JP2019069211A - Game machine - Google Patents

Abstract

To provide a game machine capable of smoothly executing a game.SOLUTION: A slot machine includes: a start lever for triggering to start rotation of respective reels, and stop buttons for triggering to stop the respective rotating reels. Further, a main-side MPU 142 includes a control IC 148 for executing a lottery on the condition that the start lever is operated. When the start lever is operated, the control IC 148 executes processing of starting rotation of the respective reels and, when the stop buttons are operated, executes processing of stopping rotation of the respective reels in a mode corresponding to a lottery result. When the start lever is operated, even if the lottery is not completed, the control IC 148 starts rotation of the respective reels.SELECTED DRAWING: Figure 39

Description

  The present invention relates to a gaming machine.

  Pachinko machines, slot machines and the like are known as a type of gaming machine. In these gaming machines, the progress of the game is controlled by executing various controls in the control device. Further, numerical information is used when executing various controls in the control device.

  For example, there is known a configuration in which an internal lottery is performed based on the establishment of a predetermined lottery condition, and a bonus is given to a player according to the result of the internal lottery. In this internal lottery, when predetermined lottery conditions are satisfied, numerical information is acquired from the updating means for updating numerical information for lottery, and whether the acquired numerical information corresponds to the winning information or not A determination is made (see, for example, Patent Document 1). There is also known a configuration in which numerical information is acquired based on the establishment of a predetermined acquisition condition, and a specific effect or notification is performed based on the result of an internal lottery performed using the numerical information.

JP, 2009-261415, A

  Here, in the gaming machine as illustrated above etc., the game needs to be played smoothly, and there is still room for improvement in this respect.

  The present invention has been made in view of the above-described circumstances and the like, and it is an object of the present invention to provide a gaming machine capable of playing a game smoothly.

In order to solve the above-mentioned subject, the invention according to claim 1 is a game executing means in which a game operation is executed,
Start operation means operated to start the game operation;
An end operation unit operated to end the game operation;
Lottery execution means for executing a lottery with at least one condition that the start operation means is operated;
The game operation is started on the condition that the start operation means is operated as at least one condition, and the operation on the end operation means is at least one condition corresponding to the result of the lottery by the lottery execution means Game control means for controlling the game execution means so that the game operation is ended;
In a gaming machine provided with
A detection unit that detects that the start operation unit has been operated;
The lottery execution means is
First acquisition means for acquiring a first lottery value based on the detection state of the detection means becoming an operation corresponding state corresponding to the operation of the start operation means;
Second acquisition means for acquiring a second lottery value based on the detection state of the detection means becoming a non-operation corresponding state corresponding to the non-operation of the start operation means;
Lottery means for executing a lottery utilizing at least the first lottery value and a lottery utilizing the second lottery value, or performing a lottery utilizing at least both the first lottery value and the second lottery value;
Equipped with
The game control means includes start control means for starting the game operation after the first lottery value is acquired and before the second lottery value is acquired.

  According to the present invention, it is possible to play a game smoothly.

It is a front view of the slot machine in a 1st embodiment. It is a figure which shows the symbol arrangement of each reel. It is explanatory drawing which shows the relationship between the design and combination line which can be visually recognized from a display window part. It is explanatory drawing which shows the relationship between a prize mode and the privilege provided. It is a block diagram which shows the electric constitution of a slot machine. It is a block diagram for demonstrating a hard random number circuit. It is a flowchart which shows the main process performed by control IC. It is a flowchart which shows the timer interruption process performed by control IC. It is a flowchart which shows the start instruction | command setting process performed by control IC. It is a flowchart which shows the normal processing performed by control IC. It is a flowchart which shows the lottery process performed by control IC. It is a figure which shows an example of the lottery table for normal modes. FIG. 18 is an explanatory view for explaining the relationship between the stop order of reels and the winning condition established when the normal mode lottery table is selected. It is a figure which shows an example of the 1st RT mode lottery table. FIG. 18 is an explanatory view for explaining the relationship between the stop order of reels and the winning condition established when the first RT mode lottery table is selected. It is a figure which shows an example of the lottery table for 2nd RT modes. FIG. 18 is an explanatory view for explaining the relationship between the stop order of reels and the winning condition established when the second RT mode lottery table is selected. It is a flowchart which shows the response | compatibility process at the time of the game end performed by control IC. It is a flowchart which shows the management operation | movement performed by a control circuit. It is a time chart which shows the timing which control IC of the 1st slot machine of comparison object acquires a random number. It is a time chart which shows the timing when the control IC of the 2nd slot machine of comparison object acquires random number. FIG. 16 is a time chart showing timings at which a control IC of a slot machine provided with a latched status acquires a random number. When a noise mixes in control side CPU, it is a time chart which shows that control IC of a slot machine provided with a latched status does not acquire a random number. It is a block diagram showing composition of a main control board in a 2nd embodiment. It is a flowchart which shows the start instruction | command setting process performed by control IC. It is a flowchart which shows the error handling process performed by control IC. It is a flowchart which shows the management operation | movement performed by control side CPU. It is a flowchart which shows the random-number acquisition process performed by control IC. It is a time chart which shows the timing when control IC of the slot machine provided with the confirmation command flag acquires a random number. It is a time chart which shows the timing which control IC of the slot machine provided with the confirmation command flag transmits an abnormal signal. (A) It is a block diagram which shows the connection aspect of control IC in another form of 2nd Embodiment, and a random number counter, It is a flowchart which shows the random number acquisition process performed by (b) control IC. It is a block diagram which shows the structure of the main control board in 3rd Embodiment. It is a flowchart which shows the start instruction | command setting process performed by control IC. It is a flowchart which shows the normal processing performed by control IC. It is a flowchart which shows the management operation | movement performed by control side CPU. 15 is a timing chart illustrating timings at which control ICs of slot machines using start enable signals acquire random numbers. It is a time chart which shows the timing when abnormality alerting processing is performed. It is explanatory drawing which shows the relationship between the prize mode in 4th Embodiment, and the privilege provided. It is a block diagram for demonstrating the electric constitution of a main control board. It is a time chart which shows the timing to which a 1st management circuit and a 2nd management circuit transmit a latch signal. It is a flowchart which shows the start instruction | command setting process performed by control IC. It is a flowchart which shows the normal processing performed by control IC. It is a flowchart which shows the lottery process performed by control IC. It is a figure which shows an example of the lottery table for normal modes. FIG. 18 is an explanatory view for explaining the relationship between the stop order of reels and the winning condition established when the normal mode lottery table is selected. It is a flowchart which shows the response | compatibility process at the time of the game end performed by control IC. It is an explanatory view for explaining a transition mode of a game state. It is a flowchart which shows AT state management processing performed by control IC. It is a flowchart which shows the process for BB performed by control IC. It is a flowchart which shows stop order alerting | reporting control processing performed by sub side MPU. It is a time chart which shows the timing which control IC acquires the 1st random number, and the timing which acquires the 2nd random number. It is explanatory drawing for demonstrating the random number for lottery in another form of 4th Embodiment. (A)-(c) It is explanatory drawing for demonstrating the random number for lottery in 5th Embodiment. It is a flowchart which shows the normal processing performed by control IC. It is a flowchart which shows the lottery process performed by control IC. (A) It is a figure which shows an example of the lottery table for normal modes, (b) It is a table which shows a part of numerical information set to each random number group. It is a flowchart which shows AT state management processing performed by control IC. (A) It is a flowchart which shows the addition lottery process performed by control IC, It is a flowchart which shows the continuation lottery process performed by (b) control IC. It is a flowchart which shows the process for BB performed by control IC. It is a block diagram for demonstrating the structure of the hard random number circuit in 6th Embodiment. It is a block diagram for demonstrating the structure of the hard random number circuit in 7th Embodiment. It is a flowchart for demonstrating the management operation in control side CPU. It is a flowchart for demonstrating AT state management processing in control IC. It is a front view which shows the structure of the game board of the pachinko machine in 8th Embodiment. It is a longitudinal cross-sectional view of the recovery passage for action openings for explaining the recovery passage for action openings and the operation hole winning detection sensor. It is a block diagram for demonstrating the electric constitution of a hard random number circuit. It is explanatory drawing for demonstrating the content of the various counters used for the etc. lottery. It is a flowchart which shows the timer interruption process in control IC. It is a flowchart which shows the special figure special electric power control processing in control IC. (A) It is a block diagram which shows the structure of RAM, (b) It is a flowchart which shows the acquisition process of pending | holding information in control IC. It is a flow chart which shows random number acquisition processing in control IC. It is a flowchart which shows the error handling process in control IC. It is a time chart which shows the timing which control IC acquires a big hit random number. It is a time chart which shows the timing which control IC transmits a latch indication signal.

First Embodiment
Hereinafter, a first embodiment in the case where the present invention is applied to a slot machine, which is a type of gaming machine, will be described in detail based on the drawings. FIG. 1 is a front view of the slot machine 10.

  The slot machine 10 is provided with a housing 11 forming an outer shell thereof. The housing 11 is formed in a box shape opened forward as a whole by fixing a plurality of wooden panels. A front door 12 is attached to the front side of the housing 11. The front door 12 is supported by the housing 11 so that the internal space of the housing 11 can be opened and closed with the left side portion as a pivot. The front door 12 is locked so as not to be opened by a locking device provided on the back of the front door 12. This locked state is released by an unlocking operation by a predetermined key on the key cylinder 14.

  A game panel 20 for notifying the player of the game state is provided on the upper side of the center of the front door 12. In the game panel 20, three vertically long display window portions 21L, 21M, 21R are formed in a line. The display windows 21L, 21M, 21R are made of a transparent or semi-transparent material, and the inside of the slot machine 10 is visible through the display windows 21L, 21M, 21R.

  The housing 11 is provided with a reel unit 31. The reel unit 31 includes a left reel 32L, a middle reel 32M and a right reel 32R which are respectively formed in a cylindrical shape. Each of the reels 32L, 32M, 32R is rotatably supported such that the central axis thereof is the rotational axis of the reel. The rotational axes of the respective reels 32L, 32M, 32R are disposed on the same axis extending substantially in the horizontal direction, and the respective reels 32L, 32M, 32R are in one-to-one correspondence with the display windows 21L, 21M, 21R. There is. Therefore, a part of the surface of each of the reels 32L, 32M, 32R is visible through the corresponding display windows 21L, 21M, 21R. In addition, when the reels 32L, 32M, 32R rotate forward, the surface of the reels 32L, 32M, 32R is projected as if it were moving from the top to the bottom through the display windows 21L, 21M, 21R.

  Each of the reels 32L, 32M, 32R is connected to a stepping motor (not shown), and the reels 32L, 32M, 32R can be driven to rotate individually, ie independently, by driving the stepping motors. It has become.

  The various operation units for the player to perform the start operation and the stop operation of the game using the respective reels 32L, 32M, 32R bulge the slot machine 10 forward of the game panel 20 below the game panel 20. It is arranged intensively in the provided bulging portion 25 for operation. The various operation units collectively arranged in the operation bulging unit 25 will be described in detail below.

  A start lever 41 operated to start rotation of each of the reels 32L, 32M, 32R is provided on the front left side of the operation bulging portion 25. When the start lever 41 is operated while medals are betted, the reels 32L, 32M, 32R start to rotate all at once.

  On the right side of the start lever 41 on the front surface of the operation bulging portion 25, stop buttons 42, 43, 44 are provided which are operated to individually stop the rotating reels 32L, 32M, 32R. . The stop buttons 42, 43 and 44 are disposed immediately below the display windows 21L, 21M and 21R corresponding to the reels 32L, 32M and 32R to be stopped. The respective stop buttons 42, 43 and 44 can be stopped when a predetermined time has elapsed after the left reel 32L starts to rotate.

  The rotation of each reel 32L, 32M, 32R is started based on the operation of the start lever 41, and the rotation of each reel 32L, 32M, 32R is stopped based on the operation of each stop button 42, 43, 44. Until completion of execution of various processing such as giving of and management of the game state is equivalent to one game (or game play).

  A medal insertion slot 45 for inserting a medal is provided on the upper right side of the operation bulging portion 25. The medal inserted from the medal insertion slot 45 is guided by the selector 52 provided on the back of the front door 12 to the hopper device 53 in the housing 11 if it can be inserted, and if it can not be inserted, the front door The medal discharge port 58 provided at the lower portion of the front surface of the T.12. The hopper device 53 has a function of paying out the medals stored in the storage tank to the medal receiver 59 through the medal discharge port 58 when a winning corresponding to the awarding of medals is established on the effective line. .

  A return button 46 is provided at a position below the medal insertion slot 45 on the front surface of the operation bulging portion 25. The return button 46 is pressed when the medal inserted into the medal insertion slot 45 is jammed in the selector 52. In addition, on the upper left side of the operation bulging portion 25, a first credit insertion button 47 for inserting a maximum amount of virtual medals stored in the RAM 144 of the main control device 140 to be described later at one time; A second credit insertion button 48 for inserting two cards at a time and a third credit insertion button 49 for inserting one virtual medal at a time are provided. In the slot machine 10, game media is a concept including medals and virtual medals.

  A settlement button 51 is provided at a position to the left of the start lever 41 on the front surface of the operation bulging portion 25. The slot machine 10 has a credit function of storing, as virtual medals, surplus insertion medals up to a predetermined maximum value (for 50 medals) and payout medals at the time of winning in the RAM 144 of the main control device 140 described later. When the settlement button 51 is operated under the situation where virtual medals are stored and stored, the virtual medals are paid out from the medal discharge port 58 as real medals.

  A power supply device 54 is provided on the left side of the hopper device 53 inside the housing 11. In the power supply unit 54, there are a power switch operated at power on or off, a reset button for resetting various states of the slot machine 10, and a setting state of the slot machine 10 from "setting 1" to "setting 6 And a setting key insertion hole operated to change in the range of

<The symbols attached to each reel 32L, 32M, 32R>
Next, the symbols attached to the respective reels 32L, 32M, 32R will be described.

  FIG. 2 shows the symbol arrangement of the left reel 32L, the middle reel 32M and the right reel 32R. As shown in the figure, 21 symbols are arranged in a line on each of the reels 32L, 32M and 32R. Moreover, although the number is attached | subjected corresponding to each reel 32L, 32M, 32R, these numbers are in the state which the main control apparatus 140 can visually recognize from the display window parts 21L, 21M, 21R. It is a number for recognizing a symbol, and is not actually attached to the reels 32L, 32M, 32R. However, the following description will be made using the corresponding numbers.

  As a symbol, "bell" symbol (for example, the 20th of left reel 32L), "replay" symbol (for example, the 19th of left reel 32L), "watermelon" symbol (for example, the 18th of left reel 32L), " "Red 7" symbol (for example, the 15th of left reel 32L), "BAR" symbol (for example, the tenth of left reel 32L), "cherry" symbol (for example, the ninth of left reel 32L), "white 7" symbol There are seven types (for example, the fifth of the left reel 32L). And in each reel 32L, 32M, and 32R, the number and arrangement | positioning order of various symbols are completely different.

  FIG. 3 is a front view of the display windows 21L, 21M, 21R. Each of the display window portions 21L, 21M, 21R is formed such that three out of 21 symbols attached to the corresponding reels 32L, 32M, 32R make the entire symbol visible. For this reason, in the state where all the reels 32L, 32M, 32R are stopped, 3 × 3 = 9 symbols become visible through the display window portions 21L, 21M, 21R.

  In the slot machine 10, one main line ML is set so as to connect positions where the symbols of the reels 32L, 32M, 32R can be visually recognized. The main line ML is a line connecting the middle design of the left reel 32L, the middle design of the middle reel 32M, and the middle design of the right reel 32R. The rotation of each reel 32L, 32M, 32R is started with a prescribed number of game media betted, and when a prize corresponding to the winning combination is established on the main line ML, a benefit of giving the game media, At least one of the benefit of replay and the transition of the gaming state is provided.

  That is, in the slot machine 10, only one main line ML is set as a line on which winning can be established. The main line ML is set as a line extending in a straight line. Therefore, the upper symbol of left reel 32L, the subline S1 connecting middle step symbol of middle reel 32M and the lower symbol of right reel 32R, the upper symbol of left reel 32L, the upper symbol of middle reel 32M and the upper symbol of right reel 32R The subline S2 connected, the lower symbol of the left reel 32L, the subline S3 connecting the lower symbol of the middle reel 32M and the lower symbol of the right reel 32R, the lower symbol of the left reel 32L, the middle step symbol of the middle reel 32M and the right reel 32R Even if a combination of symbols to be won is established on a line such as subline S4 connecting the upper symbols of, the winning is not established.

  Hereinafter, with reference to FIG. 4, the correspondence between the combination of symbols to be awarded and the benefit to be awarded when winning will be described. FIG. 4 is an explanatory view for explaining the correspondence between a combination of symbols to be won and a benefit to be awarded when the symbol is won.

  As a small winning combination in which a game medium is given, there are a first compensation winning, a second compensating winning, a third compensating winning, a bell winning, a watermelon winning, and a cherry winning. Specifically, the stop symbol of the left reel 32L on the main line ML is the "bell" symbol, the stop symbol of the middle reel 32M is the "replay" symbol, and the stop symbol of the right reel 32R is the "bell" symbol In the case, it will be the first compensation prize. Also, on the main line ML, when the stop symbol of the left reel 32L is the "watermelon" symbol, the stop symbol of the middle reel 32M is the "bell" symbol, and the stop symbol of the right reel 32R is the "bell" symbol, It will be the second compensation prize. Further, when the stop symbol of the left reel 32L is the "replay" symbol on the main line ML, the stop symbol of the middle reel 32M is the "bell" symbol, and the stop symbol of the right reel 32R is the "bell" symbol, It will be the third compensation prize. The number of targets to be provided with game media when any of the first compensation winning to the third compensation winning becomes "1" is a gaming state other than the BB state to be described later. On the other hand, the first to third compensation prizes are excluded from the establishment targets in the BB state described later.

  When the stop symbol of the left reel 32L on the main line ML is the "bell" symbol, the stop symbol of the middle reel 32M is the "bell" symbol, and the stop symbol of the right reel 32R is the "bell" symbol, the bell prize is won It becomes. The number of targets to which the game media can be awarded when the bell prize is won is "9" in the case of gaming states other than the BB state described later, and is "8" in the BB state described later.

  The stop symbol of the left reel 32L on the main line ML is the "watermelon" symbol, the stop symbol of the middle reel 32M is either the "watermelon" symbol or the "cherry" symbol, and the stop symbol of the right reel 32R is "watermelon If it is either a '' symbol or a '' white 7 '' symbol, it is a watermelon prize. The target number of game media to be awarded when the watermelon wins is "7" in the case of a gaming state other than the BB state, and is "8" in the BB state described later.

  When the stop symbol of the left reel 32L on the main line ML becomes the "cherry" symbol, it is a cherry winning even if the stop symbol of the middle reel 32M and the stop symbol of the right reel 32R are both. The number of objects to be provided with game media in the case of a cherry winning is "2" if it is a gaming state other than the BB state. On the other hand, in the BB state, the Cherry winnings are excluded from the target of establishment.

  A normal replay winning, a first RT replay winning, a second RT replay winning, a first falling replay winning and a second winning are awarded as being provided with a replay bonus that allows the player to play the next game without betting the gaming media. There is a fall replay prize. Specifically, the stop symbol of the left reel 32L on the main line ML is the "replay" symbol, the stop symbol of the middle reel 32M is the "replay" symbol, and the stop symbol of the right reel 32R is the "replay" symbol Or when the stop symbol of the left reel 32L is the "replay" symbol, the stop symbol of the middle reel 32M is the "cherry" symbol, and the stop symbol of the right reel 32R is the "bell" symbol, the normal replay win and Become. If the stop symbol on the left reel 32L is the "bell" symbol on the main line ML, the stop symbol on the middle reel 32M is the "replay" symbol, and the stop symbol on the right reel 32R is the "replay" symbol, the first RT It becomes a replay prize. If the stop symbol of the left reel 32L on the main line ML is the "watermelon" symbol, the stop symbol of the middle reel 32M is the "replay" symbol, and the stop symbol of the right reel 32R is the "replay" symbol, the second RT It becomes a replay prize. If the stop symbol of the left reel 32L on the main line ML is the "replay" symbol, the stop symbol of the middle reel 32M is the "cherry" symbol, and the stop symbol of the right reel 32R is the "replay" symbol, the first It will be a fall replay prize. If the stop symbol on the left reel 32L is the "replay" symbol on the main line ML, the stop symbol on the middle reel 32M is the "replay" symbol, and the stop symbol on the right reel 32R is the "bell" symbol, the second It will be a fall replay prize.

  When one of the above-described replay wins, it becomes possible to play the next game while making the new bet of the game medium unnecessary. Specifically, when any replay win is achieved in a game in which three bets of game media are made, it is possible to start the game of the next game in a three bet state, making new bets on the game media unnecessary. It becomes.

  Among the various replay wins, the first RT replay win, the second RT replay win, the first fall replay replay win, and the second fall replay replay win not only become a trigger for giving a replay prize benefit but also become a transition trigger for the lottery mode. In the slot machine 10, a plurality of types of lottery modes are set such that the types of winning combinations subject to lottery and the winning probability of each combination are different in the lottery process of winning combinations (FIG. 11). This occurs when a replay winning as a trigger for shifting to the lottery mode is established.

  There are a first BB prize and a second BB prize as state transition prizes in which only the transition of the gaming state is performed. Specifically, on the main line ML, the stop symbol of the left reel 32L is the "red 7" symbol, the stop symbol of the middle reel 32M is the "red 7" symbol, and the stop symbol of the right reel 32R is "red 7" If it is a symbol, it will be the first BB prize. In the case where the stop symbol of the left reel 32L is the "white 7" symbol on the main line ML, the stop symbol of the middle reel 32M is the "white 7" symbol, and the stop symbol of the right reel 32R is the "white 7" symbol , It will be the 2nd BB prize. When the first BB winning or the second BB winning is established, the gaming state shifts to the BB state. Here, the BB state is a gaming state in which the expected number of game media to be provided per unit game count is higher than any gaming state other than the BB state.

  Specifically, the player is allowed to win a bell prize with a probability (for example, 1/2) higher than in the case of the other gaming states, and the reels 32L, 32M, The bell winning will be established regardless of the stop order of 32R and the stop operation timing of the stop buttons 42 to 44 with respect to the rotational position of each of the reels 32L, 32M, 32R. In addition, winning a watermelon winning combination with a probability (for example, 1/4) higher than in the case of other gaming state to the combination that enables the establishment of the winning a prize, when the winning combination has been elected to stop each reel 32L, 32M, 32R Watermelon winning is established regardless of the order and the stop operation timing of the stop buttons 42 to 44 with respect to the rotational positions of the respective reels 32L, 32M, 32R. As a result, even if there are a plurality of winning combinations to be provided with gaming media in the BB state, if the combination corresponding to the winning combination to be provided with the gaming media is won, the winning combination is supported. The winning prize will surely be established. Further, the number of game media provided when the bell prize and the watermelon prize are established is the same number, and specifically, it is "8". As a result, even if there are a plurality of winning combinations to be provided with gaming media in the BB state, the number of provided gaming media when the winning is established is the same regardless of the type of winning. .

  The BB state continues over a plurality of games, and ends when the end condition is satisfied based on the occurrence of an event according to the execution content of the game. Although the end condition is arbitrary, it is set as the end condition in the slot machine 10 that the total number of game media provided after the start of the BB state is equal to or more than the end reference number. The first BB state and the second BB state are set in the BB state, and the end reference numbers are different between the first BB state and the second BB state. In the first BB state, the end reference number is a number that is more than five times the fixed number when the winning combination for the game medium is established in the BB state, and is six or less times the fixed number. ing. Specifically, it is set to "41". On the other hand, in the second BB state, the end reference number is a number more than 11 times the fixed number when the winning combination for the game medium is established in the BB state, and the number 12 or less times the fixed number It has become. Specifically, it is set to "89". With this configuration, a winning to be provided with gaming media is reliably established only six times in the first BB state, and a winning to be provided with gaming media is reliably established only twelve times in the second BB state. Further, as described above, in the configuration in which there are a plurality of types of winning targets to be provided with gaming media in the BB state, when the combination corresponding to the winning targets to be provided with gaming media is won, the winning combination corresponding to the selected winning combination Is surely established. Therefore, in the first BB state, only six games are surely generated as the game winning the combination corresponding to the winning combination for the gaming medium, and in the second BB state, the winning combination corresponding to the winning combination for the gaming medium is won The game will definitely occur only 12 games.

<A device for performing various notification and various effects>
Next, an apparatus for executing various types of notification and various types of effects will be described.

  As shown in FIG. 1, an upper lamp 64 and an image display device 66 are provided on the upper part of the front door 12, and a speaker 65 is provided on the lower part of the front door 12. The upper lamp 64 is controlled to emit light in a mode corresponding to the abnormality when an abnormality occurs in the slot machine 10, and is controlled to emit light in a mode corresponding to the winning result. Further, the upper lamp 64 is controlled to emit light so that a light emission effect corresponding to the display effect in the image display device 66 is performed. The speakers 65 are provided as a left-right pair, and sound output is controlled so that a sound or a voice corresponding to the abnormality is output when an abnormality occurs in the slot machine 10, and a sound or a voice corresponding to a winning result Sound output is controlled so as to be output. Further, the sound output of the speaker 65 is controlled so that the sound output effect corresponding to the display effect in the image display device 66 is performed.

  The image display device 66 has a display surface 66a, and when an abnormality occurs in the slot machine 10, display control is performed so that an image corresponding to the abnormality is displayed on the display surface 66a. Further, the image display device 66 is controlled to display an image corresponding to the winning result of the combination in the internal lottery and the winning result in each game on the display surface 66a.

<Electric Configuration of Slot Machine 10>
Next, the electrical configuration of the slot machine 10 will be described based on the block diagram of FIG.

  The main control device 140 has a main control board 141 which controls the main control of the game. On the main control board 141, an MPU 142 equipped with a hard random number circuit 146 and a control IC 148 is mounted. The hard random number circuit 146 includes, for example, random number generating means for updating the random number used for the winning lottery of the role. Details of the hard random number circuit 146 will be described later. It is not an essential configuration that the hard random number circuit 146 and the control IC 148 are integrated into one chip with respect to the MPU 142, but each may be configured as an individual chip.

  The control IC 148 is a CPU that executes main processing (FIG. 7) and timer interrupt processing (FIG. 8) using a program. In the control IC 148, a ROM 143 storing various control programs to be executed by the control IC 148 and fixed value data, and various data etc. are temporarily stored when the control program stored in the ROM 143 is executed. And a RAM 144, which is a memory of Also, the control IC 148 is provided with a clock circuit 145 for outputting a clock signal of a predetermined cycle, and a divider circuit 147 is provided at an intermediate position in the signal path between the clock circuit 145 and the control unit of the control IC 148. It is provided.

  The divider circuit 147 functions as frequency changing means for changing the cycle of the clock signal from the clock circuit 145, and is configured to output a changed clock signal for specifying the start timing of the timer interrupt processing by the control IC 148. ing. In detail, the divider circuit 147 outputs a change clock signal of an interval of 1.49 msec which is a specific cycle to the control IC 148. The control IC 148 executes processing for confirming the generation of a specific signal form such as rising or falling of the modified clock signal, and activates periodic processing (timer interrupt processing) with generation of the specific signal form as at least one condition. . In this case, the execution cycle of the periodic process is the cycle (1.49 msec) of the change clock signal.

  The fact that the ROM 143 and the RAM 144 are integrated into one chip with respect to the control IC 148 is not an essential configuration, and each may be configured as an individual chip.

  The MPU 142 is provided with an input port and an output port. On the input side of the MPU 142, the reel unit 31 (more specifically, a reel index sensor for individually detecting that each reel 32L, 32M, 32R has made one rotation), the operation of each stop button 42, 43, 44 is individually detected Stop detection sensors 42a, 43a, 44a, an insertion medal detection sensor 45a for detecting medals inserted from the medal insertion slot 45, a credit insertion detection sensor 47a for individually detecting the operation of each credit insertion button 47, 48, 49, 48a, 49a, a settlement detection sensor 51a for detecting the operation of the settlement button 51, a payout detection sensor for the hopper device 53, a reset detection sensor 56a for detecting the operation of the reset button 56, and a setting key inserted in the setting key insertion hole 57 Various sensors such as setting key detection sensor 57a that It is, these signals from the sensors are input to MPU142.

  Here, the detection signal SG1 from the start detection sensor 41a that detects the operation of the start lever 41 is input to the hard random number circuit 146 and the control IC 148. The detection signal SG1 is a signal that rises from the LOW state to the HI state when the player depresses the start lever 41, and returns from the HI state to the LOW state when the depression operation is completed. The details of the connection between the start detection sensor 41a and the hard random number circuit 146 and the connection between the start detection sensor 41a and the control IC 148 will be described later.

  Reel units 31 (more specifically, stepping motors for rotating the respective reels 32L, 32M, 32R), a payout motor of the hopper device 53, a sub control device 150, and the like are connected to the output side of the MPU 142. In each game, the rotational drive control of each reel 32L, 32M, 32R of the reel unit 31 is performed by the MPU 142, and when the small winning combination is realized and the medal payout is executed, the drive control of the hopper device 53 is MPU142. It is done by Further, a command is transmitted from the MPU 142 to the sub control device 150 at each timing of each game.

  The power failure monitoring circuit provided in the power supply device 54 is connected to the input side of the MPU 142 (not shown). The power supply unit includes a power supply unit that supplies drive power to the main controller 140 and other electronic devices in the slot machine 10 and a power failure monitoring circuit. The power failure monitoring circuit applies power to the power supply unit from an external power supply. The voltage that has been monitored is monitored, and a power failure signal is output to the MPU 142 when the voltage falls below the reference voltage. The MPU 142 executes power failure processing by receiving a power failure signal, and enables recovery to the processing state before power failure after power recovery. Further, the power supply device 54 is provided with a power-off power supply unit for supplying backup power to the RAM 144 as power-off power in a situation where the supply of operation power from the external power supply is cut off. As a result, even if the supply of operating power from the external power supply is interrupted, the data is stored and held in the RAM 144 in a state (for example, one day or two days) where backup power can be supplied by the power supply part during power interruption. Be done. However, by turning on the power of the slot machine 10 in a state in which the reset button provided on the power supply device 54 is pressed, the data stored in the RAM 144 is initialized.

  The sub control device 150 includes a sub control board 151 for executing execution control of various notifications and various effects. The MPU 152 is mounted on the sub control board 151. The MPU 152 is a ROM 153 storing various control programs to be executed by the MPU 152 and fixed value data, and a memory for temporarily storing various data etc. when the control program stored in the ROM 153 is executed. A certain RAM 154, a clock circuit 155 for outputting a rectangular wave of a predetermined frequency, an interrupt circuit, a data input / output circuit, a random number generation circuit, etc. are incorporated.

  The fact that the ROM 153 and the RAM 154 are integrated into one chip with respect to the MPU 152 is not an essential configuration, and each may be configured as an individual chip. In addition, backup power is supplied from the power supply unit of the power supply device 54 during interruption of the supply of operating power from the external power supply to the RAM 154, and the backup power is supplied (for example, one day) And 2), the data is stored and held in the RAM 154. However, by turning on the power of the slot machine 10 in a state where the reset button 56 provided on the power supply device 54 is pressed, the data stored in the RAM 154 is initialized.

  The MPU 152 is provided with an input port and an output port, respectively. The MPU 142 of the main control unit 140 is connected to the input side of the MPU 152 as described above, and receives various commands from the MPU 142.

  The upper lamp 64, the speaker 65, and the image display device 66 are connected to the output side of the MPU 152. The MPU 152 executes the light emission control of the upper lamp 64, the sound output control of the speaker 65, and the display control of the image display device 66 based on the command received from the MPU 142 of the main control device 140, thereby various notifications and effects. To be done.

  In the following description, for convenience of explanation, the MPU 142, the ROM 143 and the RAM 144 of the main control device 140 are referred to as the main MPU 142, the main ROM 143 and the main RAM 144 respectively, and the MPU 152, the ROM 153 and the RAM 154 of the sub control device 150 The MPU 152, the sub ROM 153, and the sub RAM 154 are referred to.

<Configuration of Main Control Board 141>
Next, the configuration of the main control board 141 will be described in detail using the block diagram of FIG.

  As shown in FIG. 6, the control IC 148 includes input terminals TA1 to TA3 and an output terminal TA4. Further, as shown in FIG. 6, the hard random number circuit 146 includes an updating circuit 101 for updating a random number used for determining whether or not the winning combination has been made, and a latch register 102 in which the random number updated by the updating circuit 101 is written. And a control circuit 103 capable of grasping the timing at which the start lever 41 is operated by using the detection signal SG1.

  The control circuit 103 includes a CPU 114 that executes processing using a program. The CPU 114 included in the control circuit 103 is referred to as a control CPU 114. The control side CPU 114 has a ROM 115 storing a program for executing the management operation (FIG. 19), a RAM 116 having an area for temporarily storing information, input terminals TB1 and TB2, and an output terminal. It has TB3 and TB4.

  Here, the control side CPU 114 detects the rising from the LOW state to the HI state of the detection signal SG1 input to the control side CPU 114 in the management operation (FIG. 19), and 12.8 μs has elapsed from the timing of the detection. Under the condition that it is determined that the HI state of the detection signal SG1 is maintained until then, a latch signal which is a pulse signal is transmitted to the latch register 102, and "1" is set in the latched status 113. Details of the management operation will be described later.

  Next, the connection of the start detection sensor 41a and the control IC 148, and the connection of the start detection sensor 41a and the hard random number circuit 146 will be described. As shown in FIG. 6, one signal line from the start detection sensor 41 a is branched into two on the main control board 141. One of the signal lines is connected to the input terminal TA1 of the control IC 148, and the other of the signal lines is connected to the input terminal TB1 of the control side CPU 114 constituting the hard random number circuit 146. For this reason, when noise mixes in one signal line after branching, the situation where the influence of the said noise reaches the other can be avoided.

  Next, the update circuit 101 will be described. As shown in FIG. 6, the update circuit 101 outputs a clock circuit 104 that outputs a clock signal of a predetermined frequency (for example, 16 MHz), a random number generation circuit 106 that generates an M-sequence random number updated at each update timing, And a random number counter 105 to be stored. Here, the control IC 148 operates based on the clock circuit 145 (FIG. 5) in the control IC 148. On the other hand, the update circuit 101 operates based on the clock circuit 104 in the update circuit 101 that operates independently of the clock circuit 145 in the control IC 148. For this reason, the update timing of the random number in the update circuit 101 is not influenced by the process executed by the control IC 148.

  The random number counter 105 has a storage area of 2 bytes, and the random number counter 105 stores random numbers of “1” to “65535”. The 2-byte storage area is composed of 16 positive edge D flip-flop circuits (D-FF). The D-FFs constituting the random number counter 105 are taken as D-FFs 105a to 105p for random number counter. The random number counter D-FFs 105a to 105p have a clock terminal (CLK terminal), a D terminal, and a clear terminal (CLR terminal) as input terminals, and have a Q terminal as an output terminal.

  As shown in FIG. 6, the signal line extending from the clock circuit 104 is branched into two in the updating circuit 101, and one of the signal lines after branching is further branched into 16 in the updating circuit 101. It is connected to the CLK terminals of the 16 random number counter D-FFs 105a to 105p. Therefore, the clock signal output from the clock circuit 104 is input to the CLK terminals of the random number counter D-FFs 105 a to 105 p.

  Also, the other of the signal lines branched out from the clock circuit 104 is connected to the random number generation circuit 106 via the inversion circuit 107. The 16-bit data output from the random number generation circuit 106 to the D terminals of the random number counter D-FFs 105a to 105p is triggered by the rise of the signal input to the random number generation circuit 106 via the inversion circuit 107. It will be updated. The random number counter D-FFs 105a to 105p are in the state of outputting the signal input to the D terminal from the Q terminal at the timing when the signal input to the CLK terminal rises.

  The update timing of the random number generated by the random number generation circuit 106 and the update timing of the random number stored in the random number counter 105 are half the cycle of the signal output from the clock circuit 104. Therefore, the update circuit 101 updates the data output from the random number generation circuit 106, and updates the signals output from the Q terminals of the 16 random number counter D-FFs 105a to 105p in the random number counter 105. It repeats alternately.

  Specifically, since the clock signal output from the clock circuit 104 is 16 MHz, the clock signal rises in a cycle of 62.5 ns. Therefore, the update of data in the random number generation circuit 106 occurs at a cycle of 62.5 ns, and the update of data in the random number counter 105 is performed from when the data in the random number generation circuit 106 is updated to the next data. To be done. As described above, since the execution cycle of the timer interrupt process executed by the control IC 148 is 1.49 msec, the update interval of the random number is sufficiently shorter than the execution cycle of the timer interrupt process. Note that, instead of the positive edge D-FF, a negative edge D-FF may be used for the random number counter D-FFs 105a to 105p.

  Here, the random number stored in the random number counter 105 is a 16-digit binary number. The random number generation circuit 106 is a hardware circuit that generates M-sequence random numbers. The M-sequence random number is a pseudo random number having a period. The cycle of the M-sequence random number updated by the random number generation circuit 106 is “65535”. The random number generation circuit 106 generates a second random number based on an initial value other than “0” set in advance, and generates a third random number based on the second random number. As described above, in the random number generation circuit 106, the random number represented by the 16-digit binary number is updated, and the 65535 numbers are output once to the random number counter 105, and then return to the initial value. As described above, in the M-sequence random number, the order of the random numbers to be output is determined by the initial value set in advance, and each number of “1” to “65535” appears once in one cycle. The probability of winning the winning combination can be set according to the number of numbers set as the number corresponding to the winning.

  The random number updated by the random number counter 105 is not limited to the M-sequence random number. For example, each time the update circuit 101 reaches the update timing, “1” is added to the random number stored in the random number counter 105, and the value of the random number counter 105 becomes “65535”. The configuration may be cleared. The point is that any configuration may be used as long as the result of the determination of the success or failure of the combination performed using random numbers is not biased to a specific result.

  Next, the latch register 102 in which the numerical value information of the random number stored in the random number counter 105 of the update circuit 101 is written will be described. The latch register 102 is provided with a storage area of 2 bytes in the same manner as the random number counter 105 of the update circuit 101. Specifically, the latch register 102 includes 16 positive edge triggered D-FFs. The D-FFs constituting the latch register 102 are referred to as latch register D-FFs 102 a to 102 p. The latch register D-FFs 102a to 102p include a CLK terminal, a D terminal, and a CLR terminal as input terminals, and a Q terminal as an output terminal.

  The D terminal of the latch register D-FFs 102a to 102p is connected to a signal line coming out of the Q terminal of the random number counter D-FFs 105a to 105p. Specifically, numerical value information stored in the random number counter 105 of the update circuit 101 and numerical value information stored in the latch register 102 are both 16-digit binary numbers. The Q terminals of the random number counter D-FFs 105a to 105p in which the numerical value information of the nth digit is stored in the random number counter 105 are D of latch registers D-FFs 102a to 102p in which the numerical information of the nth digit is stored in the latch register 102. It is connected to the terminal. Here, n is a natural number of 1 to 16.

  The CLK terminals of the latch register D-FFs 102 a to 102 p are connected to the output terminal TB 4 of the control side CPU 114 by a signal line. In detail, one signal line coming out of the output terminal TB4 of the control side CPU 114 is branched into 16 and enters the CLK terminal of each of the latch registers D-FFs 102a to 102p. The Q terminals of the latch register D-FFs 102a to 102p are connected to the input terminal TA3 of the control IC 148.

  Next, a configuration for acquiring numerical value information of random numbers used by the control IC 148 for determining whether the winning combination is successful or not will be described. When the detection signal SG1 input to the control side CPU 114 rises from the LOW state to the HI state and the HI state is maintained for a predetermined time (12.8 μs), the control side CPU 114 uses the output terminal TB4 for the latch register. A latch signal is output to the CLK terminals of the D-FFs 102a to 102p.

  Here, the latch signal is a pulse signal that falls from the HI state to the LOW state after rising from the LOW state to the HI state. By waiting for 12.8 μs after the detection signal SG1 input to the control circuit 103 rises, a latch signal is transmitted triggered by noise less than 12.8 μs entering the input terminal TB1 of the control side CPU 114. You can prevent that.

  Since the latch register D-FFs 102a to 102p are positive edge trigger type, when the control CPU 114 transmits a latch signal to the latch register 102, the random number stored in the random number counter 105 is written to the latch register 102. The written random number is output to the input terminal TA3 of the control IC 148.

  Specifically, in synchronization with the rising of the signal input to the CLK terminal of the latch register D-FFs 102a to 102p, the signal is output from the Q terminal of the random number counter D-FFs 105a to 105p and is transmitted to the latch register D-FF 102a to The numerical information input to the D terminal of 102p is output from the Q terminal of the latch register D-FFs 102a to 102p. When it is time to acquire a random number used to determine the part's success or failure, the control IC 148 outputs numerical information output from the Q terminal of the latch register D-FFs 102 a to 102 p and input to the input terminal TA3 of the control IC 148 get.

  The random number counter 105 and the latch register 102 may be configured to include a negative edge D-FF instead of the positive edge D-FF. The random number counter 105 and the latch register 102 may be configured to include an RS flip flop circuit or a JK flip flop circuit instead of the D-FF.

  Next, the latched status 113 will be described. As shown in FIG. 6, the control circuit 103 has a latched status 113 in which “1” is set at the timing when the random number stored in the random number counter 105 is written to the latch register 102. The latched status 113 is a status register consisting of one positive edge triggered T flip-flop circuit (T-FF). As shown in FIG. 6, the latched status, which is T-FF, includes a T terminal 113b and a CLR terminal 113c as input terminals, and a Q terminal 113a as an output terminal. The latched status 113 inverts the signal output from the Q terminal 113a in synchronization with the rising of the signal input to the T terminal 113b from the LOW state to the HI state.

  Specifically, in the state where the signal of "0" is output from the Q terminal 113a, the signal output from the Q terminal 113a is changed to "1" in synchronization with the rising of the signal input to the T terminal 113b. Reverse. Further, in the state where the signal of “1” is output from the Q terminal 113 a, the signal output from the Q terminal 113 a is inverted to “0” in synchronization with the rising of the signal input to the T terminal 113 b. The signal output from the Q terminal 113a is cleared to "0" when the signal input to the CLR terminal 113c rises from the LOW state to the HI state.

  Here, the state in which “0” is set in the latched status 113 is a state in which “0” is output from the Q terminal 113 a of the latched status 113. Further, the state in which “1” is set in the latched status 113 is the state in which “1” is output from the Q terminal 113 a of the latched status 113.

  The T terminal 113b of the latched status 113 is connected to the output terminal TB3 of the control side CPU 114 by one signal line. The control side CPU 114 is outputted from the Q terminal 113 a of the latched status 113 by transmitting a short pulse signal to the T terminal 113 b of the latched status 113 in a state where the latched status 113 is set to “0”. And the latched status 113 is set to "1".

  Specifically, the control CPU 114 detects that the detection signal SG1 input to the input terminal TB1 of the control CPU 114 has risen from the LOW state to the HI state, and the HI state continues for 12.8 μs or more. At the determined timing, a latch signal is transmitted from the output terminal TB4 to the CLK terminal of the latch register D-FFs 102a to 102p, and a pulse signal is transmitted from the output terminal TB3 to the T terminal 113b of the latched status 113 to perform latched status Set "1" to 113. Therefore, at the timing when the numerical value information of the random number stored in the random number counter 105 is written in the latch register 102, “1” is set in the latched status 113.

  The control side CPU 114 raises the signal output from the output terminal TB3 to the T terminal 113b of the latched status 113 on condition that the latched status 113 is set to “0”, and the latched status is obtained. The signal output from the Q terminal 113a of 113 is inverted from the LOW state to the HI state. As a result, “1” is set in the latched status 113. In addition, when “1” is already set in the latched status 113, the control side CPU 114 maintains the state in which “1” is set in the latched status 113 without transmitting a pulse signal. . Therefore, even if the start lever 41 is operated while the latched status 113 is set to "1", the value set to the latched status 113 is triggered by the operation from "1" to "0". It does not invert.

  Here, when the control side CPU 114 determines that the detection signal SG1 input to the input terminal TB1 of the control side CPU 114 rises from the LOW state to the HI state, and the HI state continues for 12.8 μs or more, Even when “1” is set in the latched status 113, a latch signal is output to the latch register 102 to update the numerical value information of the random number stored in the latch register 102.

  A situation where the start lever 41 is operated with the latched status 113 set to “1” will be described below using a specific example. When noise enters only the input terminal TB1 of the control side CPU 114, “1” may be set in the latched status 113. Here, the control IC 148 is a period in which the game can be started, that the rising edge of the detection signal SG1 is detected in the control IC 148, and that the latched status 113 is set to “1”. Start.

  For this reason, even if the latched status 113 is set to "1" due to noise entering the input terminal TB1 of the control side CPU 114, the control IC 148 does not detect the rising of the detection signal SG1. The game is not started, and the latched status 113 is maintained at "0". In this state, when the start lever 41 is operated, the numerical information stored in the latch register 102 corresponds to the operation of the current start lever 41 while the "1" set in the latched status 113 is maintained. Is updated to the numerical information of the selected random number.

  As described above, when the start lever 41 is operated in a state where the latched status 113 is set to “1”, the random number stored in the latch register 102 is updated. With this, it is possible to reduce the possibility that the random number stored in the latch register 102 will be used to determine the success or failure of the winning combination.

  Further, the signal line from the Q terminal of the latched status 113 is branched into two on the control circuit 103, and one of the signal lines after branching is connected to the input terminal TA2 of the control IC 148, The other of the branched signal lines is connected to the input terminal TB2 of the control side CPU 114. Therefore, the signal output from the Q terminal 113 a of the latched status 113 is input to each of the control IC 148 and the control side CPU 114.

  The control IC 148 can determine whether “1” is set in the latched status 113 of the control circuit 103 by grasping the signal input to the input terminal TA2 of the control IC 148. Further, the control side CPU 114 can determine whether or not “1” is set to the latched status 113 by grasping the signal inputted to the input terminal TB2 of the control side CPU 114.

  Further, the CLR terminal 113c of the latched status 113 is connected to the output terminal TA4 of the control IC 148 by one signal line. The control IC 148 can clear the latched status 113 to “0” by raising the signal output to the CLR terminal 113 c of the latched status 113 from the LOW state to the HI state.

  When the control side CPU 114 detects that the detection signal SG1 input to the input terminal TB1 of the control side CPU 114 has risen from the LOW state to the HI state, the HI state is 12.8 μs using the timer counter. It is determined whether or not it has been maintained. Specifically, the timer counter starts counting at the timing when the rising of the detection signal SG1 input to the input terminal TB1 of the control side CPU 114 from the LOW state to the HI state is detected. When counting is started, the timer counter counts time in units of 0.1 μs. If the HI state of the detection signal SG1 is not maintained until the timer counter has counted 12.8 μs, the timer counter is reset.

  Next, conditions for the control IC 148 to acquire the random number input to the input terminal TA3 of the control IC 148 will be described. In the timer interrupt process (FIG. 8) executed in a 1.49 ms cycle, the control IC 148 has a game startable period, and that the rising of the detection signal SG1 inputted to the control IC 148 is detected. Also, under the condition that “1” is set to the latched status 113, the random number input to the input terminal TA3 of the control IC 148 is acquired and used for the determination of the winning or losing of the winning combination.

  Since the random number input to the input terminal TA3 of the control IC 148 is updated to the random number for the operation of the start lever 41 at the timing when the latched status 113 is set to "1", the latched status 113 is "1". By setting the control IC 148 to acquire a random number on condition that the condition (1) is set, it is possible to prevent the control IC 148 from acquiring a random number before update (the previous random number).

  The timing at which the player operates the start lever 41 is any timing that is not influenced by the timing at which the timer interrupt process is performed by the control IC 148. Therefore, the timer interrupt process may be executed before 12.8 μs elapses after the detection signal SG1 input to the control circuit 103 rises. At this time, the random number input to the input terminal TA3 of the control IC 148 is the previous random number. In this case, since the condition that “1” is set to the latched status 113 is not satisfied, the control IC 148 does not acquire a random number. In this case, since the game is not started by the operation of the start lever 41 this time, the player needs to operate the start lever 41 again.

<Process Executed by Control IC 148>
Next, the process executed by the control IC 148 will be described. First, the main processing started in the control IC 148 when the supply of operation power to the control IC 148 is started will be described with reference to the flowchart in FIG. 7.

  In the main processing, first, initialization processing is executed (step S101). In the initialization process, the interrupt by the timer interrupt process is permitted, and furthermore, various initializations are performed on the register group in the control IC 148, the I / O device, and the like.

  After the initialization process is completed, it is determined whether the setting key is inserted into the setting key insertion hole 57 and the ON operation is performed (step S102). When the ON operation is performed (step S102: YES), if the reset button 56 is not ON when the power switch 55 is ON (step S103: NO), partial clear processing is executed. (Step S104) If the reset button 56 is turned on when the power switch 55 is turned on (Step S103: YES), all clear processing is executed (Step S105). That is, when the setting value of the slot machine 10 is changed without performing the operation for initializing the main RAM 144, the partial clear processing is executed, and the operation for initializing the main RAM 144 is performed. If done, all clear processing is executed.

  In the partial clear process, a partial area in the main RAM 144 is initialized, and in the all clear process, the entire area in the main RAM 144 is initialized. In the partial clear process, an area in the main side RAM 144 in which data indicating whether or not the BB state is stored, an area in which data indicating the total number of granted gaming media in the BB state is stored, and a type of lottery mode described later The respective areas of the main RAM 144 are cleared to “0” except the area in which the data indicating “1” is stored and the area in which the data indicating the setting value is stored. In this case, the area in which the winning combination is stored is cleared to "0". In the all clear process, all areas in the main RAM 144 are cleared to “0”, including the area excluded from the execution target of “0” clear in the partial clear process. As a result, even if the partial clear process is performed, the BB state is maintained in the state before the power is shut off, and when all the clear process is performed, the normal gaming state is entered regardless of the state before the power shut off.

  The present invention is not limited to the above configuration, and it may be configured not to be in the BB state when the partial clear processing is executed when the power is shut off in the BB state. In addition, even if the partial clear process is executed, the area in which the data indicating that the BB role has been won is stored may not be cleared to “0”.

  After the process of step S104 or step S105 is performed, a winning probability setting process is performed (step S106). In the winning probability setting process, the current setting value is read on the condition that the setting key is inserted and the ON operation is performed, and the current setting value is displayed on a predetermined display unit provided on the game panel 20. When the area for storing the data of the set value in the main side RAM 144 is initialized immediately before the winning probability setting process, the set value displayed on the predetermined display unit corresponds to “setting 1”. It is "one" to do. In the winning probability setting process, the setting value is updated by one each time the reset button 56 is operated, and the setting value after the updating is displayed on a predetermined display unit. When the reset button 56 is operated in a situation where the setting value is “setting 6”, the setting value is updated to “setting 1”. When the ON operation of the setting key is canceled after the start lever 41 is operated, the winning probability setting process is ended. In this case, the display of the setting value on the predetermined display unit is ended.

  After executing the winning probability setting process, the power recovery command is transmitted to the sub MPU 152 (step S107). The power recovery command is for causing the sub MPU 152 to recognize that execution of the main processing is finished and execution of the normal processing and timer interrupt processing becomes possible after the supply of operation power to the control IC 148 is started. It is a command. By receiving the power recovery command, the sub MPU 152 executes processing corresponding to the start of supply of the operating power. In this case, when the all clear process (step S105) is executed, the corresponding data is set in the power recovery command. When the power recovery command in which the data is set is received, the sub MPU 152 initializes the sub RAM 154, and when the power recovery command in which the data is not set is received, the sub MPU 152 initializes the sub RAM 154. do not do. After transmitting the power recovery command, the process proceeds to the normal processing (step S108). The normal processing will be described in detail later.

  When the setting key ON operation is not performed in the main processing (step S102: NO), the power recovery process of step S109 and subsequent steps is executed. The power recovery process is a process for restoring the state of the slot machine 10 to the state before the power is shut off. In the power recovery process, the main RAM 144 is checked to determine whether the setting value of the slot machine 10 is normal (step S109). Specifically, it is determined that the setting value is normal if the setting value is any of “setting 1” to “setting 6”, and is determined to be abnormal if the setting value is “0” or “7” or more. If the set value is normal, it is checked whether "1" is set in the power failure flag (step S110). The power failure flag is provided in the main side RAM 144, and when the processing at the time of a predetermined power failure is normally executed when the supply of the operation power to the control IC 148 is stopped, the power failure flag is "1". It will be set. If "1" is set in the power failure flag, it is checked whether the RAM determination value is normal (step S111). Specifically, the checksum value of the main side RAM 144 is checked to confirm whether the value is normal or not.

  When all the steps S109 to S111 make an affirmative determination, it means that the power failure process at the previous power failure is normally executed. In this case, the value of the stack pointer stored in the main RAM 144 is written to the stack pointer of the control IC 148, and the data saved in the main RAM 144 is restored to the register of the control IC 148 to power the register state of the control IC 148 Is restored to the state prior to the shutoff (step S112). Further, the power failure flag of the main RAM 144 is cleared to "0" (step S113). Thereafter, after a power recovery command is transmitted to the sub MPU 152 (step S114), the address is returned to the address before the power was turned off (step S115).

  On the other hand, when a negative determination is made in any of step S109 to step S111, the operation inhibiting process is executed. In the operation prohibiting process, the execution of the next timer interrupt process (FIG. 8) is inhibited (step S116), and all the output ports of the control IC 148 are cleared to "0" to prohibit all the actuators connected to the output port. An OFF state is set (step S117), and an error notification process for notifying a hole manager or the like of the occurrence of an error is executed (step S118). And it becomes an infinite loop. The operation prohibition process is canceled by executing the all clear process (step S105).

  Next, timer interrupt processing executed by the control IC 148 will be described with reference to the flowchart of FIG. The timer interrupt process is activated every 1.49 msec.

  In the register save process (step S201), the values of all the registers in the control IC 148 used in the normal process described later are saved in the main RAM 144. In step S202, it is checked whether "1" is set in the power failure flag, and when "1" is set in the power failure flag, the process proceeds to step S203, and processing upon power failure is executed. The power failure flag is set when the power failure signal from the power failure monitoring circuit of the power supply device 54 is input to the control IC 148. In the power failure process, it is first determined whether or not the transmission of the command has been completed. If the transmission has not been completed, the present process is terminated to return to the timer interrupt process and the transmission of the command is completed. When the transmission of the command is completed, the value of the stack pointer of the control IC 148 is stored in the main RAM 144. Thereafter, the output state of the output port of the control IC 148 is cleared, and all actuators not shown are turned off. Then, a determination value for determining whether or not the data in the main RAM 144 is normal is calculated when the power failure is eliminated, and is stored in the main RAM 144, and the subsequent RAM access is prohibited. After performing the above processing, the system enters an infinite loop in preparation for the fact that the power is completely shut off and the processing can not be performed.

  When "1" is not set to the power failure flag in step S202, various processes after step S204 are performed. In step S204, the watchdog timer clear processing is performed to initialize the value of the watchdog timer for monitoring the occurrence of a malfunction. In step S205, an interrupt end declaration process is performed to enable setting of the next timer interrupt to the control IC 148 itself. In step S206, start command setting processing (FIG. 9) is performed.

  In the start command setting process, "1" is set in the start command flag 144c (FIG. 6) on the condition that the random number corresponding to the operation of the start lever 41 this time is already input to the input terminal of the control IC 148. Be done. Then, when "1" is set in the start command flag 144c, a random number is acquired in step S501 of the lottery process (FIG. 11) described later. Here, with the random number corresponding to the operation of the start lever 41 this time, the detection signal SG1 rises from the LOW signal to the HI signal by the operation of the start lever 41 and the latch register from the random number counter 105 triggered by the rise of the detection signal SG1. It is a random number written to 102.

  On the other hand, when the random number inputted to the input terminal of the control IC 148 is not updated to the random number corresponding to the operation of the start lever 41 this time, "1" is not set to the start command flag 144c. In this situation, acquisition of random numbers by the control IC 148 is not performed. Here, in the situation where the random number corresponding to the operation of the start lever 41 this time is not acquired, 12.8 μsec has elapsed since the detection signal SG1 input to the input terminal of the control circuit 103 rises from the LOW signal to the HI signal. It is a situation where the start command setting process is executed before the start. Details of the start command setting process will be described later.

  In step S207, in order to rotate each of the reels 32L, 32M, 32R, a stepping motor control process is performed to drive each stepping motor. In step S208, the state of various sensors connected to the input port is read, and a sensor monitoring process is performed to monitor whether the read result is normal or not. In step S209, a timer subtraction process is performed to reduce the value of each counter or timer. In step S210, a counter process is performed to externally output the result of counting the number of betted gaming media and the number of payouts.

  In step S211, command output processing for transmitting various commands to the sub MPU 152 is performed. In step S212, port output processing is performed to output data corresponding to the I / O device from the input / output port. In step S213, the value of each register saved in the main RAM 144 in the previous step S201 is restored to the corresponding register in the control IC 148, respectively. Thereafter, in step S214, an interrupt permitting process for permitting the next timer interrupt is performed, and this series of timer interrupting process is ended.

  Next, the start command setting process executed in step S206 of the timer interrupt process (FIG. 8) will be described with reference to the flowchart of FIG. The start command setting process is executed by the control IC 148.

  First, in step S301, it is determined whether "1" is set in the start possibility flag 144a (FIG. 5). Here, the start possibility flag 144a is a flag arranged in the main side RAM 144, and is set to "1" when the game can be started, and is cleared to "0" when the game is started. It is a flag. Specifically, “1” is set in step S406 of the normal processing (FIG. 10) described later, and “0” is cleared in step S409. If the game can be started (step S301: YES), the process proceeds to step S302.

