained. It is valid only when the power switch is ON. The power OFF state is released by turning the power switch ON / OFF.

[4 output specifications]
[4.1 Output power supply specifications]
365 and 366 are diagrams showing the output power supply specifications of the power supply unit.
The output voltages are DC5V-1, DC12V-1, DC36V-1, DC12V-2, and DC36V-2.
Output fluctuations (Note 1) are ± 5%, ± 5%, ± 5%, ± 5%, and ± 7%.
The ripple voltage (Note 1) is 1% or less of the output voltage and 2% or less of the output voltage.
The minimum output current is 0A.
The rated output current (Note 2) is 2.0A, 4.0A, 2.5A, 10.0A, 6.0A.
The maximum output current (Note 3) is 2.5A, 5.0A, 4.0A, 10.0A, 6.0A.
The rated output power (Note 4) is 200VA.
The maximum output power (Note 5) is 300 VA.

The circuit type is separated from a DC-DC converter, a DC-DC converter, an AC-DC converter, a DC-DC converter, and a DC36V-1.
Overcurrent protection (including short-circuit protection) is available (Note 6) over 2.6A, Yes (Note 6) over 5.1A, Yes (Note 6) 8A, Yes (Note 6) Over 10.1A, Yes (Note 6) Note 6) 8A.
Overvoltage protection is available (Note 7).
Overheat protection is available (Note 8).
The momentary power failure holding time (AC cutoff detection time) is 25 ms.
For details of the output retention time, rise time, and fall time, refer to [4.2 Timing Chart].

(Note 1) This is the value at the rated output of 100% Duty for each power supply system alone. Sudden load changes are in the range of 50-100%.
(Note 2) This is the value at the rated output of 100% Duty for each power supply system alone.
(Note 3) This is a value for each power supply system alone.
(Note 4) This is a numerical value at the output of the DC36V generator with AC100V input and DUTY100%.
(Note 5) This is a numerical value at the output of the DC36V generator with AC100V input. However, if a certain condition is exceeded, DC12V-2 / DC36V-2 is stopped by the overload protection function. The operation of the output power (output of the DC36V generator with AC100V input) is as follows.
(1) At 200VA or less, output is possible at 100% duty and the protection function does not work (point A in the graph).
(2) When 300VA is continuously output for X seconds or more, DC12V-2 / DC36V-2 is stopped by the protection function.
(3) In the range of 201VA-300VA, it is necessary to adjust the duty so that the calorific value is equivalent to the point A in the graph shown in FIG. 366 (detection is the current value of the DC36V generator). If the same amount of heat is reached without adjusting the duty (ii), the protection function stops DC12V-2 / DC36V-2.
(Note 6) An IC, protection element or protection circuit is installed. The overcurrent value of DC5V-1 / DC12V-1 / DC12V-2 is definitely set to a value larger than the maximum output current value (overcurrent protection does not work at the maximum output current value). Even if an IC / circuit with an overcurrent protection function is provided, a short-circuit protection function is installed.
(Note 7) A protection element or protection circuit is installed.
(Note 8) Equipped with a protection function that stops the AC-DC converter with a thermal switch or the like.

[4.2 Power supply and signal timing chart]
FIG. 367 is a diagram showing a power supply and a signal timing chart.
The DC5V-1 / DC12V-1 / DC36V-1, DC12V-2 / DC36V-2, power failure detection signal (Note 1), and reset signal (Note 1) are the timing charts (1) to (4) shown below. Refer to. The numerical value is an AC100V input and a 100% duty rated load (200VA at the output of the DC36V generator).
(Note 1) Although the power failure detection signal and the reset signal are generated by the frame control board, they are described for reference because they are related to the holding time of DC5V-1. The detected voltage value and the specified time are the design values.

[(1) Rise characteristics (when the power is started)]
FIG. 368 is a diagram showing a rising characteristic (when the power supply is started).
AC-IN (100V) (50Hz / 60Hz) rises in a sinusoidal shape and rises from the time when the power supply is started.
DC36V-1 and DC36V-2 rise in a parabolic shape, and when the rise is 200 ms or less, the rate is 10% → 90%.
DC12V-1 and DC12V-2 rise linearly, and when the rise is 200 ms or less, the rate is 10% → 90%.
DC5V-1 rises linearly, and when the rise is 35 ms or less, it changes from 10% to 90%.
The power failure detection signal rises vertically after a predetermined time elapses (type: 130 ms, 100 to 200 ms) after DC36V-1 and DC36V-2 exceed 28.6 V.
The reset signal rises vertically after a predetermined time has elapsed (type: 380 ms, 300 to 500 ms) after the power failure detection signal becomes “H (ON)”.

As described above, when the voltage value of DC36V-1 or the like exceeds 28.6V, the power failure detection signal and the reset signal are released "H" after the lapse of the specified time.

[(2) Falling characteristics (when power is cut off)]
FIG. 369 is a diagram showing a falling characteristic (when the power is cut off).
AC-IN (100V) (50Hz / 60Hz) goes down when the power is cut off.
DC36V-1 descends in a straight line 25 to 35 ms after the power is cut off.
The DC12V-1 descends in a straight line after the DC36V-1 begins to descend.
DC5V-1 descends linearly 10 ms or more after DC36V-1 drops to 28 V.
DC36V-2 descends in a straight line like DC36V-1.
DC12V-2 descends in a straight line like DC12V-1.
The power failure detection signal falls vertically when DC36V-1 drops to 28V.
The reset signal falls vertically after the power failure detection signal falls, after a specified time elapses (type: 170 ms, 120 to 250 ms), or after the DC5V-1 drops.

After the momentary power failure holding time (25 ms to 35 ms) elapses, the voltage of DC36V-1 drops.
When the voltage value of DC36V-1 drops to 28V, the power off detection signal for determining the power off state becomes active (GND).
The DC5V-1 holds a voltage of 10 ms or more after detecting (active) the power failure detection signal.
Unlike DC5V-1, DC12V-1 and DC12V-2 do not hold voltage.
The reset signal becomes GND when a specified time elapses or the 5V power supply drops after the detection of the power supply cutoff detection signal.

[(3) At the time of instantaneous power failure-1 (when less than 25 ms)]
It holds all power output (DC5V-1, DC12V-1, DC36V-1, DC12V-2, DC36V-2).

[(4) At the time of instantaneous power failure-2 (when DC36V-1 cannot be completely lowered in 25 ms or more and DC5V-1 is retained)]
FIG. 370 is a diagram showing a momentary power failure-2 (when DC36V-1 cannot be completely lowered in 25 ms or more and DC5V-1 is retained).
AC-IN (100V) (50Hz / 60Hz) goes down during a momentary power failure. When the momentary power outage is released, it rises in a cosine wave.
DC36V-1 descends in a straight line 25 to 35 ms after a momentary power failure. When the momentary power failure is canceled, it rises in a straight line.
The DC12V-1 descends slightly in a straight line after the DC36V-1 begins to descend. When the momentary power failure is canceled, it rises in a straight line.
DC5V-1 does not fall.
DC36V-2 descends in a straight line like DC36V-1. When the momentary power outage is released, it rises in a cosine wave. When the momentary power outage is released, it rises in a cosine wave.
DC12V-2, like DC12V-1, descends slightly in a straight line. When the momentary power failure is canceled, it rises in a straight line.
The power failure detection signal falls vertically when DC36V-1 drops to 28V. After the momentary power failure is canceled and DC36V-1 exceeds 28.6V, it rises vertically after a lapse of a predetermined time (type: 130ms, 100 to 200ms).
The reset signal falls vertically after the power failure detection signal falls, after a specified time elapses (type: 170 ms, 120 to 250 ms), or after the DC5V-1 drops. After the momentary power failure is canceled and the power failure detection signal becomes "H (ON)", the vehicle rises vertically after a predetermined time has elapsed (type: 380 ms, 300 to 500 ms).

After the momentary power failure holding time (25 ms to 35 ms) elapses, the voltage of DC36V-1 drops.
When the voltage value of DC36V-1 drops to 28V, the power failure detection signal becomes active (GND).
The reset signal becomes GND after a lapse of a specified time after the detection of the power failure detection signal.
When the voltage value of DC36V-1 that has dropped after the AC input is restored exceeds 28.6V, the power supply cutoff detection signal and the reset signal become "H" after the lapse of the specified time.

[(5) During a momentary power failure-2 (when DC36V-1 drops over 25 ms and DC5V-1 is not retained)]
After the falling characteristic of (2) above, the rising characteristic of (1) above is obtained.

[5 connector specifications]
[5.1 CN1: Connection part 1]
FIG. 371 is a diagram showing the specifications of CN1: connecting component 1.
Pin No: 1
Signal name: AC100V-N
Signal content: AC100V input (ground side)
Remarks:-

Pin No: 2
Signal name: AC100V-L
Signal content: AC100V input (non-grounded side)
Remarks:-

Pin No: 3
Signal name: FG
Signal content: Frame GND
Remarks:-

[5.2 CN2: Connection part 2]
FIG. 372 is a diagram showing the specifications of CN2: connecting component 2.
Pin No: 1, 2
Signal name: GND
Signal content: GND
Remarks:-

Pin No: 3,4
Signal name: DC36V-1
Signal content: Main system 36V power supply Remarks:-

Pin No: 5, 6
Signal name: GND
Signal content: GND
Remarks:-

Pin No: 7,8,9,10
Signal name: DC12V-1
Signal content: Main system 12V power supply Remarks:-

Pin No. 11,12
Signal name: GND
Signal content: GND
Remarks:-

Pin No. 13,14
Signal name: DC5V-1
Signal content: Main system 5V power supply Remarks:-

Pin No. 15,16
Signal name: GND
Signal content: GND
Remarks:-

[5.3 CN3: Connection part 3]
FIG. 373 is a diagram showing the specifications of CN3: connecting component 3.
Pin No: 1, 2
Signal name: GND
Signal content: GND
Remarks: Supplied to the game board

Pin No: 3, 4, 5, 6
Signal name: DC36V-2
Signal content: Sub system 36V power supply Remarks: Supply to the game board

Pin No: 7,8,9,10
Signal name: GND
Signal content: GND
Remarks: Supplied to the game board

Pin No. 11,12,13,14
Signal name: DC12V-2
Signal content: Sub system 12V power supply (Note 1)
Remarks: Supplied to the game board

Pin No. 15,16
Signal name: GND
Signal content: GND
Remarks: Supplied to the game board

Pin No: 17,18
Signal name: GND
Signal content: GND
Remarks: Supplied to the gaming machine frame

Pin No: 19, 20, 21 and 22
Signal name: DC12V-2
Signal content: Sub system 12V power supply (Note 1)
Remarks: Supplied to the gaming machine frame

Pin No: 23, 24
Signal name: GND
Signal content: GND
Remarks: Supply to the gaming machine frame (Note 1) The same power is supplied to both the gaming board and the gaming machine frame.

[5.4 CN4: Connection part 4]
FIG. 374 is a diagram showing the specifications of CN4: connecting component 4.
Pin No: 1, 2
Signal name: FG2
Signal content: Frame GND
Remarks: Connect with main drawer connector

[5.5 CN5: Connection part 5]
FIG. 375 is a diagram showing the specifications of CN5: connecting component 5.
Pin No: 1
Signal name: FG3
Signal content: Frame GND
Remarks: Connected to the metal part of the gaming machine frame

[5.6 CN6: Connection part 6]
FIG. 376 is a diagram showing the specifications of CN6: connecting component 6.
Pin No: 1
Signal name: FG1
Signal content: Frame GND
Remarks: Connected to the metal part of the gaming machine frame

[5.7 CN7: Connection part 7]
FIG. 377 is a diagram showing the specifications of CN7: connecting component 7.
Pin No: 1
Signal name: GND
Signal content: GND
Remarks: Connect with power cutoff switch

Pin No: 2
Signal name: Power cutoff switch Signal content: Power cutoff switch ("L": power output, "H": power off)
Remarks: Connect with power cutoff switch

[6 Insulation specifications]
FIG. 378 is a diagram showing insulation specifications of the power supply unit.
The withstand voltage (between input and FG) is "there is no abnormality when AC1000V is applied for 1 minute".
The withstand voltage (between input and output) is "there is no abnormality when AC1000V is applied for 1 minute".
The remarks of the dielectric strength are 50 / 60Hz and the cutoff current is 20mA.
The insulation resistance is 1 MΩ or more when DC 500 V is applied.
The leakage current is 1 mA or less at AC100 V input. The remarks of the leakage current are 50 / 60Hz.

[7 Environmental specifications]
FIG. 379 is a diagram showing the environmental specifications of the power supply unit.
The operating environment temperature is 0 to 50 ° C.
The operating environment humidity is 20 to 90%. The remarks of the operating environment humidity are "no condensation" and "50% at high temperature".
The storage environment temperature is −10 to 60 ° C.
The storage environment humidity is 20 to 90%. The remarks of the storage environment humidity are "no condensation" and "50% at high temperature".

[8 standards]
FIG. 380 is a diagram showing a standard of a power supply unit.
The safety standard is "Compliant with the Electrical Appliance and Material Safety Law".
The noise terminal voltage is "compliant with the Electrical Appliance and Material Safety Law".
Unwanted radiation is "VCCI Class A compliant".
The static electricity is "single unit: IEC61000-4-2 compliant" and "embedded: compliant with the static electricity test on a gaming machine". The remarks of static electricity are "single unit: contact 8 kV, air 15 kV, indirect 15 kV" and "embedded: contact 20 kV, air 20 kV, indirect 20 kV".

[9 power supply configuration diagram]
FIG. 381 is a diagram showing a power supply configuration diagram of the power supply unit.
The power supply unit 5000 includes an AC100V, a signal input unit / grounding processing unit output unit 5100, a DC36V generation unit 5200, a main control board power supply generation unit 5300, a production board power supply generation unit 5400, and other output units 5500.

The AC100V and the signal input unit / ground processing unit output unit 5100 include a power switch 5101, a fuse 5102, a filter 5103, an inrush power protection 5104, a surge / overvoltage protection 5105, a noise filter 5106, a noise filter 5107, and a power cutoff switch 5108. There is.

The DC36V generator 5200 includes an input rectifying smoothing 5201, an AC / DC current protection overvoltage protection DC output stop 5202, an isolation transformer 5203, an output rectifying smoothing 5204, and a feedback circuit 5205.
An overvoltage protection 5206, an overheat protection thermal switch 5207, and an overload protection power output cutoff 5208 are connected to the DC36V generator 5200.

The power generation unit 5300 for the main control board includes a short-circuit protection 5301, a short-circuit protection 5302, a 12V generation 1DC / DC current current protection 5306, and a surge / overvoltage protection 5307.

The power supply generation unit 5400 for the effect board includes a short-circuit protection 5401, a 36V generation 2 separation circuit 5402, a short-circuit protection 5403, a 12V generation 2DC / DC overcurrent protection 5404, and a surge / overvoltage protection 5405.

Other output units 5500 include DC36V-1 (2.5A) LED5501, DC12V-1 (4A) LED5502, DC5V-1 (2A) LED5503, DC36V-2 (6A) LED5504, and DC12V-2 (10A) LED5505. I have.

The power from AC100V-L and AC100V-N is transmitted to the input rectifying smoothing 5201 and the overvoltage protection 5206 via the power switch 5101, the fuse 5102, the filter 5103, and the inrush power protection 5104.
A surge / overvoltage protection 5105, a noise filter 5106, a noise filter 5107, an FG (AC100V), an FG1, an FG2, and an FG3 are connected between the fuse 5102 and the filter 5103.

The power transmitted to the input rectifying smoothing 5201 and the overvoltage protection 5206 is passed through the AC / DC current protection overvoltage protection DC output stop 5202, the insulation transformer 5203, and the output rectifying smoothing 5204, and then the feedback circuit 5205 and the overcurrent protection overvoltage protection. It is transmitted to 5206, overload protection power output cutoff 5208, short circuit protection 5301, short circuit protection 5302, short circuit protection 5305, short circuit protection 5401, and short circuit protection 5403.

Power or signal from the feedback circuit 5205, overcurrent protection overvoltage protection 5206, overheat protection thermal switch 5207, power cutoff switch 5108 is transmitted to the AC / DC current protection overvoltage protection DC output stop 5202.

The power transmitted to the short circuit protection 5301 is transmitted to the DC36V-1 (2.5A) LED5501.
The power transmitted to the short circuit protection 5302 is transmitted to the DC12V-1 (4A) LED5502 via the 12V generated 1DC / DC overcurrent protection 5303 and the surge / overvoltage protection 5304.
The power transmitted to the short circuit protection 5305 is transmitted to the DC5V-1 (2A) LED 5503 via the SV generation 1DC / DC overcurrent protection 5306 and the surge / overvoltage protection 5307.

The power transmitted to the short-circuit protection 5401 and the power transmitted to the overload protection power output cutoff 5209 are transmitted to the DC36V-2 (6A) LED5504 via the 36V generation 2 separation circuit 5402.
The power transmitted to the short circuit protection 5403 and the power transmitted to the overload protection power output cutoff 5209 are DC12V-2 via the 12V generated 2DC / DC overcurrent protection 5604 and the surge / overvoltage protection 5405. (10A) It is transmitted to LED5505.

[10 Connector and switch component layout]
FIG. 382 is a diagram showing a component layout diagram of a connector and a switch of the power supply unit.
The upper side in the figure is the upper part of the back surface of the gaming machine, the right side in the figure is the hinge side of the back surface of the gaming machine, the lower side in the figure is the lower part of the back surface of the gaming machine, and the left side in the figure is the back surface of the gaming machine. It is the opening and closing side.
The vertical length A of the substrate of the power supply unit is, for example, 162 mm.
The horizontal length B of the substrate of the power supply unit is, for example, 179 mm.

Seven connectors are arranged on the upper part of the board of the power supply unit.
CN6, CN1, CN4, CN5, CN7, CN2, and CN3 are arranged in order from the left side of the figure.
The details of the seven connectors are as follows.
CN1: AC100V power plug connector 5601
CN2: Main system power output connector 5602
CN3: Sub system power output connector 5603
CN4: FG connector 5604 that connects to the main drawer connector
CN5: FG connector 5605 that connects to the metal part of the lifting unit
CN6: FG connector 5606 that connects to the metal part of the gaming machine frame
CN7: Connector 5607 that connects to the power cutoff switch

[Chapter 6]
[Hard interface specifications]
[(1) Main control board-frame control board interface]
The game board of the lower launch management gaming machine and the main control board and the frame control board, which are the main systems of the gaming machine frame, are connected by a drawer connector 36 pin.
The pin layout specifications and circuit configuration of the connector are as follows.

[(A) Connector pin layout specifications]
FIG. 383 is a diagram showing a connector pin arrangement specification of the drawer connector 36 pin.
Pin No: 1, 2
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 3, 4, 5
Signal: DC36V-1
Contents: Main system 36V power supply Direction: Frame → Board (Frame control board → Main control board)
Active:-
Remarks:-

Pin No: 6,7,8
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 9,10
Signal: BU power supply Contents: Backup power supply (5V) used in the main control board
Direction: Frame → Board Active:-
Remarks:-

Pin No. 11,12
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin Nos. 13, 14, 15, 16
Signal: DC12V-1
Contents: Main system 12V power supply Direction: Frame → Board Active:-
Remarks:-

Pin No: 17,18
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 19
Signal: Frame upper open switch signal Contents: Signal to detect the opening of the frame upper part (front frame) Direction: Frame → Board Active: H: Open, L: Close Remarks: (* 1)

Pin No: 20
Signal: Frame lower part open switch signal Contents: Signal to detect the opening of the frame lower part (front frame or back mechanism) Direction: Frame → Board Active: H: Open, L: Close Remarks: (* 1)

Pin No: 21 and 22
Signal: Power failure detection signal (* 4)
Contents: Signal to detect power failure Direction: Frame → Board Active: H: Release, L: Detection Remarks: (* 1)

Pin No: 23
Signal: CTX1
Contents: Asynchronous serial signal transmitted by the main control board Direction: Board → frame (main control board → frame control board)
Active: (* 2)
Remarks: (* 3)

Pin No: 24
Signal: CRX1
Contents: Asynchronous serial signal received by the main control board Direction: Frame → Board Active: (* 2)
Remarks: (* 1)

Pin No: 25
Signal: RAM clear signal Contents: RAM clear signal for main control Direction: Frame → Board Active: H: Not pressed, L: Pressed Remarks: (* 1)

Pin No: 26
Signal: Launch stop signal Contents: Signal to stop launch on the main control board Direction: Board → Frame Active: H: Launchable, L: Stop Remarks: (* 3)

Pin No: 27,28
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 29,30
Signal: DC5V-1
Contents: Main system 5V power supply Direction: Frame → Board Active:-
Remarks:-

Pin No: 31, 32
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 33,34
Signal: FG
Contents: Frame GND
Direction:-
Active:-
Remarks:-

Pin No: 35, 36
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

(* 1) The active rule is the main control board input section that is pulled up by a resistor. The signal is output from the frame control board by a transistor array or the like.
(* 2) Follow the commands in the software interface specifications.
(* 3) The active rule is the frame control board input section that is pulled up by a resistor. The signal is output from the main control board by an open collector (drain).
(* 4) The reset release of the frame control CPU is performed within 300 to 500 ms from the release (rise) of the power failure detection signal.

[(B) Circuit configuration]
FIG. 384 is a diagram showing a circuit configuration of an interface between the main control board and the frame control board.
The circuit configuration of the interface between the main control board and the frame control board is as follows.
The CPU 6201 (frame control board CPU) of the frame control board 6200 transmits the CRX1 to the main control board 6400 via the IC2 (inversion buffer), the IC3, and the main drawer connector harness board 6300.

The transistor 6401 of the main control board 6400 transmits CTX1 to the CPU 6201 via the main drawer connector harness board 6300, R1, TC4 / R2 / C1 (CR filter forward rotation buffer), and IC1 (UART expansion IC). To do.

The transistor 6402 of the main control board 6400 transmits a firing stop signal to the main drawer connector harness board 6300, R1, IC2 / R3 / C2 (CR filter inversion buffer).

The RAM clear signal from the RAM clear switch 6207 of the frame control board 6200 is transmitted to the frame control board CPU via R1, IC2 / R3 / C2 (CR filter inversion buffer), and further, IC3 and the main drawer connector harness. -It is transmitted to the main control board 6400 via the board 6300.

The frame upper opening switch signal from the frame upper opening switch 6210 is transmitted to the frame control board CPU via the relay board 6212, R1, IC2 / R3 / C2 (CR filter inversion buffer), and further, the IC3 and the main drawer connector. -It is transmitted to the main control board 6400 via the harness board 6300.

The frame lower opening switch signal from the frame lower opening switch 6211 is transmitted to the frame control board CPU via the relay board 6212, R1, IC2 / R3 / C2 (CR filter inversion buffer), and further, the IC3 and the main drawer connector. -It is transmitted to the main control board 6400 via the harness board 6300.

The power failure detection signal from the power failure detection unit 6203 of the frame control board 6200 is transmitted to the main control board 6400 via the IC2 (inverting buffer), IC3, and the main drawer connector harness board 6300.

The DC36V-1 from the power supply unit 6100 is transmitted to the main control board 6400 via the main drawer connector, harness, and board 6300.
The DC12V-1 from the power supply unit 6100 is transmitted to the main control board 6400 via the main drawer connector, harness, and board 6300.
The DC5V-1 from the power supply unit 6100 is transmitted to the main control board 6400 via the main drawer connector, harness, and board 6300. Further, DC5V-1 from the power supply unit 6100 is transmitted to the frame control board CPU via D1, C3 (backup power generation) and D1 of the frame control board 6200, and further, the main drawer connector harness board 6300. Is transmitted to the main control board 6400 via.
The GND of the power supply unit 6100 is connected to the main control board 6400 via the main drawer connector, harness, and board 6300.
The FG of the power supply unit 6100 is connected to the game board FG connection portion 6500 via the FG harness of the main drawer connector / harness / board 6300 and the main control board 6400.

FIG. 385 is a diagram showing constants and model names of parts used in the circuit configuration of the interface between the main control board and the frame control board.
Part number: IC1
Constant or part name: Predetermined part 1

Part number: IC2
Constant or part name: Predetermined part 2

Part number: IC3
Constant or part name: Predetermined part 3

Part number: IC4
Constant or part name: Predetermined part 4 (may be the same part as the predetermined part 2)

Part number: R1
Constant or part name: 4.7 kΩ

Part number: R2
Constant or part name: 100Ω

Part number: R3
Constant or part name: 1kΩ

Part number: C1
Constant or part name: 100pF

Part number: C2
Constant or part name: 0.1 μF

Part number: C3
Constant or part name: 0.47F

Part number: D1
Constant or part name: Predetermined part 5

(* 1) The frame control board side is pulled up to 5V with a resistor R1. Further, a CR filter is formed by the resistor R2 and the capacitor C1, and a forward rotation buffer or the like (IC4) is inserted.

(* 2) The frame control board side is pulled up to 5V with a resistor R1. Further, a CR filter is formed by the resistor R3 and the capacitor C2, and an inverting buffer (IC2) is inserted.

(* 3) An electric double layer capacitor C3 is used to generate a backup power supply. Although the frame control CPU and the main control CPU share the backup power supply, the diode D1 is inserted into the frame control CPU side to separate the backup power supply.

(* 4) Since the transistor array IC3 outputs from the frame control board, the resistance value on the main control board side is preferably 4.7 k to 10 kΩ in the case of 5 V. When another power source is used, it is preferable that the resistance value has a current value of 0.5 to 1 mA.

(* 5) An open collector (drain) output transistor or FET (including a network product) is preferable.

(* 6) The FG connection of the game board may be configured to connect directly from the main drawer connector board to the metal part of the game board.

[Chapter 7]
[(2) Production control board-Other production device interface]
The game board of the management game machine and the effect control board of the sub system of the game machine frame and the other effect devices are connected by a drawer connector 40 pin.
The pin layout specifications and circuit configuration of the connector are as follows.

[(A) Connector pin layout specifications]
FIG. 386 is a diagram showing a connector pin arrangement specification of the drawer connector 40 pin.
Pin No: 1, 2
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 3, 4, 5, 6
Signal: DC36V-2
Contents: Sub system 36V power supply (for game board)
Direction: Frame → Board (Frame control board → Main control board)
Active:-
Remarks:-

Pin No: 7,8,9,10
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No. 11,12,13,14
Signal: DC12V-2
Contents: Sub system 12V power supply (for game board)
Direction: Frame → Board Active:-
Remarks:-

Pin No. 15, 16, 17, 18
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 19
Signal: CS1
Contents: Chip select signal Direction: Board → Frame (Main control board → Frame control board)
Active: H
Remarks: * 1

Pin No: 20
Signal: CLK1
Contents: Clock signal Direction: Board → Frame Active: Rise Remarks: * 1

Pin No: 21
Signal: SOD1
Contents: Serial output data signal Direction: Board → Frame Active: H
Remarks: * 1

Pin No: 22
Signal: SID1
Contents: Serial input data signal Direction: Frame → Board Active: H
Remarks: * 3

Pin No: 23
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 24
Signal: CS2
Contents: Chip select signal Direction: Board → Frame Active: L
Remarks: * 2

Pin No: 25
Signal: CLK2
Contents: Clock signal Direction: Board → Frame Active: Rise Remarks: * 2

Pin No: 26
Signal: SOD2
Contents: Serial output data signal Direction: Board → Frame Active: H
Remarks: * 2

Pin No: 27
Signal: SID2
Contents: Serial input data signal Direction: Frame → Board Active: H
Remarks: * 3

Pin No: 28
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 29
Signal: PIO1
Contents: Parallel I / O data signal Direction: Frame → Board, Board → Frame Active:-
Remarks: * 4

Pin No: 30
Signal: PIO2
Contents: Parallel I / O data signal Direction: Frame → Board, Board → Frame Active:-
Remarks: * 4

Pin No: 31, 32
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

Pin No: 33
Signal: SP3 +
Contents: Audio signal for lower speaker + Side direction: Board → Frame Active:-
Remarks: * 5

Pin No: 34
Signal: SP3-
Contents: Audio signal for lower speaker-Side direction: Board → Frame Active:-
Remarks: * 5

Pin No: 35
Signal: SP2 +
Contents: Audio signal for left speaker + Side direction: Board → Frame Active:-
Remarks: * 5

Pin No: 36
Signal: SP2-
Contents: Audio signal for left speaker-Side direction: Board → Frame Active:-
Remarks: * 5

Pin No: 37
Signal: SP1 +
Contents: Audio signal for right speaker + Side direction: Board → Frame Active:-
Remarks: * 5

Pin No: 38
Signal: SP1-
Contents: Audio signal for right speaker-Side direction: Board → Frame Active:-
Remarks: * 5

Pin No: 39,40
Signal: GND
Contents: GND
Direction:-
Active:-
Remarks:-

(* 1) The active rule is the lower unit board input section that is pulled up by a resistor. The signal is output from the game board in CMOS 5V.
(* 2) The active rule is the lower unit board input section pulled down by a resistor. The signal is output from the game board in CMOS 5V.
(* 3) The active regulation is taken from the production control board input section of the game board. The signal is output from the lower unit board in CMOS 5V.
(* 4) Parallel input / output signals that are not controlled by serial input / output.
(* 5) This is the layout when the gaming machine is viewed from the front.

[(B) Circuit configuration]
FIG. 387 is a diagram showing a circuit configuration of an interface between the effect control board and other effect devices.
The circuit configuration of the interface between the effect control board and other effect devices is as follows.
The effect control board 7100 (effect control board CPU) passes the CS1 / CLK1 / SOD1 stored in the buffer 7901 via the sub drawer connector harness board 7200, the front frame sub relay board 7300, and the effect control board 7100 R1. Then, it is transmitted to IC3 / D1 (ESD protection polarity switching) of the lower unit board 7401 of the effect control board 7100.

Information from IC3 / D1 (ESD protection polarity switching) of the lower unit board 7401 passes through R1 of the upper unit board 7402 and IC3 / D1 (ESD protection buffer) of the upper unit board 7402, and IC2 of the upper unit board 7402. It is transmitted to (LED driver).
Information from IC3 / D1 (ESD protection buffer) of the upper unit board 7402 is transmitted to IC3 / D1 (ESD protection polarity switching) of the effect control board 7100.
Similar control is executed for the left unit board 7403 and the right unit board 7404.

Information (CS1, CLK1, SOL1) from IC3 / D1 (ESD protection polarity switching) of the lower unit board 7401 is transmitted to the effect switch unit 7405 via IC2 (LED driver).

Information (negative CS1, CLK1, SOL1) from IC3 / D1 (ESD protection polarity switching) of the lower unit board 7401 passes through IC1 (I / O expander) and IC4 / IC5 (vibration circuit), and is an effect switch. It is transmitted to unit 7405.

The information (SID1) from the cross key switch unit 7406 is transmitted to IC3 / D1 (ESD protection polarity switching) of the lower unit board 7401 via IC1 (I / O expander).

Information (SOD1) from IC3 / D1 (ESD protection polarity switching) of the lower unit board 7401 is transmitted to the buffer 7902 via the sub drawer connector harness board 7200.

The CS2 / CLK2 / SOD2 from the sub drawer connector harness board 7200 is transmitted to the upper unit board 7402 via the lower unit board 7401.
The SID 2 from the upper unit board 7402 is transmitted to the sub drawer connector harness board 7200 via the lower unit board 7401.

PI01 / PI02 from the sub-drawer connector harness board 7200 is transmitted to the upper unit board 7402 via the lower unit board 7401.
The PI01 / PI02 from the sub-drawer connector harness board 7200 is transmitted to the buffer 7903 of the effect control board 7100.

The SP1 + / SP1- from the audio amplifier 7104 of the effect control board 7100 is transmitted to the right speaker 7407 via the sub drawer connector harness board 7200, the lower unit board 7401, and the upper unit board 7402.

The SP2 + / SP2- from the audio amplifier 7104 of the effect control board 7100 is transmitted to the left speaker 7408 via the sub drawer connector harness board 7200, the lower unit board 7401, and the upper unit board 7402.

The SP3 + / SP3- from the audio amplifier 7104 of the effect control board 7100 is transmitted to the lower speaker 7409 via the sub drawer connector harness board 7200.

The DC38V-2 from the power supply unit 7500 is transmitted to the effect control board 7100 via the sub drawer connector harness board 7200.
The DC12V-2 from the power supply unit 7500 is transmitted to the effect control board 7100 via the sub drawer connector harness board 7200.
The power supply unit 7500 and the effect control board 7100 are connected by a GND.

FIG. 388 is a diagram showing constants and model names of parts used in the circuit configuration of the effect control board-other effect device-to-device interface.
Part number: IC1
Constant or part name: Predetermined part A

Part number: IC2
Constant or part name: Predetermined part B

Part number: IC3
Constant or part name: Schmidt buffer

Part number: IC4
Constant or part name: optional

Part number: IC5
Constant or part name: optional

Part number: D1
Constant or part name: ESD element

Part number: R1
Constant or part name: 4.7 kΩ

(* 1) Output from the game board with CMOS 5V, and pull down the lower unit board side to GND with 4.7kΩ. In addition, an ESD element and a buffer for noise suppression are inserted.
(* 2) The IC3 matches the input logic of the LED driver and I / O expander in the subsequent stage.
(* 3) Serial output is performed from the lower unit board and the expansion board. It is preferable to pull up the effect control board side of the game board.

(* 4) No parts are connected to the parallel input / output signals for expansion.
(* 5) No parts are connected to the speaker signal.
(* 6) SPI signals for input / output expansion and parallel input / output signals are wired on each unit board.

(* 7) 5V is generated from DC12V-2 on each unit board in consideration of expandability.
(* 8) The left unit and the right unit have the same configuration as the upper unit, so the description is omitted.

[(B) Terminal processing when not in use]
The SPI signals (CS2, CLK2, SOD2, SID2) and parallel input / output signals (PIO1, PIO2) are connected to the power supply and GND with a diode at the edge of the decorative substrate of the front frame.
When not in use and when in use, pull-down processing is executed at the end of the game board.

FIG. 389 is a diagram showing an outline of pull-down processing when not in use and when in use.
As shown in (A) in the figure, when the sub-drawer substrate 7202 is not in use, the sub-drawer substrate 7202 is set to GND, and a pull-down process (a process of installing a pull-down resistor) is performed on the upper unit substrate 7402 and the left unit substrate 7403.
On the other hand, as shown in (B) in the drawing, when the sub drawer board 7202 is used and the right unit board 7404 is the transmission end and the reception end, pull-down processing is performed on the upper unit board 7402 and the left unit board 7403. At the same time, the right unit board 7404, which is the transmission end and the reception end, is designated as GND.

[(C) Outline of input function of adjustment switch and effect switch]
(A) Specifications The adjustment switch and the effect switch correspond to the SPI signals of 19-pin "CS1", 20-pin "CLK1", and 22-pin "SID1" of the connector pin arrangement specifications of the effect control board-other effect device interface. There is.
The I / O expander with a built-in serial interface that can set the address in the lower unit board converts the four adjustment switches and effect switches on the top, bottom, left, and right into serial signals and sends them to the effect control board via the sub drawer connector. There is.
Details such as electrical characteristics, timing and sequence of serial data depend on the I / O expander.

(B) Block diagram FIG. 390 is a diagram showing a block diagram including an adjustment switch and the like.
The management gaming machine 500 includes an effect control board 7100 having a control circuit 7101 (effect control CPU, etc.), a front frame sub relay board 7300 of a sub drawer connector board, and a lower unit board 7401 having an I / O expander 7430. ..
The adjustment switch upper 7421, the adjustment switch lower 7422, the adjustment switch left 7423, the adjustment switch right 7424, and the effect switch 7425 are connected to the lower unit board 7401.

Signals (GPA0, GPA1, GPA2, GPA3, GPA4) from the adjustment switch up 7421, the adjustment switch down 7422, the adjustment switch left 7423, the adjustment switch right 7424, and the effect switch 7425 are transmitted to the I / O expander 7430 and down. It is transmitted to the control circuit 7101 via the unit board 7401, the front frame sub relay board 7300 of the sub drawer connector board, and the effect control board 7100.

[(D) Outline of vibration function of production switch unit]
(A) Specifications The effect switch unit supports SPI signals of 19-pin "CS1", 20-pin "CLK1", and 21-pin "SOD1", which are the connector pin arrangement specifications of the effect control board-other effect device interface.
The I / O expander with a built-in serial interface that can set the address in the lower unit board controls the ON / OFF of the vibration motor and the strength of the vibration by the SPI signal from the effect control board of the game board.
Details such as electrical characteristics, timing and sequence of serial data depend on the I / O expander.
Fixed values are set on the gaming machine frame side for the strength and weak duty ratio and the operating time per day.