  In step S302, it is determined whether the signal storage flag 144d (FIG. 5) is "0". Here, the signal storage flag 144 d is a flag disposed in the main RAM 144. The signal storage flag 144d stores the state of the detection signal SG1 input to the control IC 148 at the timing when the start command setting process is performed. The signal storage flag 144d is a flag that is set to “1” when the detection signal SG1 is in the HI state and is cleared to “0” when the detection signal SG1 is in the LOW state.

  Specifically, "1" is set to the signal storage flag 144d in step S304 and step S315 of the start instruction setting process, and the signal storage flag 144d is cleared to "0" in step S314. In step S302, when the signal storage flag 144d is "0" (step S302: YES), the process proceeds to step S303.

  In step S303, it is determined whether the detection signal SG1 input to the control IC 148 is in the HI state. That a positive determination is made in step S303 means that the detection signal SG1 that has been in the LOW state in the previous start command setting process has become the HI state in the current start command setting process. That is, it means that the rising of the detection signal SG1 has been detected. When the rising of the detection signal SG1 is detected (step S303: YES), the signal storage flag 144d is set to "1" in step S304. As a result, it is stored that the detection signal SG1 input to the control IC 148 is in the HI state at the timing when the current start command setting process is performed.

  In the following step S305, it is determined whether "1" is set in the latched status 113 or not. Specifically, it is determined whether the numerical information output from the Q terminal of the latched status 113 and input to the input terminal of the control IC 148 is “1”.

  If “1” is set in the latched status 113 (step S305: YES), this means that the random number corresponding to the operation of the start lever 41 this time is already stored in the latch register 102. In step S306, "1" is set in start instruction flag 144c (FIG. 5). Here, the start command flag 144 c is a flag disposed in the main RAM 144. When "1" is set in the start command flag 144c, the processing after step S408 of the normal processing (FIG. 10) described later is executed and the game is started. The start command flag 144c is cleared to "0" in step S408 of the normal process (FIG. 10).

  In the following step S307, the error counter 144b (FIG. 5) is cleared to "0", the latched status 113 is cleared to "0" in step S308, and this start instruction setting process is ended. Here, the error counter 144 b is a counter disposed in the main RAM 144. The error counter 144b detects the rising of the detection signal SG1 input to the control IC 148 in a game startable state, and the control IC 148 determines whether “1” is set in the latched status 113 (see FIG. When the process of step S305 is performed, it is a counter which counts the number of times in which an event for which a negative determination is made occurs continuously.

  If "1" is not set in the latched status 113 (step S305: NO), "1" is added to the error counter 144b in step S309, and the value of the error counter 144b is "3" in step S310. It is judged about whether it is "." If the value of the error counter 144 b is “1” or “2” (step S 310: NO), the present start instruction setting process is ended as it is. On the other hand, when the value of the error counter 144b is "3" (step S310: YES), it means that the negative determination in step S305 has occurred three times consecutively. In this case, the connection between the start detection sensor 41a and the control circuit 103 may be disconnected, and the detection signal SG1 may not reach the control circuit 103. For this reason, the error counter 144b is cleared to "0" in step S311, and abnormality notification processing is performed in step S312 to enter an infinite loop.

  In the abnormality notification process, the upper lamp 64, the speaker 65, and the image display device 66 execute abnormality notification indicating that an abnormality has occurred, and an external output for abnormality is output to the hall computer of the game hall To be done. A state in which the game is not started even if the start lever 41 is operated by being informed that there is a possibility that the connection between the start detection sensor 41a and the control circuit 103 has been disconnected Can avoid the situation that the

  If "1" is not set in the start possibility flag 144a in step S301, or if the signal storage flag is not "0" in step S302, the timing when the current start command setting process is performed A process (steps S313 to S315) of storing the state of the detection signal SG1 input to the control IC 148 is executed.

  Specifically, in step S313, it is determined whether the detection signal SG1 input to the control IC 148 is in the LOW state. If the detection signal SG1 is in the LOW state (step S313: YES), the signal storage flag 144d is cleared to "0" in step S314. If the detection signal SG1 is in the HI state (step S313: NO), the signal storage flag 144d is set to "1" in step S315.

  In the start command setting process this time, when the rising of the detection signal SG1 input to the control IC 148 is not detected and the process of step S306 for setting the start command flag 144c to "1" is not performed A process of clearing the latched status 113 to "0" is performed.

  Specifically, after the negative determination in step S303, after the process of step S314 or after the process of step S315, the latched status 113 is cleared to "0" in step S316, and this start instruction setting process is performed. finish. In step S316, specifically, the control IC 148 transmits a pulse signal to the CLR terminal of the latched status 113. The latched status 113 is cleared to “0” in synchronization with the rising of the signal input to the CLR terminal.

  As described above, even when the rising of the detection signal SG1 is detected in the game startable state, when the latched status 113 is set to "0", the start instruction flag 144c should be kept to "0". Thus, it is possible to avoid a situation in which the random number stored in the latch register 102 prior to the operation of the start lever 41 this time is acquired by the control IC 148 as the current random number.

  In addition, when the start command setting process is executed before 12.8 μs elapses after the detection signal SG1 input to the control circuit 103 rises, “Latched status 113” is displayed after the start command setting process. 1 is set. Also, when noise of 12.8 μs or more mixes in only the input terminal of the control circuit 103, “1” is set in the latched status 113. When the state in which the latched status 113 is set to “1” is maintained for a long time, the possibility that the start lever 41 is operated in a state in which the latched status 113 is set to “1” becomes high.

  In this case, as in the case where the latched status 113 is not used, the control IC 148 may obtain an old random number, and a determination on the winning combination may be made based on the old random number. On the other hand, in all start command setting processing in which the rising edge of the detection signal SG1 input to the control IC 148 is not detected, the control IC 148 clears the latched status 113 by "0". It can reduce the possibility of getting old random numbers.

  Next, normal processing executed by the control IC 148 will be described based on the flowchart of FIG.

  First, in step S401, interrupt permission processing for permitting the next timer interrupt is performed, and in step S402, start waiting processing is performed. In the start waiting process, it is determined whether or not any replay win has occurred in the previous game. If one of the replay wins has occurred, an automatic insertion process is performed to automatically insert virtual medals of the same number as the previous bet number, and the start waiting process is ended. If no replay prize has occurred, it is determined whether or not the settlement button 51 has been operated, and if the settlement button 51 has been operated, medals of the same number as credited virtual medals are paid out Perform medal return processing.

  At the start timing of the medal return process, the start possible flag 144a (FIG. 5) and the start command flag 144c (FIG. 5) are cleared to “0”. By clearing the start possibility flag 144a to "0" at the start timing of the medal return process, the game startable period ends. This makes it possible to prevent the state where the start instruction flag 144c can be set to "1" in the start instruction setting process (FIG. 9) despite the fact that the medal has been returned.

  Further, the start command setting process (FIG. 9) is executed at the timing after the negative determination in step S407 and before the medal return process is performed in step S402, and the start command flag 144c is “1”. May be set. Assuming that the medal return process is executed with “1” set in the start command flag 144c and that “0” clear of the start command flag 144c is not performed, then the number of medal bets reaches the specified number. At the timing, even if the player does not operate the start lever 41, the game is started. On the other hand, the game is started before the player operates the start lever 41 by executing "0" clear of the start command flag 144c at the start timing of the medal return process. It can be avoided.

  After completion of the medal return process or when the settlement button 51 is not operated, it is determined whether or not the medal input or the credit input button 47 to 49 is operated between the previous start waiting process and the current start waiting process. If any one of the bet numbers is determined, the medal insertion process is performed to change the bet number, and the start waiting process is ended. If neither medal insertion nor the operation of the credit insertion buttons 47 to 49 is performed between the previous start waiting process and the current start waiting process, the start waiting process is ended.

  After execution of the start waiting process in step S402, it is determined in step S403 whether the bet number of medals has reached a specified number ("3" in the present embodiment), and the bet number has not reached a specified number If it is (step S403: NO), the process returns to the start waiting process of step S402. If the bet number has reached the specified number (step S403: YES), it is determined in step S404 whether "1" is set in the start possibility flag 144a.

  When "1" is not set to start possible flag 144a (step S404: NO), a pulse signal is transmitted to the CLR terminal of latched status 113 in step S405, and latched status 113 is "0". clear. Even if the latched status 113 is set to “1” before the game can be started by clearing the latched status 113 to “0” immediately after the game is ready to start the game, It becomes possible to grasp whether or not the start lever 41 has been operated after the startable state is obtained.

  After the latched status 113 is cleared to "0" in step S405, the start enable flag 144a is set to "1" in step S406. The start possibility flag 144a is a flag in which “1” is set when the game can be started, and is a flag that is cleared to “0” in step S409 with the start of the game.

  After making an affirmative determination in step S404 or after performing the process of step S406, it is determined whether or not "1" is set in the start instruction flag 144c in step S407. The start command flag 144 c is “1” when the start lever 41 is operated in a game startable state and a random number corresponding to the operation of the start lever 41 is input to the input terminal of the control IC 148. It is a flag to be set. If "1" is not set in the start instruction flag 144c (step S407: NO), the process returns to the start waiting process of step S402.

  If "1" is set in start instruction flag 144c (step S407: YES), the start instruction flag 144c is cleared to "0" in step S408, and the start possibility flag 144a is "0" in step S409. clear. When the start possibility flag 144a is cleared to "0", a negative determination is made in step S301 of the start command setting process (FIG. 9), and the processes after step S302 are not executed. "1" is not set to the flag 144c.

  In step S410, after the main line ML is validated, the acceptance prohibition process is executed. By executing the acceptance prohibition process, even if a medal is inserted into the medal insertion slot 45, the medal is discharged to the medal receiver 59 without being detected by the inserted medal detection sensor 45a. In step S411, a lottery process (hereinafter, also referred to as a lottery process for a combination) for performing lottery of a combination in the current game is executed, and in step S412, each reel 32L, 32M, 32R A reel control process is performed to drive control in a manner corresponding to the result.

  Here, the details of the reel control process will be described below. In the reel control process, first, a rotation start process for starting rotation of each of the reels 32L, 32M, 32R is performed. In the rotation start process, a predetermined wait time (for example, 4.1 seconds) elapses from the time when the rotation of the reels 32L, 32M, 32R corresponding to the result of the lottery process (FIG. 11) in the previous game is started. If it has not elapsed, it waits until the wait time elapses. The details of the lottery process of the role will be described later.

  If the wait time has elapsed, the wait time for the next game is reset, and rotation start information is set in the motor control storage area provided in the main RAM 144. By performing such processing, acceleration processing of the stepping motor is started in the stepping motor control processing of step S207 in the timer interrupt processing (FIG. 8), and the respective reels 32L, 32M, 32R start rotation. Thereafter, the process waits until the reels 32L, 32M, 32R rotate at a constant speed at a predetermined rotation speed, and the rotation start process is ended. In addition, when the rotational speed of each reel 32L, 32M, 32R becomes a constant speed, the control IC 148 can generate a stop command by lighting up a lamp (not shown) of each stop button 42 to 44. To the player etc.

  Thereafter, a stop command is generated on the condition that any one of the stop buttons 42 to 44 is operated and that the operated stop buttons 42 to 44 correspond to the rotating reel and the corresponding stop buttons 42 to 44. It is determined that It waits until the condition for generating the stop command is satisfied, and when the stop command is generated, the stop command is set. The stop instruction command is a command for causing the sub MPU 152 to recognize which stop button 42 to 44 is operated to generate a stop instruction. When the stop instruction command is set, stop control processing for stopping the rotating reel is performed.

  In the stop control process, the symbol number of the reaching symbol reaching the base position (the lower end in the present embodiment) is confirmed at the timing when the stop buttons 42 to 44 are operated. Specifically, the symbol number of the arrival symbol reaching the base position is confirmed by the excitation pulse number output from the time when the detection signal of the reel index sensor is input. Thereafter, based on the stop information stored in the main side RAM 144, the number of slips of the reel to be stopped this time is calculated.

  In the slot machine 10, as a stop mode for stopping the reels 32L, 32M, 32R, the stop mode for stopping the arrival symbol reaching the base position as it is when the stop buttons 42 to 44 are operated To stop after sliding 1 reel of reels, stop after stopping by sliding 2 reels, stopping after sliding 3 stops, and stopping after sliding 4 reels Five patterns of stopping modes are prepared, including stopping modes. In the present stop control processing, any value of “0” to “4” is calculated as the slip number based on the stop information stored in the main side RAM 144.

  Thereafter, the calculated slip number is added to the symbol number of the arrival symbol, and the symbol number of the stop symbol to be actually stopped at the base position is determined. Then, it is determined whether or not the symbol number of the arrival symbol of the reel to be stopped this time and the symbol number of the stop symbol are equal, and when equal, the reel stop processing is performed to stop the rotation of the reel. Thereafter, it is determined whether all the reels 32L, 32M, 32R have stopped. If all the reels 32L, 32M, 32R are not stopped, stop information second setting processing is performed, and the process waits until the condition for generating the stop command is satisfied, and when the stop command is generated, the stop command is performed again Set a command and perform stop control processing.

  Here, the stop information is information for making the stop mode of each reel 32L, 32M, 32R correspond to the result of the lottery process (FIG. 11) of the winning combination, and by using the stop information When the stop buttons 42 to 44 are operated to stop, it is possible to calculate the slip number (specifically, "0" to "4") for the arrival symbol reaching the base position. As the stop information, slip number data indicating the correspondence between each symbol and the slip number is stored in advance in the main side ROM 143 in association with each lottery result and the stop order of each reel 32L, 32M, 32R. However, the present invention is not limited to this, and the configuration may be such that slip number data corresponding to each lottery result and the stop order of each reel 32L, 32M, 32R may be derived during rotation of the reels 32L, 32M, 32R, etc. .

  As the process for setting the above-mentioned stop information, the first stop information setting process executed in step S509 of the lottery process (FIG. 11) described later and the second stop information setting process executed in the reel control process And exist. In the stop information first setting process, the stop information is set according to the result of the lottery process of the winning combination. In the stop information second setting process, the stop information stored in the main RAM 144 in the stop information first setting process or the previous stop information second setting process is changed after the reel is stopped. In the stop information second setting process, the stop information is changed based on the set winning data, the stop order of the reels 32L, 32M, 32R, and the stop appearance of the stopped reels 32L, 32M, 32R. Do.

  When it is determined that all the reels 32L, 32M, 32R are stopped, a winning determination process is executed. In the winning determination process, the types of symbols stopped on the main line ML in each of the reels 32L, 32M, 32R are grasped. If the combination of symbols stopped and displayed on the main line ML in each of the reels 32L, 32M, 32R is a combination of symbols corresponding to the winning combination in the lottery process of the current combination, the winning combination is The winning response processing is executed as the winning is established. In the winning response process, if the winning is a small winning combination, the number of medals to be paid out is set in the main RAM 144 so as to enable the awarding of game media in the medium awarding process. On the other hand, if the winning is a replay winning, a flag setting process for executing the automatic insertion process in the next start waiting process (the process of step S402 in the normal process (FIG. 10)) is executed.

  After the winning determination process is executed, a winning result command is set as an output target to the sub MPU 152. The winning result command includes data indicating whether or not the winning is established this time, and also includes data indicating the type of the winning when the winning is established. Further, the winning result command includes data indicating which one of the normal mode, the first RT mode, and the second RT mode is the lottery mode when the current game is over.

  Returning to the description of the normal processing (FIG. 10), after performing the reel control processing in step S412, the medium application processing is executed in step S413. In the medium granting process, when a small winning combination is established in the current game, a process for giving the player a number of game media corresponding to the small winning combination is executed. Specifically, when a virtual medal is awarded, a value corresponding to the small winning combination is added to the credit counter provided in the main RAM 144, and the value of the credit counter reaches the upper limit storage number. The drive control of the hopper device 53 is performed so that medals for a few minutes exceeding the upper limit storage number are paid out to the medal receiver 59.

  After executing the medium giving process in step S413, in step S414, the game ending process is executed to enable setting of the gaming state corresponding to the result of the current game, and in step S415 the slot machine Execute an external output setting process for outputting the state of 10 to the management computer of the gaming hall. Then, in step S416, a reception permission process is executed, and the process returns to step S401. By executing the acceptance permission process, the medal inserted from the medal insertion slot 45 is collected by the hopper device 53 after being detected by the inserted medal detection sensor 45a.

  Next, the lottery process performed in step S411 of the normal process (FIG. 10) will be described with reference to the flowchart of FIG.

  First, in step S501, random number acquisition processing is executed. In the random number acquisition process, a random number to be used when performing a pass / fail determination of the winning combination is acquired. Specifically, a random number that is a 16-digit binary number is acquired by acquiring numerical information output from the Q terminals of the 16 latch register D-FFs 102 a to 102 p and input to the input terminal TA 3 of the control IC 148 Get numerical information of In the subsequent step S502, a lottery table for performing a pass / fail determination of the winning combination is read out from the main ROM 143.

  Here, in the slot machine 10, there are prepared in advance six probability of winning from “setting 1” to “setting 6”, and the setting key is inserted into the setting key insertion hole 57 to perform an ON operation and a predetermined operation. By performing the above, it is possible to set which lottery process is to be performed based on which winning probability. It should be noted that the “provision n + 1” is a winning probability that is more advantageous for the player than the “prevention n”. In addition, there are three types of lottery modes in which the lottery table is different in the control IC 148 even if the setting value is the same stage, that is, the normal mode, the first RT mode, and the second RT mode. In addition, as a game state, a BB state exists separately from the state of each of these lottery modes. In step S502, a lottery table corresponding to the combination of the current setting value and the current gaming state is selected.

  A lottery table corresponding to each of the normal mode, the first RT mode, and the second RT mode will be described by taking the case of “setting 3” and the non-BB state as an example. First, the normal mode lottery table selected in the normal mode will be described. FIG. 12 is an explanatory view for explaining the lottery table for the normal mode. In the following description, the explanatory view of FIG. 13 is referred to as appropriate.

  In the normal mode lottery table, as shown in FIG. 12, index values IV are set, and in each index value IV, a winning combination is associated with each other and a point value PV is set. The point value PV defines the winning probability of the corresponding lottery combination in relation to the maximum value (“65535”) of the free run counter.

  Specifically, bell winning data and first compensation winning data are set to index value IV = 1. In the case of winning with index value IV = 1, as shown in FIG. 13, the second stop target and the third stop target are selected when the first stop (reel on which the stop command is generated first) is the left reel 32L. Regardless of the type of reel and the operation timing of each stop button 42 to 44, the bell winning is surely generated, and in other cases, the first compensating winning is surely generated.

  In the slot machine 10, reel control is performed on each of the reels 32L, 32M, 32R that can slide up to a maximum of four symbols after the stop buttons 42 to 44 are operated. In other words, reel control is performed for each of the reels 32L, 32M, 32R to stop the operation until the specified time (190 msec) elapses after the stop buttons 42 to 44 are operated. By performing such reel control, it becomes possible to make it easier to achieve a prize corresponding to the winning combination, and to avoid that a prize corresponding to the combination not winning is established. It becomes possible. However, since the amount of rotation of the reels 32L, 32M, 32R that can be slipped is limited as described above, a combination of symbols for achieving a winning is formed on one reel 32L, 32M, 32R. Depending on the operation timing of the corresponding stop buttons 42 to 44, if there are five or more symbols between the component symbols, it may happen that the component symbols do not stop on the main line ML (the event is also called "dropout") Say). The first to third compensation prizes, the bell prize, the watermelon prize, and the various replay prizes are prize modes in which no dropout occurs when the reels 32L, 32M, and 32R are stopped in the corresponding order. The 1BB prize and the second BB prize are prize modes in which a drop may occur depending on the stop operation timing of the stop buttons 42 to 44 with respect to the rotational positions of the reels 32L, 32M, 32R.

  In the index value IV = 2, as shown in FIG. 12, bell winning data and second compensation winning data are set. When the index value IV = 2 is won, as shown in FIG. 13, when the first stop is the middle reel 32M, the types of the second stop target and the third stop target reel and the respective stop buttons 42 to 44. Regardless of the operation timing of the bell winning combination is reliably established, otherwise, the second compensation winning combination is reliably established.

  As shown in FIG. 12, the bell winning data and the third compensation winning data are set to the index value IV = 3. In the case of winning with index value IV = 3, as shown in FIG. 13, when the first stop is the right reel 32R, the types of second stop target and third stop target reels and the respective stop buttons 42 to 44. The bell winning is surely established regardless of the operation timing, and in the other cases, the third compensating winning is surely established.

  As shown in FIG. 12, only watermelon winning data is set to the index value IV = 4. In the case of winning with the index value IV = 4, as shown in FIG. 13, the watermelon winning is achieved regardless of the stopping order of the reels 32L, 32M, 32R. Further, when the index value IV = 4, the watermelon winning is surely achieved regardless of the operation timing of each stop button 42 to 44.

  As shown in FIG. 12, only cherry winning data is set to the index value IV = 5. In the case of winning with the index value IV = 5, as shown in FIG. 13, cherry winning may be achieved regardless of the stopping order of the reels 32L, 32M, 32R. However, depending on the operation timing of the left stop button 42 with respect to the rotational position of the left reel 32L, there is a possibility that the cherry winning is not established.

  As shown in FIG. 12, the first BB winning data is set to the index value IV = 6. When winning with the index value IV = 6, as shown in FIG. 13, the first BB prize can be established regardless of the stop order of the reels 32L, 32M, 32R. However, depending on the operation timing of each stop button 42 to 44, the first BB winning may not be established. Further, as shown in FIG. 12, the second BB winning data is set to the index value IV = 7. In the case of winning with the index value IV = 7, as shown in FIG. 13, the second BB winning can be established regardless of the stop order of the reels 32L, 32M, 32R. However, depending on the operation timing of each stop button 42 to 44, there is a possibility that the second BB winning is not established.

  Here, the winning data other than the first BB winning data and the second BB winning data is erased in the winning game regardless of whether or not the winning is achieved, and is held in the games following the winning game. It does not go over. On the other hand, in the first BB win data and the second BB win data, a corresponding BB win is established even in the game following the winning game except when the main RAM 144 is cleared. Memory is kept until. In this case, in the game in which the first BB win data or the second BB win data is carried over, the index value IV corresponding to the first BB win data and the second BB win data is excluded from the lottery targets. This makes it possible to prevent the BB winning data from being newly stored despite the fact that the first BB winning data or the second BB winning data is already stored, and a plurality of BB winning data are accumulated. It is possible to prevent it from being stored.

  As shown in FIG. 12, the normal replay winning data and the first RT replay winning data are set to the index values IV = 8-11. In this case, when the index value IV = 8 is won, as shown in FIG. 13, the first stop is the middle reel 32M, and the second stop (the reel where the second stop command is issued) is the left reel 32L. If the third stop (reel where the stop command is finally generated) is the right reel 32R, the first RT replay winning is surely established regardless of the operation timing of each stop button 42 to 44, otherwise In the above, the normal replay winning is surely established regardless of the operation timing of each stop button 42-44. When the index value IV = 9, the first stop is the middle reel 32M, the second stop is the right reel 32R, and the third stop is the left reel 32L. The first RT replay winning is surely established regardless of the operation timing of 44, and in the case other than that, the normal replay winning is surely established regardless of the operation timing of each stop button 42 to 44. When the index value IV = 10, the first stop is the right reel 32R, the second stop is the left reel 32L, and the third stop is the middle reel 32M. The first RT replay winning is surely established regardless of the operation timing of 44, and in the case other than that, the normal replay winning is surely established regardless of the operation timing of each stop button 42 to 44. When the index value IV = 11, the first stop is the right reel 32R, the second stop is the middle reel 32M, and the third stop is the left reel 32L. The first RT replay winning is surely established regardless of the operation timing of 44, and in the case other than that, the normal replay winning is surely established regardless of the operation timing of each stop button 42 to 44.

  When the normal mode lottery table shown in FIG. 12 is selected, the probability of winning when index value IV = 1, the probability of winning when index value IV = 2, and the probability of index value IV = 3 The probability of becoming is approximately 1 / 5.0, and the probability of winning at index value IV = 4 is approximately 1/77, and the probability of winning at index value IV = 5 is approximately 1 / 423, and the probability of winning in the case of index value IV = 6 is about 1/131, the probability of winning in the case of index value IV = 7 is about 1/655, and index value IV = 8 The probability of winning at the time of, the probability of winning at the index value IV = 9, the probability of winning at the index value IV = 10, and the probability of winning at the index value IV = 11 are each about It is /28.0.

  Here, in the normal mode lottery table, as described above, first RT replay winning data is set as the winning data of index value IV = 8 to 11 in addition to the normal replay winning data (see FIG. 12). The probability of winning any of these index values IV = 8-11 is approximately 1 / 7.0. When the index value IV is 8 to 11, the reels 32L, 32M, and 32R stop in the order corresponding to the winning combination of the first stop, the second stop, and the third stop. When the order is reached, the first RT replay winning is established, and the lottery mode shifts from the normal mode to the first RT mode. When the first RT mode is entered, the lottery table referred to in the lottery process (FIG. 11) is the first RT mode lottery table.

  Next, the first RT mode lottery table selected in the case of the “setting 3” and the first RT mode will be described. 14 and 15 are explanatory diagrams for explaining the first RT mode lottery table.

  In the first RT mode lottery table, as shown in FIG. 14, the winning combination data set to each of the index values IV = 1 to 7 and the winning probability of each index value IV are the lottery table for the normal mode (FIG. It is the same as 12). In this case, the combination that enables the provision of game media is set to index value IV = 1 to 5, and the winning combination data and each winning probability set to each of index values IV = 1 to 5 are By being the same, the types of roles that enable the provision of game media and the winning probability of those roles are mutually the same in each of the normal mode and the first RT mode. Further, BB winning data is set to the index value IV = 6 to 7 similarly to the normal mode lottery table, and the winning probability is the same as the normal mode lottery table. That is, the probability of winning in any of the BB roles in the normal mode and the first RT mode is the same.

  The winning combination data set to index value IV = 8 or later is different from the normal mode. Specifically, in the first RT mode lottery table, as shown in FIG. 14, second RT replay winning data is set as winning data of index value IV = 8 to 11 in addition to normal replay winning data. The probability of winning any of these index values IV = 8-11 is approximately 1 / 10.1. When the index value IV = 8 is won, as shown in FIG. 15, the first stop is the middle reel 32M, the second stop is the left reel 32L, and the third stop is the right reel 32R. The second RT replay winning occurs reliably regardless of the operation timing of each stop button 42 to 44. In other cases, the normal replay winning occurs reliably regardless of the operation timing of each stop button 42 to 44. If the index value IV = 9, the first stop is the middle reel 32M, the second stop is the right reel 32R, and the third stop is the left reel 32L. It reliably occurs regardless of the operation timing of each stop button 42-44, and in other cases, the normal replay winning occurs reliably regardless of the operation timing of each stop button 42-44. When the index value IV = 10, the first stop is the right reel 32R, the second stop is the left reel 32L, and the third stop is the middle reel 32M. It reliably occurs regardless of the operation timing of each stop button 42-44, and in other cases, the normal replay winning occurs reliably regardless of the operation timing of each stop button 42-44. When the index value IV = 11, the first stop is the right reel 32R, the second stop is the middle reel 32M, and the third stop is the left reel 32L. It reliably occurs regardless of the operation timing of each stop button 42-44, and in other cases, the normal replay winning occurs reliably regardless of the operation timing of each stop button 42-44. In the first RT mode, the stop order corresponds to the winning combination in which the stop order of the first stop, the second stop, and the third stop of the reels 32L, 32M, 32R is won by one of the index values IV = 8-11. When it becomes, the second RT replay winning is established, and the lottery mode shifts from the first RT mode to the second RT mode. When shifting to the second RT mode, the lottery table referred to in the lottery process (FIG. 11) is the second RT mode lottery table.

  In the first RT mode lottery table, as shown in FIG. 14, as the winning data of the index value IV = 12 to 17, first fall replay replay winning data is set in addition to the normal replay winning data. The probability of winning any of these index values IV = 12-17 is approximately 1 / 10.9.

  If the first RT mode lottery table is won with the index value IV = 12, as shown in FIG. 15, the first stop is the left reel 32L, the second stop is the middle reel 32M, and the third stop is In the case of the right reel 32R, the normal replay winning occurs reliably regardless of the operation timing of each stop button 42 to 44, and in the other cases, the first fall replay replay winning at the operation timing of each stop button 42 to 44 Certainly occur regardless of the situation. When the index value IV = 13, the first stop is the left reel 32L, the second stop is the right reel 32R, and the third stop is the middle reel 32M. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the first falling replay win occurs reliably regardless of the operation timing of the respective stop buttons 42 to 44. Also, when the index value IV = 14, when the first stop is the middle reel 32M, the second stop is the left reel 32L, and the third stop is the right reel 32R, the normal replay winning is each It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the first falling replay win occurs reliably regardless of the operation timing of the respective stop buttons 42 to 44. When the index value IV = 15, the first stop is the middle reel 32M, the second stop is the right reel 32R, and the third stop is the left reel 32L. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the first falling replay win occurs reliably regardless of the operation timing of the respective stop buttons 42 to 44. If the index value IV = 16, the first stop is the right reel 32R, the second stop is the left reel 32L, and the third stop is the middle reel 32M. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the first falling replay win occurs reliably regardless of the operation timing of the respective stop buttons 42 to 44. When the index value IV = 17, the first stop is the right reel 32R, the second stop is the middle reel 32M, and the third stop is the left reel 32L. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the first falling replay win occurs reliably regardless of the operation timing of the respective stop buttons 42 to 44. When the first fall replay winning combination is established, the lottery mode shifts to the normal mode. When the mode is shifted to the normal mode, the lottery table referred to in the lottery process (FIG. 11) is a lottery table for the normal mode.

  Only normal replay winning data is set to the index value IV = 18 in the first RT mode lottery table. The probability of winning in the index value IV = 18 is set higher than the probability of winning in other roles, and specifically, it is won in about 1 / 6.7. When the index value IV = 18 is won, the normal replay prize is established regardless of the stop order of the reels 32L, 32M, 32R and the stop operation timing of each reel 32L, 32M, 32R. .

  In the first RT mode lottery table, a combination of index values IV = 8 to 18 is set to enable the establishment of the replay winning. Then, the winning probability of these winning combinations is set to the probability as described above, so that the winning probability (hereinafter also referred to as the replay probability) of the winning combinations enabling the establishment of the replay winning in the first RT mode is approximately 1 It is /2.9. On the other hand, the replay probability in the normal mode is about 1 / 7.0. That is, the first RT mode is a gaming state in which the probability of replay is higher than that in the normal mode.

  Next, the second RT mode lottery table selected in the case of the “setting 3” and the second RT mode will be described. 16 and 17 are explanatory diagrams for explaining the second RT mode lottery table.

  In the second RT mode lottery table, as shown in FIG. 16, the winning combination data set to each of the index values IV = 1 to 7 and the winning probability of each index value IV are the lottery table for the normal mode (FIG. 12) and the first RT mode lottery table (FIG. 14). In this case, the combination that enables the provision of game media is set to index value IV = 1 to 5, and the winning combination data and each winning probability set to each of index values IV = 1 to 5 are By being the same, the types of roles that enable the provision of game media and the winning probability of those roles are mutually the same in the normal mode, the first RT mode, and the second RT mode. Further, BB winning data is set to index value IV = 6 to 7 similarly to the lottery table for the normal mode and the lottery table for the first RT mode, and the winning probability thereof is the lottery table for the normal mode and the lottery for the first RT mode. It is identical to the table. That is, the probability of winning in any of the BB roles in the normal mode, the first RT mode, and the second RT mode is the same.

  The winning combination data set to index value IV = 8 or later is different from the normal mode and the first RT mode. More specifically, in the second RT mode lottery table, as shown in FIG. 16, second fall replay replay winning data is set as winning data of index value IV = 8 to 13 in addition to normal replay winning data. . The probability of winning any of these index values IV = 8-13 is approximately 1 / 5.5.

  In the case of winning with index value IV = 8 in the second RT mode lottery table, as shown in FIG. 17, the first stop is the left reel 32L, the second stop is the middle reel 32M, and the third stop is In the case of the right reel 32R, the normal replay winning occurs reliably regardless of the operation timing of each stop button 42 to 44, and in the other cases, the second falling replay replay winning at the operation timing of each stop button 42 to 44 Certainly occur regardless of the situation. When the index value IV = 9, the first stop is the left reel 32L, the second stop is the right reel 32R, and the third stop is the middle reel 32M. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the second falling replay winning combination reliably occurs regardless of the operation timings of the respective stop buttons 42 to 44. When the index value IV = 10, the first stop is the middle reel 32M, the second stop is the left reel 32L, and the third stop is the right reel 32R. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the second falling replay winning combination reliably occurs regardless of the operation timings of the respective stop buttons 42 to 44. When the index value IV = 11, the first stop is the middle reel 32M, the second stop is the right reel 32R, and the third stop is the left reel 32L. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the second falling replay winning combination reliably occurs regardless of the operation timings of the respective stop buttons 42 to 44. When the index value IV = 12, the first stop is the right reel 32R, the second stop is the left reel 32L, and the third stop is the middle reel 32M. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the second falling replay winning combination reliably occurs regardless of the operation timings of the respective stop buttons 42 to 44. When the index value IV = 13, the first stop is the right reel 32R, the second stop is the middle reel 32M, and the third stop is the left reel 32L. It reliably occurs regardless of the operation timing of the stop buttons 42 to 44, and in the other cases, the second falling replay winning combination reliably occurs regardless of the operation timings of the respective stop buttons 42 to 44. When the second fall replay winning combination is established, the lottery mode shifts to the first RT mode. When the first RT mode is entered, the lottery table referred to in the lottery process (FIG. 11) is the first RT mode lottery table.

  Only the normal replay winning data is set to the index value IV = 14 in the second RT mode lottery table. The probability of winning in the index value IV = 14 is set higher than the probability of winning in other roles, and specifically, it is won in about 1 / 6.3. When the index value IV = 14 is won, the normal replay winning will be established regardless of the stop order of the reels 32L, 32M, 32R and the stop operation timing of each reel 32L, 32M, 32R. .

  In the second RT mode lottery table, an index value IV of 8 to 14 is set with a winning combination enabling the establishment of a replay winning combination. Then, the winning probability of these winning combinations is set to the probability as described above, so that the winning probability (hereinafter also referred to as the replay probability) of the winning combinations enabling the establishment of the replay winning in the second RT mode is approximately 1 It is /2.9. On the other hand, the replay probability in the normal mode is about 1 / 7.0. That is, the second RT mode is a gaming state in which the probability of replay is higher than that in the normal mode. On the other hand, the replay probability in the first RT mode is approximately 1 / 2.9. That is, the second RT mode has the same replay probability as the first RT mode. However, the configuration is not limited to the configuration in which the replay probability in the first RT mode is the same as the replay probability in the second RT mode. For example, although the replay probability is slightly different between the first RT mode and the second RT mode The second RT mode may have a higher replay probability than the first RT mode, or the first RT mode may have a higher replay probability than the second RT mode.

  The lottery table for the normal mode, the lottery table for the first RT mode, and the lottery table for the second RT mode are set in one-to-one correspondence with each of "setting 1" to "setting 6", and the setting value is high. Although the winning probability of the BB combination is higher as it is, the replay probability set in each lottery mode is the same or substantially the same regardless of which setting value. In addition, in a situation where one of the BB roles has been won, the first BB role and the second BB may be in any of the normal mode, the first RT mode, and the second RT mode so that the BB roles are not won in duplicate. The part is excluded from the lottery object. In addition to the normal mode lottery table, the first RT mode lottery table, and the second RT mode lottery table, the main ROM 143 also refers to the lottery process (FIG. 11) when in the first BB state or the second BB state. A lottery table for BB is stored. In the lottery table for BB, only three types of roles of bell, watermelon and normal replay are set as the lottery target roles, the probability of winning the bell is set to about 1/2, and the watermelon is won The probability is set to about 1⁄4, and the winning probability of the replay player is usually set to about 1⁄4. As a result, in the BB state, the expected number of game media to be provided per unit game number is higher than in other game states.

  Returning to the description of the lottery process (FIG. 11), after the lottery table is selected in step S502, the index value IV is set to "1" in step S503, and the determination value used when determining the success or failure of the winning combination in step S504. Set the DV. In this determination value setting process, a new determination value DV is set by adding the point value PV corresponding to the current index value IV to the current determination value DV. In the first determination value setting process, the random number value acquired in step S501 is set as the current determination value DV, and the point value PV corresponding to “1”, which is the current index value IV, is added to the random number value. A new judgment value DV is set.

  In the subsequent step S505, it is determined whether or not the combination corresponding to the index value IV is accepted. It is determined whether or not the determination value DV exceeds “65535” in the success or failure determination of the winning combination. If "65535" is exceeded (step S505: YES), in step S506, the winning data acquisition process for setting the data of the winning combination corresponding to the index value IV at that time in the main RAM 144 is executed. Do. In the winning data acquisition process, all the winning data set for the current index value IV in the reference lottery table is set in the main RAM 144. If the winning data is set, if the winning data is winning data other than BB winning data, “0” is cleared after the end of the current game regardless of the presence or absence of winnings corresponding to the winning data. In the case of winning data, "0" is cleared when a winning is achieved.

  If the determination value DV does not exceed "65535" (step S505: NO), it means that the role corresponding to the index value IV has been dropped. In such a case, 1 is added to the index value IV in step S507, and it is determined in step S508 whether or not there is a combination corresponding to the index value IV, that is, whether or not there is a determination target to be determined. . Specifically, it is determined whether the index value IV to which 1 is added has exceeded the maximum value of the index values IV set in the lottery table. If there is a determination target to be determined whether the determination is yes or no, the process returns to step S504, and the determination of the combination is continued. At this time, in step S504, a point value PV corresponding to the current index value IV is added to the determination value DV (that is, the current determination value DV) used for the determination of the success or failure of the previous combination to obtain a new determination value DV. In step S505, it is determined whether or not a winning combination has been made on the basis of the determination value DV.

  When the process of step S506 is executed, or when a negative determination is made in step S508, it means that the determination on the winning combination of the winning combination has ended. In this case, in step S509, stop information first setting processing for setting stop information for reel stop control is executed. The stop information set here is information for making the stop mode of each reel 32L, 32M, 32R correspond to the result of the lottery process of the winning combination.

  In the subsequent step S510, a game start command is set as a transmission target to the sub MPU 152. The game start command is a command for causing the sub MPU 152 to recognize that a new game has been started, and is a command for causing the sub MPU 152 to recognize the result of the lottery process of the present combination in the control IC 148. It is transmitted to the sub MPU 152 in the command output process (step S212) in the timer interrupt process (FIG. 8).

  Next, the processing at the end of the game executed in step S414 of the normal processing (FIG. 10) will be described with reference to the flowchart of FIG. Incidentally, the response processing at the end of the game is executed when the rotation of all the reels 32L, 32M, 32R is stopped in each game.

  First, in step S601, it is determined whether or not a winning corresponding to the winning BB has been won in a situation in which the first BB or second BB has been won, and the corresponding winning is achieved (step In step S601, the BB start processing is executed in step S602. In the BB start process, if the first BB winning is achieved, the first BB flag provided in the main RAM 144 is set to "1", and the end reference number counter provided in the main RAM 144 is in the first BB state. Set "41" which is the end reference number. On the other hand, if the second BB winning is achieved, the second BB flag provided in the main RAM 144 is set to "1", and the end reference number counter of the main RAM 144 is the end reference number 89 for the second BB state. Set ".

  The first BB flag is a flag for specifying in the control IC 148 that the state is the first BB state, and the second BB flag is a flag for specifying in the control IC 148 that the state is the second BB state. When “1” is set in the first BB flag or the second BB flag, the BB lottery table is referred to in the lottery process of the winning combination (FIG. 11). The end reference number counter is a counter for specifying in the control IC 148 whether or not the total number of gaming media provided in the BB state has reached the end reference number which is the end condition of the BB state. The value set in the end reference number counter is decremented by the number of game media provided by the winning, each time a winning for the provision of game media is established in the BB state. Then, when the value of the end reference number counter after the subtraction becomes “0”, the control IC 148 determines that the rotation of the reels 32L, 32M, 32R of the final game in the current BB state is stopped. In the BB state, when a prize for awarding a predetermined number of gaming media is established, the value of the end reference counter is “0” when a part of the predetermined number is subtracted from the end reference counter. Even in the case of, a predetermined number of game media are provided.

  If a negative determination is made in step S601, it is determined in step S603 whether or not the first BB state or the second BB state is selected, and the case is one of the first BB state and the second BB state In (step S603: YES), processing for BB is executed in step S604, and the corresponding processing at the end of the game is ended. In the process for BB, when the addition of game media occurs in the current game, the value of the end reference number counter of the main side RAM 144 is subtracted correspondingly, and the value of the end reference number counter after subtraction is If it is "0", processing is executed to end the BB state.

  If the BB winning condition is not established but the BB condition is not established (step S601 and step S603: NO), it is determined in step S605 whether or not the promotion condition is established, and the promotion condition is established. If it is (step S605: YES), in step S606, the process of changing the lottery table at the time of promotion is executed, and the corresponding process at the end of the main game is ended. Specifically, when it is specified that the first RT replay win has occurred in the current game, the first RT mode is selected by changing the lottery table to be used in the lottery process of the winning combination to the first RT mode lottery table. The second RT is made by switching to the mode and changing the lottery table to be used in the lottery process of the winning combination to the second RT mode lottery table when it is determined that the second RT replay win has occurred in the current game. Switch to mode.

  If a negative determination is made in step S605, it is determined in step S607 whether a fall condition is satisfied, and if a fall condition is not satisfied (step S607: NO), the process is directly performed. The processing at the end of the game ends. If the fall condition is satisfied (step S607: YES), in step S608, the process of changing the lottery table at the time of fall is executed, and the corresponding process at the end of the game is ended. Specifically, when it is specified that the second fall replay prize has occurred in the current game, the lottery table to be used in the lottery process of the winning combination is changed to the first RT mode lottery table. When it is determined that the first fall replay prize has occurred in the current game by transitioning to the 1 RT mode, the lottery table to be used in the lottery process of the winning combination is changed to the lottery table for the normal mode. Switch to mode.

<Management operation in control side CPU 114>
Next, the management operation in the control side CPU 114 will be described with reference to the flowchart of FIG.

  First, in step S701, the process waits until the detection signal SG1 input to the control CPU 114 is in the LOW state. When the detection signal SG1 input to the control side CPU 114 is in the LOW state (step S701: YES), the detection signal SG1 input to the control side CPU 114 is in the HI state in step S702. Wait up to. When the detection signal SG1 input to the control side CPU 114 is in the HI state (step S702: YES), the process proceeds to step S703. That is, when the control CPU 114 detects that the detection signal SG1 input to the control CPU 114 has risen from the LOW state to the HI state, the process proceeds to step S703.

  In step S703, the timer counter is used to start counting the time during which the HI state of the detection signal SG1 input to the control CPU 114 is continued. The time for which the HI state is continued is counted in units of 0.1 μs. In step S704, it is determined whether or not the detection signal SG1 is in the HI state. If it is in the HI state (step S704: YES), the detection signal SG1 input to the control CPU 114 is in step S705. It is determined whether 12.8 μs has elapsed since the HI state.

  When 12.8 μs has not elapsed since the detection signal SG1 input to the control side CPU 114 is in the HI state in step S705, the process returns to the determination of step S704. Then, if 12.8 μs have elapsed since the detection signal SG1 input to the control side CPU 114 has become HI state in step S705, the process proceeds to step S706.

  In step S706, counting of the time using the timer counter is stopped and the timer counter is reset, and in step S707, a latch signal which is a pulse signal is transmitted to the CLK terminals of the latch register D-FFs 102a to 102p. . Thereby, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102.

  In the following step S708, "1" is set to the latched status 113, and the process returns to step S701. Specifically, the control side CPU 114 has latched from the output terminal TB3 on condition that the signal output from the Q terminal 113a of the latched status 113 and input to the input terminal TB2 of the control side CPU 114 is in the LOW state. The signal output to the T terminal 113b of the status 113 is raised. Thereby, “1” is set to the latched status 113. When the signal output from the Q terminal 113a of the latched status 113 and input to the input terminal TB2 of the control side CPU 114 is in the HI state, the T terminal 113b of the latched status 113 is output from the output terminal TB3. Maintain the output signal. As a result, the state in which "1" is set to the latched status 113 is maintained.

  When a negative determination is made in step S704, that is, before 12.8 μs elapses from when the detection signal SG1 input to the control side CPU 114 is in the HI state, the detection signal SG1 is in the LOW state. When returning, it is considered that the detection signal SG1 has risen due to the fact that a short noise of less than 12.8 μs is mixed in the input terminal of the control side CPU 114. In this case, in step S709, the timer counter is stopped counting and the timer counter is reset, and the process returns to step S702.

  As described above, “1” is set to the latched status 113 under the condition that the control side CPU 114 detects the rising of the detection signal SG1 input to the control side CPU 114. Therefore, even when the start lever 41 is depressed and continued for a long time, a pulse signal is applied to the CLK terminals of the latch register D-FFs 102a to 102p in response to one depression. While a certain latch signal is transmitted, "1" is set to the latched status 113 only once. Even if the pressing operation of the start lever 41 is continued for a long time, the latch signal is not repeatedly transmitted.

  In addition, the control side CPU 114 sets “1” to the latched status 113 even during the game. However, in the start command setting process (FIG. 9), the control IC 148 is configured to set “1” in the start command flag 144c under the condition that the game can be started. The control IC 148 is configured to clear the latched status 113 to “0” when the start timing of the game startable period is reached in the normal process (FIG. 10). Therefore, even if "1" is set to the latched status 113 during the game, the start instruction flag 144c is not set to "1" triggered by this.

<When the control IC 148 acquires a random number>
Next, the timing at which the control IC 148 acquires a random number will be described with reference to the time charts of FIGS.

  First, the slot machine without the latched status 113 will be described with reference to FIG. The slot machine is set as the first slot machine to be compared. The first slot machine to be compared differs from the slot machine 10 of the present embodiment in that it does not have the latched status 113.

  FIG. 20 is a time chart for illustrating the timing at which the control IC acquires a random number from the latch register in the first slot machine to be compared. FIG. 20 (a) shows the state of the detection signal input to the control IC, FIG. 20 (b) shows the state of the signal storage flag, and FIG. 20 (c) shows the state of the detection signal input to the control side CPU. FIG. 20 (d) shows the state when the random number stored in the random number counter is written to the latch register, and FIG. 20 (e) shows the timing when the start command setting process (FIG. 9) is executed in the control IC. FIG. 20 (f) shows the timing at which the control IC obtains random numbers output from the latch register and input to the input terminal of the control IC.

  As shown in FIGS. 20 (a) and 20 (c), when the player operates the start lever, the detection signal input to the control IC and the control CPU rises from the LOW state to the HI state at the timing of t1. . The control side CPU transmits a latch signal to the latch register at timing t4 12.8 μs after the rise of the input detection signal. As shown in FIG. 20 (d), at the timing of t4 when the latch register receives the latch signal, the numerical information of the random number stored in the random number counter is written to the latch register.

  As shown in FIG. 20 (e), at a timing t2 which is a timing after the timing t1 at which the detection signal rises and at which a numerical value information of a random number is written to the latch register. , And start command setting processing is performed. As shown in FIG. 20A, the detection signal input to the control IC at the timing t2 is in the HI state. Therefore, as shown in FIG. 20B, the control IC sets “1” to the signal storage flag at the timing of t2. As a result, the rise of the detection signal is detected by the control IC. Therefore, as shown in FIG. 20 (f), in the lottery process (FIG. 11) executed at the timing of t3 which is after the timing of t2 and before the timing of t4, the control IC is the control IC Get the numerical information of the random number input to the input terminal of.

  Since the timing at which the control IC acquires numerical value information of the random number is earlier than the timing at t4 at which the random number corresponding to the current operation of the start lever is written to the latch register, the control IC operates the current start lever The numerical information of the random number previously written to the latch register will be acquired. As described above, when the latched status 113 is not used, a random number that does not correspond to the operation of the start lever may be used to determine whether the winning combination is successful.

  For example, after a game result advantageous to the player is obtained, the detection signal is changed from the LOW state to the HI state so that the start command setting process is performed before the random number corresponding to the operation of the start lever is written to the latch register. Injury to launch in When the fraud is performed, the control IC acquires numerical information of the same random number as the previous one. For this reason, there is a problem that the game result advantageous to the player is continued due to the fraud.

  As shown in FIGS. 20A and 20C, the detection signal input to the control IC and the control CPU falls from the HI state to the LOW state at the timing of t5 after the timing of t4. Thereafter, as shown in FIG. 20 (e), the start command setting process is executed at the timing of t6. As shown in FIG. 20A, the detection signal input to the control IC at the timing of t6 is in the LOW state. Therefore, as shown in FIG. 20 (b), the control IC clears the signal storage flag to "0" at the timing of t6.

  After the timing of t6, the game played using the random number acquired by the control IC at the timing of t2 ends, and the game can be started again. Then, as shown in FIG. 20A, the detection signal input to the control IC rises from the LOW state to the HI state at the timing of t7 after the timing of t6. However, as shown in FIG. 20C, the detection signal input to the control side CPU 114 at the timing of t7 does not rise.

  Therefore, as shown in FIG. 20 (d), numerical value information of a new random number is not written to the latch register triggered by the rise of the detection signal at the timing of t7. The numerical information stored in the latch register is maintained as the numerical information of the random number written at the timing of t4.

  As shown in FIG. 20E, the timing starts at the timing of t8, which is between the timing of t7 when the detection signal input to the control IC rises and the timing of t10 when the detection signal input to the control IC falls. Command setting processing is executed. As shown in FIG. 20A, the detection signal input to the control IC at the timing of t8 is in the HI state. Therefore, as shown in FIG. 20B, the control IC sets “1” to the signal storage flag at the timing of t8. As a result, the control IC detects the rising of the detection signal input to the control IC.

  As shown in FIG. 20 (f), in the lottery process (FIG. 11) executed at the timing of t9, which is after the timing of t8 when the rising of the detection signal is detected and before the timing of t10. The random number input to the input terminal of the control IC is acquired. The numerical value information of the random number acquired at the timing of t9 is the numerical information of the random number written from the random number counter to the latch register at the timing of t4.

  As described for t7 to t10, in a slot machine which does not have the latched status 113, when only the detection signal input to the control IC rises without the detection signal input to the control CPU rising. I have a problem. For example, when noise mixes only in the input terminal of the control IC, there arises a problem that the game is started triggered by the noise. In addition, when the start lever is operated in a state in which the signal line connecting the start detection sensor and the control side CPU is disconnected, the success or failure judgment of the combination is performed based on the old random number not corresponding to the operation timing of the current start lever. There is a problem of being lost.

  Next, on the condition that the slot machine not having the latched status 113 detects the rising of the detection signal input to the control IC and confirms that the detection signal is in the HI state twice in succession. The case of acquiring the numerical information of the random number input to the control IC will be described below. In the following description, the slot machine is referred to as a second slot machine to be compared.

  The second slot machine to be compared does not have the latched status 113, and the detection signal input to the control IC is LOW in the start command setting process (FIG. 9) executed three times in succession. The slot machine 10 differs from the slot machine 10 of this embodiment in that the numerical information of the random number input to the input terminal of the control IC is acquired on the condition that the state → HI state → HI state.

  The timing at which the control IC of the second slot machine to be compared acquires numerical value information of the random number input to the input terminal of the control IC will be described with reference to the time chart of FIG. 21 (a) shows the state of the detection signal input to the control IC, FIG. 21 (b) shows the state of the detection signal input to the control side CPU, and FIG. 21 (c) shows the random number counter. 21 (d) shows the timing at which the start command setting process is executed in the control IC, and FIG. 21 (e) shows the control IC in question. The timing which acquires the numerical information of the random number input into the input terminal of IC is shown, FIG.21 (f) shows the connection state of a start detection sensor and control side CPU.

  As shown in FIG. 21 (a), the start command setting process is executed at the timing of t1. As shown in FIG. 21F, the start detection sensor and the control CPU are in a connected state at the timing of t1, and the detection signal output from the start detection sensor is input to the control CPU. Further, as shown in FIG. 21A, the detection signal input to the control IC at the same timing t1 is in the LOW state. Thereafter, when the start lever is depressed at timing t2, as shown in FIGS. 21A and 21B, the detection signal input to the control IC and the detection input to the control side CPU The signal rises from the LOW state to the HI state.

  As shown in FIG. 21D, the start command setting process is executed at the timing of t3 which is the timing before 12.8 μs elapses from the timing of t2. As shown in FIG. 21A, the detection signal input to the control IC at the timing t3 is in the HI state.

  The control CPU causes the detection signal input to the control CPU to rise from the LOW state to the HI state at time t4, which is after time t3 and when 12.8 μs has elapsed from time t2, the time HI It is understood that the state is maintained for 12.8 μs or more. Then, the control side CPU transmits a latch signal to the CLK terminal of the latch register D-FF. As a result, as shown in FIG. 21C, the numerical value information of the random number stored in the random number counter is written to the latch register at the timing of t4.

  Thereafter, as shown in FIG. 21D, the start command setting process is executed at the timing of t5. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t5 is in the HI state. The detection signal input to the control IC at timing t1, timing t3, and timing t5 changes from the LOW state to the HI state to the HI state, so after the timing at t5 as shown in FIG. In a lottery process (FIG. 11) executed at a certain timing t6, the control IC acquires numerical information of the random number input to the input terminal of the control IC, and starts the game. The numerical value information of the random number acquired by the control IC at the timing of t6 is the numerical value information of the random number corresponding to the operation of the start lever 41 this time.

  As shown in FIGS. 21 (a) and 21 (b), each of the detection signal input to the control IC and the detection signal input to the control CPU is at timing t7 which is after timing t6. Return to LOW state. In addition, the game ends after the timing of t7.

  Thereafter, as shown in FIG. 21D, the start command setting process is executed at the timing of t8. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t8 is in the LOW state.

  After that, when an insufficient pressing operation of the start lever is performed, as shown in FIGS. 21A and 21B, the detection signal input to the control IC and the detection signal input to the control side CPU And each become HI state from the timing of t9 to the timing of t11. Here, the time interval from the timing of t9 to the timing of t11 is less than 12.8 μs. Further, the insufficient pressing operation of the start lever is a pressing operation in which the time in which the start lever is in the depressed state is less than 12.8 μs.

  In this case, since the HI state of the detection signal input to the control side CPU is not continued for 12.8 μs or longer, the control side CPU takes the CLK terminal of the D-FF for latch register triggered by the insufficient pressing operation. Does not send a latch signal to For this reason, as shown in FIG. 21, the numerical value information of the random number stored in the random number counter is not written to the latch register.

  As shown in FIG. 21D, the start instruction setting process is executed at the timing of t10 which is between the timing of t9 and the timing of t11. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t10 is in the HI state. Then, after the timing of t11, noise mixes in only the input terminal of the control IC. As a result, as shown in FIG. 21A, the detection signal input to the control IC is in the HI state from the timing of t12 to the timing of t15.

  In this case, as shown in FIG. 21D, the start command setting process is executed at the timing of t13 which is between the timing of t12 and the timing of t15. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t13 is in the HI state.

  Since the detection signal input to the control IC at the timing of t8, the timing of t10, and the timing of t13 changes from the LOW state to the HI state to the HI state, as shown in FIG. 21E, after the timing of t13. In the lottery process (FIG. 11) executed at the timing of t14, the control IC acquires numerical information of the random number input to the input terminal of the control IC, and starts the game. As shown in FIG. 21C, the numerical value information of the random numbers stored in the latch register is not updated from the timing of t9 to the timing of t14. Therefore, the numerical information of the random number acquired by the control IC at the timing of t14 is the numerical information of the old random number not corresponding to the insufficient pressing operation of the start lever 41 this time.

  As described above, when the start command setting process is executed at both the timing when the start lever 41 is not sufficiently pressed and the timing when noise is mixed in the input terminal of the control IC, the comparison target is compared. In the second slot machine, the player's success or failure judgment is performed based on the old random number numerical information.

  As shown in FIG. 21F, the connection between the start detection sensor and the control side CPU is disconnected at the timing of t16 which is the timing after t15, resulting in the disconnection state. In the disconnection state, the detection signal output from the start detection sensor is input only to the control IC.

  After that, as shown in FIG. 21D, the start command setting process is executed at the timing of t17. Here, the game has already ended at the timing of t17, and the second slot machine to be compared is in a state where the game can be started at the timing of t17. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t17 is in the LOW state.

  When the start lever is depressed at timing t18 after timing t17, the detection signal input to the control IC rises from the LOW state to the HI state as shown in FIG. 21 (a). However, as shown in FIG. 21F, after the timing of t16, the connection between the start detection sensor and the control side CPU is disconnected. Therefore, as shown in FIG. 21B, the detection signal input to the control side CPU at the timing of t18 does not rise.

  As shown in FIG. 21D, at the timing of t19, the first start command setting process is executed after the timing of t18. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t19 is in the HI state. Thereafter, as shown in FIG. 21D, at the timing of t20, the second start instruction setting process is executed after the timing of t18. As shown in FIG. 21A, the detection signal input to the control IC at the timing of t20 is in the HI state.

  Since the detection signal input to the control IC at the timing of t17, the timing of t19, and the timing of t20 changes from the LOW state to the HI state to the HI state, as shown in FIG. 21 (e), the control IC performs t20. In the lottery process (FIG. 11) executed at the timing of t21 which is after the timing of t, the numerical information of the random number input to the input terminal of the control IC is acquired, and the game is started. As shown in FIG. 21C, the numerical value information of the random number stored in the latch register is not updated from the timing of t18 to the timing of t21. Therefore, the numerical information of the random number acquired by the control IC at the timing of t21 is the numerical information of the old random number which does not correspond to the pressing operation of the current start lever.

  In the second slot machine to be compared which does not use the latched status 113, the control IC can not grasp that the numerical value information of the random number stored in the random number counter is written in the latch register. Therefore, the start instruction flag can not be set to “1” on the condition that the numerical value information of the random number stored in the random number counter is written in the latch register.

  In a slot machine that does not use the latched status 113, the detection signal being input to the control IC and the detection signal being input to the control CPU may exhibit different behavior due to noise or disconnection. There is a problem that the success or failure of the combination is determined on the basis of numerical value information of random numbers. In particular, when the connection between the start detection sensor and the control side CPU is disconnected, the determination of the winning combination based on the numerical information of the same random number will be repeated.

  Next, the slot machine 10 of the present embodiment in which the control IC 148 acquires a random number using the latched status 113 will be described with reference to FIG.

  FIG. 22 is a time chart for explaining the timing at which the control IC 148 acquires numerical value information of the random number inputted to the input terminal TA3 of the control IC 148 in the present embodiment. 22 (a) shows the state of the detection signal SG1 input to the control IC 148, FIG. 22 (b) shows the state of the signal storage flag 144d (FIG. 5), and FIG. 22 (c) shows the control side CPU 114. FIG. 22 (d) shows the timing when the numerical information of the random number stored in the random number counter 105 is written to the latch register 102, and FIG. 22 (e) shows the latched status. 22 (f) shows the timing when the start command setting process (FIG. 9) is executed in the control IC 148, and FIG. 22 (g) shows that the control IC 148 is inputted to the input terminal TA3 of the control IC 148. 22 (h) shows the state of the error counter 144b (FIG. 5).

  As shown in FIG. 22A, in the game startable period, noise enters the input terminal TA1 of the control IC 148, and the detection signal SG1 input to the control IC 148 rises from the LOW state to the HI state. As shown in FIG. 22 (a), the HI state is continued until the timing of t3. As shown in FIG. 22 (f), the start command setting process is executed at the timing of t2 which is between the timing of t1 and the timing of t3. Since the detection signal SG1 input to the control IC 148 at time t2 is in the HI state as shown in FIG. 22 (a), as shown in FIG. 22 (b), the control IC 148 stores signal at time t2. The flag 144d is set to "1". The control IC 148 detects the rising of the detection signal SG1 when the signal storage flag 144d changes from "0" to "1".

  As shown in FIGS. 22A and 22C, only the detection signal SG1 input to the control IC 148 rises at timing t1, and the detection signal SG1 input to the control CPU 114 does not rise. For this reason, as shown in FIG. 22E, the latched status 113 remains at “0” at the timing of t2. In the start command setting process performed at the timing of t2, the condition that “1” is set to the latched status 113 does not hold, and therefore, as shown in FIG. Acquisition is not performed. In this case, as shown in FIG. 22 (h), the control IC 148 adds “1” to the error counter 144b at the timing of t2.

  Thus, by using the latched status 113, when noise enters only the control IC 148, the control IC 148 acquires numerical information of the old random number input to the input terminal TA3 of the control IC 148, It is possible to avoid a situation in which a player's success or failure judgment based on old random numbers is performed. Further, when the signal line connecting the start detection sensor 41a and the control side CPU 114 is disconnected, the situation where the control IC 148 repeatedly acquires numerical information of the same random number every time the start lever 41 is operated is avoided. be able to.

  As shown in FIG. 22 (a), after the detection signal SG1 input to the control IC 148 falls at timing t3, as shown in FIG. 22 (f), start command setting processing is executed at timing t4. Be done. Since the detection signal SG1 input to the control IC 148 is in the LOW state at the timing of t4 as shown in FIG. 22 (a), as shown in FIG. 22 (b), the control IC 148 at the timing of t4. The signal storage flag 144d is cleared to "0".

  Thereafter, when the player operates the start lever 41 within the game startable period, as shown in FIGS. 22A and 22C, the detection signal SG1 input to the control IC 148 and the control side CPU 114 at the timing of t5. Will stand up. Here, the timing of t7 is a timing when 12.8 μs has elapsed from the timing of t5. As shown in FIG. 22C, the detection signal SG1 input to the control side CPU 114 is in the HI state at the timing of t7 when 12.8 μs has elapsed since the detection signal SG1 input to the control side CPU 114 has risen. It remains.

  Therefore, at the timing of t7, the control side CPU 114 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p. Thereby, as shown in FIG. 22D, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102 at the timing of t7. Further, as shown in FIG. 22E, the control side CPU 114 sets “1” to the latched status 113 at the timing of t7.

  In this case, as shown in FIG. 22 (f), the start command setting process is executed after the timing of t5 and at the timing of t6 before the timing of t7. Since the detection signal SG1 input to the control IC 148 is in the HI state at the timing of t6 as shown in FIG. 22 (a), as shown in FIG. 22 (b), the signal storage flag at the timing t6. "1" is set to 144d. At timing t6 when the signal storage flag 144d changes from "0" to "1", the control IC 148 detects the rising of the detection signal SG1.

  However, as shown in FIG. 22E, the latched status 113 remains “0” at the timing of t6. Since the condition that "1" is set to the latched status 113 is not satisfied at the timing of t6, as shown in FIG. 22 (g), acquisition of numerical value information of random numbers by the control IC 148 is not executed. In this case, as shown in FIG. 22 (h), the control IC 148 adds “1” to the error counter 144b.

  As shown in FIG. 22F, the start command setting process is executed at the timing of t8 after the timing of t7. As shown in FIG. 22B, at the timing of t8, “1” is already set in the signal storage flag 144d, and the detection signal SG1 is input to the control IC 148 at the timing of t8. It does not detect the rising of the. Therefore, in the start command setting process performed at the timing of t8, the control IC 148 transmits a pulse signal to the CLR terminal 113c of the latched status 113. As a result, as shown in FIG. 22E, the latched status 113 is cleared to "0" at the timing of t8.

  As described above, in the slot machine 10 having the latched status 113, the start command setting is made before 12.8 μs have elapsed since the detection signal SG1 input to the control side CPU 114 rises from the LOW state to the HI state. Even if the process is executed, the control IC 148 can obtain the old random number, and can avoid the situation where the player's yes or no judgment is performed based on the old random number.

  In such a configuration, the detection signal SG1 is raised from the LOW state to the HI state so that the start command setting process is performed prior to the timing when the random number stored in the random number counter 105 is written to the latch register 102. Even if is performed, the control IC 148 does not acquire the same random number as the previous one, and an error occurs. Then, the number of continuously generated errors is counted by the error counter 144b. For this reason, it is possible to prevent a situation in which the game result advantageous to the player is continued due to fraud.

  When the player operates the start lever 41 and the condition for the control IC 148 to set the start command flag 144c to “1” is not satisfied, the player needs to operate the start lever 41 again. It occurs. However, since the start command setting process is a process executed in the timer interrupt process (FIG. 8) which is executed in a 1.49 ms cycle, it takes 12.8 μs after the player operates the start lever 41. The frequency of occurrence of an event for which start command setting processing is performed is low. Thus, the player does not frequently re-operate the start lever 41.

  As shown in FIGS. 22A and 22C, at timing t9 after timing t8, the detection signal SG1 input to the control IC 148 and the control CPU 114 falls. Then, at the timing of t10 later than the timing of t9, as shown in FIG. 22 (f), the start command setting process is executed. As shown in FIG. 22 (a), at timing t10, the detection signal SG1 input to the control IC 148 is in the LOW state, so as shown in FIG. 22 (b), the control IC 148 controls the signal storage flag 144d. Clear "0".

  After that, when the player operates the start lever 41 in the game startable period, as shown in FIGS. 22A and 22C, at the timing of t11, they are input to the control IC 148 and the control side CPU 114. The detection signal SG1 rises from the LOW state to the HI state. As shown in FIG. 22C, at time t12 when 12.8 μs has elapsed since the detection signal SG1 input to the control side CPU 114 rises, the detection signal SG1 maintains the HI state. Therefore, at time t12, the control side CPU 114 transmits a latch signal to the CLK terminals of the latch registers D-FFs 102a to 102p. Thereby, as shown in FIG. 22D, numerical value information of the random number stored in the random number counter 105 is written to the latch register 102 at the timing of t12. Further, as shown in FIG. 22E, the control side CPU 114 sets “1” to the latched status 113 at the timing of t12.

  In this case, as shown in FIG. 22 (f), the start command setting process is executed at the timing of t13 after the timing of t12. Since the detection signal SG1 input to the control IC 148 is in the HI state at the timing of t13 as shown in FIG. 22 (a), as shown in FIG. 22 (b), the control IC 148 is at the timing of t13. Sets “1” to the signal storage flag 144 d. When the signal storage flag 144d changes from “0” to “1”, the control IC 148 recognizes the rising of the detection signal SG1 input to the control IC 148.

  As shown in FIG. 22E, “1” is set in the latched status 113 at the timing of t13 when the control IC 148 detects the rising of the detection signal SG1 input to the control IC 148. Since the condition that “1” is set in the latched status 113 is satisfied at the timing when the control IC 148 detects the rising of the detection signal SG1 input to the control IC 148, the control IC 148 sets the start command flag 144c. Set "1". As shown in FIG. 22 (g), in the lottery process (FIG. 11) executed at the timing of t14 after the timing of t13, the control IC 148 selects the random number input to the input terminal TA3 of the control IC 148. It acquires numerical information and uses it to judge the success or failure of the role.

  Further, at the timing of t13 when the control IC 148 sets the start command flag 144c to "1", as shown in FIG. 22 (h), the control IC 148 clears the error counter 144b to "0".

  The possibility that the start command setting process is performed before 12.8 μs elapses after the rise of the detection signal SG1 input to the control side CPU 114 is unlikely to be continuous. Further, even when the event continues twice, when the control IC 148 acquires numerical value information of a random number corresponding to the operation of the start lever 41, the error counter 144b is cleared to "0". Therefore, when the value of the error counter 144b is "3" and the abnormality notification process (the process of step S311 of the start instruction setting process (FIG. 9)) is executed, the state of the detection signal SG1 is altered. Can be substantially limited to the case where the connection between the start detection sensor 41a and the control side CPU 114 is disconnected.

  Next, a case where noise of 12.8 μs or more enters only in the control side CPU 114 will be described with reference to the time chart of FIG. The slot machine 10 is ready to start the game at the timing of t1 to t4.

  FIG. 23 (a) shows the state of the detection signal SG1 input to the control IC 148, FIG. 23 (b) shows the state of the signal storage flag 144d, and FIG. 23 (c) is input to the control CPU 114 The state of the detection signal SG1 is shown, FIG. 23 (d) shows the timing when the numerical information of the random number stored in the random number counter 105 is written to the latch register 102, and FIG. 23 (f) shows the state of the latched status 113, and FIG. 23 (g) shows that the control IC 148 acquires numerical information of the random number inputted to the input terminal TA3 of the control IC 148. Indicates the timing.

  As shown in FIG. 23C, noise enters the input terminal TB1 of the control side CPU 114, and only the detection signal SG1 input to the control side CPU 114 rises from the LOW state to the HI state from the timing of t1 to the timing of t3. . The timing t3 is a timing later than the timing t2 when 12.8 μs has elapsed from the timing t1.

  As shown in FIG. 23C, the detection signal SG1 input to the control side CPU 114 rises at the timing of t1, and maintains the HI state until the timing of t2 12.8 μs after the timing of t1. Therefore, the control side CPU 114 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p at the timing of t2. As a result, as shown in FIG. 23D, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102 at the timing of t2. Further, as shown in FIG. 23F, the control side CPU 114 sets “1” to the latched status 113 at the same timing t2.

  As shown in FIG. 23E, the start command setting process is executed at the timing of t4 which is later than the timing of t3. As shown in FIG. 23A, the detection signal SG1 input to the control IC 148 at the timing of t4 is in the LOW state, and the control IC 148 does not detect the rising of the detection signal SG1. In this case, as shown in FIG. 23 (f), the control IC 148 raises the signal output to the CLR terminal 113c of the latched status 113 in the start instruction setting process executed at the timing of t4, and latches it. Clear the completed status 113 to "0".

  As described above, even if “1” is set in the latched status 113 at timing t2 due to noise entering only the input terminal TB1 of the control side CPU 114, in the start command setting process executed at timing t4 immediately thereafter, The latched status 113 is cleared to "0".

  If the latched status 113 is not cleared to "0" at the timing of t4, the condition that it is a game startable period and the rise of the detection signal SG1 input to the control IC 148 are detected at the subsequent timing. There are three conditions that the condition of “1” is set in the latched status 113 may be satisfied. On the other hand, the control IC 148 clears the latched status 113 to "0" at the timing of t4, whereby the control IC 148 uses a random number written in the latch register 102 triggered by a noise for determining whether the role is acceptable or not. The possibilities can be reduced.

  As described above, in the control side CPU 114, the control side CPU 114 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p, and the numerical information of the random number stored in the random number counter 105 is written to the latch register 102. At timing, the latched status 113 is set to "1". Further, the control IC 148 detects that the control IC 148 detects the rising of the detection signal SG1 while the game can be started, and the latched status 113 is set to “1” at the timing when the control IC 148 detects the rising of the detection signal SG1. Under this condition, the numerical information of the random number input to the input terminal TA3 of the control IC 148 is acquired. Therefore, it is possible to limit the numerical value information of the random number acquired by the control IC 148 to the random number corresponding to the operation of the start lever 41 this time. As a result, it is possible to avoid the situation where the control IC 148 acquires the old random number and performs the determination of the player's success or failure based on the old random number. By limiting the random number used for the judgment of the winning combination to the random number corresponding to the operation of the start lever 41 this time, the gaming machine in which the judgment of the winning combination based on the random number on which the player's action is accurately reflected is performed. Can be provided.

  Further, the control side CPU 114 transmits a latch signal to the latch register 102 at the timing determined that the detection signal SG1 input to the control side CPU 114 is in the HI state and the HI state is continued for 12.8 μs. It is a structure. Therefore, when the rise of the detection signal SG1 is due to noise less than 12.8 μs, it is possible to prevent the random number from being written to the latch register 102 triggered by the noise.

  Also, the main RAM 144 is provided with an error counter 144b. The error counter 144b determines that “1” is not set in the latched status 113 at the timing when the control IC 148 detects the rising of the detection signal SG1 input to the control IC 148 in the game startable state. Is a counter that counts the number of times that is performed continuously. Then, when the value of the error counter 144 b becomes “3”, the control IC 148 performs an abnormality notification process. At the timing when the control IC 148 detects the rising edge of the detection signal SG1 input to the control IC 148, one of the causes of consecutive events in which "1" is not set in the latched status 113 is the start detection sensor 41a and Disconnection with the control side CPU 114 may be considered. When the value of the error counter 144b becomes "3", by performing notification of abnormality, in the connection between the start detection sensor 41a and the control side CPU 114, the game hall is managed with high possibility of disconnection occurring. Can be informed.

  In addition, when the start command setting process is executed before 12.8 μs elapses after the detection signal SG1 input to the control side CPU 114 rises, “Latched status 113” is displayed after the start command setting process. "1" may be set. Also, when the noise of 12.8 μs or more is mixed in only the input terminal of the control side CPU 114, “1” is set in the latched status 113. When the state in which the latched status 113 is set to “1” is maintained for a long time, the possibility that the start lever 41 is operated in a state in which the latched status 113 is set to “1” becomes high. In this case, as in the case where the latched status 113 is not used, the control IC 148 may obtain the old random number, and the player may determine whether the winning combination is successful or not based on the old random number. On the other hand, when the rising of the detection signal SG1 input to the control IC 148 is not detected in the start command setting process, the control IC 148 clears the latched status 113 by “0”. It can reduce the possibility of getting old random numbers.

  In addition, when the start lever 41 is operated during the game, a random number corresponding to the operation of the start lever 41 is written to the latch register 102 and “1” is set in the latched status 113. On the other hand, by setting the latched status 113 to “0” at the start timing of the game startable period, the random number corresponding to the operation of the start lever 41 in the game is used for the judgment of winning or not. Can be avoided.

  When the start lever 41 is operated under the condition that the latched status 113 is set to “1”, the random number stored in the latch register 102 corresponds to the operation of the start lever 41. It is a configuration that can be rewritten to random numbers. For this reason, even if noise enters only the input terminal of the control side CPU 114 and "1" is set to the latched status 113 triggered by the noise, the random number written to the latch register 102 triggered by the noise plays a role. It is possible to reduce the possibility of being used for the pass / fail judgment.

  Further, in the configuration in which the latch signal is transmitted at the timing when the rising of the detection signal SG1 input to the control IC 148 is detected, the start command setting process is performed even if the player operates the start lever 41 at the same timing. Depending on the timing of execution, the random number used to determine the winning combination changes. On the other hand, at the timing when it is determined that the detection signal SG1 input to the control CPU 114 rises from the LOW state to the HI state and the HI state is continued for 12.8 μs, the control CPU 114 controls the latch register D-FF 102a. By outputting the latch signal to the CLK terminal of ̃102p, the random number 12.8 μs after the rise of the detection signal SG1 which is always inputted to the control side CPU 114 is used for the judgment of the success or failure of the role. Thereby, the timing at which the player operates the start lever 41 can be accurately reflected on the game result.

Second Embodiment
In this embodiment, in the start command setting process, one of the conditions that the control IC 148 determines that “1” is not set in the latched status 113 is the latched status 113 in the next start command setting process. The state of is again determined. When the detection signal SG1 input to the control side CPU 114 does not rise due to disconnection or the like, the control side CPU 114 raises a latch signal triggered by the reception of a signal from the main MPU 142. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 24 is a block diagram for explaining the configuration of the main control board 141 in the present embodiment. The control IC 148 includes an output terminal TA5 (FIG. 24) in addition to the input terminals TA1 to TA3 (FIG. 6) and the output terminal TA4 (FIG. 6). Further, the control side CPU 114 has an input terminal TB5 (FIG. 24) in addition to the input terminals TB1 and TB2 (FIG. 6) and the output terminals TB3 and TB4 (FIG. 6). The output terminal TA5 of the control IC 148 and the input terminal TB5 of the control side CPU 114 are connected by a signal line, and a signal output from the output terminal TA5 of the control IC 148 is input to the input terminal TB5 of the control side CPU 114.

  Further, as shown in FIG. 24, the main RAM 144 is provided with a start possibility flag 144a, an error counter 144b, a start instruction flag 144c, a signal storage flag 144d, a confirmation instruction flag 144e, and an error state flag 144f.

  Here, the confirmation command flag 144e is a start command when the start command setting process (FIG. 25) is executed from when the detection signal SG1 rises to when "1" is set in the latched status 113. This flag is a flag for executing the process of determining the state of the latched status 113 again in the start instruction setting process subsequent to the setting process. In the processing, when it is determined that the latched status 113 is set to "1", the control IC 148 sets the start instruction flag 144c to "1", and the game is started.

  Further, the error state flag 144f is a start command setting process (FIG. 25) in which the control IC 148 detects the rising edge of the detection signal SG1 input to the control IC 148, and a start command setting next to the start command setting process. This is a flag that is set to “1” when “1” is not set to the latched status 113 in both of the processing.

  By setting the error state flag 144 f to “1”, the contents of the process for the control IC 148 to acquire the numerical value information of the random number input to the input terminal TA 3 of the control IC 148 change. When the error state flag 144 f is set to “0”, the random number acquired by the control IC 148 at the input terminal TA 3 (FIG. 6) of the control IC 148 in the random number acquisition process (FIG. 28) of this embodiment. Get numerical information of

  When the error state flag 144 f is set to “1”, the control IC 148 transmits a latch instruction signal to the control CPU 114 in the random number acquisition process (FIG. 28) of the present embodiment. It will be. Here, the latch instruction signal is a signal that triggers the control side CPU 114 to transmit a latch signal to the CLK terminals of the latch register D-FFs 102 a to 102 p. The latch instruction signal is output from the output terminal TA5 of the control IC 148 and input to the input terminal TB5 of the control side CPU 114. After transmitting the latch instruction signal, when “1” is set in the latched status 113, the control IC 148 acquires numerical value information of the random number input to the input terminal TA3 of the control IC 148. Details of the random number acquisition process will be described later.

  Next, the start command setting process according to the present embodiment will be described with reference to FIG. The start command setting process is executed in step S206 of the timer interrupt process (FIG. 8).

  First, in step S801, it is determined whether the game can be started. When the game can be started, the start possible flag 144a is set to "1". When the game can not be started (step S801: NO), the present start instruction setting process is ended. Therefore, even if the player operates the start lever 41 during the game, the start instruction flag 144c is not set to "1" based on the operation.

  If the game can be started (step S801: YES), it is determined in step S802 whether or not "1" is set in the confirmation command flag 144e. The confirmation command flag 144 e is set to step S 810 when “1” is not set in the latched status 113 at the timing when the rising of the detection signal SG 1 input to the control IC 148 is detected in the game startable state. Is a flag to be set. The confirmation command flag 144 e is cleared to “0” in step S 812.

  In the case where the start command setting process is executed before 12.8 μs elapses after the detection signal SG1 input to the control side CPU 114 rises, assuming that the confirmation command flag 144e is set to “1”. It is conceivable that noise may enter only at the input terminal of, and the connection between the start detection sensor 41a and the control CPU 114 may be cut off, and the detection signal SG1 input to the control CPU 114 may not rise. Among them, the start command setting process is executed before 12.8 μs elapses after the detection signal SG1 input to the control side CPU 114 rises, so that “1” is set in the latched status 113 in the start command setting process. Is determined not to be set, “1” is set to the latched status 113 within 12.8 μs after the determination.

  Therefore, when the control IC 148 determines that "1" is not set in the latched status 113, it sets "1" in the confirmation command flag 144e, ends the start command setting process, and starts the next time. In the command setting process, under the condition that "1" is set in the confirmation command flag 144e, it is judged again whether "1" is set in the latched status 113 or not. As a result, when the player operates the start lever 41 and the detection signal SG1 rises, the control IC 148 performs the current operation based on the operation of the start lever 41 regardless of when the start command setting process is performed. A random number corresponding to the operation of the start lever 41 can be obtained.

  By configuring the main RAM 144 to include the confirmation command flag 144e, it is possible to avoid the situation where the game is not started even if the player operates the start lever 41 in the state where the game can be started. In addition, it is possible to avoid the situation where the control IC 148 acquires an old random number that does not correspond to the operation of the start lever 41 this time.

  If "1" is not set in confirmation command flag 144e (step S802: NO), whether or not the rising of detection signal SG1 input to control IC 148 is detected in steps S803 and S804. To determine Specifically, in step S803, it is determined whether the value of the signal storage flag 144d is "0". If the value of the signal storage flag 144d is "0" (step S803: YES), it is determined in step S804 whether the detection signal SG1 input to the control IC 148 is in the HI state. When it is determined in step S804 that the detection signal SG1 is in the HI state (step S804: YES), "1" is set to the signal storage flag 144d in step S805.

  As described above, when the signal storage flag 144 d changes from “0” to “1”, the control IC 148 is in a state of detecting the rising of the detection signal SG1 input to the control IC 148.

  In the following step S806, "1" is set to the latched status 113 based on the signal output from the Q terminal 113a (FIG. 6) of the latched status 113 and input to the input terminal TB2 of the control IC 148. It is determined whether or not it exists. When “1” is set in the latched status 113 (step S806: YES), numerical information of a random number corresponding to the operation of the start lever 41 this time is already input to the input terminal TA3 of the control IC 148 It means being in the state. In this case, the start command flag 144 c is set to “1” in step S 807 so that the control IC 148 can start the game by acquiring the numerical information of the random number input to the input terminal TA 3 of the control IC 148. .

  In the subsequent step S808, the error counter 144b is cleared to "0". The error counter 144b in the present embodiment is both the start command setting process in which the control IC 148 detects the rising of the detection signal SG1 input to the control IC 148, and the start command setting process following the start command setting process. Is a counter to which "1" is added when an event occurs in which "1" is not set in the latched status 113. The error counter 144 b is a counter used to grasp that the event is occurring continuously.

  Therefore, if it is confirmed that "1" is set in the latched status 113, the error counter 144b is cleared to "0" in step S808. Then, in step S809, a pulse signal is transmitted to the CLR terminal 113c (FIG. 6) of the latched status 113 to clear the latched status 113 to "0", and the present start instruction setting process is ended.

  If it is determined in step S806 that "1" is not set in the latched status 113, the process proceeds to step S810 in order to perform processing for determining the state of the latched status 113 again in the next start instruction setting process. Then, the confirmation command flag 144 e is set to “1”, and this start command setting process is ended.

  If it is determined in step S804 that the detection signal SG1 input to the control IC 148 is in the LOW state, this means that the rising of the detection signal SG1 has not been detected. In this case, since “0” is already set in the signal storage flag 144 d, the latched status 113 is cleared to “0” in step S 809, and the present start instruction setting process is ended.

  When it is determined in step S803 that "1" is set in the signal storage flag 144d, the detection signal SG1 input to the control IC 148 at the timing at which the previous start instruction setting process was performed. Is in the HI state, which means that the detection signal SG1 has already risen. In this case, it is determined in step S811 whether or not the detection signal SG1 input to the control IC 148 is in the LOW state. If the detection signal SG1 is in the LOW state (step S811: YES), the signal storage flag 144d is cleared to "0" in step S812.

  After determining that the detection signal SG1 input to the control IC 148 is in the HI state in step S811 (step S811: NO), or after clearing the signal storage flag 144d to "0" in step S812, the process proceeds to step S809. Then, the latched status 113 is cleared to "0", and the start command setting process is ended.

  If it is determined in step S802 that the confirmation command flag 144e is set to "1", the start instruction setting process of this time is started in step S810 in which the confirmation command flag 144e is set to "1". It means that it is the start command setting process of the next time of the command setting process. In this case, the confirmation instruction flag 144 e is cleared to “0” in step S 813, and the numerical information output from the Q terminal 113 a of the latched status 113 and input to the input terminal TA 2 of the control IC 148 in step S 814 is input. Based on the determination, it is determined whether "1" is set in the latched status 113 or not.

  If it is determined in step S 814 that “1” is set to the latched status 113, numerical information of random numbers corresponding to the operation of the start lever 41 at this time is already input to the input terminal TA 3 of the control IC 148. Mean that it is in the In this case, the processes of steps S807 to S809 are performed as in the case where it is determined in step S806 that "1" is set in the latched status 113. Specifically, the start instruction flag 144c is set to "1" (step S807), and the error counter 144b is cleared to "0" (step S808). Then, by transmitting a pulse signal to the CLR terminal 113c of the latched status 113, the latched status 113 is cleared to "0" (step S809), and this start instruction setting process is ended.

  If it is determined in step S814 that "1" is not set in the latched status 113, an error handling process is performed in step S815, and the start instruction setting process is ended. The error handling process is performed when “1” is not set in the latched status 113 while the start command setting process is performed twice after the detection signal SG1 input to the control IC 148 rises.

  Next, the error handling process executed in step S815 of the start command setting process (FIG. 25) will be described with reference to FIG. FIG. 26 is a flowchart for explaining the error handling process executed by the control IC 148.

  First, in step S901, it is determined whether the value of the error counter 144b is "0". If the value of the error counter 144b is "0" (step S901: YES), "1" is added to the error counter 144b in step S902. If the value of the error counter 144 b is not “0” (step S 901: NO), this means that the error handling process is being performed twice in succession. In this case, there is a high possibility that the connection between the start detection sensor 41a and the control CPU 114 is disconnected. Therefore, in step S903, an abnormal signal is transmitted to the management computer of the game hall to notify the manager of the game hall that the possibility of disconnection is high.

  As a case where the error handling process is performed, a case where the connection between the start detection sensor 41a and the control side CPU 114 is disconnected and a case where noise is mixed in the control IC 148 can be considered. When the value of the error counter 144 b is “0”, the possibility of noise entering the control IC 148 can not be excluded, so that only the transmission of the latch instruction signal is performed without transmitting the abnormal signal. On the other hand, when the value of the error counter 144 b is “1”, the possibility of disconnection is high, so that the abnormal signal is transmitted and the latch instruction signal is transmitted.

  When the detection signal SG1 input to the control CPU 114 does not rise even if the start lever 41 is depressed as in the case where the connection between the start detection sensor 41a and the control CPU 114 is disconnected The process of step S903 for transmitting an abnormal signal is continuously executed. The manager of the gaming hall can grasp that disconnection has occurred by grasping that the abnormal signal is repeatedly transmitted to the management computer of the gaming hall.

  After “1” is added to the error counter 144 b in step S 902 or after transmitting an abnormality signal in step S 903, in step S 904, a latch instruction signal is transmitted to the control side CPU 114. When receiving the latch instruction signal, the control side CPU 114 transmits a latch signal to the CLK terminal of the latch register D-FFs 102 a to 102 p (FIG. 6). Thereby, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102.

  After the latch signal is transmitted in step S904, "1" is set in start instruction flag 144c in step S905, and "1" is set in error state flag 144f in step S906, and this error handling process is ended. Do.

  When the connection between the start detection sensor 41 a and the control side CPU 114 is disconnected, the control side CPU 114 can not grasp the timing at which the start lever 41 is operated. Therefore, even if the player operates the start lever 41, the numerical value information of the random number stored in the random number counter 105 is not written to the latch register 102. In this state, when the control IC 148 acquires numerical value information of the random number input to the input terminal of the control IC 148, the success or failure determination of the winning combination is performed based on the old random number not corresponding to the operation of the start lever 41 this time.

  On the other hand, the control IC 148 transmits the latch instruction signal to the control side CPU 114, and the control side CPU 114 which receives the latch instruction signal transmits the latch signal to the latch register 102, whereby the control IC 148 can A random number corresponding to the operation of the start lever 41 this time can be obtained. Since the controller IC 148 is configured to obtain random numbers based on the operation of the start lever 41 while notifying the administrator of the gaming hall that a disconnection has occurred and the administrator of the gaming hall responds, it is unfair for the player. The manager of the game hall can perform maintenance at such a timing as not to be a disadvantage situation.

  In this embodiment, there are two types of timings that trigger the control side CPU 114 to transmit latch signals to the CLK terminals of the latch register D-FFs 102a to 102p. The first timing is a timing at which the detection signal SG1 input to the control side CPU 114 rises from the LOW state to the HI state, and the control side CPU 114 determines that the HI state of the detection signal SG1 continues for 12.8 μs. is there. The timing is referred to as a first timing.

  The first timing is a timing after a predetermined time (12.8 μs) since the player operates the start lever 41 and the detection signal SG1 input to the control side CPU 114 rises, so the player starts the start lever The timing at which the user operates 41 is strongly reflected.

  The second timing is timing when the control IC 148 transmits a latch instruction signal in step S904 of the error handling process (FIG. 26) and the control CPU 114 receives the latch instruction signal. The timing is referred to as a second timing.

  The error handling process is a process executed in the start command setting process (FIG. 25). The start instruction setting process is a process executed in the timer interrupt process (FIG. 8) executed in a 1.49 ms cycle. The time from when the player operates the start lever 41 to when the first timer interrupt process is executed has a width of about 1.49 ms. Specifically, the timer interrupt process may be executed immediately after the start lever 41 is operated, and the timer interrupt process may be executed about 1.49 ms after the start lever 41 is operated. is there.

  As described above, the second timing is a timing that reflects the timing at which the player operates the start lever 41, but is not a timing at which only the operation timing of the start lever 41 by the player is reflected. The second timing also reflects an element that does not depend on the player's operation.

  Therefore, in the present embodiment, in the normal state where the signal line connecting the start detection sensor 41a and the control side CPU 114 is not disconnected, the numerical value of the random number stored in the random number counter 105 at the first timing. Information is written to the latch register 102. As a result, it is possible to perform a winning or failure judgment of a winning combination by using numerical value information of random numbers in which the operation timing of the start lever 41 by the player is strongly reflected.

  On the other hand, in an error state where the signal line connecting the start detection sensor 41a and the control side CPU 114 is disconnected, the detection side signal SG1 inputted to the control side CPU 114 does not rise, so the control side CPU 114 sets the first timing. Can not figure out. In this case, the control IC 148 transmits a latch instruction signal to the control side CPU 114, whereby the numerical information of the random number stored in the random number counter 105 is written to the latch register 102. As a result, even in the error state, it is possible to determine the winning or failure of the winning combination by using the numerical value information of the random number on which the operation timing of the start lever 41 by the player is reflected.

  Next, the management operation executed by the control side CPU 114 of the present embodiment will be described with reference to FIG. FIG. 27 is a flowchart showing the management operation in the present embodiment.

  First, in step S1001, it is determined whether a latch instruction signal has been received from the control IC 148 or not. If it is determined in step S1001 that the latch instruction signal has not been received, it is determined in step S1002 whether or not the detection signal SG1 input to the control CPU 114 is in the LOW state. If it is determined in step S1002 that the detection signal SG1 input to the control CPU 114 is in the HI state, the process returns to step S1001.

  If it is determined in step S1002 that the detection signal SG1 input to the control side CPU 114 is in the LOW state, it is determined in step S1003 whether or not a latch instruction signal has been received. If the latch signal is not received in step S1003, it is determined in step S1004 whether the detection signal SG1 input to the control CPU 114 is in the HI state. If the detection signal SG1 input to the control side CPU 114 is in the LOW state (step S1004: NO), the process returns to step S1003.

  If the detection signal SG1 input to the control side CPU 114 is in the HI state in step S1004, it means that the detection signal SG1 has risen from the LOW state to the HI state. In this case, in step S1005, counting of the time during which the HI state of the detection signal SG1 input to the control side CPU 114 continues is started. The counting of the time is performed using a timer counter that counts the time in units of 0.1 μs.

  In the subsequent step S1006, it is determined whether or not a latch instruction signal has been received from the control IC 148. If the latch instruction signal is received in step S1006 (step S1006: YES), processing is performed to invalidate the latch instruction signal received this time in step S1007. Specifically, it is determined that the latch instruction signal is not received until the next latch instruction signal is received without transmitting the latch signal to latch register 102 based on the latch instruction signal received this time. As it can, it erases the record which received the latch indication signal.

  After making a negative determination in step S1006, or after invalidating the latch instruction signal in step S1007, in step S1008, whether or not the detection signal SG1 input to the control side CPU 114 is in the HI state To determine Then, if the detection signal SG1 is in the HI state, is 12.8 μs elapsed from the timing when the rising of the detection signal SG1 input to the control side CPU 114 from the LOW state to the HI state is detected in step S1009? It is determined whether or not it is. If 12.8 μs has not elapsed from the timing of detecting the rising, the process returns to step S1008.

  If it is determined in step S1009 that 12.8 μs has elapsed from the rise of the detection signal SG1 input to the control side CPU 114 (step S1009: YES), other processing is performed in step S1010, and It returns to step S1001. In the other processing, the processing of steps S706 to S708 in the management operation (FIG. 19) of the first embodiment is executed.

  When the detection signal SG1 input to the control side CPU 114 is in the LOW state in step S1008, that is, the detection signal SG1 input to the control side CPU 114 rises from the LOW state to the HI state, and When the detection signal SG1 returns to the LOW state before the lapse of 8 μs, in step S1011, the timer counter stops counting time, and the process returns to step S1003. In this case, the timer counter is reset.

  If the latch instruction signal is received in step S1001 or step S1003, the latch signal is transmitted to the latch register 102 in step S1012. Specifically, a pulse signal is transmitted to the CLK terminal of the latch register D-FFs 102a to 102p. Thereby, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102. In the subsequent step S1013, "1" is set to the latched status 113, and the process returns to step S1001.

  As described above, when the latch instruction signal is received from the control IC 148 in step S1001 or step S1003 of this management operation, the latch signal is transmitted to the CLK terminals of the latch register D-FFs 102a to 102p, and the latch is performed. The completion status 113 is set to “1”. Therefore, even when the connection between the start detection sensor 41a and the control side CPU 114 is disconnected, the control IC 148 transmits a latch instruction signal to latch the status 113 at the timing corresponding to the pressing operation of the start lever 41. Can be set to "1".

  If a negative determination is made in step S1004, it is determined whether or not a latch instruction signal has been received (step S1003), and whether or not the detection signal SG1 input to the control side CPU 114 is in the LOW state And (step S1004) are repeated. Therefore, even when the latch instruction signal is received while waiting for the detection signal SG1 to be in the HI state in step S1004, the latch signal output to the CLK terminal of the latch register D-FFs 102a to 102p And the process of setting “1” in the latched status 113 (step S1003).

  If a negative determination is made in step S1009, it is determined whether the detection signal SG1 is in the HI state (step S1008), and 12.8 μs has elapsed since the detection signal SG1 rose to the HI state. The determination (step S1009) is repeated.

  As described above, the start command setting process (FIG. 25) at the timing when the control IC 148 detects the rising of the detection signal SG1 input to the control IC 148 and the next time it is executed about 1.49 ms after the start command setting process. When “1” is not set in the latched status 113 in both of the start instruction setting processing, the control IC 148 transmits a latch instruction signal to the control side CPU 114. Since the start command setting process is a process executed in the timer interrupt process (FIG. 8) executed in a 1.49 ms cycle, while waiting for 12.8 μs to elapse in steps S1008 and S1009. The start command setting process is not performed twice.

  The processes in steps S1005 to S1009 of this management operation are processes which are executed until 12.8 μs have elapsed since the detection signal SG1 input to the input terminal TB1 of the control side CPU 114 rises. Therefore, when noise is not considered, the latch instruction signal is not received while waiting for 12.8 μs to elapse in steps S1005 to S1009.

  On the other hand, when noise mixes in the input terminal TA1 of the control IC 148 to which the detection signal SG1 is input, it may be determined that the latch instruction signal is received in step S1006 of the management operation.

  Specifically, when noise mixes only in the input terminal TA1 of the control IC 148, or when noise less than 12.8 μs mixes in both the input terminal TA1 of the control IC 148 and the input terminal TB1 of the control side CPU 114, The start command setting process (FIG. 25) is executed in the control IC 148 while the signal inputted to the input terminal TA1 of the control IC 148 is in the HI state due to the noise.

  In this case, the control IC 148 sets "1" in the confirmation command flag 144e in the start command setting process. It is input to the input terminal TB1 of the control side CPU 114 at a timing after the start command setting process and at a timing before the next start command setting process executed about 1.49 ms after the start command setting process. When a signal rises from the LOW state to the HI state, it may be determined in step S1006 of the management operation that the latch instruction signal is received from the control IC 148.

  As described above, when the latch instruction signal is received in step S1006 of the management operation, the latch instruction signal is affected by noise. Therefore, when it is determined in step S1006 that the control side CPU 114 has received the data, the control side CPU 114 is configured to invalidate the latch instruction signal. This makes it possible to reduce the possibility that the control IC 148 acquires the numerical value information of the random number written in the latch register 102 triggered by noise and uses the numerical value information of the random number to execute the winning / not determining of the winning combination.

  Next, random number acquisition processing executed in step S501 of the lottery processing (FIG. 11) will be described with reference to the flowchart of FIG. The random number acquisition process is a process executed by the control IC 148.

  First, in step S1101, it is determined whether "1" is set in the error state flag 144f. If "1" is not set in the error state flag 144f (step S1101: NO), the detection signal SG1 input to the control CPU 114 rises from the LOW state to the HI state, and the HI state of the detection signal SG1 The control side CPU 114 transmits a latch signal to the CLK terminals of the latch registers D-FFs 102 a to 102 p at a timing when the control side CPU 114 grasps that the time has continued for 12.8 μs or more. Therefore, when a negative determination is made in step S1101, the control IC 148 has already confirmed that "1" is set in the latched status 113.

  On the other hand, when the error state flag 144 f is set to “1” (step S 1101: YES), the control IC 148 transmits a latch instruction signal to the control CPU 114, and the control side receives the latch instruction signal. In this case, the CPU 114 transmits a latch signal to the CLK terminals of the latch register D-FFs 102a to 102p. In this case, it is necessary to confirm that the numerical value information of the random number stored in the random number counter 105 has been written to the latch register 102. Therefore, in step S1102, the error state flag 144f is cleared to "0", and in step S1103, the process waits until the latched status 113 is set to "1". When it is determined that “1” is set in the latched status 113 (step S1103: YES), a pulse signal is transmitted to the CLR terminal of the latched status 113 in step S1104 and latched Clear the status 113 to "0".

  After making a negative determination in step S1101 or clearing the latched status 113 to "0" in step S1104, in step S1105, numerical information of the random number input to the input terminal of the control IC 148 is acquired , Finish the random number acquisition process.

  Even when the connection between the start detection sensor 41 a and the control side CPU 114 is disconnected, the control IC 148 is input to the input terminal of the control IC 148 under the condition that “1” is set in the latched status 113. Is configured to acquire numerical information of the random numbers. Therefore, it is possible to avoid the situation where the control IC 148 acquires the numerical information of the random number written in the latch register 102 before the operation of the start lever 41 this time.

  Next, the timing at which the control IC 148 acquires numerical value information of the random number input to the input terminal TA3 of the control IC 148 will be described with reference to the time charts of FIGS.

  First, the case where the start command setting process is executed before 12.8 μs elapses after the detection signal SG1 input to the control side CPU 114 rises will be described with reference to the time chart of FIG. The slot machine 10 is ready to start the game at the timing of t1 to t5.

  29 (a) shows the state of the detection signal SG1 input to the control IC 148, FIG. 29 (b) shows the state of the signal storage flag 144d, and FIG. 29 (c) is input to the control side CPU 114. 29 (d) shows the timing when the numerical information of the random number stored in the random number counter 105 is written to the latch register 102. FIG. 29 (e) shows the start command setting process in the control IC 148. 29 (f) shows the state of the latched status 113, FIG. 29 (g) shows the state of the confirmation command flag 144e, and FIG. 29 (h) shows the control IC 148 of the control IC 148. The timing for acquiring the numerical information of the random number input to the input terminal TA3 is shown.

  When the player operates the start lever 41 at the timing of t1, as shown in FIGS. 29A and 29C, the detection signal SG1 input to the control IC 148 and the control CPU 114 rises from the LOW state to the HI state. .

  The timing t3 is a timing at which 12.8 μs has elapsed from the timing t1 at which the detection signal SG1 input to the control side CPU 114 rises. The timing t2 is a timing after the timing t1 and a timing before the timing t3. As shown in FIG. 29E, the start command setting process is executed at the timing of t2. As shown in FIG. 29A, at timing t2, the detection signal SG1 input to the control IC 148 is in the HI state. Therefore, as shown in FIG. 29B, at timing t2, the control IC 148 sets “1” in the signal storage flag 144d. When the signal storage flag 144 d changes from “0” to “1”, the control IC 148 detects the rising of the detection signal SG1.

  As shown in FIG. 29F, at the timing of t2 when the control IC 148 detects the rising of the detection signal SG1, the value of the latched status 113 is “0”. Therefore, as shown in FIG. 29 (g), the control IC 148 sets "1" in the confirmation command flag 144e in the start command setting process executed at the timing of t2.

  As shown in FIG. 29C, the detection signal SG1 input to the control side CPU 114 rises at the timing of t1, and maintains the HI state until the timing of t3 12.8 μs after the rise. Therefore, the control side CPU 114 transmits a latch signal to the CLK terminals of the latch register D-FFs 102a to 102p at the timing of t3. As a result, as shown in FIG. 29D, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102 at the timing of t3. Further, as shown in FIG. 29F, the control side CPU 114 sets “1” to the latched status 113 at the timing of t3.

  Thereafter, as shown in FIG. 29 (e), the start command setting process is executed at the timing of t4 after the timing of t3. As shown in FIG. 29 (g), "1" is set in the confirmation command flag 144e at the timing of t4, and as shown in FIG. 29 (f), "1" is also in the latched status 113. It is set. Therefore, as shown in FIG. 29 (f), at the timing of t4, the control IC 148 transmits a pulse signal to the CLR terminal 113c of the latched status 113 to clear the latched status 113 to "0". As shown in FIG. 29 (g), the confirmation command flag 144e is cleared to "0".

  Further, the control IC 148 sets “1” to the start command flag 144 c at the same timing of t 4. Therefore, in the lottery process (FIG. 11) executed at the timing of t5 which is after the timing of the timing t4, the control IC 148 is inputted to the input terminal TA3 of the control IC 148 as shown in FIG. Get the numerical information of the random number

  As described above, when "1" is not set in the latched status 113 at the timing when the control IC 148 detects the rising of the detection signal SG1, the confirmation command flag 144e is set to "1". When the confirmation command flag 144 e is set to “1” and the latched status 113 is set to “1” in the start command setting process, the control IC 148 sets “1” to the start command flag 144 c. The setting is made to obtain the numerical value information of the random number inputted to the input terminal TA3 of the control IC 148. Therefore, even if the start command setting process is executed before 12.8 μs elapses after the detection signal SG1 input to the control side CPU 114 rises, the control IC 148 is a random number corresponding to the operation of the start lever 41 this time. The numerical information of can be obtained.

  Next, in a state where the connection between the start detection sensor 41a and the control side CPU 114 is disconnected, the timing when the control IC 148 acquires the numerical information of the random number input to the input terminal TA3 of the control IC 148 is shown in FIG. Description will be made with reference to the chart. The slot machine 10 is ready to start the game at the timing of t1 to t5 and at the timing of t8 to t12.

  FIG. 30 (a) shows the state of the detection signal SG1 input to the control IC 148, FIG. 30 (b) shows the state of the signal storage flag 144d, and FIG. 30 (c) is input to the control CPU 114 The state of the detection signal SG1 is shown, FIG. 30 (d) shows the timing when the numerical information of the random number stored in the random number counter 105 is written to the latch register 102, and FIG. FIG. 30 (f) shows the state of the latched status 113. FIG. 30 (g) shows that the control IC 148 acquires numerical information of the random number inputted to the input terminal TA3 of the control IC 148. 30 (h) shows the state of the confirmation command flag 144e, and FIG. 30 (i) shows the state of the error counter 144b. And, FIG. 30 (j) shows the timing of control IC148 transmits an abnormality signal to the game hall management computer.

  As shown in FIG. 30A, when the player operates the start lever 41 at the timing of t1, the detection signal SG1 input to the control IC 148 rises from the LOW state to the HI state. As shown in FIG. 30C, since the connection between the start detection sensor 41a and the control side CPU 114 is disconnected, the detection signal SG1 inputted to the control side CPU 114 remains in the LOW state.

  As shown in FIG. 30 (e), when the start command setting process is executed at the timing of t2 which is the timing after the timing of t1 when the detection signal SG1 rises, as shown in FIG. 30 (a). Since the detection signal SG1 input to the control IC 148 at the timing of t2 is in the HI state, the control IC 148 sets the signal storage flag 144d to "1" as shown in FIG. 30 (b). As a result, in the control IC 148, the rising of the detection signal SG1 is detected.

  The timing of t2 is a period in which the game can be started, and the rising of the detection signal SG1 is detected, but "1" is not set in the latched status 113 as shown in FIG. 30 (f). For this reason, as shown in FIG. 30G, acquisition of a random number by the control IC 148 is not performed at the timing of t2. As shown in FIG. 30H, the control IC 148 sets the confirmation command flag 144e to “1” in the start command setting process performed at the timing of t2, and ends the current start command setting process.

  As shown in FIG. 30E, the next start instruction setting process of the start instruction setting process performed at the timing of t2 is performed at the timing of t3 approximately 1.49 ms after the timing of t2. Since the operation of the start lever 41 by the player is a human action, it is longer than the interval at which the start command setting process is executed, and the detection signal SG1 is in the HI state also at the timing of t3 as shown in FIG. It is. Further, as shown in FIG. 30H, at the timing of t3, "1" is set in the confirmation command flag 144e. However, since the connection between the start detection sensor 41a and the control side CPU 114 is disconnected, “1” is not set in the latched status 113 even at the timing of t3, as shown in FIG. 30 (f). Further, as shown in FIG. 30I, at the timing of t3, the value of the error counter 144b is "0". Therefore, as shown in FIG. 30H, the control IC 148 clears the confirmation command flag 144e to “0” in the start command setting process executed at the timing of t3, and performs the error handling process (FIG. 26). Then, as shown in FIG. 30I, the control IC 148 adds “1” to the error counter 144b in the error handling process executed at the timing of t3.

  The control IC 148 also transmits a latch instruction signal in the error handling process performed at the timing of t3. The control side CPU 114 having received the latch instruction signal transmits the latch instruction signal to the CLK terminal of the latch register D-FFs 102 a to 102 p. As a result, as shown in FIG. 30 (d), at timing t4, which is after timing t3, the control-side CPU 114 transmits a latch signal to update the numerical information of the random number stored in the latch register 102. At the same time, as shown in FIG. 30F, “1” is set to the latched status 113.

  As shown in FIG. 30G, in the random number acquisition process (FIG. 29) executed at the timing of t5 after the timing of t4, the control IC 148 is a random number inputted to the input terminal TA3 of the control IC 148. Get the numerical information of and start the game. Further, as shown in FIG. 30F, the control IC 148 transmits a pulse signal to the CLR terminal 113c of the latched status 113 at the same timing of t5 to clear the latched status 113 to "0".

  Thereafter, as shown in FIG. 30A, the detection signal SG1 input to the control IC 148 falls at the timing of t6. Then, as shown in FIG. 30 (e), the start command setting process is executed at the timing of t7 which is after the timing of t6. As shown in FIG. 30 (a), since the detection signal SG1 inputted to the control IC 148 at the timing of t7 is in the LOW state, as shown in FIG. 30 (b), the control IC 148 controls the signal storage flag 144d. Clear "0".

  Thereafter, the game started at the timing of t5 ends, and as shown in FIG. 30A, when the player operates the start lever 41 at the timing of t8, the detection signal SG1 inputted to the control IC 148 rises. Then, at the timing of t9 after the timing of t8, the start command setting process is executed as shown in FIG. As shown in FIG. 30 (a), the detection signal SG1 input to the control IC 148 at the timing of t9 is in the HI state, so as shown in FIG. 30 (b), the control IC 148 stores the signal storage flag at the timing of t9. Set "1" to 144d. When the signal storage flag 144 d changes from “0” to “1”, the control IC 148 detects the rising of the detection signal SG1.

  As shown in FIG. 30 (f), since the value of the latched status 113 is “0” at the timing of t9, as shown in FIG. 30 (h), the control IC 148 sets “1” in the confirmation command flag 144e. It sets and ends this start command setting processing.

  As shown in FIG. 30E, at the timing of t10 after the timing of t9, the start instruction setting processing of the next cycle of the start instruction setting processing executed at the timing of t9 is performed. As shown in FIG. 30H, "1" is set in the confirmation command flag 144e at the timing of t10. Further, as shown in FIG. 30F, the value of the latched status 113 is “0” at the timing of t10. Then, as shown in FIG. 30I, at the timing of t10, the value of the error counter 144b is "1". In such a situation, although the rise of the detection signal SG1 is detected by the control IC 148, an event in which “1” is not set in the latched status 113 is triggered twice in response to the rise of the detection signal SG1. Represents what happened. If the event occurs twice in a row, there is a high possibility that the connection between the start detection sensor 41a and the control side CPU 114 is disconnected.

  Therefore, as shown in FIG. 30 (h), the control IC 148 clears the confirmation command flag 144e to "0" at the timing of t10 and performs the error handling process. As shown in FIG. 30 (j), the control IC 148 transmits an abnormality signal to the game hall management computer in the error handling process performed at the timing of t10, and is input to the control side CPU 114 by the game hall manager. Informing that abnormality has occurred in the behavior of the detection signal SG1.

  In addition, the control IC 148 transmits a latch instruction signal in the error handling process performed at the timing of t10. The control side CPU 114 that has received the latch instruction signal from the control IC 148 transmits a latch signal to the CLK terminal of the latch register D-FFs 102 a to 102 p. Thereby, as shown in FIG. 30D, the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102 at the timing of t11. Further, as shown in FIG. 30F, the control side CPU 114 sets “1” to the latched status 113 at the same timing of t11.

  Thereafter, in the lottery process (FIG. 11) executed at the timing of t12, as shown in FIG. 30G, the control IC 148 acquires numerical information of the random number inputted to the input terminal TA3 of the control IC 148. Further, as shown in FIG. 30F, the control IC 148 clears the latched status 113 to "0" at the same timing of t12.

  As described above, when only the detection signal SG1 input to the control IC 148 rises and the detection signal SG1 input to the control side CPU 114 does not rise, at the timing when the rising of the detection signal SG1 is detected in the control IC 148. In response, control IC 148 transmits a latch instruction signal. Then, the control side CPU 114 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p in response to the reception of the latch instruction signal. As a result, even in the state where the connection between the start detection sensor 41a and the control side CPU 114 is disconnected, it is possible to perform the success or failure judgment of the role using the numerical information of the random number corresponding to the timing when the player operates the start lever 41. it can.

  Further, even though the control IC 148 detects rising of the detection signal SG1, an event that “1” is not set in the latched status 113 occurs twice or more consecutively according to the rising of the detection signal SG1. In the second and subsequent error handling processes, the control IC 148 transmits an abnormal signal to the game hall management computer. As a result, it is possible to notify the administrator of the gaming hall that the game is continued in a state where there is an abnormality in the behavior of the detection signal SG1 input to the input terminal TA3 of the control side CPU 114.

  As described above, the start command setting process is executed in a state where the game can be started, the rising of the detection signal SG1 input to the control IC 148 is detected, and it is determined that "1" is not set in the latched status 113. In this case, the confirmation instruction flag 144e is set to "1", and the state of the latched status 113 is determined again in the next start instruction setting process. Then, in the next start instruction setting process of the start instruction setting process finished by setting “1” to the confirmation instruction flag 144 e, when “1” is set to the latched status 113, the control IC 148. Is a configuration for acquiring numerical information of the random number input to the input terminal TA3 of the control IC 148. Therefore, even when the start command setting process is executed before 12.8 μs elapses from when the detection signal SG1 input to the control side CPU 114 rises, the random number corresponding to the operation of the start lever 41 this time is It is possible to execute the success or failure judgment of the combination using numerical information.

  In addition, even if the rising of detection signal SG1 input to control IC 148 is detected, control IC 148 transmits a latch instruction signal when an event occurs in which "1" is not set in latched status 113. Do. Then, the control side CPU 114 that has received the latch instruction signal transmits the latch signal to the CLK terminal of the latch register D-FFs 102 a to 102 p. Also, the second time when an event that “1” is not set to the latched status 113 occurs twice or more consecutively although the rising of the detection signal SG1 input to the control IC 148 is detected. The control IC 148 is configured to transmit an abnormality signal to the management computer of the gaming hall in the subsequent error handling process. Thereby, even when the connection between the start detection sensor 41a and the control side CPU 114 is disconnected, the control IC 148 acquires numerical information of the random number written in the latch register 102 triggered by the pressing operation of the start lever 41. You can continue. In addition, the manager of the gaming hall can execute maintenance of the slot machine 10 at a timing that does not cause a disadvantage to the player.

  In addition, in the start command setting process executed in the game startable state, when the rising of the detection signal SG1 input to the control IC 148 is not detected, the latched status 113 is cleared to “0”. The control IC 148 is configured to transmit a pulse signal to the CLR terminal 113 c of the latched status 113. Therefore, noise enters only the control side CPU 114 before the player operates the start lever 41, and even if "1" is set to the latched status 113 triggered by the noise, the player enters noise after entering the noise. When the start command setting process is executed before the start lever 41 is operated, the latched status 113 is cleared to “0” in the start command setting process. The start lever 41 is operated in a state where the latched status 113 is set to “1”, and the possibility that the control IC 148 acquires numerical information of an old random number not corresponding to the operation of the start lever 41 this time may be reduced. it can.

<Another form of the second embodiment>
In the error handling process (FIG. 26) of the second embodiment described above, when the value of the error counter 144 b is “1” (step S 901: NO), the control IC 148 obtains numerical information of random numbers from the random number counter 105. It is good also as composition acquired directly. Here, with direct acquisition of random numbers by the control IC 148, the control IC 148 acquires numerical information of the random numbers output from the Q terminals of the D-FFs 105a to 105p for random number counters without passing through the latch register 102. It means that.

  FIG. 31A is a block diagram for explaining a connection mode between the control IC 148 provided in the main control board 141 and the random number counter 105. The configuration of the main control board 141 in the present configuration will be described using the block diagram. The same configuration as the configuration of the main control board 141 in the second embodiment is omitted. As shown in FIG. 31A, in the main control board 141 of this configuration, the signal lines extending from the Q terminals of the random number counter D-FFs 105a to 105p are branched and the Ds of the latch registers D-FFs 102a to 102p are branched. It is connected to the terminal and the input terminal TA6 of the control IC 148. Therefore, the numerical value information of the random number stored in the random number counter 105 is output to each of the latch register 102 and the input terminal TA6 of the control IC 148. The numerical value information of the random number output to the latch register 102 is written to the latch register 102 at the timing when the pulse signal is transmitted to the CLK terminals of the latch register D-FFs 102 a to 102 p. In addition, the numerical value information of the random number output to the input terminal TA3 of the control IC 148 is in a state where "1" is not set in the latched status 113 when the detection signal SG1 input to the control IC 148 rises. If it is, it is acquired by the control IC 148.

  Here, the input terminal TA3 (FIG. 6) of the control IC 148 to which numerical value information of random numbers output from the Q terminals of the latch register D-FFs 102a to 102p is input is the Q of the D-FFs 105a to 105p for random number counters. This is an input terminal different from the input terminal TA6 (FIG. 31 (a)) of the control IC 148 to which numerical value information of the random number output from the terminal is input. Therefore, the control IC 148 can identify and selectively acquire the numerical value information of the random number output from the latch register 102 and the numerical value information of the random number output from the random number counter 105.

  When the control IC 148 directly acquires the numerical information of the random number output from the Q terminals of the random number counter D-FFs 105 a to 105 p and input to the input terminal TA 6 of the control IC 148, the second embodiment In the error handling process (FIG. 26), the process of step S904 is omitted. The error handling process in this configuration will be specifically described below.

  If the value of the error counter 144 b is “0” (step S 901: YES), the control IC 148 adds “1” to the error counter 144 b (step S 902), and then adds “1” to the start command flag 144 c. It sets (step S905). Then, the error state flag 144 f is set to “1” (step S 906), and the error handling process is ended. Further, when the value of the error counter 144b is "1" (step S901: NO), the control IC 148 transmits an abnormality signal to the game hall management computer (step S903), and then the start command flag 144c. Is set to "1" (step S905). Then, the error state flag 144 f is set to “1” (step S 906), and the error handling process is ended.