(B) Block diagram FIG. 391 is a diagram showing a block diagram including an effect switch unit and the like.
The management game machine 500 has an effect control board 7100 having a control circuit 7101 (effect control CPU, etc.), a front frame sub relay board 7300 of a sub drawer connector board, an I / O expander 7430, and a control circuit 7431 of a vibration motor. It includes a unit board 7401.
An effect switch unit 7440 having an effect switch substrate 7441 and a vibration motor 7442 is connected to the lower unit substrate 7401.

Signals from the control circuit 7101 of the production control board 7100 (GPB0 (motor ON / OFF), GPB1 (vibration strength)) are the front frame sub-relay board 7300, I / O expander 7430, vibration of the sub-drawer connector board. It is transmitted to the vibration motor 7442 via the motor control circuit 7431 and the effect switch board 7441.

[(E) Outline of LED control of front frame and production switch unit]
(A) Specifications The managed gaming machine is equipped with 161 full-color LEDs and 17 white LEDs on the front frame. The full-color LED can control RGB independently, and the number of systems is 171 for the full-color LED, 6 for the white LED, and 177 for the whole.

The LED control is performed by the LED driver IC whose address can be set, and eight LED driver ICs are used in the front frame.
The LED control signals correspond to the signals of 19-pin "CS1", 20-pin "CLK1", and 21-pin "SOD1" of the connector pin specifications of the effect control board-other effect device interface.

Regarding the adjustment of the white color mixing ratio (R = 26mA, G = 22mA, B = 12mA) of the full-color LED, R: G: B = 2: 2: 1 is set as an approximate color mixing ratio with an external current limiting resistor. doing. Since the LED driver used is a constant current drive system, output duty control is possible.

FIG. 392 is a diagram showing a list of LEDs and control specifications.
The list of LEDs and control specifications is as follows.
The number of mounted LEDs is 178 in total.
Among them, 161 full-color LEDs and 17 white LEDs.

The number of LED systems is 171 for full-color LEDs (57 systems x 3: RGB) and 6 for white LEDs (6 systems x 1: W).

The total number of LED drivers used is eight.
As the communication method, SPI communication (with address setting) is used as a whole.

FIG. 393 is a diagram showing a block diagram of LED control of the front frame.
(B) Block diagram The block diagram of the LED control in the front frame is as follows.
The front frame includes a lower unit board 7401, a left unit board 7403, a right unit board 7404, an upper unit board 7402, and an effect switch board 7441, and LEDs are mounted on each board.
The numbers shown in the figure (Example 1- (1)) correspond to (c) LED arrangement and system diagram described later.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 1 of the lower unit board 7401. The LED driver 1 of the lower unit board 7401 controls eight LEDs (1- (1) to (3)) of the effect switch board 7441 and 13 LEDs (1- (4) to (8)) of the lower unit board 7401. ..

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 2 of the lower unit board 7401. The LED driver 2 of the lower unit board 7401 controls 22 LEDs (2- (1) to (8)) of the lower unit board 7401.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 3 of the left unit board 7403. The LED driver 3 of the left unit board 7403 controls 22 LEDs (3- (1) to (8)) of the left unit board 7403.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 4 of the left unit board 7403. The LED driver 4 of the left unit board 7403 controls 18 LEDs (4- (1) to (6)) of the left unit board 7403.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 5 of the right unit board 7404. The LED driver 5 of the right unit board 7404 controls 22 LEDs (5- (1) to (8)) of the right unit board 7404.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 6 of the right unit board 7404. The LED driver 6 of the right unit board 7404 includes 18 LEDs (6- (1) to (6)) of the right unit board 7404 and 17 LEDs (6- (7) to (12)) of the right unit board 7404. Control.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 7 of the lower unit board 7401. The LED driver 7 of the lower unit board 7401 controls 20 LEDs (7- (1) to (7)) of the lower unit board 7401.

CS1, CLK1, and SOD1 from the effect control board 7100 are transmitted to the LED driver 8 of the lower unit board 7401. The LED driver 8 of the lower unit board 7401 controls 18 LEDs (8- (1) to (6)) of the lower unit board 7401.

(* 1) LEDs 0 to LED 23 are output signal names of the LED driver.
(* 2) Only the LED driver 6 has a mixture of constant current control (full-color LED) and constant voltage control (white LED).

[(C) LED arrangement and system diagram]
FIG. 394 is a diagram showing an LED arrangement and a system diagram.
The LED arrangement and system diagram of the front frame are as follows.
The numbers shown on each LED (Example 1- (1)) are assigned to the LED driver output of (d) described later.

LED1- (1), LED1- (2), and LED1- (3) are arranged in order from the left side on the central member 7600 of the front frame.

In the lower member 7601 of the front frame, LEDs1- (4) to LED1- (8) are arranged on the left side, and LEDs2- (1) to LED2- (8) are arranged on the center and the right side.

On the left member 7602 of the front frame, LEDs3- (1) to LED3- (7) are arranged on the lower side, and LEDs4- (1) to LED4- (6) are arranged on the upper side.

On the right member 7603 of the front frame, LEDs5- (1) to LED5- (8) are arranged on the lower side, and LEDs6- (1) to LED6- (12) are arranged on the upper side. As for the LED 6, some LEDs are arranged on the lower side.

LEDs8- (1) to LED1- (6) are arranged on the left side of the upper member 7604 of the front frame, and LEDs7- (1) to LED7- (7) are arranged on the right side.

[(D) Correspondence between LED system diagram and LED driver]
FIG. 395 is a diagram showing the correspondence between the LED system diagram and the LED driver.
The driver address values and output assignments to the LED system diagram are as follows.
The lower unit board and the effect switch board include a driver 1 and a driver 2.
The LED addresses are 11H and 12H, respectively.

The left unit board includes a driver 3 and a driver 4.
The LED addresses are 13H and 14H, respectively.

The right unit board includes a driver 5 and a driver 6.
The LED addresses are 15H and 16H, respectively.

The upper unit board includes a driver 7 and a driver 8.
The LED addresses are 17H and 18H, respectively.

[LED driver output]
When LED0 is transmitted to the driver 1, 1- (1) B lights up.
When LED0 is transmitted to the driver 2, 2- (1) B lights up.
When LED0 is transmitted to the driver 3, 3- (1) B lights up.
When LED0 is transmitted to the driver 4, 4- (1) B lights up.
When LED0 is transmitted to the driver 5, 5- (1) B lights up.
When LED0 is transmitted to the driver 6, 6- (1) B lights up.
When LED0 is transmitted to the driver 7, 7- (1) B lights up.
When LED0 is transmitted to the driver 8, 8- (1) B lights up.

When the LED 1 is transmitted to the driver 1, 1- (1) G lights up.
When the LED 1 is transmitted to the driver 2, 2- (1) G lights up.
When the LED 1 is transmitted to the driver 3, 3- (1) G lights up.
When the LED 1 is transmitted to the driver 4, 4- (1) G lights up.
When the LED 1 is transmitted to the driver 5, 5- (1) G lights up.
When the LED 1 is transmitted to the driver 6, 6- (1) G lights up.
When the LED 1 is transmitted to the driver 7, 7- (1) G lights up.
When the LED 1 is transmitted to the driver 8, 8- (1) G lights up.

When the LED 2 is transmitted to the driver 1, 1- (1) R lights up.
When the LED 2 is transmitted to the driver 2, 2- (1) R lights up.
When the LED 2 is transmitted to the driver 3, 3- (1) R lights up.
When the LED 2 is transmitted to the driver 4, 4- (1) R lights up.
When the LED 2 is transmitted to the driver 5, 5- (1) R lights up.
When the LED 2 is transmitted to the driver 6, 6- (1) R lights up.
When the LED 2 is transmitted to the driver 7, 7- (1) R lights up.
When the LED 2 is transmitted to the driver 8, 8- (1) R lights up.

When the LED 3 is transmitted to the driver 1, 1- (2) B lights up.
When the LED 3 is transmitted to the driver 2, 2- (2) B lights up.
When the LED 3 is transmitted to the driver 3, 3- (2) B lights up.
When the LED 3 is transmitted to the driver 4, 4- (2) B lights up.
When the LED 3 is transmitted to the driver 5, 5- (2) B lights up.
When the LED 3 is transmitted to the driver 6, 6- (2) B lights up.
When the LED 3 is transmitted to the driver 7, 7- (2) B lights up.
When the LED 3 is transmitted to the driver 8, 8- (2) B lights up.

When the LED 4 is transmitted to the driver 1, 1- (2) G lights up.
When the LED 4 is transmitted to the driver 2, 2- (2) G lights up.
When the LED 4 is transmitted to the driver 3, 3- (2) G lights up.
When the LED 4 is transmitted to the driver 4, 4- (2) G lights up.
When the LED 4 is transmitted to the driver 5, 5- (2) G lights up.
When the LED 4 is transmitted to the driver 6, 6- (2) G lights up.
When the LED 4 is transmitted to the driver 7, 7- (2) G lights up.
When the LED 4 is transmitted to the driver 8, 8- (2) G lights up.

When the LED 5 is transmitted to the driver 1, 1- (2) R lights up.
When the LED 5 is transmitted to the driver 2, 2- (2) R lights up.
When the LED 5 is transmitted to the driver 3, 3- (2) R lights up.
When the LED 5 is transmitted to the driver 4, 4- (2) R lights up.
When the LED 5 is transmitted to the driver 5, 5- (2) R lights up.
When the LED 5 is transmitted to the driver 6, 6- (2) R lights up.
When the LED 5 is transmitted to the driver 7, 7- (2) R lights up.
When the LED 5 is transmitted to the driver 8, 8- (2) R lights up.

Hereinafter, similarly, when the output signal of the LED is transmitted to the driver, the LED lights up according to the contents shown in the figure. LEDs 0 to 23 are output signal names of the LED driver. Some combinations of LEDs 0 to 23 and the driver are unused.

[(F) Outline of audio output function]
(A) Specifications In the management gaming machine, one magnetically shielded speaker is mounted on the lower part of the front frame, and one speaker is mounted on each side of the front frame (two in total). The audio (speaker) signal is 33-pin "SP3 +", 34-pin "SP3-", 35-pin "SP2 +", 36-pin "SP2-", 37-pin, which are the connector pin layout specifications of the production control board-other production device interface. Corresponding to "SP1 +" and 38-pin "SP7-", when the game machine is viewed from the front, SP3 is the lower speaker, SP2 is the left speaker, and SP1 is the right speaker. Further, on the board on the frame side of the gaming machine, no parts or circuits are added to the audio signal, and the signal is connected to the speaker.
The speaker specifications are as follows.

FIG. 396 is a diagram showing the specifications of the lower speaker.
The impedance is 8 ± 1.2Ω.
The permissible input has a rating of 15 W and a maximum of 20 W.
The resonance frequency is 110 ± 22 Hz.
The sound pressure is 82.5 ± 2 dB (measurement distance: 1 m).
The shape is 77φ.

FIG. 397 is a diagram showing specifications of the left speaker and the right speaker.
The impedance is 8 ± 1.2Ω.
The permissible input has a rating of 10 W and a maximum of 15 W.
The resonance frequency is 145 ± 29 Hz.
The sound pressure is 82.5 ± 2 dB (measurement distance: 0.5 m).
The shape is 66φ.

(B) Block diagram FIG. 398 is a diagram showing a block diagram including an upper speaker, a left speaker, a right speaker, and the like.
The management game machine 500 includes an effect control board 7100 having a voice amplifier control circuit 7110, a sub drawer connector board 7200, a front frame sub relay board 7300, a lower unit board 7401, a right unit board 7404, an upper unit board 7402, and a lower speaker 7409. It is equipped with a left speaker 7408 and a right speaker 7407.

The signal from the audio amplifier control circuit 7110 of the effect control board 7100 is transmitted to the lower speaker 7409 via the sub drawer connector board 7200 and the front frame sub relay board 7300, and further, the lower unit board 7401 and the right unit board 7404. , It is transmitted to the left speaker 7408 and the right speaker 7407 via the upper unit board 7402.

[Chapter 8]
This chapter describes the configuration of the entire circuit of the managed gaming machine.
399 to 423 are diagrams showing an overall circuit diagram of the managed gaming machine.

[Fig. 399]
The game ball rental device connection terminal plate 554 and the frame control board 550 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC5V-1
Pin No2: GND
Pin No3: Counting 5V
Pin No4: GND
Pin No5: Frame control TX
Pin No6: Frame control RX
Pin No7: Connection signal

The reference current value of the above harness is as follows.
DC5V-1: 0.1A or less Counting 5V: 0.1A or less Other signals: 0.1A or less

The frame control board 550 also includes a 7-pin connector. The contents of the 7-pin connector are as follows.

[7-pin connector]
Pin No1: Test firing test data 1
Pin No2: Test firing test data 2
Pin No3: Test firing test data 3
Pin No4: GND
Pin No5: GND
Pin No6: GND
Pin No7: GND

The above reference current values are as follows.
Other signals: 0.1A or less

The frame control board 550 also includes a 4-pin connector. The contents of the 4-pin connector (L01) are as follows.

[4-pin connector]
Pin No1: GND
Pin No2: Verification synchronization confirmation Pin No3: Verification data signal Pin No4: GND

The above reference current values are as follows.
Other signals: 0.1A or less

[Fig. 400]
The main drawer connector board 591 (game board) and the frame control board 550 are connected by a game board supply power supply and a predetermined harness capable of transmitting signals. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pins No3-5: DC36V-2
Pin Nos. 6-8: GND
Pin No9, 10: BU power supply Pin No11, 12: GND
Pins No. 13 to 16: DC12V-1
Pins No17, 18: GND
Pin No19, 20: Frame upper open switch signal Pin No21, 22, 2: Power failure detection signal Pin No23: CTX1 (MW)
Pin No24: CRX1 (WM)
Pin No25: RAM clear signal Pin No26: Fire stop signal Pins No27, 28: GND
Pin No29, 30: DC5V-1
Pins No31, 32: GND
Pins Nos. 33 and 34 of the main drawer connector board 591 and pins Nos. 1 and 2 of the power supply unit 6100: FG
Pins No. 35, 36 of the main drawer connector board 591, pins No. 33, 34 of the frame control board 550: GND

The reference current value of the above harness is as follows.
It is 2A per pole.

FIG. 401.
The power supply unit 6100 and the power supply cutoff switch are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Power cutoff switch

The FG of the power supply unit 6100 is connected to the gaming machine main body.
The FG of the power supply unit 6100 is connected to the lifting unit.

FIG. 402.
The power supply unit 6100 and the frame control board 550 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pins Nos. 3 and 4: DC36V-2
Pins Nos. 5 and 6: GND
Pin No7-10: DC12V-1
Pins No11, 12: GND
Pins No13, 14: DC5V-1
Pins No15, 16: GND

The reference current value of the above harness is as follows.
It is 3A per pole.

[Fig. 403]
The power supply unit 6100 and the sub drawer connector board 7206 are connected by a predetermined harness capable of transmitting a frame sub power supply or the like. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin No3-6: DC36V-2
Pins No. 7-10: GND
Pins No. 11-14: DC12V-2
Pins No15, 16: GND

The power supply unit 6100 and the front frame sub-relay board 7300 are connected by a predetermined harness. The contents of the predetermined harness are as follows.
Pins Nos. 17 and 18 (Pins Nos. 1 and 2 in the front frame sub-relay board 7300): GND
Pins Nos. 18 to 22 (Pins Nos. 3 to 6 in the front frame sub-relay board 7300): DC12V-2
Pins Nos. 23 and 24 (Pins Nos. 7 and 8 in the front frame sub-relay board 7300): GND

FIG. 404.
The sub-drawer connector board 7206 and the game board are connected by a game board side sub-connector.
The sub-drawer connector board 7206, the power supply unit 5000, and the front frame sub-relay board 7300 are connected by a predetermined harness (sub-drawer connector) or the like. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin No3-6: DC36V-2
Pins No. 7-10: GND
Pins No. 11-14: DC12V-2
Pins No15, 16: GND
Pins Nos. 17 and 18 (Pins Nos. 9 and 10 in the front frame sub-relay board 7300): GND
Pin No. 19 (Pin No. 11 in the front frame sub-relay board 7300): CS1
Pin No. 20 (Pin No. 12 in the front frame sub-relay board 7300): CLK1
Pin No. 21 (Pin No. 13 in the front frame sub-relay board 7300): SOD1
Pin No. 22 (Pin No. 14 in the front frame sub-relay board 7300): SID1
Pin No. 23 (Pin No. 15 in the front frame sub-relay board 7300): GND
Pin No. 24 (Pin No. 16 in the front frame sub-relay board 7300): CS2
Pin No. 25 (Pin No. 17 in the front frame sub-relay board 7300): CLK2
Pin No. 26 (Pin No. 18 in the front frame sub-relay board 7300): SOD2
Pin No. 27 (Pin No. 19 in the front frame sub-relay board 7300): SID2
Pin No. 28 (Pin No. 20 in the front frame sub-relay board 7300): GND
Pin No. 29 (Pin No. 21 in the front frame sub-relay board 7300): PIO1
Pin No. 30 (Pin No. 22 in the front frame sub-relay board 7300): PIO2
Pins Nos. 31 and 32 (Pins Nos. 23 and 24 in the front frame sub-relay board 7300): GND
Pin No33 (Pin No25 in the front frame sub-relay board 7300): SP3 (+)
Pin No. 34 (Pin No. 26 in the front frame sub-relay board 7300): SP3 (-)
Pin No35 (Pin No27 in the front frame sub-relay board 7300): SP2 (+)
Pin No. 36 (Pin No. 28 in the front frame sub-relay board 7300): SP2 (-)
Pin No. 37 (Pin No. 29 in the front frame sub-relay board 7300): SP1 (+)
Pin No. 38 (Pin No. 30 in the front frame sub-relay board 7300): SP1 (-)
Pins No. 39, 40 (Pins No. 31, 32 in the front frame sub-relay board 7300): GND

[Fig. 405]
The power supply unit 6100, the sub drawer connector board 7206, the frame control board 550, and the front frame sub relay board 7300 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2 (Pins Nos. 17 and 18 in the power supply unit 6100): GND
Pins Nos. 3 to 6 (Pins Nos. 19 to 22 in the power supply unit 6100): DC12V-2
Pins Nos. 7 and 8 (Pins Nos. 23 and 24 in the power supply unit 6100): GND
Pins Nos. 9 and 10 (Pins Nos. 17 and 18 on the sub drawer connector board 7206): GND
Pin No. 11 (Pin No. 19 in the sub drawer connector board 7206): CS1
Pin No. 12 (Pin No. 20 in the sub drawer connector board 7206): CLK1
Pin No. 13 (Pin No. 21 in the sub drawer connector board 7206): SOD1
Pin No. 14 (Pin No. 22 in the sub drawer connector board 7206): SID1
Pin No. 15 (Pin No. 23 in the sub drawer connector board 7206): GND
Pin No. 16 (Pin No. 24 in the sub drawer connector board 7206): CS2
Pin No. 17 (Pin No. 25 on the sub drawer connector board 7206): CLK2
Pin No. 18 (Pin No. 26 in the sub drawer connector board 7206): SOD2
Pin No. 19 (Pin No. 27 in the sub drawer connector board 7206): SID2
Pin No. 20 (Pin No. 28 in the sub drawer connector board 7206): GND
Pin No. 21 (Pin No. 29 in the sub drawer connector board 7206): PIO1
Pin No. 22 (Pin No. 30 in the sub drawer connector board 7206): PIO2
Pins Nos. 23 and 24 (Pins Nos. 31 and 32 in the sub drawer connector board 7206): GND
Pin No. 25 (Pin No. 33 in the sub drawer connector board 7206): SP3 (+)
Pin No. 26 (Pin No. 34 in the sub drawer connector board 7206): SP3 (-)
Pin No. 27 (Pin No. 35 on the sub drawer connector board 7206): SP2 (+)
Pin No. 28 (Pin No. 36 in the sub drawer connector board 7206): SP2 (-)
Pin No. 29 (Pin No. 37 in the sub drawer connector board 7206): SP1 (+)
Pin No. 30 (Pin No. 38 in the sub drawer connector board 7206): SP1 (-)
Pins Nos. 31 and 32 (In the sub-drawer connector board 7206, pins Nos. 39 and 40): GND

Pins Nos. 33 and 34 (Pins Nos. 1 and 2 in the frame control board 550): GND
Pins Nos. 35 and 36 (Pins Nos. 3 and 4 in the frame control board 550): DC12V-1
Pin No. 37 (Pin No. 5 in the frame control board 550): Voice alarm command for frame 1
Pin No. 38 (Pin No. 6 in the frame control board 550): Voice alarm command for frame 2
Pin No. 39 (Pin No. 7 in the frame control board 550): Voice alarm command for frame 3
Pin No. 40 (Pin No. 8 in the frame control board 550): DC5V-1

[Fig. 406]
The frame control board 550 and the main relay board 8000 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: DC12V-1S
Pins Nos. 3 and 4: GND
Pins Nos. 5 and 6: DC5V-1
Pin No7: GND
Pin No8: Frame upper opening switch Pin No9: Frame lower opening switch Pin No10: Frame radio wave sensor A
Pin No11: Winning passage count sensor Pin No12: Non-winning passage count sensor Pin No13: Ball passage Ball clogging monitoring sensor Pin No14: Lifting inlet sensor Pin No15: Lifting exit sensor Pin No16: Lifting motor sensor Pin No17: Lifting Motor A1 phase (OUT1)
Pin No18: Lifting motor B3 phase (OUT2)
Pin No19: Lifting motor A3 phase (OUT3)
Pin No20: Lifting motor B1 phase (OUT4)

The reference current value of the above harness is as follows.
DC12V-1S: 1.0A or less DC5V-1: 0.1A or less Lifting motor phase: 0.5A or less Other signals: 0.1A or less

[Fig. 407]
The frame control board 550 and the launch control board 8010 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1
Pin No2: DC12V-1S
Pins Nos. 3 and 4: GND
Pins Nos. 5 and 6: DC36V-1
Pin Nos. 7 and 8: GND
Pin No9: DC5V-1
Pin No10, 11: GND
Pin No12: Subtraction mechanism inlet sensor Pin No13: Subtraction mechanism exit sensor Pin No14: Foul ball sensor Pin No15: Subtraction solenoid Pin No16: Launch permission signal Pin No17: Subtraction reference signal Pin No18: Launch stop switch Pin No19: Touch sensor Pin No20 : VR1
Pin No21: VR2
Pin No22: VR3

The reference current value of the above harness is as follows.
DC12V-1: 0.3A or less DC12V-1S: 1.0A or less DC36V-1: 4.0A or less (30 / 600ms DUTY)
Subtraction solenoid: 1.0A or less Other signals: 0.1A or less

[Fig. 408]
The frame control board 550 and the front frame main relay board 8020 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1
Pin No2: DC12V-1S
Pins Nos. 3 and 4: GND
Pin No5: Fire stop switch Pin No6: Touch sensor Pin No7: VR1
Pin No8: VR2
Pin No9: VR3
Pin No10: Radio wave sensor B for frame
Pin No11: Counting 5V
Pin No12: Counting switch Pin No13: Counting LEDR data Pin No14: Counting LEDG data Pin No15: Counting LEDB data Pins No16 to 22: Game ball number display segments 1 to 6
Pins No. 23 to 28: Game ball number display digits R1 to R6
Pins No. 29 to 34: Game ball number display digits G1 to G6

The reference current value of the above harness is as follows.
DC12V-1: 0.2A or less Counting 5V: 0.1A or less Other signals: 0.1A or less

[Fig. 409]
The frame control board 550 and the front frame sub-relay board 7300 are connected by a frame voice notification power supply and a predetermined harness capable of transmitting signals. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2 (Pins Nos. 33 and 34 in the front frame sub-relay board 7300): GND
Pins Nos. 3 and 4 (Pins Nos. 35 and 36 in the front frame sub-relay board 7300): DC12V-1
Pin No. 5 (Pin No. 37 in the front frame sub-relay board 7300): Voice alarm command for frame 1
Pin No. 6 (Pin No. 38 in the front frame sub-relay board 7300): Voice alarm command for frame 2
Pin No. 7 (Pin No. 39 in the front frame sub-relay board 7300): Voice alarm command for frame 3
Pin No. 8 (Pin No. 40 in the front frame sub-relay board 7300): DC5V-1

The reference current value of the above harness is as follows.
Other signals: 0.1A or less

[Fig. 410]
The main relay board 8000 and the frame upper opening switch 8001 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Frame upper opening switch

The main relay board 8000 and the frame lower opening switch 8002 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Frame lower opening switch

The main relay board 8000 and the radio wave sensor 8003 for the management gaming machine frame are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Radio wave sensor A for frame
Pin No2: GND

The main relay board 8000 and the winning passage count sensor 8004 (through-type proximity sensor or the like) are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Winning passage count sensor

The main relay board 8000 and the non-winning passage count sensor 8005 (through-type proximity sensor or the like) are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Non-winning passage count sensor

The main relay board 8000 and the ball passage ball clogging monitoring sensor 8006 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Ball passage Ball clogging monitoring sensor

[Fig. 411]
The main relay board 8000 and the lifting relay board 8030 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: DC12V-1S
Pin No3: Lifting motor B1 phase Pin No4: Lifting motor A3 phase Pin No5: Lifting motor A1 phase Pin No6: Lifting motor B3 phase Pin No7: Lifting inlet sensor Pin No8: Lifting outlet sensor Pin No9: Lifting Upper motor sensor pin No10: DC5V-1
Pins No11, 12: GND

The reference current value of the above harness is as follows.
DC12V-1S: 1.0A or less DC5V-1: 0.1A or less Lifting motor phase: 0.5A or less Other signals: 0.1A or less

[Fig. 412]
The launch control board 8010 and the launch relay board 8040 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Subtraction mechanism inlet sensor Pin No3: Subtraction mechanism exit sensor Pin No4: Foul ball sensor Pin No5: GND
Pin No6: DC12V-1S
Pin No7: Subtraction solenoid Pin No8: Launch solenoid +
Pin No9: Launch solenoid-

The reference current value of the above harness is as follows.
DC12V-1S: 1.0A or less Subtraction solenoid: 1.0A or less Launch solenoid ±: 4.0A or less (30 / 600ms DUTY)
Other signals: 0.1A or less

[Fig. 413]
The front frame main relay board 8020 and the handle relay board 8050 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Fire stop switch Pin No3: Touch sensor Pin No4: GND
Pin No5: DC12V-1
Pin No6: VR1
Pin No7: VR2
Pin No8: VR3

The handle relay board 8050, the launch stop switch 8051, the touch sensor 8052, and the handle volume 8053 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Fire stop switch Pin No3 (Pin No1): Touch sensor Pin No4 (Pin No2): GND
Pin No5 (Pin No3): DC12V-1
Pin No6 (Pin No1): VR1
Pin No7 (Pin No2): VR2
Pin No8 (Pin No3): VR3

The front frame main relay board 8020 and the management game machine frame radio wave sensor 8060 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Radio wave sensor B for frame
Pin No3: GND

[Fig. 414]
The front frame main relay board 8020 and the game ball number display 8070 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin Nos. 2-8: Game ball number display segment 1-7
Pins No. 9 to 14: Game ball number display digits R1 to R6
Pin Nos. 15 to 20: Game ball number display digits G1 to G6

The front frame main relay board 8020 and the counting switch 530 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Counting 5V
Pin No3: Counting switch Pin No4: Counting LEDR data Pin No5: Counting LEDG data Pin No6: Counting LEDB data Pin No7: DC12V-1

[Fig. 415]
The lifting relay board 8030 and the lifting inlet sensor 8031 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Lifting inlet sensor

The lifting relay board 8030 and the lifting outlet sensor 8032 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Lifting outlet sensor Pin No2: GND

The lifting relay board 8030 and the lifting motor sensor 8033 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC5V-1
Pin No2: Lifting motor sensor Pin No3: GND

The lifting relay board 8030 and the lifting motor sensor 8034 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: Lifting motor B3 phase Pin No2: Lifting motor A3 phase Pin No3, 4: DC12V-1S
Pin No5: Lifting motor B1 phase Pin No6: Lifting motor A1 phase

[Fig. 416]
The launch relay board 8040 and the subtraction mechanism inlet sensor 8041 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Subtraction mechanism inlet sensor Pin No3: GND

The launch relay board 8040 and the subtraction mechanism outlet sensor 8042 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Subtraction mechanism outlet sensor Pin No3: GND

The launch relay board 8040 and the foul ball sensor 8043 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Foul ball sensor Pin No3: GND

The firing relay board 8040 and the subtraction solenoid 8044 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: DC12V-1S
Pin No2: Subtraction solenoid

The firing relay board 8040 and the firing solenoid 8045 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: Launch solenoid +
Pin No2: Launch solenoid-

[Fig. 417]
The cross key board 8080 and the lower unit board 7401 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: Adjustment switch 1
Pin No3: Adjustment switch 2
Pin No4: Adjustment switch 3
Pin No5: Adjustment switch 4

The front frame sub-relay board 7300 and the lower unit board 7401 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin Nos. 3 and 4: DC12V-2
Pins Nos. 5 and 6: GND
Pin No7: CS1
Pin No8: CLK1
Pin No9: SOD1
Pin No10: SID1
Pin No11: CS2
Pin No12: CLK2
Pin No13: SOD2
Pin No14: SID2
Pin No15: PIO1
Pin No16: PIO2
Pins No17, 18: GND
Pin No19: SP2 +
Pin No20: SP2-
Pin No21: SP1 +
Pin No22: SP1-

[Fig. 418]
The front frame sub-relay board 7300 and the lower speaker 7409 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: SP3 +
Pin No2: SP3-

The front frame sub-relay board 7300 and the frame voice notification board 7301 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin Nos. 3 and 4: DC12V-1
Pin No5: Voice alarm command for frame 1
Pin No6: Voice alarm command for frame 2
Pin No7: Voice alarm command for frame 3
Pin No8: DC5V-1

The frame voice notification board 7301 and the frame speaker 7302 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: Frame SP +
Pin No2: Frame SP-

[Fig. 419]
The lower unit board 7401 and the right unit board 7404 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin Nos. 3 and 4: DC12V-2
Pins Nos. 5 and 6: GND
Pin No7: CS1
Pin No8: CLK1
Pin No9: SOD1
Pin No10: SID1
Pin No11: CS2
Pin No12: CLK2
Pin No13: SOD2
Pin No14: SID2
Pin No15: PIO1
Pin No16: PIO2
Pins No17, 18: GND
Pin No19: SP2 +
Pin No20: SP2-
Pin No21: SP1 +
Pin No22: SP1-

[Fig. 420]
The lower unit board 7401 and the left unit board 7403 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin Nos. 3 and 4: DC12V-2
Pins Nos. 5 and 6: GND
Pin No7: CS1
Pin No8: CLK1
Pin No9: SOD1
Pin No10: SID1
Pin No11: CS2
Pin No12: CLK2
Pin No13: SOD2
Pin No14: SID2
Pin No15: PIO1
Pin No16: PIO2
Pins No17, 18: GND
Pin No19: SP2 +
Pin No20: SP2-
Pin No21: SP1 +
Pin No22: SP1-

[Fig. 421]
The lower unit board 7401 and the effect switch board 7441 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: DC12V-2
Pin No3: LED1-B
Pin No4: LED1-G
Pin No5: LED1-R
Pin No6: LED2-B
Pin No7: LED2-G
Pin No8: LED2-R
Pin No9: LED3-B
Pin No10: LED3-G
Pin No11: LED3-R
Pin No12: PWM
Pin Nos. 13 and 14: GND
Pin No15: VCL
Pin No16: Production switch

The effect switch board 7441 and the vibration motor 7442 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: GND
Pin No2: DC12V-2
Pin No3: PG
Pin No4: PWM
Pin No5: FR

[Fig. 422]
The right unit board 7404 and the upper unit board 7402 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pins Nos. 1 and 2: GND
Pin Nos. 3 and 4: DC12V-2
Pins Nos. 5 and 6: GND
Pin No7: CS1
Pin No8: CLK1
Pin No9: SOD1
Pin No10: SID1
Pin No11: CS2
Pin No12: CLK2
Pin No13: SOD2
Pin No14: SID2
Pin No15: PIO1
Pin No16: PIO2
Pins No17, 18: GND
Pin No19: SP2 +
Pin No20: SP2-
Pin No21: SP1 +
Pin No22: SP1-

[Fig. 423]
The upper unit board 7402 and the left speaker 7408 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: SP2 +
Pin No2: SP2-

The upper unit board 7402 and the right speaker 7407 are connected by a predetermined harness. The contents of the predetermined harness are as follows.

[Predetermined harness]
Pin No1: SP1 +
Pin No2: SP1-

The lower unit includes a cross key substrate 8080, a lower unit substrate 7401, an effect switch substrate 7441, a vibration motor 7442, and the like.
The right unit includes a right unit substrate 7404.
The left unit includes a left unit substrate 7403.
The upper unit includes an upper unit substrate 7402, a left speaker 7408, and a right speaker 7407.

(Note 1) The BU power supply is a power supply in which DC5V-1 is charged with an electric double layer capacitor in the frame control board. CTX and CRX are serial communication signals between the frame control board and the game board.
(Note 2) Parts are optional.
(Note 3) The frame voice notifications 1 to 8 are integrated as sub-system signals. For example, it is designed to use eight power supplies and signals.

(Note 4) The sub 12V power supply for the frame is supplied directly from the power supply unit, and the number of signals and the connector are arbitrary depending on the power supply capacity used.
(Note 5) Pins 1 to 16 of the sub drawer connector are fixed, and pins 19 to 40 can be changed depending on the front decoration used. The IF specification uses two bidirectional SPI communication (4-wire system) as a description example, but it can be changed including the communication method. However, it is preferable to comply with the maximum rated current of 2.0 A (when using AWG24) of the contact of the sub drawer connector.
(Note 6) The sub-connector on the game board side can be freely selected depending on the configuration on the game board side and the connector used.

(Note 7) As an example, the signals of the upper, lower, left, and right unit boards of the Joyco general-purpose frame are described (5V is generated by each unit board).
(Note 8) The effect switch may be passed through the lower unit board or may be directly connected to the front frame sub-relay board.
(Note 9) The frame control board, launch control board, game ball, etc. rental connection terminal board are boards manufactured by the manufacturer.

[Chapter 9]
[Regarding the design unit replacement structure]
FIG. 424 is a diagram showing a design unit replacement range of the managed gaming machine.
In the management gaming machine 500, the operation unit 9000 is arranged at the lower part, and the design unit 9100 is arranged at the upper part of the operation unit 9000. The design unit replacement range is the range shown by A in the figure.

FIG. 425 is a diagram showing a design unit.
The design unit 9100 includes a right unit 9101, an upper unit 9102, a left unit 9103, and a lower unit 9104.
The right unit 9101 can be attached to the right side of the table frame base 9200.
The upper unit 9102 can be attached to the upper side of the table frame base 9200.
The left unit 9103 can be attached to the left side of the table frame base 9200.
The lower unit 9104 can be attached to the lower side of the table frame base 9200.

The reference weight of each design unit is, for example, as follows.
Right unit 9101: 5 kg
Upper unit 9102: 5 kg
Left unit 9103: 5 kg
Lower unit 9104: 5 kg
The total weight is preferably 15 kg or less.

The design unit 9100 above the operation unit 9000 has a replaceable structure.
It is preferable that the weight of each design unit is set to 5 kg or less and not to exceed 15 kg in total.
The division of the design unit can be arbitrarily set within a range that can be attached by using the fixed portion of the front frame base 9200.

FIG. 426 is a diagram showing a method of attaching and detaching the design unit.
The design unit is attached and detached after the front frame (door) is opened.
The design unit can be replaced by loosening the knob screw on the back of the front frame (door) and operating the lock lever corresponding to each design unit.
The design unit is fixed to the front frame base with knob screws and hooks.

[Hook placement]
As shown in (A) in the figure, hooks are provided at three locations on the left side of the table frame base 9200, hooks are provided at seven locations on the upper side, and hooks are provided at three locations on the right side. There are 5 hooks on the lower side.

[Release operation]
As shown in (B) in the figure, when the lock levers (lock lever 9300A for part A, lock lever 9300B for part B, lock lever 9300C for part C, lock lever 9300D for part D) are operated, the corresponding lock bar is operated. The 9400 (one of the four) is activated and the lock is released.

[Arrangement of knob screws]
As shown in (C) in the figure, the knob screws are arranged at four places (9500B) on the upper part, one place (9500A) on the left side, three places (9500D) in the center, and one place (9500C) on the right side.

[Regarding the electrical connection of the design unit]
427 and 428 are diagrams showing a method of electrically connecting the design unit.
The electrical connection between the design unit 9100 mounted on the front frame (door) and the board surface (panel) is connected to each design unit via the front frame sub-relay board 7300 via the drawer connector.
As a standard specification, the harness from the lower unit 9104 is connected to the front frame sub-relay board 7300 through the through hole 7300H for the front frame sub-relay board, and then the adjacent design units are directly connected to each other from the front side.

[Relay board for expansion]
FIG. 429 is a diagram showing an expansion relay board.
An expansion relay board 9710 (expansion front frame sub-relay board 9710A, expansion center relay board 9710B, expansion upper relay board 9710C) can be mounted on the back surface of the front frame base 9200.
By passing the harness from each design unit through the harness opening 9720 (7 locations) to the back surface of the front frame base 9200, it is possible to connect to the expansion relay board 9710. By mounting the upper left relay board for expansion, it is also possible to connect directly to the board surface (panel).

The above-described embodiment includes at least 15 technical features shown below.
(1) Configuration of ball removal operation (2) Configuration of ball removal operation 2
(3) Configuration of spare area and reserved area of telegram (4) Configuration of serial number of telegram (5) Configuration of display device such as number of game balls (6) Setting of priority of game machine information type (7) Calculation of performance information (8) Dedicated cable disconnection (9) Main control state 1
(10) Main control state 2
(11) Display device for the number of game balls, etc. (12) Clear switch for game balls (number of medals) (13) Confirmation of CM activation (14) Game information (15) Fraud detection status 1
Hereinafter, each technical feature will be described. The issues and effects described in the following technical features are only secondary issues, and the main issues and effects are "providing innovative gaming machines". Further, the following technical features can be applied not only to pachinko machines but also to slot machines. In this case, the game ball can be changed to a game medal.

[(1) Configuration of ball pulling operation]
The technical features are as follows.
For the control for the ball pulling operation, the power is turned on while pressing the "ball pulling button (ball pulling switch)" mounted on the frame control board, and the number of game balls of the game ball number display device is "0". Only in the case of, the ball removal operation is started.
The problem of this technical feature is to propose appropriate conditions when shifting to the ball pulling operation.

[About stopping the game of the main control board during the ball pulling operation]
For maintenance of the main body of the managed gaming machine, it is necessary to perform an operation of taking out the gaming ball in the managed gaming machine to the outside (ball pulling operation). At that time, the game ball will be launched on the surface of the game board, but since it is under maintenance, it can be specified that the game ball does not win even if the game ball wins the prize opening.

At this time, if the main control board receives information from the frame control board that "the ball is being pulled out" by communication between the main control board and the frame control board when the power is turned on, the main control board is until the power is turned off. , The game can be stopped.
During the ball pulling operation, it is preferable to be in a state where firing can be performed in order to remove all the game balls remaining in the managed game machine.

According to this technical feature, it is possible to shift to the ball pulling operation under appropriate conditions.
It should be noted that, as a conventional technique, there is no technique that indicates a condition that enables a ball pulling operation.

[(2) Configuration of ball pulling operation 2]
The technical features are as follows.
When the main control board receives information from the frame control board that "the ball is being pulled out" by communication between the main control board and the frame control board when the power is turned on during the ball pulling operation, the main control board is turned off. Until then, the game is stopped.
The problem of this technical feature is to propose a configuration in which the main control is controlled so that a problem does not occur during the ball pulling operation.

According to this technical feature, the main control can be controlled to an appropriate state during the ball pulling operation.
It should be noted that, as a conventional technique, there is no technique indicating a condition for enabling the ball pulling operation, a state of the main control during the ball pulling operation, and a firing control during the ball pulling operation.

[(3) Configuration of telegram reserve area and reserved area]
The technical features are as follows.
Regarding the data part of the telegram, a spare area for future expansion and a reserved area that is not used on the gaming machine side are provided. Regarding the spare area, even if a value other than the initial value is entered, the receiving side does not notify the error.
The problem of this technical feature is to propose an appropriate command configuration in a managed gaming machine.

In the management game, each information is notified by a telegram composed of "telegram length / command / serial number / data capital / checksum" between the frame control and the CM.
The "data unit" is provided with a spare area for future expansion and a reserved area that is not used on the gaming machine side (see FIG. 315).

Regarding the spare area, even if a value other than the initial value is stored, the receiving side (CM side) can prevent the error notification from being performed. If a value other than the initial value is stored, the receiving side (CM side) may perform error notification.

According to this technical feature, it is possible to construct a telegram that can respond to future specification changes. Further, according to the present technical features, it is possible to realize an error configuration that is not too excessive.
In addition, as a conventional technique, a technique that specifically indicates what the spare area is, what kind of value is specifically set, and what kind of value is stored when a non-default value is stored. There is no technology that even shows whether to control.

In addition to the configuration in which error processing is not performed on the CM side for frame control → CM, the configuration in which frame control does not perform error processing for commands (telegrams) of main control → frame control even if the spare area of the command is other than the initial value. May be.

[(4) Composition of telegram serial numbers]
The technical features are as follows.
(I) Create a telegram to be sent when communicating with the outside (dedicated unit). The telegram includes an independent serial number for each telegram type. When the telegram is created normally, it is a numerical value of the serial number +1 of the same type of telegram notified, and when the serial number notified last time is 255, which is the maximum value, 1 which is the serial number +2 is retained. The serial number is initialized to 0 when the power is turned on.
(Ii) In the above (i), the telegram exchanged inside the gaming machine (main control → frame control) also includes a serial number. If the previous serial number was 255, which is the maximum value, the telegram exchanged inside the gaming machine (main control → frame control) may be 1 of serial number +2, or 0 of serial number + 1. You may do so.
The problem of this technical feature is to propose an appropriate command configuration in a managed gaming machine.

In the managed gaming machine, each information is notified by a telegram composed of "telegram length / command / serial number / data unit / checksum" between the frame control and the CM.
This "serial number" is a value that is updated every time a telegram is transmitted in the range of 0 to 255, and when the telegram is created normally, it becomes a value of the serial number +1 of the same type of telegram notified last time. The serial number is initialized to 0 when the power is turned on. The serial number is basically a value of +1 last time, but if the serial number notified last time is 255, which is the maximum value, 1 which is a serial number +2 is retained. The serial number is configured to be "0" only when the power is turned on, and can be distinguished from the serial number at other timings (see FIGS. 309 to 312).

According to this technical feature, the serial number is configured to be "0" only when the power is turned on, and can be distinguished from the serial number at other timings.
As a conventional technique, there is no technique showing at least a configuration that "when the serial number notified last time is 255, which is the maximum value, 1 which is the serial number +2 is retained".

[(5) Configuration of display device for the number of game balls, etc.]
The technical features are as follows.
The number of game media (medals / game balls) is stored in a predetermined byte.
An upper limit is set for the number of game media that can be stored, and the upper limit is a number smaller than the number that can be stored in a predetermined number of bytes.
The problem of this technical feature is to set the upper limit of the number of game media (game balls, game medals) to an appropriate value.

In a slot machine that uses game medals as a game medium (may be a medalless game machine), the number of game medals is stored in 2 bytes, but the upper limit is set to 16383 (not 65535). As a result, the damage that can occur when a goto occurs can be reduced (65535 sheets are not damaged).
Similarly, a managed gaming machine that uses a gaming machine as a gaming medium also stores the number of gaming balls in 3 bytes, but 0 to 990000, which is a range smaller than 0 to 16777215, is set in a storable range. (See FIG. 315).

According to this technical feature, it is possible to suppress damage in the event of a goto.
As a conventional technique, there is no technique indicating that the upper limit of the number of storable items is set to a value less than 65535 even though the two-byte structure is stored.

[About the term medium]
In managed gaming machines and medalless gaming machines, there are cases where the word "medium" does not fit. This is because the numerical value displayed by the game ball number display device (game ball number display device or game medal number display device) is data. In such a case, the stored data can be replaced with the wording "game value" from "game medium".

On top of that, in the management game machine, there are cases where the actual game ball is shown and data is shown, but both cases are likened to a conventional pachinko machine (a game machine that uses a game ball for payout) for convenience. The game medals in the medalless gaming machines are unified as "game balls" and are only treated as data because the actual medals are not used for games at all, but conventional pachislot machines (using medals). It may be called as a game medal for convenience by comparing it to a game machine).

Similarly, "○○ medals (acquired medals, etc.)" and "△△ number (paid out medals, etc.)" may be inappropriate words to indicate data, but even if they are actually data, In some cases, it is likened to a medal in a conventional game machine that uses medals.

[(6) Setting the priority of the gaming machine information type]
The technical features are as follows.
In the command transmitted from the frame control to the CM board (dedicated unit), there is different information transmitted in different cycles (for example, a command for fraud monitoring information, a command for gaming machine installation information). If the cycles overlap, the command of fraud monitoring information has priority.

The problem of this technical feature is to propose an appropriate command configuration in a managed gaming machine.
[Premise]
The frame control notifies the CM of the gaming machine information.
There are three types of gaming machine information: gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information, and one of them is notified according to the notification conditions of each information.

[Special]
The following priorities are set for the gaming machine information notification, and when the notification conditions overlap, the notification is made according to the priorities (see FIG. 350).
[Priority: 1] Hall control / fraud monitoring information (with game information)
(Notify every 300ms from the completion of starting the gaming machine)
[Priority: 2] Pachinko machine installation information
(Notification after 60s have passed since the start of the gaming machine. After that, notification is made every 60s cycle)
[Priority: 3] Pachinko machine performance information
(Notification after 180s have passed since the start of the gaming machine. After that, notification is made every 180s cycle)
[Priority: 4] Hall control / fraud monitoring information (no game information)
(Notification is made at a cycle of 300 ms when the game machine is started. After that, notification is made at a cycle of 300 ms)

According to this technical feature, it is possible to prevent a problem due to duplication of command (telegram) transmission timing. Further, according to the present technical feature, it is possible to avoid a problem due to timing duplication when each information transmitted at different cycles is provided.
It should be noted that, as a conventional technique, there is no technique showing a configuration in which priorities are set when timings overlap on the premise that a plurality of pieces of information are transmitted at different cycles.
Further, as a conventional technique, even if there is a technique for indicating a configuration in which the one having the higher priority is transmitted when there are a plurality of commands to be transmitted, if the contents of the command are included, the priority of this technical feature is given. It is a configuration that cannot be derived from the prior art until the configuration for setting the order.

[(7) Processing for calculating performance information]
The technical features are as follows.
The frame control board calculates (generates) performance information. The frame control board performs calculations based on the "performance information status notification" transmitted from the main control. The "performance information status notification" is included in the "game machine information" transmitted from the main control, and the "performance information status notification" is included in the "game machine information" transmitted at least at the first time of the power failure recovery. It is transmitted at the beginning (the first in a set of telegrams) (see FIGS. 299 and 300).
The subject of this technical feature is the proposal of an appropriate method for calculating performance information in managed gaming machines.

According to this technical feature, it is possible to quickly calculate the performance information by frame control immediately after the power failure is restored.
In addition, as a conventional technique, there is no technique for showing the information necessary for the frame control board to calculate, including the point where the main control transmits the information and how the information is transmitted from the main control. not exist.

The "performance information status notification" may always be transmitted first in the "game machine information", not only when the power is restored. With such a configuration, for example, a game ball that wins just before shifting to the big hit state is notified of the big hit state at the beginning and is treated as a game ball that won a prize during the big hit, but within the margin of error. There is no problem. In this way, by always transmitting the "performance information status notification" at the beginning, it is not necessary to switch the transmission order depending on the status, so that the processing and design are simplified.

[(8) Dedicated cable disconnection]
The technical features are as follows.
(I) A power supply (VL) for connection confirmation input from a dedicated unit is provided. If the connection confirmation power supply (VL) is switched from ON to OFF while the gaming machine is running, the gaming ball cannot be launched (see FIG. 348).
(Ii) In the above (i), even when the connection confirmation power supply (VL) is switched from ON to OFF during the startup of the gaming machine and the launching of the gaming ball is stopped, the starting opening prize is won. If it is broken, the hold (hold displayed by the main control device or hold displayed by the effect control device) increases.

The problem of this technical feature is to carry out appropriate control when the dedicated cable is broken.
[Specific configuration]
When the dedicated cable breaks during the game, the CM notifies the gaming machine of the break in the dedicated cable, the connection confirmation power supply (VL) is turned off, and the connection confirmation power supply (VL) is turned on when the dedicated cable is restored. To do. When the connection confirmation power supply (VL) is OFF, the game ball cannot be launched and the count button is disabled. However, for the telegrams that perform periodic transmission, the transmission is performed in the same way as when the connection confirmation power supply (VL) is ON. Do.

According to this technical feature, the connection status with the dedicated unit is confirmed by the connection confirmation power supply (VL), and if the connection cannot be confirmed, the game ball cannot be launched. It is possible to prevent the game from being executed in a state where the connection is not normally established.
Further, according to the present technical feature, it is possible to reduce the occurrence rate of information loss or contradiction during communication between the gaming machine and the dedicated unit when the dedicated cable is recovered from the disconnection.
As a conventional technique, there is no technique for continuing periodic transmission of a telegram when the connection confirmation power supply (VL) is turned off, or a technique for showing the contents related to the effect side.

〔Concrete example〕
When the power supply (VL) for connection confirmation is OFF, hold increase / decrease, symbol change start (effect symbol change start), effect execution, symbol stop (effect symbol stop), major game, error notification, operation of various operation means, model custom At least one of the change / power saving modes may be implemented, or at least one may not be implemented.

[(9) Main control state 1]
The technical features are as follows.
A main control state 1 is provided, which is a 1-byte area (information) capable of holding up to 8 bits of bit information that treats 1 bit as one flag.
Bit information 0 can be treated as flag OFF and 1 as flag ON.
The main control state 1 is the first specific bit information in which the flag is turned on during a predetermined jackpot, the second specific bit information in which the flag is turned on during all jackpots, and the jackpot that shifts to a predetermined state after the jackpot. Holds the third specific bit information that turns on the flag.
The main control state 1 can be treated as a numerical value of 255 or less by combining a plurality of bit information including the first to third specific bit information.
When only the first specific bit information is ON, it is set as a numerical value 1, and when only the second specific bit information is ON, it is set as a numerical value 2. Only the third specific bit information is set as a numerical value 2. When it is ON, it can be treated as a numerical value of 4. When a plurality of specific bit information is ON, it is preferable to add numerical values to handle the information.
It has at least one unused bit, and 0 is held in the unused bit (see FIG. 263).

The problem of this technical feature is to improve the ease of managing the internal state of the gaming machine.
[Specific configuration]
The information related to the internal state during the jackpot and the output state of the signal related to the internal state are held as bit information, and a maximum of 256 types of information can be treated as a 1-byte main control state 1 that can be identified by combining the bit information.

According to this technical feature, by collectively managing the internal state and signal output state related to the special symbol, it is easy for the administrator to grasp the internal state of the gaming machine, and by holding it as bit information, the capacity is increased. It will be a reduction.
As a conventional technique, there is no technique indicating that the contents of Bit0 and Bit1 of the present technical feature are the same and that bit8 is unused (fixed to 0) as an area for future expansion.
By retaining unused bits, it is possible to leave room for expansion by adding specifications in the future.

[(10) Main control state 2]
The technical features are as follows.
A main control state 2 is provided, which is a 1-byte area (information) capable of holding up to 8 bits of bit information that treats 1 bit as one flag.
Bit information 0 can be treated as flag OFF and 1 as flag ON.
In the main control state 2, the winning probability of the normal symbol lottery is high during the big hit, the winning probability of the normal symbol lottery is high, or the winning probability of the special symbol lottery is high during the small hit rush state (the winning probability of the normal symbol lottery is low and the winning probability is high. The first specific bit information whose flag is ON during the state), the second specific bit information whose flag is ON during the high probability of winning the special symbol lottery, and the winning probability of the normal symbol lottery are high probability states. It holds the third specific bit information in which the flag is turned on during the medium (in the time shortened state in which the fluctuation time of the normal symbol or the special symbol is shortened) or in the small hit rush state.
The main control state 2 can be treated as a numerical value of 255 or less by combining a plurality of bit information including the first to third specific bit information.
When only the first specific bit information is ON, it is set as a numerical value 1, and when only the second specific bit information is ON, it is set as a numerical value 2. Only the third specific bit information is set as a numerical value 2. When it is ON, it can be treated as a numerical value of 4. When a plurality of specific bit information is ON, it is preferable to add numerical values to handle the information.
It has at least one unused bit, and 0 is held in the unused bit (see FIG. 264).

The problem of this technical feature is to improve the ease of managing the internal state of the gaming machine.
[Specific configuration]
Information related to the internal state in the time saving / high accuracy state is held as bit information, and up to 256 types of information can be treated as a 1-byte main control state 2 that can be identified by combining bit information.

According to this technical feature, by managing various internal states collectively, it is easy for the administrator to grasp the internal state of the gaming machine, and by holding it as bit information, the capacity can be reduced.
As a conventional technique, the area after Bit3 is an unused area as in the present technical feature, and there is no technique in the present technical feature indicating that bit2 is in a time saving or advantageous state. In this technical feature, three types of time saving, high accuracy, and SKR (small hit rush) can be identified by the combination of bits 0 to 3 (three types if there is no difference in the setting contents of bits 0 to 3 between high accuracy and SKR). Cannot be identified).

〔Concrete example〕
"High probability medium" is a probability fluctuation (a special symbol lottery is in a high probability state).
"Medium time reduction" is electric support (normal symbol lottery is in a high probability state) + non-probability fluctuation (special symbol lottery is in a low probability state).
The "advantageous state" is that there is electric support (normal symbol lottery is in a high probability state).

Therefore, since the bit information is as follows, it is possible to identify the time saving, high accuracy, and SKR.
Time saving and high accuracy SKR
1st bit information: 1 1 1
2nd bit information: 0 1 1
3rd bit information: 1 1 0
Binary notation: 101 111 011
When treating as a decimal number: 4 6 3

[(11) Display device for the number of game balls, etc.]
The technical feature is that the maximum numerical value that can be displayed on the display device (display device for the number of game balls, etc.) is limited to a predetermined numerical value of 999999 or less.

The problem of this technical feature is to use the maximum number of displayable balls that can withstand a long game.

[Specific configuration]
The maximum value that can be displayed on the display device is up to 990000 as a value that can withstand continuous games for a long time.

According to this technical feature, it is possible to prevent a situation in which a player cannot display on a display device when a player has obtained a game profit that greatly deviates from the average probability when playing a game for a long time. it can.
As a conventional technique, there is no technique for showing the content regarding the display upper limit of the display device such as the number of game balls.

〔Concrete example〕
The maximum value that can be displayed on the display device is 990000 as the upper limit that can withstand continuous game for 10 hours (see FIG. 319).
When the number of game media stored in the display device exceeds 40,000, an error notification is sent to notify the player that the stored game media are to be counted, and an error is sent to the machine or device outside the game machine. The signal is output, but the game can be continued.

[(12) Game ball (number of medals) clear switch]
The present technical feature has a switch (game ball clear switch) for initializing backup information (for example, information on the number of game balls) stored in the RAM of the frame control board, and by a predetermined operation (for example, the game ball clear switch). , A game machine capable of initializing backup information (by turning on the power while pressing the game ball clear switch) (see FIG. 130).
The problem of this technical feature is to clear the backup information stored in the RAM of the frame control board.

[Specific configuration]
It has a switch for clearing the backup information stored in the RAM of the frame control board.

According to this technical feature, it is possible to individually initialize the backup information stored in the RAM of the frame control board and the backup information stored in the RAM of the main control board.
As a conventional technique, there is no technique for initializing the backup information stored in the RAM of the frame control board.

[(13) CM start confirmation]
The technical features are as follows.
(1) A power supply (VL) for connection confirmation input from a dedicated unit is provided. If the connection confirmation power supply (VL) is not turned on after the start of the gaming machine is completed, the gaming ball cannot be launched.
(2) In (1) above, even when the connection confirmation power supply (VL) is not turned on and the launch of the gaming ball is stopped after the activation of the gaming machine is completed, the starting opening prize is won. In that case, it is possible to start the fluctuation.

The problem of this technical feature is to confirm the start state of the CM by the connection confirmation power supply (VL) and to execute an appropriate process when the CM is not started.

[Specific configuration]
If the CM has not been started when the game machine has been started, the connection confirmation power supply (VL) is turned off, and the connection confirmation power supply (VL) is turned on after the CM start is completed. When it is OFF, the game ball cannot be launched and the counting button is disabled, but the telegram for periodic transmission is transmitted in the same manner as when it is ON (see FIG. 348).

According to this technical feature, if the gaming machine is activated while the dedicated unit is not activated, the game ball cannot be launched, so that the game is executed when the dedicated unit is not activated. It is possible to avoid being done.
In addition, according to this technical feature, when the dedicated unit is activated from the state where the dedicated unit is not activated, the occurrence rate of information loss or contradiction during communication between the gaming machine and the dedicated unit. Can be reduced.

As a conventional technique, there is no technique for showing the behavior when the VL is already turned off when the gaming machine is started.

〔Concrete example〕
When the power supply (VL) for connection confirmation is OFF, hold increase / decrease, symbol change start (effect symbol change start), effect execution, symbol stop (effect symbol stop), major game, error notification, operation of various operation means, model custom At least one of the change / power saving modes may be implemented, or at least one may not be implemented.

[(14) Game information]
The technical features are as follows.
(I) Game information including a plurality of type information, a plurality of count information corresponding to the type information, and at least one game information number which is the number of type information and count information is provided (FIGS. 266 to 298, FIG. 319-see FIG. 321).
The type information is information indicating the occurrence of winning a winning opening, passing through a specific area, or the like.
The count information is information representing the number or number of times corresponding to the type information.
There is a one-to-one correspondence between type information and count information, and one piece of information is not retained more than the other.
The number of game information is the number of type information and count information, and has a maximum of 15.
In the game information, if a start port prize has been generated since the last message transmission, a numerical value corresponding to the start port prize is set in the upper 4 bits of the type information, and the lower 4 bits of the type information is the start port that has won a prize. A numerical value corresponding to the position is set, a numerical value corresponding to the number of prize balls at the time of winning the start opening is set in the upper 4 bits of the count information, and 1 is set in the lower 4 bits of the count information.

When the start opening prize is generated twice or more within a predetermined period, a plurality of type information and count information are created, and up to 15 of each can be created.
It is equipped with a connection confirmation power supply (VL).
If the VL is in the OFF state when the start of the game machine is completed, it is judged that the dedicated unit may not be started, and the state in which the game ball cannot be launched is maintained until the VL is turned on. Telegrams containing information are transmitted periodically.
When the VL is switched from the ON state to the OFF state after the start of the game machine is completed, it is judged that the connection with the dedicated unit is not made, and the game ball cannot be launched until the VL is turned ON. Keep it, but the telegram containing the game information is sent periodically.
The period of the telegram transmitted periodically is allowed to deviate by a period equal to or less than a predetermined value. For example, the frame control 3150 notifies the CM3072 of the hall control / fraud monitoring information in the range of 300 ms or more and 310 ms or less, the game machine installation information in the range of 60 s or more and 62 s or less, and the game machine performance information in the range of 180 s. Notify within the range of 186s or more (see FIGS. 351 and 352).

(Ii) In the above (i), even if the VL is in the OFF state at the time of starting, the hold increase due to the starting opening winning can occur. Even if the VL is switched from ON to OFF after the start-up, the hold increase due to the start opening winning can occur.

The problem of this technical feature is to improve the ease of managing the internal state of the gaming machine.
[Specific configuration]
Game information such as starting opening prizes and big hits that occur in a predetermined period is periodically transmitted to the dedicated unit.
According to this technical feature, it is possible for the administrator to grasp detailed game information of the game machine.

[(15) Fraud detection state 1]
The technical features are as follows.
A fraud detection state 1 is provided, which is a 1-byte area (information) capable of holding up to 8 bits of bit information that treats 1 bit as one flag.
Bit information 0 can be treated as flag OFF and 1 as flag ON.
In the fraud detection state 1, the first specific bit information that turns on the flag while changing the setting, the second specific bit information that turns on the flag while checking the setting, and the third specific bit information that turns on the flag when the RWM is cleared are displayed. Hold.
The fraud detection state 1 can be treated as a numerical value of 255 or less by combining a plurality of bit information including the first to third bit information.
When only the first specific bit information is ON, it is set as a numerical value 1, and when only the second specific bit information is ON, it is set as a numerical value 2. Only the third specific bit information is set as a numerical value 2. When it is ON, it can be treated as a numerical value of 4. When a plurality of specific bit information is ON, it is preferable to add numerical values to handle the information.
It has at least one unused bit, and 0 is held in the unused bit.

The problem of this technical feature is to improve the ease of managing the internal state of the gaming machine.
[Specific configuration]
The signal output information related to the fraud detected by the main control is held as bit information, and a maximum of 256 types of information can be identified by combining the bit information as a 1-byte fraud detection state 1 (see FIG. 322).

According to this technical feature, by collectively managing the signal output information related to fraud detected by the main control, it is easy for the administrator to grasp the fraud detection state of the gaming machine, and by holding it as bit information. It will reduce the capacity.
As a conventional technique, there is no technique for showing a configuration for holding signal output information related to fraudulent main control detection.

FIG. 430 is a perspective view showing a slot machine 1 which is an example of a rotating drum type gaming machine.
Further, FIG. 431 is a diagram showing an internal configuration of the slot machine 1.
Although some parts are described using the same reference numerals as those of the above-mentioned pachinko machines, the same reference numerals may have different functions.
The slot machine 1 is, for example, a type in which a game is played using a game medal as a medium, and is a so-called "pachislot machine".

The slot machine 1 includes a box-shaped housing 2, and the slot machine 1 is installed on an island facility in a game hall (hall) via the housing 2 by nailing or the like. In FIG. 430, the diagonally lower left side corresponds to the front of the slot machine 1, and normally, the player is seated in the hall so as to face the slot machine 1 from the front.

Here, in the present specification, the left side is the left side when viewed from the player who is seated so as to face the slot machine 1, the right side is the right side when viewed from the player, and the upper side is the top side when viewed from the player. The explanation is that the lower side is the lower side when viewed from the person, the front side is the front side when viewed from the player, and the back side is the rear side when viewed from the player.

The front side of the housing 2 is open, and this opening can be opened and closed by the front door 4. FIG. 430 shows the slot machine 1 with the front door 4 closed, and FIG. 431 shows the slot machine 1 with the front door 4 open.

The left end of the front door 4 is connected to the housing 2 via a hinge mechanism (not shown).
Further, a locking device is provided on the inside (back side) of the right end portion of the front door 4, and a locking tool is also provided on the inner wall surface on the right side of the housing 2 correspondingly. As shown in FIG. 430, in a state where the front door 4 is closed, the locking device makes it impossible to open the front door 4 together with the locking tool of the housing 2. On the other hand, a cylinder lock 4a is provided on the right edge of the front door 4, and when a clerk at the amusement park twists the cylinder lock 4a clockwise using a dedicated key, the locking device is activated and the front door 4 is operated. It will be in a state where it can be opened. In this way, the front door 4 can be opened and closed by using a dedicated key.

A display window 14 is formed in the upper right portion of the front door 4, and three reels 6, 8 and 10 are installed inside the display window 14.
Each of the three reels 6, 8 and 10 is formed in an annular shape, and a reel band in which a plurality of symbols (not shown) are attached in a row at intervals is wound around the reels. Specifically, the outer peripheral surfaces of the three reels 6, 8 and 10 are divided into a plurality of areas (each area is also referred to as a "frame") at regular intervals, and each frame has a plurality of types of symbols. Is arranged. The three reels 6, 8 and 10 are connected to stepping motors corresponding to the three reels 6, 8 and 10, respectively, and rotate around the axis of the stepping motor, and the pulse number and pulse width of the drive pulse of the stepping motor. By controlling the above, it is possible to stop in frame units (predetermined rotation angle unit, predetermined rotation amount unit).

On reels 6, 8 and 10, for example, a combination of symbols associated with a big bonus combination, a combination of symbols associated with a regular bonus combination, a combination of symbols associated with a bell combination (small combination), A combination of symbols associated with the cherry role (small role), a combination of symbols associated with the watermelon role (small role), a combination of symbols associated with one of the winning combinations, the "replay role", etc. May be displayed. The combination of symbols is composed of the symbols displayed on each reel. However, in the present embodiment, some of the various symbols constituting the combination of symbols are displayed by symbols or figures whose differences between the symbols are relatively difficult for the player to recognize.

In the three reels 6, 8 and 10, for example, a horizontal effective line and an oblique effective line are set. The effective line in the horizontal direction is a line set at each position of the upper position, the middle position, and the lower position of the three reels 6, 8 and 10 when the player sees through the display window 14. Further, the effective line in the diagonal direction is the upper position of the left reel 6, the middle position of the middle reel 8, and the lower position of the right reel 10 for the three reels 6, 8 and 10 when the player sees through the display window 14. It may be a line set to the lower position of the left reel 6, the middle position of the middle reel 8, and the upper position of the right reel 10. The effective line may be an irregular line in a direction in which the horizontal direction and the diagonal direction are combined. Examples of the irregular line include a line set at the lower position of the left reel 6, the middle position of the middle reel 8, the middle position of the right reel 10, and the like. In the present embodiment, effective lines are set at the upper position, the middle position, and the lower position of the display window 14.

A medal insertion slot 16 is provided on the right end side of the front door 4. The medals inserted by the player are accepted one by one through the medal insertion slot 16, and are counted as the number of medals thrown into the game. If medals are inserted in excess of the maximum number of medals that can be thrown in one game (for example, 3 medals), that amount is stored as credits.

A credit display unit 12a is provided on the right side of the medal insertion slot 16, and the number of medals stored as credits is numerically displayed on the credit display unit 12a. The credit can be stored up to 50, for example.

A medal tray 28 is formed at the lower end of the front door 4, and if the medal insertion is not accepted, the medal inserted from the medal insertion slot 16 is returned to the medal tray 28.

A start lever 18 is installed on the left end side of the front door 4. The start lever 18 is operated (pressed) by the player in order to start (start) the rotation of each of the reels 6, 8 and 10. When the start lever 18 is operated with the necessary medals thrown in one game, the reels 6, 8 and 10 start rotating all at once. Further, when the start lever 18 is operated, the lottery process described later is executed.

On the rear side of the medal insertion slot 16, a guide path (not shown) extending from the medal insertion slot 16 to the inside of the housing 2 is arranged, and the inserted medals are placed inside the slot machine 1 one by one by the guide path. You will be guided. If the inserted medals can be accepted, the inserted medals pass through the guide path and are received by the hopper of the payout control device 94 (see FIG. 431) inside the housing 2. If the insertion of medals cannot be accepted (for example, if the number of credits has reached the upper limit), the insertion of medals will not be accepted even if the medals are inserted. Specifically, a switching mechanism (not shown) is provided at an upstream position of the guide path, and this switching mechanism switches the guide destination of the medal to either the guide path or the medal tray 28 by using, for example, a solenoid. I do. When the number of credits has not reached the upper limit, the switching mechanism does not operate, and the guide destination of the medal is directed to the payout control device 94 (see FIG. 431). On the other hand, when the number of credits has reached the upper limit, the switching mechanism is activated to switch the guide destination of the medal to the direction of the medal tray 28, and the insertion of more medals is not accepted. Further, when the start lever 18 is operated in one game, the switching mechanism operates until the reels 6, 8 and 10 stop, and it becomes impossible to accept any more medals.

On the front door 4, three stop buttons 20, 22, and 24 are arranged side by side on the right side of the start lever 18. These stop buttons 20, 22, and 24 correspond to the left, middle, and right reels 6, 8 and 10, respectively, in order. When the player operates (presses) the stop buttons 20, 22 and 24 one by one while the reels 6, 8 and 10 are rotating at a constant speed, the rotation of the corresponding reels 6, 8 and 10 is stopped individually. To do.

When the stop buttons 20, 22, and 24 are operated by the player and all the reels 6, 8 and 10 stop rotating, the result of the game is determined based on the combination of the symbols displayed on the effective line (described later). Result judgment processing is executed).

On the right side of the credit display unit 12a, a payout number display unit 12b is provided, and the number of medals paid out at the time of each winning is displayed here.

In addition, other display units 12c are provided above the credit display unit 12a and the payout number display unit 12b, and various lamps indicating the game status of the slot machine 1 and the like are arranged.

A MAX bet button 32 is installed on the upper part of the start lever 18, and the player operates the MAX bet button 32 to use the remaining number of credits to obtain the maximum number of cards required for this game (for example, 3). You can bet. If there is a sufficient number of remaining credits (for example, 3 or more), the player can operate the MAX bet button 32 once to obtain the maximum number of credits (for example, 3) that can be invested in the game. It can be deducted from and used as the number of medals thrown in the game. Although not particularly shown, a normal bet button (1 bet button) capable of betting one bet may be arranged. When the normal bet button is pressed once, the number of credits is reduced by one, and that amount is used as the number of medals thrown in the game. When the bet button is pressed repeatedly until the maximum number is reached, the number of credits is reduced by the number of times each is pressed, and the number of bets is added instead.

When ending the game with the slot machine 1, the player does not need to determine the number of medals to be thrown in the next game. A checkout button 34 is provided above the start lever 18, and if there is a remaining number of credits, the player can operate the checkout button 34 to settle the remaining number and receive a medal return. it can. When the settlement button 34 is pressed, the medal is returned to the medal tray 28. When the settlement button 34 is pressed and held for a long time, it functions as a settlement button, and when the settlement button 34 is pressed only once for a short time, it functions as a normal bet button. ) May be combined.

A decorative panel 36 is installed below the front door 4 and above the medal tray 28. The decorative panel 36 displays the model name of the slot machine 1 and is decorated based on the game concept. The decorative panel 36 may be a liquid crystal display, or may function as the following effect switching button 45.

An effect switching button 45 is installed in the center of the front door 4. The player can switch the effect content and change the volume and brightness by pressing the effect switching button 45 (operation input).

Further, the front door 4 is provided with a top lamp 38, a side lamp 40, and the like at the upper end portion and the left and right end portions. The top lamp 38 and the side lamp 40 diffuse the light emitted from the built-in LED to emit light, and can perform an effect associated with the game. The side lamp 40 can also be a movable body that can move left and right (opens and closes like a blade).

A large liquid crystal display 42 (display device) is installed in the central portion of the front door 4. The liquid crystal display 42 can display an effect associated with the game by displaying an image, characters, or the like.
The liquid crystal display 42 can display an image at a low update rate (30 FPS) or a high update rate (60 FPS).

A speaker 54 is installed at the lower end of the front door 4 (see FIG. 431), and the speaker 54 outputs sound effects, sounds, BGM, and the like to perform an effect associated with the game.
Further, on the back side of the front door 4, a payout control device 94 (see FIG. 431) for paying out medals to the medal tray 28 is provided.

FIG. 432 is a block diagram showing various electronic devices installed in the slot machine 1.
The slot machine 1 includes a main control device 70, and the main control device 70 mainly controls the progress of the game in the slot machine 1. The main control device 70 is equipped with a circuit board on which a main control CPU 72, which is a central arithmetic processing unit, is mounted. The main control CPU 72 is an LSI package in which semiconductor memories such as ROM 74 and RAM 76 are integrated together with a CPU core (not shown). It is configured as.

Although not shown in particular, the main control device 70 is equipped with an input / output driver (interface), a random number generation counter, various ICs, etc. in addition to the main control CPU 72, and these are circuit boards together with the main control CPU 72. Implemented above. Further, a signal transmission path, a power supply path, a control bus, and the like are formed as wiring patterns on the circuit board.

The start lever 18 and the stop buttons 20, 22, and 24 described above are equipped with a start operation sensor 80 and a stop operation sensor 82 that detect their respective operations. The operation of the start lever 18 (start operation) and the operation of the stop buttons 20, 22, and 24 (stop operation) performed by the player are detected by using the start operation sensor 80 and the stop operation sensor 82, respectively. The stop operation sensor 82 is provided for each of the three stop buttons 20, 22, and 24. The detection signals of the start operation sensor 80 and the stop operation sensor 82 are input to the main control CPU 72, and the main control CPU 72 accepts a start operation or a stop operation by the player based on the input detection signals.

Similarly, the MAX bet button 32 is also equipped with the bet button sensor 86, and the bet button sensor 86 is used by the player for the operation (insertion operation) of throwing a medal into the game using the MAX bet button 32. Is detected. Further, the insertion medal sensor 88 is also equipped in the guide path of the medal arranged behind the medal insertion slot 16, and the operation (insertion operation) in which the player throws a medal into the game through the medal insertion slot 16 is the insertion medal. It is detected using the sensor 88. The detection signals of the bet button sensor 86 and the insertion medal sensor 88 are input to the main control CPU 72. Based on the input detection signal, the main control CPU 72 performs a process of accepting a player's insertion operation and adding or subtracting the number of credits stored.