  As described above, the control IC 148 of this configuration does not transmit the latch instruction signal to the control side CPU 114. The management operation executed by the control side CPU 114 of this configuration is the same processing configuration as the management operation (FIG. 19) executed by the control side CPU 114 of the first embodiment.

  Specifically, first, the process waits until the detection signal SG1 input to the control side CPU 114 is in the LOW state (step S701), and when in the LOW state (step S701: YES), the detection signal SG1 is It waits until it becomes HI state (step S702). When the detection signal SG1 is in the HI state (step S702: YES), the timer counter is used to start counting the time during which the HI state is continued (step S703).

  If 12.8 μs has elapsed while the detection signal SG1 remains in the HI state (step S704: YES, step S705: YES), the counting of the time using the timer counter is stopped (step S706). Then, a latch signal is sent to the CLK terminal of the latch register D-FFs 102a to 102p (step S707), and the latched status 113 is set to "1" until the detection signal SG1 becomes LOW again. The process returns to the first process of waiting (step S701).

  When the HI state of the detection signal SG1 returns to the LOW state after less than 12.8 μs (step S704: NO), the timer counter stops counting time (step S709), and the timer counter is reset. Then, the process returns to the second process (step S702) of waiting until the detection signal SG1 is in the HI state again.

  Next, random number acquisition processing in the case where the control IC 148 directly acquires numerical value information of random numbers stored in the random number counter 105 in the present configuration will be described with reference to the flowchart of FIG.

  First, in step S1201, it is determined whether "1" is set in the error state flag 144f. When the error state flag 144 f is set to “1” in step S 1201, the numerical value information of the random number corresponding to the operation of the start lever 41 this time is not written in the latch register 102. In this case, the error status flag 144f is cleared to "0" in step S1202, and is output from the Q terminal of the random number counter D-FF 105a to 105p in step S1203 and input to the input terminal TA3 (FIG. 6) of the control IC 148. The numerical value information of the input random number is acquired, and the random number acquisition process is ended.

  Further, in the case where the error state flag 144 f is not set to “1” in step S 1201, this is because the numerical information of the random number corresponding to the operation of the start lever 41 this time is already written in the latch register 102. is there. In this case, in step S1204, numerical value information of the random number output from the latch register 102 and input to the input terminal TA6 (FIG. 31A) of the control IC 148 is acquired, and this random number acquisition processing ends. Do.

  Thus, the control IC 148 of this configuration can obtain random numbers in two ways. Among them, a random number acquired by a method in which the control IC 148 acquires a random number output from the Q terminal of the latch register D-FFs 102 a to 102 p and input to the input terminal TA3 of the control IC 148 is an indirect acquired random number. The indirectly acquired random number is a random number stored in the random number counter 105 12.8 μs after the rise of the detection signal SG1 input to the control side CPU 114 is detected. The timing at which the indirectly acquired random number is acquired is a random number stored in the random number counter 105 after a predetermined time from the timing when the detection signal SG1 rises, and the predetermined time is a relatively short time of 12.8 μs.

  On the other hand, the random numbers acquired by the method of the control IC 148 acquiring are directly acquired random numbers, which are output from the Q terminals of the random number counter D-FFs 105a to 105p and input to the input terminal TA6 of the control IC 148. The said directly acquired random number is a random number acquired in the timer process (FIG. 8) performed by control IC148. The timing at which the directly acquired random number is acquired is a random number stored in the random number counter 105 after an indefinite time from the timing when the detection signal SG1 rises, and the indefinite time is in a time range of 1.49 ms. And the time of 1.49 ms is a long time when compared with 12.8 μs.

  Therefore, the indirectly acquired random number is a random number that reflects the operation timing of the start lever 41 by the player more largely than the directly acquired random number. The present configuration is configured to execute the winning / non-falling judgment of the winning combination using the indirectly acquired random number in a state where the connection between the start detection sensor 41a and the control side CPU 114 is not disconnected, and the start detection sensor 41a and the control side CPU 114 In the state where the connection is disconnected, the random number to be used for the judgment of the winning combination is directly switched to the acquired random number.

  According to this configuration, the operation timing of the start lever 41 by the player can be accurately reflected on the game result, and the random number used for the judgment of the winning combination is also started when the connection between the start detection sensor 41a and the control side CPU 114 is disconnected. It can be updated according to the operation timing of the lever 41.

Third Embodiment
In the present embodiment, the timing at which the control CPU 114 sets “1” in the latched status 113 is limited to a period in which the game can be started. In addition, the control IC 148 starts the game when the detection signal SG1 input to the control IC 148 is in the HI state and “1” is set in the latched status 113. The description of the same configuration as that of the first embodiment is basically omitted.

  FIG. 32 is a block diagram for explaining the configuration of the main control board 141 in the present embodiment. As shown in FIG. 32, the main MPU 142 of this embodiment includes a control IC 148 and a hard random number circuit 146. The hard random number circuit 146 includes a control circuit 103, an update circuit 101, and a latch register 102.

  The update circuit 101 of the present embodiment has the same configuration as the update circuit 101 (FIG. 6) of the first embodiment described above. Therefore, the updating circuit 101 includes the clock circuit 104 and the random number counter 105. The random number counter 105 of this embodiment has the same configuration as the random number counter 105 of the first embodiment described above. Specifically, the random number counter 105 is configured of 16 random number counter D-FFs 105a to 105p (FIG. 6).

  Further, the latch register 102 of the present embodiment has the same configuration as the latch register 102 of the first embodiment described above. Specifically, the latch register 102 is composed of 16 latch register D-FFs 102a to 102p (FIG. 6).

  Also, the control circuit 103 of this embodiment has the same configuration as the control circuit 103 (FIG. 6) of the first embodiment described above. In detail, the control circuit 103 comprises a control side CPU 114 and a latched status 113. The control side CPU 114 is a CPU that executes processing using a program. A program for executing a management operation (FIG. 35) is stored in the ROM 115 of the control side CPU 114, and a storage area for temporarily storing information is set in the RAM 116 of the control side CPU 114.

  Further, as shown in FIG. 32, the main RAM 144 in the present embodiment is provided with an error counter 144b and a start command flag 144c. The control IC 148 includes an output terminal TA7, and the control CPU 114 includes an input terminal TB7. The output terminal TA7 of the control IC 148 and the input terminal TB7 of the control side CPU 114 are connected by a signal line, and the start enable signal output from the output terminal TA7 of the control IC 148 is input to the input terminal TB7 of the control side CPU 114 There is.

  In the normal processing (FIG. 34), the control IC 148 raises the start enable signal when the start timing of the game start enable period comes, and the start enable signal when the game start enable period ends. Fall down. Therefore, the control side CPU 114 can determine whether or not the game can be started by grasping the state of the start enable signal input to the input terminal TB7. The control side CPU 114 in this embodiment sets “1” to the latched status 113 as one of the conditions that the game can be started. The details of the normal process (FIG. 34) in the present embodiment will be described later.

  Further, as shown in FIG. 32, the control side CPU 114 has an output terminal TB6 connected to the CLR terminal 113c of the latched status 113. Here, the control IC 148 in the present embodiment does not have the output terminal connected to the CLR terminal 113 c of the latched status 113. In the present embodiment, “0” clear of the latched status 113 is performed by the control side CPU 114.

  Specifically, after the control-side CPU 114 sets the latched status 113 to “1”, if the start enable signal falls to the LOW state before a predetermined time elapses, the control IC 148 has the latched status. In normal processing (FIG. 34) executed after setting “1” to 113, it means that it is time to start the game. In this case, at the falling timing, a pulse signal is transmitted from the output terminal TB6 to the CLR terminal 113c of the latched status 113 to clear the latched status 113 to "0".

  In addition, after the control side CPU 114 sets “1” to the latched status 113, only the input terminal TB1 of the control side CPU 114 if the start enable signal does not fall to the LOW state even after a predetermined time passes. This means that the control-side CPU 114 has set the latched status 113 to “1” in response to the noise.

  Specifically, when noise enters only the input terminal TB1 of the control side CPU 114, the signal input to the input terminal TB1 rises from the LOW state to the HI state, and the HI state is maintained for 12.8 μs. The side CPU 114 transmits a latch signal to the latch register 102 and transmits a pulse signal to the T terminal 113 b of the latched status 113 to set “1” in the latched status 113.

  In this case, since the detection signal SG1 input to the input terminal TA1 of the control IC 148 does not rise, the start enable signal does not fall. The control side CPU 114 is configured to determine whether or not the game is in progress based on a signal output from the output terminal TA7 of the control IC 148 and being input to the input terminal TB7 of the control side CPU 114. The control side CPU 114 sets “1” to the latched status 113 triggered by a noise, and when the state in which “1” is set to the latched status 113 is maintained for a long time, “Latched status 113” The player operates the start lever 41 in the state in which 1 is set.

  When the start lever 41 is operated while the latched status 113 is set to "1", the detection signal SG1 input to the input terminal TA1 of the control IC 148 and the input terminal TB1 of the control side CPU 114 is in the LOW state Stand up to HI state from When the detection signal SG1 input to the input terminal TB1 of the control side CPU 114 rises to the HI state and the HI state is maintained for 12.8 μs or more, at the timing when 12.8 μs has elapsed from the rise of the detection signal SG1. The control side CPU 114 outputs a latch signal to the latch register 102 and transmits a pulse signal to the T terminal 113 b of the latched status 113 to set “1” in the latched status 113.

  In this case, if the detection signal SG1 input to the input terminal TA1 of the control IC 148 rises, and the start command setting process is executed at a timing before 12.8 μs elapses from the rise of the detection signal SG1, the start The detection signal SG1 input to the input terminal TA1 of the control IC 148 at the timing when the command setting process is performed is in the HI state, and “1” is set in the latched status 113. The start command flag 144c is set to "1". For this reason, in the normal processing performed thereafter, there is a possibility that the control IC 148 executes the lottery of the winning combination using the numerical value information of the random numbers written in the latch register 102 in response to the introduction of noise.

  On the other hand, the start enable signal HI that is input to the input terminal TB7 of the control CPU 114 is HI until the predetermined time elapses from the timing when the control CPU 114 sets “1” in the latched status 113. When the control side CPU 114 clears the latched status 113 by “0” when it does not fall to the LOW state from the state, the random number written in the latch register 102 triggered by the mixing of noise by the control IC 148 It is possible to reduce the possibility of executing the winning or losing lottery of the part by using the numerical information of.

  Here, the above-mentioned predetermined time is a time longer than the maximum time until the start enable signal falls after the detection signal SG1 rises in the slot machine 10, and is 5 ms in this embodiment. . In the slot machine 10, after the detection signal SG1 rises, the maximum time for the start enable signal to fall is experimentally determined in the design stage.

  Next, the start instruction setting process executed in step S206 of the timer interrupt process (FIG. 8) will be described with reference to FIG. FIG. 33 is a flowchart showing the start command setting process executed by the control IC 148.

  First, in step S1301, it is determined whether it is a game startable period, and if it is not a game startable period (step S1301: NO), the main start instruction setting process is ended as it is, and the game startable period If it is determined that (step S1301: YES), the process proceeds to step S1302.

  In step S1302, it is determined whether or not the detection signal SG1 input to the control IC 148 is in the HI state. If the detection signal SG1 is in the LOW state (step S1302: NO), this start instruction setting process is directly performed. finish. If the detection signal SG1 is in the HI state (step S1302: YES), it is determined in step S1303 whether "1" is set in the latched status 113 or not. If “1” is set in the latched status 113 (step S1303: YES), this means that the condition for starting the game is satisfied, so “1” is set in the start command flag 144c in step S1304. Is set, the error counter 144b is cleared to "0", and the start instruction setting process is terminated.

  Here, in the present embodiment, the condition for starting the game is a condition that “1” is set to the latched status 113 under the condition that the detection signal SG1 input to the control IC 148 is in the HI state. It is.

  When "1" is not set in the latched status 113 in step S1303, in steps S1306 to S1309, steps S308 to S308 in the start command setting process (FIG. 9) of the first embodiment are performed. The same process as step S312 is performed.

  Specifically, after adding "1" to the error counter 144b (step S1306), when the error counter 144b becomes "3" (step S1307: YES), the error counter 144b is cleared to "0". Then (step S1308), an abnormality notification process is executed (step S1309). If the error counter 144b after the addition of “1” is “2” or less (step S1307: NO), the present start instruction setting process is ended as it is.

  Thus, the control IC 148 is configured to start the game on condition that the detection signal SG1 input to the control IC 148 is in the HI state and that the latched status 113 is set to "1". . Therefore, it starts at a timing before the numerical information of the random number stored in the latch register 102 is updated 12.8 μs after the detection signal SG1 output from the start detection sensor 41a rises to the HI state. When the command setting process is executed, the timing at which the control IC 148 starts the game is grasped as compared with the configuration in which the flag for confirming the state of the latched status 113 is set again in the next start command setting process. Processing load can be reduced.

  Next, normal processing executed by the control IC 148 will be described with reference to FIG. First, in step S1401, the same process as step S401 in the normal process (FIG. 10) of the first embodiment is executed. Specifically, an interrupt permitting process for permitting the next timer interrupt process (FIG. 8) is executed.

  In the following step S1402, the same processing as step S402 in the normal processing (FIG. 10) of the first embodiment is executed. Specifically, start waiting processing is executed. Here, when the medal return process is executed in the start waiting process of the present embodiment, the control IC 148 clears the start command flag 144c to “0” at the start timing of the medal return process and the start enable signal. Fall down.

  By clearing the start command flag 144c to “0” at the start timing of the medal return process, the game is started before the start lever 41 is operated at the timing when the bet number of medals reaches the specified number again. It can be avoided. In addition, it is possible to prevent the control side CPU 114 from setting the latched status 113 to “1” after medal return by lowering the start enable signal.

  In the following step S1403, the same processing as step S403 in the normal processing (FIG. 10) of the first embodiment is executed. Specifically, if the bet number has not reached the specified number (step S1403: NO), the process returns to step S1402, and if the bet number has reached the specified number (step S1403: YES), the process proceeds to step S1404. .

  In step S1404, it is determined whether the start enable signal output from the output terminal TA7 (FIG. 32) of the control IC 148 is in the HI state. If the start enable signal is in the LOW state (step S1404: NO), it means that it is the start timing of the game start enable period, so the start enable signal is raised to the HI state in step S1405. Thus, the control CPU 114 receiving the start enable signal can grasp the start timing of the game start enable period.

  If the start enable signal is in the HI state in step S 1404, it means that the game start available period has already been started. After making a negative determination in step S1404 or raising the start enable signal to the HI state in step S1405, it is determined in step S1406 whether "1" is set in start instruction flag 144c. If "1" is not set in start instruction flag 144c (step S1406: NO), the process returns to step S1402.

  If "1" is set in start command flag 144c in step S1406 (step S1406: YES), the numerical information of the random number corresponding to the operation of start lever 41 of this time is the input terminal of control IC 148 It means that it is input to TA3. In this case, the start instruction flag 144c is cleared to "0" in step S1407, and the start enable signal is lowered in step S1408. As a result, the control CPU 114 receiving the start enable signal can recognize that it is the end timing of the game start enable period.

  In the subsequent step S1409, other processes are executed, and the process returns to step S1401. In the other processes, the same processes as the processes of steps S410 to S416 in the normal process (FIG. 10) of the first embodiment are performed.

  Next, the management operation executed by the control side CPU 114 will be described with reference to the flowchart of FIG. First, in step S1501, it is determined whether or not the game can be started. Specifically, when the start enable signal output from the output terminal TA7 to the control IC 148 and input to the input terminal TB7 of the control side CPU 114 is in the LOW state, it is determined that the game start enable period is out. Wait until the possible start signal rises to the HI state. If the start enable signal is in the HI state, it is determined that the game can be started, and the process advances to step S1502.

  In steps S1502 to S1510, the same processes as steps S701 to S708 in the management operation (FIG. 19) in the first embodiment described above are executed. Specifically, the process waits until the detection signal SG1 input to the control side CPU 114 is in the LOW state (step S1502). If the detection signal SG1 input to the control side CPU 114 is in the LOW state (step S1502: YES), the process waits until the detection signal SG1 is in the HI state (step S1503).

  When the detection signal SG1 input to the control side CPU 114 is in the HI state (step S1503: YES), the timer counter is used to start counting the time during which the detection signal SG1 maintains the HI state (step S1504). In the present embodiment, the count is referred to as a first count. After the first count is started, it is determined whether the HI state of the detection signal SG1 input to the control side CPU 114 is maintained for 12.8 μs or more (steps S1505 and S1506). Then, when the duration of the HI state of the detection signal SG1 is less than 12.8 μs (step S1505: NO), the first count is stopped and the timer counter is reset (step S1507), step S1503 Return to

  If it is determined that the detection signal SG1 maintains the HI state for 12.8 μs or more (step S1505: YES, step S1506: YES), the first count is stopped and the timer counter is reset (step S1508). . Then, a latch signal is transmitted to the CLK terminal of the latch register D-FFs 102a to 102p (step S1509), and "1" is set to the latched status 113 (step S1510).

  After "1" is set to the latched status 113 in step S1510, in step S1511, the timer counter is used to start counting the time during which the latched status 113 is continuously set to "1". . The count is taken as a second count. In the following step S1512, it is determined whether or not the start enable signal is in the LOW state, and if the start enable signal is in the HI state (step S1512: NO), “1” is included in the latched status 113 in step S1513. It is determined whether 5 ms has elapsed since the setting, and if 5 ms has not elapsed, the process returns to step S1512.

  If it is determined in step S1512 that the start enable signal is in the LOW state, this means that the game start available period has ended, so that the second count is stopped and the timer counter is reset in step S1514. Then, in step S1515, a pulse signal is transmitted to the CLR terminal 113c of the latched status 113 to clear the latched status 113 to "0", and the process returns to step S1501.

  When an affirmative determination is made in step S1513, the start command flag is set in the start command setting process executed by control IC 148 until 5 ms elapses from when 1 is set to latched status 113. It means that "1" was not set to 144c. Such a state occurs when noise is mixed into the input terminal TB1 of the control side CPU 114 and "1" is set to the latched status 113 triggered by the mixing of the noise.

  In this case, the second count is stopped in step S1516 and the timer counter is reset, and a pulse signal is transmitted to the CLR terminal 113c of the latched status 113 in step S1517 to set the latched status 113 to "0. "Clear and return to step S1502.

  As described above, the control side CPU 114 determines whether or not the game startable period is set, and "1" is set to the latched status 113 as one condition that the game startable period is set. . Therefore, the processing load for the control IC 148 to execute the start command setting process can be reduced.

  The detection of the rising edge of the detection signal SG1 input to the control side CPU 114 from the LOW state to the HI state is one of the conditions for setting the latched status 113 to “1”. Therefore, when the start operation of the start lever 41 is performed and the depression operation is continued for a long time, a process is performed in which “1” is set in the latched status 113 according to the start timing of the depression operation. Is done only once. The process of setting the latched status 113 to “1” is not repeated in response to the depression operation being continued.

  In addition, it is one of the conditions for setting “1” in the latched status 113 that the game can be started. Therefore, even when the start lever 41 is pressed outside the game startable period, the latched status 113 is not set to "1" triggered by the pressing operation.

  Here, the process of lowering the start enable signal to the LOW state is the process of step S1408 of the normal process (FIG. 34) performed by the control IC 148. The process of step S1408 is performed on condition that the start instruction flag 144c is set to "1". Then, the process of setting “1” in the start command flag 144c (the process of step S1304 in the start command setting process (FIG. 33)) sets one condition that “1” is set in the latched status 113. Done as.

  Therefore, after the start enable signal is determined to be in the HI state in step S1501 of the management operation, the start enable signal is LOW until “1” is set in the latched status 113 in step S1510. It never falls into a state. For example, while waiting for the detection signal SG1 to be in the LOW state in step S1502, while waiting for the detection signal SG1 to be in the HI state in step S1503, and for the detection signals in step S1505 and step S1506. The start enable signal does not fall to the LOW state while waiting until it is determined that the SG1 HI state continues for 12.8 μs or more.

  In addition, “1” is set to the latched status 113 under a partial condition that the game can be started and that the detection signal SG1 input to the control CPU 114 rises from the LOW state to the HI state. It is. Therefore, when the start operation of the start lever 41 is started during the game and the period when the game can be started in the state where the depression operation is continued, the latched status 113 is triggered by the depression operation. "1" is never set to. In the slot machine 10, the game is started under the condition that the start lever 41 is operated in the state where the game can be started.

  Next, the timing at which the control IC 148 acquires numerical value information of the random number input to the input terminal TA3 of the control IC 148 will be described with reference to the time chart of FIG. 36 (a) shows the state of the detection signal SG1 inputted to the control IC 148, FIG. 36 (b) shows the state of the detection signal SG1 inputted to the control side CPU 114, and FIG. 36 (c) shows random numbers 36 (d) shows the state of the latched status 113, and FIG. 36 (e) shows the start command setting process in the control IC 148. 36 (f) shows the timing when the control IC 148 acquires numerical information of the random number input to the input terminal TA3 of the control IC 148, and FIG. 36 (g) shows the start command flag 144c. 36 (h) shows a period during which the game can be started, and FIG. 36 (i) shows the state of the error counter 144b. It is.

  When noise is mixed into only the input terminal TB1 of the control side CPU 114 at the timing of t1, as shown in FIG. 36A, the detection signal SG1 inputted to the control side CPU 114 rises from the LOW state to the HI state. The HI state of the detection signal SG1 is continued until the timing of t3. The control side CPU 114 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p at a timing 12.8 μs after the timing t1 and at a timing t2 before the timing t3. , And transmits a pulse signal to the T terminal 113 b of the latched status 113. Thereby, as shown in FIG. 36C, the random number stored in the random number counter 105 is written to the latch register 102 at the timing of t2, and as shown in FIG. 36D, the latched status 113 is stored. "1" is set.

  As shown in FIG. 36E, the start command setting process is executed by the control IC 148 at the timing of t4 which is after the timing of t3. As shown in FIG. 36A, since the detection signal SG1 input to the control IC 148 at the timing of t4 is in the LOW state, as shown in FIG. 36G, the control IC 148 starts at the timing of t4. The command flag 144c is not set to "1". In this case, as shown in FIG. 36D, the control side CPU 114 clears the latched status 113 to “0” at the timing of t5 which is after the timing of t4 and at the timing of 5 ms after the timing of t3. .

  As shown in FIGS. 36 (a) and 36 (b), the start lever 41 is depressed at timing t6 after timing t5, and the detection signal SG1 input to the control IC 148 and the control side CPU 114 is LOW. From state to HI state. As shown in FIG. 36E, the start command setting process is executed at timing t7 which is a timing after timing t6 and which is before timing t8 at which 12.8 μs has elapsed from timing t6. .

  At the timing of t7, as shown in FIG. 36A, the detection signal SG1 input to the control IC 148 is in the HI state, but as shown in FIG. 36D, the latched status 113 is “1”. Since it is not set, as shown in FIG. 36 (g), the control IC 148 does not set the start instruction flag 144c to "1" at the timing of t7. As shown in FIG. 36 (i), the control IC 148 adds "1" to the error counter 144b at the timing of t7.

  Thereafter, at time t8, the control side CPU 114 transmits a latch signal to the CLK terminals of the random number counter D-FFs 102a to 102p and transmits a pulse signal to the T terminal 113b of the latched status 113, as shown in FIG. The random number stored in the random number counter 105 is written to the latch register 102 as shown in FIG. 36, and "1" is set to the latched status 113 as shown in FIG. 36 (d).

  Thereafter, as shown in FIG. 36E, the start command setting process is executed at the timing of t9. At timing t9, as shown in FIG. 36A, the detection signal SG1 input to the control IC 148 is in the HI state, and as shown in FIG. 36D, the latched status 113 is “1”. Is set. Therefore, as shown in FIG. 36 (g), the control IC 148 sets “1” to the start command flag 144c at the timing of t9, and clears the error counter 144b to “0” as shown in FIG. 36 (i). Do.

  In the normal processing executed at the timing of t10 which is after the timing of t9, the control IC 148 clears the start instruction flag 144c to "0" as shown in FIG. 36 (g), and as shown in FIG. 36 (h) The start possible signal is lowered to the LOW state to end the period in which the game can be started.

  The control side CPU 114 clears the latched status 113 to "0" as shown in FIG. 36 (d) at the timing of t9 when the start enable signal falls. Further, the control IC 148 acquires numerical information of the random number input to the input terminal TA3 of the control IC 148 in the lottery process executed at the timing of t9.

  As described above, when “1” is set to the latched status 113 triggered by noise entering only the control CPU 114, the latched status 113 is cleared to “0” 5 ms later. Therefore, it is possible to avoid the situation where the start lever 41 is operated in a state where the latched status 113 is set to "1" and the control IC 148 acquires an old random number.

  Further, when the detection signal SG1 input to the control IC 148 is in the HI state, the control IC 148 always determines whether "1" is set to the latched status 113 or not. Therefore, even if the start command setting process is executed before 12.8 μs elapses after the rise of the detection signal SG1 output from the start detection sensor 41a, the control IC 148 corresponds to the operation of the current start lever 41. Random numbers can be obtained.

  Next, a case where the start lever 41 is pressed in a state where the connection between the start detection sensor 41a and the input terminal TB1 of the control side CPU 114 is disconnected will be described with reference to the time chart of FIG. FIG. 37 (a) shows the detection signal SG1 inputted to the control IC 148, FIG. 37 (b) shows the timing of the start command setting process executed by the control IC 148, and FIG. 37 (c) shows the error counter 144b. FIG. 37 (d) shows the timing at which abnormality notification processing is performed. Here, the connection between the start detection sensor 41a and the input terminal TB1 of the control side CPU 114 is disconnected. Further, the timing of t1 to t4 is a period in which the game can be started.

  As shown in FIG. 37A, when the start lever 41 is operated at the timing of t1, the detection signal SG1 input to the control IC 148 rises from the LOW state to the HI state. Thereafter, as shown in FIG. 37B, the start command setting process is executed at the timing of t2 and at the timing of t3 approximately 1.49 ms after the timing of t2. As shown in FIG. 37 (a), although the detection signal SG1 input to the control IC 148 is in the HI state at the timing of t2 to t4, the detection signal SG1 input to the control side CPU 114 does not rise, so it is latched "1" is not set in the status 113.

  Therefore, as shown in FIG. 37C, “1” is added to the error counter 144b at each of the timing of t2 and the timing of t3. In the start command setting process executed at the timing of t4, “1” is added to the error counter 144b, and the value of the error counter 144b becomes “3”, as shown in FIG. 37 (c). At the timing of t4, the error counter 144b is cleared to "0", and as shown in FIG. 37 (d), "1" is not set in the latched status 113 by executing the abnormality notification processing. To the manager of the gaming hall.

  As described above, in the start command setting process, it is determined that the detection signal SG1 input to the control IC 148 is in the HI state and the events in which it is determined that “1” is not set in the latched status 113 are continuous. When three occurrences occur, the anomaly notification process is executed. As a result, the latched status 113 is not set to “1”, and it is possible to avoid a situation in which the determination of whether the combination using the old random number not corresponding to the operation of the start lever 41 is repeated is repeated.

  As described above, as a condition for setting “1” to the latched status 113 in the control side CPU 114, the condition that the game can be started is detected, and the rising of the detection signal SG1 input to the control side CPU 114 is detected. And the condition that the HI state of the detection signal SG1 input to the control side CPU 114 is continued for 12.8 μs or more from the detection of the rising edge. Therefore, the conditions for the control IC 148 to set the start command flag 144c to “1” in the start command setting process include the condition that the detection signal SG1 input to the control IC 148 is in the HI state, and the latched status 113 It is narrowed down to the condition that "1" is set to. As a result, it is possible to reduce the processing load for the control IC 148 to set “1” in the start command flag 144c.

  In addition, the timing at which the control side CPU 114 sets “1” in the latched status 113 is limited to a period in which the game can be started, and the control IC 148 says that the detection signal SG1 input to the control IC 148 is in the HI state. When both the condition and the condition that “1” is set in the latched status 113 are satisfied, numerical value information of the random number input to the input terminal TA3 of the control IC 148 is acquired. Therefore, even when the start instruction setting process is executed before the numerical value information of the random number stored in the random number counter 105 is written to the latch register 102, the control IC 148 acquires the random number corresponding to the operation of the start lever 41. can do.

  In the start command setting process, the control IC 148 sets the numerical value information of the random number input to the input terminal TA3 of the control IC 148 as one condition that the detection signal SG1 input to the control IC 148 is in the HI state. Get and start the game. Since the player is pressing the start lever 41 at the timing when the control IC 148 starts the game, the control IC 148 acquires numerical information of random numbers due to the timing at which each processing is performed being shifted. Even if the timing is delayed, the game can be started with the player continuing the pressing operation of the start lever 41.

  More specifically, after the player has started pressing the start lever 41, if the start command setting process is executed before the latched status 113 is set to "1", the start command setting process is performed. In the start instruction setting process following the start instruction setting process, the start instruction flag 144 c is set to “1”, and the game is started.

  Therefore, when the player starts the game by setting the start command flag 144c to “1” in the start command setting process which is first executed after the player operates the start lever 41, the player may use the start lever 41. There is a case where the game is started by setting “1” to the start command flag 144c in the start command setting process which is executed for the second time after the operation of. When "1" is set to the start command flag 144c in the second start command setting process, the game is started more than when "1" is set to the start command flag 144c in the first start command setting process. Timing is delayed.

  However, in any case, the player continues to depress the start lever 41 at the timing when the game is started. Therefore, the game is started after the player's pressing operation of the start lever 41 is finished, and it is possible to avoid giving a sense of discomfort to the player at the start timing of the game.

  In addition, the control-side CPU 114 clears the latched status 113 to “0” at a timing when 5 ms has elapsed since “1” is set to the latched status 113, whereby the latched status 113 is triggered by noise. It is possible to prevent the control IC 148 from acquiring an old random number when the start lever 41 is operated while the state is maintained.

  The control side CPU 114 transmits a pulse signal to the CLK terminal of the latch register D-FFs 102 a to 102 p that the game can be started and that the rising edge of the detection signal SG 1 is detected in the control side CPU 114. As part of the condition. Therefore, even if the player continues pressing the start lever 41 during the game and the start timing of the game startable period is reached with the start lever 41 pressed, the game is started immediately after the start timing. Is never started. The game can be started only when the start lever 41 is operated within the game startable period.

Fourth Embodiment
The hard random number circuit 146 in the present embodiment includes two latch registers 407 and 408 (FIG. 39). Numerical information of different random numbers is written to the two latch registers 407 and 408 at different timings. The numerical information of the two random numbers written in the two latch registers 407 and 408 are used for different lottery. The description of the same configuration as that of the first embodiment is basically omitted.

  First, referring to FIG. 38, the correspondence between the combination of symbols to be won in the present embodiment and the benefit provided when winning is given, together with the correspondence in the first embodiment (FIG. 4). Explains the differences.

  In the present embodiment, the first cherry role and the second cherry role exist as cherry roles. First, the first cherry will be described. In the present embodiment, when the first cherry is won, the preparation state ST31 (FIG. 47) of the AT state ST3 (FIG. 47) advantageous for the player is obtained. In the present embodiment, when the first cherry is won and the first cherry is won, a game medium is provided. That is, the first cherry winning is a small winning combination.

  Specifically, when the stop symbol of the left reel 32L on the main line ML becomes a "cherry" symbol, the stop symbol of the middle reel 32M and the stop symbol of the right reel 32R are symbols other than the "cherry" symbol ("bell") Even if it is any of a symbol, a "watermelon" symbol, a "replay" symbol, a "red 7" symbol, and a "white 7" symbol), it becomes the first cherry winning prize. The number of objects to be provided with game media when the first cherry winning is achieved is "2" if it is a gaming state other than the BB state. On the other hand, the first cherry winning combination is excluded from the target of establishment in the BB state.

  On the other hand, when the first cherry is won and the first cherry is not won, the game medium is not provided. In this case, the combination of the stop symbol of the left reel 32L, the stop symbol of the middle reel 32M, and the stop symbol of the right reel 32R on the main line ML is a combination of stop symbols aligned only in this case. Therefore, the player can grasp that the first cherry is won and the first cherry is not won by looking at the combination of the stop symbols.

  Here, it is assumed that the number of games set as the number of games continued by the AT state ST3 is the number of continuable games. If the first cherry is won in the state other than the AT state ST3, "30" is set as the number of continuable games. When the first cherry is won in the AT state ST3, "30" is added to the set number of continuable games. In the preparation state ST31 of the AT state ST3, when transitioning to the second RT mode, the base state ST32 (FIG. 47) of the AT state ST3 is established. The number of continuable games is not reduced while in the preparation state ST31, and when it is in the base state ST32, "1" is subtracted each time one game is ended. Details of the AT state ST3 will be described later.

  Next, the second cherry role will be described. In the present embodiment, when the second cherry is won, the preparation state ST31 (FIG. 47) of the AT state ST3 (FIG. 47) advantageous for the player is obtained. In the present embodiment, when the second cherry is won and the second cherry is won, a game medium is provided. That is, the second cherry winning combination is a small winning combination.

  Specifically, the stop symbol of the left reel 32L on the main line ML is a "cherry" symbol, the stop symbol of the middle reel 32M is a "cherry" symbol, and the stop symbol of the right reel 32R is a "cherry" symbol If so, you will win the second Cherry. The target number of game media to be awarded when the second cherry prize is won is "2" if it is a gaming state other than the BB state. On the other hand, the second cherry winning combination is excluded from being established in the BB state.

  On the other hand, when the second cherry is won and the second cherry is not won, the game medium is not provided. In this case, the combination of the stop symbol of the left reel 32L, the stop symbol of the middle reel 32M, and the stop symbol of the right reel 32R on the main line ML is a combination of stop symbols aligned only in this case. Therefore, the player can grasp that the second cherry is won and the second cherry is not won by looking at the combination of the stop symbols.

  If the second cherry is won in the state other than the AT state ST3, "300" is set as the number of continueable games. When the first cherry is won in the AT state ST3, "300" is added to the set number of continuable games. Details of the AT state ST3 will be described later.

  Next, with reference to FIG. 39, the configuration of the main control board 141 of the present embodiment will be described about differences from the main control board 141 (FIG. 6) of the first embodiment. FIG. 39 is a block diagram showing the configuration of the main control board 141 in the present embodiment.

  As shown in FIG. 39, the main MPU 142 includes a control IC 148 and a hard random number circuit 146. First, the configuration of the control IC 148 will be described. The control IC 148 temporarily stores various data and the like when the control program stored in the main ROM 143 stores the various control programs executed by the control IC 148 and fixed value data. And a main side RAM 144 which is a memory for The main RAM 144 in the present embodiment is provided with a startable flag 144a, a signal storage flag 144d, a first start instruction flag 144g, and a second start instruction flag 144h. Further, the main RAM 144 is provided with a random number counter for addition (not shown). In the addition random number counter, the addition random number used for the addition lottery is updated. The addition random number counter of the main side RAM 144 is a loop counter in which “1” is added to the previous value each time the update timing is reached, and it returns to “0” after reaching the maximum value “65535”. The control IC 148 updates the random number for addition in the timer interrupt process (FIG. 8) executed every 1.49 ms. The addition lottery is performed when the watermelon combination is won in the game performed in the base state ST32 of the AT state ST3, and the number of continuable games is added when the watermelon is won in the addition lottery.

  As shown in FIG. 39, the start detection sensor 41a and the control IC 148 are connected by one signal line. A detection signal SG2 is output from the start detection sensor 41a. The detection signal SG2 is a signal in the LOW state when the start lever 41 is not operated, and is in the HI state when the start lever 41 is operated to be pressed.

  The first start instruction flag 144 g is a flag in which “1” is set as one condition that the rising of the detection signal SG <b> 2 input to the control IC 148 is detected. The control IC 148 acquires numerical information of the first random number, which is the first random number, under the condition that "1" is set in the first start instruction flag 144g. The second start command flag 144 h is a flag in which “1” is set as one condition that the falling of the detection signal SG <b> 2 input to the control IC 148 is detected. The control IC 148 acquires numerical value information of a second random number, which is a second random number, triggered by the fact that "1" is set in the second start instruction flag 144h.

  Unlike the main RAM 144 of the first embodiment, the main RAM 144 of the present embodiment does not include the error counter 144b (FIG. 5) and the start command flag 144c (FIG. 5).

  Next, the configuration of the hard random number circuit 146 will be described. As shown in FIG. 39, the hard random number circuit 146 according to the present embodiment includes the update circuit 101 including the random number counter 105, and a latch register in which numerical value information of random numbers stored in the random number counter 105 is temporarily written. And 407, and control circuits 403 and 404 for transmitting latch signals to the latch registers 407 and 408 when the input signal rises to the HI state and the HI state continues for 12.8 μs. Specifically, the hard random number circuit 146 of the present embodiment includes the first latch register 407 and the second latch register 408 as latch registers, and also includes the first management circuit 403 and the second management circuit 404 as management circuits. ing.

  As shown in FIG. 39, one signal line from the start detection sensor 41 a branches at two branch points 171 and 172 on the main control board 141. Specifically, the signal line from the start detection sensor 41 a is branched into two at a first branch point 171 on the main control board 141. One of the signal lines branched at the first branch point 171 is connected to the input terminal TA1 of the control IC 148. Therefore, the detection signal SG2 output from the start detection sensor 41a is input to the input terminal TA1 of the control IC 148.

  Further, the other of the signal lines branched at the first branch point 171 is branched into two at the second branch point 172 on the main control board 141. One of the signal lines branched at the second branch point 172 is connected to the first management circuit 403, and the other of the signal lines branched at the second branch point 172 is disposed on the main control board 141. It is connected to the second management circuit 404 via the inverting circuit 431. Therefore, the detection signal SG2 is input to the first management circuit 403, and the inversion detection signal SG3 generated by inverting the detection signal SG2 is input to the second management circuit 404.

  The first management circuit 403 is a hardware circuit provided with a timer counter which subtracts “1” from the set value in 0.1 μs units. "128" is preset to the timer counter. In the first management circuit 403, when the signal input to the first management circuit 403 rises from the LOW state to the HI state, the timer counter starts counting down. The countdown by the timer counter is continued until the value of the timer counter becomes “0” when the detection signal SG2 inputted to the first management circuit 403 maintains the HI state. Then, when the value of the timer counter becomes “0”, a latch signal is transmitted from the first management circuit 403 to the first latch register 407. In this case, the timer counter is reset and the initial value “128” is set. When the timer counter is reset, the state in which the initial value is set is maintained until the detection signal SG2 input to the first management circuit 403 rises again. In addition, when the detection signal SG2 input to the first management circuit 403 rises from the LOW state to the HI state, the timer counter starts counting down, and the detection signal SG2 is before the value of the timer counter becomes "0". When it falls to the LOW state, the countdown by the timer counter stops. In this case, the timer counter is reset and the initial value is set.

  The second management circuit 404 has the same configuration as the first management circuit 403 described above. The inverted detection signal SG3 is input to the second management circuit 404. Therefore, the inverted detection signal SG3 rises to the HI state, and the second management circuit 404 outputs the latch signal to the second latch register 408 at the timing when the HI state is maintained for 12.8 μs.

  Further, the updating circuit 101 in the present embodiment has the same configuration as the updating circuit 101 in the first embodiment. Specifically, the update circuit 101 includes a clock circuit 104 and a random number counter 105. The clock circuit 104 outputs a 16 MHz clock signal. The numerical value information of the random number stored in the random number counter 105 is updated at the timing when the clock signal rises. The random number counter 105 is composed of 16 random number counter D-FFs 105a to 105p (FIG. 6), and has a 2-byte storage area. The random number stored in the random number counter 105 is a 16-digit binary number.

  Further, each of the first latch register 407 and the second latch register 408 has the same configuration as the latch register 102 in the first embodiment. Specifically, each of the first latch register 407 and the second latch register 408 is configured of 16 D-FFs, and includes a 2-byte storage area. The D-FFs constituting the first latch register 407 are referred to as first latch D-FFs 407a to 407p, and the D-FFs constituting the second latch register 408 are referred to as second latch D-FFs 408a to 408p. I assume. A 16-digit binary number is stored in each of the first latch register 407 and the second latch register 408.

  One signal line coming out of the Q terminal of the random number counter D-FF 105a to 105p is branched into two on the way, and one signal line after branching is the D terminal of the first latch register D-FF 407a to 407p. And the other signal line after branching is connected to the D terminals of second latch register D-FFs 408a to 408p. More specifically, one signal line from the Q terminal of the D-FF for random number counter 105a-105p which stores the numerical value information of the nth digit in the random number counter 105 passes the numerical information of the nth digit in the first latch register 407. Connected to the D terminals of the first latch D-FFs 407a to 407p to be stored and the D terminals of the second latches D-FFs 408a to 408p to store the numerical information of the n-th digit in the second latch register 408 . Here, n is a natural number of 1 to 16.

  The CLK terminals of the first latch D-FFs 407 a to 407 p are connected to the first management circuit 403, and the CLK terminals of the second latches D-FFs 408 a to 408 p are connected to the second management circuit 404. Specifically, one signal line from the first management circuit 403 is branched into 16 and connected to the CLK terminals of the first latch D-FFs 407 a to 407 p, and 1 from the second management circuit 404. This signal line is branched into 16 lines and connected to the CLK terminals of the second latch D-FFs 408a to 408p. Further, as shown in FIG. 39, the Q terminals of the first latch D-FFs 407a to 407p are connected to the input terminal TA8 of the control IC 148, and the Q terminals of the second latches D-FFs 408a to 408p are control IC 148. Input terminal TA9.

  Therefore, the latch signal is transmitted from the first management circuit 403 to the CLK terminals of the first latch D-FFs 407a to 407p, whereby the numerical information of the random number stored in the random number counter 105 is the first latch register. While being written to 407, it is outputted to the input terminal TA8 of the control IC 148. Further, the latch signal is transmitted from the second management circuit 404 to the CLK terminals of the second latch D-FFs 408 a to 408 p, whereby the numerical information of the random number stored in the random number counter 105 is the second latch register 408. And is output to the input terminal TA9 of the control IC 148.

  The relationship between the state of the detection signal SG2 output from the start detection sensor 41a and the timing when the latch signal is output from the first management circuit 403 and the second management circuit 404 will be described with reference to the time chart of FIG. . 40 (a) shows the state of the start lever 41, FIG. 40 (b) shows the state of the detection signal SG2 input to the first management circuit 403, and FIG. 40 (c) shows the state in the first management circuit 403. FIG. 40 (d) shows the timing at which the first management circuit 403 transmits a latch signal to the first latch register 407. FIG. 40 (e) is inputted to the second management circuit 404. FIG. 40 (f) shows the state of the timer counter in the second management circuit 404. FIG. 40 (g) shows the second management circuit 404 transmitting a latch signal to the second latch register 408. Show the timing of

  When the start lever 41 is depressed at timing t1 as shown in FIG. 40A, as shown in FIG. 40B, the detection signal SG2 input to the first management circuit 403 is in the LOW state. Stand up to HI state from Then, as shown in FIG. 40C, at the timing of the time t1, the counting of the time by the timer counter in the first management circuit 403 is started. In the timer counter, “1” is subtracted from the initial value “128” every 0.1 μs. Further, as shown in FIG. 40E, the inverted detection signal SG3 input to the second management circuit 404 at timing t1 falls from the HI state to the LOW state.

  As shown in FIG. 40B, the HI state of the detection signal SG2 input to the first management circuit 403 is continued from the timing of t1 to the timing of t3. Here, the timing t3 is a timing after the timing t2 when 12.8 μs has elapsed from the timing t1. Therefore, as shown in FIG. 40C, counting of time by the timer counter in the first management circuit 403 is continued from the timing of t1, and the first management is performed at the timing of t2 when 12.8 μs has elapsed from the timing of t1. The value of the timer counter in the circuit 403 becomes "0". At timing t2 when the value of the first management circuit 403 becomes “0”, the first management circuit 403 transmits a latch signal to the first latch register 407 as shown in FIG. 40 (d). Thereby, the numerical value information of the random number stored in the random number counter 105 at the timing of t2 is written to the first latch register 407 as the numerical value information of the first random number.

  When the pressing operation of the start lever 41 is finished at the timing of t3 as shown in FIG. 40A, as shown in FIG. 40B, the detection signal SG2 inputted to the first management circuit 403 is in the HI state. Fall to LOW from. Then, as shown in FIG. 40E, the inversion detection signal SG3 input to the second management circuit 404 rises from the LOW state to the HI state at the timing of t3. As a result, as shown in FIG. 40F, counting of time by the timer counter in the second management circuit 404 is started.

  As shown in FIG. 40 (e), the HI state of the inverted detection signal SG3 input to the second management circuit 404 is continued at the timing of t4. Here, the timing of t4 is a timing when 12.8 μs has elapsed from the timing of t3. Therefore, as shown in FIG. 40 (f), the counting of the time by the timer counter in the second management circuit 404 is continued from the timing of t3, and the second management is performed at the timing of t4 when 12.8 μs has elapsed from the timing of t3. The value of the timer counter in the circuit 404 becomes "0". The second management circuit 404 transmits a latch signal to the second latch register 408 at time t4 when the value of the second management circuit 404 becomes "0". Thereby, the numerical value information of the random number stored in the random number counter 105 at the timing of t4 is written to the second latch register 408 as the numerical value information of the second random number.

  When the player depresses the start lever 41 once, the detection signal SG2 outputted from the start detection sensor 41a rises from the LOW state to the HI state, and after the HI state is maintained for 12.8 μs or more, it returns to the LOW state. The operations of t1 to t4 are performed. By the operations of t1 to t4, the first random number is written to the first latch register 407, and the second random number is written to the second latch register 408.

  As described above, numerical value information of the first random number is numerical value information of the random number to be written to the first latch register 407 under the condition that the detection signal SG2 input to the first management circuit 403 rises. In other words, the first random number is a random number corresponding to the timing when the pressing operation of the start lever 41 by the player is started. On the other hand, numerical value information of the second random number is numerical value information of the random number written to the second latch register 408 under the condition that the inversion detection signal SG3 inputted to the second management circuit 404 rises. In other words, the second random number is a random number corresponding to the timing when the pressing operation of the start lever 41 by the player is finished.

  The control IC 148 acquires numerical information of the first random number input to the input terminal of the control IC 148 at the rising timing of the detection signal SG2 input to the control IC 148, and detects the input to the control IC 148 The numerical information of the second random number input to the input terminal of the control IC 148 is acquired at the falling timing of the signal SG2. Thus, while the player operates the start lever 41 once, the control IC 148 can acquire two different random numbers.

  Since the pressing operation of the start lever 41 by the player is a human action, the time during which the state where the start lever 41 is pressed continues is different every time. For this reason, in addition to the drawing using the numerical information of the first random number, the control IC 148 can perform the drawing using the numerical information of the second random number, which is a random number asynchronous to the first random number, in addition to the drawing using the numerical information of the first random number .

  Next, the start command setting process of the present embodiment will be described with reference to FIG. The start command setting process is a process executed in step S206 of the timer interrupt process (FIG. 8).

  First, in step S1601, it is determined whether or not it is a game startable period by determining whether or not “1” is set in the start possibility flag 144a. If it is a game startable period (step S1601: YES), it is determined in step S1602 whether "1" is set in the signal storage flag 144d. If "1" is not set in the signal storage flag 144d in step S1602, it is determined in step S1603 whether or not the detection signal SG2 input to the control IC 148 is in the HI state.

  The detection signal SG2 in the LOW state in step S1603 means that the rising of the detection signal SG2 in the LOW state in the previous start command setting process is not detected. In this case, since the signal storage flag 144d is already "0", the present start instruction setting process is ended as it is.

  The fact that the detection signal SG2 is in the HI state in step S1603 means that the rising of the detection signal SG2 that was in the LOW state in the previous start command setting process is detected, and the condition under which the control IC 148 acquires numerical information of the first random number is It means being in order. In this case, “1” is set in the signal storage flag 144 d in step S1604, “1” is set in the first start instruction flag 144 g in step S1605, and this start instruction setting process is ended.

  If "1" is set in the signal storage flag 144d in step S1602, it is determined in step S1606 whether or not the detection signal SG2 input to the control IC 148 is in the LOW state. The fact that the detection signal SG2 is in the HI state in step S1606 means that the fall of the detection signal SG2 that has been in the HI state in the previous start command setting processing has not been detected. Since "1" is already set in the signal storage flag 144d, the present start instruction setting process is ended as it is.

  That the detection signal SG2 is in the LOW state in step S1606 means that the fall of the detection signal SG2 in the HI state in the previous start command setting process is detected, and the control IC 148 acquires numerical information of the second random number. It means that you are ready. In this case, in step S1607, the signal storage flag 144d is cleared to "0", and in step S1608, the second start instruction flag 144h is set to "1", and the present start instruction setting process is ended.

  The fact that the start enable flag 144a is not set to "1" in step S1601 means that the game can not be started. In this case, only the process of updating the numerical information set in the signal storage flag 144d is executed according to the state of the detection signal SG2 input to the control IC 148, and the present start instruction setting process is ended. In the main start command setting process executed by the control IC 148, “1” is not set in the first start command flag 144g and the second start command flag 144h by the operation of the start lever 41 performed in a state where the game can not be started It is a structure. Therefore, the operation of the start lever 41 performed in the state where the game can not be started can be invalidated.

  Specifically, when the detection signal SG2 input to the control IC 148 is in the LOW state in step S1609, the signal storage flag 144d is cleared to "0" in step S1610, and this start instruction setting process is performed. finish. If the detection signal SG2 input to the control IC 148 is in the HI state in step S1609, the signal storage flag 144d is set to "1" in step S1611, and this start instruction setting process is ended. .

  Thus, when the rising of the detection signal SG2 is detected in the control IC 148, the first start instruction flag 144g is set to "1", and when the falling of the detection signal SG2 is detected in the control IC 148, the second The start command flag 144h is set to "1". The start command setting process is a process that is executed in a cycle of approximately 1.49 ms. On the other hand, since the pressing operation of the start lever 41 by the player is a human action, it is considered that the time from the start of the pressing operation of the start lever 41 to the end is longer than 1.49 ms. .

  When the pressing operation of the start lever 41 is 1.49 ms or more, the rising of the detection signal SG2 is detected in the first start command setting process after the pressing operation is started, and the start command setting after the next time In the process, the falling of the detection signal SG2 is detected. Thereby, the control IC 148 can acquire numerical information of two unsynchronized random numbers by one pressing operation of the start lever 41.

  In addition, after the start command setting process is performed, short noise in which both the rising and the falling of the detection signal SG2 input to the control IC 148 occur in a short time until the next start command setting process is performed. Even if the second signal is mixed, "1" is never set to the first start command flag 144g and the second start command flag 144h triggered by the noise.

  In detail, in the start command setting process executed immediately before the noise is mixed, the detection signal SG2 input to the input terminal TA1 of the control IC 148 is in the LOW state, and thus the signal storage flag 144d in the start command setting process. Is "0". Further, in the start command setting process executed immediately after the noise is mixed in, since the detection signal SG2 input to the input terminal TA1 of the control IC 148 is returned to the LOW state, the signal storage flag 144d is set in the start command setting process. Remains unchanged at "0".

  In the start command setting process before and after noise mixes, the value of the signal storage flag 144d does not change, so “1” is set in the first start command flag 144g and the second start command flag 144h due to the mixing of the noise. There is no.

  Next, normal processing executed by the control IC 148 will be described with reference to the flowchart of FIG.

  In steps S1701 to S1703, the same processes as steps S401 to S403 in the first embodiment are performed. Specifically, an interrupt permitting process for permitting the next timer interrupt is performed in step S1701, and a start waiting process is performed in step S1702.

  Here, when the medal return process is executed in the start waiting process of the present embodiment, the control IC 148 can start the flag 144a (FIG. 39) at the start timing of the medal return process, and the first start command flag 144g. (FIG. 39) and the second start command flag 144h (FIG. 39) are cleared to “0”. By clearing the start possibility flag 144a to "0" at the start timing of the medal return process, the game startable period ends. This makes it possible to prevent the state where the start command flag 144c can be set to “1” in the start command setting process (FIG. 41) despite the fact that the medal has been returned. Also, by clearing the first start command flag 144g and the second start command flag 144h to “0” at the start timing of the medal return process, the timing when the bet number of medals reaches the specified number again after the medals are returned. In this case, it is possible to avoid the situation where the game is started before the operation of the start lever 41 is performed.

  Returning to the description of the normal processing (FIG. 42), after the start waiting processing is executed in step S1702, it is determined in step S1703 whether the number of bet on medals has reached a specified number. If the bet number of medals has not reached the specified number (step S1703: NO), the process returns to the start waiting process of step S1702.

  If the bet number has reached the specified number (step S1703: YES), the game is ready to start, so whether or not "1" is set in the start enable flag 144a in step S1704. To determine If "1" is not set in the start enable flag 144a (step S1704: NO), "1" is set in the start enable flag 144a in step S1705. After making a negative determination in step S1704 or after setting the start enable flag 144a to "1" in step S1705, in step S1706, whether or not "1" is set to the first start instruction flag 144g To determine If "1" is not set in the first start instruction flag 144g (step S1706: NO), the process returns to the start waiting process of step S1702. If “1” is set in the first start command flag 144g (step S1706: YES), this means that the rising of the detection signal SG2 input to the control IC 148 has been detected, so the process proceeds to step S1707. Then, numerical value information of the first random number input to the input terminal TA8 of the control IC 148 is acquired. The control IC 148 uses the first random number for determining whether or not the winning combination has been made.

  After that, in steps S1708 to S1711, processing is executed that is necessary regardless of the value of the first random number acquired in the previous step S1707. Specifically, in step S1708, the first start instruction flag 144g is cleared to "0", and in step S1709, the medal inserted by performing the acceptance prohibition process is discharged to the medal receiver 59. Then, in step S1710, the first reel control process is executed.

  In the first reel control process, the rotation start process, which is initially executed in the reel control process (step S412) in the normal process (FIG. 10) of the first embodiment described above, is executed. In the rotation start process, a predetermined wait time (for example, 4.1 seconds) starts from the time when the rotation of the reels 32L, 32M, 32R corresponding to the result of the lottery process (FIG. 43) in the previous game is started. It checks whether or not it has elapsed, and if it has not, it waits until the wait time has elapsed. The details of the lottery process of the role will be described later.

  If the wait time has elapsed, the wait time for the next game is reset, and rotation start information is set in the motor control storage area provided in the main RAM 144. By performing such processing, acceleration processing of the stepping motor is started in the stepping motor control processing of step S207 in the timer interrupt processing (FIG. 8), and the respective reels 32L, 32M, 32R start rotation.

  Returning to the description of the normal processing (FIG. 42) in the present embodiment, after the first reel control processing is executed in step S1710, the standby period is set in step S1711. Here, the start timing of the standby period is the timing at which the rotation of each reel 32L, 32M, 32R is started in the first reel control process (step S1710), and the end timing of the standby period is each reel 32L, 32M. , 32R after a predetermined time has elapsed, and is later than the timing at which each reel 32L, 32M, 32R starts constant speed rotation. The standby period is the time from when the first reel control process is executed in step S1711 to when each reel rotates at a constant speed. The specific length of the waiting period is determined by experiments in the design stage.

  In the following step S1712, an addition random number used for addition lottery is acquired from the addition random number counter (not shown) in the main side RAM 144, and in step S1713, the process waits until the second start instruction flag 144h is set to "1". . As described above, after the setting of the waiting period, the random number for addition is acquired before the addition random number is acquired until the second start command flag 144 h is set to “1”. The processing load of the control IC 148 can be distributed as compared with the configuration for acquiring.

  If "1" is set to the second start command flag 144h in step S1713, it means that the falling of the detection signal SG2 input to the control IC 148 is detected. The timing at which the detection signal SG2 input to the control IC 148 falls is the timing at which the inversion detection signal SG3 input to the second management circuit 404 rises. The numerical value information of the random number stored in the random number counter 105 is written in the second latch register 408 under the condition that the rising of the inversion detection signal SG3 is detected.

  In this case, the control IC 148 clears the start possibility flag 144a to "0" in step S1714. As a result, the current game is over, and the first start command flag 144g and the second start command flag are set in the start command setting process (FIG. 41) until the start enable flag 144a is set to "1" again in step S1705. It will be in the state where "1" is not set to 144h. Thereafter, at step S1715, numerical value information of the second random number inputted to the input terminal TA9 of the control IC 148 is acquired, and at step S1716 the second start instruction flag 144h is cleared to "0".

  In the following step S1717, a lottery process of winning combinations in the current game is executed. Then, in step S1718, it is determined whether or not the standby period set in step S1712 is ended, and the standby period is ended and standby is performed until the rotational speeds of the respective reels 32L, 32M, 32R become constant. Then, if the standby period has ended (step S1718: YES), the second reel control process is executed in step S1719.

  Here, the second reel control process executed in step S1719 will be described. First, the control IC 148 notifies the player or the like that it is possible to generate a stop command by lighting on the not-shown lamps of the stop buttons 42 to 44. After that, when the stop button 42 to 44 corresponding to the rotating reel is operated, the control IC 148 sets the stop command command to stop the reel control process for stopping the rotating reel, all reels 32L, Do this until 32M and 32R stop.

  In the stop control process, when a stop command is generated, that is, when the stop button corresponding to the reel being rotated is operated, which stop button 42 to 44 is operated to generate a stop command on the sub side A stop command for causing the MPU 152 to recognize is set, and stop control processing is performed to stop the rotating reel.

  In the stop control process, the symbol number of the reaching symbol reaching the base position (the lower end in the present embodiment) is confirmed at the timing when the stop buttons 42 to 44 are operated. Specifically, the symbol number of the arrival symbol reaching the base position is confirmed by the excitation pulse number output from the time when the detection signal of the reel index sensor is input. Thereafter, based on the stop information stored in the main side RAM 144, the number of slips of the reel to be stopped this time is calculated.