The credit display unit 12a, the payout number display unit 12b, the other display unit 12c, and the like are collectively controlled as the game information display device 90. The game information display device 90 is composed of an LED, a 7-segment LED, and a drive circuit thereof, and the main control CPU 72 controls the game information display device 90 according to the progress of the game and operates various display units.

The reels 6, 8 and 10 are rotated and stopped by the reel driving device 92. The reel drive device 92 includes three stepping motors corresponding to the reels 6, 8 and 10 and an index sensor for detecting the rotation position of the reels 6, 8 and 10. The main control CPU 72 outputs a drive pulse to each stepping motor through an output driver, and controls the reels 6, 8 and 10 to be rotated or stopped at a predetermined position.

From the reel drive device 92, the detection signal of the index sensor is output to the main control CPU 72. The main control CPU 72 can detect the position related to the rotation of each reel 6, 8 and 10 (for example, the number of steps from the reference position) based on the detection signal of the index sensor.

The payout control device 94 includes a mechanism (motor and drive circuit) for actually paying out medals, a payout sensor for detecting the actually paid out medals, and a function as a hopper for storing the inserted medals. .. The payout control device 94 is installed inside the housing 2 (see FIG. 431), and the hopper portion for storing medals has a large opening on the upper surface. It is dropped on the hopper portion of the payout control device 94 behind.

Further, the payout control device 94 can rotate the motor to continuously eject medals one by one. The ejected medals are paid out to the medal tray 28 from the back side of the front door 4. The main control CPU 72 outputs a drive signal to the motor of the payout control device 94, and executes medal payout, credit settlement, and the like.

Further, the main control CPU 72 can output a signal (medal-in signal, medal-out signal, game status signal, etc.) to the outside of the slot machine 1 (for example, a data lamp or a hall computer) through an external terminal plate (not shown).

Apart from the main control device 70 described above, the slot machine 1 includes an effect control device 124 as a control configuration. The effect control device 124 controls the effect as the game progresses in the slot machine 1. The effect control device 124 is also equipped with a circuit board on which the effect control CPU 126, which is a central arithmetic processing unit, is mounted. The effect control CPU 126 is also configured as an LSI package in which semiconductor memories such as the control ROM 180 and the RAM 130 are integrated. The effect control CPU 126 controls the effect based on the command for effect transmitted from the main control CPU 72.

The effect control CPU 126 is configured as an LSI in which a semiconductor memory such as a RAM (RWM) 130 or an eRAM131 (see FIG. 433) is built in together with a CPU core (not shown). The effect control device 124 is equipped with various functions required to realize the effect in the slot machine 1. For example, a VDP 152 for drawing an effect screen reproduced on the screen of the liquid crystal display 42, a driver IC 132 for controlling devices such as various lamps 38 and 40 that produce visual effects, and a speaker 54 for outputting sound. It is equipped with a voice IC 134 or the like for control. The internal functional configuration of the effect control device 124 will be described in detail later with reference to another figure.

The effect control device 124 and the main control device 70 are connected to each other via, for example, a communication harness (not shown). However, communication between them is performed in only one direction from the main control device 70 to the effect control device 124, and communication in the opposite direction is not performed. The communication harness adopts a parallel format according to the bus width of various effects commands (hereinafter, referred to as "effect commands") transmitted from the main control device 70 to the effect control device 124. Alternatively, the serial format may be adopted according to the hardware configuration of each driver (I / O).

A sub-connection board 136 is connected to the effect control device 124, and drive signals from the driver IC 132 and the audio IC 134 are transmitted to various lamps 38 and 40 and the speaker 54 via the sub-connection board 136. Further, the effect switching button 45 is connected to the sub-connection board 136, and when the player operates the effect switching button 45, the contact signal of the effect switching button 45 is input to the effect control device 124 through the sub-connection board 136. To.

In addition, a driver board 138 is installed on the effect control device 124, and a movable motor 57 is connected to the driver board 138. In the present embodiment, when the side lamp 40 is a movable body, the movable body motor 57 drives the movable body via, for example, a link mechanism (not shown). The drive signal from the driver IC 132 is transmitted to the movable motor 57 via the driver board 138, respectively.

A liquid crystal display 42 is connected to the effect control device 124, and the display screen can be visually recognized through a substantially rectangular opening formed in the front door 4. Further, an inverter board 158 is connected to the effect control device 124, and the inverter board 158 generates an AC power supply applied to the backlight (for example, a cold cathode tube) of the liquid crystal display 42.

In addition, a power supply control unit (not shown) is provided inside the slot machine 1. This power supply control unit has a built-in switching power supply circuit, and when external power (for example, AC100V, etc.) is taken from the island equipment through a power cord or the like, necessary power (for example, DC + 12V, + 5V, etc.) can be generated from the external power. The electric power generated by the power supply control unit is supplied to a device that requires electric power, such as the main control device 70 and the effect control device 124. The power supply unit is also used when changing the setting of the slot machine 1 or resetting the RAM 76 of the main control CPU 72. The "setting" is for changing the machine allocation of the slot machine 1 predetermined to a plurality of stages, and the "setting" is prepared, for example, from 1 to 6. "Settings", their changes, resets, etc. can be executed by a setting change device (setting change means).

[Internal configuration of production control device]
FIG. 433 is a block diagram showing an internal functional configuration of the effect control device 124.
As described above, the effect control device 124 has a role as an effect control processor that controls the effect as the game progresses. Therefore, in addition to the effect control CPU 126, the effect control device 124 is equipped with a control ROM 180 and a watchdog timer IC (WDTIC) 188, which are necessary for the effect control device 124 to function as the effect control processor. The control ROM 180 stores a basic program for controlling the effect. The effect control CPU 126 controls the effect by accessing the control ROM 180 via a CPU bus (not shown) and executing a program stored in the control ROM 180. The watchdog timer IC188 is a timer that monitors whether the control executed by the effect control device 124 is normally performed (whether the process is completed within the estimated time), and is connected to the reset terminal of the effect control CPU 126. There is. If the signal (clear pulse) for clearing the monitoring timer of the watchdog timer IC188 is not input within a predetermined time, the watchdog timer IC188 outputs a signal (reset pulse) for resetting and activating the effect control CPU 126. To do. As a result, the effect control device 124 is forcibly reset and activated.

In addition to these, the effect control device 124 has SRAM 182, which is a storage area for backup data, a crystal oscillator 181 that generates a clock signal of a predetermined frequency, and a real-time clock (RTC) 184 that manages time. , SRAM 182, a lithium battery 186 that supplies backup power to the real-time clock 184, peripheral ICs such as an input / output driver and a counter / timer circuit (not shown) are provided. The lithium battery 186 stores the electric power and charges itself while the driving electric power is being supplied from the power supply control unit 162 to the effect control device 124. The SRAM 182 and the real-time clock 184 are connected to the lithium battery 186, and can be driven by the lithium battery 186 when the supply of the driving power from the power supply control unit 162 to the effect control device 124 is cut off. Therefore, even if the power supply from the power supply control unit 162 is cut off, the SRAM 182 and the real-time clock 184 continue to operate for a period until the lithium battery 186 is depleted (for example, about one and a half months). The SRAM 182 can retain the stored information for a while even when the power is turned off.

The effect control program is configured to store information on security, monitoring, defects, and the like that should not be easily erased in the SRAM 182. As a result, for example, when some trouble occurs in the effect control device 124, the slot machine 1 is collected (or inspected in the installed state), and the information held in the SRAM 182 is analyzed to proceed with the investigation of the cause of the trouble. It becomes possible.

By the way, in order to control the effect executed by the effect control CPU 126 according to the program stored in the control ROM 180, as described above, the effect control using devices such as the liquid crystal display 42, various lamps 38 and 40, and the speaker 54 is used. Is included. The flow of this effect control can be roughly divided into two stages, "overall control (reproduction instruction)" and "individual control (reproduction control)". The effect control CPU 126 first receives an effect command transmitted from the main control device 70, and indirectly instructs each device to reproduce the effect according to the content of the effect command (overall control). Next, the effect control CPU 126 generates instruction data obtained by converting the instruction content into a more specific expression suitable for each device, and relays between the effect control CPU 126 and each device. Send to (individual control). As a result, each control device 134, 152, 198, 199 controls each device based on the instruction data, and the effect reproduction (screen display, voice output, lamp emission, movable body displacement) using each device in the slot machine 1 is performed. Etc.) is realized.

As described above, the effect control CPU 126 has different functions depending on the stage of the effect control, and these functions are realized by properly using the resources of the effect control CPU 126. At the stage of overall control, the effect control unit 210 in the effect control CPU 126 becomes the main operator. Further, in the stage of individual control, the display control unit 220, the voice control unit 222, the lamp control unit 224, the motor control unit 226, or the sensor control unit 228 in the effect control CPU 126 are the main operating units according to the device to be controlled. It becomes. The effect control unit 210 may be configured to directly control the control devices 134, 152, 198, and 199.

The effect control device 124 functions as an effect control processor at the stage of overall control, whereas it functions as an effect reproduction processor at the stage of individual control. Therefore, in addition to the circuit board (effect display control board) and CGROM (image / audio ROM) 190 on which the VDP 152 is mounted, the effect control device 124 also includes an audio IC 134 for controlling various devices used for reproducing the effect. It is equipped with an LED driver 198, an SMC (serial control controller) 199, and a driver IC 132.

The CGROM 190 stores the drawing material (moving image data) constituting the effect screen and the audio material (audio data) output as the effect progresses in a state of being compressed by a predetermined compression algorithm. The CGROM 190 is connected to the VDP 152 and the voice IC 134 via a CG bus (not shown).

The VDP152 is a processor dedicated to drawing an effect image, and is integrated into one chip together with the effect control CPU 126. Further, the VDP 152 has a built-in VRAM 156 (video memory) mainly used when developing a drawing material, and a drawing material decoder 157 for decompressing (decoding) the drawn drawing material in a compressed state. The VDP 152 first analyzes the instruction content transmitted from the display control unit 220, reads the necessary drawing material from the CG ROM 190 via the CG bus, and transfers it to the VRAM 156. Then, the read drawing material is decoded by the drawing material decoder 157, the effect image is drawn on the VRAM 156, and the effect image is expanded in the frame buffer (video memory) for each frame (still image per unit time). By individually driving each pixel (full-color pixel) of the liquid crystal display 42 based on the image data buffered here, the reproduction of the effect screen is realized.

The VRAM 156 (frame buffer) is a memory commonly used when displaying an image at a low update rate (30 FPS) and when displaying an image at a high update rate (60 FPS), and displays the image on the liquid crystal display 42. A video memory that stores image data for display.

The audio IC 134 is a sound generator that generates sound effects such as sound effects and BGM that are reproduced during the execution of the effect, and is connected to an amplifier, an external DRAM, or a CG bus (not shown). Further, the audio IC 134 has a built-in audio material decoder 135 that decompresses (decodes) the compressed audio material. The voice IC 134 first analyzes the instruction content transmitted from the voice control unit 222, and reads out the necessary voice material from the CGROM 190 via the CG bus. Then, the read audio material is decoded on the external DRAM using the audio material decoder 135. By outputting the decoded audio to the speaker 54 via the amplifier, stereo 2ch or monaural 2ch audio reproduction (may be a larger number of channels) is realized.

The LED driver 198 controls a lighting pattern and a brightness pattern associated with the execution of the effects of the various lamps 38 and 40 provided on the front side of the slot machine 1. In the LED driver 198, an address designation synchronous serial system is adopted. The LED driver 198 first controls the lighting pattern and the brightness pattern based on the instruction content transmitted from the lamp control unit 224, and transfers the drive data corresponding to the control to the driver IC 132.

When the movable body for production is arranged, the SMC 199 controls the drive pattern of the movable body motor 57 which is the drive source of the movable body. In SMC199, a clock synchronous serial system is adopted. The SMC 199 first generates a drive pattern based on the instruction content transmitted from the motor control unit 226, and transfers this to the driver IC 132. Although the SMC 199 is used only for generating the drive pattern of the motor here, since the SMC 199 can generate not only the motor but also the lighting pattern and the brightness pattern of the lamp, the SMC 199 is applied instead of the LED driver 198 described above. However, it is also possible that the SMC 199 is configured to generate data patterns for both lamps and motors.

The driver IC 132 controls the drive voltage applied to the lamp or the motor based on the drive data transferred from the LED driver 198 or the SMC 199. The driver IC 132 includes switching elements such as PWM (pulse width modulation) ICs and MOSFETs (not shown), and switches (or duty switches) the drive voltages applied to the various lamps 38 and 40 to manage their operations. As a result, it is possible to reproduce the effect using a lamp or a movable body.

In addition to this, the driver IC 132 transfers the contact signal input when the effect switching button 45 is operated to the effect control unit 210 via the sensor control unit 228. The effect control unit 210 appropriately changes the effect content to be reproduced based on the content of the transferred contact signal.

The above is a configuration example relating to the control of the slot machine 1. Subsequently, the control processing executed by the main control CPU 72 of the main control device 70 will be described.

[Main processing]
FIG. 434 is a flowchart showing the procedure of the main process executed by the main control CPU 72. Hereinafter, each procedure will be described.

Step S10: In the medal insertion process, the main control CPU 72 confirms the detection signal from the insertion medal sensor 88 or the bet button sensor 86. Upon receiving any of the detection signals, the main control CPU 72 increments the bet counter on, for example, the RAM 76. When the bet number counter reaches the upper limit (for example, 3), the main control CPU 72 invalidates the operation of the MAX bet button 32.

Further, the main control CPU 72 confirms the detection signal from the inserted medal sensor 88, and when the detection signal is received in a state where the bet number counter reaches the upper limit (for example, 3), the credit number counter is incremented on the RAM 76, for example. .. As a result, the credit display unit 12a displays a numerical value according to the credit number counter.

When the main control CPU 72 receives the detection signal from the insertion medal sensor 88 or the bet button sensor 86, the main control CPU 72 transmits an insertion processing command to the effect control CPU 126 each time. The insertion processing command includes information that the player's insertion operation and credit addition operation have been accepted, and also includes information such as the value of the bet number counter and the value of the credit number counter at that time. ing.

Step S12: In the start lever processing, when the value of the bet number counter reaches the required number of sheets (for example, 3), the main control CPU 72 enables the operation of the start lever 18 to be accepted.

Step S14: The main control CPU 72 determines whether or not the number of medals required for this game has been inserted and the start lever 18 has been operated. These conditions can be determined based on the value of the bet number counter and the detection signal from the start operation sensor 80. The main control CPU 72 confirms whether or not the detection signal from the start operation sensor 80 has been input while referring to the value of the bet number counter, and if it is determined that any of the conditions is not satisfied (No), the step. The process from S10 to step S14 is repeated.

On the other hand, when the number of medals required for this game has been inserted and the detection signal from the start operation sensor 80 is received (Yes), the main control CPU 72 cannot accept the operation of the start lever 18. To do. The main control CPU 72 operates the switching mechanism described above to switch the guiding direction of the medal inserted into the medal insertion slot 16 to the direction of the medal tray 28.

Further, when the main control CPU 72 receives the detection signal from the start operation sensor 80, the main control CPU 72 transmits a start operation command to the effect control CPU 126. The start operation command includes information that the operation of the start lever 18 by the player has been accepted. At the same time, the main control CPU 102 outputs the number of medal-in signals through an external terminal plate (not shown).

Step S16: The main control CPU 72 executes the lottery process. In the lottery process, the main control CPU 72 acquires a random number (for example, any of 0 to 65535 in decimal notation) from a random number generation counter (random number generator or the like). Then, the main control CPU 72 refers to the lottery table read from the ROM 74, and determines whether or not the acquired random number value matches any of the winning values. In the lottery table, a winning range (winning area) and a non-winning range (non-winning area) for all random values (0 to 65535) are defined. In addition, at least one winning combination or losing combination is assigned to the winning range.

In any case, the probability of winning (N / 65536) is determined by the number of hit values (N) in the total number of random values (65536). The lottery table is prepared for each of "setting 1" to "setting 6". Generally, "setting 1" has the lowest probability of winning, and "setting 6" has the highest probability of winning.

The main control CPU 72 sets the lottery result flag on the RAM 76 based on the lottery result. The lottery result flag is internal information used to determine the result of the lottery in this game, and if it is not won, it remains the default, and if it is won, the winning flag according to the winning combination is set respectively. ..

More specifically, the main control CPU 72 sets the winning flag corresponding to the winning combination determined to be won from the non-winning state (off state) to the winning state (on state) based on the result of the lottery. When two or more types of winning combinations are won in duplicate, a winning flag corresponding to each of the two or more types of winning combinations won in duplicate is set in the winning state.

When the main control CPU 72 executes the lottery process, the main control CPU 72 transmits a winning number command to the effect control CPU 126. The winning number command includes information on whether the result of the lottery is non-winning or, if winning, which winning combination is applicable.

Step S17: The main control CPU 72 executes the state transition determination process. In the state transition determination process, when the main control CPU 72 stays in the normal gaming state (normal mode) that shifts after reset, whether or not to shift to the chance zone (fireworks zone) based on the result of the lottery. judge.

In addition, when staying in the chance zone, it is determined whether or not to shift to the AT (assist time) state based on the result of the lottery, and whether or not to end the chance zone and shift to the normal gaming state. .. The game state transition process based on the determination result is executed in the result determination process described later.

When staying in the normal gaming state (normal mode), for example, when the main control CPU 72 shifts to the chance zone at 0.1% of the replay winning combination and shifts to the chance zone at 20% of the cherry winning combination. judge.
When staying in the chance zone, the main control CPU 72 determines that, for example, 10% of the replay winning combination shifts to the AT state, and 45% of the cherry winning combination wins shifts to the AT state.
The main control CPU 72 determines that the chance zone is terminated when the specified number of games is exhausted.

When the main control CPU 72 executes the state transition determination process, the main control CPU 72 transmits an internal state command to the effect control CPU 126. The internal state command includes a normal mode indicating that the player is staying in the normal game state, a chance zone indicating that the player is staying in the chance zone, and an ART state indicating that the user is in the ART (assist replay time) state. , Normal mode transition indicating transition to normal game state, chance zone transition indicating transition to chance zone, AT state transition indicating transition to AT state, ART state transition indicating transition to ART state, etc. Information is included.

Step S18: Next, the main control CPU 72 executes the rotating cylinder rotation process. If the predetermined rotation start condition is satisfied, the main control CPU 72 outputs a drive pulse to the reel drive device 92. As a result, the three reels 6, 8 and 10 start rotating. When the main control CPU 72 executes the rotation cylinder rotation process, the main control CPU 72 transmits a rotation cylinder rotation command to the effect control CPU 126.

Further, when the main control CPU 72 confirms that the rotation speeds of the reels 6, 8 and 10 have become constant, the function of the stop operation sensor 82 is enabled for each of the stop buttons 20, 22 and 24.

Further, the main control CPU 72 reads the reel control table corresponding to the lottery result flag from the ROM 74 and stores it in the RAM 76. Information for individually controlling the stop positions of the reels 6, 8 and 10 is recorded in the reel control table in advance. Specifically, the number of steps (number of drive pulse outputs) from the time when the main control CPU 72 receives the detection signal from the stop operation sensor 82 to the time when the stepping motors of the reels 6, 8 and 10 are stopped is recorded. ing. As a result, combinations of symbols that should not be displayed on the effective line are expelled, and conversely, combinations of symbols that may be displayed on the effective line are drawn in (so-called "slip" occurs).

Step S20: When the reels 6, 8 and 10 are rotated, the main control CPU 72 then executes the rotation cylinder stop processing. This process corresponds to so-called "reel control". When the main control CPU 72 receives the detection signal from the stop operation sensor 106 for any of the stop buttons 20, 22, and 24, the main control CPU 72 controls the operation of the reel drive device 92 based on the reel control table. At the same time, the main control CPU 72 sets the first stop flag, the second stop flag, and the third stop flag on the RAM 76 in the order in which the detection signals are received from the stop operation sensor 82, and the reels 6, 8, which have already been stopped, For 10, the stopped flag is set for each.

When the main control CPU 72 executes the rotation cylinder stop processing, it transmits an operation rotation cylinder command, a pressing position command, a stop position command, and a command after the rotation cylinder is stopped to the effect control CPU 126. Of these, the operation rotation command includes information indicating which of the left reel 6, the middle reel 8, and the right reel 10 has been stopped. Further, the push position command includes information indicating which of the symbol combinations is located in the display window 14 for the reels 6, 8 and 10 and the stop buttons 20, 22 and 24 are pressed. The stop position command includes information indicating the stop positions of the reels 6, 8 and 10, that is, the combination of symbols displayed at the upper, middle and lower positions in the display window 14 (so-called "rolls"). Is included. The command after stopping the rotation is a command indicating that all reels 6, 8 and 10 have stopped.

In the rotating cylinder stop processing, as a result of the main control CPU 72 individually controlling the stop positions of the reels 6, 8 and 10 based on the reel control table, the combination of symbols associated with the winning combination is on the effective line as much as possible. Stop at. For example, when the winning combination is the "watermelon combination", it is effective even if the stop buttons 20, 22, and 24 are operated at the timing when the combination of symbols associated with the "watermelon combination" is not located on the effective line. In order to display the combination of symbols associated with the "watermelon combination" on the line, the main control CPU 72 stops the reels 6, 8 and 10 at a position where the reels 6, 8 and 10 are rotated by a predetermined number of frames. Since the range of extra rotation (sliding) is determined in advance by the reel control table (for example, for a maximum of 4 frames), depending on the timing when the stop buttons 20, 22, and 24 are operated, "watermelon" is placed on the effective line. The combination of symbols associated with "role" may not stop.

Step S22: The main control CPU 72 determines whether or not all of the three reels 6, 8 and 10 have been stopped. If any of the reels 6, 8 and 10 is still rotating (No), the main control CPU 102 executes the rotation stop processing in step S20. When it is determined that all the three reels 6, 8 and 10 have stopped (Yes), the main control CPU 72 proceeds to the next step S24.

Step S24: When all three reels 6, 8 and 10 have been stopped, the main control CPU 72 performs a result determination process. In this process, the main control CPU 72 determines the result of the game based on the combination of symbols stopped on the effective line in the display window 14. For example, when the combination of symbols associated with the "watermelon combination" is displayed on the valid line, the main control CPU 72 determines that the small combination "watermelon combination" has been won. In addition to this, when the combination of symbols associated with the "bell role" is displayed or the combination of symbols associated with the "cherry role" is displayed, the main control CPU 72 is set to "bell" respectively. It is judged that the player has won a small role such as "role" or "cherry role".

For example, when a combination of symbols associated with "cherry role", "bell role", "watermelon role", etc. is displayed on the effective line, "cherry role", "bell role", or "watermelon role", respectively. It is judged that he won a small role. The combination of symbols associated with the small combination includes those that display the same type of symbols on the effective line in combination (for example, "watermelon symbol"-"watermelon symbol"-"watermelon symbol"), for example, on the effective line. There is also a combination of different types of symbols displayed (for example, "cherry symbol"-"ANY symbol"-"ANY symbol").

In addition, if a combination of symbols associated with the "replay combination" is displayed on the valid line, the result of the game is determined to be a replay. If the result of the game is a re-game, the next game can be executed without throwing a new medal.
In this way, the main control CPU 72 (re-game execution means) enables the next game without the need to insert a game medal when the combination of symbols corresponding to the re-game is displayed on the predetermined effective line. ..

On the other hand, when a combination of symbols associated with the "big bonus combination" (for example, "7 symbols"-"7 symbols"-"7 symbols") is displayed on the valid line, a so-called "big bonus game" is displayed. It shifts to a special game state (processing during the special game state) such as. In addition, when a combination of symbols associated with the "regular bonus combination" (for example, "BAR symbol"-"BAR symbol"-"BAR symbol", etc.) is displayed on the valid line, a so-called "regular bonus game" is displayed. It shifts to a special game state (processing during the special game state) such as.

When the game shifts to the special game state, the game progresses under favorable conditions for the player, and for example, there is an opportunity to win a small role such as "bell role" or "watermelon role" more frequently than in the normal game state. , The number of payouts for winning can be increased, and it becomes possible to win a small role of a type that does not win in the normal game state.

On the other hand, if the combination of symbols displayed on the valid line does not correspond to a predetermined winning combination or re-game, the main control CPU 72 determines the result of the game as "other". "Other" is determined when the lottery is not won, or even if the lottery is won, the combination of symbols associated with the winning combination in the rotation stop processing in step S20 can be displayed. If you couldn't. In the case of non-winning, it corresponds to "missing", but if the combination of symbols associated with the winning combination cannot be displayed in the reel stop processing, the player operates the stop buttons 20, 22, 24. Since the timing to do this is due to the fact that the conditions of the reel control table are not met, it corresponds to the "missing" of the winning combination or the intentional "removal" of the winning combination.

When it is determined in the result determination process that a small winning combination has been won, the main control CPU 72 writes the corresponding scheduled payout number values (for example, 10, 15, etc.) on the RAM 76. In other cases, the main control CPU 72 leaves the value of the planned payout number at 0 (default).

Although not particularly shown, when the process shifts to the above-mentioned special game state processing, the main control CPU 72 controls the progress of the game in a special game state called, for example, a "big bonus game" or a "regular bonus game". At the same time, the main control CPU 72 outputs a game status signal through an external terminal board (not shown). In this case, the main control CPU 72 erases the winning flag on the RAM 130 and rewrites the basic game information (required number of sheets, lottery table, etc.) to the one in the special game. As a result, the game proceeds under conditions different from the normal game state before the transition to the special game state. In particular, the lottery table has a higher probability of winning a small role than in the normal game state, so there is a high probability of winning a small role in each game, and as a result, there is an opportunity to receive medals by winning frequently. Is given to the player. The special game state is one in which the game ends when the number of payouts reaches the specified number during that period, or one in which the game ends after the specified number of games.

Further, in the case of staying in the chance zone, if the condition for shifting to the AT state is satisfied, the gaming state shifts to the AT state (processing during the AT state). In the AT state, the winning probability of the small winning combination or the replay has not changed, but the navigation effect that assists the combination of the symbols associated with the winning combination is displayed on the effective line is executed. The condition for shifting to the AT state can be, for example, the condition of winning the AT lottery that is executed when a small role, replay, or the like is won. Further, the AT state is an RT preparation state for shifting to the RT (replay time) state. The RT state is a state in which the winning probability of the replay combination is changed (set higher) than the winning probability (about 1 / 7.3) of the replay combination in the normal game state (non-RT state). The RT preparation state is a gaming state in which the winning probability of the replay combination is the same as that in the normal state, but the "RT state rush replay combination" described later can be won. Then, by correctly answering the push order by the navigation by the AT state, the combination of the symbols associated with the "RT state rush replay combination" which is one of the conditions for shifting to the RT state is easily displayed on the effective line. It becomes a state. The AT state may be a state in which the AT state is changed to the AT state after the AT preparation state.

Then, when the combination of the symbols associated with the "RT state rush replay combination" is displayed on the effective line, the game shifts to the RT state (processing during the RT state) different from the normal game state and the special game state. The RT state is a state in which the "replay role" is won with a higher probability than the normal game state. As the transition condition to the RT state, one condition may be defined, or a plurality of conditions may be defined. When a plurality of conditions are set, it is possible to shift to the RT state based on the fact that at least one of the plurality of predetermined conditions is satisfied. It should be noted that a plurality of RT states can be set as the RT states.

Then, when the above-mentioned RT state and AT state are generated at the same time, the state shifts to the ART (assist replay time) state (processing during the ART state). The AT state, RT state, and ART state are terminated when a predetermined termination condition is satisfied.

Step S26: When the result of the game is determined, the main control CPU 72 next performs the payout process. In this process, the main control CPU 72 controls the operation of the payout control device 94 with reference to the value of the planned payout number recorded in the RAM 102. In the credit mode for storing payouts, if a value other than 0 is recorded in the planned payout number, the main control CPU 72 refers to the value of the credit count counter, and if the maximum number is not reached, the value of the planned payout number. Is added to the value of the credit count counter, and the amount is subtracted from the planned payout number. When the value of the credit number counter reaches the maximum number, the main control CPU 72 outputs a drive signal to the motor of the payout control device 94, and actually executes the medal payout operation. Then, when the main control CPU 72 receives the detection signal from the payout sensor of the payout control device 94, the main control CPU 72 subtracts the detection signal from the scheduled payout number, and when the value becomes 0, the motor of the payout control device 94 is stopped.

Further, when the main control CPU 72 executes the payout process, it transmits a command to the effect control CPU 126 after stopping the rotation. The command after stopping the rotation includes information indicating that all reels 6, 8 and 10 have stopped. When medals are paid out, the main control CPU 72 outputs medals out signals for the number of medals through an external terminal plate (not shown).

When the result determination process determines that the game is a re-game, the main control CPU 72 holds (or restores) the value of the bet number counter stored in the current game, or the bet number counter required for the next game. The value is set and the process proceeds to step S10. Further, when shifting to the special game state in the result determination process, the main control CPU 72 sets the special game state flag on the RAM 76, and for example, shifts to the special game state process different from the main process, and is in the special game state. Executes the processing of. Further, when shifting to the AT state, RT state, ART state, etc. in the result determination process, the main control CPU 72 sets the AT state flag, RT state flag, ART state flag, etc. on the RAM 76, and is different from the main process, for example. The process shifts to the AT state processing, the RT state processing, and the ART state processing, and the processing in each state is executed.
In other cases, the main control CPU 72 clears the winning flag, ends the payout process, and returns to step S10. However, if the winning flag corresponding to the transition to the special gaming state (for example, the one corresponding to the big bonus role or the regular bonus role) is set, the result judgment process corresponds to the big bonus role or the regular bonus role. If it is determined that the combination of the attached symbols is not displayed, the main control CPU 72 ends the payout process without clearing the winning flag, and returns to step S10.

[Example of production image]
Next, the effect image actually displayed on the liquid crystal display 42 in the slot machine 1 will be described with some examples.

FIG. 435 is a diagram showing an example of a normal effect and a special effect.

[Normal mode]
As shown in FIG. 435 (A), in the normal mode (normal effect), a background image in which the female character is walking is displayed.
Further, in the normal mode, the normal image display area R1 of 1 row and 3 columns for variablely displaying the effect design imitating the design displayed on the main reel of a general pachislot machine is displayed in the lower part of the screen. ing. When the player looks at the display window 14, the area of 3 rows and 3 columns on the three reels 6, 8 and 10 can be confirmed, but in this normal mode, the area of 1 row and 3 columns (1 row and 3 columns). For example, it is possible to perform an effect as if looking at the area (the area at the middle position of the display window 14), that is, as if looking at the area of one row and three columns of the main reel of a general pachislot machine. it can.

In the normal image display area R1, a combination of production symbols corresponding to the combinations of symbols displayed on the three reels 6, 8 and 10 that can be visually recognized from the display window 14 may be displayed or displayed. The combination of the effect symbols corresponding to the combinations of the symbols displayed on the three reels 6, 8 and 10 that can be visually recognized from the window 14 may not be displayed.
Specifically, when a combination of symbols corresponding to the "replay combination" is displayed on the effective lines of the three reels 6, 8 and 10 that can be visually recognized from the display window 14, the normal image display area R1 is displayed. The combination of the effect symbols corresponding to the "replay combination" may be displayed, or the combination of the effect symbols corresponding to the "bell combination" may be displayed in the normal image display area R1.

Then, in this normal mode, the player plays a game aiming at winning the "big bonus game" or the "regular bonus game".
In addition, in this normal mode, when a specific small combination is established, it may enter the "fireworks zone" shown below. For example, 20% of the time when the role of cherry is won will enter the "fireworks zone" as a chance zone.

[Fireworks zone]
As shown in FIG. 435 (B), in the fireworks zone (special effect), a background image expressing a scene in which fireworks are launched in the night sky is displayed.
Further, in the fireworks zone, a special image display area R2 having 3 rows and 3 columns for variablely displaying the above-mentioned effect pattern is displayed in the central portion of the screen. When the player looks at the display window 14, he / she can see the area of 3 rows and 3 columns on the three reels 6, 8 and 10, but in this fireworks zone, it corresponds to the area of 3 rows and 3 columns. It is possible to perform an effect as if looking at an area, that is, an effect as if looking at an area of 3 rows and 3 columns of the main reel of a general pachislot machine.

In the special image display area R2, a combination of production symbols corresponding to the combinations of symbols displayed on the three reels 6, 8 and 10 that can be visually recognized from the display window 14 is displayed as in the normal mode. In some cases, the combination of the effect symbols corresponding to the combinations of the symbols displayed on the three reels 6, 8 and 10 that can be visually recognized from the display window 14 may not be displayed.

In this way, during the execution of the fireworks zone (special effect), a pseudo reel effect (effect that reproduces the movement of the reel) using the special image display area R2 is executed, and this pseudo reel effect produces a pattern for effect. It is an effect of variable display, and is an effect of displaying more patterns for effect than in the normal mode (normal effect).

Then, in this fireworks zone, the player plays a game aiming at the establishment of the transition condition of the "AT state" leading to the "ART state". The fireworks zone is, for example, a chance zone limited to 10 games.
In this fireworks zone, when a specific small winning combination is established, it may enter an "AT state" (not shown). For example, 45% of the time when the role of cherry is won, the player enters the "AT state". When the player enters the "AT state", the navigation effect is executed, and when the game is performed according to the navigation effect, the game shifts to the "RT state", and finally the "AT state" and the "RT state". Shifts to the "ART state" in which "" and "" are occurring at the same time.

The content of the "ART state" may be a game property by managing the number of games in which the ART state ends in a predetermined number of games from the start of the ART state, and the ART state is obtained by paying out a predetermined number of medals from the start of the ART state. It may be a game by managing the number of medals that end, and if the number of games in one set is predetermined and a continuous lottery is executed at the start or end of one set and the continuous lottery is won, the game moves to the next set. It may be a game by managing the number of sets of continuous lottery. Further, the content of the final gaming state that rushes from the fireworks zone is not limited to the "ART state", and may be the "AT state" or the "RT state".

Here, the image is displayed at 30 FPS during the execution of the normal effect (normal mode), and the image is displayed at 60 FPS during the execution of the special effect (fireworks zone).

FIG. 436 is a diagram showing an example of a normal effect.
In FIG. 436 (A): The effect is executed in the normal mode, which is an example of the normal effect.
The reels 6, 8 and 10 are not rotated, and the effect symbol displayed in the normal image display area R1 is not rotated (variable display is not performed).

In FIG. 436 (B): Here, it is assumed that the player presses the start lever 18 and does not win any of the winning combinations. In this case, as the reels 6, 8 and 10 rotate, the effect symbol displayed in the normal image display area R1 rotates (variably displayed).

In FIG. 436 (C): Here, it is assumed that the player presses the stop buttons 20, 22, and 24 in order from the left side. In this case, the effect symbol is displayed in the normal image display area R1 in a detached manner (“watermelon symbol”-“bell symbol”-“replay symbol”).

437 and 438 are diagrams showing an example of a special effect.

In FIG. 437 (A): The effect is executed in the state of the fireworks zone, which is an example of the special effect.
The reels 6, 8 and 10 are not rotating, and the effect symbol displayed in the special image display area R2 is not rotating either.

In FIG. 437 (B): Here, it is assumed that the player presses the start lever 18 and does not win any of the winning combinations. In this case, as the reels 6, 8 and 10 rotate, the effect symbol displayed in the special image display area R2 rotates.

In FIG. 437 (C): Here, it is assumed that the player presses the stop buttons 20, 22, and 24 in order from the left side. In this case, the effect symbol is displayed in the special image display area R2 in a detached manner (for example, "bell symbol"-"cherry symbol"-"watermelon symbol" is displayed in the upper position, and in the middle position. "Replay symbol"-"Bell symbol"-"Bell symbol" is displayed, and "Bar symbol"-"Replay symbol"-"Replay symbol" is displayed at the lower position).

In FIG. 437 (D): Here, it is assumed that the player presses the start lever 18, wins the replay combination, and the condition for clearing the chance zone is satisfied (the condition for shifting to the AT state is satisfied). ). In this case, as the reels 6, 8 and 10 rotate, the effect symbol displayed in the special image display area R2 rotates.

In FIG. 438 (E): In this case, the information "Aim for the cherry!" Is displayed in the special image display area R2.

In FIG. 438 (F): Here, as the reels 6, 8 and 10 rotate, the effect symbol displayed in the special image display area R2 continues to rotate. During the execution of the special effect (fireworks zone), the image is displayed at 60 FPS, so the display of the effect symbol is smoother than in the normal game state, and the so-called "pressing" is easy to perform (timing to press the stop button). Is in a state where it is easy to take. The effect symbol displayed in the special image display area R2 can be slid by a predetermined number of frames (for example, up to 4 frames) in the same manner as the reels 6, 8 and 10.

In FIG. 438 (G): Then, it is assumed that the player presses the stop buttons 20, 22, and 24 aiming at the cherry symbol as the effect symbol displayed on the liquid crystal display 42. In the display area of the special image display area R2, a cherry symbol as an effect symbol is displayed at a position corresponding to the lower position of the left reel.

In FIG. 438 (H): Then, the information "superb!" Is displayed in the display area of the special image display area R2. Then, after that, it shifts to the "AT state" and finally enters the "ART state".

Next, an example of a control method for concretely realizing the above effect will be described. The above-mentioned normal effect, special effect, and the like are all controlled through the control process executed by the effect control device 124.

[CPU initialization process (main) process in the effect control device]
FIG. 439 is a flowchart showing a procedure example of the CPU initialization process executed by the effect control device 124. FIG. 439 (A) shows the entire CPU initialization process, and FIG. 439 (B) shows the process executed in the main loop among the CPU initialization processes.

The CPU initialization process is a process for adjusting the initial state of the slot machine 1 by clearing various information in the effect control device 124, and more specifically, when the effect control device 124 is started (more specifically, to the slot machine 1). It is executed by the effect control CPU 126 when the power is turned on, or when the effect control device 124 is restarted for some reason). By executing the CPU initialization process, the realization of a stable effect in the slot machine 1 is guaranteed.

FIG. 439 (A) is a flowchart showing a procedure example of the CPU initialization process executed by the effect control device 124. Hereinafter, the processing executed by the effect control CPU 126 will be described step by step.

Step S300: The effect control CPU 126 releases the reset of the CPU. In order to guarantee the normal operation of the effect control device 124, the effect control CPU 126 resets the CPU after the power is turned on to the effect control device 124 until the output voltage rises normally to the operation guarantee level and the peripheral circuits are stabilized. During that time, the reset state is continued. By doing so, it is possible to prevent the program from operating in a state where the effect control device 124 is not stable. When the reset of the CPU is released, the execution of the control program in the effect control device 124 is started with this as an opportunity.

Step S310: The effect control CPU 126 executes the system initialization process. In the system initialization process, initial settings related to hardware, system operation settings, and the like are performed as initial settings required before various interrupt processes corresponding to the substance of the effect control are started. In the system initialization process, for example, in addition to the settings related to access to each register and I / O port of the effect control CPU 126 and each device connected to the effect control CPU 126, the RAM 130 (main memory) and the command buffer are cleared. Will be.

The area of the RAM 130 that is cleared in the system initialization process is not constant, and varies depending on the situation at the time of starting the effect control device 124. For example, when the power is restored after a temporary power failure occurs during the execution of the game, the checksum normality is checked using the checksum value stored in the SRAM 182 and calculated at the time of the power failure. If it is confirmed and the checksum is normal (backup is successful), the target area of the checksum is not cleared. Since information about the game is stored in the target area of the checksum, the effect is restarted in the same state as when the power is turned off by excluding this area from the clear target of the RAM 130. Further, when the effect control device 124 is restarted (reset start) by detecting the runaway of the control program and activating the watchdog timer, there is a possibility that an incomplete part may occur in the data. , The RAM 130 is cleared including the target area of the checksum. As a result, the effect that was being reproduced before the restart is once cleared, and the effect is constructed from scratch based on the effect command transmitted from the main control device 70 after the restart. Furthermore, if it is confirmed that the checksum is not normal (backup has failed), or if garbled data in the RAM 130 is detected, a serious problem may have occurred. A wider area will be cleared than in any of the above cases.

Step S320: The effect control CPU 126 executes the task execution pre-processing. Here, the "task" refers to an individual process executed due to the occurrence of an interrupt. In the task execution pre-processing, preparations for executing the task are performed. For example, the effect control device 124 is provided with a plurality of LED lamps (hereinafter, referred to as “status LEDs”) that can be visually recognized from the back side of the slot machine 1, and the effect control device 124 uses these LED lamps. The internal state is notified by a plurality of lighting patterns, and the initial state of the status LED is set in the task execution preprocessing. In addition, the frequency of the command input / output port required for receiving the effect command transmitted from the main control device 70 is set, the RTC184 is set up, the interrupt is permitted, and the like. When the task execution pre-processing is completed, the status LED lights up in a manner indicating the completion of the initialization processing, various effect commands can be received, and the state shifts to a state in which various interruptions can occur.

The effect control device 124 has different types such as a timer interrupt that is periodically executed at regular intervals, an event interrupt that occurs due to the occurrence of a predetermined event on the effect control device 124, and the like. Various interruptions can occur. A priority is set in advance for each interrupt, and when an interrupt occurs, the effect control CPU 126 controls the interrupt according to the priority and executes the corresponding interrupt process.

Step S330: The effect control CPU 126 executes the effect control main process. In the effect control main process, among the controls executed as the game progresses, other processes that are not executed in various tasks are performed. The contents of the effect control main process will be further described later.

As shown in FIG. 439 (A), the effect control main process is incorporated in an infinite loop, and when the effect control CPU 126 finishes executing the effect control main process once, a predetermined execution interval is set. The execution of the next effect control main process is restarted from. Therefore, unless the power supply to the slot machine 1 is maintained and the effect control device 124 is restarted, the effect control CPU 126 continues to repeatedly execute the effect control main process. Further, during the execution of the effect control main process, various interrupts are generated triggered by various factors, and the effect control CPU 126 executes the process according to each interrupt generated. In these processes, image display control on the liquid crystal display 42, audio output control on the speaker 54, drive control of various lamps 38 and 40, etc. were performed and directly or indirectly connected to the effect control device 124. By controlling each device, the effect content is constructed and the effect is embodied.

As described above, the infinite loop in FIG. 439 (A) corresponds to the main loop in the effect control device 124, and the effect control main process is literally positioned as the main process executed in the effect control device 124.

FIG. 439 (B) is a flowchart showing a procedure example of the effect control main process executed by the effect control device 124. Hereinafter, the processing executed by the effect control CPU 126 will be described step by step.

Step S340: The effect control CPU 126 executes the voltage control monitoring process. In the voltage control monitoring process, the effect control CPU 126 performs a monitoring process for canceling the interruption of the 5V signal supplied to the external driver in a fixed time. If a voltage is applied to the lamp or the movable body at the same time, the lamp or the movable body may generate excessive heat due to the inrush current, leading to malfunction or failure. Therefore, the timing of applying the voltage (timing of releasing the signal) is shifted to disperse the inrush current, and the lamp, the movable body, and the like are protected from heat generation.

Step S350: The effect control CPU 126 executes the watch dock clear process. In addition to being equipped with a watchdog timer IC188 connected to the effect control CPU 126 and a watchdog timer using the built-in function of the effect control CPU 126, the effect control device 124 is equipped with a watchdog timer by a control program. There is. That is, in the effect control device 124, a total of three watchdog timers, including two watchdog timers on the hardware and one watchdog timer on the software, are operating, and each watchdog timer has a different monitoring time. , Whether or not the timer interrupt has occurred normally (whether the timer interrupt process executed by the timer interrupt is executed normally) is monitored.

After completing the above procedure, the effect control CPU 126 returns to the main loop of the CPU initialization process ((A) in FIG. 439) and executes the effect control main process again. The effect control main process is executed at substantially constant intervals when the effect control device 124 is in a normal state. For example, in the normal state, the effect control main process is called every 33.3 ms (while returning from the timer interrupt process that is separately executed), and the process of each step goes through in the meantime. Therefore, when each of the steps S340 and S350 of the effect control main process completes without delay, the effect control CPU 126 performs the standby process in the remaining time until the next effect control main process is called, and waits for the start process during that time. Transition to the (sleep) state. With the exhaustion of the remaining time, the effect control CPU 126 ends the standby process, returns to the main loop, and calls the next effect control main process.

[Timer interrupt processing in the effect control device]
FIG. 440 is a flowchart showing a procedure example of various timer interrupt processes (VSYNC interrupt process, frame interrupt process, phase interrupt process) that are periodically executed at regular intervals in the effect control device 124. The effect control unit 210 generates various timer interrupts in a predetermined interrupt cycle (for example, 512 μs to 33.3 ms cycle) during execution of the main loop in FIG. 439 (A), and timer interrupts corresponding to the interrupts. The interrupt process is executed at regular intervals.
Hereinafter, the processing executed by the effect control CPU 126 will be described step by step.

FIG. 440 (A) is a flowchart showing a procedure example of the VSYNC interrupt process. The VSYNC interrupt is an interrupt of an image signal generated at the timing of switching the effect image displayed on the liquid crystal display 42, and is generated once at 16.6 ms intervals (60 times per second). The effect control CPU 126 executes the VSYNC interrupt process when the VSYNC interrupt occurs.
The VSYNC interrupt is an interrupt notified from the VDP of the effect control device 124 to the effect control CPU 126.

Step S1300: The effect control CPU 126 sets the VSYNC interrupt monitoring flag (sets the flag value to "1"). The VSYNC interrupt monitoring flag is a flag used for confirming whether or not the VCYNC interrupt is normally generated, and is stored in the RAM 130.
Step S1302: The effect control CPU 126 executes the VSYNC interrupt control process. In the VSYNC interrupt control process, various tasks executed due to the VSYNC interrupt are controlled.

Step S1304: The effect control CPU 126 executes a process of waking up the upper control unit (a process of calling the upper control unit management process). By executing this process, the operation of the upper control unit starts (the program of the upper control unit management process starts to be executed). Since the VSYNC interrupt occurs every 16.6 ms, the upper control unit wakes up every 16.6 ms. The details of the management process of the upper control unit will be described later.
When the above procedure is completed, the effect control CPU 126 returns to the main loop ((A) in FIG. 439).

In FIG. 440 (B): It is a flowchart which shows the procedure example of a frame interrupt process. The frame interrupt is an interrupt that occurs twice as often as the above-mentioned VSYNC interrupt, that is, once at 16.6 ms intervals (60 times per minute). The effect control CPU 126 executes the frame interrupt process when the frame interrupt occurs.

Step S1310: The effect control CPU 126 sets the frame interrupt monitoring flag (sets the flag value to “1”). The frame interrupt monitoring flag is a flag used to confirm whether or not frame interrupt has occurred normally, and is stored in the RAM 130.
Step S1312: The effect control CPU 126 executes the frame interrupt control process. In the frame interrupt control process, various tasks executed due to the frame interrupt process are controlled.
When the above procedure is completed, the effect control CPU 126 returns to the main loop ((A) in FIG. 439).

FIG. 440 (C): is a flowchart showing a procedure example of the phase interrupt process. The phase interrupt process is an interrupt for controlling the internal device of the effect control device 124, and is generated once at 512 μs intervals (1920 times per minute). The effect control CPU 126 executes the phase interrupt process when the phase interrupt occurs.

Step S1320: The effect control CPU 126 sets the phase interrupt monitoring flag (sets the flag value to “1”). The phase interrupt monitoring flag is a flag used to confirm whether or not the phase interrupt has occurred normally, and is stored in the RAM 130.
Step S1322: The effect control CPU 126 executes the phase interrupt control process. In the phase interrupt control process, various tasks executed due to the phase interrupt are controlled.
When the above procedure is completed, the effect control CPU 126 returns to the main loop ((A) in FIG. 439).

In this way, in any timer interrupt process, the interrupt monitoring flag for each timer interrupt is first set, and then various tasks executed due to the interrupt are controlled.

[Production control processing]
As described above, the effect control device 124 has a function as an effect control processor and a function as an effect display processor, and realizes these two functions by allocating different resources of the effect control CPU 126 to each of them. .. The effect control CPU 126 as the effect control processor receives the effect command transmitted from the main control device 70, and transmits an effect reproduction command instructing the reproduction of the effect according to the contents. Further, the effect control CPU 126 as the effect reproduction processor operates each device (by the liquid crystal display 42) by giving more specific instructions to each device based on the content of the effect reproduction command transmitted from the effect control processor. The screen display, the sound output by the speaker 54, the light emission by the various lamps 38 and 40, etc.) are controlled to realize the effect reproduction on the slot machine 1.

Therefore, for convenience of explanation, in the following description, the operation subject when the effect control CPU 126 functions as the effect control processor is expressed as "effect control unit 210", and the effect control CPU 126 functions as the effect display processor. The operating subject of the case is appropriately expressed as "display control unit 220", "voice control unit 222", "lamp control unit 224", or "motor control unit 226" depending on the content.

FIG. 441 is a flowchart showing a procedure example of the effect control process. This effect control process is executed, for example, as a part of the VSYNC interrupt control process (step S1302) in FIG. 440 (A).

The effect control process includes command reception process (step S400), display effect management process (step S402), lamp effect management process (step S404), sound effect management process (step S406), effect random number update process (step S408), and others. It is a configuration including a group of subroutines of the effect management process (step S410). Hereinafter, the basic flow of the effect control process will be described along with each process.

Step S400: In the command reception process, the effect control unit 210 receives the effect command transmitted from the main control CPU 72. Further, the effect control unit 210 analyzes the received effect commands and stores them in the command buffer area of the RAM 130 for each type. The effect commands transmitted from the main control CPU 72 include, for example, input processing command, start operation command, winning number command, rotation cylinder rotation command, operation rotation cylinder command, pressing position command, stop position command, and rotation cylinder stop post-command. , Internal state commands, etc.

Step S402: In the display effect management process, the effect control unit 210 (effect execution means) controls the content of the image to be displayed on the liquid crystal display 42 based on the effect command transmitted from the main control CPU 72. Specifically, the effect control unit 210 transmits an effect reproduction command (for example, an effect pattern number, a background pattern number, etc.) instructing the display control unit 220 of the effect content. In response to this, the display control unit 220 gives a specific drawing instruction to the VDP 152 based on the content of the received effect reproduction command, and controls the display operation by the liquid crystal display 42.

For example, when an internal state command indicating "in normal mode" is received, the effect control unit 210 executes a process of selecting a display effect corresponding to the normal mode (for example, the effect shown in FIG. 435 (A)). ..
Further, when the internal state command indicating "in the chance zone" is received, the effect control unit 210 executes a process of selecting a display effect corresponding to the fireworks zone (for example, the effect shown in FIG. 435 (B)). ..
Further, when the internal state command indicating "in ART state" is received, the effect control unit 210 executes a process of selecting a display effect corresponding to the ART state.

Further, when the internal state command indicating "normal mode shift" is received, the effect control unit 210 executes a process of selecting a display effect to shift from the "fireworks zone" to the "normal mode".
Further, when the internal state command indicating "chance zone shift" is received, the effect control unit 210 executes a process of selecting a display effect to shift from the "normal mode" to the "fireworks zone".
Then, when the internal state command indicating "AT state transition" is received, the effect control unit 210 shifts from the "fireworks zone" to the "AT state" (for example, in FIG. 437 (D), FIG. 438, etc.). The process of selecting the effect shown in) is executed.
When the internal state command indicating "ART state transition" is received, the effect control unit 210 performs a process of selecting a display effect (for example, an ART state entry effect) for shifting from the "AT state" to the "ART state". Execute.

By executing such a process, the effect control unit 210 (effect execution means) is in the normal mode using the liquid crystal display 42 when the effect execution condition (special effect execution condition) of the fireworks zone is not satisfied. (Normal effect) is executed, and when the effect execution condition (special effect execution condition) of the fireworks zone is satisfied, the liquid crystal display 42 is used to produce an effect in the fireworks zone that is different from the effect in the normal mode. (Special effect) can be executed.

Step S404: In the lamp effect management process, the effect control unit 210 first transmits an effect reproduction command instructing the lamp control unit 224 to indicate the effect content. In response to this, the lamp control unit 224 relays the LED driver 198 based on the content of the received effect reproduction command, outputs a specific drive signal to the driver IC 132, and drives (lights up) various lamps 38, 40, etc. Or turn off, blink, change brightness gradation, etc.).

Step S406: In the sound effect management process, the effect control unit 210 first transmits an effect reproduction command instructing the voice control unit 222 to indicate the effect content. In response to this, the voice control unit 222 instructs the voice IC 134 of the specific output content based on the content of the received effect reproduction command, and the speaker 54 gives a sound (sound effect, BGM, etc.) according to the effect content. Is output.

Step S408: In the effect random number update process, the effect control unit 210 updates various effect random numbers in the counter area of the RAM 130. The production random numbers include, for example, random numbers used for production selection and advance notice selection, random numbers used for a normal background change lottery (effect lottery), and the like.

Step S412: In other processes, for example, the effect control unit 210 first transmits an effect reproduction command instructing the motor control unit 226 to indicate the content of the effect. In response to this, the motor control unit 226 gives an instruction of specific control contents to the SMC 199 based on the contents of the received effect reproduction command. Further, the SMC 199 creates an operation pattern of the movable body for production based on the instruction from the motor control unit 226, outputs a control signal corresponding to the operation pattern to the driver IC, and drives the movable body for production. The movable body for the effect operates by using the movable body motor 57 as a drive source, and produces the effect in synchronization with the display of the image by the liquid crystal display 42 or independently.

Through the above-mentioned effect control process, the effect control unit 210 can comprehensively control the effect content in the slot machine 1.

[Upper control unit management process]
FIG. 442 is a flowchart showing a procedure example of the upper control unit management process. Hereinafter, each procedure will be described.

Here, the upper control unit and the lower control unit will be described.
The higher-level control unit is a part in charge of higher-level processing in the effect control CPU 126 (effect control unit 210), and is activated when a predetermined interrupt (VSYNC interrupt) is triggered.
On the other hand, the lower control unit is a part in charge of lower processing in the effect control CPU 126 (effect control unit 210), and is activated by the upper control unit.

The details of the upper control unit and the lower control unit are as follows.
The upper control unit executes a process of setting the VDP 152 for displaying the effect image / moving image on the liquid crystal display.
The lower control unit determines what kind of effect image / moving image is to be displayed on the liquid crystal display, and executes a process of setting information (drawing command / moving image information) related to the determined effect image / moving image.

Step S910: The upper control unit of the effect control CPU 126 confirms whether or not the liquid crystal display update cycle is reached. In this process, the determination content is different when the process of switching the frame rate (FPS) is adopted. For example, if the frame rate value set in the frame rate switching process (FPS switching process) is 30 FPS, it is determined as affirmative (Yes) at 16.6 ms × 2 (33.3 ms), and the frame rate value is 60 FPS. If there is, it is determined to be affirmative (Yes) at 16.6 ms × 1. When the process of not switching the frame rate (FPS) is adopted, if the initial value of the frame rate is, for example, 30 FPS, 16.6 ms × 2 (33.3 ms) is determined as affirmative (Yes). ..

As a result, when it is confirmed that the liquid crystal display update cycle is reached (Yes), the upper control unit of the effect control CPU 126 executes step S912. On the other hand, when it cannot be confirmed that the liquid crystal display update cycle is reached (No), the upper control unit of the effect control CPU 126 returns to the VSYNC interrupt process ((A) in FIG. 440).

Step S912: The upper control unit of the effect control CPU 126 confirms whether or not the command construction is completed. Specifically, in this process, it is determined whether or not the command is stored in the command buffer for transmitting (notifying) to the lower control unit among the command buffers. When changing the frame rate, if the selected frame rate is 60 FPS, the command is constructed in 16.6 ms, so the command constructed in the previous 16.6 ms is referred to. On the other hand, when the selected frame rate is 30 FPS, since the command is constructed in 33.3 ms, the command constructed in 16.6 ms two times before is referred to.

As a result, when it is confirmed that the command construction is completed (Yes), the upper control unit of the effect control CPU 126 executes step S914. On the other hand, when it cannot be confirmed that the command construction is completed (No), the upper control unit of the effect control CPU 126 returns to the VSYNC interrupt process ((A) in FIG. 440).

Step S914: The upper control unit of the effect control CPU 126 confirms whether or not the drawing is completed. Specifically, the upper control unit of the effect control CPU 126 confirms whether or not drawing by VDP is completed (whether or not drawing is in progress).

As a result, when it is confirmed that the drawing is completed, that is, when it is confirmed that the drawing is not in progress (Yes), the upper control unit of the effect control CPU 126 executes step S916. On the other hand, when it cannot be confirmed that the drawing is completed, that is, when it is confirmed that the drawing is in progress (No), the upper control unit of the effect control CPU 126 returns to the VSYNC interrupt process ((A) in FIG. 440). To do.

Step S916: The upper control unit of the effect control CPU 126 executes the display switching process. The specific contents of the display switching process are as follows.

The VDP includes a register that determines the area starting from the address of the VRAM to be output to the liquid crystal display 42 (liquid crystal panel), and the display switching process here is a process of rewriting the register.

The frame buffer for storing an image to be displayed on the liquid crystal display 42 reserves two areas in VRAM for "drawing" and "display", and an image for which drawing has not been completed is displayed. It prevents it from being stolen.

Then, the display switching process is specifically a process of switching between the above-mentioned "for drawing" and "for display".
For example, if the area starting from "0" of VRAM is used as the frame buffer of "No. 1" and the area starting from "100" is reserved in VRAM as the frame buffer of "No. 2", first, "No. 1" is reserved. "Address 0" is set in the register for display, and drawing is performed at "Address 100" of "2". Then, when the drawing of "No. 2" is completed, "Address 100" of "No. 2" is set in the register for display, and drawing is performed at "Address 0" of "No. 1".

Step S922: The upper control unit of the effect control CPU 126 executes a process of transferring the drawing command to the VDP. The drawing command to be transferred is a drawing command generated in the drawing command construction process (step S932) of the lower control unit management process (FIG. 443).

Step S924: The upper control unit of the effect control CPU 126 executes a process of transmitting a drawing start instruction. According to this instruction, the VDP starts drawing, and the liquid crystal display 42 reproduces the moving image.

Step S926: The upper control unit of the effect control CPU 126 executes a process of waking up the lower control unit (a process of calling the lower control unit management process). By executing this process, the operation of the lower control unit starts (the program of the lower control unit management process starts to be executed). The details of the lower control unit management process will be described later.
When the above procedure is completed, the upper control unit of the effect control CPU 126 transitions to the standby (sleep) state and returns to the VSYNC interrupt process ((A) in FIG. 440).

[Lower control unit management process]
FIG. 443 is a flowchart showing a procedure example of the lower control unit management process. Hereinafter, each procedure will be described.

Step S930: The lower control unit of the effect control CPU 126 executes a process of determining the effect content to be displayed on the liquid crystal display 42. Since the effect content has already been determined by the effect control process (FIG. 441), the lower control unit of the effect control CPU 126 displays the liquid crystal display 42 on the liquid crystal display 42 based on the content determined by the effect control process (FIG. 441). Determine the content of the effect to be displayed.

Here, when the lower control unit of the effect control CPU 126 determines the content to be shifted from the normal mode to the fireworks zone as the effect content, or when the content to shift from the fireworks zone to the normal mode or the AT state is determined, It is decided to issue an FPS switching request.

Step S932: The lower control unit of the effect control CPU 126 executes a process of constructing a drawing command. As the drawing command, the drawing command corresponding to the effect content determined in step S930 is stored in advance in the control ROM 180 or the like, and the lower control unit of the effect control CPU 126 reads the corresponding drawing command from the control ROM 180 and draws. Build a command.

Step S934: The lower control unit of the effect control CPU 126 confirms whether or not there is an FPS switching request. Specifically, in the production decision in step S930, it is confirmed whether or not it is decided to issue the FPS switching request.

As a result, when it is confirmed that there is an FPS switching request (Yes), the lower control unit of the effect control CPU 126 executes step S936. On the other hand, when it cannot be confirmed that there is an FPS switching request (No), the lower control unit of the effect control CPU 126 transitions to the standby (sleep) state.

Step S936: The lower control unit of the effect control CPU 126 executes a process of issuing an FPS switching request to the upper control unit. For example, the lower control unit of the effect control CPU 126 executes a process of turning on the FPS switching request flag of the RAM 130.

When the above procedure is completed, the lower control unit of the effect control CPU 126 transitions to the standby (sleep) state.

[Drawing completion interrupt processing]
FIG. 444 is a flowchart showing a procedure example of the drawing completion interrupt process. The drawing completion interrupt process is an interrupt process executed when the drawing process by VDP is completed, and is executed by the upper control unit of the effect control CPU 126. Hereinafter, each procedure will be described.

Step S940: The upper control unit of the effect control CPU 126 confirms whether or not there is an FPS switching request. For example, the upper control unit of the effect control CPU 126 can determine that there is an FPS switching request when the FPS switching request flag of the RAM 130 is ON.

As a result, when it is confirmed that there is an FPS switching request (Yes), the upper control unit of the effect control CPU 126 executes step S942. On the other hand, when it cannot be confirmed that there is an FPS switching request (No), the upper control unit of the effect control CPU 126 returns to the caller.

Step S942: The upper control unit of the effect control CPU 126 executes the FPS switching process. Specifically, the upper control unit of the effect control CPU 126 sets the frame rate to 60 FPS when the current frame rate is 30 FPS, and sets the frame rate to 30 FPS when the current frame rate is 60 FPS. Execute the process to be set. In this process, the upper control unit of the effect control CPU 126 executes a process of turning off the FPS switching request flag of the RAM 130.

When the above procedure is completed, the upper control unit of the effect control CPU 126 returns to the caller.

By executing such a process, the effect control CPU 126 (upper control unit, update rate setting process execution means) sets 30 FPS (low update rate) during execution of the normal effect (during the normal mode, etc.). During the execution of the special effect (during the fireworks zone), the update rate setting process for setting 60 FPS (high update rate) can be executed. Then, by executing the update rate setting process, the effect image is displayed at 60 FPS in the fireworks zone, and the effect image is displayed at 30 FPS outside the fireworks zone.

Further, when the effect control CPU 126 (upper control unit, update rate setting processing execution means) switches the update rate from 30 FPS to 60 FPS or from 60 FPS to 30 FPS, the drawing process of the image to be displayed on the liquid crystal display 42 is completed. After that (after the drawing process for one frame is completed), the update rate is switched.

Further, by executing such a process, the effect control CPU 126 (lower control unit) determines what kind of image is to be displayed on the liquid crystal display 42, and draw commands based on the determined contents. The process of generating (drawing information) (drawing command construction process) is executed, the effect control CPU 126 (upper control unit) executes the update rate setting process, and the drawing command generated by the lower control unit is executed. The transfer process of transferring to the VDP (device that controls the liquid crystal display 42) is executed.

[Medalless pachinko machine]
The above-mentioned slot machine 1 is a medal-using gaming machine that uses game medals, but it is also possible to transform the above-mentioned slot machine 1 into a medalless gaming machine (a gaming machine that does not use game medals) described below. .. Hereinafter, the contents of the medalless gaming machine will be described with reference to Chapters S1 to S6.

In Chapters S1 to S6 described below, the contents described in each chapter can be used alone, or the contents described in each chapter can be used in combination. In addition, the contents of the medalless gaming machine described in each chapter can be used in combination with the contents of the medal-using gaming machine. In each of the following chapters, even parts having the same function may be described with different reference numerals for each chapter. Further, regardless of whether or not the machine has the same function as the above-mentioned medal-using gaming machine, the description may be given with the same reference numerals as the above-mentioned medal-using gaming machine. If the content of one chapter is different from the content of the other chapter, the content of one of the chapters can be adopted, and if the content of each chapter lacks the content of the explanation, the content of another chapter , The contents of the above-mentioned medal-using game machine, and the contents of the above-mentioned pachinko machine (normal game machine, managed game machine) can be supplemented.
Hereinafter, Chapters S1 to S6 will be described in order.

[Chapter S1 Medalless Pachinko Machine-Dedicated Unit Connection Specifications]
[1. Glossary〕
The terms used in this chapter are explained below.

[No1]
The gaming machine information center is a center that collects ball ejection information and the like output from the gaming machine.

[No2]
A medalless gaming machine is a gaming machine equipped with a gaming medal number display device (game ball number display device) and having a function of being able to output various information of the gaming machine to the gaming machine information center (hereinafter, simply referred to as a gaming machine). In some cases). The medalless gaming machine is a gaming machine that does not use a gaming medal, and can execute a game based on information transmitted from a dedicated unit. Therefore, the player does not need to insert the game medal. Further, in the medalless gaming machine, since the concept of credit is lost, a "credit display unit" is not provided.

[No3]
The main control CPU is a CPU mounted on the main board (main control board) of a gaming machine related to rom and read / write memory (hereinafter, may be simply referred to as main control).

[No4]
The medal number control CPU is a CPU mounted on a main board or a medal number control board of a gaming machine related to rom and read / write memory (hereinafter, may be simply referred to as medal number control).

[No5]
The dedicated unit is a unit (external unit) dedicated to the gaming machine.

[No6]
The dedicated interface is an interface for defining communication specifications between the gaming machine and the dedicated unit. At least a part of a dedicated interface, a dedicated cable, and devices, boards (main control board, medal number control board), circuits, CPUs, software, programs, etc. associated therewith are communication control means.

[No7]
A hall computer is a computer that collects hall control and fraud monitoring information (hereinafter, may be referred to as HC).

[No8]
The card company data center is a card unit group or a card company center connected to the gaming machine information center (hereinafter, may be referred to as a company center).

[No9]
The management computer is a computer that connects to a dedicated unit.

[No10]
The main control chip ID number is the ID number of the main control of the gaming machine. The name of the ID number of the main control differs depending on the manufacturer. For example, if it is made by the first manufacturer, it may be called an individual chip number, and if it is made by a second manufacturer, it may be called a chip code.

[No11]
The medal number control chip ID number is an ID number for controlling the number of medals of the gaming machine. The ID number for controlling the number of medals has a different name depending on the manufacturer. For example, if it is made by the first manufacturer, it may be called an individual chip number, and if it is made by a second manufacturer, it may be called a chip code.

[No12]
The number of game medals is the number of medals that can be inserted into the game machine (the number of medals recorded on the game medal number display device).

[No13]
The number of counting medals is the number of counting medals transmitted by the gaming machine to, for example, a dedicated unit.

[No14]
The number of rented medals is the number of rented medals transmitted by the dedicated unit to, for example, a gaming machine.

[No15]
The number of medals held is the number of counting medals received by the dedicated unit from, for example, a gaming machine, and the number of medals managed by the card company.

[No16]
The gaming machine information is a general term for gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information.

[No17]
The gaming machine installation information is information such as a maker code, a product code, and a chip ID number for main control and medal number control, and is information transmitted to the gaming machine information center.

[No18]
The game machine performance information is MY (maximum difference number), bonus ratio (ratio of the total number of paid out game machine medals to be paid out by the bonus), and continuous bonus ratio (out of the paid out game medals). It is information such as the rate of payout by continuous bonuses), and is information transmitted to the gaming machine information center.

[No19]
The hall control / fraud monitoring information is information such as game results such as IN, OUT, and jackpot information, and various errors.

[2. Scope of application〕
The configuration shown below is applicable to the soft / hard interface between the medalless gaming machine and the dedicated unit shown in the system configuration diagram below (see C in FIG. 445).

[3. System Configuration〕
FIG. 445 is a diagram showing a system configuration diagram of the medalless gaming machine.
The gaming machine 9800 (medalless gaming machine) has a function of transmitting "hole control / fraud monitoring information" to the dedicated unit 9802 according to the specifications described in this chapter, and the dedicated unit 9802 has a function of outputting the information to the HC9804. ..

[4. Hardware overview]
The hardware of the dedicated interface is composed of dedicated interface circuits 9801 and 9803 between the gaming machine 9800 and the dedicated unit 9802.

[4.1. Outline of dedicated interface circuit between gaming machine and dedicated unit]
The dedicated interface circuits 9801 and 9803 use an asynchronous serial port and perform communication by an isolation method using a photocoupler.
The dedicated interface circuits 9801 and 9803 transmit the hall control / fraud monitoring information and the counting notification from the gaming machine 9800 to the dedicated unit 9802 by the telegram method, and receive the rental notification from the dedicated unit 9802 to the gaming machine 9800. Do.

[4.2. Dedicated unit overview]
The dedicated unit 9802 has a communication function with the gaming machine information center 9807.
The dedicated unit 9802 notifies the gaming machine information center 9807 of various information related to the gaming machine.

[5. Dedicated interface hardware specifications]
[5.1. Dedicated interface I / O connector]
FIG. 446 is a diagram showing connector pin assignment of the dedicated interface input / output connector.
[Pin number 1]
Signal name: LG
Direction: Dedicated unit → Pachinko machine Signal content: Insulated GND

[Pin number 2]
Signal name: LG
Direction: Dedicated unit → Gaming machine Signal content: Connect to LG on the dedicated unit side and use it as the GND of the transmission signal.

[Pin number 3]
Signal name: LG
Direction: Dedicated unit → Pachinko machine Signal content: Connect to LG on the dedicated unit side and use it as the GND of the received signal.

[Pin number 4]
Signal name: PSI
Direction: Gaming machine → Dedicated unit Signal content: Connection confirmation signal (Signal to confirm that the dedicated unit is connected to the medalless gaming machine)

[Pin number 5]
Signal name: LG
Direction: Dedicated unit → Pachinko machine Signal content: Insulated GND

[Pin number 6]
Signal name: Transmission signal Direction: Game machine → Dedicated unit Signal content: Signal transmitted by the game machine to the dedicated unit

[Pin number 7]
Signal name: Received signal Direction: Dedicated unit → Gaming machine Signal content: Signal received by the gaming machine from the dedicated unit

[Pin numbers 8 and 9]
Signal name: VL
Direction: Dedicated unit → Pachinko machine Signal content: Insulation 5V

[Pin number-]
Signal name: FG_U
Direction:-(* 1)
Signal content: Dedicated unit side frame GND
(* 1) It is preferable not to connect to the FG in the medalless game machine.

FIG. 447 is a diagram showing a connection example of the dedicated cable.
The gaming machine 9800 and the dedicated unit 9802 are connected by a dedicated cable 9810. The length of the dedicated cable 9810 is preferably 1.5 m to 2.0 m.
The dedicated cable 9810 has DSUB 9-pin (pin type) connectors 9811 at both ends.

On the game machine 9800 side, a DSUB 9-pin (socket type, with spring unit) connector 9813 is installed on the game ball rental device connection terminal plate 9812 of the game machine 9800, and a DSUB 9-pin (pin type) of the dedicated cable 9810 is installed. ) Is connected to the connector 9811.
A predetermined connector (not shown) is installed on the dedicated unit 9802 side, and is connected to the DSUB 9-pin (pin type) connector 9811 of the dedicated cable 9810.

FIG. 448 is a diagram showing a connector diagram of the dedicated cable.
The type of connector 9811 of the dedicated cable 9810 is DSUB 9 pin (pin type, with lock plate).
The maximum lateral length X1 of the connector 9811 is, for example, 39.99 mm.
The length X2 of the lateral pin arrangement region of the connector 9811 is, for example, 16.89 mm.
The maximum length Y1 of the connector 9811 in the vertical direction is, for example, 14.15 mm.
The length Y2 of the connector 9811 excluding the protruding portions at the upper and lower ends in the vertical direction is, for example, 12.4 mm.
The length Y3 of the vertical pin arrangement region of the connector 9811 is, for example, 8.35 mm.

[5.2. Dedicated cable〕
In the dedicated cable 9810, it is preferable to twist the 6th pin and the 2nd pin, and the 7th pin and the 3rd pin.
The cable used for the dedicated cable 9810 is preferably shielded and connected to the metal parts of the DSUB connectors on both sides.

[5.3. Dedicated interface signal specifications]
[5.3.1. Input / output method]
The input / output method is an insulation method using a photocoupler.

[5.3.2.2. Interface signal shared power supply (VL)]
The interface signal shared power supply uses VL (insulated 5V) supplied from the dedicated unit. The power supply is an isolated DC5V. The maximum current consumption is 150 mA.

[5.3.3.3. Interface signal logic]
FIG. 449 is a diagram showing the logic of the transmission signal and the reception signal on the connector of the dedicated cable.
When the start bit is first transmitted (or received), the signal changes from H level to L level, then 8 signals for 1 byte are transmitted, and finally when the stop bit is transmitted, the signal becomes L level. Becomes H level.

[5.4. Input / output circuit]
FIG. 450 is a diagram showing an example of an input / output circuit of a dedicated unit and a gaming machine.
The dedicated unit 9802 includes a unit board 9820 having a unit control unit 9821.
The gaming machine 9800 includes a gaming ball rental device connection terminal plate 9812.
The unit board 9820 and the game ball rental device connection terminal board 9812 are connected by an FG and a 9-pin dedicated cable 9810.