  In the slot machine 10, as a stop mode for stopping the reels 32L, 32M, 32R, the stop mode for stopping the arrival symbol reaching the base position as it is when the stop buttons 42 to 44 are operated To stop after sliding 1 reel of reels, stop after stopping by sliding 2 reels, stopping after sliding 3 stops, and stopping after sliding 4 reels Five patterns of stopping modes are prepared, including stopping modes. The control IC 148 calculates one of “0” to “4” as the slip number based on the stop information stored in the main RAM 144.

  Thereafter, the calculated slip number is added to the symbol number of the arrival symbol, and the symbol number of the stop symbol to be actually stopped at the base position is determined. Then, it is determined whether or not the symbol number of the arrival symbol of the reel to be stopped this time and the symbol number of the stop symbol are equal, and when equal, the reel stop processing is performed to stop the rotation of the reel. Thereafter, it is determined whether all the reels 32L, 32M, 32R have stopped.

  When all the reels 32L, 32M, 32R are not stopped, the winning data being set, the stopping order of the reels 32L, 32M, 32R, and the stopping points of the stopped reels 32L, 32M, 32R and , And the process of changing the stop information is performed, and the process returns to the process of determining again whether the stop button 42 to 44 is operated.

  Here, the stop information is information for making the stop mode of each reel 32L, 32M, 32R correspond to the result of the lottery process (FIG. 43) of the winning combination, and by using the stop information When the stop buttons 42 to 44 are operated to stop, it is possible to calculate the slip number (specifically, "0" to "4") for the arrival symbol reaching the base position. As the stop information, slip number data indicating the correspondence between each symbol and the slip number is stored in advance in the main side ROM 143 in association with each lottery result and the stop order of each reel 32L, 32M, 32R. However, the present invention is not limited to this, and the configuration may be such that slip number data corresponding to each lottery result and the stop order of each reel 32L, 32M, 32R may be derived during rotation of the reels 32L, 32M, 32R, etc. .

  Thereafter, when it is determined that all the reels 32L, 32M, 32R are stopped, the control IC 148 executes a winning determination process. In the prize determination process, the number of medals to be paid out is set in the main RAM 144 if the small winning combination is achieved, and if it is the replay winning, the step S402 in the next start waiting process (normal process (FIG. 10)). In the processing), the winning combination processing for executing the flag setting processing for executing the automatic insertion processing is executed, and the winning result command is set as the output target to the sub MPU 152.

  Returning to the description of the normal processing (FIG. 42), after executing the second reel control processing in step S1719, in the case where a minor winning combination has been established in the current game in step S1720, A medium giving process for giving the player a number of game media is executed, and in step S1721, a game ending process is executed to enable setting of the gaming state corresponding to the result of the current game. . Details of the response processing at the end of the game in the present embodiment will be described later. In the following step S1722, external output setting processing for outputting the state of the slot machine 10 to the management computer of the gaming hall is executed, and in step S1723, the acceptance permission processing is executed, and the processing returns to the interrupt permission processing in step S1701. .

  Next, the lottery process executed in step S1717 of the normal process (FIG. 42) will be described with reference to the flowchart of FIG.

  First, in step S 1801, a lottery table for performing a pass / fail determination of the winning combination is read out from the main ROM 143. Specifically, the lottery table corresponding to the combination of the current setting value and the current gaming state is selected.

  The lottery table corresponding to the normal mode will be described by taking the case of “setting 3” and being in the non-BB state as an example. FIG. 44 is an explanatory view for explaining the normal mode lottery table. In the following description, the explanatory view of FIG. 45 is referred to as appropriate. The description of the same contents as those of the normal mode lottery table (FIG. 12) in the first embodiment is basically omitted.

  As shown in FIG. 44, index values IV are set in the normal mode lottery table, and the first point value PV1 is set to each index value IV in association with the winning combination. There is. The first point value PV1 defines the winning probability of the corresponding lottery combination in relation to the maximum value (“65535”) of the first random number.

  In addition to the first point value PV1, a second point value PV2 is set to the index value IV = 5. The second point value PV2 is used to determine whether or not the second cherry combination is won if the first cherry combination is won. The win for the second cherry role takes precedence over the win for the first cherry role. Specifically, when the second cherry combination is won, the first cherry combination is canceled and the second cherry combination is won. If the second cherry role is not won, the winning state of the first cherry role is maintained.

  In the case of winning with the index value IV = 5, and when the first cherry combination is won, as shown in FIG. 45, regardless of the stop order of the reels 32L, 32M, 32R, the first Cherry winning is possible. However, depending on the operation timing of the left stop button 42 with respect to the rotational position of the left reel 32L, the first cherry winning may not be established.

  Further, in the case where the index value IV = 5 is won and the second cherry role is won, as shown in FIG. 45, regardless of the stop order of the reels 32L, 32M, 32R. The second Cherry Prize can be won. However, depending on the operation timing of the stop buttons 42 to 44, there is a possibility that the second cherry winning is not established.

  Here, the first cherry winning data and the second cherry winning data are erased in the winning game regardless of whether or not the winning is achieved, and they are not carried over to the next and subsequent games of the winning game. .

  When the normal mode lottery table of FIG. 44 is selected, the probability of being won when the index value IV = 5 is about 1/423. When the index value IV = 5 is won, a judgment on the second cherry combination is made. In this determination, the probability of winning the second cherry combination is approximately 1/262. Therefore, when the normal mode lottery table of FIG. 44 is selected, the probability of winning the first cherry combination is about 1/424 and the probability of winning the second cherry combination is about 1/110 834.

  In the case of “setting 3” and in the non-BB state, also in the first RT mode lottery table selected in the first RT state and the second RT mode lottery table selected in the second RT state, The probability of winning the first cherry role and the probability of winning the second cherry role do not change.

  Returning to the description of the lottery process (FIG. 43), after the lottery table is selected in step S1801, in step S1802, the index value IV is set to "1", and the first used in step S1803 to determine the success or failure of the winning combination. The determination value DV1 is set. In this determination value setting process, a new first determination value DV1 is set by adding a first point value PV1 corresponding to the current index value IV to the current first determination value DV1. In the first determination value setting process, the first random number acquired in the process of step S1707 of the normal process (FIG. 42) is set as the current first determination value DV1, and the random number value is the current index value IV. A first point value PV1 corresponding to “1” is added to obtain a new first determination value DV1.

  In the following step S1804, it is determined whether or not the combination corresponding to the index value IV is accepted. It is determined whether or not the first determination value DV1 exceeds “65535” in the determination of the winning combination of the winning combination. If the first determination value DV1 does not exceed “65535” (step S1804: NO), it means that the player has fallen out of the role corresponding to the index value IV. In such a case, 1 is added to the index value IV in step S1805, and it is determined in step S1806 whether or not there is a combination corresponding to the index value IV, that is, whether or not there is a determination target to be determined. . Specifically, it is determined whether the index value IV to which "1" is added exceeds the maximum value of the index values IV set in the lottery table.

  If there is a determination target to be determined whether the determination is yes or no (step S1806: YES), the process returns to step S1803 to continue the determination of the combination. At this time, in step S1803, a first point value PV1 corresponding to the current index value IV is added to the first determination value DV1 (that is, the current first determination value DV1) used for the determination of the previous winning combination. The first determination value DV1 is set, and in step S1804, a winning / non-presence determination of a winning combination is performed based on the first determination value DV1.

  If the first determination value DV1 exceeds “65535” in step S1804 (step S1804: YES), it is determined in step S1807 whether or not the first cherry is won. If it is determined that the first cherry has been won (step S1807: YES), it is determined whether or not the second cherry has been won. In the determination of the second cherry combination, the second random number acquired in step S1715 of the normal process (FIG. 42) is used as the second determination value DV2. Specifically, in step S1808, the second point value PV2 is added to the second random number which is the second determination value DV2 to obtain a new second determination value DV2. For example, when the normal mode lottery table (FIG. 44) in the non-BB state and “setting 3” is selected, the second point value PV2 is 250. In the following step S1809, it is determined whether or not the new second determination value DV2 calculated in step S1808 exceeds "65535".

  After making a negative determination in step S1807 or step S1809, in step S1810, a first winning data acquisition process for setting data of the winning combination in the main RAM 144 is executed. In the first winning data acquisition process, all the winning data set for the current index value IV in the lottery table to be referred to is set in the main RAM 144. Here, in the case of the index value IV = 5 in the first winning data acquisition process, the first cherry winning data is set. If the winning data is set, if the winning data is a winning data other than the BB winning data, "0" is cleared after the end of the current game regardless of the presence or absence of winnings corresponding to the winning data, and BB won If it is data, it is cleared to "0" when a winning is achieved.

  If the second determination value DV2 exceeds “65535” in step S1809, it means that the second cherry combination has been won. Therefore, in step S1811, the second winning data acquisition process is executed. In the second winning data acquisition process, second cherry winning data is set. The state in which the second cherry winning data is set is cleared to “0” after the end of the current game regardless of whether or not the second cherry winning is achieved.

  After making a negative determination in step S1806, after executing the first winning data acquisition processing in step S1810, or after executing the second winning data acquisition processing in step S1811, in step S1812, the reel stop control is performed. The first stop information setting process for setting the stop information is executed, and a game start command is set as a transmission target to the sub MPU 152 in step S1813. The game start command is a command for causing the sub MPU 152 to recognize that a new game has been started, and is a command for causing the sub MPU 152 to recognize the result of the lottery process of the present combination in the control IC 148. is there. The game start command is transmitted to the sub MPU 152 in the command output process (the process of step S212) in the timer interrupt process (FIG. 8).

  Next, the processing at the end of the game, which is executed in step S1721 of the normal processing (FIG. 42), will be described with reference to the flowchart of FIG. Incidentally, the response processing at the end of the game is executed when the rotation of all the reels 32L, 32M, 32R is stopped in each game.

  First, in step S1901, it is determined whether or not a winning corresponding to the winning combination has been established in the situation where the first or second BB combination has been won, and the corresponding winning is established (step In S1901: YES), a winning result command is transmitted to the sub MPU 152 in step S1902. In the following step S1903, processing for BB start is executed. In the BB start process, if the first BB winning is achieved, the first BB flag provided in the main RAM 144 is set to "1", and the end reference number counter provided in the main RAM 144 is in the first BB state. Set "41" which is the end reference number. Also, if the second BB winning is achieved, the second BB flag provided in the main RAM 144 is set to "1", and the end reference number counter provided in the main RAM 144 is the end reference number for the second BB state. Set "89".

  If a negative determination is made in step S1901, it is determined in step S1904 whether it is in the BB state or not, and if it is in the BB state (step S1904: YES), the processing for BB is performed in step S1905. Is executed, and the correspondence processing at the end of the game is ended. In the process for BB, when the addition of game media occurs in the current game, the value of the end reference number counter of the main side RAM 144 is subtracted correspondingly, and the value of the end reference number counter after subtraction is If it is "0", processing is executed to end the BB state. When the BB state ends, the lottery mode is the normal mode even if the lottery mode before the start of the BB state is any mode. When the BB state is started in the AT state ST3, the state returns to the AT state ST3 in the normal mode after the BB state ends regardless of the state before the start of the BB state.

  If it is in the non-BB state and BB winning is not established (step S1901 and step S1904: NO), AT state management processing (FIG. 48) described later is executed in step S1906. In the AT state management process, when the first cherry winning or the second cherry winning is established in the non-AT state, the process shifts to the AT state ST3. In addition, in the AT state ST3, when the first cherry winning or the second cherry winning is established, the number of continuable games is added.

  In the following step S1907, it is determined whether or not the promotion condition is established, and if the promotion condition is established (step S1907: YES), the process of changing the lottery table at the time of promotion is executed in step S1908. Do. Here, the change process of the lottery table at the time of promotion is the same process as the process of step S606 of the process (FIG. 18) at the time of game end in the first embodiment.

  In the subsequent step S1909, it is determined whether or not the promotion established this time is promotion from the first RT mode to the second RT mode, and in the case where it is not promotion from the first RT mode to the second RT mode (step S1909: NO). , The processing at the end of the game is ended. If the current promotion is promotion from the first RT mode to the second RT mode (step S1909: YES), it is determined in step S1910 whether "1" is set in the preparation state flag. Here, the preparation state flag is a flag set in the main RAM 144, and when the preparation state ST31 of the AT state ST3 is reached, "1" is set, and in the preparation state ST31 of the AT state ST3. It is a flag that is cleared to "0" when there is no more.

  If the preparation state flag is not set to "1" in step S1910, this means that the slot machine 10 is not in the preparation state ST31 of the AT state ST3, so the processing for dealing with the end of the game is ended. Do. When the preparation state flag is set to "1" in step S1910, this means that the slot machine 10 is in the preparation state ST31 of the AT state ST3. In this case, since the condition for transitioning from the preparation state ST31 of the AT state ST3 to the base state ST32 is satisfied by promotion this time, the preparation state flag is cleared to "0" in step S1911, and the base state command is selected in step S1912. Is set as a transmission target to the sub MPU 152, and the processing at the end of the game is ended. The sub MPU 152 can execute an effect for notifying the player that the base state ST32 of the AT state ST3 is started by receiving the base state command.

  If a negative determination is made in step S1907, it is determined in step S1913 whether a fall condition is satisfied, and if the fall condition is not satisfied (step S1913: NO), The corresponding processing at the end of the game is ended. Further, if the fall condition is satisfied (step S1913: YES), in step S1914, the change process of the lottery table at the fall time is executed, and the correspondence process at the end of the game is ended. Here, the change process of the lottery table at the time of fall is the same process as the process at step S608 of the process (FIG. 18) at the time of game end in the first embodiment.

  The first RT mode is promoted to the second RT mode (step S1909: YES), and when the preparation state flag is set to "1" (step S1910: YES), the base state ST32 of the AT state ST3 is set. . In the base state ST32, the number of continuable games is decremented by one for each game. In the base state ST32, if the fall condition is satisfied (step S1913: YES), the process returns to the first RT mode. However, the preparation status flag remains "0". For this reason, once the base state ST32 of the AT state ST3 is reached, the number of continuable games is decremented by one for each game even if the first RT mode is dropped.

<Mode of transition of gaming state>
Next, the transition mode of the gaming state will be described with reference to the explanatory view of FIG. In the slot machine 10, a normal gaming state ST1, a BB state ST2, and an AT state ST3 are set.

  When the main RAM 144 and the sub RAM 154 are initialized, the normal game state ST1 is entered. Also, under conditions other than BB state ST2 and AT state ST3, the supply of operating power to main MPU 142 and sub MPU 152 is stopped, and thereafter the supply of operating power to main MPU 142 and sub MPU 152 is started. Also in the case where it is determined, the normal gaming state ST1 is obtained. When the BB state ST2 (the first BB state ST21 or the second BB state ST22) ends, the transition condition to the AT state ST3 is not satisfied, and the termination condition different from the transition to the BB state ST2 is satisfied. Even when the AT state ST3 ends, the normal gaming state ST1 is obtained.

  The normal gaming state ST1 is a state in which there is neither BB state ST2 nor AT state ST3. In the normal gaming state ST1, the user can stay in any of the normal mode, the first RT mode, and the second RT mode.

  When the first BB winning or the second BB winning is established in the normal gaming state ST1 or the AT state ST3, the BB state ST2 is attained. In this case, the first BB state ST21 is obtained when the first BB prize is reached, and the second BB state ST22 is attained when the second BB prize is obtained. As already described, the termination reference number in the first BB state ST21 is "41", and the termination reference number in the second BB state ST22 is "89". In this case, only the bell and watermelon roles are set as medium grant roles, and the reel 32L, 32M, 32R stop order and stop operation timing when the bell or watermelon roles are won in the BB state ST2 The winning combination corresponding to the medium granting combination won is established regardless of. Further, in the BB state ST2, the number of game media to be provided is "8" regardless of whether a bell prize is established or a watermelon prize is established. Therefore, in the first BB state ST21, a game winning the medium providing role is generated six times, and in the second BB state ST22, a game winning the medium providing role is generated twelve times.

  Here, a state transition mode after the end of the last game in the BB state ST2 will be described. In the case where the game is changed from the normal gaming state ST1 to the BB state ST2, when a bell prize is won in the final game of the BB state ST2, the transition lottery L1 is not performed, and the preparation state ST31 of the AT state ST3 is entered.

  On the other hand, in the case where the normal game state ST1 is changed to the BB state ST2, when the watermelon is won in the final game of the BB state ST2, a transition lottery L1 is performed. Then, when it is won in the transition lottery L1, it becomes the preparation state ST31 of the AT state ST3. In addition, when it does not win in the transition lottery L1, it becomes normal game state ST1.

  In addition, when the last game of the BB state ST2 ends in the case of changing from the AT state ST3 to the BB state ST2, the transition lottery L1 is not performed, and the preparation state ST31 of the AT state ST3 is entered as it is.

  Here, the AT state ST3 will be described. In the AT state ST3, in the second RT mode, the notification of the stop order of the reels 32L, 32M, 32R enabling the establishment of the bell winning when the index value IV = 1 to 3 is won is the reel 32L. , 32M, 32R is a game state started before the rotation is started. In this case, if the stop order of the reels 32L, 32M, 32R enabling the formation of the bell winning is notified, the probability that the bell winning is established in each game is about 1 / 1.7. Then, when the bell winning is established, "9" game media, which is larger than "3" which is the number of game media required to start one game, is provided. On the other hand, if the stop order of the reels 32L, 32M, 32R enabling the formation of the bell winning is not notified, the probability of the bell winning being established in each game is about 1 / 5.1. Then, when the reels 32L, 32M, 32R are not stopped in the stop order corresponding to the establishment of the bell winning when the index value IV = 1 to 3 is won, the compensating winning is established. The 1 'game media is awarded. The number of provided game media is smaller than the number of game media required to start one game. With the above configuration, the AT state ST3 can be brought into an advantageous gaming state.

  In addition, in the AT state ST3, the reels 32L, 32M, 32R are stopped to enable the establishment of the winning combination corresponding to the winning combination among the first RT replay winning and the second RT replay winning when winning the combination for promoting the lottery mode. The notification of the order is started before the rotation of the reels 32L, 32M, 32R is started, and when winning the role of causing the lottery mode to fall, it corresponds to the winning combination among the first falling replay and the second falling replay. In the gaming state, the notification of the stop order of the reels 32L, 32M, 32R which makes it possible to avoid the establishment of winnings is started before the rotation of the reels 32L, 32M, 32R is started. In the AT state ST3, any one of the normal mode, the first RT mode and the second RT mode can be maintained.

  In this case, the state of staying in the first RT mode or the second RT mode in the AT state ST3 is the ART state. In the ART state, the probability of establishing a replay winning is increased, and the expected number of game media to be granted in one game is increased as described above. Therefore, it becomes possible to make an ART state into an advantageous gaming state.

  When the first cherries win is established from the normal gaming state ST1 and the transition to the preparation state ST31 of the AT state ST3 and when the transition from the BB state ST2 to the preparation state ST31 of the AT state ST3 takes place, "30" is set. Further, when the second cherry winning is established from the normal gaming state ST1 to shift to the preparation state ST31 of the AT state ST3, "300" is set as the number of continuable games. In the preparation state ST31 of the AT state ST3, the number of continuable games is not reduced. When the first RT mode is changed to the second RT mode in the preparation state ST31 of the AT state ST3, the slot machine 10 is in the ART state. Then, in the case of the ART state, the number of continuable games is decremented by one each time one game is over. Then, when the number of continueable games becomes “0”, the slot machine 10 returns to the normal gaming state ST1.

  If the first cherry winning is established before the number of continuable games becomes “0” in the AT state ST3, “30” is added to the continuable game number. Further, if the second cherry winning is achieved before the number of continuable games becomes “0” in the AT state ST3, “300” is added to the continuable game number. When the watermelon combination is won in the AT state ST3, an addition lottery for determining whether or not to execute a process of adding "30" to the number of continueable games is executed.

  Here, the addition lottery performed using the addition random number will be described. The control IC 148 obtains numerical value information of the random number updated by the random number counter for addition (not shown) of the main side RAM 144 to obtain an addition random number. The timing at which the control IC 148 acquires the addition random number is a timing immediately after the timing at which the control IC 148 acquires the first random number input to the input terminal TA8 of the control IC 148 in the normal process (FIG. 42).

  Next, the AT state management process executed in step S1906 of the game completion process (FIG. 46) will be described with reference to FIG. FIG. 48 is a flowchart showing an AT state management process performed by the control IC 148.

  First, in step S2001, it is determined whether the value of the AT state counter is "0". Here, the AT state counter is a counter that counts the number of continueable games in the base state ST32 of the AT state ST3. The number of continueable games is set when the transition to the AT state ST3 is performed. The number of continuable games set in the AT state counter is decremented by "1" every time one game is finished in the base state ST32 of the AT state ST3.

  If it is determined in step S2001 that the value of the AT state counter is "0", it is determined that the first cherry has been won in step S2002 because it is in the non-AT state. If it is determined that the first cherry has been won (step S2002: YES), "30" is set in the AT state counter at step S2003 as the number of continuable games. If the first cherry has not been won (step S2002: NO), whether or not the second cherry has been won is determined in step S2004. Then, if it is determined that the second cherry has been won (step S2004: YES), "300" is set in the AT state counter at step S2005 as the number of continuable games.

  After setting the number of continuable games of AT state ST3 in the AT state counter in step S2003 or step S2005, the preparation state flag is set to "1" in step S2006, and the preparation state command is set to sub MPU152 in step S2007. It is set as a transmission target, and this AT state management processing ends. By receiving the preparation state command, the sub MPU 152 can grasp the timing to notify the player that the preparation state of the AT state ST3 is started. On the other hand, if it is determined in step S2004 that the second cherry has not been won, the AT state management process is ended as it is.

  If it is determined in step S2001 that the number of possible continuation games is "1" or more is set in the AT state counter, since it is AT state ST3, whether or not the preparation state flag is "0" in step S2008. judge. When the preparation state flag is "0" in step S2008, the preparation state ST31 of the AT state ST3 is changed to the base state ST32, and the number of continuable games is reduced by one each for one game. In step S2009, "1" is subtracted from the AT state counter. Then, in step S2010, it is determined whether the watermelon has been won.

  After it is determined in step S2008 that the preparation state flag is "1" and it is determined that preparation state ST31 for AT state ST3 is made, or after it is determined in step S2010 that no watermelon is won, the first step is performed in step S2011. It is determined whether or not Cherry has been won. Then, if it is determined in step S2011 that the first cherry has been won, "30" is added to the AT state counter in step S2012.

  If the first cherry has not been won (step S2011: NO), it is determined whether or not the second cherry has been won in step S2013. If it is determined that the second cherry has been won (step S2013: YES), "300" is added to the AT state counter in step S2014.

  If addition is performed on the number of continuable games set in the AT state counter in step S2012 or step S2014, an addition command is transmitted to the sub MPU 152 in step S2015, and the AT state is determined. End the management process. By receiving the addition command, the sub MPU 152 can grasp timing for performing an effect for informing the player that the number of the continuable games in the AT state ST3 has been added is notified.

  If it is determined in step S2013 that the second cherry is not won, it is determined in step S2016 whether or not the number of continueable games set in the AT state counter is "0". If the number of continuable games does not remain (step S2016: YES), an AT state end command is transmitted to the sub MPU 152 in step S2017, and the present AT state management process is ended. By receiving the AT state end command, the sub MPU 152 can grasp the timing to perform an effect for notifying the player that the AT state ST3 has ended. On the other hand, if the number of continueable games remains in step S2016, the present AT state management process is ended.

  If the watermelon has been won in step S2010, the watermelon winning process is executed in step S2018, and the present AT state management process is ended. In the watermelon winning process, an addition lottery using the random number for addition acquired by the control IC 148 in step S1712 of the above-described normal process (FIG. 42) is executed.

  Specifically, with respect to the addition lottery, “21845” is added to the addition random number capable of taking values “0” to “65535” to make a determination value for addition lottery, and the determination value for addition lottery is “65535”. It is determined whether it exceeds or not. If the determination value for addition lottery exceeds “65535”, it means that the addition lottery has been won. Here, the probability of winning the addition lottery is 1/3. In this case, "30" is added to the AT state counter, and an addition command is sent to the sub MPU 152, and the watermelon winning process is ended. In addition, when the determination value for addition lottery does not exceed “65535”, it means that the lottery for addition is removed. In this case, when the AT state counter is not "0", the watermelon winning process is terminated. When the AT state counter is "0", an AT state end command is transmitted to the sub MPU 152, and the watermelon winning process is ended.

  As described above, even in the addition lottery performed using the addition random number different from the first random number and the second random number generated by the update circuit 101, the number of continuable games in the AT state ST3 can increase. Therefore, while setting the winning probability of the second cherry to a low probability of less than 1/65535, the player can add the number of continueable games even when the watermelon is won except when the first cherry is won and the second cherry is won. Create a situation that expects to be played and improve the interest of the game.

  Next, the processing for BB executed in step S1905 of the response processing at the end of the game (FIG. 46) will be described with reference to FIG. FIG. 49 is a flowchart showing processing for BB executed by the control IC 148.

  First, in step S 2101, it is determined whether or not a medium-improved combination prize, specifically, a bell prize or a watermelon prize, has occurred in the current game. If no winning of the medium imparting combination has occurred (step S2101: NO), the processing for this BB ends. If a winning of the medium awarding combination has occurred (step S2101: YES), a subtraction process of the residual awarding number counter provided in the main side RAM 144 is executed in step S2102. In the subtraction process, “8” is subtracted from the value of the remaining assignment number counter.

  In the following step S2103, it is determined whether the value of the remaining application number counter is "0". If the value of the remaining assignment number counter is not “0” (step S2103: NO), the processing for this BB ends. If the value of the remaining application number counter is "0" (step S2103: YES), this means that the BB state has ended, so whether or not the value of the AT state counter is "0" at step S2104. To determine the

  If the value of the AT state counter is "0" (step S2104: YES), it means that the normal gaming state ST1 has been changed to the BB state ST2. In this case, it is determined in step S2105 whether or not the bell has been won. If the bell has not been won in step S2105 (step S2105: NO), it is determined in step S2106 whether or not the watermelon has been won. If it is determined in step S2106 that the watermelon has not been won, the processing for this BB ends.

  If the watermelon is won in the final game of the BB state ST2 (step S2106: YES), the transition lottery L1 is executed in step S2107 and step S2108. In the transition lottery L1, when the transition is won, the AT state ST3 is selected, and when the transition is not won, the normal gaming state ST1 is entered.

  Specifically, with respect to the transition lottery L1, using the second random number acquired at the start of the current game as the second determination value DV2 in step S2107, “21845” is added to the second determination value DV2 to create a new first 2 Calculate the determination value DV2. In the following step S2108, it is determined whether or not the second determination value DV2 calculated in step S2107 exceeds "65535". If the second determination value DV2 exceeds “65535” in step 2108 (step S2108: YES), it means that the transition lottery to the AT state ST3 has been won. Here, the probability of winning the transition lottery L1 to the AT state ST3 is 1/3.

  If a negative determination is made in step S2104, that is, if the AT state ST3 is changed to the BB state ST2, if the bell is won in the last game of the BB state ST2 (step S2105: YES), or AT If the transition lottery to state ST3 is won (step S2108: YES), "30" is set in the AT state counter of the main side in step S2109, and the preparation state for the sub side MPU 152 in step S2110 The command is transmitted to shift to the preparation state ST31 of the AT state ST3. By receiving the preparation state command, the sub MPU 152 can grasp the timing to execute the effect for notifying the player that the preparation state ST31 of the AT state ST3 has been reached. Then, in step S2111, the preparation state flag is set to "1", and the fact that it has shifted to the preparation state ST31 is stored.

  After being shifted to the AT state ST3 in step S2108, or after setting the preparation state flag to "1" in step S2111, the BB flag is cleared to "0" in step S2112, and the process proceeds to step S2113. Then, the BB end command is transmitted to the sub MPU 152, and the processing for BB is ended. By receiving the BB end command, the sub MPU 152 can execute an effect for informing the player that the BB state ST2 has ended.

<Process Performed by Sub MPU 152>
Next, the stop order notification control process executed by the sub MPU 152 will be described with reference to the flowchart of FIG. The sub MPU 152 periodically (for example, 2 msec cycle) performs periodic processing. The sub MPU 152 receives the preparation state command transmitted from the control IC 148 to grasp the timing at which the preparation state ST31 of the AT state ST3 is started, and receives the base state command transmitted from the control IC 148. Thus, the timing at which the base state ST32 of the AT state ST3 is started is grasped. If the sub MPU 152 is aware that the AT state ST3 is in progress, the sub MPU 152 executes in-AT processing in periodic processing. The stop order notification control process (FIG. 50) is a process that is executed when the sub MPU 152 receives a game start command from the control IC 148 during the AT process.

  In the stop order notification control process (FIG. 50), first, in step S2201, data indicating that the player has won by one of the index values IV = 1 to 3 in the lottery process of the winning combination is set to the game start command received this time It is determined whether or not it exists. If the index value IV is 1 to 3 (step S2201: YES), it is determined in step S2202 whether or not the lottery mode is the RT mode. Here, the RT mode means the first RT mode or the second RT mode. When it is the first RT mode or the second RT mode (step S2202: YES), in step S2203, the stop order setting process of the bell winning is executed. As a result, notification of the stop order of the reels 32L, 32M, 32R that enables the establishment of the bell winning is started in the image display device 66 before the stop operation of the reels 32L, 32M, 32R becomes possible.

  After performing a negative determination in step S2201, after performing a negative determination in step S2202, or after performing a stop order setting process for bell winning in step S2203, in step S2204, a lottery process for a winning combination is performed. It is determined whether or not data indicating that a promotion target combination has been won is set in the game start command received this time. If the player is elected as the promotion target combination (step S2204: YES), in step S2205, the stop order setting process for promotion occurrence is executed. Thereby, the notification of the stop order of the reels 32L, 32M, 32R enabling the establishment of the first RT replay win or the second RT replay win corresponding to the winning becomes possible before the operation of stopping the reels 32L, 32M, 32R becomes possible. The image display 66 starts.

  After performing a negative determination in step S2204 or after performing the stop order setting process for promotion occurrence in step S2205, in step S2206, data indicating that the demolition target is won in the lottery process of the combination is It is determined whether or not the game start command received this time is set. If the player is elected as a target for demotion (step S2206: YES), the process for setting stop order for avoidance of demotion is executed in step S2207, and the process for notification control of stop order is ended. In this way, it is possible to stop the reels 32L, 32M, 32R to notify the stop order of the reels 32L, 32M, 32R that can avoid the establishment of the first fall replay prize or the second fall replay prize corresponding to the winning. It is started in the image display device 66 before becoming.

  Next, referring to the time chart of FIG. 51, the start timing and end timing of the standby period, and the timing at which the rotation of each reel 32L, 32M, 32R is started will be described.

  FIG. 51 (a) shows the state of the detection signal SG2 output from the start detection sensor 41a, FIG. 51 (b) shows the standby period, and FIG. 51 (c) shows the first management register 403 as the first latch register. 51 (d) shows the timing when the control IC 148 acquires numerical information of the first random number inputted to the input terminal TA8 of the control IC 148, and FIG. 51 (d) shows the timing when the latch signal is transmitted. e) shows the timing at which the second management circuit 404 transmits a latch signal to the second latch register 408, and FIG. 51 (f) shows the second random number in which the control IC 148 is inputted to the input terminal TA9 of the control IC 148. 51 (g) shows the rotational speed of each of the reels 32L, 32M, 32R, and FIG. 51 (h) shows that the lottery process is performed. That shows the timing.

  When the start lever 41 is depressed at timing t1, as shown in FIG. 51A, the detection signal SG2 output from the start detection sensor 41a rises from LOW to HI at timing t1. Since the HI state of the detection signal SG2 continues for 12.8 μs or more, as shown in FIG. 51C, the first management circuit 403 transmits a latch signal at the timing of t2 when 12.8 μs has elapsed from the timing of t1. Do. Thus, the first random number is written to the first latch register 407.

  As shown in FIG. 51 (d), in the normal processing (FIG. 42) executed at the timing of t3 after the timing of t2, the control IC 148 is the first random number inputted to the input terminal TA8 of the control IC 148. Get numerical information of Further, as shown in FIG. 51 (g), the control IC 148 performs the first reel control process at the same timing t3 to start the rotation of each reel 32L, 32M, 32R. The reels 32L, 32M, 32R that have started to rotate at the timing of t3 are in an acceleration state in which the rotational speed is increased until the constant rotation state is reached.

  Thereafter, as shown in FIG. 51A, the detection signal SG2 outputted from the start detection sensor 41a falls from the HI state to the LOW state at the timing of t4. As shown in FIG. 51 (e), since the second management circuit 404 transmits a latch signal to the second latch register 408 at the timing of t5 when 12.8 μs has elapsed from the timing of t4, the second latch register is generated. A second random number is written at 408.

  In the normal process (FIG. 42) performed at the timing of t6 after the timing of t5, the control IC 148 acquires numerical value information of the second random number input to the input terminal TA9 of the control IC 148. Further, as shown in FIG. 51 (h), at the same timing t6, the control IC 148 executes a lottery process using the first random number and the second random number. Thereafter, as shown in FIG. 51 (g), at the timing of t7, the acceleration period of each of the reels 32L, 32M, 32R starting from the timing of t3 ends, and a constant speed rotation period starts. As a result, as shown in FIG. 51 (b), the waiting period ends at the timing of t7, and the player can operate the stop buttons 42 to 44.

  As described above, by providing the standby period for invalidating the operation of the stop button 42 to 44 by the player, the control IC 148 stops the reels 32L, 32M, 32R before acquiring the first random number and the second random number. Can be avoided.

  As described above, when the first management circuit 403 determines that the detection signal SG2 input to the first management circuit 403 rises to the HI state, and determines that the HI state is maintained for 12.8 μs or more, the first management circuit 403 performs the first operation. The latch signal is transmitted to the CLK terminals of the latch D-FFs 407a to 407p. In addition, the second management circuit 404 causes the second latch to be triggered when the inverted detection signal SG3 input to the second management circuit 404 rises to the HI state and determines that the HI state is maintained for 12.8 μs or more. The latch signal is transmitted to the CLK terminals of the D-FFs 408a to 408p. Each of the timing when the numerical information of the first random number is written to the first latch register 407 and the timing when the numerical information of the second random number is written to the second latch register 408 changes according to the operation of the player. It is a different timing. Therefore, the control IC 148 can execute a lottery using two unsynchronized random numbers.

  Further, the detection signal SG2 output from the start detection sensor 41a is input to the first management circuit 403, and the detection signal SG2 output from the start detection sensor 41a is inverted and generated in the second management circuit 404. The inverted detection signal SG3 is input. Thus, while the two management circuits 403 and 404 have the same configuration, the timings at which the two management circuits 403 and 404 transmit latch signals to the CLK terminals of the latch register D-FFs 102 a to 102 p are different. be able to.

  Further, in the determination of the success or failure of the combination performed using the first random number, when the first cherry combination is won, the determination on the success or failure of the second cherry combination is performed using the second random number. The winning probability of the second cherry role is smaller than 1/65535, which is the minimum probability that can be set using one 16-digit binary number. As described above, by performing the two-step success / failure determination using two non-synchronized random numbers, a combination having a winning probability lower than that of the lowest settable winning probability in the success / failure determination using only the first random number is set. It is possible to improve the interest of the game.

  In a non-BB state in which a yes / no decision regarding the first cherry combination is performed, a yes / no decision regarding the second cherry combination is performed based on the second random number, and a yes / no decision regarding the first cherry combination is not performed In the game, the transition lottery to the AT state ST3 based on the second random number is performed. As a result, it is possible to add a lottery for deciding whether the transition to the AT state ST3 advantageous to the player is successful or not without increasing the number of random numbers acquired by the control IC 148, and to improve the interest of the game.

  Further, the control IC 148 is configured to execute the first reel control process (step S1711) for starting the rotation of each of the reels 32L, 32M, 32R at the timing when the control IC 148 acquires the first random number. The time from the operation timing of the start lever 41 to the timing of the rotation start in each of the reels 32L, 32M, 32R can be shortened compared to the configuration in which the first reel control process is executed at the timing of acquiring random numbers. As a result, it is possible to reduce the possibility that the player feels a time lag between the operation of the start lever 41 and the start of rotation of each of the reels 32L, 32M, 32R.

  Further, in the game performed in the base state ST32 of the AT state ST3, when the first cherry role or the second cherry role is won, the number of continuable games is added and the winning combination is won when the watermelon role is won. When the game is won and the winning is made in the addition lottery, the number of possible continuation games is added. Here, only the first random number is used to determine whether to win the first cherry combination and whether to win the watermelon combination, and to determine whether to win the second cherry combination. The second random number is used in addition to the first random number. Further, in the addition lottery performed when the watermelon role is won, an addition random number is used. Thus, as a pattern to which the number of continuable games in the AT state ST3 is added, a pattern to be added based on a combination of the first random number and the second random number and a pattern to be added based on only the first random number By the presence of the first random number and the pattern to be added based on the addition random number, the interest of the game can be improved.

<Another form of the fourth embodiment>
In the present embodiment, in the normal process (FIG. 52) executed by the control IC 148, the second random number is acquired after the rotation of each of the reels 32L, 32M, 32R is started, and the second lottery is performed using the second random number. Processing (processing in step S2313 of the normal processing (FIG. 52)) is performed. The description of the same configuration as that of the fourth embodiment is basically omitted.

  First, normal processing in the present embodiment will be described with reference to the flowchart of FIG. First, in step S2301, a first lottery preparation process is performed. In the first lottery preparation process, the processes of steps S1701 to S1712 in the normal process (FIG. 42) of the fourth embodiment described above are performed.

  Specifically, for the normal process (FIG. 52), after executing the interrupt permitting process for permitting the next timer interrupt process (step S1701), a start waiting process is performed (step S1702). Then, if the bet number is not the prescribed number (step S1703: NO), the process returns to the start waiting process. If the bet amount is a prescribed number (step S1703: YES), it is determined whether the start enable flag 144a is set to "1" (step S1704). Then, when “1” is not set in the start possibility flag 144a (step S1704: NO), “1” is set in the start possibility flag 144a.

  Then, it is determined whether or not “1” is set in the first start instruction flag 144g, and if “1” is not set (step S1706: NO), the process returns to the start waiting process. When the first start command flag 144g is set to "1" (step S1706: YES), the control IC 148 acquires numerical information of the first random number input to the input terminal TA8 of the control IC 148. (Step S1707), the first start instruction flag 144g is cleared to "0" (step S1708). After that, the acceptance prohibition process is performed, whereby the medal inserted into the medal insertion slot 45 is discharged as it is to the medal receptacle 59 (step S1709). Subsequently, the first reel control processing is performed to start rotation of each of the reels 32L, 32M, 32R (step S1710), and the time until the rotational speed of each reel 32L, 32M, 32R becomes constant is set as a standby period. (Step S1711). Then, numerical value information of the updated random number is acquired by the addition random number counter (not shown) of the main side RAM 144, and it is set as the current addition random number (step S1712).

  Returning to the description of the normal processing (FIG. 52), after the first lottery preparation processing is executed in step S2301, the first lottery processing is executed in step S2302. In the first lottery process, the same processes as steps S502 to S505, step S507, and step S508 in the lottery process (FIG. 11) of the first embodiment are performed. Specifically, a lottery table for performing a winning or losing lottery of a combination is read from the main ROM 143 (step S502), and "1" is set as the index value IV (step S503). Further, the first point value PV1 is added to the current first determination value DV1 to obtain a new first determination value DV1 (step S504), and it is determined whether the new determination value exceeds “65535” or not. (Step S505). Here, a first random number is used as the first determination value DV1 of the first time.

  If the new first determination value DV1 does not exceed “65535” (step S505: NO), “1” is added to the current index value IV to update the index value IV (step S507). After that, it is determined whether or not there is a determination combination corresponding to the current index value IV in the lottery table with reference to the lottery table being read (step S508). If there is a determination combination corresponding to the current index value IV (step S508: YES), the first determination value DV1 corresponding to the current index value IV is added to the first determination value DV1 to generate a new first value. The process returns to the process of setting the determination value DV1 (step S504).

  In the first lottery process, when the first determination value DV1 exceeds “65535” (step S505: YES), or when the determination combination corresponding to the updated index value IV is not present (step S508: NO) Finish to). As described above, it is checked whether or not the player has been elected while changing the index value IV. If the player has won the combination, the index value IV of the combination corresponding to the winning combination is acquired.

  Returning to the description of the normal processing (FIG. 52), after performing the first lottery processing in step S2302, in step S2303, it is determined whether or not the first cherry combination is won. If the first cherry combination is not won (step S2303: NO), stop information for setting the stop mode of each reel 32L, 32M, 32R in step S2304 to correspond to the result of the lottery process of the combination Execute the first setting process. Then, in order to make the sub MPU 152 recognize that a new game has been started in step S2305, a game start command is set as a transmission target to the sub MPU 152.

  If the first cherry combination is won in step S 2303, “1” is set in the cherry winning flag (not shown) set in the main RAM 144 in step S 2306. After the game start command is set in step S2305 or after the cherry winning flag is set to "1" in step S2306, whether or not "1" is set to the second start command flag 144h in step S2307 judge. If "1" is not set in the second start command flag 144h (step S2307: NO), the process waits until the second start command flag 144h is set in "1". When "1" is set to the second start command flag 144h (step S2307: YES), the process proceeds to the process of step S2308 and subsequent steps.

  In steps S2308 to S2310, the same processes as steps S1714 to S1716 in the normal process (FIG. 42) of the fourth embodiment are performed. Specifically, at step S2308, the start possibility flag 144a is cleared to "0", and at step S2309 the numerical information of the second random number inputted to the input terminal TA9 (FIG. 39) of the control IC 148 is obtained. Then, the second start command flag 144h is cleared to "0".

  In the following step S2311, it is determined whether or not "1" is set to the cherry winning flag (not shown), and if "1" is set to the cherry winning flag (step S2311: YES), the step is performed. The processing of step S2312 to step S2314 is executed.

  After clearing the cherry winning flag "0" in step S2312, a second lottery process is executed in step S2313. In the second lottery process, a second random number is used as the second determination value DV2, and a new second determination value DV2 obtained by adding the second point value PV2 to the second determination value DV2 is "65535". It is determined whether or not it has exceeded. When the new second determination value DV2 exceeds "65535", the second cherry combination is won, and when the second determination value DV2 is less than "65535", the first cherry combination is determined. Maintain the status of being won.

  Returning to the description of the normal processing (FIG. 52), after executing the second lottery processing in step S2313, the stop mode of each reel 32L, 32M, 32R corresponds to the result of the second lottery processing (step S2313) in step S2314. The stop information first setting process for performing the above process is executed. Specifically, when the second cherry is won in the second lottery process, the first stop information setting process for setting the stop information corresponding to the second cherry is executed. In addition, when it does not become the second cherry winning in the second lottery processing, the stop information first setting processing for setting the stop information corresponding to the first cherry winning is executed. Then, in the subsequent step S2315, a game start command for causing the sub MPU 152 to recognize that a new game has been started is set as a transmission target to the sub MPU 152.

  After making a negative determination in step S2311, after making a negative determination in step S2314, or after setting a game start command in step S2316, it is determined in step S2317 whether the waiting period has ended. If the waiting period has not ended (step S2317: NO), the processing waits until the waiting period ends. Then, after the waiting period ends (step S2317: YES), other processes are executed in step S2318, and the process returns to the process of step S2301. Here, in the other processing of step S2318, the same processing as step S1719 to step S1723 of the normal processing (FIG. 42) of the fourth embodiment is executed.

  Specifically, after the second reel control process has been executed (step S1719), if a minor winning combination is established in the current game, the player is awarded the number of gaming media corresponding to the minor winning combination. A medium imparting process for playing the game is executed (step S1720), and a response process at the end of the game for enabling the setting of the gaming state corresponding to the result of the current game is executed (step S1721). Then, the external output setting process for outputting the state of the slot machine 10 to the management computer of the gaming hall is executed (step S1722), and the acceptance permitting process is executed (step S1723).

  In the normal process (FIG. 42) of the fourth embodiment, after the standby time is set in step S1712, the process waits until the second start command flag 144h is set to "1" in step S1713. . On the other hand, in the normal process (FIG. 52) of this embodiment, the first random number is used before the process of waiting until the second start command flag 144h is set to "1" (the process of step S2307). The first lottery process is performed. Therefore, if the standby period has ended by the timing when the determination process of step S2317 is executed, the player can press the stop button 42 to 44 after acquiring the second random number in step S2309. The time to become can be shortened.

Fifth Embodiment
In this embodiment, the control IC 148 is a 32-digit binary number by combining the 16-digit binary number first random number numeric information and the 16-digit binary number second random number numeric information. Generate a random number for lottery. Then, the control IC 148 executes an acceptance lottery of a combination including a second cherry combination having a winning probability of less than 1/65535 in one lottery using the random number for lottery. The description of the same configuration as that of the fourth embodiment is basically omitted.

  First, random numbers for lottery used for a winning lottery of a combination in the present embodiment will be described with reference to FIGS. 53 (a) to 53 (c). FIG. 53 (a) is an explanatory drawing for explaining the first random number, FIG. 53 (b) is an explanatory drawing for explaining the second random number, and FIG. 53 (c) is a drawing random number FIG.

  In the present embodiment, the control IC 148 uses the random number for lottery to perform a winning lottery of the role. Further, in the present embodiment, in addition to the winning lottery of the combination performed using the random numbers for lottery, the transition lottery L1, the continuous lottery, and the additional lottery are performed. Here, the first random number is used for the transition lottery L1, the continuous lottery, and the additional lottery.

  Then, when the watermelon combination is won in the transition lottery L1, a lottery for determining whether or not to set “100” to the number of continuable games in the AT state ST3 using the second random number is executed. In addition, in the continuation lottery, when it becomes the continuation winning, the lottery for determining whether or not “100” is set as the number of possible continuation games of the AT state ST3 using the second random number is executed. In addition, in the addition lottery, when the addition is won, a lottery for determining whether to add “100” to the number of continuable games in the AT state ST3 using the second random number is executed. In addition, since the transition lottery L1, the continuation lottery, and the additional lottery are not performed simultaneously, in one game, two or more lotterys are not performed from among the transition lottery L1, the continuous lottery, and the additional lottery. .

  As shown in FIG. 53 (a), the first random number is a 16-digit binary number. Let the number of the nth digit of the first random number be An. Here, n is a natural number of 1 to 16. Also, A1 to A16 are numbers of “1” or “0”, and the maximum value of the first random number is “65535”. Similarly, as shown in FIG. 53 (b), the second random number has 16 binary digits. It is assumed that the nth digit of the second random number is Bn. Here, n is a natural number of 1 to 16. B1 to B16 are numbers of "1" or "0", and the maximum value of the second random number is "65535".

  In the present embodiment, the control IC 148 generates a random number for lottery by combining the first random number and the second random number. As shown in FIG. 53 (c), the random number for lottery is a 32-digit binary number. Let the m-th digit of the random number for lottery be Cm. Here, m is a natural number of 1 to 32. In addition, C1 to C32 are numbers of "1" or "0", and the number of possible values for the random number for lottery is "4294836225".

  As shown in FIG. 53 (c), the first digit (C1) to the sixteenth digit (C16) in the random number for lottery are the first digit (B1) to the sixteenth digit in the second random number. Of the 17th digit (C17) to the 32nd digit (C32) in the random number for drawing, and the 16th digit from the 1st digit (A1) on the first random number The same as the numbers (A16).

  In the lottery table used in the lottery process (FIG. 55) performed using the random number for lottery, a plurality of winning numbers for winning each winning combination are set. In addition, it is set that there is no duplication in the winning numbers among the winning combinations. That is, the same winning number is not set for different roles. The probability of winning each role is determined by the number of winning numbers set for that role. The control IC 148 determines whether or not the random number for drawing matches the winning number in order from the winning combination in which the index value IV is "1", and there is a winning combination in which the same winning number as the random number for drawing is set. If it is determined that the winning combination has been won.

  Here, in the lottery table of the present embodiment, the winning numbers corresponding to each combination are set at random intervals. As described above, the numbers 1 to 16 (C1 to C16) of the random number for lottery are the same as the numbers 1 to 16 (B1 to B16) of the second random number, and 17 to 32 of the random number for lottery The digit numbers (C17 to C32) are the same as the first to sixteenth digit numbers of the first random number. For this reason, in the lottery table, when the winning numbers corresponding to each combination are set as serial numbers without an interval, a row using the first random number and the lottery random number is used. There is a possibility that it will be linked with the result of the lottery being played. Similarly, there is a possibility that the result of the lottery performed using the second random number interlocks with the result of the lottery performed using the random number for lottery.

  On the other hand, in the lottery table of the present embodiment, the winning numbers corresponding to each combination are set at random intervals, so that the lottery result and the lottery performed using the first random number are made. It is possible to reduce the possibility that the player notices the relation with the result of the lottery performed using the random number. Similarly, it is possible to reduce the possibility that the player notices the relationship between the result of the lottery performed using the second random number and the result of the lottery performed using the random number for lottery. The details of the lottery process in the present embodiment will be described later.

  Next, normal processing executed by the control IC 148 will be described with reference to the flowchart of FIG. First, in step S2401, a first random number acquisition process is performed. In the first random number acquisition process, the same process as step S1701 to step S1707 in the normal process (FIG. 42) of the fourth embodiment is executed. In the following step S2402, the same processing as step S1709 to step S1716 in the fourth embodiment is executed.

  In the following step S2403, the 4-byte random number for drawing is generated by combining the acquired 2-byte first random number numerical information and the 2-byte second random number numerical information, and in step S2404 the 4-byte random number for drawing Execute the lottery process, which is the winning or losing lottery of the role using the. The details of the lottery process in the present embodiment will be described later. After the lottery process is performed in step S2404, other processes are performed in step S2405, and the process returns to the first random number acquisition process of step S2401. In the other processing, the processing of step S1718 to step S1723 in the normal processing (FIG. 42) of the fourth embodiment is executed.

  Next, the lottery process executed by the control IC 148 will be described with reference to the flowchart of FIG. First, in step S 2501, a lottery table used for a winning lottery for a combination performed using random numbers for lottery is read out from the main RAM 144.

  Here, the configuration of the lottery table of the present embodiment will be described with reference to the normal mode lottery table of FIG. 56 (a). As shown in FIG. 56A, in the lottery table, the numbers 1 to 11 are set as the index value IV, and the winning combination is set for each index value IV. In addition, an nth random number group is set as a group of winning numbers for determining whether or not a winning combination having an index value IV of n is won. Here, n is a natural number of 1 to 11.

  FIG. 56 (b) is a table showing a part of the random numbers set in the first random number group to the eleventh random number group. In the random number group table, numerical value information of random numbers is shown converted from binary numbers to decimal numbers. As shown in FIG. 56 (b), the numerical information set as the winning number of each random number group is not a sequential number. On the other hand, in the present embodiment, the value of the random number to be elected in the lottery performed using the first random number and the value of the random number to be elected in the lottery performed using the second random number are both set in sequence numbers. There is. For this reason, the player randomizes the first random number from the result of the lottery process of the winning combination performed by using the random number for lottery by setting an irregular interval in the numerical information set as the winning number of each random number group. It is possible to avoid a situation in which the result of the lottery performed using the second random number and the result of the lottery performed using the second random number can be easily predicted.

  Returning to the explanation of the lottery process (FIG. 55), after the lottery table is read out in step S2501, in step S2502, "1" is set as the first index value IV. In the following step S2503, it is determined whether or not the current random number for lottery is included in the IVth random number group of the lottery table for the current index value IV. If the random number for lottery this time is not included in the IV random number group (step S 2503: NO), “1” is added to the current index value IV in step S 2504 to update to a new index value IV. It is determined whether or not the updated index value IV is set as the index value IV of the lottery table read out in step S2505.

  If the updated index value IV is set in the lottery table being read (step S2505: YES), the process returns to step S2503 and the random number for lottery for the updated index value IV is the IVth random number of the lottery table Execute determination processing whether or not included in a group.

  If the random number for drawing is included in the IV random number group in step S2503 (step S2503: YES), or if the updated index value IV is not set in the lottery table being read in step S2505 Proceed to step S2506.

  In step S2506, stop information first setting processing is performed to set stop information in accordance with the winning result of the winning combination, and in step S2507 a game start command is made to the sub side in order to make the sub side MPU 152 recognize that a new game has started. This is transmitted to the MPU 152, and the lottery process is finished.

  Next, AT state management processing executed by the control IC 148 will be described with reference to the flowchart of FIG. First, in step S2601, it is determined whether the AT state counter is "0". If the AT state counter is not "0" (step S2601: NO), it means that the AT state ST3 is established. In this case, it is determined in step S2602 whether the value of the preparation state flag is "0".

  If the value of the preparation state flag is "0", the AT mode ST3 has already shifted from the first RT mode to the second RT mode, and the number of continuable games is decremented by one each game. It is in the state. In this case (step S2602: YES), "1" is subtracted from the AT state counter in step S2603. In the following step S2604, it is determined whether or not the watermelon has been won. If the watermelon is won (step S2604: YES), the additional lottery process is executed in step S2605, and the present AT state management process is ended.

  Here, the additional lottery process executed in step S2605 will be described with reference to the flowchart of FIG. First, in step S2701, a first additional lottery process is executed. In the first additional lottery process, if the result of adding “4369” to the first random number exceeds “65535”, the winning is achieved. The probability of winning in the first additional lottery process is 1/15.

  In step S2702, it is determined whether or not the first additional lottery has been won, and if the first additional lottery has not been won (step S2702: NO), the additional lottery process is ended. When the first additional lottery is won (step S2702: YES), the second additional lottery process is executed in step S2703. In the second additional lottery process, if the result of adding “5” to the second random number exceeds “65535”, the winning is achieved. The probability of winning in the second additional lottery process is 1/13107.

  In step S2704, it is determined whether or not the second additional lottery has been won. If the second additional lottery is not won (step S2704: NO), "30" is added to the AT state counter in step S2705. If the second additional lottery is won (step S2704: YES), "100" is added to the AT state counter in step S2706.

  After the addition processing to the AT state counter is executed in step S2705 or step S2706, an addition command is transmitted to the sub MPU 152 in step S2707, and the extra lottery process is ended. By receiving the addition command, the sub MPU 152 can grasp timing for performing an effect for notifying the player that the number of continuable games in the AT state ST3 has increased. Here, the probability that "300" is added to the AT state counter when this additional lottery process is performed is 1/196605, which is smaller than 1/65535.

  Returning to the description of the AT state management process (FIG. 57), if it is determined in step S2604 that the watermelon has not been won, it is determined in step S2606 whether or not the cherry has been won. Here, the cherry winning means the first cherry winning or the second cherry winning. If it is determined in step S2606 that the cherry is not selected, it is determined in step S2607 whether the AT state counter is "0". Then, if the AT state counter is not "0" (step S2607: NO), the present AT state management processing is ended, and if the AT state counter is "0" (step S2607: YES), step S2608. At this time, the continuous lottery process is executed, and the present AT state management process is ended.

  Here, the continuous lottery process executed in step S2608 will be described with reference to the flowchart of FIG. 58 (b). First, in step S2801, a first continuous lottery process is executed. In the first continuous lottery process, if the result of adding “4369” to the first random number exceeds “65535”, the winning is achieved. The probability of winning in the first continuous lottery process is 1/15.

  In step S2802, it is determined whether or not the first continuous lottery has been won, and if the first continuous lottery has not been won (step S2802: NO), the present continuous lottery process is ended as it is. If the first continuous lottery is won (step S2802: YES), the second continuous lottery process is executed in step S2803. In the second continuous lottery process, if the result of adding “5” to the second random number exceeds “65535”, the winning is achieved. The probability of winning in the second continuous lottery process is 1/13107.

  In step S2804, it is determined whether or not the second continuous lottery has been won. If the second continuation lottery has not been won (step S2804: NO), "30" is added to the AT state counter in step S2805. If the second continuous lottery is won (step S2804: YES), "100" is added to the AT state counter in step S2806.

  After the addition process to the AT state counter is executed in step S2805 or step S2806, an addition command is transmitted to sub side MPU 152 in step S2807, and the continuous lottery process is ended. By receiving the addition command, the sub MPU 152 can grasp timing for performing an effect for notifying the player that the number of continuable games in the AT state ST3 has increased. Here, the probability that "100" is added to the AT state counter when this continuous lottery process is performed is 1/196605, which is smaller than 1/65535.

  Returning to the description of the AT state management process (FIG. 57), if it is determined in step S2606 that the cherry has been won, in step S2609, the corresponding process of the cherry win is executed and the present AT state management process is ended. In the cherry-winning process in step S2609, the same process as step S201 1 to step S2015 in the AT state management process (FIG. 48) of the fourth embodiment is executed.

  Specifically, it is determined whether or not the first cherry has been won (step S2011: YES), "30" is added to the AT state counter (step S2012), and an addition command is transmitted to the sub MPU 152 (Step S2015). Further, when the winning of the second cherry combination is established (step S2013: YES), "300" is added to the AT state counter (step S2014), and the addition command is transmitted to the sub MPU 152 (step S2014). S2014).

  Returning to the description of the AT state management process (FIG. 57), when the value of the AT state counter is "0" at step S2601 or when the value of the preparation state flag is "1" at step S2602. The other processes are executed in step S2610 to end the present AT state management process. In the other processing, the processing of step S2002 to step S2007 of the AT state management processing (FIG. 48) of the fourth embodiment is executed.

  Specifically, when the first cherry is won (step S2002: YES), "30" is added to the AT state counter (step S2003), and the preparation state flag is set to "1" (step S2006). And an AT state start command to the sub MPU 152 (step S2007). Also, when the winning of the second cherry combination is established (step S2002: NO, step S2004: YES), "300" is added to the AT state counter (step S2005), and the preparation state flag is set to "1". Is set (step S2006), and an AT state start command is transmitted to the sub MPU 152 (step S2007).

  Next, the processing for BB executed by the control IC 148 will be described with reference to the flowchart in FIG. First, in steps S2901 to S2904, the same processing as step S2101 to step S2104 in the processing for BB (FIG. 49) of the fourth embodiment is executed. More specifically, when the medium award winning combination does not occur in the current game (step S2901: NO), the processing for this BB ends, and the medium award winning combination occurs in the current game In (step S2901: YES), "8" is subtracted from the value of the remaining application number counter (step S2902).