[Pin numbers 8 and 9 on the dedicated unit 9802 side]
Pin numbers 8 and 9 on the dedicated unit 9802 side are connected to ICa (+ VOUT) via VL and VL (insulation 5V).
[Pin numbers 1 and 5 on the dedicated unit 9802 side]
Pin numbers 1 and 5 on the dedicated unit 9802 side are connected to ICa (-VOUT) via LG and LG (insulated GND).
Cb is arranged between VL (insulation 5V) and LG (insulation GND).

ICa (+ VIN) is connected to the unit 5V.
The ICa (-VIN) is connected to the unit GND.
Ca is arranged between the unit 5V and the unit GND.
The ICa (ON / OFF) is connected to the unit control unit 9821.

[Pin numbers 8 and 9 on the gaming machine 9800 side]
Pin numbers 8 and 9 on the gaming machine 9800 side are connected to the VL.
[Pin numbers 1 and 5 on the gaming machine 9800 side]
Pin numbers 1 and 5 on the gaming machine 9800 side are connected to LG.
C1 and Z1 are arranged between VL and LG.

[Pin number 4 on the dedicated unit 9802 side]
The pin number 4 on the dedicated unit 9802 side is connected to the ICb via VL, Ra, LG, and Rc.
Da and Db are arranged between VL and LG.
Rb and Dc are arranged between Ra and Rc.

The ICb is connected to the unit control unit 9821 via the unit 5V having Rd.
The ICb is connected to the unit GND.

[Pin number 4 on the gaming machine 9800 side]
Pin number 4 on the gaming machine 9800 side is connected to LG.

[Pin number 6 on the dedicated unit 9802 side]
The pin number 6 on the dedicated unit 9802 side is connected to the ICc via VL, Re, LG, and Rg.
Dd and De are arranged between VL and LG.
Rf and Df are arranged between Re and Rg.

The ICc is connected to the unit 5V, the unit control unit 9821, and the unit GND.
Cc is arranged between the unit 5V and the unit GND.

[Pin number 6 on the gaming machine 9800 side]
The pin number 6 on the gaming machine 9800 side is connected to the IC2 via R2, LG, VL, and VL.
D1, D2, and R3 are arranged between VL (left side in the figure) and LG.

[Pin number 2 on the dedicated unit 9802 side]
Pin number 2 on the dedicated unit 9802 side is connected to LG.
[Pin number 2 on the gaming machine 9800 side]
The pin number 2 on the gaming machine 9800 side is connected to the IC2.
C2 is arranged between the VL (on the right side in the figure) and the pin number 2 on the gaming machine 9800 side.
The IC2 is connected to the gaming machine 5V and the transmission signal.

[Pin number 7 on the dedicated unit 9802 side]
The pin number 7 on the dedicated unit 9802 side is connected to the ICd via Rh, VL, and LG.
Dg and Dh are arranged between VL and LG.
Ri, Di, and Cd are arranged between the VL and the ICd.

The ICd is connected to the unit 5V and the unit control unit 9821.
Dj and Rj are arranged between the unit 5V and the unit control unit 9821.

[Pin number 7 on the gaming machine 9800 side]
The pin number 7 on the gaming machine 9800 side is connected to the IC3 via LG, VL, R5, and R4.
D3 and D4 are arranged between VL and LG.
The IC3 is connected to the gaming machine 5V, the received signal, and the gaming machine GND.

[Pin number 3 on the dedicated unit 9802 side]
Pin number 3 on the dedicated unit 9802 side is connected to LG.
[Pin number 3 on the gaming machine 9800 side]
The pin number 3 on the gaming machine 9800 side is connected to the IC3 via R6.
R5 is arranged between the VL and the pin number 3 on the gaming machine 9800 side.

IC1 is connected to VL and LG having R1. Further, the IC1 is connected to the VL connection and the gaming machine GND.
The IC2 is connected to the gaming machine 5V, and a transmission signal (a signal transmitted from the gaming machine to the dedicated unit) is input.
The IC3 is connected to the gaming machine 5V and the gaming machine GND, and a reception signal (a signal received by the gaming machine from the dedicated unit) is input.

[5.5. Interface circuit resistance constant]
[5.5.1. Game machine side interface circuit resistance constant]
FIG. 451 is a diagram showing a circuit resistance constant and the like of the gaming machine side interface.
Part number: IC1
Constant or part name: Specified part 1 (for example, photocoupler)

Part number: IC2, IC3
Constant or part name: Specified part 2 (for example, photocoupler)

Part number: R1
Constant or part name: 330Ω

Part number: R2
Constant or part name: 100Ω

Part number: R3, R5
Constant or part name: 1kΩ

Part number: R4, R6
Constant or part name: 330Ω

Part number: C1
Constant or part name: 1 μF

Part number: C2
Constant or part name: 0.1 μF

Part number: D1, D2, D3, D4
Constant or part name: Specified part 3 (for example, diode)

Part number: Z1
Constant or part name: Specified part 4 (for example, surge absorber)

[5.5.1. Dedicated unit side interface circuit resistance constant]
FIG. 452 is a diagram showing a circuit resistance constant and the like of the dedicated unit side interface.
Part number: ICa
Constant or part name: Specified part 5 (for example, circuit or converter) (* 1)

Part number: ICb
Constant or part name: Specified part 6 (for example, photocoupler) (* 2)

Part number: ICc, ICd
Constant or part name: Specified part 7 (for example, photocoupler) (* 2)

Part number: Ra, Rc
Constant or part name: 300Ω

Part number: Rb
Constant or part name: 10kΩ

Part number: Rd
Constant or part name: 1kΩ

Part number: Re, Rg
Constant or part name: 270Ω

Part number: Rf, Ri
Constant or part name: 820Ω

Part number: Rh
Constant or part name: 100Ω

Part number: Rj
Constant or part name: 150Ω

Part number: Ca
Constant or part name: 10-100 μF

Part number: Cb
Constant or part name: 1-100 μF

Part number: Cc, Cd
Constant or part name: 0.1 μF

Part number: Da ~ Dj
Constant or part name: Specified part 8 (for example, diode) (* 3)

(* 1) [5.3.2.2. It is preferable that the regulator circuit or DC-DC converter satisfies the specifications of the interface signal shared power supply (VL)] and can be turned ON / OFF. Further, when the regulator circuit or the DC-DC converter is turned off, it is preferable to arrange so that the interface signal shared power supply of ICb, ICc, and ICd is also turned off.
(* 2) The parts used can be any parts.
(* 3) It is preferable that the parts are capable of taking measures against static electricity and other measures (noise measures, etc.). If the parts used are discontinued, equivalent products can be selected as appropriate.

[6. Software Overview]
(1) The software interface of the dedicated interface communicates information for lending game medals, information for counting game medals, and game machine information by a telegram method using an asynchronous serial port.
(2) Information on renting game medals is transmitted and received between the dedicated unit and the game machine by telegram in units of the number of game medals.
(3) The information for counting the game medals is transmitted by the game machine in a telegram in units of the number of game medals.
(4) There are three types of gaming machine information: gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information, and the gaming machine notifies one of them by telegram according to the notification conditions.

[7. Communication conditions between gaming machines and dedicated units]
FIG. 453 is a diagram showing communication conditions between the gaming machine and the dedicated unit.
The communication method is asynchronous serial communication.
The communication speed is 62,500 bps.
The bit configuration is "start bit: 1, data bit: 8, stop bit: 1: parity: none".
The communication control is full-duplex communication, the primary station is a gaming machine, and the secondary station is a dedicated unit.

[8. Data structure between gaming machine and dedicated unit]
FIG. 454 is a diagram showing a data structure between the gaming machine and the dedicated unit.
In the data structure, "telegram length", "command", "serial number", "data section", and "checksum" are arranged in order from the beginning of the data. The telegram range is from the beginning to the end of the data.
It is preferable that the telegram is always transmitted in one frame and not divided.

FIG. 455 is a diagram showing details of the data configuration between the gaming machine and the dedicated unit.
[No1]
Name: Telegram length Data length: 1 byte Data format: HEX (hexadecimal)
Contents: Stores the length of the telegram from the telegram length to the checksum. The range is 0x05-0x39 (5-57).

[No2]
Name: Command Data length: 1 byte Data format: HEX (hexadecimal)
Contents: Stores the command code of the telegram.

[No3]
Name: Serial number Data length: 1 byte Data format: HEX (hexadecimal)
Contents: Stores serial numbers, counting serial numbers, and rental serial numbers. This is the sequence number of the serial number. The range is 0x00 to 0xFF (0 to 255).

[No4]
Name: Data part Data length: 1 to 53 bytes Data format: HEX (hexadecimal)
Contents: Stores telegram data.

[No5]
Name: Checksum Data length: 1 byte Data format: HEX (hexadecimal)
Contents: The data from the telegram length to the data part are added, and the lower 1 byte of the total is stored.

[8.1. Byte order between game machine and dedicated unit]
The byte order in this chapter defines B as big endian and L as little endian.

[9. Business telegram between game machine and dedicated unit]
[9.1. List of telegrams between gaming machines and dedicated units]
FIG. 456 is a diagram showing a list of telegrams between the gaming machine and the dedicated unit.
[No1]
Telegram name: Game machine information notification Transmission direction: Game machine → Dedicated unit Command: 0x01
Summary: The gaming machine notifies the dedicated unit of the gaming machine information.

[No2]
Telegram name: Counting notification Transmission direction: Gaming machine → Dedicated unit Command: 0x02
Summary: The gaming machine notifies the dedicated unit of the counting information.

[No3]
Telegram name: Lending notification Transmission direction: Dedicated unit → Pachinko machine Command: 0x13
Summary: The dedicated unit notifies the gaming machine of the rental information.

[No4]
Telegram name: Lending receipt result response Transmission direction: Gaming machine → Dedicated unit Command: 0x03
Summary: The gaming machine responds to the dedicated unit with the result of receiving the loan information.

[9.2. Details of the telegram between the game machine and the dedicated unit]
[9.2.1. Game machine information notification]
FIG. 457 is a diagram showing details of the gaming machine information notification.
Telegram name: Game machine information notification Telegram length: 18 to 57 bytes (variable length)
Transmission direction: Gaming machine → Dedicated unit Telegram outline: The gaming machine notifies the dedicated unit of the gaming machine information by this telegram. There are three types of gaming machine information: gaming machine installation information, gaming machine performance information, and hall control / fraud monitoring information, and one of them is notified according to the notification conditions of each information.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x12 to 0x39

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x01

[No3]
Data name: Serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Game machine type Data length: 1 byte Byte order:-
Contents: Indicates the type of gaming machine.

[No5]
Data name: Game machine information type Data length: 1 byte Byte order:-
Contents: 0x00: Pachinko machine performance information, 0x01: Pachinko machine installation information, 0x02: Hall control / fraud monitoring information

The gaming machine information notifies one of the following set by the type code.
[No6]
Data name: Game machine performance information of game machine information (details are shown in 9.2.1.4)
Data length: 51 bytes Byte order:-
Contents: Total number of input, total number of payout, MY, etc.

[No6]
Data name: Game machine installation information of game machine information (details are shown in 9.2.1.5)
Data length: 40 bytes Byte order:-
Contents: Manufacturer code, product code, chip ID number of main control / medal number control

[No6]
Data name: Hall control / fraud monitoring information for gaming machine information (details are shown in 9.2.1.6)
Data length: 12-16 bytes Byte order:-
Contents: IN (number of input medals), OUT (number of output medals), BB (big bonus), RB (regular bonus), AT (assist time), door open signal, security signal, etc.

[No7]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[9.2.1.1. About serial number (9.2.1.No3)]
The gaming machine notifies the dedicated unit of the serial number by the following control.
(1) When the power is turned on, the serial number "0x00 (0)" is notified.
(2) After the power is turned on, the serial number (9.2.1.No3) is updated (+1) every time a notification is made.
(3) The next value of the serial number "0xFF (255)" is updated (+2) to "0x01 (1)".

[9.2.1.2. About game machine type (9.2.1.No4)]
FIG. 458 is a diagram showing a code system (1 byte) of a gaming machine type.
Bit7: Management medium (0 = game ball, 1 = game medal)
Bit6 to Bit4: Group classification (0 = A union, 1 = B union, 2-7 = reserve)
Bit3 to Bit0: Game machine type (1 = pachinko game machine, 2 = rotating body type game machine, 3 = arrange ball game machine, 4 = Jiyan ball game machine, 5 to 15 = spare, 0 = unused)

FIG. 459 is a diagram showing an example of a gaming machine type list.
Code: 0x01
Game machine: Pachinko game machine Group: A union Management medium: Game ball

Code: 0x82
Pachinko machine: Revolving pachinko machine Group: A union Management medium: Pachinko medal

Code: 0x83
Game machine: Arrange ball game machine Group: A union Management medium: Game medal

Code: 0x84
Game machine: Jiyan ball game machine Group: A union Management medium: Game medal

Code: 0x92
Pachinko machine: Revolving pachinko machine Group: B union Management medium: Pachinko medal

[9.2.1.3. About game machine information type (9.2.1.No5)]
The gaming machine notifies the type of gaming machine information with the following code.
(1) Type code 0x00: Game machine performance information Notifies the total number of input, total number of payouts, MY, etc.
(2) Type code 0x01: Game machine installation information Notify the manufacturer code, product code, and chip ID number of the main control / medal number control.
(3) Type code 0x02: Hall control / fraud monitoring information IN, OUT, BB, RB, AT, door open signal, security signal, etc. are notified.

[9.2.1.4. Telegram when "0x00: Gaming machine performance information" is set for the gaming machine information type]
FIG. 460 is a diagram showing a telegram when "0x00: gaming machine performance information" is set as the gaming machine information type.
Data name: Total number of input of game machine information (game machine performance information) Data length: 3 bytes Byte order: L
Contents: Cumulative number of inputs since the power was turned on (replay is not included)
For those that store information from the power ON, such as the total number of input sheets, the value is cleared (reset) when the power is turned off or when the power is turned on. For example, the same applies to the following information such as the total number of payouts, MY, and the total number of bonuses paid out, as well as the information that stores the information from the power ON.

Data name: Total number of game machine information (game machine performance information) to be paid out Data length: 3 bytes Byte order: L
Contents: Cumulative number of payouts from power ON (excluding replay)
The total number of payouts here indicates only the number of game values paid out to the player by winning a "small role" such as a "bell role", a "watermelon role", or a "cherry role".

In this way, the medalless gaming machine (medal number control board, communication control means) is information excluding a predetermined number of game medals inserted by the re-game execution means, and the number of inserted game medals accumulated from the time the power is turned on. Information excluding the total number of inserted game medals (total number of inserted number information) and the predetermined number of game medals inserted by the re-game execution means, and the total number of paid out number of game medals accumulated from the time the power is turned on (total number of paid medals) Information on the number of payouts) is sent to the dedicated unit.

Data name: MY of gaming machine information (gaming machine performance information)
Data length: 3 bytes Byte order: L
Contents: Maximum MY calculated after the power is turned on

Data name: Total number of pachinko and pachislot machines to be paid out for game machine information (game machine performance information) Data length: 3 bytes Byte order: L
Contents: Number of payouts due to the operation of the accessory accumulated from turning on the power

Data name: Total number of continuous characters paid out for game machine information (game machine performance information) Data length: 3 bytes Byte order: L
Contents: Number of payouts due to the operation of the first-class special accessory accumulated from turning on the power

Data name: Character ratio of game machine information (game machine performance information) Data length: 1 byte Byte order:-
Contents: Information on the role ratio monitor (FFh when the specified number of games is not reached). In addition, the role ratio monitor is a role ratio, a continuous role ratio, an advantageous section ratio, an instruction-included role ratio (a role ratio including a game medal acquired when an instruction is issued), and a state ratio of a character, etc. (all). It is a display device that displays the ratio of the number of games played when the accessory is activated and when the accessory is not activated). The advantageous section is a section in which an instruction effect for instructing a small winning combination can be executed.

Data name: Continuous character ratio of game machine information (game machine performance information) Data length: 1 byte Byte order:-
Contents: Information on the role ratio monitor (FFh when the specified number of games is not reached)

Data name: Advantageous section ratio of gaming machine information (gaming machine performance information) Data length: 1 byte Byte order:-
Contents: Information on the role ratio monitor (FFh when not applicable / specified number of games has not been reached)

Data name: Instructed accessory ratio of game machine information (game machine performance information) Data length: 1 byte Byte order:-
Contents: Information on the role ratio monitor (FFh when not applicable / specified number of games has not been reached)

Data name: Characteristic status ratio of game machine information (game machine performance information) Data length: 1 byte Byte order:-
Contents: Information on the role ratio monitor (FFh when the specified number of games is not reached)

Data name: Number of games played in game machine information (game machine performance information) Data length: 2 bytes Byte order: L
Contents: Cumulative number of games since the power was turned on

Data name: Preliminary data length of game machine information (game machine performance information): 24 bytes Byte order:-
Contents: Spare (1 byte x 24, fixed at 00h when not in use)

Data name: Reservation of gaming machine information (gaming machine performance information) 1
Data length: 3 bytes Byte order:-
Contents: Used in the dedicated unit (fixed to 00h) (maximum MY calculated by the dedicated unit).

Data name: Reservation of gaming machine information (gaming machine performance information) 2
Data length: 2 bytes Byte order:-
Contents: Used in the dedicated unit (fixed to 00h) (number of games calculated by the dedicated unit).
The gaming machine performance information is information transmitted from the dedicated unit to the gaming machine information center.

[9.2.1.5. Telegram when "0x01: Game machine installation information" is set for the game machine information type]
FIG. 461 is a diagram showing a telegram when "0x01: game machine installation information" is set as the game machine information type.
Data name: Main control chip ID number of game machine information (game machine installation information) Data length: 9 bytes Byte order: B
Contents: Main control chip ID number of the gaming machine

Data name: Main control chip maker code of game machine information (game machine installation information) Data length: 3 bytes Byte order: B
Contents: Manufacturer code written in the control area of the main control

Data name: Main control chip for game machine information (game machine installation information) Product code Data length: 8 bytes Byte order: B
Contents: Product code written in the control area of the main control

Data name: Number of medals Control chip ID number Data length: 9 bytes Byte order: B
Contents: Game machine medal number control chip ID number (0 when not installed)

Data name: Number of medals Control chip Maker code Data length: 3 bytes Byte order: B
Contents: Manufacturer code written in the management area for controlling the number of medals (0 when not installed)

Data name: Number of medals Control chip Product code Data length: 8 bytes Byte order: B
Contents: Product code written in the management area for controlling the number of medals (0 when not installed)
The gaming machine installation information is information transmitted from the dedicated unit to the gaming machine information center.

[9.2.1.1.5.1. Main control chip ID number]
FIG. 462 is a diagram showing a method of generating the main control chip ID number (in the case of the first chip).
The individual chip numbers of the CPU are read in ascending order of address.
The upper 4 bytes of this number are padded with 0, and an identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip individual number is 0x12345678, 0 padding is 4 bytes (0x00000000000), the chip individual number is 4 bytes (0x12345678), and the identification code (*) is 1 byte (0x21).

FIG. 463 is a diagram showing a method of generating the main control chip ID number (in the case of the second chip).
The CPU chip code is read from the youngest address.
The upper 4 bytes of this code are padded with 0, and the identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip code is 0x34567812, 0 padding is 4 bytes (0x00000000000), the chip code is 4 bytes (0x34567812), and the identification code (*) is 1 byte (0x41).

[9.2.1.1.5.2. Medal number control chip ID number]
FIG. 464 is a diagram showing a method of generating a medal number control chip ID number (in the case of the first chip).
The individual chip numbers of the CPU are read in ascending order of address.
The upper 4 bytes of this number are padded with 0, and an identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip individual number is 0x87654321, 0 padding is 4 bytes (0x00000000000), the chip individual number is 4 bytes (0x87654321), and the identification code (*) is 1 byte (0x21).

FIG. 465 is a diagram showing a method of generating a medal number control chip ID number (in the case of the second chip).
The CPU chip code is read from the youngest address.
The upper 4 bytes of this code are padded with 0, and the identification code is added to the lower 1 byte to make 9 bytes.
For example, when the chip code is 0x21876543, 0 padding is 4 bytes (0x00000000000), the chip code is 4 bytes (0x21876543), and the identification code (*) is 1 byte (0x41).

FIG. 466 is a diagram showing a method of generating a medal number control chip ID number (when the medal number control is not installed).
The upper 8 bytes are padded with 0, and an identification code (not installed) is added to the lower 1 byte to make 9 bytes.
In this case, 0 padding is 8 bytes (0x0000000000000000), and the identification code (*) is 1 byte (0x00).

FIG. 467 is a diagram showing an identification code of the main control / medal number control chip ID number.
The identification code is 1 byte.
The CPU maker identifies by Bits 5 to 7.
The CPU type is identified by Bits 0 to 4.

When Bits 5 to 7 are "0", the CPU maker is "not equipped with or unused the medal number control chip".
When Bits 5 to 7 are "1", the CPU maker is the "first maker".
When Bits 5 to 7 are "2", the CPU maker is "second maker".
When Bits 5 to 7 are "3 to 7", it is a spare.

When Bits 5 to 7 are "0" and Bits 0 to 4 are "0", the CPU type is "not equipped with medal number control".
When Bits 5 to 7 are "0" and Bits 0 to 4 are "1 to 31", the CPU type is "unused".

When Bits 5 to 7 are "1" and Bits 0 to 4 are "0", it is unused.
When Bits 5 to 7 are "1" and Bits 0 to 4 are "1", the CPU type is "first chip A".
When Bits 5 to 7 are "1" and Bits 0 to 4 are "2", the CPU type is "first chip B".
When Bits 5 to 7 are "1" and Bits 0 to 4 are "3 to 31", it is a spare.

When Bits 5 to 7 are "2" and Bits 0 to 4 are "0", it is unused.
When Bits 5 to 7 are "2" and Bits 0 to 4 are "1", the CPU type is "second chip A".
When Bits 5 to 7 are "2" and Bits 0 to 4 are "2", the CPU type is "second chip B".
When Bits 5 to 7 are "2" and Bits 0 to 4 are "3", the CPU type is "second chip C".
When Bits 5 to 7 are "2" and Bits 0 to 4 are "4 to 31", it is a spare.

When Bits 5 to 7 are "3 to 7" and Bits 0 to 4 are "0", it is unused.
When Bits 5 to 7 are "3 to 7" and Bits 0 to 4 are "1 to 31", it is a spare.

[9.2.1.6. Telegram when "0x02: Hall control / fraud monitoring information" is set as the game machine information type]
468 to 470 are diagrams showing a telegram when "0x02: Hall control / fraud monitoring information" is set as the gaming machine information type.

[Fig. 468]
Data name: Number of game medals for game machine information (hall control / fraud monitoring information) (* 1)
Data length: 3 bytes Byte order: L
Contents: The current number of game medals (0x0000000 to 0xFF3F00 (0 to 16383)) recorded (displayed) on the game medal number display device (game ball number display device). The storage example is 0xD00700 when the number of game medals is 2000.

Data name: Number of medals inserted for game machine information (hall control / fraud monitoring information) Data length: 1 byte Byte order:-
Contents: Number of medals inserted (0xFD to 0x03 (-3 to 3)). The upper 1 bit is a code (+/-) bit. If there is a return medal by the checkout button, subtract it. It is not treated as an HC signal (external signal CN2-1).

Data name: Number of medals to be paid out for game machine information (hall control / fraud monitoring information) Data length: 1 byte Byte order:-
Contents: Number of medals paid out (0x00 to 0x0F (0 to 15)). It is not treated as an HC signal (external signal CN2-2).

In this way, the medalless gaming machine (medal number control board, communication control means) has the number of inserted medals related to the number of inserted game medals (information on the number of inserted medals) and the number of paid medals related to the number of paid out game medals. (Information on the number of medals to be paid out) is sent to the dedicated unit.
The number of inserted medals and the number of paid medals are treated as information for the dedicated unit, and are not treated as information for the hall computer connected to the dedicated unit.

Data name: Main control status of gaming machine information (hall control / fraud monitoring information) 1
Data length: 1 byte Byte order:-
Contents: Bit0: RB (external signal CN2-3), Bit1: BB (external signal CN2-4), Bit2: AT (external signal CN2-5), Bit3: gaming machine status signal 1, Bit4: gaming machine status signal 2 , Bit5: gaming machine status signal 3, Bit6: gaming machine status signal 4, Bit7: unused

Data name: Main control status of gaming machine information (hall control / fraud monitoring information) 2
Data length: 1 byte Byte order:-
Contents: Bit0: Gaming machine status signal 5, Bit1: Gaming machine status signal 6, Bit2: Gaming machine status signal 7, Bit3: Unused, Bit4: Unused, Bit5: Unused, Bit6: Unused, Bit7: Unused

[Fig. 469]
Data name: Game machine error status of game machine information (hall control / fraud monitoring information) Data length: 1 byte Byte order:-
Description: Error code occurring on the gaming machine. Bit0-5: Error code (000000 = no error), Bit6: 0 = Medal number control, 1 = Main control, Bit7: 0 = Notification only, 1 = Notification + HC (Hallcon) output. Bit0-7: 0 = No error occurred. The alarm indicates an alarm (for example, an error display or an output of a warning sound) by a dedicated unit. The presence or absence of HC output for each error is arbitrarily determined by the gaming machine.

Data name: Gaming machine fraud 1 (main control) of gaming machine information (hall control / fraud monitoring information)
Data length: 1 byte Byte order:-
Contents: Bit0: Setting changing signal, Bit1: Setting confirmation signal, Bit2: Fraud detection signal 1, Bit3: Fraud detection signal 2, Bit4: Fraud detection signal 3, Bit5: Security signal (external signal CN2-7), Bit6 : Unused, Bit7: Unused

Data name: Game machine fraud 2 (main control or medal number control) of game machine information (hall control / fraud monitoring information)
Data length: 1 byte Byte order:-
Contents: Bit0: Setting door open signal, Bit1: Door open signal (external signal CN2-8), Bit2: Unused, Bit3: Game medal number clear detection, Bit4: Unused, Bit5: Unused, Bit6: Unused, Bit7: Unused

Data name: Game machine fraud 3 (main control or medal number control) of game machine information (hall control / fraud monitoring information)
Data length: 1 byte Byte order:-
Contents: Bit0-7: Unused

Data name: Number of game information of game information (external signals CN2-1 and 2) Data length: 1 byte Byte order:-
Contents: Number of type information / count information (n). n = 0x00 to 0x02 (0 to 2). When the number of game information is 0, the following type information and count information are not transmitted.

Data name: Type information 1 of game information (external signals CN2-1 and 2)
Data length: 1 byte Byte order:-
Contents: Type information 1

Data name: Count information 1 of game information (external signals CN2-1 and 2)
Data length: 1 byte Byte order:-
Contents: Count information 1

Data name: Type information 2 of game information (external signals CN2-1 and 2)
Data length: 1 byte Byte order:-
Contents: Type information 2

Data name: Count information 2 of game information (external signals CN2-1 and 2)
Data length: 1 byte Byte order:-
Contents: Count information 2

(* 1) The "number of game medals", "number of inserted medals", and "number of paid medals" transmitted in this telegram have the following relationship.
As a result, the dedicated unit detects an abnormality in the "number of game medals".
"Number of game medals" = "Number of game medals" sent last time- "Number of inserted medals" + "Number of paid medals"
＋ "Number of rented medals" received after "Number of game medals" sent last time
-"Number of counting medals (* 2)" sent after "Number of game medals" sent last time
(* 2) The "counting medal" is transmitted even if the information is other than the gaming machine information (hall control / fraud monitoring information).

[9.2.1.6.1. Main control state 1]
FIG. 471 is a diagram showing details of each bit in the main control state 1.
Each signal in the main control state 1 is treated as an HC signal. Each signal output from the gaming machine is output from the dedicated unit to the HC side as it is.
[Bit0]
Name: RB (external signal CN2-3)
Details: RB operating information. Set "1" during bonus operation equivalent to RB.

[Bit1]
Name: BB (external signal CN2-4)
Details: BB operating information. Set "1" during bonus operation equivalent to BB.

[Bit2]
Name: AT (external signal CN2-5)
Details: AT operating information. Set "1" during the bonus operation equivalent to AT.

[Bit3]
Name: Pachinko machine status signal 1 (* 1)
Details: Game machine status signal. Set "1" while the gaming machine status signal 1 is ON.

[Bit4]
Name: Pachinko machine status signal 2 (* 1)
Details: Game machine status signal. Set "1" while the gaming machine status signal 2 is ON.

[Bit5]
Name: Pachinko machine status signal 3 (* 1)
Details: Game machine status signal. Set "1" while the gaming machine status signal 3 is ON.

[Bit6]
Name: Game machine status signal 4 (* 1)
Details: Game machine status signal. Set "1" while the game machine status signal 4 is ON.

[Bit7]
Name: Unused Details: Fixed to 0

(* 1) The gaming machine status signals 1 to 4 are used when setting the gaming machine status other than RB, BB, and AT. The usage of the game machine status signals 1 to 4 differs depending on the model of the game machine.

[9.2.1.6.2. Main control state 2]
FIG. 472 is a diagram showing details of each bit in the main control state 2.
Each signal in the main control state 2 is treated as an HC signal. Each signal output from the gaming machine is output to the HC side as it is from the dedicated unit.
[Bit0]
Name: Pachinko machine status signal 5 (* 2)
Details: Game machine status signal. Set "1" while the gaming machine status signal 5 is ON.

[Bit1]
Name: Pachinko machine status signal 6 (* 2)
Details: Game machine status signal. Set "1" while the gaming machine status signal 6 is ON.

[Bit2]
Name: Pachinko machine status signal 7 (* 2)
Details: Game machine status signal. Set "1" while the gaming machine status signal 7 is ON.

[Bit3-7]
Name: Unused Details: Fixed to 0

(* 2) The gaming machine status signals 5 to 7 are used when setting the gaming machine status other than RB, BB, and AT. The usage of the gaming machine status signals 5 to 7 differs depending on the model of the gaming machine.

[9.2.1.6.3. Pachinko machine fraud 1]
FIG. 473 is a diagram showing details of the gaming machine fraud 1.
Each signal of the gaming machine fraud 1 is treated as an HC signal. Each signal output from the gaming machine is output from the dedicated unit to the HC side as it is.
[Bit0]
Name: Setting changing signal Details: Indicates that the setting is being changed or the setting has been changed. This signal is continuously output from the setting change to the end of one game after the setting change. 0 = Normal, 1 = Setting change in progress and after setting change.

[Bit1]
Name: Setting confirmation signal Details: Indicates that setting is being confirmed. 0 = normal, 1 = setting is being confirmed.

[Bit2]
Name: Fraud detection signal 1 (* 3)
Details: In addition to the above, it indicates that there is a risk of fraud. 0 = normal, 1 = abnormal is occurring.

[Bit3]
Name: Fraud detection signal 2 (* 3)
Details: In addition to the above, it indicates that there is a risk of fraud. 0 = normal, 1 = abnormal is occurring.

[Bit4]
Name: Fraud detection signal 3 (* 3)
Details: In addition to the above, it indicates that there is a risk of fraud. 0 = normal, 1 = abnormal is occurring.

[Bit5]
Name: Security signal (external signal CN2-7)
Details: Indicates that any of the fraud detection signals 1 to 3 is ON, the setting is being changed, or the setting is being confirmed (logical sum output). The setting changing signal in this signal is continuously output from the setting change to the end of one game after the setting change. 0 = normal, 1 = fraud detected.

[Bits 6 and 7]
Name: Unused Details: Fixed to 0

(* 3) The fraud detection signals 1 to 3 differ in the content of fraud detected depending on the model and specifications of the gaming machine. Also, it is limited to gaming machines that have a function to detect various frauds.

[9.2.1.6.4.4. Pachinko machine fraud 2]
FIG. 474 is a diagram showing details of the gaming machine fraud 2.
Each signal of the gaming machine fraud 2 is treated as an HC signal. Each signal output from the gaming machine is output from the dedicated unit to the HC side as it is.
[Bit0]
Name: Setting door open signal (* 4)
Details: Indicates that the door of the setting change device has been opened. 0 = Normal, 1 = The door of the setting change device is open.

[Bit1]
Name: Door open signal (external signal CN2-8)
Details: Indicates that the opening of the pachinko / pachislot machine door has been detected. 0 = Normal, 1 = The door of the gaming machine is open.

[Bit2]
Name: Unused Details: Fixed to 0

[Bit3]
Name: Clear detection of the number of game medals (* 5)
Details: Indicates that the number of game medals has been cleared. This signal is continuously output until the end of one game after clearing the number of game medals. 0 = normal, 1 = clear detection of the number of game medals.

[Bit4-7]
Name: Unused Details: Fixed to 0

(* 4) The setting door open signal is limited to a gaming machine having a function of detecting the opening of the door of the setting changing device.
(* 5) The function of clearing the number of game medals operates when a button or the like related to the function is operated when the power is turned on.

[9.2.1.6.5.5. Pachinko machine fraud 3]
FIG. 475 is a diagram showing details of the gaming machine fraud 3.
[Bit0-7]
Name: Unused Details: Fixed to 0

[9.2.1.6.6.6. Game information]
FIG. 476 is a diagram showing details of game information.
The game information is composed of a total of 2 bytes of type information (upper 1 byte) and count information (lower 1 byte).
The type information is information indicating whether the specified number or the number of payouts generated in the gaming machine is different. The specified number indicates the number of game medals required to perform one game.
Further, the count information is information indicating the number of sheets generated in the type information.
When the number of game information is 0, the above type information and count information are not transmitted.
The game information is treated as an HC signal. The game information output from the game machine is output as it is from the dedicated unit to the HC side.

[(1) Type information]
FIG. 477 is a diagram showing details of the type information.
The type information (1 byte) is composed of a data type (upper 4 bits, Bits 4 to 7) and a data number (lower 4 bits, Bits 0 to 3).

[(A) Details of data type (top 4 bits)]
FIG. 478 is a diagram showing details of (a) data type (upper 4 bits).
Bit 4-7: 0
Type name: Unused Contents:-

Bit 4-7: 1
Type name: Specified number (IN, number of inputs)
Contents: Notify the specified number of the game. When the start lever is accepted, the specified number of games will be notified. For example, it corresponds to the IN signal of the external signal CN2-1. The "start lever reception time" is when the start lever is operated with the specified number of medals required for the game inserted.

Bit 4-7: 2
Type name: Number of payouts (OUT, number of outputs)
Contents: Notify the number of payouts at the end of the game. Notify the number of medals won by winning (small winning combination) and the specified number at the time of re-game operation. For example, it corresponds to the OUT signal of the external signal CN2-2.
The number of payouts here indicates the game value acquired by the player as a result of the game. More specifically, the number of payouts here is not only the number of game values paid out to the player by winning "small roles" such as "bell role", "watermelon role", and "cherry role". , In addition to this, the game value acquired when the re-game is activated is also included.
In addition, "when the replay is activated" indicates that the result of the game is a prize for "replay" such as "replay" (display of a symbol combination corresponding to the replay on the valid line). When the re-game is activated, the game value required for the next game is automatically input.

As described above, the medalless gaming machine (medal number control board, communication control means) is information including a predetermined number of game medals inserted by the re-game execution means, and relates to the number of inserted game medals in one game. Information including a specified number (specified number information) and a predetermined number of game medals inserted by the re-game execution means, and the number of medals to be paid out in one game (information on the number of medals to be paid out). Send to a dedicated unit.
The specified number and the number of payouts are treated as information for the dedicated unit and are treated as information for the hall computer connected to the dedicated unit.

Bit 4-7: 3-15
Type name: Unused Contents:-

[(B) Details of data number (lower 4 bits) set for each data type]
FIG. 479 is a diagram showing details of (b) a data number (lower 4 bits) set for each data type.
The type information (1 byte) includes a data type (Bits 4 to 7) and a data number (Bits 0 to 3).

Data type (Bit4-7): 0 = unused Data number (Bit0-3): 0-15 = unused

Data type (Bit4-7): 1 = specified number (IN)
Data number (Bit0-3): 1 fixed. 0 and 2 to 15 = unused.

Data type (Bit4-7): 2 = number of payouts (OUT)
Data number (Bit0-3): 1 fixed. 0 and 2 to 15 = unused.

Data type (Bit4 to 7): 3 to 15 = unused Data number (Bit0 to 3): 0 to 15 = unused

[(2) Count information]
The setting contents of the count information differ depending on the data type.
The detailed contents and data storage example for each data type are shown below.
(A) When the data type is a specified number FIG. 480 is a diagram showing details of count information when the data type is a specified number.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and a specified number (lower 4 bits, Bits 0 to 3).

[Bit4-7]
Name: Unused Details: Fixed to 0

[Bit0-3]
Name: Specified number Details: Specified number of the game. 1-3 = specified number (1 (sheets) to 3 (sheets)).

FIG. 481 is a diagram showing a specific example of game information in the case of a specified number of three-card game.
Data type of type information (1 byte) (Bit4 to 7): 1 = specified number (IN)
Data number of type information (1 byte) (Bit0 to 3): 1 fixed Number of count information (1 byte) unused (Bit4 to 7): 0 fixed Number of count information (1 byte) specified (Bit0 to 3): 3 = 3 specified number 0x1103 is set for the game information.

(B) When the data type is the number of payouts FIG. 482 is a diagram showing the details of the count information when the data type is the number of payouts.
The count information is composed of unused (upper 4 bits, Bits 4 to 7) and the number of payouts (lower 4 bits, Bits 0 to 3).

[Bit4-7]
Name: Unused Details: Fixed to 0

[Bit0-3]
Name: Number of payouts Details: Number of payouts for the game (when the re-game is activated, the specified number of the game). 1 to 15 = number of payouts (1 (sheets) to 15 (sheets)).

FIG. 483 is a diagram showing a specific example of game information when 10 medals are paid out by winning a prize.
Data type of type information (1 byte) (Bit4 to 7): 2 = number of payouts (OUT)
Data number of type information (1 byte) (Bit 0 to 3): 1 fixed Number of count information (1 byte) unused (Bit 4 to 7): 0 fixed Number of count information (1 byte) to be paid out (Bit 0 to 3): 10 = 0x210A is set as the game information for paying out 10 cards.

[9.2.2.2. Counting notification]
FIG. 484 is a diagram showing details of the counting notification.
Telegram name: Counting notification Telegram length: 7 bytes Transmission direction: Gaming machine → Dedicated unit Telegram outline: The gaming machine notifies the dedicated unit of counting information.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x07

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x02

[No3]
Data name: Counting serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Number of counting medals Data length: 1 byte Byte order:-
Contents: Number of counting medals (0x00 to 0x32 (0 to 50))

[No5]
Data name: Counting Cumulative number of medals Data length: 2 bytes Byte order: L
Contents: Counting cumulative number of medals (0x0000 to 0xFFFF (0 to 65535)). The storage example is 0xD007 when the cumulative number of medals counted is 2000.

[No6]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[9.2.2.1. About counting serial number (9.2.2.2 No3)]
The gaming machine notifies the dedicated unit of the counting serial number (9.2.2.2 No3) by the following control.
(1) When the power is turned on, the serial number "0x00 (0)" is notified.
(2) After the power is turned on, the serial number is updated (+1) each time a notification is sent.
(3) The next value of the counting serial number "0xFF (255)" is updated (+2) to "0x01 (1)".

[9.2.2.2. About counting cumulative medals (9.2.2.2 No5)]
The gaming machine notifies the dedicated unit of the cumulative number of medals counted (9.2.2.2 No. 5) by the following control.
(1) The next value after the cumulative number of medals counted is "0xFFFF (65535)" is updated to "0x0000 (0)".
(2) When the power of the gaming machine is turned on, the cumulative number of medals counted is cleared to "0".

[9.2.3. Lending notice]
FIG. 485 is a diagram showing details of the loan notification.
Telegram name: Lending notification Telegram length: 5 bytes Transmission direction: Dedicated unit → Gaming machine Telegram outline: The dedicated unit notifies the gaming machine of lending information by this telegram.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x05

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x13

[No3]
Data name: Lending serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Number of medals to be lent Data length: 1 byte Byte order:-
Contents: Number of medals to be rented for game medals (0x00 to 0x32 (0 to 50))

[No5]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[9.2.3.1. About loan notice (9.2.3.)]
When the dedicated unit receives the counting notification, it notifies the gaming machine of the lending notification. However, if any of the following applies, the number of medals to be lent will be "0".
(1) When the gaming machine information notification has not been received (2) When the notification is made other than the gaming machine information type "0x02: Hall control / fraud monitoring information" (3) When the number of counting medals in the counting notification is "1" or more When notified The dedicated unit can notify the gaming machine of the number of rented medals "1" or more only when the above does not apply.

[9.2.3.2. About rental serial number (9.2.3.No3)]
The dedicated unit notifies the gaming machine of the rental serial number under the following control.
(1) When communication with the gaming machine is started, the serial number is notified by "0".
(2) Update the loan serial number received in the loan receipt result response (+1) and notify in the next loan notification.
(3) The next value of the loan serial number "0xFF (255)" is updated (+2) to "0x01 (1)".

[9.2.4.4. Lending receipt result response]
FIG. 486 is a diagram showing details of the loan receipt result response.
Telegram name: Lending receipt result response Telegram length: 5 bytes Transmission direction: Gaming machine → Dedicated unit Telegram outline: The gaming machine responds to the dedicated unit with the receipt result of lending information.

[No1]
Data name: Telegram length Data length: 1 byte Byte order:-
Contents: 0x05

[No2]
Data name: Command Data length: 1 byte Byte order:-
Contents: 0x03

[No3]
Data name: Lending serial number Data length: 1 byte Byte order:-
Contents: Sequence number (0x00 to 0xFF (0 to 255))

[No4]
Data name: Number of medals lent Received result Data length: 1 byte Byte order:-
Contents: Result of receipt of the number of medals lent. 0x00 = normal, 0x01 = abnormal. If a value other than the above is notified, it is considered abnormal.

[No5]
Data name: Checksum Data length: 1 byte Byte order:-
Contents: Checksum data

[9.2.4.1. About rental serial number (9.2.4.4.No3)]
The gaming machine responds to the dedicated unit with the following control.
(1) Number of rented medals When the receipt result is normal (0x00), the loan serial number received from the dedicated unit is returned.
(2) Number of rented medals When the receipt result is abnormal (0x01), the loan serial number received from the dedicated unit is returned when the loan receipt result is normal (0x00).
(3) When the power of the gaming machine is turned on, the rental serial number is cleared to "0".

[9.2.4.2. About the result of receiving the number of medals to be lent (9.2.4.No4)]
The gaming machine responds with the result of receiving the number of rented medals "abnormal (0x01)" in the following cases.
(1) When the lending serial number (9.2.3.No3) notified by the dedicated unit is not continuous (2) When the number of medals lent in the lending notification is outside the specified range (0 to 50) ( 3) When the result of adding the number of rented medals to the number of game medals exceeds 16383 The game machine adds the number of rented medals to the game medal number display device after transmitting the normal result of receiving the number of rented medals.

[10. Communication sequence between gaming machine and dedicated unit]
[10.1. Basic communication sequence]
FIG. 487 is a diagram showing a basic communication sequence.
The gaming machine 9800 is a primary station, and the dedicated unit 9802 is a secondary station.
[G200] The gaming machine 9800 transmits a gaming machine information notification (serial number = n) to the dedicated unit 9802.
[G201] The gaming machine 9800 transmits a counting notification (counting serial number = m) to the dedicated unit 9802.

[G202] The dedicated unit 9802 transmits a rental notification (rental serial number = k) to the gaming machine 9800.
[G203] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k) to the dedicated unit 9802.
[G204] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 1) to the dedicated unit 9802.

The gaming machine 9800 notifies the dedicated unit 9802 of the gaming machine information notification (9.2.1.) At a cycle of 300ms (* 1), and from the gaming machine information notification (9.2.1.) To 100ms ( * 2) Notify the count notification (9.2.2.) After the elapse.
The dedicated unit 9802 notifies the gaming machine 9800 of the lending notification (9.22.3.) Within 170 ms after receiving the counting notification (9.2.2.). The gaming machine 9800 responds to the loan receipt result response (9.2.4.) Within 10 ms in response to the loan notification (9.2.3.) From the dedicated unit 9802.

(* 1) The gaming machine 9800 notifies the next gaming machine information notification within a range of 300 ms or more and 310 ms or less from the start of the gaming machine information notification.
(* 2) The gaming machine 9800 notifies the counting notification within a range of 90 ms or more and 100 ms or less from the start of the gaming machine information notification.
(* 3) The dedicated unit 9802 notifies the gaming machine 9800 of the lending notification within 170 ms from the start of receiving the counting notification. However, the loan notification received outside the scope of this regulation will be discarded, and the loan receipt result response will not be notified.
(* 4) The gaming machine 9800 notifies the loan receipt result response within 10 ms after the receipt of the loan notification is completed.

[10.2. Startup sequence]
[10.2.1. Sequence when the gaming machine is started first]
FIG. 488 is a diagram showing a sequence when the gaming machine is started first.
When the power is off, the VL of the [G211] gaming machine 9800 is OFF, and the VL and PSI of the [G212] dedicated unit 9802 are OFF.

[G213] The power is turned on, and power is supplied to the gaming machine 9800 and the dedicated unit 9802.
[G214] The VL of the gaming machine 9800 is OFF, and the VL and PSI of the [G215] dedicated unit 9802 are OFF. The dedicated unit 9802 is set to VL = OFF until the start-up is completed.

[G216] The state in which the gaming machine is started is changed to the state in which the gaming machine is started [G217]. [G218] The gaming machine 9800 transmits a gaming machine information notification (serial number = 0) to the dedicated unit 9802. [G219] The gaming machine 9800 transmits a counting notification (counting serial number = 0) to the dedicated unit 9802. The gaming machine 9800 transmits a telegram, updates the serial number, and notifies the user regardless of the completion of activation of the dedicated unit 9802. However, since the dedicated unit 9802 is in the state in which the [G220] dedicated unit is activated, the telegram from the gaming machine 9800 cannot be received.

[G221] The activation of the dedicated unit 9802 is completed.
As a result, [F222] the game medal can be inserted (VL = ON), and the counting button (counting switch) becomes effective (PSI = ON).

[G223] The gaming machine 9800 transmits a gaming machine information notification (serial number = n) to the dedicated unit 9802.
[G224] The gaming machine 9800 transmits a counting notification (counting serial number = m) to the dedicated unit 9802.
The dedicated unit 9802, which has been activated, can receive these notifications.
After the activation is completed, the dedicated unit 9802 starts receiving the telegram notified from the gaming machine 9800. The dedicated unit 9802 manages from the notified serial number.

[10.2.2. Sequence when the dedicated unit is started first]
FIG. 489 is a diagram showing a sequence when the dedicated unit is started first.
[G230] The power of the gaming machine 9800 is off, and the power of the dedicated unit 9802 of [G231] is turned on.
[G232] In the dedicated unit 9802, VL = OFF and PSI = OFF.
When the dedicated unit 9802 shifts from the state in which the [G233] dedicated unit is activated to the state in which the [G234] dedicated unit has been activated, VL = ON and PSI = ON in the [G235] dedicated unit 9802. After that, the dedicated unit 9802 is in a state of waiting for the [G236] gaming machine connection until it receives the gaming machine information notification.

When the power of the [G237] gaming machine 9800 is turned on and the state shifts from the state where the gaming machine is starting to the state where the gaming machine is started [G239], the [G240] gaming machine 9800 and the dedicated unit 9802 have VL = ON, PSI = ON.

[G241] The gaming machine 9800 transmits a gaming machine information notification (serial number = 0) to the dedicated unit 9802.
[G242] The gaming machine 9800 transmits a counting notification (counting serial number = 0) to the dedicated unit 9802.
The gaming machine 9800 notifies the dedicated unit 9802 of a telegram after the activation is completed. After the power is turned on, the serial number starts from 0.
The dedicated unit 9802 starts receiving the telegram notified from the gaming machine 9800. The dedicated unit 9802 manages from the notified serial number.

[G243] The gaming machine 9800 transmits a gaming machine information notification (serial number = n) to the dedicated unit 9802.
[G244] The gaming machine 9800 transmits a counting notification (counting serial number = m) to the dedicated unit 9802.

[10.3. Pachinko machine information notification sequence]
FIG. 490 is a diagram showing notification conditions applied in the gaming machine information notification sequence.
The gaming machine notifies the dedicated unit of the gaming machine information under the following notification conditions. If the notification conditions overlap, the notification will be given according to the priority.

Game machine information type: (1) Game machine installation information Notification condition: Notify after 60 seconds (* 1) have passed since the start of the game machine was completed. After that, the notification is made in a cycle of 60s (* 1).
Priority: 1

Game machine information type: (2) Game machine performance information Notification condition: Notify after 180 s (* 2) have passed since the start of the game machine was completed. After that, the notification is made in a cycle of 180s (* 2).
Priority: 2

Game machine information type: (3) Hall control / fraud monitoring information Notification condition: Notify after 300 ms (* 3) has elapsed from the completion of game machine startup. After that, the notification is made in a cycle of 300 ms (* 3).
Priority: 3

[10.3.1. Basic sequence of game machine information notification]
FIG. 491 is a diagram showing a basic sequence of gaming machine information notification.
When the activation of the [G250] gaming machine 9800 is completed, the [G251] gaming machine 9800 transmits the gaming machine information notification (hall controller / fraud monitoring information) to the dedicated unit 9802.
Until this information is received, the dedicated unit 9802 is in a state of waiting for [G252] gaming machine connection.

[G253] The gaming machine 9800 transmits a counting notification to the dedicated unit 9802.
[G254] The dedicated unit 9802 transmits a loan notification to the gaming machine 9800.
[G255] The gaming machine 9800 transmits a loan receipt result response to the dedicated unit 9802.
[G256] The gaming machine 9800 transmits a gaming machine information notification (hall control / fraud monitoring information) to the dedicated unit 9802.

[G257] The gaming machine 9800 transmits a gaming machine information notification (hall control / fraud monitoring information) to the dedicated unit 9802.
[G258] The gaming machine 9800 transmits a counting notification to the dedicated unit 9802.
[G259] The dedicated unit 9802 transmits a lending notice to the gaming machine 9800.
[G260] The gaming machine 9800 transmits a loan receipt result response to the dedicated unit 9802.
[G261] The gaming machine 9800 transmits a gaming machine information notification (gaming machine installation information) to the dedicated unit 9802.

[G262] The gaming machine 9800 transmits a gaming machine information notification (gaming machine installation information) to the dedicated unit 9802. Here, since the notification timings of the gaming machine installation information and the gaming machine performance information overlap, the gaming machine installation information having a high priority is notified first.
[G263] The gaming machine 9800 transmits a counting notification to the dedicated unit 9802.
[G264] The dedicated unit 9802 transmits a loan notification to the gaming machine 9800.
[G265] The gaming machine 9800 transmits a loan receipt result response to the dedicated unit 9802.
[G266] The gaming machine 9800 transmits a gaming machine information notification (gaming machine performance information) to the dedicated unit 9802. Here, after notifying the gaming machine installation information, the gaming machine performance information is notified.

(* 1) The gaming machine 9800 notifies the gaming machine installation information within a range of 60s or more and 62s or less.
(* 2) The gaming machine 9800 notifies the gaming machine performance information within a range of 180s or more and 186s or less.
(* 3) The gaming machine 9800 notifies the hall control / fraud monitoring information within a range of 300 ms or more and 310 ms or less.

[10.4. Counting notification sequence]
492 and 493 are diagrams showing a counting notification sequence.
[G300] It is assumed that the gaming machine 9800 has detected the pressing of the counting button.
At this point, [G301] number of game medals = 200, and [G302] number of medals possessed = 20.

[G303] The gaming machine 9800 transmits a gaming machine information notification (serial number = n, number of gaming medals = 200) to the dedicated unit 9802.
[G304] The gaming machine 9800 transmits a counting notification (counting serial number = m, number of counting medals = 50, cumulative number of counting medals = 50) to the dedicated unit 9802. The gaming machine 9800 notifies the counting (counting serial number = m, number of counting medals = 50, cumulative number of counting medals = 50). The dedicated unit 9802 adds the number of counted medals to the number of medals held (number of medals held = 20 + 50).
At this point, [G305] number of game medals = 150 and [G306] number of medals possessed = 70.

[G307] The dedicated unit 9802 transmits a lending notification (lending serial number = k, number of rented medals = 0) to the gaming machine 9800.
[G308] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = normal) to the dedicated unit 9802.

[G309] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 1, number of gaming medals = 150) to the dedicated unit 9802.
[G310] The gaming machine 9800 transmits a counting notification (counting serial number = m + 1, number of counting medals = 50, cumulative number of counting medals = 100) to the dedicated unit 9802. The gaming machine 9800 notifies the counting (counting serial number = m + 1, number of counting medals = 50, total number of counting medals = 100). The dedicated unit 9802 adds the number of counted medals to the number of medals held (number of medals held = 70 + 50).
At this point, the number of [G311] game medals is 100, and the number of [G312] medals held is 120.

[G313] The dedicated unit 9802 transmits a loan notification (rental serial number = k + 1, number of loan medals = 0) to the gaming machine 9800.
[G314] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k + 1, loan medal number receipt result = normal) to the dedicated unit 9802.

[Fig. 493]
[G315] It is assumed that the gaming machine 9800 has detected that the counting button is released (not pressed).
[G316] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 2, number of gaming medals = 100) to the dedicated unit 9802.
[G317] The gaming machine 9800 transmits a counting notification (counting serial number = m + 2, number of counting medals = 0, cumulative number of counting medals = 100) to the dedicated unit 9802.
At this point, the number of [G318] game medals is 100, and the number of [G319] medals held is 120.

[G320] The dedicated unit 9802 transmits a loan notification (rental serial number = k + 2, number of loan medals = 0) to the gaming machine 9800.
[G321] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k + 2, loan medal number receipt result = normal) to the dedicated unit 9802.
[G322] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 3, number of gaming medals = 100) to the dedicated unit 9802.
(* 1) The gaming machine 9800 notifies the counting notification within a range of 90 ms or more and 100 ms or less from the start of the gaming machine information notification.

[10.5. Lending notification sequence]
FIG. 494 is a diagram showing a loan notification sequence.
[G330] It is assumed that the dedicated unit 9802 has detected the pressing of the lending button.
At this point, the number of [G331] game medals is 10.

[G332] The gaming machine 9800 transmits a gaming machine information notification (serial number = n, number of gaming medals = 10) to the dedicated unit 9802.
[G333] The game machine 9800 transmits a counting notification (counting serial number = m, number of counting medals = 0, cumulative number of counting medals = 0) to the dedicated unit 9802.

[G334] The dedicated unit 9802 transmits a lending notification (lending serial number = k, number of rented medals = 47) to the gaming machine 9800. The dedicated unit 9802 notifies the loan (lending serial number = k, number of rented medals = 47). The dedicated unit 9802 notifies in the range of 1 to 50 sheets.
[G335] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = normal) to the dedicated unit 9802. The game machine 9800 adds the number of rented medals to the number of game medals (number of game medals = 10 + 47) and responds with the result of receiving the number of rented medals (lending serial number = k, result of receiving number of rented medals = normal). The dedicated unit 9802 confirms the result of receiving the number of medals lent.

[G336] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 1, number of gaming medals = 57) to the dedicated unit 9802.
At this point, the number of [G337] game medals = 57.
(* 1) The gaming machine 9800 notifies the next gaming machine information notification within a range of 300 ms or more and 310 ms or less from the start of the gaming machine information notification.
(* 2) The dedicated unit 9802 notifies the gaming machine 9800 of the lending notification within 170 ms from the start of receiving the counting notification. However, the loan notification received outside the scope of this regulation will be discarded, and the loan receipt result response will not be notified.
(* 3) The gaming machine 9800 notifies the loan receipt result response within 10 ms after the receipt of the loan notification is completed.

[10.6. Recovery sequence when the dedicated cable is broken]
495 and 496 are diagrams showing a recovery sequence when the dedicated cable is broken.
At the first time point, the number of [G340] game medals = 200.
[G341] The gaming machine 9800 transmits a gaming machine information notification (serial number = n, number of gaming medals = 200) to the dedicated unit 9802.
[G342] The game machine 9800 transmits a counting notification (counting serial number = m, number of counting medals = 0, cumulative number of counting medals = 0) to the dedicated unit 9802.

[G343] The dedicated unit 9802 transmits a loan notification (rental serial number = k, number of loan medals = 0) to the gaming machine 9800.
[G344] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = normal) to the dedicated unit 9802.
[G345] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 1, number of gaming medals = 200) to the dedicated unit 9802.

[G346] Here, it is assumed that the dedicated cable 9810 is broken. In this case, the dedicated unit 9802 sets VL = OFF.

As a result, in the [G347] gaming machine 9800, VL = OFF (game medal insertion unacceptable state, counting button invalid state), and in the [G348] dedicated unit 9802, VL = OFF and PSI = OFF.

[G349] The game machine 9800 transmits a counting notification (counting serial number = m + 1, number of counting medals = 0, number of cumulative counting medals = 0) to the dedicated unit 9802. Since the counting button is invalid, the number of counting medals is notified (counting serial number = m + 1, number of counting medals = 0, cumulative number of counting medals = 0). However, this notification does not reach the dedicated unit 9802.

[G350] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 2, number of gaming medals = 200) to the dedicated unit 9802. However, this notification does not reach the dedicated unit 9802.
At this point, the number of [G351] game medals is 200.

[G351] The game machine 9800 transmits a counting notification (counting serial number = m + 2, number of counting medals = 0, cumulative number of counting medals = 0) to the dedicated unit 9802. However, this notification does not reach the dedicated unit 9802.

[Fig. 496]
[G353] Here, it is assumed that the disconnection of the dedicated cable 3110 has been restored. In the gaming machine 9800 and the dedicated unit 9802, VL = ON and PSI = ON (game medal insertion acceptance state, counting button enabled state). Check the number of game medals by the clerk processing and recover the error. The dedicated unit 9802 confirms the dedicated cable connection status after VL = ON.

[G354] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 3, number of gaming medals = 200) to the dedicated unit 9802.
[G355] The game machine 9800 transmits a counting notification (counting serial number = m + 3, number of counting medals = 0, cumulative number of counting medals = 0) to the dedicated unit 9802.

[G356] The dedicated unit 9802 transmits a lending notification (lending serial number = 0, number of rented medals = 0) to the gaming machine 9800. When the connection with the gaming machine is started, the rental serial number 0 is notified.
At this point, the number of [G357] game medals = 200.
[G358] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = abnormality) to the dedicated unit 9802.

[G359] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 4, number of gaming medals = 200) to the dedicated unit 9802.
[G360] The game machine 9800 transmits a counting notification (counting serial number = m + 4, number of counting medals = 0, cumulative number of counting medals = 0) to the dedicated unit 9802.

[G361] The dedicated unit 9802 transmits a lending notification (lending serial number = k + 1 (= 1), number of rented medals = 0) to the gaming machine 9800. Update and notify the loan serial number of the loan receipt result response.
[G362] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k + 1, loan medal number receipt result = normal) to the dedicated unit 9802.

[10.7. Communication error during counting]
497 and 498 are diagrams showing communication abnormalities during counting.
[G370] It is assumed that the gaming machine 9800 has detected the pressing of the counting button.
At this point, the number of [G371] game medals is 200, and the number of [G372] medals held is 20.

[G373] The gaming machine 9800 transmits a gaming machine information notification (serial number = n, number of gaming medals = 200) to the dedicated unit 9802.
[G374] The gaming machine 9800 transmits a counting notification (counting serial number = m, number of counting medals = 50, cumulative number of counting medals = 50) to the dedicated unit 9802. The gaming machine 9800 notifies the counting (counting serial number = m, number of counting medals = 50). The dedicated unit 9802 adds the number of counted medals to the number of medals held (number of medals held = 20 + 50).
At this point, the number of [G375] game medals is 150, and the number of [G376] medals held is 70.

[G377] The dedicated unit 9802 transmits a lending notification (lending serial number = k, number of rented medals = 0) to the gaming machine 9800.
[G378] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = normal) to the dedicated unit 9802.

[G379] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 1, number of gaming medals = 150) to the dedicated unit 9802.
[G380] The gaming machine 9800 transmits a counting notification (counting serial number = m + 1, number of counting medals = 50, number of cumulative counting medals = 100) to the dedicated unit 9802. The gaming machine 9800 notifies the counting (counting serial number = m + 1, number of counting medals = 50). However, this notification does not reach the dedicated unit 9802.
At this point, the number of [G381] game medals is 100, and the number of [G382] medals held is 70.

[G383] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 2, number of gaming medals = 100) to the dedicated unit 9802. However, this notification does not reach the dedicated unit 9802. The dedicated unit 9802 detects a communication abnormality in the gaming machine information notification, and sets VL = OFF after a maximum of 300 ms.

In the [G384] gaming machine 9800, VL = OFF (game medal insertion unacceptable state, counting button invalid state), and in the [G385] dedicated unit 9802, VL = OFF and PSI = OFF.

[Fig. 498]
At this point, the number of [G386] game medals = 100.
[G387] The gaming machine 9800 transmits a counting notification (counting serial number = m + 2, number of counting medals = 0, cumulative number of counting medals = 100) to the dedicated unit 9802. Since the counting button is invalid, the number of counting medals is 0 (counting serial number = m + 2, number of counting medals = 0, cumulative number of counting medals = 100). However, this notification does not reach the dedicated unit 9802.

[G388] The dedicated unit 9802 is in a state of waiting for error recovery of the dedicated unit 9802. Check the number of game medals and the number of medals held by the clerk processing, and recover the error. The dedicated unit 9802 sets VL = ON after recovering from the error.

(* 1) The gaming machine 9800 notifies the next gaming machine information notification within a range of 300 ms or more and 310 ms or less from the start of the gaming machine information notification.
(* 2) The gaming machine 9800 notifies the counting notification within a range of 90 ms or more and 100 ms or less from the start of the gaming machine information notification.

[10.8. Communication error at the time of lending]
FIG. 499 is a diagram showing a communication abnormality at the time of lending.
[G400] It is assumed that the dedicated unit 9802 has detected the pressing of the lending button.
At this point, the number of [G401] game medals is 10.

[G402] The gaming machine 9800 transmits a gaming machine information notification (serial number = n, number of gaming medals = 10) to the dedicated unit 9802.
[G403] The game machine 9800 transmits a counting notification (counting serial number = m, number of counting medals = 0, cumulative number of counting medals = 0) to the dedicated unit 9802.

[G404] The dedicated unit 9802 transmits a lending notification (lending serial number = k, number of rented medals = 47) to the gaming machine 9800. The dedicated unit 9802 notifies the loan (lending serial number = k, number of rented medals = 47). The dedicated unit 9802 notifies in the range of 1 to 50 medals depending on the rental medal unit price and the loan amount.
At this point, the number of [G405] game medals = 57.

[G406] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = normal) to the dedicated unit 9802. However, this response does not reach the dedicated unit 9802. The dedicated unit 9802 determines that the loan has not been completed because the response to the loan receipt result has not been received.

[G407] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 1, number of gaming medals = 57) to the dedicated unit 9802.
[G408] The game machine 9800 transmits a counting notification (counting serial number = m + 1, number of counting medals = 0, number of cumulative counting medals = 0) to the dedicated unit 9802.

[G409] The dedicated unit 9802 transmits a lending notification (lending serial number = k, number of rented medals = 47) to the gaming machine 9800. I don't know if the loan notification I notified last time has reached the frame control, so I will resend it.
At this point, the number of [G410] game medals = 57.

[G411] The gaming machine 9800 transmits a loan receipt result response (lending serial number = k, loan medal number receipt result = abnormality) to the dedicated unit 9802. The gaming machine 9800 checks the continuity of the lending serial number of the lending notification, and if it is not continuous, responds with an abnormality. If the serial number matches the previous lending notice, the dedicated unit 9802 determines that the lending notice has arrived at the gaming machine and completes the lending.

At this point, the number of [G412] game medals = 57.
[G413] The gaming machine 9800 transmits a gaming machine information notification (serial number = n + 2, number of gaming medals = 57) to the dedicated unit 9802.

(* 1) The gaming machine 9800 notifies the next gaming machine information notification within a range of 300 ms or more and 310 ms or less from the start of the gaming machine information notification.
(* 2) The dedicated unit 9802 notifies the gaming machine 9800 of the lending notification within 170 ms from the start of receiving the counting notification. However, the loan notification received outside the scope of this regulation will be discarded, and the loan receipt result response will not be notified.
(* 3) The gaming machine 9800 notifies the loan receipt result response within 10 ms after the receipt of the loan notification is completed.

[Chapter S2]
[About calculation processing of gaming machine performance information (1)]
FIG. 500 is a diagram showing details of gaming machine performance information.
The gaming machine performance information includes "special information" and "information about the role ratio monitor" as information types.
The contents of "special information" are "total number of input", "total number of payouts", "total number of payouts while the accessory is operating", "total number of payouts during continuous bonus operation" and "MY (* 1)". Is.
The contents of the "information about the role ratio monitor" are "advantageous section ratio (* 2)", "instructed bonus ratio (* 3)", "feature ratio", "continuous bonus ratio" and "features, etc." State ratio (* 4) ".

(* 1) MY refers to the number of increase in game medals from the standard (the number obtained by subtracting the total number of input from the total number of acquisitions) based on the time when the number of game medals when the result of the game is obtained is the smallest. ..
(* 2) The advantageous section ratio refers to the ratio of the number of games played in the advantageous section (the section having the performance related to the instruction function) to the total number of games played.
(* 3) The character status ratio is the ratio of the total number of game medals to be acquired, which is the sum of the number of medals acquired when the character is activated and the number of medals acquired when the instruction function is activated.
(* 4) The ratio of the total number of games played when the continuous accessory operating device is activated and the number of games played when the continuous accessory operating device is not activated to all the number of games played.

A rotating machine (medalless gaming machine) equipped with a gaming medal number display device can be equipped with a process for monitoring special information (for example, information for contributing to addiction countermeasures). The medalless gaming machine calculates special information in the gaming machine and transmits it to a dedicated unit (rental unit) via a terminal board for connecting a rental device such as a gaming ball.

[Calculation processing execution location (calculation subject)]
FIG. 501 is a diagram showing a simple block diagram of a medalless gaming machine.
The medalless gaming machine includes a main control board 9830 and a medal number control board 9832, and is connected to a dedicated unit 9802.
The main control board 9830 and the medal number control board 9832 can communicate with each other, and the medal number control board 9832 and the dedicated unit 9802 can communicate with each other.

The main control board 9830 can execute control processing related to the game.
The medal number control board 9832 can communicate with the main control board 9830 and the dedicated unit 9802, and can execute the insertion control process related to the insertion of game medals.

The main control board 9830 transmits information such as the number of inserted sheets, the number of paid out sheets, and game information to the medal number control board 9832.
The medal number control board 9832 calculates (generates, calculates) game machine performance information based on the information transmitted from the main control board 9830.
The medal number control board 9832 transmits the calculated gaming machine performance information to the dedicated unit 9802.
The "medal number control board" refers to a main board on which a rom equipped with a medal number control rom is mounted.

Since the game machine performance information does not affect the result of the game and is an item exclusively related to payout, the game machine performance is based on the rom (medal number control rom) specified in the technical standards shown below. Information can be calculated. The calculation process of the gaming machine performance information may be performed on the main control board 9830.

[Technical standards]
It is not possible to transmit a signal that may affect the result of the game to a machine or device outside the game machine.

The interpretation of "a signal that may affect the result of the game" shall be read as "a signal" from "function" of "a function that may affect the result of the game". However, the following (1) to (3) are excluded.
(1) A signal for transmitting the result of operating the winning, replaying, accessory, and accessory continuous operating device to the outside of the gaming machine through the terminal plate for connecting the rental device such as a gaming ball or the external terminal plate (2) The gaming ball or The result of lending the game medal is transmitted to the outside of the game machine through the game ball lending device connection end plate, and the result of inputting, firing and paying out is the game ball lending device connecting end plate or external terminal. Signal to be transmitted to the outside of the gaming machine through the board (3) Signal to transmit the result of displaying the symbol to the outside of the gaming machine through the game ball rental device connection terminal board or the external terminal board

A rom and read / write memory mounted on the main board, which sends a signal indicating the number of game medals, etc. rented or won by winning to a saucer, or rented or won by winning. It is preferable that the total number of items to be transmitted to the game ball number display device or the game medal number display device does not exceed one through all the main boards.

[Chapter S3]
[About calculation processing of gaming machine performance information (Part 2)]
The game machine performance information is illegal because it is assumed that if an abnormal value is found in the monitoring operation, it will be inspected and confirmed at the sales office (hall, etc.) where the corresponding game machine is installed. It also leads to prevention.
Regarding the "information about the role ratio monitor" in the game machine performance information, as an item related to fraud prevention, an area different from the area of use of the ROM (main control ROM) specified in the technical standards shown below (outside the area of use, Calculation processing can be performed outside the area (area other than the used area).

Since "special information" to be transmitted to the dedicated unit (rental unit) as game machine performance information is also an item related to fraud prevention, it can be calculated and processed outside the area used by the main control ROM. In this case, the conditions for the program preferably satisfy at least one of the following (1) to (9), and more preferably all of them.

(1) Programs placed outside the area of use shall be used for the purpose of calculating game machine performance information (prevention of fraud) and shall not impair the fairness of the game.
(2) For the used area and the control area and data area outside the used area, arrange them in clearly distinct areas.
(3) The program placed outside the used area shall be statically called from the program in the used area and then executed. In that case, the callee address must be clearly stated in the program list.
(4) The program should be modularized for each function and protect all the registers used in the used area when called.
(5) Access to RWMs in each other's areas from the used area or outside the used area can only be referred to, and cannot be updated.
(6) It is not possible to call a subroutine in the control area of the use area from the control area outside the use area.
(7) Do not provide a common general-purpose subroutine outside the used area.
(8) Be sure to call the module in the form of a subroutine, and after the subroutine ends, return immediately after the call by the RET instruction.
(9) There should be one module for each purpose.

FIG. 502 is a diagram showing a list of processes performed outside the used area of the main control ROM.
The contents of the processing performed outside the usage area of the main control ROM are as follows.
The process performed outside the use area of the main control ROM preferably includes at least one of the following processes, and more preferably includes all of the following processes. In addition, at least one of the following processes may be executed in the used area.
(1) Processing related to detection of foreign matter attacking the inside of the gaming machine (2) Door sensor processing (3) Random number abnormality confirmation processing (4) Set value abnormality confirmation processing (5) Main control RWM abnormality confirmation processing (6) Main control RWM backup error confirmation processing (7) Processing related to tester connection signals (8) Calculation processing of gaming machine performance information

FIG. 503 is a diagram showing a list of processes performed outside the use area of the medal number control ROM.
Each of the processes (1) to (6) shown in this figure can be implemented outside the area of use of rom (control of the number of medals) specified in the technical standards shown below.
The process performed outside the use area of the medal number control ROM preferably includes at least one of the following processes, and more preferably includes all of the following processes. In addition, at least one of the following processes may be executed in the used area.
If the processes executed by the main control ROM and the medal number control ROM overlap, they can be executed by either ROM. The conditions for the program are the same as the above conditions.

(1) Processing related to detection of foreign matter attacking the inside of the gaming machine (2) Door sensor processing (3) Medal number control RWM abnormality confirmation processing (4) Medal number control RWM backup abnormality confirmation processing (5) Testing machine connection signal Processing related to (6) Calculation processing of gaming machine performance information

[Technical standards]
(1) In the control area (the storage area of the ROM or read / write memory in which information other than the information necessary for preventing unauthorized modification or other changes is stored or is to be stored). Of which, the data area is divided into a data area (a storage area other than the data area (a storage area in which only information other than the program is stored or will be stored)) and a data area. It is preferable to have.

(2) The capacity of the control area of the rom (excluding the one in (3) below) related to the revolving pachinko machine does not exceed 4.5 KB, and the capacity of the data area does not exceed 3 KB. It is preferable that it is a thing.

(3) Rom and read / write memory mounted on the main board, and the number of game medals, etc. rented out or won by winning is sent to the saucer, or lent out or won by winning. It is preferable that the total number of signals to be transmitted to the game ball number display device or the game medal number display device does not exceed one through all the main boards.

[Chapter S4]
[About the processing method to invalidate the count button]
FIG. 504 is a diagram showing a block diagram including a counting button.
The game machine 9800 (medalless game machine) includes a medal number control board 9832, a game ball rental device connection terminal board 9834, a counting button 9836 (counting switch), and a game medal number display device 9838.
The medal number control board 9832 and the dedicated unit 9802 (rental unit, external unit) are connected by a VL power supply connection line. The connection line of the VL power supply may or may not pass through the game ball or the like rental device connection terminal plate 9834.