  If the value of the remaining assignment number counter does not become "0" after the subtraction (step S2903: NO), the processing for this BB ends. If the value of the remaining assignment number counter becomes “0” after the subtraction (step S2903: YES), it is determined whether the value of the AT state counter is “0” (step S2904).

  If the value of the AT state counter is "0" (step S2904: YES), the first transition lottery process is executed in step S2905. In the first transition lottery process, the winning is achieved when the result of adding “4369” to the first random number exceeds “65535”. The probability of winning in the first transition lottery process is 1/15. In step S2906, it is determined whether or not the first transition lottery has been won, and if the first transition lottery has been won (step S2906: YES), the second transition lottery process is executed in step S2907. In the second transition lottery process, the winning is achieved when the result of adding “5” to the second random number exceeds “65535”. The probability of winning in the second transition lottery process is 1/13107.

  In step S2908, it is determined whether or not the second transition lottery has been won. If the value of the AT state counter is not "0" at step S2904 (step S2904: NO), or if it is determined at step S2908 that the second transition lottery has not been won, the AT state counter is determined at step S2909. Set "30" to If it is determined in step S2908 that the second transition lottery has been won, "100" is set in the AT state counter in step S2910. Here, in this processing for BB, the probability of setting "100" in the AT state counter is smaller than 1/65535, by winning the first transition lottery and winning the second transition lottery, 1/196605 It is.

  After the number of continuable games is set in the AT state counter in step S2909 or step S2910, in step S2911 the preparation state flag is set to "1", and it is stored that the preparation state ST31 of AT state ST3 has been made. A preparation state command is transmitted to the sub MPU 152 at S2912.

  After it is determined in step S2906 that the first transition lottery has not been won, or after the preparation state command is transmitted in step S2912, the flag for BB is cleared to "0" in step S2913, and the sub MPU152 is displayed in step S2914. Then, the BB end command is transmitted to end the processing for BB.

  As described above, a random number for lottery is generated based on the first random number and the second random number, and a lottery using the first random number, a lottery using the second random number, and a lottery using the random number for lottery are It is a configuration to be performed. Since all three random numbers used for the lottery are determined by reflecting the operation timing of the player, the random number determined depending on the processing timing of the control IC 148 is compared with the case where the third random number is used. Thus, the operation timing of the player can be largely reflected on the game result.

  In addition, after the player switches the start lever 41 from the OFF state to the ON state, the first random number and the second random number are acquired from a series of operations for returning the ON state to the OFF state, and a lottery based on the first random number As compared with the configuration in which the lottery based on the second random number and the second random number are performed, the types of the lottery can be increased, and the interest of the game can be improved.

  In addition, it is possible to set a role with a low winning probability that can not be set in a lottery using a 2-byte lottery random number by adopting a configuration to perform a winning or not lottery of the role using a 4-byte lottery random number. Can. And since it is the composition which uses one random number for lottery in the success lottery of a role, compared with the composition which uses two random numbers in the success lottery of a role, increasing the number of random numbers used for lottery other than the winning lottery of a role. Can. Since it is possible to use the first random number and the second random number for lottery other than the winning lottery of the role, it is possible to perform the second transition lottery in addition to the first transition lottery, increasing the pattern of the effect that occurs as a result of the transition lottery The interest of the game can be improved.

Sixth Embodiment
In the present embodiment, both the detection signal SG2 and the inversion detection signal SG3 are input to one management circuit 421 (FIG. 60), and the latch signal output from the management circuit 421 is one latch register 102 (FIG. 60) is input. The description of the same configuration as that of the fourth embodiment is basically omitted.

  The configuration of the main control board 141 in the present embodiment will be described with reference to the block diagram of FIG. As shown in FIG. 60, the main MPU 142 includes a control IC 148 and a hard random number circuit 146. The hard random number circuit 146 includes a management circuit 421, a latch register 102, and an update circuit 101. Here, the latch register 102 in the present embodiment has the same configuration as the latch register 102 (FIG. 6) in the first embodiment, and the update circuit 101 in the present embodiment is the update circuit 101 in the first embodiment. It has the same configuration as (FIG. 6).

  As shown in FIG. 60, the signal line from the start detection sensor 41 a is branched into two at a first branch point 171 on the main control board 141. Since one signal line after branching is connected to the input terminal TA1 of the control IC 148, the detection signal SG2 is input to the input terminal TA1 of the control IC 148. Further, the other signal line after branching is branched into two at the second branch point 172 on the main control board 141. One of the signal lines branched at the second branch point 172 is directly connected to the management circuit 421, and the other of the signal lines branched at the second branch point 172 is connected to the management circuit 421 via the inverting circuit 431. It is done. Therefore, the detection circuit SG2 and the inverted detection signal SG3 are input to the management circuit 421.

  The management circuit 421 is a hard circuit. In the management circuit 421, when either the detection signal SG2 or the inversion detection signal SG3 input to the management circuit 421 rises from the LOW state to the HI state, counting of time by the timer counter is started. When the timer counter starts counting time triggered by the rise of the detection signal SG2 input to the management circuit 421, the timer counter counts time while the HI state of the detection signal SG2 is maintained. It will be continued. The counting of time by the timer counter is stopped when 12.8 μs is counted by the timer counter or when the detection signal SG2 falls to the LOW state before 12.8 μs is counted by the timer counter. When 12.8 μs is counted by the timer counter, a latch signal is transmitted from the management circuit 421 to the latch register 102 at the end timing of the count.

  When the counting by the timer counter is stopped, the timer counter is reset. For this reason, even when the 12.8 μs count by the timer counter is stopped halfway and the condition to start counting is satisfied thereafter, the detection signal SG2 rises to the HI state, and the HI state is 12.8 μs or more. The condition for continuing the transmission of the latch signal from the management circuit 421 to the latch register 102 does not change. Even if the HI state of the detection signal SG2 is cumulatively 12.8 μs or more, the latch signal can not be transmitted unless the HI state is continuously 12.8 μs or more.

  When the timer counter starts counting time triggered by the rise of the inversion detection signal SG3 input to the management circuit 421, while the HI state of the inversion detection signal SG3 is maintained, the timer counter The counting of time is continued. The counting of time by the timer counter is stopped when 12.8 μs is counted by the timer counter or when the inverted detection signal SG3 falls to the LOW state before 12.8 μs is counted by the timer counter. When 12.8 μs is counted by the timer counter, a latch signal is transmitted from the management circuit 421 to the latch register 102 at the end timing of the count.

  When the counting by the timer counter is stopped, the timer counter is reset. Therefore, even when the timer counter stops counting 12.8 μs on the way, and the conditions for starting counting are satisfied again thereafter, the inverted detection signal SG3 rises to the HI state, and the HI state is 12.8 μs. The condition that the control circuit 421 transmits the latch signal to the latch register 102 does not change. Even if the HI state of the inversion detection signal SG3 is cumulatively 12.8 μs or more, the latch signal can not be transmitted unless the HI state is continuously 12.8 μs or more.

  The latch register 102 is a register composed of 16 latch register D-FFs 102a to 102p (FIG. 6). The D terminals of the latch register D-FFs 102a to 102p are connected to the Q terminals of the random number counter D-FFs 105a to 105p (FIG. 6) constituting the random number counter 105. The Q terminals of the latch register D-FFs 102a to 102p are connected to the input terminal TA8 of the control IC 148. The CLK terminals of the latch register D-FFs 102 a to 102 p are connected to the management circuit 421.

  Therefore, when a latch signal is output from the management circuit 421 to the CLK terminal of the latch register D-FFs 102a to 102p, the numerical information of the random number stored in the random number counter 105 is written to the latch register 102, The numerical value information of the random number is output to the input terminal TA8 of the control IC 148. The control IC 148 acquires numerical value information of the random number input to the input terminal TA8 of the control IC 148.

  Here, the random number output to the input terminal TA8 of the control IC 148 is set as a first random number triggered by the rise of the detection signal SG2 input to the management circuit 421, and the inversion detection input to the management circuit 421 The random number output to the input terminal TA8 of the control IC 148 at the rising edge of the signal SG3 is set as a second random number.

  The normal process executed by the control IC 148 of the present embodiment is the same process as the normal process (FIG. 42) in the fourth embodiment. In the normal process, the control IC 148 acquires numerical information of the first random number from the input terminal TA8 of the control IC 148 when “1” is set in the first start command flag 144 g (step S1706: YES). 2) "1" is set to the start command flag 144h (step S1709: YES), and after clearing the start enable flag 144a to "0" (step S1710), numerical information of the second random number from the input terminal TA8 of the control IC 148 To get

  For this reason, in the present configuration in which the hard random number circuit 146 includes one latch register 102, the control IC 148 acquires the numerical information of the first random number and the numerical information of the second random number at different timings and performs different lottery It can be used for

  As described above, the hard random number circuit 146 includes one latch register 102, and the numerical information stored in the random number counter 105 is triggered by the rise of the detection signal SG2 input to the management circuit 421 as the first random number. While being written as numerical information, the numerical information stored in the random number counter 105 is written as numerical information of the second random number triggered by the rise of the inversion detection signal SG3 input to the management circuit 421. A latch register that constitutes the hard random number circuit 146 in comparison with a configuration in which the hard random number circuit 146 separately includes a latch register in which numerical value information of the first random number is written and a latch register in which numerical value information of the second random number is written. By reducing the number of 102, the cost of manufacturing the hard random number circuit 146 can be reduced or the area can be reduced.

<Another form of the sixth embodiment>
As the management circuit 421 in the sixth embodiment described above, the latch signal is output to the latch register 102 triggered by the rise of the detection signal SG2 inputted, and the latch register 102 triggered by the fall of the detection signal SG2 inputted. Alternatively, a management circuit that transmits a latch signal may be used. Thereby, the inverting circuit 431 on the main control board 141 can be omitted.

Seventh Embodiment
In the present embodiment, the hard random number circuit 146 adds the third latch register 409 (FIG. 60) to the first latch register 407 of the fourth embodiment and the second latch register 408 of the fourth embodiment. Have. When the player operates the start lever 41 once, different random numbers are written to the three latch registers 407 to 409, respectively. The control IC 148 uses the two random numbers to determine whether the winning combination is in the non-BB state or not, and uses one remaining random number to perform the continuous lottery for the AT state ST3. The description of the same configuration as that of the fourth embodiment is basically omitted.

  First, the configuration of the hard random number circuit 146 in the present embodiment will be described with reference to FIG. FIG. 61 is a block diagram for describing a configuration of hard random number circuit 146. Referring to FIG. In the following, differences from the configuration of the hard random number circuit 146 (FIG. 39) in the fourth embodiment will be described.

  As shown in FIG. 61, the hard random number circuit 146 includes a control circuit 405, latch registers 407 to 409, and an update circuit 411. The control circuit 405 includes a CPU 406 that operates using a program. The CPU 406 is referred to as a control CPU 406. The control side CPU 406 has a ROM 115 storing a program for executing a management operation (FIG. 62) described later, a RAM 116 for temporarily storing information, and a detection signal SG2 output from the start detection sensor 41a. An input terminal TB1 being input and two output terminals TB8 and TB9 for outputting latch signals which are pulse signals at two different timings are provided.

  Further, as shown in FIG. 61, the hard random number circuit 146 includes, as random number generation means, an update circuit 411 for updating the random numbers used in the winning / not determining of the winning combination, the transition lottery L1 and the continuous lottery. Here, the continuous lottery is a lottery for determining whether or not the AT state ST3 is continued when the AT state counter becomes "0" in the AT state ST3.

  The update circuit 411 includes a first clock circuit 414 that outputs a first clock signal that is a clock signal of a predetermined frequency, and a second clock signal that is a clock signal that has a frequency different from that of the first clock circuit. A clock circuit 415, a first random number counter 416 whose random number is updated at a predetermined interval, and a second random number counter 417 updated at an interval different from the first random number counter 416 are provided. Here, the frequency of the first clock signal output from the first clock circuit 414 is 16 MHz, and the frequency of the second clock signal output from the second clock circuit 415 is 12 MHz. Each of the two random number counters 416 and 417 is composed of 16 random number counter D-FFs, and can store a 16-digit binary number.

  Specifically, the numerical range of the random numbers that can be stored in the two random number counters 416 and 417 is set to “1 to 65535”. Here, the sixteen D-FFs constituting the first random number counter 416 are designated as the first random number counter D-FF, and the sixteen D-FFs constituting the second random number counter 417 are 2 Set as D-FF for random number counter.

  The update circuit 411 updates the random number stored in the first random number counter 416 in synchronization with the rising of the first clock signal output from the first clock circuit 414. In detail, the update circuit 411 includes a first random number generator (not shown). The first random number generator has the same configuration as the random number generation circuit 106 (FIG. 6) of the first embodiment. The first random number generator receives the inverted first clock signal generated by inverting the first clock signal. Therefore, in the first random number generator, the random numbers are updated at intervals of 62.5 nsec. The random numbers updated by the first random number generator are the same M-sequence random numbers as the random numbers updated by the random number generation circuit 106 in the first embodiment. Since numerical value information of random numbers output from the first random number generator is input to the first random number counter 416, the random numbers stored in the first random number counter 416 are updated at an interval of 62.5 nsec. The update period is sufficiently shorter than the execution period of the timer interrupt process in the control IC 148.

  Further, the updating circuit 411 updates the random number stored in the second random number counter 417 in synchronization with the rising of the second clock signal output from the second clock circuit 415. In detail, the updating circuit 411 includes a second random number generator (not shown). The inverted second clock signal generated by inverting the second clock signal is input to the second random number generator. In the second random number generator, “1” is added to the current random number stored in the second random number generator in synchronization with the rising of the inverted second clock signal to generate the next random number. The second random number generator is a loop counter that returns to “0” when the random number reaches “65535” which is the upper limit value. Since numerical value information of random numbers output from the second random number generator is input to the second random number counter 417, the random numbers stored in the second random number counter 417 are updated at intervals of 83.3 nsec. The update period is sufficiently shorter than the execution period of the timer interrupt process in the control IC 148.

  The random numbers stored in the first random number counter 416 and the random numbers stored in the second random number counter 417 are clocks output from clock circuits 414 and 415 different from the clock circuit provided in the control IC 148 Since the update is performed in synchronization with the rising of the signal, the timer interrupt process of the control IC 148 is updated asynchronously. The random number stored in the first random number counter 416 may be updated in synchronization with the fall of the first clock signal. Further, the random number stored in the second random number counter 417 may be updated in synchronization with the fall of the second clock signal.

  The random numbers updated in the first random number counter 416 are M-sequence random numbers, and each time the update timing comes, the next random number is calculated based on the currently stored random numbers. On the other hand, the random number updated in the second random number counter 417 is different from the M-sequence random number. The second random number counter 417 adds “1” to the current random number each time the update timing comes, and calculates a new random number. When the random number stored in the second random number counter 417 reaches the maximum value (“65535”), “0” is cleared.

  The combination of the random number updated by the first random number counter 416 and the random number updated by the second random number counter 417 is not limited to the above combination. For example, the random numbers updated by the first random number counter 416 and the random numbers updated by the second random number counter 417 may be the same M-sequence random number. Also in this case, since the clock signal supplied to the first random number counter 416 by the first clock circuit 414 and the clock signal supplied to the second random number counter 417 by the second clock circuit 415 are different, the first random number and the second random number The random number and the third random number can be updated in different modes.

  As shown in FIG. 61, the hard random number circuit 146 includes a first latch register 407 and a second latch register 408 as registers to which numerical value information of random numbers updated by the first random number counter 416 is written. A third latch register 409 is provided as a register to which numerical value information of random numbers updated by the second random number counter 417 is written.

  The first latch register 407 in the present embodiment has the same configuration as the first latch register 407 (FIG. 39) in the fourth embodiment, and the second latch register 408 in the present embodiment has the same configuration as in the fourth embodiment. The configuration is the same as that of the second latch register 408. That is, the first latch register 407 is composed of 16 first latch D-FFs 407a to 407p (FIG. 39), and the second latch register 408 is composed of 16 second latch D-FFs 408a to 408p (FIG. Fig. 39). Further, as shown in FIG. 61, the third latch register 409 is composed of sixteen third latch D-FFs 409a to 409p.

  The D terminals of the first latch D-FFs 407 a to 407 p are connected to the Q terminal of the first random number counter D-FF constituting the first random number counter 416. Specifically, the first latch register 407 stores the Q terminal of the first random number counter D-FF storing the nth digit numerical information in the 16-digit binary number stored in the first random number counter 416 16. It is connected to the D terminal of the first latch D-FFs 407a to 407p for storing the numerical information of the nth digit in the binary number of the digit.

  The Q terminals of the first latch D-FFs 407a to 407p are connected to the input terminal TA8 (FIG. 61) of the control IC 148. Therefore, the numerical value information of the random number stored in the first latch register 407 is output to the input terminal TA8 of the control IC 148. Here, numerical value information of the random number stored in the first latch register 407 is used as numerical value information of the first random number.

  Also, the D terminals of the third latch register D-FFs 409 a to 409 p (FIG. 61) are connected to the Q terminals of the second random number counter D-FFs constituting the second random number counter 417. Specifically, the third latch register 409 stores the Q terminal of the second random number counter D-FF storing the nth digit numerical information in the 16 digit binary number stored in the second random number counter 417 16 It is connected to the D terminal of the third latch register D-FF 409a to 409p which stores the numerical information of the nth digit in the binary number of the digit.

  The Q terminals of the third latch D-FFs 409a to 409p are connected to the input terminal TA10 of the control IC 148. Therefore, numerical value information of the random number stored in the third latch register 409 is output to the input terminal TA10 of the control IC 148. Here, numerical value information of the random number stored in the third latch register 409 is taken as numerical value information of the third random number.

  The CLK terminals of the first latch D-FFs 407 a to 407 p and the CLK terminals of the third latch D-FFs 409 a to 409 p are connected to the output terminal TB 8 of the control side CPU 406. Specifically, one signal line from the output terminal TB 8 of the control side CPU 406 is branched into two at a branch point on the hard random number circuit 146. One signal line after the branching is branched into 16 lines on the hard random number circuit 146 and connected to the CLK terminals of the first latch D-FFs 407 a to 407 p. The other signal line after branching is branched on the hard random number circuit 146 and connected to the CLK terminals of the third latch D-FFs 409a to 409p.

  The signal line that is output from the Q terminal of the first random number counter D-FF that configures the first random number counter 416 and is connected to the D terminal of the first latch D-FF 407 a to 407 p is on the hard random number circuit 146. , And are also connected to the D terminals of the second latch D-FFs 408a to 408p. In detail, regarding the second latch register 408, the Q terminal of the first random number counter D-FF storing the nth digit numerical information in the 16-digit binary number stored in the first random number counter 416 is the second latch It is connected to the D terminals of second latch D-FFs 408 a to 408 p that store the numerical information of the n-th digit of the 16-digit binary number stored in the register 408.

  The Q terminals of the second latch D-FFs 408 a to 408 p are connected to the input terminal TA 9 of the control IC 148. Therefore, the numerical value information of the random number stored in the second latch register 408 is output to the input terminal TA9 of the control IC 148. Here, numerical value information of the random number stored in the second latch register 408 is taken as numerical value information of the second random number.

  The CLK terminals of the second latch D-FFs 408 a to 408 p are connected to the output terminal TB 9 of the control side CPU 406. Specifically, one signal line from the output terminal TB9 of the control side CPU 406 is branched into 16 on the hard random number circuit 146 and connected to the CLK terminals of the second latch D-FFs 408a to 408p.

  In the control side CPU 406 of this embodiment, the detection signal SG2 input to the input terminal TB1 of the control side CPU 406 rises from the LOW state to the HI state, and from the output terminal TB8 at the timing when the HI state is maintained for 12.8 μs. A latch signal which is a pulse signal is transmitted to the first latch register 407 and the third latch register 409. Further, the control side CPU 406 of this embodiment outputs the detection signal SG2 input to the input terminal TB1 of the control side CPU 406 at the timing when the LOW state is maintained at 12.8 μs from the HI state falling to the LOW state. A latch signal which is a pulse signal is transmitted from the terminal TB 9 to the second latch register 408.

  The control side CPU 406 counts the time for which the detection signal SG2 input to the input terminal TB1 is maintained in the HI state and the time for which the detection signal SG2 is maintained in the LOW state by the timer counter. The timer counter counts time in 0.1 μs units. When 12.8 μs has elapsed from the start of counting, or when the detection signal SG2 is inverted before 12.8 μs elapses from the start of counting, counting of time by the timer counter is stopped and the timer counter is reset.

  Thereby, the numerical value information of the random number stored in the first random number counter 416 is written to the first latch register 407 as the numerical value information of the first random number at the rising timing of the detection signal SG2, and the timing of the rising of the detection signal SG2. The numerical value information of the random number stored in the second random number counter 417 is written to the third latch register 409 as numerical value information of the third random number.

  The timing when the numerical information of the first random number is written to the first latch register 407 and the timing when the numerical information of the third random number is written to the third latch register 409 are the same. However, the type of the random number updated by the first random number counter 416 and the type of the random number updated by the second random number counter 417 are different. Therefore, the third random number is a random number different from the first random number.

  Further, at the falling timing of the detection signal SG2, numerical value information of the random number stored in the first random number counter 416 is written to the second latch register 408 as numerical value information of the second random number. The timing at which the numerical value information of the second random number is written to the second latch register 408, the timing at which the numerical value information on the first random number is written to the first latch register 407, and the numerical information on the third random number is written to the third latch register 409 It is different from the timing. The second random number is a random number that is not synchronized with the first random number and the third random number because the time interval from the timing when the detection signal SG2 rises to the timing when the detection signal SG2 falls is an indeterminate interval that changes with human operation. .

  The control IC 148 performs the first process input to the input terminal TA8 of the control IC 148 in the normal process (FIG. 42) immediately after the first start command flag 144g is set to “1” in the start command setting process (FIG. 41). The numerical value information of the random number and the numerical value information of the third random number input to the input terminal TA10 are acquired. Then, "1" is set to the second start command flag 144h in the start command setting process after the next time, and in the normal process immediately thereafter, the numerical information of the second random number input to the input terminal TA9 of the control IC 148 is acquired Do. Thus, the control IC 148 can obtain a third random number different from the first random number and the second random number, in addition to the first random number and the second random number.

  Next, the management operation executed by the control side CPU 406 of this embodiment will be described with reference to the flowchart of FIG. In steps S3001 to S3008, the same processes as steps S701 to S707 and step S709 are performed. Specifically, when the detection signal SG2 input to the input terminal TB1 of the control side CPU 406 is in the LOW state (step S3001), the detection signal SG2 is in the LOW state (step S3001: YES). To wait until the detection signal SG2 is in the HI state (step S3002). When the detection signal SG2 is in the HI state (step S3002: YES), the timer counter is used to start counting the time during which the HI state is maintained (step S3003).

  If the duration of the HI state of the detection signal SG2 is less than 12.8 μs (step S3004: NO), the timer counter stops counting and waits until the detection signal SG2 becomes the HI state again. Also, when the HI state of the detection signal SG2 is continued for 12.8 μs or more (step S3004: YES, step S3005: YES), the timer counter stops counting time, and the output terminal TB8 of the control side CPU 406 A latch signal is transmitted to the first latch register 407 and the third latch register 409 (step S3008).

  Thereafter, in step S3009, it is determined whether or not the detection signal SG2 input to the input terminal TB1 of the control side CPU 406 is in the LOW state, and if the detection signal SG2 is in the HI state (step S3009: NO), It waits for the detection signal SG2 to be in the LOW state. When the detection signal SG2 is in the LOW state (step S3009: YES), the timer counter is used in step S3010 to start counting the time during which the LOW state is continued.

  In the following step S3011, it is determined whether or not the detection signal SG2 is in the LOW state, and if it is in the LOW state (step S3011: YES), 12.8 μs has elapsed since the fall of the detection signal SG2 in step S3012. It is determined whether it is or not. Then, if 12.8 μs has not elapsed from the fall of the detection signal SG2 (step S3012: NO), the process returns to step S3011. If it is determined in step S3011 that the detection signal SG2 is in the HI state (step S3011: NO), counting of time by the timer counter is stopped in step S3013, and the process returns to step S3009.

  If 12.8 μs have elapsed since the detection signal SG2 input to the input terminal TB1 of the control side CPU 406 has fallen to LOW in step S3012 (step S3012: YES), the process proceeds to step S3014. Stop counting time by the timer counter. In the subsequent step S3015, a latch signal is transmitted from the output terminal TB9 to the second latch register 408, and the process returns to step S3001.

  As described above, the timing at which the detection signal SG2 input to the input terminal TB1 of the control CPU 406, which operates using the program, rises to the HI state and the HI state is maintained for 12.8 μs, By transmitting a latch signal at the timing when the detection signal SG2 falls to the LOW state and the LOW state is maintained for 12.8 μs, numerical information of unsynchronized random numbers available to the control IC 148 can be increased. it can. Also, by outputting from the output terminal TB8 of the control side CPU 406 to the first latch register 407 and the third latch register 409, the numerical information of the random numbers written to the latch registers 407 to 409 triggered by the start of the operation of the start lever 41 It can be increased.

  In the present embodiment, the control IC 148 performs the same lottery process as the lottery process (FIG. 43) in the fourth embodiment, using the first random number and the third random number. Specifically, the first random number is used to determine whether the winning combination is successful or not. If the determination on the part's validity is made in the non-BB state and the first cherry is won, the third random number is used for the determination on whether or not the second cherry has been won. In addition, when the game state is changed from the normal game state ST1 to the BB state ST2, the third random number is also used for the transition lottery L1 for determining whether to shift to the AT state ST3 in the last game of the BB state ST2. Be

  Next, in the present embodiment, the lottery performed using the second random number will be described. In the present embodiment, when the AT state counter becomes “0” in the AT state ST3, a continuous lottery for determining whether to continue the AT state ST3 is performed. The second random number is used in the continuous lottery performed in the AT state management process.

  The management processing of the AT state executed by the control IC 148 will be described with reference to FIG. The management process of the AT state is a process executed in step S1906 of the process (FIG. 46) at the end of the game.

  First, in step S3101, it is determined whether the value of the AT state counter is "0". If the value of the AT state counter is not "0", it means that the current AT state ST3. If it is in the AT state (step S3101: NO), it is determined in step S3102 whether the value of the preparation state flag is "0". If the value of the preparation state flag is "0" (step S3102: YES), it means that it is the base state ST32 of the AT state ST3. Therefore, the value set in the AT state counter in step S3103 Subtract "1" from.

  After making a negative determination in step S3102, or after performing subtraction processing in step S3103, in step S3104, it is determined whether or not either the first cherry winning or the second cherry winning is established. If the first cherry winning is not established and the second cherry winning is not established (step S3104: NO), the value of the AT state counter is "0" at step S3105. It is determined whether or not If the value of the AT state counter is not "0" (step S3105: NO), this means that the base state ST32 of the AT state ST3 is continuing or the preparation state ST31, so the main AT state is as it is. End the management process.

  Whether the AT state ST3 is continued in step S3106 and step S3107 if the value of the AT state counter is "0" and it is the timing when the base state ST32 of the AT state ST3 ends (step S3105: YES) Execute a continuous lottery to determine whether or not. In the continuation lottery, the AT state ST3 is continued when it is won, and when it is not won, the AT state ST3 is ended and it becomes the normal gaming state ST1.

  In step S3106, a second random number is set to the third determination value DV3, and "13107" is added to the third determination value DV3 to calculate a new third determination value DV3. In the following step S3107, it is determined whether or not the third determination value DV3 calculated in step S3105 exceeds "65535". If the third judgment value DV3 exceeds "65535" (step S3107: YES), it means that the player has won the continuation lottery, so "30" is added to the AT state counter in step S3108, and the step is performed. At S3109, the continuation command is transmitted to sub side MPU 152, and this AT state management processing is ended.

  The sub MPU 152 that has received the continuation command executes effect setting processing at the time of continuation. In the effect setting process at the time of continuation, data setting is performed in order to notify the player using the upper lamp 64, the speaker 65 and the image display device 66 that the winning in the continuation lottery is made.

  If the third determination value DV3 does not exceed “65535” in step S3107, an AT state end command is transmitted to the sub MPU 152 in step S3120, and the present AT state management process is ended. In the continuation lottery, the probability of being continuously elected is 1/5.

  If it is determined in step S3104 that the first cherry winning combination has been established or the second cherry winning combination has been established, addition processing of the AT state counter is performed in step S3121 to execute the main AT End the state management process. In the AT state addition process, the process of step S2010 to step S2014 in the AT state management process (FIG. 48) of the fourth embodiment is executed.

  Specifically, when the first cherry winning is established (step S2010: YES), "30" is added to the AT state counter (step S2011), and the second cherry winning is realized. (Step S2012: YES), "300" is added to the AT state counter (step S2013). Then, after addition is performed to the AT state counter, an addition command is transmitted to the sub MPU 152 (step S2014), and the addition process of the present AT state counter is ended.

  Returning to the description of the AT state management process (FIG. 63), that the value of the AT state counter is “0” in step S3101 means that the current state is the non-AT state. In this case, the AT state start process is performed in step S3122, and the present AT state management process is ended. In the AT state start process, the process of step S2002 to step S2007 in the AT state management process (FIG. 48) of the fourth embodiment is executed.

  Specifically, when the first cherry winning is established (step S2002: YES), "30" is set in the AT state counter (step S2003). Then, the preparation state flag is set to "1" (step S2006), an AT state start command is transmitted to the sub MPU 152 (step S2007), and this AT state start processing is ended. If the second cherry winning is achieved (step S2002: NO, step S2004: YES), "300" is set in the AT state counter (step S2005). Then, the preparation state flag is set to "1" (step S2006), an AT state start command is transmitted to the sub MPU 152 (step S2007), and this AT state start processing is ended. If the condition for becoming the AT state ST3 is not satisfied (step S2002: NO, step S2004: NO), the present AT state start process is ended as it is.

  As described above, the method of generating random numbers in the first random number counter 416 connected to the first latch register 407 is the same as the method of generating random numbers in the second random number counter 417 connected to the third latch register 409 It is different. Further, the time interval at which the first random number counter 416 updates the random number is different from the time interval at which the second random number counter 417 updates the random number. Therefore, even if the timing for acquiring the first random number and the timing for acquiring the third random number are the same, the third random number can be different from the first random number. In this way, by performing the winning or losing lottery of the role using two random numbers updated in different cycles, it can be a lottery based on highly uniform random numbers, it is possible to improve the interest of the game .

Eighth Embodiment
In the present embodiment, in the pachinko machine (not shown), the control IC 271 (FIG. 66) is an input of the control IC 271 under the condition that “1” is set in the latched status 113 (FIG. 66). The jackpot random number input to the terminal TA13 (FIG. 66) is acquired. Hereinafter, a pachinko gaming machine (hereinafter, referred to as a "pachinko machine"), which is a type of gaming machine, will be described based on the drawings.

  First, the configuration of the game board 224 provided in the pachinko machine of the present embodiment will be described based on FIG. FIG. 64 is a front view of the game board 224. FIG.

  The inner rail portion 225 and the outer rail portion 226 are attached to the game board 224 so as to partition a part of the outer edge of the game area PA, and the inner rail portion 225 and the outer rail portion 226 guide means Guide rails are configured as. Here, a game ball firing mechanism (not shown) for firing the game ball toward the game space PA is installed on the lower right side of the game space PA, and the game ball fired from the game ball firing mechanism is an induction rail The user is guided to the top of the game area PA by the

  The game board 224 is formed with a plurality of large and small openings penetrating in the front-rear direction. In each opening, a general winning opening 231, a special electric winning device 232, a first operation opening 233, a second opening 234, a through gate 235, a variable display unit 236, a special drawing unit 237, a drawing unit 238 and the like are provided. ing.

  Even if the ball enters the through gate 235, the payout of the game ball is not executed. On the other hand, when entering the general winning opening 231, the special power winning device 232, the first operation opening 233, and the second operation opening 234, a predetermined number of game balls are paid out. Specifically, with respect to the number of winning balls, when entering the first operation port 233 occurs or when entering the second operation port 234, three winning balls are paid out. When the entry to the general winning opening 231 occurs, the payout of 10 winning balls is executed, and when the entry to the special electric winning device 232 occurs, the payout of 15 winning balls is To be executed.

  The number of winning balls is arbitrary. For example, although the number of winning balls in the second operation port 234 is smaller than that in the first operating port 233, the number of winning balls may be different from the above. The second operating port 234 may have a larger number of winning balls than the first operating port 233.

  In addition, an out port 224a is provided at the lowermost portion of the game board 224, and the game balls that did not enter the various winning ports etc. are discharged from the game area PA through the out port 224a. Further, on the game board 224, a large number of nails 224b are implanted to appropriately disperse and adjust the falling direction of the game balls, and various members such as a windmill are disposed.

  Here, entering the ball means that the gaming ball passes through the predetermined opening, and not only the aspect of being ejected from the gaming area PA after passing through the opening, but also from the gaming area PA after passing through the opening Also included is an aspect of continuing the flow of the game area PA without being discharged. However, in the following description, the general winning opening 231, the special electric winning device 232, the first operation opening 233, the second operation opening 234, and the through gate 235 are clearly distinguished from entering the gaming ball into the out opening 224a. The entry of the game ball to the is also expressed as a winning.

  The first operating port 233 and the second operating port 234 are unitized as an operating port device and installed on the game board 224. The first operating port 233 and the second operating port 234 are both open upward. Further, both operation ports 233 and 234 are aligned in the vertical direction such that the first operation port 233 is at the upper side. The second operating port 234 is provided with a general-purpose utility product 234a as a guide piece consisting of a pair of left and right movable pieces. In the closed state of the universal power product 234a, the gaming ball can not win a prize in the second operation port 234, and a winning in the second operation port 234 becomes possible by the universal power object 234a being opened.

  Here, for the first operation port 233 and the second operation port 234, one operation port winning detection sensor that is common to both operation ports 233 and 234 is provided. The entering game ball is detected by the operation port winning detection sensor, and the game ball entering the second operation port 234 is also detected by the operation port winning detection sensor.

  With reference to FIG. 65, a configuration for detecting a gaming ball with operation hole winning detection sensor 245 provided commonly to both operation openings 233 and 234 will be described. FIG. 65 is a longitudinal cross-sectional view of the operation port collection passage 246 for explaining the operation port collection passage 246 and the operation port winning detection sensor 245. FIG.

  A passage area 246a through which gaming balls can pass is formed in the operation port collection passage 246. The passage region 246a extends in the longitudinal direction. The passage area 246a allows passage of one game ball, but the passage width is set such that passage of a plurality of game balls is not performed in the same position.

  The operation opening prize detection sensor 245 is provided at an intermediate position of the passage area 246a, and detects a game ball passing through the passage area 246a. The operation opening winning detection sensor 245 is configured of a proximity sensor of a magnetic detection type, and includes a detection unit 245a for detecting the passage of a game ball. The detection part 245a is formed with a through hole 245b penetrating in the thickness direction of the operation hole winning detection sensor 245 as a passage part or a detection area. The through holes 245 b are formed such that the cross section in the direction orthogonal to the penetration direction is circular. Further, the through holes 245 b are formed to extend in the same direction over the whole, and the diameters of the holes are the same or substantially the same over the whole. The diameter of the hole is 11.5 mm, which is slightly larger than the diameter 11.0 mm of the gaming ball. The operation hole winning detection sensor 245 is installed such that the axis of the through hole 245b is on the same straight line as the axis of the passage area 246a. As a result, the gaming ball falling in the passage area 246a passes through the through hole 245b.

  The operation hole winning detection sensor 245 outputs a detection signal SG4 whose signal form changes as the gaming ball passes through the through hole 245b. In detail, a detection coil (not shown) is built in the detection section 245a along the outer peripheral side of the through hole 245b, and further, an oscillation circuit having a detection coil as a part of the operation hole winning detection sensor 245 And a sensor substrate (not shown) having a detection circuit, a comparator circuit, and an output circuit. Thereby, when the gaming ball is present in the through hole 245b, the magnetic flux penetrates the detection coil and the oscillation is stopped.

  The operation port winning detection sensor 245 changes the signal form of the detection signal SG4 based on the stop of the oscillation. In detail, in the situation where the gaming ball is not present in the through hole 245b (oscillating situation), the operation opening prize detection sensor 245 outputs a LOW signal which is a non-detection corresponding signal as the detection signal SG4. Then, in a situation where the gaming ball is present in the through hole 245b (a situation where the oscillation is stopped), the operation opening prize detection sensor 245 outputs an HI signal which is a detection corresponding signal as the detection signal SG4. That is, when the gaming ball passes through the through hole 245b, the detection signal SG4 rises. By grasping the rise, it becomes possible to detect the winning of the game ball.

  In the situation where no gaming ball is present in the through hole 245b, the HI signal which is a non-detection correspondence signal is output, and in the situation where the gaming ball is present in the through hole 245b, the LOW signal is a detection correspondence signal. It may be configured to output. Further, the winning of the game ball may be detected by grasping the falling of the detection signal SG4.

  Referring back to FIG. 64, a through gate 235 is provided upstream of the second operation port 234 in the flow direction of the gaming ball. The through gate 235 has a through hole (not shown) penetrating in the longitudinal direction, and the gaming ball that has won the through gate 235 flows down the gaming area PA after winning. Thus, it is possible for the game ball winning the through gate 235 to win the second operation opening 234.

  Based on the winning on the through gate 235, the utility power item 234a of the second operation port 234 is switched from the closed state to the open state. Specifically, the internal lottery is performed triggered by the winning of the through gate 235, and a common drawing display of the drawing unit 238 provided in the lower right corner which is an area where the game ball does not pass in the game area PA The variation display of the pattern is performed in the portion 238a. Then, when the result of the internal lottery is the electronic combination open winning, the stop result corresponding to the result is displayed, and the variable display of the common view display portion 238a is ended, the electronic combination is shifted to the electronic combination open state. In the open state, the general electric utility 234a is open in a predetermined manner.

  The common view display unit 238a is configured of a segment display in which a plurality of segment light emitting units are arranged in a predetermined manner. Further, in the common drawing unit 238, a common drawing suspension display part 238b is provided at a position adjacent to the common drawing display part 238a. The number of game balls winning through the through gate 235 is held up to a maximum of four, and the number of held balls is displayed by lighting of the common drawing hold display portion 238b.

  A lottery is triggered by winning of the first operation port 233 or the second operation port 234 as a trigger. Then, the lottery result is clearly indicated through display effects in the special display unit 237 and the symbol display device 241 of the variable display unit 236.

  More specifically, the special drawing unit 237 is provided with a special drawing display unit 237a. The display area of the special view display portion 237a is narrower than the display surface 241a of the symbol display device 241. In the special view display unit 237a, the winning of the first operation opening 233 or the winning of the second operation opening 234 is a trigger, and a lottery is performed, thereby performing variable display of symbols or predetermined display. Then, the result corresponding to the lottery result is displayed. In addition, although the special view display part 237a is comprised by the segment display which a some segment light emission part is arranged in a predetermined | prescribed aspect, it is not limited to this, A liquid crystal display device, an organic electroluminescence display , Or a display device such as a CRT or dot matrix display. In addition, as the design displayed in the special view display portion 237a, a configuration in which a plurality of types of characters are displayed, a configuration in which a plurality of types of symbols are displayed, a configuration in which a plurality of types of characters are displayed, or a plurality of colors May be displayed.

  In the special drawing unit 237, a special drawing reservation display unit 237b is provided at a position adjacent to the special drawing display unit 237a. The number of game balls played in the first operation opening 233 or the second operation opening 234 is held up to a maximum of four, and the number of holdings is displayed by turning on the special view holding display unit 237b.

  In detail about the symbol display device 241, the symbol display device 241 is configured as a liquid crystal display device provided with a liquid crystal display, and the display content is controlled by a display control device described later. The symbol display device 241 is not limited to a liquid crystal display device, and may be another display device having a display screen such as a plasma display device, an organic EL display device, or a CRT, and is a dot matrix display. May be

  In the symbol display device 241, when variation display or predetermined display of the symbol is performed in the special view display portion 237a based on the winning of the first operation opening 233 or the winning of the second operation opening 234, the symbol is displayed accordingly. Variable display or predetermined display is performed. In the symbol display device 241, not only display effects triggered by winning in the first operation port 233 or the second operation port 234, but also display effects in the open / close execution mode described later, etc. Is done.

  When a big hit is won in the winning lottery based on the winning on the first operation port 233 or the winning on the second operation port 234, transition to the open / close execution mode in which winning on the special power winning device 232 is possible. The special power winning device 232 has a not-shown large winning opening communicating with the back side of the game board 224, and also has an open / close door 232a for opening and closing the large winning opening. The open / close door 232a is disposed in either the closed state or the open state. Specifically, the open / close door 232a is normally in a closed state in which the game ball can not be won, and is switched to an open state in which the game ball can be won if the shift to the open / close execution mode is won in the internal lottery It has become. By the way, the open / close execution mode is a mode in which transition is made when a hit result is obtained. In the closed state, although it is not impossible to win, it may be in a state in which the winning is less likely to occur than in the open state.

<Structure related to lottery using hard random numbers>
Next, the configuration of the main control board 261 in the pachinko machine of the present embodiment will be described using the block diagram of FIG.

  The main control board 261 is provided with an MPU 262. Further, the MPU 262 includes a control IC 271 and a hard random number circuit 267. The control IC 271 is a CPU that executes processing using a program, and has a ROM 263 storing a program for executing timer interrupt processing (FIG. 68) and the like, and an area for temporarily storing information. And the RAM 264. The control IC 271 also includes input terminals TA11 to TA13 and output terminals TA14 and TA15.

  Also, as shown in FIG. 66, the hard random number circuit 267 includes an updating circuit 101 for updating the big hit random number, a latch register 102 where the big hit random number updated by the updating circuit 101 is written, and a detection signal SG4. And a control circuit 303 capable of grasping the timing at which the winning of the first operation port 233 or the second operation port 234 has occurred.

  The control circuit 303 includes a CPU 304 that executes processing using a program. Here, the CPU 304 included in the control circuit 303 is referred to as a control side CPU 304. The control side CPU 304 has a ROM 305 storing a program for executing a management operation, a RAM 306 having an area for temporarily storing information, input terminals TB11, TB12 and TB15, and an output terminal TB13, It has TB14.

  Here, the management operation executed by the control side CPU 304 is the same as the management operation (FIG. 19) of the first embodiment. Specifically, the rising of the detection signal SG4 input to the control CPU 304 from the LOW state to the HI state is detected, and the HI state of the detection signal SG4 is maintained until 12.8 μs elapses from the timing of the detection. Under the condition that it is determined, the latch signal which is a pulse signal is transmitted to the latch register 102, and “1” is set to the latched status 113. Details of the management operation in the present embodiment will be described later.

  Next, the connection between the operation opening winning detection sensor 245 and the control IC 271 and the connection between the operation opening detection sensor 245 and the hard random number circuit 267 will be described. As shown in FIG. 66, one signal line coming out of the operation hole winning detection sensor 245 is branched into two at a branch point 311 on the main control board 261. One of the signal lines is connected to the input terminal TA11 of the control IC 271, and the other of the signal lines is connected to the input terminal TB11 of the control side CPU 304 constituting the hard random number circuit 267. For this reason, when noise mixes in one signal line after branching, the situation where the influence of the said noise reaches the other can be avoided.

  Next, the update circuit 101 will be described. The update circuit 101 has the same configuration as the update circuit 101 (FIG. 6) of the first embodiment. Specifically, the update circuit 101 includes a clock circuit 104, a random number generation circuit 106, and a random number counter 105. Similar to the clock circuit 104 of the first embodiment, the clock circuit 104 outputs a clock signal of a predetermined frequency (for example, 16 MHz). The update circuit 101 operates based on the clock signal output from the clock circuit 104 in the update circuit 101. On the other hand, the control IC 271 operates based on a clock signal output from a clock circuit (not shown) in the control IC 271. Therefore, the update timing of the random number in the update circuit 101 is not influenced by the process executed by the control IC 271.

  Further, the random number counter 105 is configured of 16 random number counter D-FFs 105a to 105p (FIG. 6) as in the random number counter 105 of the first embodiment, and has a 2-byte storage area. ing. The random number counter 105 stores jackpot random numbers of “1” to “65535”.

  The clock signal output from the clock circuit 104 is input to the CLK terminals of the random number counter D-FFs 105 a to 105 p. Specifically, the signal line output from the clock circuit 104 is branched into 16 at the branch point, and connected to the CLK terminals of the 16 random number counter D-FFs 105 a to 105 p.

  In the updating circuit 101, the random number stored in the random number counter 105 is updated in synchronization with the rising of the clock signal output from the clock circuit 104. The update interval of the random number is the cycle of the clock signal, and is 62.5 nsec in detail. As described above, since the execution cycle of the timer interrupt process executed by the control IC 271 is 4 msec, the update interval of the random number is sufficiently shorter than the execution cycle of the timer interrupt process. The numerical information output from the Q terminals of the random number counter D-FFs 105 a to 105 p is updated at a cycle of 62.5 nsec.

  Here, the random number stored in the random number counter 105 is a 16-digit binary number. The random numbers updated by the update circuit 101 are M-sequence random numbers. The M-sequence random number is a pseudo random number having a cycle. The cycle of the M-sequence random number updated by the update circuit 101 is “65535”. In the M-sequence random number, since each of the numbers “1” to “65535” appears once in one cycle, the probability of being a big hit can be set according to the number of pieces of numerical information used as a big hit random number.

  The random number updated by the random number counter 105 is not limited to the M-sequence random number. For example, each time the update circuit 101 reaches the update timing, “1” is added to the random number stored in the random number counter 105, and the value of the random number counter 105 becomes “65535”. It may be cleared and "1" may be added again. The point is that the configuration in which the jackpot determination result of the jackpot performed using the jackpot random number is not biased to a specific result.

  Next, the latch register 102 in which the numerical value information of the random number stored in the random number counter 105 of the update circuit 101 is written will be described. The latch register 102 has the same configuration as the latch register 102 (FIG. 6) of the first embodiment described above, and is configured of sixteen latch register D-FFs 102a to 102p (FIG. 6).

  The D terminal of the latch register D-FFs 102a to 102p is connected to a signal line coming out of the Q terminal of the random number counter D-FFs 105a to 105p. Specifically, numerical value information stored in the random number counter 105 of the update circuit 101 and numerical value information stored in the latch register 102 are both 16-digit binary numbers. The Q terminals of the random number counter D-FFs 105a to 105p in which the numerical value information of the nth digit is stored in the random number counter 105 are D of latch registers D-FFs 102a to 102p in which the numerical information of the nth digit is stored in the latch register 102. It is connected to the terminal. Here, n is a natural number of 1 to 16.

  The CLK terminals of the latch register D-FFs 102 a to 102 p are connected to the output terminal TB 14 of the control side CPU 304 by a signal line. In detail, one signal line from the output terminal TB14 of the control side CPU 304 is branched into 16 and enters the CLK terminal of each of the latch registers D-FFs 102a to 102p. The Q terminals of the latch register D-FFs 102 a to 102 p are connected to the input terminal TA 13 of the control IC 271.

  Further, the control side CPU 304 latches from the output terminal TB14 when the detection signal SG4 inputted to the control side CPU 304 rises from the LOW state to the HI state and the HI state is maintained for a predetermined time (12.8 μs). A latch signal is output to the CLK terminals of the register D-FFs 102a to 102p.

  Therefore, the control CPU 304 transmits a latch signal from the output terminal TB14 to the CLK terminal of the latch register D-FFs 102a to 102p, so that the numerical information of the big hit random number stored in the random number counter 105 is the latch register 102. The numerical information of the jackpot random number written in the latch register 102 is output from the Q terminal of the latch register D-FFs 102 a to 102 p to the input terminal TA 13 of the control IC 271.

  Next, the latched status 113 will be described. As shown in FIG. 66, the control circuit 303 has a latched status 113 in which “1” is set at the timing when the random number stored in the random number counter 105 is written to the latch register 102. The latched status 113 in this embodiment has the same configuration as the latched status 113 (FIG. 6) of the first embodiment described above, and includes a Q terminal 113a as an output terminal and a T terminal 113b as an input terminal. And a CLR terminal 113c.

  The T terminal 113 b of the latched status 113 is connected to the output terminal TB 13 of the control side CPU 304 by one signal line. The control side CPU 304 transmits the pulse signal to the T terminal 113 b of the latched status 113 in a state where the latched status 113 is set to “0”, and is outputted from the Q terminal 113 a of the latched status 113. Inverted signal to set latched status 113 to “1”.

  Specifically, the control side CPU 304 detects that the detection signal SG4 input to the input terminal TB11 of the control side CPU 304 has risen from the LOW state to the HI state, and the HI state continues for 12.8 μs or more. At the determined timing, a latch signal is transmitted from the output terminal TB14 to the CLK terminal of the latch register D-FFs 102a to 102p, and a pulse signal is transmitted from the output terminal TB13 to the T terminal 113b of the latched status 113 to perform latched status Set "1" to 113. Therefore, at the timing when the numerical value information of the random number stored in the random number counter 105 is written in the latch register 102, “1” is set in the latched status 113.

  Here, on the condition that “0” is set in the latched status 113, the control side CPU 304 raises the signal output from the output terminal TB13 to the T terminal 113b of the latched status 113. The signal output from the Q terminal 113a of the latched status 113 is inverted from the LOW state to the HI state. As a result, “1” is set in the latched status 113. When “1” is already set in the latched status 113, the control side CPU 304 does not transmit a pulse signal, so the state in which “1” is set in the latched status 113 is maintained.

  It is conceivable that “1” is set to the latched status 113 when noise enters the input terminal TB11 of the control side CPU 304. In this case, since the detection signal SG4 input to the control IC 271 does not rise, "1" is not set in the start possibility flag 144a. In this state, when a winning on the first operation port 233 or the second operation port 234 occurs, the numerical information stored in the latch register 102 is maintained while the "1" set in the latched status 113 is maintained. The jackpot random number corresponding to the winning of the operation port 233, 234 is updated to numerical information. As described above, the random number stored in the latch register 102 is updated when a winning on the operation port 233 or 234 occurs while the latched status 113 is set to “1”. It is possible to avoid the situation where the random number stored in the latch register 102 triggered by the noise is used for the determination of the success or failure of the winning combination.

  The signal line from the Q terminal 113a of the latched status 113 is branched into two on the control circuit 303, and one of the branched signal lines is connected to the input terminal TA12 of the control IC 271. The other of the branched signal lines is connected to the input terminal TB12 of the control side CPU 304. Therefore, the signal output from the Q terminal 113a of the latched status 113 is input to each of the input terminal TA12 of the control IC 271 and the input terminal TB12 of the control side CPU 304.

  The control IC 271 can determine whether “1” is set in the latched status 113 of the control circuit 303 by grasping the signal input to the input terminal TA12. Further, the control side CPU 304 can determine whether “1” is set to the latched status 113 by grasping the signal input to the input terminal TB12.

  Further, the CLR terminal 113c of the latched status 113 is connected to the output terminal TA14 of the control IC 271 through a single signal line. The control IC 271 can clear the latched status 113 to “0” by raising the signal output to the CLR terminal 113 c of the latched status 113 from the LOW state to the HI state.

  When the control side CPU 304 detects that the detection signal SG4 input to the input terminal TB11 of the control side CPU 304 has risen from the LOW state to the HI state, the HI state is 12.8 μs using the timer counter. It is determined whether or not it has been maintained. Specifically, the timer counter starts counting at the timing when the rising of the detection signal SG4 input to the input terminal TB11 of the control side CPU 304 from the LOW state to the HI state is detected. When counting is started, the timer counter counts time in units of 0.1 μs. If the HI state of the detection signal SG4 is not maintained until the timer counter has counted 12.8 μs, the timer counter is reset.

  Next, conditions for the control IC 271 to store the jackpot random number input to the input terminal TA13 of the control IC 271 will be described. The control IC 271 detects that the rising of the detection signal SG4 input to the control IC 271 is detected in the timer interrupt process (FIG. 68) executed in a 4 ms cycle, and the latched status 113 is set to "1". And the jackpot random number input to the input terminal TA13 of the control IC 271 is stored under the condition that the hold number and the hold number have not reached the upper limit number.

  The timing at which the winning of the operation openings 233 and 234 occurs is an arbitrary timing that is not influenced by the timing at which the timer interrupt process is performed in the control IC 271. Therefore, the timer interrupt process may be executed before 12.8 μs elapses after the detection signal SG4 input to the input terminal TB11 of the control side CPU 304 rises. At this time, the jackpot random number input to the input terminal TA13 of the control IC 271 is the previous jackpot random number. In this case, since the condition that “1” is set in the latched status 113 is not satisfied, the control IC 271 does not store the big hit random number in the timer interrupt process this time, and the next timer interrupt process It is determined again whether “1” is set to the latched status 113 again.

  The time from when the detection signal SG4 input to the input terminal TB11 of the control side CPU 304 rises to when “1” is set to the latched status 113 is 12.8 μs, and at intervals at which timer interrupt processing is performed It is a time shorter than a certain 4 ms. Therefore, when “1” is set to the latched status 113 at a timing 12.8 μs after the rise of the detection signal SG4 input to the input terminal TB11 of the control side CPU 304, detection by the control IC 271 In the timer interrupt process at the timing when the rising edge of the signal SG4 is detected or at the next timer interrupt process of the timer interrupt process executed at the timing, the latched status 113 is set to "1". It can be detected.

  The jackpot random number input to the input terminal TA13 of the control IC 271 is updated to the jackpot random number corresponding to the winning of the operation port 233, 234 at the timing when the latched status 113 is set to "1". By configuring the control IC 271 to acquire the jackpot random number on condition that “1” is set to the completed status 113, the control IC 271 is prevented from acquiring the jackpot random number before the update (previous jackpot random number) can do.

  The control IC 271 uses various numerical information including a big hit random number at the time of playing a game, determines the status of display, setting of display of the symbol display device 241, setting of display of the symbol display unit 238a, etc. I will do it. The configuration of various counters will be described with reference to FIG. FIG. 67 is an explanatory view showing the configuration of various counters.

  The control IC 271 is used for a jackpot random number used for lottery for jackpot occurrence, a jackpot type counter C2 used for determining a jackpot type, and a reach occurrence lottery when the symbol display device 241 is moved out during various lottery The reach random number counter C3 and the variation type counter CS for determining the display continuation time in the special view display unit 237a and the symbol display device 241 are used. Furthermore, the common power release counter C4 used in the lottery of whether or not the common power utility item 234a of the second operation port 234 is to be in the power open state is used. The jackpot random number is provided from the hard random number circuit 267 as already described, and the jackpot type counter C2, the reach random number counter C3, the fluctuation type counter CS, and the general charge release counter C4 are provided in the lottery counter area 284b of the RAM 264. There is.

  Each counter C2, C3, CS, C4 is a loop counter in which 1 is added to the previous value each time it is updated, and reaches a maximum value and returns to 0. These counters C2, C3, CS, C4 Updated at short intervals. The jackpot random number of the hard random number circuit 267, and each numerical information of the jackpot type counter C2 and the reach random number counter C3 are generated when a winning on the first operation opening 233 occurs or when a winning on the second operation opening 234 occurs. , And is stored in a pending storage area 284a provided in the RAM 264 as acquisition information storage means.

  The holding storage area 284a includes a holding area RE and an execution area AE. The reserve area RE includes a first reserve area RE1, a second reserve area RE2, a third reserve area RE3 and a fourth reserve area RE4, and the winning history to the first operation port 233 or the second operation port 234 At the same time, the jackpot random number and the numerical value information of the jackpot type counter C2 and the reach random number counter C3 are stored as hold information in any one of the hold areas RE1 to RE4.

  In this case, if winnings to the first operation port 233 or the second operation port 234 occur a plurality of times consecutively in the first holding area RE1 to the fourth holding area RE4, the first holding area RE1 → second Each numerical value information is stored in chronological order in the order of reserved area RE2, third reserved area RE3, and fourth reserved area RE4. By providing four reserve areas RE1 to RE4 as described above, the winning history of the game balls to the first operation opening 233 or the second operation opening 234 is reserved and stored up to a maximum of four. .

  The number that can be reserved and stored is not limited to four and is arbitrary, and may be other plural such as two, three, five or more, or may be singular.

  The execution area AE is an area for moving each numerical information stored in the first holding area RE1 of the holding area RE when the variable display of the special view display portion 237a is started, and the start of one game cycle is started On the occasion of the above, on the basis of various numerical value information stored in the execution area AE, a judgment of success or failure is performed.

  The respective counters will be described in detail.

  First, the common charge release counter C4 will be described. For example, the common charge release counter C4 is sequentially incremented by 1 within the range of 0 to 250, and returns to 0 after reaching the maximum value. The routine charge release counter C4 is periodically updated, and is stored in the hold position area 284c of the RAM 264 at the timing when the game ball wins the through gate 235. Then, at a predetermined timing, a lottery is performed to determine whether or not the general-purpose utility 234a is controlled to be in the open state by the value of the stored general-purpose charge release counter C4.

  In this pachinko machine, a plurality of types of support modes are set such that the modes of support by the commercial power utilities 234a differ from one another. Specifically, in the support mode, when compared with the situation where the firing of the game ball is continued in the same manner with respect to the game area, the commercial battery 234a of the second operation opening 234 is per unit time The high frequency support mode and the low frequency support mode are set such that the frequency of the open state is relatively high and low.

  In the high-frequency support mode and the low-frequency support mode, the probability of winning in the open position in the electric combination release lottery in the electric combination release lottery using the common charge release counter C4 is the same (for example, both 4/5), In the high-frequency support mode, the number of times the general-purpose utility 234a is released when the electronic-wiring-released state is elected is set to a greater number of times than in the low-frequency support mode, and one open time is set longer. ing. In this case, when the open state is elected in the high frequency support mode and the open state of the general purpose utility 234a occurs a plurality of times, it is from the end of one open state to the start of the next open state. The closing time is set to be shorter than one opening time. Furthermore, in the high-frequency support mode, the securing time minimumly secured when the next electric combination opening lottery is performed after the one electric combination opening lottery is performed rather than the low frequency support mode (ie, The one display continuation time in the common drawing display portion 238a is set to be short.