In the game machine 9800 equipped with the game medal number display device 9838, the dedicated unit aims to prevent troubles such as loss of game medals when the counting button 9863 is operated while the dedicated unit 9802 is not normally connected. If it cannot be confirmed that the device is connected to the 9802, the count button can be disabled on the main board (medal number control board 9832 or main control board).

FIG. 505 is a flowchart showing a processing procedure for disabling the counting button.
The CPU of the medal number control board 9832 confirms whether or not it recognizes the VL power supply (whether or not VL = ON) (S8000), and when it recognizes the VL power supply (S8000; Yes). , It is confirmed whether or not the counting button is pressed (S8001), and if the counting button is pressed (S8001; Yes), the counting process (processing related to the number of game medals) is executed (S8002).

[Related technical standards]
(1) The player must have the ability to freely transmit a signal indicating the number of recorded game medals.
(2) "Can be freely transmitted" means that at any time, at the player's will, a signal indicating the number of all or part of the recorded game medals can be freely transmitted. Being able to send.

[Chapter S5]
[About game machines equipped with a game medal number display device (medalless game machines)]
[Prerequisites]
The "dedicated unit" refers to a device for renting the number of game balls, etc., which can receive the number of game medals transmitted from the medalless game machine.
The “counting process” means transmitting the number of game medals recorded on the game medal number display device to the dedicated unit.
The "main control board" means a board on which a rom and a read / write memory are mounted.
The "medal number control board" refers to a board on which a rom and a read / write memory are mounted for the purpose of managing a game medal number display device and performing counting processing.

FIG. 506 is a diagram showing a block diagram of a gaming machine (medalless gaming machine) on which a medal number control board is mounted.
The gaming machine (medalless gaming machine) includes a main control board 9830, a medal number control board 9832, and a game ball rental device connection terminal board 9834.
The medal number control board 9832 and the dedicated unit 9802 are connected by a connection line of a VL power supply. The connection line of the VL power supply and other communication lines may or may not pass through the game ball or the like rental device connection terminal board 9834.

The main control board 9830 includes a main control rom 9831 (main control CPU).
The medal number control board 9832 includes a medal number control rom 9833 (medal number control CPU).
The main control rom 9831 and the medal number control rom 9833 can communicate with each other by "communication between main control and medal number control".
The medal number control rom 9833 and the dedicated unit 9802 can communicate with each other by "medal number control-communication between dedicated units".

Information (signals) from the clearing button 9841, the start lever 9842, the stop button 9843 (three), and the game medal insertion button 9844 (1 bet, MAX bet) is input to the main control rom 9831.
The information (signal) from the counting button 9836 is input to the medal number control rom 9833.

The main control rom 9831 transmits information for controlling lighting / extinguishing of the game medal insertion display LED 9839 on the sub-board 9840 (effect control board, production control device, etc.) based on the information from the game medal insertion button 9844 and the like. ..

The medal number control rom 9833 transmits information for controlling the display content of the game medal number display device 9838 on the sub-board 9840 based on the information from the main control rom 9831, the counting button 9836, the dedicated unit 9802, and the like.
"VL" is a power supply supplied from a dedicated unit.

[How to check the connection between the gaming machine and the dedicated unit]
The method of confirming that the gaming machine (medalless gaming machine) and the dedicated unit are not connected can be performed when any of the following is detected.
(A) When VL is OFF (b) When there is no command (for example, lending notification command) sent from the dedicated unit for a certain period of time When it cannot be confirmed that the gaming machine and the dedicated unit are connected, the gaming machine Can be in an error state.

[About inserting game medals when the dedicated unit is not connected]
If it cannot be confirmed that the gaming machine and the dedicated unit are connected, the main control board can perform a process of disabling the insertion of game medals. Even if it cannot be confirmed that the gaming machine and the dedicated unit are connected, a process that enables the insertion of game medals by the main control board may be performed.
In the case of a gaming machine equipped with a medal number control board, a process is performed in which a signal that the dedicated unit is not connected is transmitted from the medal number control board to the main control board so that the main control board cannot insert the game medal. It can be carried out.
If it cannot be confirmed that the gaming machine and the dedicated unit are connected, counting processing cannot be performed, so the game cannot be played until it can be confirmed that the dedicated unit can be connected normally (the game cannot be played). )can do.

[Other processing during counting processing]
When the counting process is performed, the following process can be performed by the main control board. In the gaming machine equipped with the medal number control board, the signal during the counting process is transmitted from the medal number control board to the main control board, and the main control board performs the following processes (a) to (d). It can be performed. The following processes (a) to (d) may be performed by at least one process, preferably a plurality of processes, and more preferably all processes.

(A) If the counting process is performed while the game medals can be inserted, the game medals cannot be inserted.
(B) When the rotating cylinder rotation operating device is operable and the counting process is performed, the start lever is invalidated. In addition, in the whole specification, "reel" means "reel". Further, the "rotating cylinder rotation operating device" is a "start lever". "The rotating cylinder rotation operating device can be operated" means that a specified number of medals required for the game has been inserted.
(C) If the counting process is performed during the rotation of the rotating cylinder, the stop button is invalidated.
Since it is not necessary for the player to play the game during the counting process, it is possible to prevent an unexpected irregular process from occurring by blocking unnecessary interrupt processing.
(D) It is possible to invalidate the payout of game medals based on the winning of a role with a payout such as a small role and the insertion of a specified number of game medals required for the next game based on the winning (display) of a replay role or the like. ..

[About counting processing in a specific state]
Whether or not the main control board is in a state where counting processing can be performed (a state in which the counting button is valid) may be arbitrary as long as it is predetermined in the following states.
In a gaming machine equipped with a medal number control board, a signal for disabling counting processing is transmitted from the main control board to the medal number control board, and the medal number control board performs processing for disabling counting processing. Can be done.

(A) The counting process is invalidated when the specified number of game medals have been inserted into the game machine.
(B) The counting process is invalidated between the time when the rotating cylinder rotation operating device is activated and the time when the next game medal can be inserted.
(C) The counting process is invalidated while the game cannot be performed due to the error state defined by the main board (including the main control board and the medal number control board).
As a result, it is possible to prevent an unexpected irregular process from occurring while the player is playing a game and when the game is not possible.

[Related rules, etc.]
(1) The player must have the ability to freely transmit a signal indicating the number of recorded game medals.
(2) "Can be freely transmitted" means that at any time, at the player's will, a signal indicating the number of all or part of the recorded game medals is free. Must be able to be sent to.

[Regarding game medal insertion processing on the medal number control board]
FIG. 507 is a diagram showing a block diagram of a gaming machine (medalless gaming machine) equipped with a medal number control board capable of executing a game medal insertion process.
The difference from FIG. 506 is that the information (signal) from the game medal insertion button 9844 is input to the medal number control rom 9833, and the medal number control rom 9833 controls the game medal insertion display LED 9838 based on this information. It is a point to do. Since the other configurations are the same, the description thereof will be omitted.
By adopting such a configuration, the following processing can be performed on the medal number control board (medal number control rom).
(A) Controls related to acceptance of the game medal insertion button (b) Controls related to the insertion of game medals by subtracting the number of game medals recorded on the game medal number display device. Since it is possible to control the game medal number display device, it is also possible to perform a process of inserting a game medal from the game medal number display device.

The game medal insertion button enables the insertion of game medals.
The game medal number display device can record the number of game medals and can display the number of recorded game medals.
When the operation of the game medal insertion button is detected as the insertion control process, the medal number control board subtracts the number of game medals recorded on the game medal number display device and inserts the subtracted number of game medals. Make the process executable.

[Chapter S6]
FIG. 508 is a diagram showing a communication timing chart between the medalless gaming machine and the dedicated unit.
The medalless gaming machine notifies the dedicated unit of the next gaming machine information notification within the first hour T1 (for example, in the range of 300 ms or more and 310 ms or less) from the start of the gaming machine information notification.
The medalless gaming machine notifies the dedicated unit of the counting notification within the second time T2 (for example, in the range of 90 ms or more and 100 ms or less) from the start of the gaming machine information notification.
The dedicated unit notifies the medalless gaming machine of the loan notification within T3 (for example, within 170 ms) of the third hour after receiving the counting notification.
After receiving the loan notification, the medalless gaming machine notifies the dedicated unit of the loan receipt result response within the fourth hour T4 (for example, within 10 ms).
The time TB is the time for transmitting one telegram.

The above-described embodiment of the medalless gaming machine includes at least two technical features shown below.
(T1) Insertion control using the medal number control board (T2) Transmission of the number of inserted and paid out numbers without and with replay to the dedicated unit The technical features will be described below. The issues and effects described in the following technical features are only secondary issues, and the main issues and effects are "providing innovative gaming machines". In addition, the following technical features can be applied not only to medalless gaming machines but also to pachinko machines.

[(T1) Insertion control with the medal number control board]
An issue of this technical feature is to reduce the capacity used by the main control board in a medalless gaming machine.

The technical features are as follows.
In addition to the main control board 9830, a medal number control board 9832 is provided, and the medal number control board 9832 performs insertion control (see FIG. 507).
The contents of the input control are as follows.
(A) Control related to acceptance of the game medal insertion button 9844.
(B) The number of game medals recorded on the game medal number display device 9840 is subtracted, and control related to the insertion of game medals (for example, a process of lighting the game medal insertion display LED 9839 according to the number of bets) is performed.

According to this technical feature, it is possible to reduce the capacity used by the main control board in a medalless gaming machine.

[(T2) Send the number of input and payouts without replay and with replay to the dedicated unit]
The problem of this technical feature is to enable the hall computer and the outside of the hall (various centers) to appropriately monitor the exiting coastal information.

The technical features are as follows.
As the gaming machine performance information in the gaming machine information, the number of replay-excluded inputs (total number of inputs) and the number of replays without replays (total number of payouts) are transmitted to the dedicated unit (sand) (see FIG. 460).
In addition, as the hall control / fraud monitoring information (“game information” in the game machine information), the specified number (IN: the number of input including replay) and the number of payouts (OUT: the number of payout including replay) are dedicated units ( It is transmitted to (sand) (treated as external signals CN2-1 (IN signal) and CN2-2 (OUT signal). See FIG. 478).
Further, the number of inserted medals and the number of paid medals are transmitted to the dedicated unit (sand) as the hall control / fraud monitoring coastal information of the gaming machine information (see FIG. 468). However, the number of inserted medals and the number of paid medals are not treated as external signals CN2-1 and CN2-2.

According to this technical feature, it is possible to appropriately monitor the exit information at the hall computer and outside the hall (various centers).

[Transformed form]
The managed gaming machine or the medalless gaming machine can be modified as follows. The following contents can be applied to the above-mentioned managed gaming machines, and can also be applied to medalless gaming machines.
The following modified forms can be applied to both managed gaming machines and medalless gaming machines within a consistent range. In the following description of the modified form, when the description is intended only for the managed gaming machine, in principle, it is the modified form intended only for the managed gaming machine. However, even if the description is intended only for managed gaming machines, the content of the modified form is established even if "game ball" is read as "game medal" and "frame control board" is read as "medal number control board". If so, it can also be applied to medalless gaming machines.

[About the performance of the display device such as the number of game balls]
In a gaming machine (managed gaming machine or medalless gaming machine) equipped with a display device such as the number of gaming balls, the player presses the counting button under special circumstances such as when the dedicated knit is not connected or the dedicated unit is not turned on. If a signal indicating the number of all or part of the number of game balls (game medals) recorded by pressing is freely transmitted, the number of stored game balls may be lost. There is. In order to avoid such a case, the player cannot press the count button when the connection confirmation power supply (VL) is not supplied from the dedicated unit or when the dedicated unit is not connected. Technical means can be provided. Therefore, "at any time, at the player's will, a signal indicating the number of all or part of the recorded number of game balls can be freely transmitted." The interpretation is only a principle, and it can be interpreted that this is not the case as an exception when the connection confirmation power supply (VL) is not supplied from the dedicated unit or when it is not connected to the dedicated unit. ..

In the management gaming machine, the counting switch power supply supplied to the board on which the counting switch is mounted can be turned ON or OFF as a result of monitoring the connection confirmation power supply (VL).
The player can visually confirm the number of recorded game balls on the display device such as the number of game balls. By pressing the counting switch, the recorded number of gaming balls is transmitted from the gaming machine to the dedicated unit. At this time, the dedicated unit counts the number of gaming balls due to a communication accident between the gaming machine and the dedicated unit. It is assumed that it cannot be received. If the dedicated unit cannot receive the number of game balls, the number of game balls displayed on the display device such as the number of game balls and the number of game balls additionally displayed on the dedicated unit cannot be matched, and the hall operator and the hall operator Since troubles may occur with the player, the above technical means are means for avoiding such problems.

[Capacitors mounted on terminal boards for rental devices such as game balls]
Horizontally mounted capacitors, three-terminal regulators, etc. can be used for main boards, gaming machine terminal boards, or gaming boards as long as they meet the following technical standards.

[Technical standards, etc.]
The “game machine terminal board” refers to a board on which only electronic components for connecting wiring to each other are mounted.
"Electronic components for connecting wiring to each other" includes electronic components having functions necessary for eliminating noise and connecting wiring to each other (however, those having functions other than the functions are excluded. ).
"Electronic components for connecting wiring to each other" refers to operations other than signal inflow and outflow control depending on the performance of the electronic components among connectors, fuses, photocouplers, relays, resistors, varistor, diodes, and filters. Understand that it is not used for.
The "game ball rental device connection terminal board" is a wiring between a machine or device and a game machine that transmits a signal for renting a game medal or a game ball outside the game machine among the game machine terminal boards. It is for connecting to the wiring inside the gaming machine.

The managed gaming machine or the medalless gaming machine can be modified as follows.
(1) Asynchronous serial that is common to machines or devices outside the game machine from the frame control board via the game ball rental device connection terminal board, for rental signals, counting signals, and game machine information signals. Communication may be performed using the communication port.

(2) The game ball information and the game machine information are separated from the frame control board to the machine or device outside the game machine via the game ball rental device connection terminal plate, and the signal and the counting related to the rental are related. The signal can be divided into an asynchronous serial communication port different from the signal related to the gaming machine information.
The signal related to lending and the signal related to counting may be communicated with a common asynchronous serial communication port.

(3) Two-way communication and one-way communication are classified from the frame control board to the machine or device outside the game machine via the game ball rental device connection terminal plate, and the signal related to rental is counted. The signal and the signal related to the gaming machine information can be separated into different asynchronous serial communication ports.
The signal related to counting and the signal related to game machine information may be communicated by a common asynchronous serial communication port.

(4) The following contents may be displayed on the 7-segment display used in the performance display monitor or the role ratio monitor.
(I) Game machine performance information (ii) Number of game balls recorded and displayed on the game ball number display device (iii) Error code

(5) A switch for clearing the RWM area in which the "number of game balls" is recorded may be mounted on the frame control board. In addition, in order to clearly know that the number of gaming balls has been cleared using this switch, it is possible to notify by voice or the like and output an illegal information signal to a machine or device outside the gaming machine in the same way as when an illegality is detected. it can.

(6) In addition to the number of game balls (number of game medals) recorded on the 7-segment display used as the game ball number display device, an error code may be displayed. Regarding the display, the number of game balls is always displayed in the normal state, but the number of game balls (number of game medals) and the error code can be displayed alternately only when an error occurs.

(7) Game ball lending device When a machine or device that transmits a signal for lending a game ball, game medal, etc. is not connected to the connection terminal board (when a dedicated unit is not connected), a launching device May be stopped or the game may be infeasible.

(8) Communication method between the managed gaming machine and a machine or device outside the gaming machine In the managed gaming machine, the total number of gaming balls that the player can launch on the frame control board (hereinafter referred to as "the number of gaming balls"). ) Is recorded by an electromagnetic method, but the number of rented game balls, the counting information of the number of game balls displayed on the "game ball number display device", and the game machine information such as performance information and game status are communicated with the dedicated unit. Therefore, the following configuration can be adopted.

[Types of signals sent and received by gaming machines]
(I) Signal related to lending Receives the number of lending balls and the lending serial number for communication management, and transmits the lending ball number receipt result and the lending serial number in order to respond to the reception result (two-way communication).
Dedicated unit → Frame control board Dedicated unit ← Frame control board

(Ii) Signal related to counting The number of counting balls and the counting serial number for communication management are transmitted.
The signal for confirming the transmission result is not received (unidirectional communication).
Dedicated unit ← Frame control board

(Iii) Signals related to gaming machine information Transmission of gaming machine installation information, gaming machine performance information, external output signal output from the external terminal board of the dedicated unit, the number of gaming balls, and the serial number of the number of gaming balls for communication management. To do.
The signal for confirming the transmission result is not received (unidirectional communication).
Dedicated unit ← Frame control board

In managed gaming machines, the amount of communication information is larger than that of conventional gaming machines, and communication security is enhanced. Therefore, we stopped adopting the conventional method in which one wiring has one meaning, and multiple information in one wiring. It is possible to adopt a telegram communication method for transmitting information.

FIG. 509 is a diagram showing the types of signals.
(1) Signal related to lending [No1]
Direction: Dedicated unit → Frame control board Signal name: Number of rented balls, rented serial number Contents: Number of game balls related to rent, serial number of communication related to rent Purpose: A

[No2]
Direction: Frame control board → Dedicated unit Signal name: Number of rented balls Received result, rental serial number Contents: Number of rented balls received result, serial number of communication related to lending Purpose: A

(2) Signal related to counting [No1]
Direction: Frame control board → Dedicated unit Signal name: Number of counting balls, counting serial number Contents: Number of counting balls, serial number of communication related to counting Purpose: B

(3) Signal related to gaming machine information [No1]
Direction: Frame control board → Dedicated unit Signal name: Game machine installation information Contents: Main / frame control CPU manufacturer code, model code, chip ID number Purpose: C

[No2]
Direction: Frame control board → Dedicated unit Signal name: Game machine performance information Contents: Number of game balls acquired per minute (low base), bonus ratio, continuous bonus ratio, etc. Purpose: D

[No3]
Direction: Frame control board → Dedicated unit Signal name: Hallcon information Contents: Big hit, probability fluctuation, time reduction, number of winning balls in each winning opening, etc. Purpose: E

[No4]
Direction: Frame control board → Dedicated unit Signal name: Illegal monitoring information Contents: Number of game balls (current number of balls), number of game balls Serial number Purpose: F

In addition, the contents of the purpose are A: Lending of game balls, B: Counting of game balls, C: Machine history management, D: Aggregation of performance information, E: Aggregation of information of Hallcon, F: Fraud monitoring by dedicated unit. is there.

FIG. 510 is a diagram showing a configuration of a communication port.
As the configuration of the communication port, any of the configurations (A), (B), and (C) in the figure can be adopted. Note that (1) to (3) in the figure correspond to (1) to (3) in FIG. 509.

As shown in (A) in the figure, signals and counting related to lending from the frame control board 550 to the dedicated unit 700 (machine or device outside the game machine) via the game ball or the like lending device connection terminal plate. Communicate signals and signals related to gaming machine information through a common asynchronous serial communication port.

Specifically, [No2] of (1), [No1] of (2), and [No1] to [No4] of (3) are transmitted from the frame control board 550 to the dedicated unit 700 by asynchronous serial communication. To do. [No. 1] of (1) is transmitted from the dedicated unit 700 to the frame control board 550 by asynchronous serial communication.

As shown in (B) in the figure, the information of the game ball and the information of the game machine are separated from the frame control board 550 to the dedicated unit 700 via the game ball rental device connection terminal plate, and the signal related to the rental. And the signal related to counting is divided into an asynchronous serial communication port different from the signal related to game machine information.
The signal related to lending and the signal related to counting are communicated by a common asynchronous serial communication port.

Specifically, [No. 1] of (1) is transmitted from the dedicated unit 700 to the frame control board 550 by asynchronous serial communication. [No. 2] of (1) and [No. 1] of (2) are transmitted from the frame control board 550 to the dedicated unit 700 by asynchronous serial communication. In this case, a port that shares (1) a signal related to lending and (2) a signal related to counting is used.
[No. 1] to [No. 4] of (3) are transmitted from the frame control board 550 to the dedicated unit 700 by asynchronous serial communication. In this case, (3) the signal port related to the gaming machine information is used.

As shown in (C) in the figure, bidirectional communication and one-way communication are separated from the frame control board 550 to the dedicated unit 700 via the game ball rental device connection terminal plate, and the signal related to rental and the signal related to rental. Separate the asynchronous serial communication port from the signal related to the game machine information.
The signal related to counting and the signal related to game machine information are communicated by a common asynchronous serial communication port.

Specifically, [No. 1] of (1) is transmitted from the dedicated unit 700 to the frame control board 550 by asynchronous serial communication. [No. 2] of (1) is transmitted from the frame control board 550 to the dedicated unit 700 by asynchronous serial communication. In this case, (1) the signal port related to lending is used.
[No1] of (2) and [No1] to [No4] of (3) are transmitted from the frame control board 550 to the dedicated unit 700 by asynchronous serial communication. In this case, a port that shares (2) a signal related to counting and (3) a signal related to gaming machine information is used.

(9) In the managed gaming machine, the total number of gaming balls that the player can launch on the frame control board (hereinafter referred to as "the number of gaming balls") is recorded by an electromagnetic method, but the number of rented gaming balls is recorded. , It is necessary to communicate the counting information of the number of game balls and the play branch machine information such as the performance information and the game state displayed on the "game ball number display device" with the dedicated unit.
However, when the counting information and the gaming machine information cannot be communicated (not connected and no response), it is preferable to stop the launching device and limit the game because it is affected by the following.
Regarding the counting information, if it takes time to recover while the game continues after communication is lost, there is a big difference between the number of game balls recorded by the gaming machine and the number of gaming balls recorded by the dedicated unit. If it may occur, and as a result, it becomes impossible to judge whether or not the number of gaming balls is normal, or if it takes time to recover while the game continues after communication is not possible in the gaming machine information. Since the playground machine information stored in the RWM of the frame control board is limited, the information exceeding the upper limit may be lost.

Therefore, the launching device may be stopped or the game may be stopped when the dedicated unit is not connected to the rental device connection terminal plate for the game ball or the like.
The control for stopping the launching device when the dedicated unit is not connected to the terminal board for renting a game ball or the like is as follows.

[Control to stop the launcher]
The frame control board monitors the power supply (VL) for connection confirmation supplied from the dedicated unit, and when the VL is not supplied, determines that the connection is not established and stops the launching device.

FIG. 511 is a diagram showing a communication timing chart when a dedicated unit is not connected to a terminal board for renting a game ball or the like.
(I) When the game ball can be rented, the dedicated unit 700 transmits a preparation signal related to the rent at a cycle of 300 ms. Further, when the lending switch (lending button) is pressed within the cycle of 300 ms, the lending signal is transmitted with the number of lending balls set to 125.

(Ii) The frame control board 550 transmits a preparation signal related to lending and a reception result response of the signal related to lending within 10 ms.
(Iii) The frame control board 550 transmits a signal related to counting 100 ms after receiving a preparation signal related to lending and a signal related to lending. Further, when the counting switch is pressed within the cycle of 300 ms, the number of counting balls is set to 250 and the signal related to counting is transmitted.

(Iv) The frame control board 550 transmits a signal related to the gaming machine information 200 ms after receiving the preparation signal related to the rental and the signal related to the rental.
(V) After that, the same operation is repeated in a cycle of 300 ms.

(Vi) Unconnected such as disconnection of the dedicated cable occurs. In this case, since VL is not supplied, the frame control board 550 determines that a non-connection has occurred and stops firing. In addition, the transmission of the reception result response of the lending preparation signal and the lending signal, the counting signal, and the game machine information signal is stopped.

521 to 515 are diagrams showing the operation after error and fraud detection.
In the managed gaming machine (main control or frame control) and the medalless gaming machine (main control or medal number control), the following processes can be executed.
The processes related to [No1] to [No5] can be executed in the area, and the processes related to [No6] to [No23] can be executed outside the area. Further, the error code may be set so that skip numbers do not occur (for example, H01, H02, H03, etc.).

In the figure, "○" means "detect by frame control and require notification or function stop", and "□" means "notify main control after detection by frame control and notify or stop function". "Mandatory" means "essential", "◎" means "mandatory detection and notification or function stop by main control", and "△" means "detection and notification or function by main control". It is recommended to stop. " In a medalless gaming machine, "frame control" and "managed gaming machine frame (game machine frame)" can be read as "main control or medal number control", and "ball" can be read as "medal".

[Fig. 512]
[No1]
Error code: H04
Error name: Dedicated cable disconnection error and fraud detection Details: Detected that the dedicated unit and the management gaming machine frame are not connected.

[Operation after error and fraud detection]
Voice output of notification of game machine frame:-
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing of pachinko machine frame function stop: ○
Stop counting the number of outages of the gaming machine frame: ○

Audio output of game board notification:-
Liquid crystal display (LCD) for notification of the game board:-
Illuminations (LED) for notification of the game board:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: L (Low)
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No2]
Error code: H05
Error name: No response for communication between the management game machine and dedicated unit Error and fraud detection Details: No response for communication between the dedicated unit and the management game machine frame was detected.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing of pachinko machine frame function stop: ○
Stop counting the number of outages of the gaming machine frame: ○

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H (High)
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No3]
Error code: H06
Error name: Communication error in the management game machine Error and fraud detection content: Communication between the management game machine game board and the management game machine frame No response or no connection was detected.

[Operation after error and fraud detection]
Voice output of notification of game machine frame:-
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification: ◎
LCD production of game board notification: ◎
Illuminations of the game board notification: ◎
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[Fig. 513]
[No4]
Error code: H14
Error name: Subtraction mechanism entrance sensor (subtraction sensor) Abnormal error and fraud detection Details: When the subtraction mechanism entrance sensor detects ball clogging or the subtraction mechanism entrance sensor has detected a failure.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing of pachinko machine frame function stop: ○
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No5]
Error code: H23
Error name: Game ball number exceeded Error and fraud detection content: Game ball exceeded 40,000 balls

[Operation after error and fraud detection]
Voice output of notification of game machine frame:-
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification: □
LCD production of game board notification: □
Illuminations of the game board notification: □
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No6]
Error code: H16
Error name: Abnormality in ball polishing device Error and fraud detection Details: Detected that the polishing motor does not rotate

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No7]
Error code: H17
Error name: Game ball circulation device error Error and fraud detection content: Detected that the lifting motor does not rotate

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No8]
Error code: H18
Error name: Abnormal discharge ball passage Error and fraud detection Details: Ball clogging was detected between the discharge ball passage and the ball polishing device.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No9]
Error code: H19
Error name: Winning ball passage abnormality Error and fraud detection Details: Ball clogging was detected from the winning ball passage with a ball polishing device.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No10]
Error code: H20
Error name: Ball polishing device passage abnormality Error and fraud detection Details: Ball clogging was detected in the ball polishing device.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No11]
Error code: H21
Error name: Game ball circulation device passage error Error and fraud detection Details: Ball clogging was detected in the game ball circulation device.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No12]
Error code: H22
Error name: Cassette not installed Error and fraud detection Details: Detected that the ball polishing device is not installed in the cassette

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[Fig. 514]
[No13]
Error code: H24
Error name: Insufficient number of circulating balls Error and fraud detection Details: Insufficient number of circulating balls detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No14]
Error code: H25
Error name: Excessive number of circulating balls Error and fraud detection Details: Excessive number of circulating balls detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No15]
Error code: H26
Error name: Proximity sensor error of management game machine frame Error and fraud detection content: Winning passage counter sensor (winning sensor), non-winning passage counter sensor (non-winning sensor), ball clogging sensor, polishing entrance sensor or lifting entrance sensor Abnormality detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output: ○
Hallcon fraudulent information output:-

[No16]
Error code: H64
Error name: Front decoration release Error and fraud detection Details: Front decoration release detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame:-
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification: ◎
LCD production of game board notification: ◎
Illuminations of the game board notification: ◎
Stop firing of pachinko machine frame function stop: ◎

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output:-
Illegal information output of Hallcon: ○

[No17]
Error code: H65
Error name: Back mechanism opening Error and fraud detection Details: Back mechanism opening detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame:-
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification: ◎
LCD production of game board notification: ◎
Illuminations of the game board notification: ◎
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output:-
Illegal information output of Hallcon: ○

[No18]
Error code: H66
Error name: Illegal radio wave detection Error and fraud detection content: Abnormal radio wave was detected in the management game machine frame

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid: ○
Hallcon error information output:-
Illegal information output of Hallcon: ○

[No19]
Error code: H67
Error name: Clear game ball number Error and fraud detection Details: Clear game ball number detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid:-
Dedicated unit card return button invalid:-
Hallcon error information output:-
Illegal information output of Hallcon: ○

[No20]
Error code: H68
Error name: Abnormal number of winning balls 1
Error and fraud detection details: The difference between the number of winning balls detected by the main control board and the number of winning balls detected by the frame control board is 100 or more.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid: ○
Hallcon error information output:-
Illegal information output of Hallcon: ○

[Fig. 515]
[No21]
Error code: H69
Error name: Abnormal number of winning balls 2
Error and fraud detection details: The difference between the number of launched balls and the total number of returned balls (winning passage count sensor + non-winning passage count sensor) is 100 or more.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid: ○
Hallcon error information output:-
Illegal information output of Hallcon: ○

[No22]
Error code: H85
Error name: Small ball detection Error and fraud detection Details: Small ball detection A ball of 10.7 mm or less was detected.

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid: ○
Hallcon error information output:-
Illegal information output of Hallcon: ○

[No23]
Error code: H86
Error name: Iron ball detection Error and fraud detection Details: Iron ball detected

[Operation after error and fraud detection]
Voice output of notification of game machine frame: ○
Display device for the number of game balls, etc. for notification of the game machine frame: ○
Stop firing the stop function of the gaming machine frame:-
Stop counting the number of outages of the gaming machine frame:-

Audio output of game board notification:-
LCD production of game board notification:-
Illuminations of the game board notification:-
Stop firing the stop function of the gaming machine frame:-

Dedicated unit VL: H
Ball lending button of dedicated unit invalid: ○
Dedicated unit card return button invalid: ○
Hallcon error information output:-
Illegal information output of Hallcon: ○

[Tests for managed and medalless pachinko and pachislot machines]
〔Required specifications〕
During the test firing test, it is preferable that artificial operations (rental, counting) are the minimum necessary.
If a sufficient number can be displayed on the game ball (medal) number display device, no artificial operation may be necessary.

[Technical means]
[Management game machine]
In the managed gaming machine, the upper limit of the number of gaming balls (hereinafter, referred to as “the number of balls held”) recorded on the display device such as the number of gaming balls by an electromagnetic method can be up to 990,000. In addition, when the value of the number of balls held reaches 40,000, the error state of the gaming machine is set, and the player is notified that the gaming balls recorded on the display device such as the number of gaming balls are settled (counted). The peripheral board notifies the voice and outputs an error status signal to the machines and devices outside the gaming machine, but the game is not stopped. Therefore, when the test firing test of game balls is performed for 10 hours, the number of launched game balls (60,000) for 10 hours is recorded on the display device such as the number of game balls at the start of the test, and the upper limit value even if the test firing test is performed. Never reach. In addition, the method of suppressing the error that occurs when the number of balls held reaches 40,000 is to check the signal of the number of balls held from the gaming machine and "automatically lend when approaching 0". "A function to perform counting" or "a function to automatically count when the upper limit (40,000 pieces) is approached" is required.

[Medalless pachinko machine]
Since the maximum number of medals that can be displayed on the game medal number display device is 16,383, even if the maximum number of medals is lent out in a lump at the start of the test, the number of medals will be insufficient in the 17,500 (52,500) test. there is a possibility. Therefore, in this case, human operation is required.

〔Required specifications〕
In the game ball (medal) number display device, depending on the number that can be displayed, when it approaches 0 or the upper limit, the output of the "game machine error status signal (managed game machine: input request lamp signal) is stopped (medalless game machine). May be required. As a result, an artificial operation is performed.
In the game ball (medal) number display device, depending on the number that can be displayed, "a function that automatically lends when approaching 0" or "a function that automatically counts when approaching the upper limit" is required. There is a possibility of becoming.

[Technical means]
[Medalless pachinko machine]
By manufacturing a "test unit" that has "a function to automatically lend when approaching 0" and "a function to automatically count when approaching the upper limit", no human operation is required. can do.

[Clearing process for medalless pachinko machines]
When a plurality of RWMs (RAMs) are provided in the medalless gaming machine, the RWMs (RAMs) to be cleared may be different depending on the state at the time of recovery from power failure.
In the medalless gaming machine, the number of gaming medals may not be cleared by changing the setting or clearing the RAM.
In the medalless gaming machine, the gaming machine performance information may be cleared when the number of gaming medals is cleared.
In the medalless gaming machine, when the setting is changed or the RAM is cleared, the inserted medals may be cleared but the number of game medals may not be cleared.
In a medalless gaming machine, when the number of game medals is cleared, the number of game medals may be cleared but the number of inserted medals may not be cleared.
In the medalless gaming machine, when clearing the number of game medals, the status of clearing the number of game medals may be set to ON and the ON state may be maintained until the end of one game.

[Backup power supply for main control board]
The medal number control board may be equipped with its own backup power supply (battery) and a backup power supply for the main control board.
One board (medal number control board or other board) other than the main control board may be equipped with a power supply for backing up both the main control board and the medal number control board.
A backup power supply (battery) of its own may be mounted on the medal number control board, and a backup power supply for the main control board may be mounted on another board (for example, a board that controls a reel).

[What to do if the gaming machine starts before the dedicated unit]
Until the VL is turned on when the gaming machine is started before the dedicated unit, various "notifications" are periodically transmitted to the dedicated unit from the time when the gaming machine is started. However, the control method may be changed so that the gaming machine monitors the VL and does not send various "notifications" until the VL is turned on.
If the gaming machine and the dedicated unit are not in two-way communication, it is okay for the gaming machine to check the VL, but there is a problem that the signal from the dedicated unit triggers the gaming machine to perform some action. is there. Therefore, the gaming machine cannot start transmitting various "notifications" by receiving the activation completion signal from the dedicated unit. Therefore, the gaming machine needs to operate independently without depending on the signal from the dedicated unit. If there is a premise that it is not two-way communication, the gaming machine will return the response result to the lending notification from the dedicated unit side, but there will be no response to the counting notification sent by the gaming machine side. Become.

[Correspondence when the transmission timing of multiple gaming machine information notifications is the same]
The correspondence when the three cycles overlap can be as follows.
Three signals, such as priority 1 gaming machine installation information (60S), priority 2 gaming machine performance information (180S), and priority 3 hall control / fraud monitoring information (300ms), are transmitted at the same timing. May arrive.

In this case, any of the following control methods (a) to (c) can be adopted.
(A) Just send according to the priority. As a result, the gaming machine installation information is transmitted, then the gaming machine performance information is transmitted after the lapse of 300 ms, and the hall controller / fraud monitoring information is transmitted after the lapse of the next 300 ms. That is, the hall control / fraud monitoring information is transmitted with a delay of two cycles. In this case, the hall control / fraud monitoring information is not sent once in 600 times for a time close to 900 ms.

(B) Although the priority order is followed, the transmission cycles of priority order 1 and 2 are shifted from the middle. The gaming machine installation information is transmitted, and then the gaming machine performance information is transmitted after a lapse of 300 ms. The transmission cycle of the gaming machine performance information is set to every 60S from the transmission timing thereafter. As a result, the transmission timing of the gaming machine installation information and the gaming machine performance information does not occur at the same timing thereafter. As a result, although it may occur that the gaming machine installation information and the hall control / fraud monitoring information are at the same timing, and the gaming machine performance information and the hall control / fraud monitoring information are at the same timing, the hall control / fraud monitoring information The delay is only one cycle at the maximum.

(C) In the first place, a control method in which the transmission cycles of priority order 1 and 2 are shifted by 300 ms from the beginning is also conceivable. However, processing and timers for shifting the initial transmission cycle may be required. A method of shifting all transmission cycles of priorities 1, 2, and 3 is also conceivable.

1 Pachinko machine 8 Game board unit 8a Game area 20 Start gate 28 Variable start winning device 33 Normal symbol display device 33a Normal symbol operation memory lamp 34 1st special symbol display device 35 2nd special symbol display device 34a 1st special symbol operation memory Lamp 35a Second special symbol operation memory lamp 38 Game status display device 42 Liquid crystal display 45 Effect switching button 70 Main control device 72 Main control CPU
74 ROM
76 RAM
124 Production control device 126 Production control CPU
500 Management game machine 9800 Medalless game machine

Claims (1)

Main control board and
A frame control board capable of communicating with the main control board and an external unit is provided.
The frame control board is
A gaming machine characterized in that different information is transmitted to the external unit at different cycles, and when the cycles overlap, high-priority information is transmitted.

Images