  As described above, in the high frequency support mode, the probability of winning in the second operation port 234 is higher than in the low frequency support mode. In other words, in the low frequency support mode, the probability of winning in the first operation port 233 is higher than that of the second operation port 234, but in the high frequency support mode, the second operation than the first operation port 233 The probability of winning in the mouth 234 is high. And, when the winning a prize to the 2nd operation opening 234 occurs, because the payout of the game sphere of specified number is executed, in the high frequency support mode, the game while the player does not decrease the ball very much It can be carried out.

  The configuration for increasing the frequency with which the high-frequency support mode is to be in the open state per unit time than in the low-frequency support mode is not limited to the above-described one. It is also possible to increase the probability of being in the electronic combination open state winning state in. In addition, a securing time (for example, based on winning on the through gate 235) is secured in the securing period when the next electric combination opening lottery is performed after the one electric combination opening lottery is performed (for example, In the configuration in which multiple types of variable display to be executed are prepared, in the high frequency support mode, it is set so that a short securing time is easier to be selected or the average securing time is shorter than the low frequency support mode. It may be Furthermore, the number of times of opening is increased, the opening time is lengthened, and the securing time secured upon the execution of the next electric combination opening lottery after the one electric combination opening lottery is performed is shortened. The advantage of the high frequency support mode over the low frequency support mode may be enhanced by applying any one condition or any combination of conditions among the shortening of the average securing time and the increase of the winning probability. .

  Next, the jackpot random number updated by the hard random number circuit 267 will be described. The jackpot random number updated in the hard random number circuit 267 is stored in the hold storage area 284 a based on the game ball winning in the first operation port 233 or the second operation port 234.

  The value of the random number for winning the jackpot is stored in the ROM 263 as a success or failure table. As the pass / fail table, a pass / fail table for the low probability mode and a pass / fail table for the high probability mode are set. That is, in this pachinko machine, the low probability mode and the high probability mode are set as the lottery mode in the hit / fall lottery means.

  Under the gaming state where the low probability mode hit / fail table is referred to at the time of the lottery, the value of the random number to be a big hit is 100. On the other hand, under gaming conditions in which the high probability mode pass / fail table is referred to at the time of the lottery, the number of random numbers for winning a big hit is set larger than when the low probability mode pass / fail table is referred to Specifically, it is 2000 pieces.

  In each lottery mode, the lottery result is out of the results except for the value of the random number for winning the jackpot. In the case where the result is an out-of-focus condition, no transition occurs triggered by the lottery result for all of the open / close execution mode, the pass / fail lottery mode, and the support mode.

  Next, the jackpot type counter C2 will be described. The jackpot type counter C2 is configured to be sequentially incremented by one within the range of 0 to 49 and to return to 0 after reaching the maximum value. The jackpot type counter C2 is periodically updated, and stored in the hold storage area 284a based on the game ball having won the first operation port 233 or the second operation port 234.

  Here, in this pachinko machine, a plurality of jackpot results are set, but each of these jackpot results are (1) contents of opening / closing execution mode, (2) contents of acceptance lottery mode after opening / closing execution mode, (3 ) At least one of the three contents of the support mode after the opening / closing execution mode is different.

  The opening / closing execution mode executed when the jackpot is won is a round number defining mode which is executed with the predetermined number of round games as the upper limit. A round game is a game that continues until either a predetermined upper limit continuation time elapses or a predetermined upper limit number of gaming balls wins on the special power prize device 232 is satisfied. It is. Further, the number of round games executed in the number-of-rounds regulation mode is the same as the number of fixed rounds regardless of the type of the jackpot result which has triggered the transition. Specifically, the upper limit number of round games is set to 15 rounds regardless of which jackpot result.

  In the number-of-rounds defining mode, the high-frequency winning mode and the low-frequency winning mode are performed such that the frequency of occurrence of winnings on the special power winning device 232 becomes relatively high and low between the start of the open / close execution mode and the end. And is set. Specifically, in the pachinko machine of the present invention, a single opening mode of the special electric winning device 232 is set to a plurality of types by making the opening continuation time from the opening of the special electric winning device 232 to the closing different. . Specifically, a long-time mode in which the opening continuation time is set to 29 sec which is a long time, and a short-time mode in which the opening continuation time is set to 0.1 sec which is a time shorter than the long time are set. ing. In this pachinko machine, in a situation where the launch operation device 228 is operated by the player, the game ball emission mechanism 227 is drive-controlled so that one game ball is emitted toward the game area in 0.6 sec. . In addition, the upper limit number of end conditions of the round game is set to nine. Then, in the long time mode among the above-mentioned open modes, the open continuation time of a time longer than the product of the firing cycle of the game balls and the upper limit number of one round game is set. On the other hand, in the short-time mode, the opening duration of a time shorter than the product of the game ball firing cycle and the upper limit number of one round game, more specifically, the time shorter than the game ball firing cycle is set. ing. Therefore, when the special power winning device 232 is opened once in the long time mode, it is expected that the special electric number winning device 232 will generate winnings for the upper limit number in one round game, and the short time When the special power winning device 232 is opened once in a mode, the special power winning device 232 does not have a winning or if there is a winning, it takes about one, and there is a high probability that the winning will not occur. Is expected to be

  In the high frequency winning mode, the special power winning device 232 is opened once in a long time mode in each round game. That is, the special power prize device 232 is opened 15 times in the long time mode. On the other hand, in the low frequency winning mode, the special power winning device 232 is opened once in a short time mode in each round game. That is, the special power prize device 232 is opened 15 times in a short time mode.

  In addition, the number of opening and closing times of special power winning device 232 in high frequency winning mode and low frequency winning mode, the number of round games, the opening continuation time for one opening, and the upper limit number in one round game, the high frequency winning mode If the frequency of occurrence of winning to the special power winning device 232 is higher than in the low frequency winning mode from when the opening / closing execution mode is started to when it is ended, it is not limited to the above value and is optional It is.

  The sorting destination of the type of jackpot result for the jackpot type counter C2 is stored in the ROM 263 as a sorting table. In the distribution table, the low probability jackpot result, the explicit high probability jackpot result, and the most advantageous jackpot result are set as the sort destination of the jackpot result.

  The low probability jackpot result is a jackpot result in which the opening / closing execution mode becomes the high frequency winning mode, and after the opening / closing execution mode ends, the pass / fail lottery mode becomes the low probability mode and the support mode becomes the high frequency support mode. However, in the high-frequency support mode, the transition to the low-frequency support mode is made when the number of games has reached the end reference frequency (specifically, 100 times) after the transition.

  The explicit high probability jackpot result is a jackpot result in which the opening / closing execution mode becomes the low frequency winning mode, and after the opening / closing execution mode ends, the pass / fail lottery mode becomes the high probability mode and the support mode becomes the high frequency support mode. . The high probability mode and the high frequency support mode continue until the lottery result in the success or failure lottery becomes the jackpot state winning, and shifts to the jackpot state by it.

  The most advantageous jackpot result is a jackpot result in which the opening / closing execution mode becomes the high frequency winning mode, and after the opening / closing execution mode ends, the pass / fail lottery mode becomes the high probability mode and the support mode becomes the high frequency support mode. The high probability mode and the high frequency support mode continue until the lottery result in the success or failure lottery becomes the jackpot state winning, and shifts to the jackpot state by it.

  In the distribution table, among the values of the jackpot type counter C2 of “0 to 29”, “0 to 9” correspond to the low probability jackpot result, and “10 to 14” correspond to the explicitly high probability jackpot result “15-29” corresponds to the most advantageous jackpot result.

  Next, the reach random number counter C3 will be described. For example, the reach random number counter C3 is configured to be sequentially incremented by one within the range of 0 to 238, and to return to 0 after reaching the maximum value. Here, in this pachinko machine, an expected effect is set as a type of display effect on the symbol display device 241. An expected effect includes the symbol display device 241 capable of performing variable display of symbols, and in the gaming machine that results in a predetermined jackpot, the symbol display device 241 is a gaming machine in which a final stop result is an application result. Before the stop result is derived and displayed after the variable display of the symbol in is started, it means the display state for making the player think that it is a variable display state in which the above-mentioned correspondence with correspondence result is likely to be obtained. In addition, specifically, about the provision corresponding | compatible result, the combination of the symbol in which the same number was attached | subjected on one effective line is stopped-displayed.

  In the expectation effect, two types of reach display and advance notice display for expecting the occurrence of reach display and the occurrence of the response to an assignment in a stage before the reach display and the like are set.

  In the reach display, a combination of reach symbols is displayed by stopping the symbols of some of the plurality of symbol rows displayed on the display surface 241a of the symbol display device 241, and the remaining symbols are displayed in that state. The display state which performs the fluctuation display of a symbol in a symbol row is included. Also, while displaying combinations of reach symbols as described above, while performing variable display of symbols in the remaining symbol rows, and performing reach effects by displaying a predetermined character or the like as a moving image on the background screen, or Also, there is a method of performing reach effect by displaying a predetermined character or the like as a moving image over substantially the entire display surface 241 a after reducing or displaying a combination of reach symbols in reduced size or non-display.

  In the advance notice display, after variation display of symbols is started on the display surface 241a of the symbol display device 241, in a situation where symbols are variably displayed in all symbol rows Z1 to Z3, or in some symbol rows In a situation where symbols are variably displayed in a plurality of symbol rows, a mode is included in which characters are displayed separately from the symbols on the symbol rows Z1 to Z3. In addition, the background screen is a predetermined mode different from the previous modes, and the pattern on the symbol rows Z1 to Z3 is the predetermined mode different from the previous modes. Such advance notice may occur at any of the game times when the reach display is performed and when the reach display is not performed, but the case where the reach display is performed is higher than the case where the reach display is not performed. It is set to occur with probability.

  The reach display is executed regardless of the value of the reach random number counter C3 in the game times in which the combination of the same symbols is finally stopped and displayed. Moreover, in the game time corresponding to the big hit result in which the combination of the same symbol is not stopped and displayed, it is not performed irrespective of the value of the reach random number counter C3. Further, in the game times corresponding to the disconnection result, when the reach random number counter C3 acquired at a predetermined timing with reference to the reach table stored in the reach table storage area of the ROM 263 corresponds to the occurrence of the reach display To be executed.

  On the other hand, it is not determined in the main control device (not shown) but in the sound emission control device (not shown) whether the advance display is to be performed or not. In this case, in the voice light emission control device, the game times corresponding to any of the jackpot results are more likely to generate a notice display than the game times corresponding to the out result, and a notice display having a low appearance rate is generated. In order to satisfy at least one of the conditions that it is easy to do, a lottery process for displaying a notice is performed. By the way, this lottery result is reflected when the effect for the game round is executed by the symbol display device 241.

  Next, the variation type counter CS will be described. For example, the fluctuation type counter CS is sequentially incremented by one within the range of 0 to 198, and returns to 0 after reaching the maximum value. The fluctuation type counter CS is used when the MPU 262 determines the display continuation time in the special view display unit 237a and the display continuation time of the symbol in the symbol display device 241. The fluctuation type counter CS is updated once each time a normal process to be described later is executed once, and is repeatedly updated even within the remaining time in the normal process. Then, the value of the fluctuation type counter CS is acquired at the time of the start of the fluctuation display in the special view display portion 237a and the fluctuation pattern determination at the start of the fluctuation of the symbol by the symbol display device 241.

<Timer interrupt processing>
Next, among the processes executed to advance the game with the control IC 271 of the main control device (not shown), timer interrupt processing that is activated periodically (in this embodiment, in a cycle of 4 msec), This will be described with reference to FIG.

  First, in step S3201, a power failure information storage process is executed. In the power failure information storage processing, it is monitored whether or not a power failure signal corresponding to the occurrence of the power supply interruption is received from the power failure monitoring board, and when the occurrence of the power failure is specified, the power failure processing is executed.

  In the following step S3202, a lottery random number update process is executed. In the random number updating process for drawing, the jackpot type counter C2, the reach random number counter C3 and the general public release counter C4 are updated. Specifically, the present numerical information is sequentially read out from the jackpot type counter C2, the reach random number counter C3 and the common charge release counter C4, and the read out numerical information is added one by one. Execute the overwrite process. In this case, when the counter value reaches the maximum value, it is cleared to "0". Thereafter, in step S3203, the variation counter updating process for updating the variation type counter CS is executed. In the updating process, the present numerical value information is read out from the fluctuation type counter CS, and the process of adding one to the read out numerical value information is executed, and then the process of overwriting the read source counter is executed. In this case, when the counter value reaches the maximum value, it is cleared to "0".

  In the following step S3204, a fraud detection process is performed to monitor whether or not a predetermined event set as a fraud monitoring target has occurred. In the fraud detection process, occurrence of a plurality of types of events is monitored, and by confirming that a predetermined event has occurred, an affirmative determination is made in step S3205 described later.

  Thereafter, in step S3205, it is determined whether or not the progress of the game is stopped. The state in which the progress of the game is stopped is set when the occurrence of a predetermined event set as the monitoring target for fraud is confirmed in the fraud detection process of step S3204. If a negative determination is made in step S3205, the processes in step S3206 and subsequent steps are executed.

  In step S3206, port output processing is performed. In the port output process, when setting of output information is performed in the previous timer interrupt process, a process for performing an output corresponding to the output information to the various drive units 232 b and 234 b is executed. For example, when the information to switch the special power winning device 232 to the open state is set, the output of the drive signal to the drive unit 232b for the special power is started, and the information to switch to the closed state is set. Stops the output of the drive signal. In addition, when the information to switch the common use utility product 234a in the second operation port 234 to the open state is set, the output of the drive signal to the drive unit 234b for general use power is started to switch to the closed state. When the information is set, the output of the drive signal is stopped.

  In the following step S3207, the reading process is executed. In the reading process, reading of signals other than the power failure signal and the winning signal is executed, and the read information is stored for use in future processing.

  In the following step S3208, a winning detection process is executed. In the winning detection process, the signals received from the operation opening winning detection sensor 245 and other winning detection sensors 269a to 269c are read, and the general winning opening 231, the special power winning device 232, the first operation opening 233, the second operation opening A process of identifying the presence or absence of the ball entering the ball 234 and the through gate 235 is executed.

  In the following step S3209, a timer update process for collectively updating numerical information of a plurality of types of timer counters provided in the RAM 264 is executed. In this case, the timer counter is stored in which the stored numerical information is subtracted and updated, but both the update of the subtraction type timer counter and the update of the addition type timer counter are collectively performed. It is good also as composition.

  In the following step S3210, a launch control process is performed to control the launch of the game ball. In the situation where the firing operation is continued to the firing operation device 228, one gaming ball is fired in 0.6 seconds.

  In the following step S3211, as input state monitoring processing, based on the information read in the reading processing in step S3207, disconnection confirmation of the operation hole winning detection sensor 245 and the other winning detection sensors 269a to 269c, the gaming machine main body 212 and the front The opening confirmation of the door frame 214 is performed.

  In the following step S3212, the special figure special power control process for performing execution control of the game run and execution control of the open / close execution mode is executed. The processing content of the special figure special power control process will be described in detail later.

  In the following step S3213, a general-purpose general control control process is executed. In the common control common control process, when winning through the through gate 235 occurs, processing for obtaining numerical information of the common use release counter C4 is executed, and the numerical information is stored. The open determination is performed on the numerical information, and further, the open determination is triggered by the open determination, and processing for performing an effect for common use is performed in the common view display unit 238a. Also, based on the result of the open determination, processing is performed to open and close the general purpose utility product 234a of the second operation port 234.

  In the following step S3214, setting of output information for reflecting the increase / decrease number of the suspension information according to the special view display unit 237a on the special view suspension display unit 237b based on the processing result of the immediately preceding step S3212 and step S3213 The output information for reflecting the increase / decrease number of the hold information related to the figure display unit 238a on the common view hold display unit 238b is set. In step S3214, output information for updating the display content of the special view display unit 237a is set based on the processing results of the immediately preceding step S3212 and step S3213, and the display content of the common view display unit 238a is set. Set the output information for updating.

  In the subsequent step S3215, the contents of the command and signal received from the payout control device 277 are confirmed, and a payout state reception process for executing a process corresponding to the confirmation result is executed. In step S3216, a payout output process for setting a winning ball command as an output target is executed. In the subsequent step S3217, an external information setting process is performed to control the start and end of the output of the external signal according to the processing results of the various processes executed in the timer interrupt process this time.

  If an affirmative determination is made in step S3205, or after the processes of steps S3206 to S3217 are performed, the timer interrupt process is ended.

<Special figure special power control process>
Next, the special figure electric power control process executed in step S3212 in the timer interrupt process (FIG. 68) of the MPU 262 will be described with reference to the flowchart of FIG.

  In the special figure special power control process, the process for acquiring the hold information is executed when the first operation port 233 or the second operation port 234 is winning, and the hold information is stored. Judgment determination is performed on the hold information, and further, processing for producing effects for the game cycle is executed triggered by the judgment. Further, based on the result of the success or failure determination, the processing to shift to the opening / closing execution mode after the presentation for the game cycle is executed, and the processing in the opening / closing execution mode and at the end of the opening / closing execution mode is executed.

  Specifically, first, in step S3301, a process of acquiring pending information is executed. This will be described later.

  After the process of acquiring the suspension information in step S3301, the process proceeds to step S3302. In step S3302, a process of reading information of the special view special charge counter provided in the RAM 264 is executed. In the following step S3303, the special figure special power address table stored in the ROM 263 is read out. Then, in step S3304, processing is performed to acquire the start address corresponding to the information of the special figure special charge counter from the special figure special charge address table.

  Here, the processing contents of step S3302 to step S3304 will be described. As described above, the special view special power control process includes a process relating to an effect for game circulation and a process relating to the open / close execution mode. In this case, as a process relating to an effect for game use, a special figure change start process (step S3306) which is a process for starting an effect for game use, and a process for promoting an effect for game use A special figure changing process (step S3307) and a special figure determining process (step S3308), which is a process for ending the effects for game circulation, are set.

  Also, as a process related to the open / close execution mode, a special power start process (step S3309) which is a process for controlling the opening in the open / close execution mode and a special electric power which is a process for controlling the open state of the special electric winning device 232. Processing during opening (step S3310), processing during special power closing (step S3311) which is processing for controlling the closing state of special electric winning device 232, ending in open / close execution mode and gaming state at the end of open / close execution mode And a special power termination process (step S3312), which is a process for controlling the transition of the image.

  In such a processing configuration, the special figure special charge counter is a counter for the MPU 262 to grasp which of the plurality of types of processing should be executed, and the special figure special charge address table A start address of a program for executing the plurality of types of processing is set corresponding to the numerical information of the special charge counter.

  In this case, the start address SA0 is a start address of a program for executing the special figure change start process (step S3306), and the start address SA1 is a program for performing the special figure change in process (step S3307). The start address SA2 is a start address of a program for executing the special view determination process (step S3308). The start address SA3 is a program for executing the special power start process (step S3309). The start address SA4 is a start address of a program for executing the special power release process (step S3310). The start address SA5 is a program for executing the special power close process (step S3311). Start address, start address SA6 is Electrically movable device control termination processing is the starting address of a program for executing (step S3312).

  The special figure special power counter performs special figure special power control in the next processing cycle when the condition for updating the numerical value information is satisfied when the process corresponding to the currently stored numerical information is finished. One is added, one is subtracted, or "0" is cleared (initialized) corresponding to the process executed in the process. Therefore, in the special figure special power control process in each processing cycle, the process according to the numerical information set in the special figure special power counter may be executed. In addition, "0" is set as an initial value for the special figure special power counter.

  After the process of step S3304 is performed, in step S3305, a process of jumping to the process indicated by the start address acquired in step S3304 is performed. Specifically, when the acquired start address is SA0, the process jumps to the special map change start process of step S3306.

  In the special figure fluctuation start process, on the condition that the suspension information is stored on hold, it is determined whether or not the suspension information corresponds to the big hit in the case of supporting the big hit or the win determination process. Executes a distribution determination process to determine which jackpot result the hold information corresponds to. In detail, it is determined whether or not the hold information exists, and when the hold information exists, a process of shifting the hold information is executed. That is, the hold information stored in the first hold area RE1 is shifted to the execution area AE, and the hold information stored in the n-th hold area REn (n = 2 to 4) is held at the (n-1) th hold. Shift to area RE (n-1). Then, it is determined whether or not the jackpot random number stored in the execution area AE is the numerical information corresponding to the jackpot win, as the success or failure judgment processing. Further, as a distribution determination process, it is determined whether or not the value of the jackpot type counter C2 corresponds to any of the jackpot result classifications.

  In addition to the success / failure determination processing and the distribution determination processing, when the big hit random number does not correspond to the big hit winning, the reach determination processing is executed to determine whether or not the reach is to be generated. The processing of selecting the duration is carried out to select the duration of the game play using the numerical information of the CS. In the reach determination process, it is determined whether the value of the reach random number counter C3 stored in the execution area AE corresponds to the reach occurrence.

  When information on duration is selected, a variation command including information on the duration and a type command including information on gaming results are transmitted to the voice emission control device, and variation of the pattern in the special view display portion 237a Start the display. As a result, one game cycle is started, and the special game display unit 237a and the symbol display device 241 start effects for the game cycle.

  By the way, when the effect for the game circulation is started in this way, the numerical information of the special figure special electric power counter corresponds to the special figure fluctuation start processing by adding 1 to the numerical information of the special figure special electric power counter To the one corresponding to the processing during the special map change.

  If the acquired start address is SA1, the process jumps to the special figure variation processing of step S3307. In the special figure changing process, a process of determining whether or not it is a timing before the finalized display during the game time is executed, and if it is the finalized display, the display of the pattern in the special view display portion 237a Execute processing to change the aspect regularly.

  By the way, this special view change is not performed after waiting for the special display change processing until the final display timing is reached, and after the process for regularly changing the above-mentioned regular display is not performed. End the process. Therefore, after the special effects for the game are started, the special figure variation in progress process is activated every time the special figure electric power control process is activated, until the timing for finalizing the display. In addition, when it is time to display fixedly, by adding 1 to the numeric information of the special chart special power counter, it corresponds to the special chart finalization process from the one corresponding to the special chart fluctuation process of the numerical information of the counter. Update to what you

  If the acquired start address is SA2, the process jumps to processing during special image determination in step S3308. In the special figure finalization process, the final stop command is transmitted to the voice emission control device to display the final stop result of the current game run on the symbol display device 241, and the symbol display in the special view display portion 237a is displayed. The mode is a display mode corresponding to the lottery result of the current game run. Further, in the processing during special figure determination, it is determined whether or not the period during the definite display has elapsed, and when the period has elapsed, it is determined whether or not transition to the open / close execution mode occurs. When the transition to the open / close execution mode occurs, the processing for transition to the open / close execution mode is executed.

  By the way, instead of waiting in the processing during the special drawing determination until the period during the definite display elapses, the processing during the special drawing determination is ended when the period has not elapsed. Therefore, after the definite display is started, the special figure determination processing is activated every time the special figure electric power control processing is activated until the period during the definite display elapses. In addition, if the transition to the open / close execution mode does not occur when the fixed display period has elapsed, the numeric information of the special figure special power counter is initialized (that is, "0" is cleared), and the transition to the open / close execution mode is performed. In a situation where occurs, the numerical information of the special figure special electric power counter is added by 1, and the numerical information of the special figure special electric power counter is updated from the one corresponding to the special figure determination process to the one corresponding to the special electric power start process.

  If the acquired start address is SA3, the process jumps to the special power start process of step S3309. In the special power start process, an opening command indicating that the open / close execution mode is started is transmitted to the sound emission control apparatus. Also, in the special power start process, it is determined whether or not the opening period of the open / close execution mode has elapsed. If the opening period has not elapsed, the special power start process is terminated instead of waiting in the special power start process. Therefore, after the opening effect in the open / close execution mode is started, the special power start process is activated every time the special electric power control process is activated until the opening period elapses. In addition, when the opening period has elapsed, the numerical information of the special figure special electric power counter is added by 1, and the numerical information of the special figure special electric power counter corresponds to the special electric power start processing to the special electric power open process Update to

  If the acquired start address is SA4, the processing jumps to the processing during the power-off in step S3310. In the special power open process, it is determined whether a round game of 1 is started and whether or not an end condition of the round game is established. If the termination condition is not satisfied, the process does not stand by in the process of opening the TPC, but after executing the process for monitoring the establishment of the termination condition, the process of the TPC being opened is ended. When the above termination condition is satisfied, adding 1 to the numerical information of the special figure special electric power counter corresponds to the special electric special process closing process from the one corresponding to the special electric special open process of the numerical information of the special special electric charge counter Update to what you

  If the acquired start address is SA5, the process jumps to the processing during the special power closing of step S3311. In the special power closed process, a process to end one round game is executed. In addition, in an interval period between round games, it is determined whether an interval period has elapsed. If the interval period has not elapsed, the process is terminated instead of waiting in the process of closing the special power supply, but ending the process of closing the special electric charge. Therefore, when the interval period is started, the special electric power closing process is activated every time the special electric power special control process is activated until the period has elapsed. In addition, when the interval period has elapsed, the numerical information of the special figure special electric power counter is subtracted by 1, so that the special information special electric special charge counter's numerical information corresponds to the special electric power closing process. Update to things.

  On the other hand, in the special electric power closing process for the last round game, after executing the processing to end the first round electric power game, the numerical information of the special electric special electric power counter is added 1 Update from those corresponding to medium processing to those corresponding to special power termination processing.

  If the acquired start address is SA6, the process jumps to the special power termination process of step S3312. In the special power termination process, an ending command indicating that the open / close execution mode is terminated is transmitted to the sound emission control apparatus. Further, in the special power termination process, it is determined whether the ending period of the open / close execution mode has elapsed. If the ending period has not elapsed, the special power termination process is ended instead of waiting in the special power termination process. Therefore, after the ending effect in the open / close execution mode is started, the special power termination process is activated every time the special electric power control process is activated until the ending period elapses. Also, when the ending period has elapsed, after executing processing for setting the gaming state (lottery mode and support mode) after the opening / closing execution mode, the numerical information of the special view special charge counter is initialized, The numerical information of the special drawing special power counter is updated from the one corresponding to the special electric power termination processing to the one corresponding to the special drawing fluctuation start processing.

<Obtaining information acquisition processing>
Before describing the acquisition process of the suspension information executed in step S3301 of the special view special power control process (FIG. 69), the flags and counters included in the RAM 264 (FIG. 66) of this embodiment are as shown in FIG. It explains, referring to. The RAM 264 includes an error counter 264a, a signal storage flag 264b, a confirmation instruction flag 264c, and an error status flag 264d.

  Here, in the error counter 264a of the RAM 264, the event that “1” is not set in the latched status 113 of the control circuit 303 occurs continuously even though the detection signal SG4 input to the MPU 262 rises. It is a counter that counts the number of times. The signal storage flag 264b of the RAM 264 is a flag for storing the state of the detection signal SG4 input to the control IC 271 in the random number acquisition process (FIG. 71) executed by the control IC 271.

  Specifically, in the random number acquisition process, when the detection signal SG4 input to the control IC 271 is in the HI state, "1" is set in the signal storage flag 264b of the RAM 264, and is input to the control IC 271. When the detection signal SG4 is in the LOW state, the signal storage flag 264b of the RAM 264 is cleared to "0". The information set in the signal storage flag 264b of the RAM 264 is stored until the next random number acquisition processing.

  Then, in the next random number acquisition process, when the signal storage flag 264b of the RAM 264 is set to “0” and the detection signal SG4 input to the control IC 271 is in the HI state, the control IC 271 selects the control IC 271. It is determined that the rising of the detection signal SG4 input to the is detected.

  Further, in the random number acquisition process (FIG. 71) executed by the control IC 271, the confirmation command flag 264c of the RAM 264 detects that the rising edge of the detection signal SG4 input to the control IC 271 is detected. The flag is set to “1” on the condition that “1” is not set in the latched status 113 at the above timing. The control IC 271 can perform processing according to the result of the previous random number acquisition processing by performing determination on the state of the confirmation instruction flag 264 c of the RAM 264 in the random number acquisition processing.

  Further, the error status flag 264 d is set to “1” when the latched status 113 is not set to “1” although the rising of the detection signal SG 4 input to the MPU 262 is detected. Is a flag that As a situation where the error state flag 264 d is set to “1”, it may be considered that the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is disconnected. The control IC 271 executes processing according to a state in which the detection signal SG4 input to the control side CPU 304 does not rise when the error state flag 264d is set to “1”, and stores it in the random number counter 105. The jackpot random number that is being played can be written to the latch register 102.

  Next, acquisition processing of suspension information executed in step S3301 of the special figure special power control process (FIG. 69) will be described with reference to the flowchart of FIG. 70 (b). The acquisition process of the suspension information is a process executed by the control IC 271.

  First, in step S3401, it is determined whether "1" is set in the error status flag 264d. When "1" is set to the error state flag 264d (step S3401: YES), the control IC 271 that detects the rising of the detection signal SG4 input to the control IC 271 has the operation port winning detection sensor 245 and the control side In this case, it is determined that the connection with the CPU 304 is disconnected, and the latch instruction signal is transmitted to the control CPU 304.

  If "1" is set in the error state flag 264d (step S3401: YES), it is determined in step S3402 whether "1" is set in the latched status 113 or not. When "0" is set to the latched status 113 (step S3402: NO), the update of the jackpot random number stored in the latch register 102 triggered by the transmission of the latch instruction signal by the control IC 271 is completed. This means that the process of acquiring the hold information is ended as it means that the process is not performed.

  When "1" is set to the latched status 113 (step S3402: YES), the jackpot random number stored in the latch register 102 is already updated in response to the transmission of the latch instruction signal by the control IC 271. There is. In this case, the error status flag 264 d is cleared to “0” in step S3403, and a pulse signal is transmitted to the CLR terminal of the latched status 113 in step S3404 to “0” the latched status 113. clear.

  In the following step S3405, the jackpot random number input to the input terminal TA13 of the control IC 271 is acquired, and the jackpot random number is set as the jackpot random area in the first hold area among the free hold areas RE1 to RE4 of the holding area RE. Store. Thereafter, in step S3406, the value of the jackpot type counter C2 and the value of the reach random number counter C3 are acquired from the lottery counter area 284b of the RAM 264, and the acquired numerical information is stored as the jackpot random number in the step S3405. It stores in the corresponding area in a reservation area, and ends acquisition processing of this reservation information.

  If “1” is not set in the error state flag 264 d in step S3401, the random number acquisition process is executed in step S3407, and the process of acquiring the hold information ends.

  Next, the random number acquisition process executed in step S3407 of the suspension information acquisition process (FIG. 70 (b)) will be described with reference to the flowchart of FIG.

  First, in step S3501, it is determined whether "1" is set in the confirmation command flag 264c of the RAM 264 or not. Here, when "1" is set to the confirmation command flag 264c of the RAM 264, "1" is stored in the latched status 113 in the random number acquisition process in which the rising of the detection signal SG4 input to the control IC 271 is detected. Is not set.

  If the value of the confirmation command flag 264c in the RAM 264 is "0" (step S3501: NO), it is determined in step S3502 whether the value of the signal storage flag 264b in the RAM 264 is "0". Here, the case where the value of the signal storage flag 264b of the RAM 264 is “0” means that the detection signal SG4 input to the control IC 271 in the previous random number acquisition processing is in the LOW state, and the signal of the RAM 264 The case where the value of the storage flag 264b is “1” is the case where the detection signal SG4 input to the control IC 271 in the previous random number acquisition process is in the HI state.

  If it is determined in step S3502 that the value of the signal storage flag 264b in the RAM 264 is "0", it is determined in step S3503 whether or not the detection signal SG4 input to the control IC 271 is in the HI state. If it is determined in step S3503 that the detection signal SG4 is in the HI state, the control IC 271 detects the rising of the detection signal SG4. In this case, “1” is set to the signal storage flag 264b of the RAM 264 in step S3504 to indicate that the detection signal SG4 input to the control IC 271 is in the HI state in the random number acquisition process this time. After storing, the process proceeds to step S3505.

  In step S3505, it is determined whether or not the current pending number is the upper limit number ("4"). If the current pending number is "3" or less (step S3505: NO), it is determined in step S3506 whether "1" is set in the latched status 113 or not. When “1” is set in the latched status 113 (step S3506: YES), the jackpot random number corresponding to the rising of the current detection signal SG4 is already written in the latch register 102, and the input terminal TA13 of the control IC 271 Is being input to the

  If "1" is set in the latched status 113 at step S3506 (step S3506: YES), the jackpot random number input to the input terminal TA13 of the control IC 271 is acquired at step S3507, and the jackpot The random number is stored in the area for the jackpot random number in the first holding area among the free holding areas RE1 to RE4 of the holding area RE. Thereafter, in step S3508, the value of the big hit type counter C2 and the value of the reach random number counter C3 are obtained from the drawing counter area 284b of the RAM 264, and the obtained numerical information is stored as the big hit random number in the step S3507. Store in the corresponding area in the reserve area.

  In the subsequent step S3509, the error counter 264a of the RAM 264 is cleared to “0” in response to the fact that the jackpot random number can be acquired without using the latch instruction signal in the present random number acquisition processing. Then, in step S3510, a pulse signal is transmitted to the CLR terminal of the latched status 113 to clear the latched status 113 to "0", and the random number acquisition processing is finished.

  In addition, although “1” is not set in the latched status 113 despite detection of the rising of the detection signal SG4 input to the control IC 271 in the random number acquisition processing this time (step S3506: NO) In order to execute determination on the status of the latched status 113 again in the next random number acquisition process, the CPU 250 sets "1" in the confirmation instruction flag 264c of the RAM 264 in step S3511, and terminates this random number acquisition process. .

  In addition, if the current pending number is “4”, which is the upper limit number in step S 3505, the pending number can not be increased any more. Therefore, in step S 3510, the CLR terminal of latched status 113 A pulse signal is transmitted to the above, the latched status 113 is cleared to "0", and this random number acquisition processing is ended.

  Also, in step S3503, when the detection signal SG4 is in the LOW state, it means that the rising of the detection signal SG4 is not detected in the random number acquisition processing this time. In this case, since “0” is already set in the signal storage flag 264 b of the RAM 264, the latched status 113 is transmitted by transmitting a pulse signal to the CLR terminal of the latched status 113 in step S 3510. Is cleared to "0", and this random number acquisition processing is finished.

  If "1" is set in the signal storage flag 264b of the RAM 264 in step S3502, it is determined in step S3512 whether or not the detection signal SG4 input to the control IC 271 is in the LOW state. . If it is determined in step S3512 that the detection signal SG4 is in the LOW state, the signal storage flag 264b of the RAM 264 is cleared to "0" in step S3513. After the detection signal SG4 is determined to be in the HI state in step S3512, or after the signal storage flag 264b of the RAM 264 is cleared to "0" in step S3513, the CLR terminal of the latched status 113 is determined in step S3510. By transmitting the pulse signal, the latched status 113 is cleared to “0”, and the random number acquisition process is finished.

  When “1” is set in the confirmation command flag 264c of the RAM 264 in step S3501, the rising of the detection signal SG4 input to the control IC 271 is detected in the previous random number acquisition processing. , Means that "1" is not set in the latched status 113. In this case, after the confirmation instruction flag 264c of the RAM 264 is cleared to "0" in step S3514, it is determined in step S3515 whether "1" is set in the latched status 113 or not.

  In the case where the confirmation command flag 264c of the RAM 264 is set to "1" in the previous random number acquisition process because the signal line connecting the operation port winning detection sensor 245 and the control side CPU 304 is disconnected, Since the detection signal SG4 input to the control side CPU 304 does not rise, the latched status 113 remains "0" also in the present random number acquisition processing (step S3515: NO). In this case, an error handling process (FIG. 74) to be described later is executed in step S3516, and the random number acquisition process ends.

  On the other hand, since the previous random number acquisition processing is executed before 12.8 μs elapses from when the detection signal SG4 output from the operation opening prize detection sensor 245 rises, the confirmation command flag 264c of the RAM 264 is set to "1". If it has been set, "1" is set in the latched status 113 for about 4 ms from the previous random number acquisition processing to the current random number acquisition processing (step S3515: YES) ). In this case, the processes of steps S3507 to S3510 are performed, and the random number acquisition process ends.

  Specifically, the jackpot random number input to the input terminal TA13 of the control IC 271 is acquired, and the jackpot random number is used as the jackpot random number area in the first hold area among the free hold areas RE1 to RE4 of the holding area RE. It stores it (step S3507). Thereafter, the value of the jackpot type counter C2 and the value of the reach random number counter C3 are acquired from the lottery counter area 284b of the RAM 264, and the acquired numerical information is stored in the corresponding area in the reserve area where the present jackpot random number is stored. (Step S3508). Then, the error counter 264a of the RAM 264 is cleared to "0" (step S3509), the signal output to the CLR terminal of the latched status 113 is raised (step S3510), and this random number acquisition processing is ended.

  Next, the error handling process executed in step S3516 of the random number acquisition process (FIG. 71) will be described with reference to the flowchart of FIG.

  First, in step S3601, it is determined whether the value of the error counter 264a of the RAM 264 is "0". If the value of the error counter 264a of the RAM 264 is “0” (step S3601: YES), it means that the event of suspected disconnection of the connection between the operation opening prize detection sensor 245 and the control side CPU 304 has occurred for the first time Do. In this case, "1" is added to the error counter 264a of the RAM 264 in step S3602.

  If the value of the error counter 264a of the RAM 264 is "1" at step S3601, an event is suspected in which disconnection of the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is suspected to occur continuously. Means In this case, an abnormal signal is transmitted to the management computer of the game hall in step S3603. Thereby, the manager of the game hall can grasp that the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is disconnected.

  After “1” is added to the error counter 264a of the RAM 264 at step S3602 or after transmitting an abnormal signal at step S3603, at step S3604, the current number of pending items reaches the upper limit number (“4”) It is determined whether or not it exists. If the current number of held items has reached the upper limit number (step S3604: YES), the control IC 271 does not need to acquire the jackpot random number corresponding to the current winning, so the error handling process is ended as it is.

  If it is determined in step S3604 that the currently held number is "3" or less, it is necessary to obtain a jackpot random number corresponding to the current winning, so in step S3605 a latch instruction signal to control side CPU 304 Is set, the error state flag 264d is set to "1" in step S3606, and the error handling process is ended.

  Even if the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is cut off, the jackpot random number corresponding to the present prize can be obtained so that the situation is not unduly disadvantageous for the player. Can be Further, by notifying the manager of the hall that the abnormality has occurred, the manager of the hall can perform maintenance for eliminating the abnormal state at an appropriate timing.

  Next, the timing at which the control IC 271 acquires the jackpot random number input to the input terminal TA13 of the control IC 271 will be described with reference to FIGS. 73 and 74. First, the case where the connection between the operation port winning detection sensor 245 and the control CPU 304 is not disconnected will be described with reference to FIG.

  FIG. 73 (a) shows the state of the detection signal SG4 input to the control IC 271, FIG. 73 (b) shows the state of the signal storage flag 264b of the RAM 264, and FIG. 73 (c) is input to the control side CPU 304. 73 (d) shows the timing when the big hit random number stored in the random number counter 105 is written to the latch register 102, and FIG. 73 (e) shows timer interrupt processing (FIG. 70). 73 (f) shows the state of the latched status 113, and FIG. 73 (g) shows the timing when the control IC 271 acquires the jackpot random number input to the input terminal TA13 of the control IC 271. FIG. 73 (h) shows the state of the confirmation command flag 264c of the RAM 264.

  As shown in FIGS. 73 (a) and 73 (c), when a winning on the first operation port 233 or the second operation port 234 occurs at the timing of t1, the detection signal SG4 input to the control IC 271 and the control side CPU 304. Rises from the LOW state to the HI state. As shown in FIG. 73C, from the timing of t1 when the detection signal SG4 input to the control side CPU 304 rises to the timing of t2 when 12.8 μs has elapsed, the detection signal SG4 input to the control side CPU 304 Is in the HI state. Therefore, the control side CPU 304 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p. Therefore, as shown in FIG. 73 (d), the jackpot random number stored in the random number counter 105 is written to the latch register 102 at the timing of t2. As shown in FIG. 73 (f), the control circuit 303 sets the latched status 113 to “1” at the same timing t2 as the latch register 102 latches the big hit random number.

  As shown in FIG. 73 (e), at the timing t3 which is after the timing t2, the first timer interrupt process (FIG. 70 (b)) is executed after the detection signal SG4 rises. At timing t3, as shown in FIG. 73A, the detection signal SG4 input to the control IC 271 is in the HI state. Therefore, as shown in FIG. 73 (b), the control IC 271 sets “1” to the signal storage flag 264b of the RAM 264 at the timing of t3. When the signal storage flag 264b of the RAM 264 changes from “0” to “1”, the control IC 271 detects the rising of the detection signal SG4. Then, as shown in FIG. 73 (f), since “1” is set in the latched status 113 at the timing of t3, as shown in FIG. 73 (g), the control IC 271 determines the timing of the t3. In the above, the jackpot random number input to the input terminal TA13 of the control IC 271 is acquired. The jackpot random number acquired this time is the jackpot random number written in the latch register 102 from the random number counter 105 triggered by the winning of the game ball this time.

  As shown in FIGS. 73 (a) and 73 (c), when passage of the gaming ball ends at the timing of t4 later than t3, the detection signal SG4 input to the control IC 271 and the control side CPU 304 starts from the HI state Return to LOW state. Thereafter, as shown in FIG. 73 (e), timer interrupt processing is executed at the timing of t5. As shown in FIG. 73 (a), at the timing of t5, the detection signal SG4 input to the control IC 271 is in the LOW state. Therefore, as shown in FIG. 73 (b), the control IC 271 clears the signal storage flag 264b of the RAM 264 to "0" at the timing of t5.

  Thereafter, when a new winning to the first operation port 233 or the second operation port 234 occurs at the timing of t6, as shown in FIGS. 73 (a) and 73 (c), they are input to the control IC 271 and the control side CPU 304. The detection signal SG4 rises again. As shown in FIG. 73 (e), the timer interrupt process is executed at the timing of t7 which is after the timing of t6. As shown in FIG. 73 (a), since the detection signal SG4 input to the control IC 271 at the timing of t7 is in the HI state, as shown in FIG. 73 (b), the control IC 271 controls the RAM 264 at the timing of t7. The “1” is set to the signal storage flag 264b of When the signal storage flag 264b of the RAM 264 changes from “0” to “1”, the control IC 271 detects the rising of the detection signal SG4 at the timing of t7.

  As shown in FIG. 73 (f), "1" is not set in the latched status 113 at the timing of t7 when the control IC 271 detects the rising of the detection signal SG4. Therefore, as shown in FIG. 73 (h), the control IC 271 sets “1” in the confirmation command flag 264c of the RAM 264 at the timing of t7.

  As shown in FIG. 73 (c), it is a timing at which 12.8 μs has elapsed from the timing of t6 at which the detection signal SG4 input to the control side CPU 304 has risen, and at t8 which is a timing after the timing of t7. Until timing, the detection signal SG4 input to the control side CPU 304 maintains the HI state. Therefore, the control circuit 303 transmits a latch signal to the CLK terminals of the latch register D-FFs 102a to 102p at the timing of the time t8. As a result, as shown in FIG. 73 (d), the jackpot random number stored in the random number counter 105 is written to the latch register 102 at the timing of t8.

  Thereafter, as shown in FIG. 73E, at the timing of t9 which is after the timing of t8, the second timer interrupt processing is executed after the timing of t6 when the detection signal SG4 rises. At timing t9, as shown in FIG. 73 (h), “1” is set in the confirmation command flag 264c of the RAM 264, and as shown in FIG. 73 (f), the latched status 113 is “ 1 is set. Therefore, as shown in FIG. 73 (g), the control IC 271 acquires the jackpot random number input to the control IC 271 at the timing of t9.

  The control IC 271 transmits a pulse signal to the CLR terminal of the latched status 113 as shown in FIG. 73 (f) at the timing of t9 when the big hit random number is acquired, and clears the latched status 113 to "0". At the same time, as shown in FIG. 73 (h), the confirmation command flag 264c of the RAM 264 is cleared to "0".

  The control IC 271 is configured to acquire the jackpot random number input to the input terminal TA13 of the control IC 271 under the condition that “1” is set in the latched status 113. For this reason, even when the acquisition process of the suspension information is executed before the jackpot random number stored in the random number counter 105 is written to the latch register 102 after the detection signal SG4 rises, the control IC 271 receives a prize for the current prize. It is possible to avoid acquiring the old jackpot random number which does not correspond.

  Next, when the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is disconnected, the control IC 271 transmits a latch instruction signal to the control side CPU 304, and an abnormality signal to the game hall management computer Will be described with reference to FIG.

  74 (a) shows the state of the detection signal SG4 input to the control IC 271, FIG. 74 (b) shows the state of the signal storage flag 264b of the RAM 264, and FIG. 74 (c) is stored in the random number counter 105. 74 (d) shows the timing when the timer interrupt process (FIG. 70 (b)) is executed, and FIG. 74 (e) shows the latched status 113 of the latched status 113. 74 (f) shows the timing when the control IC 271 acquires the jackpot random number inputted to the input terminal TA13 of the control IC 271, FIG. 74 (g) shows the state of the confirmation command flag 264c of the RAM 264. FIG. 74 (h) shows the state of the error counter 264a of the RAM 264, and FIG. 74 (j) shows a timing at which the control IC 271 transmits a latch instruction signal to the control CPU 304, and FIG. 74 (k) shows an error status flag. It shows the state of H.264d. In addition, since the connection between the operation port winning detection sensor 245 and the control side CPU 304 is disconnected, the detection signal SG4 inputted to the control side CPU 304 is always in the LOW state, and does not rise to the HI state.

  As shown in FIG. 74 (a), when a winning on the first operation port 233 or the second operation port 234 occurs at the timing of t1, the detection signal SG4 input to the control IC 271 changes from the LOW state to the HI state stand up. Thereafter, as shown in FIG. 74 (d), timer interrupt processing is executed at the timing of t2.

  As shown in FIG. 74 (a), since the detection signal SG4 input to the control IC 271 at the timing of t2 is in the HI state, as shown in FIG. 74 (b), the control IC 271 controls the RAM 264 at the timing of t2. The “1” is set to the signal storage flag 264b of When the signal storage flag 264b of the RAM 264 changes from “0” to “1”, the control IC 271 is in a state where the rising of the detection signal SG4 is detected at the timing of t2.

  Since the detection signal SG4 input to the control side CPU 304 does not rise, "1" is not set in the latched status 113 at the timing of t2, as shown in FIG. 74 (e). Therefore, as shown in FIG. 74 (g), the control IC 271 sets “1” in the confirmation command flag 264c of the RAM 264 at the timing of t2.

  As shown in FIG. 74 (d), the next hold information acquisition process is executed at the timing t3 which is after the timing t2. At timing t3, as shown in FIG. 74 (g), “1” is set in the confirmation command flag 264c of the RAM 264. However, as shown in FIG. 74 (e), “1” is not set in the latched status 113. Therefore, as shown in FIG. 74 (g), the control IC 271 clears the confirmation command flag 264c of the RAM 264 to "0" at the timing of t3 and, as shown in FIG. 74 (h), the error counter 264a of the RAM 264. Add "1".

  Further, the control IC 271 transmits a latch instruction signal to the control side CPU 304 as shown in FIG. 74 (j) at the same timing of t3, and as shown in FIG. 74 (k), an error state flag 264d. Set "1". The control side CPU 304 having received the latch instruction signal transmits a latch signal to the CLK terminals of the latch register D-FFs 102a to 102p at the same timing t3. As a result, as shown in FIG. 74C, the jackpot random number stored in the random number counter 105 is written to the latch register 102 at the timing of t3. Further, the control side CPU 304 sets “1” to the latched status 113 as shown in FIG. 74 (e) at the same timing t3.

  Thereafter, as shown in FIG. 74 (d), at the timing of t4, acquisition processing of the next holding information is executed. At the timing of t4, as shown in FIG. 74 (k), “1” is set in the error state flag 264d, and as shown in FIG. 74 (e), the latched status 113 is “1”. "Is set. This is because the control side CPU 304 which receives the latch instruction signal from the control IC 271 transmits a latch signal to the CLK terminal of the latch register D-FFs 102a to 102p, and the big hit random number stored in the random number counter 105 is the latch register 102. Is written to the

  Therefore, as shown in FIG. 74 (f), the control IC 271 acquires the jackpot random number input to the input terminal TA13 of the control IC 271 at the timing of t4. The control IC 271 clears the latched status 113 to "0" as shown in FIG. 74 (e) at the same timing t4, and as shown in FIG. 74 (k), the error status flag 264d is "0". clear.

  Thereafter, as shown in FIG. 74 (a), at time t5, passage of the gaming ball ends, and the detection signal SG4 input to the control IC 271 falls from the HI state to the LOW state. Then, at the timing of t6 later than the timing of t5, as shown in FIG. 74 (d), the acquisition processing of the suspension information is executed. As shown in FIG. 74 (a), the detection signal SG4 input to the control IC 271 at the timing of t6 is in the LOW state. Therefore, as shown in FIG. 74 (b), the control IC 271 clears the signal storage flag 264b of the RAM 264 to "0" at the timing of t6.

  As shown in FIG. 74 (a), when a winning on the first operation port 233 or the second operation port 234 occurs at the timing of t7 after the timing of t6, the detection signal SG4 input to the control IC 271 Rises from the LOW state to the HI state. Thereafter, as shown in FIG. 74 (d), timer interrupt processing is executed at the timing of t8. As shown in FIG. 74 (a), since the detection signal SG4 input to the control IC 271 at the timing of t8 is in the HI state, as shown in FIG. 74 (b), the control IC 271 controls the RAM 264 at the timing of t8. The “1” is set to the signal storage flag 264b of When the signal storage flag 264b of the RAM 264 changes from "0" to "1", the control IC 271 detects the rising of the detection signal SG4 at the timing of t8.

  Since the detection signal SG4 inputted to the control side CPU 304 does not rise, "1" is not set to the latched status 113 at the timing of t8 as shown in FIG. 74 (e). Therefore, as shown in FIG. 74 (g), the control IC 271 sets “1” to the confirmation command flag 264c of the RAM 264 at the timing of t8.

  As shown in FIG. 74 (d), the next hold information acquisition process is executed at the timing of t9 which is after the timing of t8. At timing t9, as shown in FIG. 74 (g), "1" is set in the confirmation command flag 264c of the RAM 264. However, as shown in FIG. 74 (e), “1” is not set in the latched status 113. Further, as shown in FIG. 74 (h), “1” is set in the error counter 264a of the RAM 264. Therefore, as shown in FIG. 74 (g), the control IC 271 clears the confirmation command flag 264c of the RAM 264 to “0” at the timing of t9, and as shown in FIG. 74 (i), In response, it sends an abnormal signal.

  Further, the control IC 271 transmits a latch instruction signal to the control side CPU 304 as shown in FIG. 74 (j) at the same timing of t9, and as shown in FIG. 74 (k), an error status flag 264d is generated. Set "1". The control side CPU 304 having received the latch instruction signal transmits a latch signal to the CLK terminals of the latch register D-FFs 102a to 102p at the same timing of t9. As a result, as shown in FIG. 74C, the jackpot random number stored in the random number counter 105 is written to the latch register 102 at the timing of t9. Further, as shown in FIG. 74E, the control side CPU 304 sets “1” to the latched status 113 at the same timing of t9.

  Thereafter, as shown in FIG. 74 (d), at the timing of t10, the next timer interrupt processing is executed. At the timing of t10, as shown in FIG. 74 (k), “1” is set in the error state flag 264d, and as shown in FIG. 74 (e), the latched status 113 is “1”. "Is set.

  Therefore, as shown in FIG. 74 (f), the control IC 271 acquires the jackpot random number input to the input terminal TA13 of the control IC 271 at the timing of the time t10. The control IC 271 clears the latched status 113 to "0" as shown in FIG. 74 (e) at the same timing of t10, and as shown in FIG. 74 (k), the error status flag 264d is "0". clear.

  As described above, the control side CPU 304 sets the latched status 113 to “1” at the timing when the big hit random number stored in the random number counter 105 is written to the latch register 102. The control IC 271 is configured to obtain the jackpot random number input to the input terminal TA13 of the control IC 271 under the condition that “1” is set in the latched status 113. For this reason, when acquisition processing of suspension information is executed before the jackpot random number stored in the random number counter 105 is written to the latch register 102, the old control IC 271 is input to the input terminal TA13 of the control IC 271. It is possible to avoid getting the jackpot random number.

  Further, in the random number acquisition process, when “1” is not set in the latched status 113 even though the rising of the detection signal SG4 input to the control IC 271 is detected, The check command flag 264c of the RAM 264 is set to "1". Then, in the next random number acquisition process, the process of determining the state of the latched status 113 is executed again. Therefore, even when the random number acquisition process is executed before “1” is set to the latched status 113, the winning is not invalidated, and the control IC 271 receives a random number corresponding to the current winning. It can be acquired.

  In addition, even when the detection signal SG4 input to the control IC 271 rises, "1" is not set in the latched status 113, as in the case where the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is disconnected. When the control IC 271 continuously generates, the control IC 271 transmits a latch instruction signal to the control side CPU 304 in response to the rise of the detection signal SG4 in the control IC 271. Then, the control side CPU 304 that has received the latch instruction signal transmits a latch signal to the CLK terminal of the latch register D-FFs 102 a to 102 p and sets “1” in the latched status 113. Therefore, even when the connection between the operation opening prize detection sensor 245 and the control side CPU 304 is disconnected, the control IC 271 can continue to acquire the jackpot random number corresponding to the present prize.

  In addition, even if the detection signal SG4 input to the control IC 271 rises, if an event that "1" is not set to the latched status 113 occurs continuously, the control IC 271 is a management computer for the game hall. Is configured to transmit an abnormal signal. For this reason, the manager of the gaming hall can grasp the disconnection state, and can perform maintenance for eliminating the disconnection state at timing when the player is not at a disadvantage.

  Further, in the random number acquisition process, when the rising of the detection signal SG4 input to the control IC 271 is not detected, the latched status 113 is transmitted by transmitting a pulse signal to the CLR terminal of the latched status 113. Is cleared to "0". Thereby, the latched status 113 is periodically cleared to “0”. Even when noise enters only the input terminal TB11 of the control side CPU 304 and "1" is set to the latched status 113 triggered by the noise, a state in which "1" is set to the latched status 113 is periodical. It is possible to reduce the possibility that the control IC 271 acquires an old random number that does not correspond to a winning, due to noise.

Other Embodiments
In addition, it is not limited to the description content of embodiment mentioned above, A various deformation | transformation improvement is possible within the range which does not deviate from the meaning of this invention. For example, it may be changed as follows. Incidentally, the configurations of the following different embodiments may be applied individually to the configurations of the above-described embodiment, or may be applied in combination.

  (1) In the above-described first to third and eighth embodiments, the control circuits 103 and 303 include the CPUs 114 and 304 that execute processing using a program. The control circuits 103 and 303 may be hard circuits that do not use a program.

  For example, in the first embodiment described above, the control circuit which is a hard circuit is configured to receive the detection signal SG1 output from the start detection sensor 41a and the signal output from the control IC 148. The control circuit internally includes a timer counter capable of counting time in units of 0.1 μs. In the control circuit, when the detection signal SG1 input to the control circuit rises from the LOW state to the HI state, counting by the timer counter is started. The count by the timer counter is stopped and reset when the detection signal SG1 input to the control circuit falls from the HI state to the LOW state or when the timer counter counts up to 12.8 μs.

  When the timer counter counts up to 12.8 μs in the control circuit, a latch signal is transmitted to the latch register 102, and numerical information stored in the random number counter 105 is written to the latch register 102. Also, at the same timing, the signal output from the control circuit to the input terminal TA2 of the control IC 148 rises from the LOW state to the HI state, and the latched status 113 is set to "1". The signal representing the state of the latched status 113 being output from the control circuit to the input terminal TA2 of the control IC 148 rises from the HI state to the LOW state by the control IC 148 transmitting a pulse signal to the control circuit. Go down.

  (2) In the first to eighth embodiments described above, the control ICs 148 and 271 and the hard random number circuits 146 and 267 are integrated into one chip with respect to the main control boards 141 and 261, Each may be configured separately as a chip.

  (3) In the first to seventh embodiments described above, when the player operates the stop buttons 42 to 44, processing for using the latched status is performed, and random numbers for lottery May be acquired. For example, in the above-described first embodiment, when the stop buttons 42 to 44 are in the depressed state, control is performed by the same processing as in the case where the start lever 41 is in the depressed state in the above-described first embodiment. The IC 148 may be configured to acquire the numerical value information of the random number output from the latch register 102.

  Specifically, operation detection signals output from the stop detection sensors 42a to 44a (FIG. 5) are input to the control IC 148 and the control CPU 114, respectively. The operation detection signal is a signal that rises from the LOW state to the HI state when the stop buttons 42 to 44 are in the depressed state, and returns from the HI state to the LOW state when the depressed state is released.

  The control-side CPU 114 sends a latch signal to the latch register 102 when the step buttons 42 to 44 are depressed and the depressed state continues for 12.8 μs, and the latched status 113 is “1”. Set ". As a result, the numerical value information updated by the random number counter 105 is stored in the latch register 102, and the numerical value information is output to the control IC 148.

  The control IC 148 outputs the output from the latch register 102 on condition that the operation detection signal input to the control IC 148 reaches from the LOW state to the HI state and that the latched status 113 is set to “1”. Obtained numerical information as a random number for lottery. By using the latched status 113, it is possible to use a random number for lottery corresponding to the operation timing of the stop buttons 42 to 44 while suppressing the influence of noise.

  (4) As in the fourth to seventh embodiments described above, a configuration in which two or more random numbers are acquired with each of the start timing and the end timing of the operation of the start lever 41 as a trigger for random number acquisition Unlike the first embodiment to the third embodiment, in the configuration in which one random number is acquired triggered by one timing in the operation of the start lever 41, when the start lever 41 is operated, each reel 32L, 32L, The process of starting the rotation of 32M and 32R may be performed prior to the lottery process (step S411) of the normal process (FIG. 10).

  For example, in the first embodiment described above, after the acceptance prohibition process is executed in step S410 of the normal process (FIG. 10), each reel 32L, 32M, 32L, 32M, 32L is executed before the lottery process is executed in step S411. The configuration may be such that a rotation start process for starting the rotation of 32R is executed. Thus, the game can be started without an interval from the operation of the start lever 41 by the player. In addition, by executing the lottery process using the standby time until each reel 32L, 32M, 32R moves from the acceleration period to the constant speed period, the operation of the stop button 42 to 44 is invalidated due to the lottery process. It is possible to suppress the possibility that the waiting time to be

  In addition, a predetermined delay time is provided from when the start lever 41 is operated to when the control IC 148 acquires a random number, and the control IC 148 sets the respective reels 32L, 32L before the predetermined delay time elapses. It is good also as composition which performs rotation start processing which starts rotation of 32M and 32R. By performing the rotation start process between the time when the start lever 41 is operated and the control IC 148 acquires a random number, the game can be started without leaving a space from the operation of the start lever 41 by the player. Further, compared with a configuration in which the control IC 148 executes both the lottery process and the rotation start process after the predetermined delay time, the processing load after the control IC 148 acquires the random number can be reduced.

  (5) The abnormality notification sound may be output intermittently from the speaker 65 of the slot machine 10 when the abnormality notification process is performed. In addition, when the event that triggers the execution of the abnormality notification process is continued, the level of the abnormality notification may be increased.

  A specific configuration will be described with reference to FIG. 5 of the above-described first embodiment. The sub MPU 152 (FIG. 5) receives an abnormality signal and an abnormality release signal output from the control IC 148, respectively. When the abnormality signal switches from the LOW state to the HI state, the sub MPU 152 sets an abnormality flag indicating that the abnormality is in the sub RAM 154 (FIG. 5), and the abnormality release signal changes from the LOW state to the HI state. When it rises up, the sub MPU 152 cancels the abnormality flag set in the sub RAM 154.

  When the abnormality signal input from the control IC 148 is in the HI state and the abnormality flag is set in the sub RAM 154, the sub MPU 152 executes a process for outputting an alarm sound from the speaker 65. As a result, it can be intermittently notified that the connection between the start detection sensor 41a and the control side CPU 114 is disconnected.

  (6) In the fourth to seventh embodiments described above, in the depressing operation of the start lever 41 performed in the state where the game can be started, the depressed state of the start lever 41 is for a predetermined time or more. If continued, a notification may be given to urge the player to release the pressed state of the start lever 41.

  Specifically, in the fourth embodiment described above, the first management circuit 403 (FIG. 39) outputs a notification signal to the control IC 148. When the detection signal SG2 input to the first management circuit 403 rises from the LOW state to the HI state, the first management circuit 403 starts counting time by the timer counter. The first management circuit 403 transmits a latch signal to the first latch register 407 when the timer counter counts 12.8 μs, and outputs the latch signal to the control IC 148 when the timer counter counts three seconds. Raise the notification signal from the LOW state to the HI state.

  The control IC 148 transmits a command serving as a trigger for notifying the sub MPU 152 to release the depression state when the notification signal input from the first management circuit 403 rises from the LOW state to the HI state. . The sub MPU 152 that has received the command executes notification using the speaker 65 and the image display device 66 to prompt the release of the pressed state. As a result, it is possible to prevent the player from continuing pressing the start lever 41 unconsciously, and to obtain a state in which the second random number is acquired at a normal timing.

  (7) In the first to third and eighth embodiments described above, the control side CPUs 114 and 304 transmit the T terminal 113b (FIG. 6, FIG. 32, FIG. 66) of the latched status 113. Output terminal TB3 (FIG. 6, FIG. 32, FIG. 66) for outputting a pulse signal and an output terminal TB4 for outputting a latch signal to the latch register 102 from the control side CPUs 114 and 304 (FIG. 6, FIG. 32 and FIG. 66) may be the same output terminal.

  For example, one signal line extending from the output terminal TB3 of the control side CPUs 114 and 304 to the T terminal 113b of the latched status 113 is branched into two signal lines on the control circuit 103 and 303, and the branched signal lines While one is connected to the T terminal 113 b of the latched status 113 and the other of the signal lines after branching is connected to the latch register 102, the output terminal TB4 of the control side CPUs 114 and 304 is omitted. Can.

  In this case, when the control side CPUs 114 and 304 output a latch signal to the latch register 102, “1” can be set to the latched status 113 at the same timing.

  (8) In the first to third and eighth embodiments described above, the control side CPUs 114 and 304 (FIG. 6, FIG. 32, and FIG. 66) are the random number counter 105 of the update circuit 101 (FIG. 6). , And 66) may be configured to be able to acquire numerical value information of random numbers stored in FIG. In this case, when the detection signals SG1 and SG4 input to the input terminals TB1 and TB11 of the control side CPUs 114 and 304 rise from the LOW state to the HI state and the HI state continues for 12.8 μs or more, the control side CPU 114, In step S 304, the random number information stored in the random number counter 105 is acquired and stored in the RAMs 116 and 306. Then, when the control IC 148 or 271 comes to the timing to acquire the random number, the control IC 148 or 271 can acquire the numerical value information of the random number from the control side CPUs 114 and 304.

  (9) In the first embodiment, the second embodiment and the eighth embodiment described above, after “1” is set in the latched status 113 (FIG. 6, FIG. 66), the latched status 113 When a specific release condition is satisfied without being cleared to “0”, the control side CPUs 114 and 304 (FIG. 6, FIG. 66) may be configured to clear the latched status 113 to “0”. For example, after a predetermined time (for example, 3 ms or 8 ms) has elapsed from the timing when the latched status 113 is set to “1”, the latched status 113 is set when the latched status 113 is set to “1”. It may be configured to clear "0".

  If the state in which “1” is set to the latched status 113 continues for 3 ms, the timer interrupt process executed in the 1.49 ms cycle in the first and second embodiments described above is executed twice or more Be done. In addition, when the state in which “1” is set to the latched status 113 continues for 8 ms or more, the timer interrupt process executed in the 4 ms cycle in the eighth embodiment described above is executed twice or more.

  By limiting the state in which the latched status 113 is set to “1” by the control side CPUs 114 and 304 for a certain period of time, the control IC 148 reliably grasps that the latched status 113 is set to “1”. While being possible, it can be set as the composition which can be canceled early on the state where "1" is set to latched status 113 under the influence of noise. In this case, the control IC 148 or 271 can omit the process of clearing the latched status 113 to “0” in the timer interrupt process.

  (10) In the first to third embodiments described above, the control side CPU 114 (FIG. 6, FIG. 32) is input to the input terminal TB1 (FIG. 6, FIG. 32) of the control side CPU 114. The latch signal is always transmitted on condition that the detection signal SG1 changes from the LOW state to the HI state and the HI state continues for 12.8 μs, but the T terminal of the latched status 113 at the same timing as the timing to transmit the latch signal. Transmitting a pulse signal to 113b (FIG. 6, FIG. 32) to set “1” to the latched status 113 is limited to the case where “1” is set to the start possible flag 144 a (FIG. 5) It is good also as composition.

  The control side CPU 114 transmits a latch signal on condition that the detection signal SG1 input to the input terminal TB1 of the control side CPU 114 changes from the LOW state to the HI state, but the HI state of the detection signal SG1 is The configuration may be such that “1” is set to the latched status 113 as a condition of continuing 12.8 μs. Thereby, the difference between the timing when the player operates the start lever 41 and the timing when the random number is written to the latch register 102 (FIG. 6, FIG. 32) can be reduced while suppressing the influence of noise less than 12.8 μs. it can.

  (11) The process for acquiring the first random number is executed triggered by the start of the operation of depressing the start lever 41, and the second random number is triggered by the end of the operation of depressing the start lever 41. In the fourth to seventh embodiments in which the process for acquiring the second ID is executed, the second start instruction is issued even if a predetermined time has elapsed after the control IC 148 acquires the numerical information of the first random number. If “1” is not set in the flag 144h, the control IC 148 may acquire numerical value information of the second random number that does not become the second cherry winning in the lottery process of the winning combination. The normal processing (FIG. 42) of the fourth embodiment described above will be specifically described below as an example. The description of the same configuration as that of the normal process (FIG. 42) of the fourth embodiment described above will be omitted.

  After acquiring numerical value information of the first random number in step S1707, the control IC 148 starts the countdown by the upper limit timer before clearing the first start instruction flag 144g to "0" in step S1708. The length of time which the upper limit timer counts is preset in the main RAM 144. The length of time that the upper limit timer counts is set so that the time from when the player starts operating the start lever 41 until the player can press each stop button 42 to 44 is not too long. It is. The specific value of the time counted down by the upper limit timer is grasped at the design stage of the slot machine 10.

  After acquiring the numerical information of the addition random number in step S1712 of the normal process (FIG. 42), the control IC 148 determines whether the countdown by the upper limit timer is completed. If the countdown by the upper limit timer has not ended, the control IC 148 proceeds to step S1713 and waits until the second start instruction flag 144h is set to "1". At this time, the control IC 148 repeats the determination of whether or not the countdown by the upper limit timer is completed, and the determination of whether or not “1” is set in the second start instruction flag 144 h in step S1713.

  Then, if “1” is set in the second start command flag 144 h before the countdown by the upper limit timer ends (step S 1713: YES), the control IC 148 performs the second process in step S 1715 performed thereafter. Get numerical information of random numbers. On the other hand, when the second start command flag 144h is not set to "1" at the timing when the countdown by the upper limit timer ends, the control IC 148 acquires the number information for disconnection in step S1715 performed thereafter. .

  The numerical information for the deviation is the numerical information stored in advance in the main ROM 143, and the lottery process of the combination performed using the numerical information of the first random number acquired in step S1707 and the numerical information for the deviation. In FIG. 43, it is numerical information set so as not to be the second cherry winning.

  As described above, when “1” is not set in the second start command flag 144 h even if a predetermined time has elapsed since the control IC 148 acquired the numerical information of the first random number, the numerical value for the control IC 148 is out. When the fall of the detection signal SG2 that has risen to the HI state is not detected for a long time, as in the case where the pressing operation of the start lever 41 is continued for a long time by acquiring information and proceeding to the processing of step S1714 and thereafter. Can also start the game. In this case, the player who intentionally depresses the start lever 41 does not obtain a game result that is more advantageous than a player who performs a normal operation by making a lottery result in which the second cherry role is not won. can do.

  (12) After acquiring the first random number with the rise of detection signal SG2 (FIG. 39) as one condition, the fourth random number is acquired with the fall of detection signal SG2 as one condition. In the seventh to seventh embodiments, "1" is set in the latched status in synchronization with the timing at which the numerical value information of the random number is written to the latch registers 102, 407 to 409 (FIG. 39, FIG. 60, FIG. 61). And the numerical value information of the random numbers stored in the latch registers 102, 407 to 409 is acquired by the control IC 148 under the condition that "1" is set to the latched status. It may be The fourth embodiment described above will be specifically described below as an example. Description of the same configuration as that of the fourth embodiment described above will be omitted.

  The first management circuit 403 (FIG. 39) has a first latched status, and the state of the first latched status is output to the control IC 148, and the second management circuit 404 (FIG. 39). 39) has a second latched status, and the state of the second latched status is output to the control IC 148. Here, the first latched status is a storage area in which "1" is set in synchronization with the timing when the random number is written to the first latch register 407, and the second latched status is a random number in the second latch register 408. It is a storage area in which “1” is set in synchronization with the timing at which is written.

  The control IC 148 (FIG. 39) detects that the start enable flag 144a (FIG. 39) is set to “1” in the start command setting process (FIG. 41) and the rising of the detection signal SG2 input to the control IC 148 is detected. Under the condition that the first latched status is set to "1", the first start command flag 144g (FIG. 39) is set to "1", and the first latched status is set to "0." Output a signal to clear.

  Further, in the start command setting process, the control IC 148 sets “1” to the start enable flag 144 a, that the falling of the detection signal SG2 input to the control IC 148 is detected, and the second latched Under the condition that "1" is set in the status, the second start command flag 144h (FIG. 39) is set to "1", and a signal for clearing the second latched status to "0" is output. .

  Thus, when the player operates the start lever 41, the numerical information of the random number written in the first latch register 407 (FIG. 39) can be used as the first random number triggered by the start of the current operation. The numerical value information of the random number written in the second latch register 408 (FIG. 39) upon completion of the current operation can be used as the second random number.

  On the other hand, after the detection signal SG2 output from the start detection sensor 41a rises, before the passage of 12.8 μs from the rise of the detection signal SG2, it becomes the execution timing of the start command setting process (FIG. 41). At timing when the old random number information is written to the first latch register 407 before the operation of the start lever 41 this time, acquisition of the first random number by the control IC 148 is not performed. In this case, the game is not started with the operation of the start lever 41 this time.

  Also, after the detection signal SG2 output from the start detection sensor 41a falls, before the passage of 12.8 μs from the fall of the detection signal SG2, the execution instruction setting process (FIG. 41) is executed timing, When the two random numbers become the numerical value information of the old random number written in the second latch register 408 before the operation of the start lever 41 this time, the numerical value information for deviation is acquired as the second random number. The numerical information for the deviation is numerical information stored in advance in the main ROM 143, and in the lottery process (FIG. 43) of the combination performed using the numerical information of the first random number and the numerical information for the deviation, It is numerical information set so as not to be the second cherry winning.

  As described above, the control IC 148 acquires the first random number under the condition that “1” is set to the first latched status, and “1” is set to the second latched status. The control IC 148 acquires the second random number with one of the conditions, so that both the first random number and the second random number used for the lottery performed in each game correspond to the operation of the start lever 41 this time. The probability of becoming a random number can be increased, and the operation timing of the start lever 41 by the player can be greatly reflected on the game result.

  Further, after the detection signal SG2 output from the start detection sensor 41a falls, before execution of 12.8 μs from the fall of the detection signal SG2, execution timing of the start command setting process (FIG. 41) is reached. In the next start instruction setting process, determination on the state of the second latched status may be performed again. In the second determination, when "1" is set to the second latched status, the current numerical information stored in the second latch register 408 is acquired as the second random number, and the second latched When “1” is not set in the status, numerical information for deviation is acquired as a second random number. Thereby, in a mode that is not disadvantageous to the player, it is possible to increase the probability that both the first random number and the second random number used for the lottery performed in each game will be random numbers corresponding to the operation of the start lever 41 this time. it can.

  (13) In the fourth to seventh embodiments described above, instead of the configuration in which the rotation start process is executed before the second random number is acquired after the first random number is acquired, The rotation start process may be executed after the second random number is acquired. Here, the rotation start process is a process for starting rotation of the reels 32L, 32M, 32R (FIG. 3).

  (14) The gaming machine main body supported in an openable and closable manner by the outer frame is provided with the storage section and the loading device, and the start lever is operated after the predetermined number of gaming balls stored in the storage section are loaded by the loading device. The present invention can also be applied to a gaming machine in which a pachinko machine and a slot machine are fused by starting to rotate the reels.

<About the invention group extracted from the above embodiment>
Hereinafter, the features of the invention group extracted from the above-described embodiment will be described while showing effects and the like as necessary. In the following, for ease of understanding, the corresponding configuration in the above embodiment is appropriately shown in parentheses or the like, but the present invention is not limited to the specific configuration illustrated in the parentheses or the like.

<Feature A group>
Features A1. Numerical updating means (updating circuit 101) for updating numerical information;
Based on the occurrence of the first acquisition trigger (the rise of the detection signal SG1 inputted to the input terminal TB1 of the control side CPU 114, the rise of the detection signal SG4 inputted to the input terminal TB11 of the control side CPU 304) Memory execution means (the control circuit 103 that executes the process of step S 707) that stores the numerical information updated by the numerical update means in the acquisition storage means (the latch register 102), and the function that executes the process of step S 1010 in the control circuit 103 , A function of executing the process of step S1509 in the control circuit 103),
Based on the occurrence of the second acquisition trigger (the rise of the detection signal SG1 input to the input terminal TA1 of the control IC 148, the rise of the detection signal SG4 input to the input terminal TA1 of the control IC 271) And control means for executing special processing using numerical information stored in the means (function of executing processing of step S503 to step S509 in control IC 148, function of executing processing of step S3302 to step S3312 in control IC 271) ,
In a gaming machine provided with
An information setting unit (step in the control CPU 114) for setting acquired information (latched status 113) when the first acquisition trigger occurs and the numerical value is stored in the acquired storage unit; The function of executing the process of S 708, the function of executing the process of step S 1010 in the control side CPU 114, and the function of executing the process of step S 1510 in the control side CPU 114)
A game machine characterized in that the control means executes the special processing under at least one condition that the acquired information is set when the second acquisition opportunity is generated.

  According to the feature A1, the control means is configured to perform the special process on the condition that the acquired information is set. Thus, the special process performed by the control means can always be the special process using the numerical information stored in the acquisition storage means at the first acquisition opportunity. It is possible to avoid the situation where numerical information other than the numerical information stored in the acquisition storage means is used at the first acquisition opportunity in the special process performed by the control means.

Feature A2. The first acquisition trigger is a predetermined event (an event that the detection signal SG1 output from the start detection sensor 41a rises from the LOW state to the HI state, the detection signal SG4 output from the operation opening winning detection sensor 245 is the LOW state) Occurs when the situation corresponding to the occurrence of an event that rises to the HI state continues for a predetermined period (for example, 12.8 μs),
The second acquisition timing occurs when the monitoring timing (the timing at which the timer interrupt process is executed in the control IC 148) is reached and the situation corresponding to the occurrence of the predetermined event (the period in which the game can be started). The gaming machine according to feature A1, characterized in that:

  According to the feature A2, the monitoring timing comes, and the numerical information used in the special processing executed when the second acquisition trigger occurs is based on the occurrence of the first acquisition trigger due to the continuation of the predetermined event for a predetermined period. It can be numerical information to be stored.

  Feature A3. The storage execution means causes the acquisition storage means to store the numerical information updated by the numerical value update means even when the acquired information is already set, when the first acquisition trigger occurs. The gaming machine according to feature A1 or A2, characterized in that

  According to the feature A3, by using the numerical value information stored in the acquisition storage means as the numerical value information stored based on the occurrence of the latest first acquisition trigger, the numerical value information used by the control means in the special process is the latest. It can be based on the first acquisition opportunity.

Feature A4. The control means
Determining means for determining whether or not the second acquisition trigger has occurred each time the monitoring timing (the timing when the timer interrupt process is executed in the control IC 148) (function to execute the processing of step S302 to step S304 in the control IC 148 A function of executing the processing of step S803 to step S805 in the control IC 148, a function of executing the processing of step S3502 to step S3504 in the control IC 271),
A unit that executes the special processing with at least one condition that the acquired information is set when it is determined that the second acquisition trigger is generated by the determination unit (step S306 of the control IC 148 The function to execute the process, the function to execute the process of step S407 to step S411 in the control IC 148, the function to execute the process of step S3302 to step S3304 in the control IC 271, the function to execute the process of step S3507 and step S3508 in the control IC 271 )When,
A unit for canceling the setting state of the acquired information when the acquired information is set although it is determined that the second acquisition trigger has not occurred at the monitoring timing by the determination unit (step in control IC 148 A function of executing the process of S315, a function of executing the process of step S809 in the control IC 148, a function of executing the process of step S3510 in the control IC 271),
A game machine according to any one of features A1 to A3, characterized in that it comprises:

  According to the feature A4, when the occurrence of the second acquisition trigger is not confirmed at the monitoring timing but the acquired information is set, the setting of the acquired information is canceled. In this configuration, the special processing is not performed until both the occurrence of the second acquisition trigger and the setting of the acquired information are confirmed at the monitoring timing. Thereby, the possibility that the control means executes the special processing using numerical information other than the numerical information based on the latest first acquisition opportunity can be reduced.

Feature A5. In a situation where the acquired information is set, when the numerical information stored in the acquired storage unit is used by the control unit, a first release unit (the control IC 148 cancels the set state of the acquired information A function of executing the processing of step S308, a function of executing the processing of step S809 in the control IC 148, a function of executing the processing of step S1515 in the control CPU 114, a function of executing the processing of step S3510 in the control IC 271);
When the setting state of the already acquired information is not canceled by the first releasing unit even when a specific period (for example, 5 ms) elapses in the situation where the already acquired information is set, the set state of the already acquired information is cancelled. Second release means (function of executing the process of step S1517 in the control side CPU 114);
A game machine according to any one of the features A1 to A4, comprising:

  According to the feature A5, by canceling acquired information set due to noise or the like after a specific period, the control unit performs numerical information not based on the occurrence of the first acquisition trigger due to noise or the like. It can be used to reduce the possibility of performing special processing.

Feature A6. The control means
Determining means for determining whether or not the second acquisition trigger has occurred each time the monitoring timing (the timing when the timer interrupt process is executed in the control IC 148) (function to execute the processing of step S302 to step S304 in the control IC 148 A function of executing the processing of step S803 to step S805 in the control IC 148, a function of executing the processing of step S3502 to step S3504 in the control IC 271),
A control execution unit (steps in the control IC 148 that execute the special processing with at least one condition that the acquired information is set when it is determined that the second acquisition trigger is generated by the determination unit A function to execute the processing of S306, a function to execute the processing of steps S407 to S411 in the control IC 148, a function to execute the processing of steps S3302 to S3304 in the control IC 271, and a processing of steps S3507 and S3508 in the control IC 271 Function) and,
The control execution means, when it is determined that the second acquisition trigger is generated by the determination means at a predetermined monitoring timing, but the acquired information is not set, the control execution means performs the monitoring timing next to the monitoring timing. The gaming machine according to any one of the features A1 to A5, wherein the special process is executed under at least one condition that the acquired information is set.

  According to the feature A6, although it is determined that the second acquisition opportunity has occurred at the monitoring timing, when the acquired information is not set, the control means sets the acquired information at the next monitoring timing. The special processing is executed with one of the conditions. As a result, after the occurrence of the second acquisition trigger, if the monitoring timing comes before the acquisition completion information is set based on the occurrence of the first acquisition trigger, the control means is the second acquisition trigger of this time. A special process based on the occurrence of the first acquisition trigger can be executed without invalidating the occurrence.

  Feature A7. The control execution means, when it is determined that the second acquisition trigger has occurred by the determination means at a predetermined monitoring timing, but the acquired information is not set, the control execution means performs the monitoring timing next to the monitoring timing. Even if it is determined that the second acquisition opportunity has not occurred by the determination means, the game according to the feature A6, wherein the special process is executed with at least one condition that the acquired information is set. Machine.

  According to the feature A7, after the first monitoring timing, the first monitoring timing at the second monitoring timing even if a new second acquisition trigger does not occur before the second monitoring timing occurs. The special processing based on the occurrence of the second acquisition trigger grasped in As a result, after the occurrence of the second acquisition trigger, if the monitoring timing comes before the acquisition completion information is set based on the occurrence of the first acquisition trigger, the control means is the second acquisition trigger of this time. A special process based on the occurrence of the first acquisition trigger can be executed without invalidating the occurrence.

  Feature A8. The control means executes a predetermined process execution means (control IC 148) when a situation where the second information acquisition trigger occurs but the acquired information is not set occurs a predetermined number of times (for example, three times) Of the control IC 148, the function of executing the processing of step S1309 in the control IC 148, and the function of executing the processing of step S3603 in the control IC 271). A game machine according to any one of features A1 to A7 characterized in that.

  According to the feature A8, the abnormal state is eliminated and the occurrence of the second acquisition trigger is invalidated by executing the predetermined process when the state where the acquired information is not set is repeated even if the second acquisition trigger occurs. It can be in a state where

  Feature A9. The predetermined process execution means executes abnormality notification (the process of step S312 in the control IC 148, the process of step S903 in the control IC 148, the process of step S1309 in the control IC 148, the process of step S3603 in the control IC 271) as the predetermined process. A game machine according to feature A8, characterized by performing processing for:

  According to the feature A9, it is possible to eliminate the abnormal state in which the occurrence of the second acquisition trigger is invalidated by executing the abnormality notification to notify the administrator of the gaming hall that the state is abnormal.

  Feature A10. The predetermined process execution means is configured to store, as the predetermined process, the numerical information updated by the numerical value update means in the acquisition storage means even in a situation where the first acquisition opportunity has not occurred. A game machine according to feature A8 or A9, characterized by executing processing (function to execute processing of step S904 in control IC 148, processing of step S1001, step S1003 and step S1012 in control side CPU 114).

  According to the feature A10, even when the first acquisition trigger does not occur due to the disconnection or the like, the update of the numerical information stored in the acquisition storage unit can be performed.

Characteristics A11. The predetermined process execution means transmits acquisition instruction information (latch indication signal) to the storage execution means as the predetermined process.
The gaming machine according to the feature A10, wherein the storage execution unit stores the numerical information updated by the numerical value update unit in the acquisition storage unit when the acquisition instruction signal is received.

  According to the feature A11, the control means causes the storage execution means to store the numerical information updated by the numerical value update means in the acquisition storage means, thereby obtaining the acquisition storage means even if the first acquisition opportunity does not occur. The numerical information stored in can be updated.

  Feature A12. The information setting means sets the acquired information even when the numerical value information is stored in the acquisition storage means based on the reception of the acquisition instruction signal. Gaming machine.

  According to the feature A12, even when the numerical value information updated by the numerical value update unit is stored in the acquisition storage unit triggered by the reception of the acquisition instruction information, the information setting unit is configured to set the acquired information. Means can execute special processing using numerical information.

Feature A13. It detects whether or not a predetermined event (an event that the start lever 41 is operated to be depressed, an event that the gaming ball is won in the operation port winning detection sensor 245) is detected, and the predetermined event has not occurred In this case, the output state of the detection information becomes the first state (LOW state of the detection signal SG1, LOW state of the detection signal SG4) and the output state of the detection information becomes the second state (detection The detection means (start detection sensor 41a, operation port winning detection sensor 245) which becomes HI state of the signal SG1 and HI state of the detection signal SG4 is provided,
The first acquisition trigger occurs when the output state of the detection means is switched from the first state to the second state,
The gaming machine according to any one of the features A1 to A12, wherein the second acquisition opportunity occurs when the output state of the detection unit is the second state.

  According to the feature A13, when the output state of the detection information is switched from the first state to the second state, the second acquisition trigger is generated when the output state of the detection information is the second state. The processing load for the control means to grasp the second acquisition opportunity can be reduced compared to the configuration in which the second acquisition opportunity occurs.

  Feature A14. The information setting means does not set the acquired information even when the output state of the detection means is switched from the first state to the second state in a restricted state (a state where game start is not possible). The gaming machine according to feature A13.

  According to the feature A14, since the acquired information is not set in the restricted situation, the control means can be prevented from performing the special process under the restricted situation.

  Feature A15. The gaming machine according to feature A14, wherein the restriction situation is established when the special process is executed by the control means.

  According to the feature A15, when the control means performs the special process, the configuration is in the restricted state, so that when the process based on the result of the special process is performed after the special process, the result of the special process is handled. It is possible to avoid a situation where new acquired information is set and new special processing is started before completion of the processing.

Feature A16. The control means
A unit configured to set information indicating the restricted state when the special process is performed (a function of executing the process of step S404 in the control IC 148 and the process of step S1405 in the control IC 148);
A unit that cancels the setting state of the information indicating the restricted state when the restricted state ends (a process of step S409 in the control IC 148, a function of executing the process of step S1408 in the control IC 148);
The gaming machine according to feature A15, comprising:

  According to the feature A16, the setting of the information indicating that the control means is in the restricted state, and the cancellation of the setting state of the information, the information setting means starts the restricted state based on the information. The timing and the end timing can be grasped to determine whether or not the situation is limited.

  Feature A17. The control means executes notification of abnormality based on the occurrence of a reference number of times (for example, three times) when the output state of the detection means is the second state and the acquired information is not set. (Step S309 to step S311 in the control IC 148, step S901 and step S902 on the control IC 148, step S1306 to step S1309 in the control IC 148, step S3601 and step S3062 in the control IC 271) A game machine according to any one of features A13 to A16, characterized in that it comprises means for performing the processing of

  According to the feature A17, even when the output state of the detection means is the second state, the control means executes the abnormality notification to cancel the abnormal state when the acquired information is not set for the reference number of times. be able to.

Feature A18. When the special processing is executed, a unit game is executed in the game execution means (image display device 66),
The storage execution means does not store the numerical information in the acquisition storage means even if the output state of the detection means is switched from the first state to the second state during execution of the unit game, or the acquisition The gaming machine according to any one of the features A13 to A17, wherein the end information is not set.

  According to the feature A18, in the configuration in which the storage execution unit does not store the numerical information in the acquisition storage unit during the unit game or in the configuration in which the acquired information is not set, the acquired information is not set. It is possible to reduce the possibility of executing the following special processing during the game.

  Note that any one or more of the features A1 to A18, the features B1 to B7, the features C1 to C16, and the features D1 to D5 may be applied to any one of the features A1 to A18. . This makes it possible to produce a synergistic effect by the combined configuration.

  The invention of the feature group A can solve the following problems.

  Pachinko machines, slot machines and the like are known as a type of gaming machine. In these gaming machines, the progress of the game is controlled by executing various controls in the control device. Further, numerical information is used when executing various controls in the control device.

  For example, there is known a configuration in which an internal lottery is performed based on the establishment of a predetermined lottery condition, and a bonus is given to a player according to the result of the internal lottery. In this internal lottery, when predetermined lottery conditions are satisfied, numerical information is acquired from the updating means for updating numerical information for lottery, and whether the acquired numerical information corresponds to the winning information or not A determination is made. There is also known a configuration in which numerical information is acquired based on the establishment of a predetermined acquisition condition, and a specific effect or notification is performed based on the result of an internal lottery performed using the numerical information.

  Here, in a gaming machine such as that illustrated above, it is necessary to preferably obtain numerical information at the time of lottery, and there is still room for improvement in this respect.

<Feature B group>
Feature B1. There are predetermined events (events in which the detection signal SG1 output from the start detection sensor 41a rises from the LOW state to the HI state, events in which the detection signal SG4 output from the operation port winning detection sensor 245 rises from the LOW state to the HI state) It is detected whether or not a predetermined event has occurred, and when the predetermined event has not occurred, the output state of the detection information becomes the first state (LOW state of detection signal SG1, LOW state of detection signal SG4) and the predetermined event occurs. Detection means (start detection sensor 41a, operation opening winning detection sensor 245) in which the detection information output state is the second state (HI state of detection signal SG1, HI state of detection signal SG4)
The information setting means (the control side CPU 114) executes the process of step S708 in the special information (latched status 113) based on the fact that the output state of the detection means is switched from the first state to the second state. Function to execute the processing of step S1010 in the control side CPU 114, and the function to execute the processing of step S1510 in the control side CPU 114);
Control means for executing a specific process when the output state of the detection means is the second state and the special information is set (function for executing the process of steps S503 to S509 in the control IC 148, A function of executing the processing of step S3302 to step S3312 in the control IC 271),
A game machine characterized by comprising:

  According to the feature B1, the control means confirms that the special information to be set is set based on the fact that the output state of the detection means is switched from the first state to the second state by the information setting means. The condition that the output state of the detection means is switched from the first state to the second state even if the control means itself does not know that the output state of the detection means has switched from the first state to the second state As a specific process can be performed.

  Therefore, as compared with the configuration in which the control means itself monitors the switching of the output state of the detection means from the first state to the second state, it is determined whether the condition for executing the specific process is satisfied. Processing load can be reduced.

  Further, since the control means is configured to execute the identification process based on the output state of the detection means and the special information, the control means is compared with the configuration to execute the identification process only based on the set special information. , Noise and the like can be reduced.

  Feature B2. The information setting means is characterized in that the special information is not set even if the output state of the detection means is switched from the first state to the second state in a restricted state (a state where game start is not possible). The gaming machine according to feature B1.

  According to the feature B2, the special information is not set even if the output state of the detection means is switched from the first state to the second state in the limited situation, so the possibility of the control means executing the specific processing in the limited situation is reduced. be able to.

  Feature B3. The gaming machine according to the feature B2, wherein the restriction situation occurs when the specific process is executed by the control means.

  According to the feature B3, since the restriction status is set when the specific process is executed, the control is performed while the process performed in the mode according to the result of the specific process is performed after the specific process. The means can reduce the possibility of executing the specific process again, and can reflect the result of one specific process on the process performed after the specific process.

Feature B4. The control means
A unit configured to set the information indicating the restricted state when the specific process is executed (the function of executing the process of step S404 in the control IC 148 and the process of step S1405 in the control IC 148);
A unit that cancels the setting state of the information indicating the restricted state when the restricted state ends (a process of step S409 in the control IC 148, a function of executing the process of step S1408 in the control IC 148);
The gaming machine according to feature B3, comprising:

  According to the feature B4, when the specific process is executed, the information indicating the restriction situation is set to be the restriction situation, and the setting of the information indicating the restriction situation when the restriction situation is ended The configuration is to be released. For this reason, the information setting means can determine whether or not there is a restriction situation based on the setting state of the information indicating that the restriction situation is concerned.

  Feature B5. The control means is notified of an abnormality based on the occurrence of a reference frequency (for example, three times) when the output state of the detection means is the second state and the special information is not set. (Steps S309 to S311 in the control IC 148, steps S901 and S902 in the control IC 148, steps S1306 to S1309 in the control IC 148, and steps S3601 and S3062 in the control IC 271). A game machine according to any one of features B1 to B4, comprising means for performing a process.

  According to the feature B5, when the reference number of times where the special information is not set while the output state of the detection means is the second state occurs, the control means executes an anomaly notification as a trigger for eliminating the abnormal state. Can.

Feature B6. Numerical updating means (updating circuit 101) for updating numerical information;
Storage execution means for storing the numerical information updated by the numerical value updating means in the acquisition storage means (latch register 102) based on the fact that the output state of the detection means is switched from the first state to the second state (The function of executing the process of step S707 in the control circuit 103, the function of executing the process of step S1010 in the control circuit 103, and the function of executing the process of step S1509 in the control circuit 103)
The game machine according to any one of the features B1 to B5, wherein the information setting means sets the special information when the numerical value information is stored in the acquisition storage means.

  According to the feature B6, since the special information is set when the numerical information is stored in the acquisition storage unit, the numerical information used in the specific processing performed on the condition that the special information is set The numerical value information stored in the acquisition storage unit from the update circuit can be set based on the fact that the output state of the detection means is switched from the first state to the second state.

Feature B7. When the special processing is executed, a unit game is executed in the game execution means (image display device 66),
The storage execution means does not store the numerical information in the acquisition storage means even if the output state of the detection means is switched from the first state to the second state during execution of the unit game, or the acquisition The gaming machine according to feature B6, wherein the end information is not set.

  According to the feature B7, even if the output state of the detection means is switched from the first state to the second state, no special information is set during the unit game, so the possibility that the control means executes the specific processing during the unit game Can be reduced.

  Note that any one or more of the features A1 to A18, the features B1 to B7, the features C1 to C16, and the features D1 to D5 may be applied to any one of the features B1 to B7. . This makes it possible to produce a synergistic effect by the combined configuration.

  The invention of the feature B group can solve the following problems.

  Pachinko machines, slot machines and the like are known as a type of gaming machine. In these gaming machines, the progress of the game is controlled by executing various controls in the control device. Further, numerical information is used when executing various controls in the control device.

  For example, there is known a configuration in which an internal lottery is performed based on the establishment of a predetermined lottery condition, and a bonus is given to a player according to the result of the internal lottery. In this internal lottery, when predetermined lottery conditions are satisfied, numerical information is acquired from the updating means for updating numerical information for lottery, and whether the acquired numerical information corresponds to the winning information or not A determination is made. There is also known a configuration in which numerical information is acquired based on the establishment of a predetermined acquisition condition, and a specific effect or notification is performed based on the result of an internal lottery performed using the numerical information.

  Here, in a gaming machine such as that illustrated above, it is necessary to preferably obtain numerical information at the time of lottery, and there is still room for improvement in this respect.

<Feature C group>
Feature C1. Detection means (start detection sensor 41a) for detecting whether or not a predetermined event (event in which the start lever 41 is in a depressed state) has occurred;
First acquisition means (first latch register 407) for acquiring a first lottery value (first random number) based on the detection state of the detection means;
Second acquisition means (second latch register 408) for acquiring a second lottery value (second random number) based on the detection state of the detection means;
Lottery execution means (for performing lottery using at least the first lottery value and lottery using the second lottery value, or lottery using at least the first lottery value and the second lottery value) A function of executing the processing of step S1802 to step S1812 in control IC 148, a function of executing the processing of step 2302 to step S2306 and a processing of step S2311 to step S2315 in control IC 148, a function of executing the processing of step S2501 to step S2507 in control IC 148 )When,
A game machine characterized by comprising:

  According to the feature C1, two lottery values are acquired based on the detection state of the detection means, and the lottery using the two lottery values is executed, so that it is acquired based on the detection state of the detection means The pattern of the game result determined by the lottery can be increased as compared with the configuration in which the lottery is performed by one lottery value. In addition, by using two lottery values, it is possible to set a lottery result having a winning probability lower than that of the combination having the lowest winning probability which can be set in the lottery performed using one lottery value.

Feature C2. The first acquisition unit is configured to generate the first acquisition trigger (when the detection signal SG2 output from the start detection sensor 41a rises from the LOW state to the HI state) based on the detection state of the detection unit. Get the lottery value,
The second acquisition unit is configured to receive the second acquisition trigger (when the detection signal SG2 output from the start detection sensor 41a falls from the HI state to the LOW state) based on the detection state of the detection unit. The gaming machine according to the feature C1, characterized in that 2 lottery values are obtained.

  According to the feature C2, since the timing at which the first acquisition trigger occurs and the timing at which the second acquisition trigger occurs are different, the first lottery value acquired at the first acquisition trigger and the second acquired at the second acquisition trigger (2) The possibility of synchronization with the lottery value can be reduced.

Feature C3. The detection means outputs the detection information when the output state of the detection information becomes the first state (LOW state of the detection signal SG2) when the predetermined event has not occurred and the output state of the detection information when the predetermined event has occurred Is the second state (HI state of the detection signal SG2),
The first acquisition trigger occurs based on the switching of the output state of the detection unit from the first state to the second state,
The gaming machine according to the feature C2, wherein the second acquisition opportunity is generated based on switching of the output state of the detection unit from the second state to the first state.

  According to the feature C3, the first lottery value is acquired based on the switching of the output state of the detection information from the first state to the second state, and the output state of the detection information is switched from the second state to the first state The second lottery value is acquired based on the replacement. For this reason, two lottery values can be acquired in a series of flows in which the output state of the detection information changes from the first state to the second state, and the first state is set again. Therefore, compared to the configuration in which one lottery value is acquired in the series of flows, the lottery can be used in one game without increasing the number of operations performed by the player to start one game. The number of values can be increased.

Feature C4. A numerical updating unit (updating circuit 101) for updating numerical information;
The first acquisition unit acquires, as the first lottery value, numerical information updated by the numerical update unit when the first acquisition trigger occurs.
The gaming machine according to the feature C2 or C3, wherein the second acquisition unit acquires, as the second lottery value, numerical information updated by the numerical update unit when the first acquisition trigger occurs. .

  According to the feature C4, since the trigger for acquiring the first lottery value and the trigger for acquiring the second lottery value are different from each other, the first lottery value which is the numerical information updated by the same numerical value updating means And the second lottery value can be made different, and a lottery using two different lottery values can be executed.

Feature C5. First numerical value updating means (first random number counter 416) for updating numerical information;
Second numerical value updating means (second random number counter 417) for updating numerical information;
Equipped with
The first acquisition means acquires numerical value information updated by the first numerical value update means as the first lottery value,
The gaming machine according to any one of the features C1 to C4, wherein the second acquisition means acquires numerical value information updated by the second numerical value update means as the second lottery value.

  According to the feature C5, the numerical value information updated by the first numerical value updating means is made the first lottery value, and the numerical value information updated by the second numerical value updating means different from the first numerical value updating means is the second drawing By setting it as a value, it is possible to increase the possibility that the first lottery value and the second lottery value will not be synchronized with each other. And the game result decided based on the 1st lottery value and the 2nd lottery value can be made not to be biased to a specific result.

Feature C6. The lottery execution means is
First lottery means for executing the first lottery process using the first lottery value (functions for executing the processes of steps S1801 to S1806, S1812, and S1813 in the control IC 148, the processes of steps S2301 to S2306) Function to execute)
Second lottery means for executing the second lottery process using the second lottery value (function to execute the processing of step S1807 to step S1811 in the control IC 148, function to execute the processing of step S2311 to step S2315 in the control IC 148) When,
The gaming machine according to any one of the features C1 to C5, comprising:

  According to the feature C6, since each of the first lottery value and the second lottery value is used for two lotterys in which the matters determined by the lottery are different, the lottery that can be performed in the unit game It is possible to improve the interest of the game by increasing the types.

  Feature C7. One of the lottery processes of the first lottery process and the second lottery process is executed when the result of the other lottery process becomes a specific result (for example, the first cherry won). Characteristic C6 The gaming machine described in.

  According to the feature C7, since there is a case where the second lottery process is executed according to the result of the first lottery process, and a case where the second lottery process is not executed, the first lottery process and the second lottery process are performed. It is possible to set many variations in a series of lottery processes performed using the lottery process, and can perform a deeper effect compared to the lottery performed using one lottery value .

  Feature C8. The probability that the other lottery process is executed by being the specific result in the one lottery process and the predetermined result (for example, the second cherry is won) in the other lottery process can be set in the one lottery process The gaming machine according to Feature C7, wherein the probability is lower than the lowest probability.

  According to the feature C8, a probability lower than the lowest probability settable in one lottery process is set as the probability that the predetermined lottery result will be obtained by the other lottery process executed in response to the result of one lottery process It is a structure. By setting a predetermined result having a low occurrence frequency, it is possible to give the player a special feeling when the predetermined result is obtained, and to allow the player to expect the predetermined result, so that the game can be played. Can improve the interest of

Feature C9. The lottery execution means is
A unit for deriving a group lottery value (random number for lottery) having a bit number larger than the individual bit number of each lottery value using at least the first lottery value and the second lottery value (step S2403 in the control IC 148 Function to execute processing),
A unit that executes a lottery using the set lottery value (a function of executing the processing of steps S2501 to S2507 in the control IC 148);
A game machine according to any one of the features C1 to C8, comprising:

  According to the feature C9, in one lottery using each lottery value as a probability that each result occurs in one lottery using a set lottery value of a bit number larger than the individual bit number of each lottery value It is possible to set a lower probability than the lowest probability that each result will occur.

Feature C10. The lottery execution means is
First lottery means for executing a first lottery process using the first lottery value (a function of executing the process of step S2701 in the control IC 148, a function of executing the process of step S2801 in the control IC 148);
Second lottery means (a function of executing the process of step S2703 in the control IC 148, a function of executing the process of step S2803 in the control IC 148) executing the second lottery process using the second lottery value;
The gaming machine according to feature C9, comprising:

  According to the feature C10, each of the first lottery process and the second lottery process is executed separately from the lottery using the collective lottery value. The collective lottery value is a lottery value derived based on the first lottery value and the second lottery value. By acquiring two lottery values and making three lottery values available, the number of types of lottery that can be executed is increased as compared with the configuration in which two lotterys are performed using two lottery values. The variation of the lottery result can be increased to improve the interest of the game.

Feature C11. A game execution means (the processing of step S1710 in the control IC 148), a function of executing the processing of step S2301 in the control IC 148, a step of S2402 in the control IC 148 Function to execute the processing of
After the first lottery value is acquired and before the second lottery value is acquired, the game operation in the game execution means is started, and after the second lottery value is acquired, the termination condition is The game control means (the function of executing the process of step S1719 in the control IC 148, the function of executing the process of step S2317 in the control IC 148, the control IC 148) A function of executing the process of step S2405 in
A game machine according to any one of the features C1 to C10, comprising:

  According to the feature C11, since the game operation is started after the first lottery value is acquired and before the second lottery value is acquired, the game operation is performed after the second lottery value is acquired. The difference between the time range in which the game operation is being performed and the time range in which the operation serving as a trigger for determining the game result can be reduced as compared with the configuration in which the game is started. As a result, it is possible to reduce the possibility that the player feels the time lag between the start timing and the end timing of the game operation.

Feature C12. A start operation means (start lever 41) operated to start the game operation;
The predetermined event is a state in which the start operation means is operated,
The game control means controls the game execution means to start the game operation with at least one condition that the start operation means is operated (executes the processing of step S1602 to step S1605 in the control IC 148 Function to execute the processing of step S1706 to step S1710 in the control IC 148, and the function to execute the processing of step S2301 and step S2302 in the control IC 148),
The first acquisition means is an operation corresponding state in which the detection state of the detection means corresponds to the operation of the start operation means (a state where the detection signal SG2 outputted from the start detection sensor 41a rises from the LOW state to the HI state) Acquire the first lottery value based on the fact that
The second acquisition means is a non-operation corresponding state corresponding to the non-operation of the start operation means (the detection state of the detection means has risen from the HI state to the LOW state of the detection signal SG2 output from the start detection sensor 41a) The gaming machine according to Feature C11, wherein the second lottery value is acquired based on the state (a).

  According to the feature C12, since the first lottery value and the second lottery value are acquired at different timings while operating one start operation means, the timing and the second one for acquiring the first lottery value The timing at which the lottery value is acquired may be the timing at which the operation timing of the start operation means is reflected, and the first lottery value and the second lottery value may be lottery values not synchronized with each other.

Feature C13. And an end operation means (stop buttons 42 to 44) operated to end the game operation.
The game control means
End control means for controlling the game execution means to end the game operation with at least one condition that the end operation means is operated in a situation where the game operation is being executed (step S1719 in the control IC 148 A function to execute the process, a function to execute the process of step S2317 in the control IC 148, a function to execute the process in step S2405 of the control IC 148),
Operation corresponding unit that enables control corresponding to the operation of the end operation unit after the second lottery value is acquired by the second acquisition unit (function to execute processing of step S1717 and step S1718 in control IC 148, control A function of executing the process of step S2316 in the IC 148, a function of executing the process of step S2405 in the control IC 148),
The gaming machine according to feature C12, comprising:

  According to the feature C13, control corresponding to the operation of the end operation means becomes possible at the timing after the second lottery value is acquired, and the game operation is performed under the condition that the end operation means is operated after the timing. Is terminated, the termination operation means is operated before the second lottery value is obtained, and the game operation is terminated before the second lottery value is obtained based on the operation of the termination operation means. Can be avoided.

  Feature C14. The game machine according to Feature C13, wherein the end control means executes the end control of the game operation in a mode corresponding to the lottery result of the lottery execution means.

  According to the feature C14, the state in which the gaming operation is ended is configured to be an aspect corresponding to the lottery result of the lottery execution means. Thus, the player can grasp the lottery result by seeing the state of the game execution means after the game operation is completed.

Feature C15. The game execution means is a pattern display means (each reel 32L, 32M, 32R) for variably displaying a pattern,
When the variable display of the pattern is started by the pattern display means, a constant speed period in which the variable display of the pattern becomes constant occurs after an acceleration period in which the variable display speed of the pattern is accelerated. ,
The operation corresponding means enables the control corresponding to the operation of the termination operation means after the second lottery value is acquired by the second acquisition means and after the constant speed period is reached. The gaming machine according to feature C13 or C14 characterized by the feature.

  According to the feature C15, since the timing at which the control corresponding to the operation of the end operation means by the operation corresponding means becomes possible is the timing after the constant speed period, it is before the constant speed period By operating the end operation means during an acceleration period in which the fluctuation speed of the pattern is relatively slow, it is possible to avoid the situation where the player can align the desired pattern.

Feature C16. The lottery execution means is
Even if the second lottery value is not acquired based on the acquisition of the first lottery value, the first lottery means (step in the control IC 148) executes the first lottery process using the first lottery value Function to execute the process of S2302),
Second lottery means (function of executing the process of step S2313 in the control IC 148) that executes a second lottery process using the second lottery value based on the acquisition of the second lottery value;
The gaming machine according to any one of the features C11 to C15, comprising:

  According to the feature C16, the process after the second lottery value is acquired by executing the first lottery process in the waiting time until the timing to acquire the second lottery value after acquiring the first lottery value The load can be reduced.

  Note that any one or more of the features A1 to A18, the features B1 to B7, the features C1 to C16, and the features D1 to D5 may be applied to any one of the features C1 to C16. . This makes it possible to produce a synergistic effect by the combined configuration.

  The invention of the feature C group can solve the following problems.

  Pachinko machines, slot machines and the like are known as a type of gaming machine. In these gaming machines, the progress of the game is controlled by executing various controls in the control device. Further, numerical information is used when executing various controls in the control device.

  For example, there is known a configuration in which an internal lottery is performed based on the establishment of a predetermined lottery condition, and a bonus is given to a player according to the result of the internal lottery. In this internal lottery, when predetermined lottery conditions are satisfied, numerical information is acquired from the updating means for updating numerical information for lottery, and whether the acquired numerical information corresponds to the winning information or not A determination is made. There is also known a configuration in which numerical information is acquired based on the establishment of a predetermined acquisition condition, and a specific effect or notification is performed based on the result of an internal lottery performed using the numerical information.

  Here, in a gaming machine such as that illustrated above, it is necessary to preferably obtain numerical information at the time of lottery, and there is still room for improvement in this respect.

<Feature D group>
Feature D1. Game execution means (a function of executing the processing of step S1710 in the control IC 148, a function of executing the processing of step S2301 in the control IC 148, a function of executing the processing of step S2402 in the control IC 148)
Start operation means (start lever 41) operated to start the game operation;
End operation means (stop buttons 42 to 44) operated to end the game operation;
Lottery execution means for executing a lottery with at least one condition that the start operation means is operated (function to execute the processing of step S1802 to step S1812 in control IC 148, step 2302 to step S2306 and step S2311 in control IC 148 A function of executing the process of step S2315, a function of executing the processes of step S2501 to step S2507 in the control IC 148),
The game operation is started on the condition that the start operation means is operated as at least one condition, and the operation on the end operation means is at least one condition corresponding to the result of the lottery by the lottery execution means Game control means for controlling the game execution means so that the game operation is ended (function to execute the process of step S1719 in the control IC 148, function to execute the process of step S2317 in the control IC 148, step S2405 in the control IC 148 Function to execute processing),
In a gaming machine provided with
The game control means is a start control means for starting the game operation even if the lottery by the lottery execution means is not completed based on the operation of the start operation means (steps S1602 to S1602 in the control IC 148 A gaming machine characterized by having a function of executing the processing of step S1605, a function of executing the processing of step S1706 to step S1710 in the control IC 148, and a function of executing the processing of step S2301 and step S2302 in the control IC 148. .

  According to the feature D1, since the start of the game operation performed based on the operation of the start operation means is executed even in a situation where the lottery by the lottery execution means is not completed, the lottery by the lottery execution means The time interval from the operation timing of the start operation means to the start timing of the game operation can be shortened, as compared with the configuration in which the start of the game operation is postponed until the completion of. Thus, it is possible to avoid a situation where the game operation is started with a time difference after the start operation means is operated.

  Feature D2. The game control means is an operation corresponding means (a function of executing the processing of step S1717 and step S1718 in the control IC 148, which enables control corresponding to the operation of the end operation means after the lottery by the lottery execution means is completed. The gaming machine according to the feature D1, comprising a function of executing the process of step S2316 in the IC 148 and a function of executing the process of step S2405 in the control IC 148.

  According to the feature D2, since the processing corresponding to the operation of the end operation means is possible after the completion of the lottery by the lottery execution means, the process corresponding to the operation of the end operation means in the mode corresponding to the lottery result at all times Can be performed. As a result, the player can grasp the lottery result by observing the state in which the game operation has ended.

Feature D3. The game execution means is a pattern display means (each reel 32L, 32M, 32R) for variably displaying a pattern,
When the variable display of the pattern is started by the pattern display means, a constant speed period in which the variable display of the pattern becomes constant occurs after an acceleration period in which the variable display speed of the pattern is accelerated. ,
The operation corresponding means enables control corresponding to the operation of the end operation means after the lottery by the lottery execution means is completed and after the constant speed period is reached. The gaming machine described.

  According to the feature D3, since the control corresponding to the operation of the termination operation means is performed after the constant speed period, it is before the constant speed period and the pattern fluctuation rate is relatively slow. By operating the end operation means, it is possible to avoid the situation where the player can align the desired pattern.

Feature D4. It has detection means (start detection sensor 41a) for detecting that the start operation means has been operated,
The lottery execution means is
Based on the detection state of the detection means becoming the operation corresponding state corresponding to the operation of the start operation means (the state where the detection signal SG2 outputted from the start detection sensor 41a rises from the LOW state to the HI state) First acquisition means (first latch register 407) for acquiring a first lottery value;
In the non-operation corresponding state (the state where the detection signal SG2 output from the start detection sensor 41a has risen from the HI state to the LOW state) corresponding to the non-operation of the start operation means Second acquiring means (second latch register 408) for acquiring the second lottery value on the basis of
Lottery means (control that executes a lottery using at least the first lottery value and a lottery using the second lottery value, or performs a lottery using at least both the first lottery value and the second lottery value Function to execute the process of step S1802 to step S1812 in IC 148, function to execute the process of step 2302 to step S2306 and step S2311 to step S2315 in control IC 148, function to execute the process of step S2501 to step S2507 in control IC 148) When,
Equipped with
In any one of the features D1 to D3, the start control means starts the game operation after the first lottery value is acquired and before the second lottery value is acquired. The gaming machine described.

  According to the feature D4, when the detection means is in the operation corresponding state, the first lottery value is acquired based on the start timing of the operation corresponding state, and the second drawing value based on the end timing of the operation corresponding state. Since the lottery value is acquired and the game operation is started after the first lottery value is acquired and before the second lottery value is acquired, the second lottery value is acquired. Compared with the configuration in which the game operation is started later, the possibility that the player feels the time lag can be reduced between the start timing of the operation response state and the start timing of the game operation.

Feature D5. The lottery means is
Even if the second lottery value is not acquired based on the acquisition of the first lottery value, the first lottery means (step in the control IC 148) executes the first lottery process using the first lottery value Function to execute the process of S2302),
Second lottery means (function of executing the process of step S2313 in the control IC 148) that executes a second lottery process using the second lottery value based on the acquisition of the second lottery value;
The gaming machine according to feature D4, comprising:

  According to the feature D5, the process after the second lottery value is acquired by executing the first lottery process in the waiting time until the timing to acquire the second lottery value after acquiring the first lottery value The load can be reduced.

  Note that any one or more of the features A1 to A18, the features B1 to B7, the features C1 to C16, and the features D1 to D5 may be applied to any one of the features D1 to D5. . This makes it possible to produce a synergistic effect by the combined configuration.

  The invention of the feature D group can solve the following problems.

  Pachinko machines, slot machines and the like are known as a type of gaming machine. In these gaming machines, the progress of the game is controlled by executing various controls in the control device. Further, numerical information is used when executing various controls in the control device.

  For example, there is known a configuration in which an internal lottery is performed based on the establishment of a predetermined lottery condition, and a bonus is given to a player according to the result of the internal lottery. In this internal lottery, when predetermined lottery conditions are satisfied, numerical information is acquired from the updating means for updating numerical information for lottery, and whether the acquired numerical information corresponds to the winning information or not A determination is made. There is also known a configuration in which numerical information is acquired based on the establishment of a predetermined acquisition condition, and a specific effect or notification is performed based on the result of an internal lottery performed using the numerical information.

  Here, in the gaming machine as illustrated above etc., the game needs to be played smoothly, and there is still room for improvement in this respect.

  The basic configuration of a gaming machine to which the above-described features can be applied will be shown below.

  Pachinko gaming machine: operation means operated by a player, game ball firing means for firing game balls based on the operation of the operation means, a ball passage for guiding the fired game balls to a predetermined game area, and a game A gaming machine comprising: each gaming component arranged in an area, and providing a bonus to a player when a gaming ball passes through a predetermined passing portion of the gaming components.

  Throttle type gaming machines such as slot machines: Start rotation of the orbiter based on the operation of the start operation means, stop rotation of the orbiter based on the operation of the stop operation means, and the player according to the pattern after the stop A gaming machine that grants benefits.

DESCRIPTION OF SYMBOLS 10 Slot machine, 32L, 32M, 32R ... Reel, 41 ... Start lever, 41a ... Start detection sensor, 42-44 ... Stop button, 66 ... Image display device, 101 ... Update circuit, 102 ... Latch register, 103 ... Control Circuit 113: latched status 114: control side CPU 148: control IC 245: operation opening winning detection sensor 271: control IC 304: control side CPU 407: first latch register 408: second latch Register, 416: first random number counter, 417: second random number counter, SG1, SG2, SG4: detection signal, TA1, TB1, TB11: input terminal.

Claims (1)

Game execution means for executing a game operation;
Start operation means operated to start the game operation;
An end operation unit operated to end the game operation;
Lottery execution means for executing a lottery with at least one condition that the start operation means is operated;
The game operation is started on the condition that the start operation means is operated as at least one condition, and the operation on the end operation means is at least one condition corresponding to the result of the lottery by the lottery execution means Game control means for controlling the game execution means so that the game operation is ended;
In a gaming machine provided with
A detection unit that detects that the start operation unit has been operated;
The lottery execution means is
First acquisition means for acquiring a first lottery value based on the detection state of the detection means becoming an operation corresponding state corresponding to the operation of the start operation means;
Second acquisition means for acquiring a second lottery value based on the detection state of the detection means becoming a non-operation corresponding state corresponding to the non-operation of the start operation means;
Lottery means for executing a lottery utilizing at least the first lottery value and a lottery utilizing the second lottery value, or performing a lottery utilizing at least both the first lottery value and the second lottery value;
Equipped with
The game control means includes start control means for starting the game operation after the first lottery value is acquired and before the second lottery value is acquired. .

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