JP2001070589A5 - - Google Patents

Description

[Document name] Specification [Title of invention] Game machine [Claims]
[Claim 1]
Display means for displaying the symbols, and a main control unit for controlling the game, and a display control means for causing the variable display of the symbols by the display means based on a control command transmitted from the main control unit In the game machine
The control command transmitted from the main control means is used to determine a fluctuation pattern command indicating the fluctuation pattern of the fluctuation display and a stop symbol to be stopped and displayed on the display means at the end of the fluctuation display. It is composed of at least a stop symbol determination command and a stop command for ending the variation display.
The display control means
A storage means for storing the symbol data displayed on the display means is provided, and the symbol data is read from the storage means based on the stop symbol determination command, and the symbol corresponding to the data is displayed.
When the stop command is received at the end of the variation display based on the variation pattern command, the display means causes the display means to stop and display the stop symbol determined based on the stop symbol determination command.
Even before the end timing of the variation display based on the variation pattern command arrives, when the stop command is received, the stop symbol determined based on the stop symbol determination command is stopped and displayed by the display means. An termination means for ending the variation display and
A gaming machine characterized in that it is provided with a replacement means for replacing a symbol so that the variation display ends with a stop symbol determined based on the stop symbol determination command at the end of the variation display based on the variation pattern command.
2.
The gaming machine according to claim 1, wherein the variable display of the symbol performed by the display control means is a scroll display in the horizontal direction.
3.
The gaming machine according to claim 1 or 2, wherein the number of columns in which the symbols are variablely displayed is three.
4.
The gaming machine according to any one of claims 1 to 3, wherein the gaming machine is a pachinko machine.
Description: TECHNICAL FIELD [Detailed description of the invention]
[0001]
BACKGROUND OF THE INVENTION The present invention is relates to the gaming machine, which is represented by such as a pachinko machine.
0002.
The main control board for controlling the Related Art pachinko machine or the like of the game, and the payout control board paid out control such as winning balls and rental ball, sound effect control board controlling the output of the sound effect, the symbol A display control board or the like that controls display such as variable display is connected. Of these boards, control of the display control board is performed by a control command transmitted from the main control board to the display control board .
0003
When the display device that displays the fluctuation of the symbol is composed of three lines, the upper row, the middle row, and the lower row, and the fluctuation display is performed while scrolling horizontally from right to left for each of the three lines, for example, the figure. As shown in 16, control commands (1) to (10) are transmitted from the main control board to the display control board, and a series of variable display of symbols is performed.
0004
First, the control command (1) starts the variable display of the symbols for all three lines of the upper row, the middle row, and the lower row. Then, replacement of symbols, with the upper symbol by the control command (2), with the middle of the symbol by the control commands (3), the lower symbol by the control commands (4) are performed, respectively. The control command (5) slows down the fluctuation display of all three lines that are fluctuating at high speed, and the control command (6) repeatedly fluctuates the upper and lower displays back and forth from side to side. The fluctuation display in the middle row is regarded as medium speed fluctuation. Further, the control command (7) sets the fluctuation display in the middle row to low-speed fluctuation, then the control command (8) stops the fluctuation display in the upper row, and the control command (9) stops the fluctuation display in the lower row. Then, the control command (10) stops the fluctuation display in the middle row. As a result, the variation display of all three lines is stopped, and the series of variation display ends.
0005
PROBLEM TO BE SOLVED: To solve a problem of a variable display. Since a control command for controlling a variable display is transmitted from a main control board to a display control board at each point where the variable display state changes, the variable display is displayed. Most of the control will be done on the main control board .
0006
The present invention has been made to solve the above-exemplified problems and the like , and provides a gaming machine that does not require a control command to be transmitted from the main control means at each point where the state of the variable display changes. It is an object.
0007
[Means for Solving the Problems] In order to achieve this object, the gaming machine according to claim 1 is transmitted from a display means for displaying a symbol, a main control means for controlling a game, and the main control means. and a display control means for causing the variable display of the symbols by the display means based on the control commands that, the control command transmitted from the main control means, variations indicating the variable display pattern of variation It is composed of at least a pattern command, a stop symbol determination command used when determining a stop symbol to be stopped and displayed on the display means at the end of the variation display, and a stop command to end the variation display. The display control means includes a storage means for storing the data of the symbol displayed on the display means, reads the symbol data from the storage means based on the stop symbol determination command, and displays the symbol corresponding to the data. When the stop command is received at the end of the variation display based on the variation pattern command, the display means causes the display means to stop and display the stop symbol determined based on the stop symbol determination command. Even before the end timing of the variation display based on the variation pattern command arrives, when the stop command is received, the stop symbol determined based on the stop symbol determination command is stopped and displayed by the display means. It is provided with an ending means for ending the variation display and a replacement means for replacing the symbol so that the variation display ends with the stop symbol determined based on the stop symbol determination command at the end of the variation display based on the variation pattern command. There is.
The gaming machine according to claim 2 is the gaming machine according to claim 1. In the gaming machine according to claim 1, the variable display of the symbol performed by the display control means is a scroll display in the horizontal direction.
The gaming machine according to claim 3 is the gaming machine according to claim 1 or 2, in which the symbols are variablely displayed in three columns.
The gaming machine according to claim 4 is the gaming machine according to any one of claims 1 to 3, wherein the gaming machine is a pachinko machine.
0008
BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In this embodiment, as an example of the gaming machine, a pachinko machine which is a kind of ball gaming machine, particularly a first-class pachinko gaming machine will be described. It is naturally possible to use the present invention for a third-class pachinko gaming machine and other gaming machines.
0009
FIG. 1 is a front view of the game board of the pachinko machine P of this embodiment. Around the game board 1, there are a plurality of winning openings 2 in which 5 to 15 balls are paid out when a hit ball is won. Further, in the center of the game board 1, a liquid crystal (LCD) display 3 for displaying a pattern or the like as a plurality of types of identification information is provided. The display screen of the LCD display 3 is divided into three in the horizontal direction, and in each of the three divided display areas, a variable display of a symbol is performed while scrolling from right to left in the horizontal direction.
0010
A symbol operating port (type 1 starting port) 4 is provided below the LCD display 3, and when a hit ball passes through the symbol operating port 4, the variable display of the LCD display 3 is started. A specific winning opening (large winning opening) 5 is provided below the symbol operating opening 4. When the display result after the change of the LCD display 3 matches one of the predetermined combinations of symbols, the specific winning opening 5 becomes a big hit and a predetermined time (for example, 30) so that the hit ball can easily win a prize. It is a winning opening that is opened until a second elapses or until 10 hit balls are won. A V zone 5a is provided in the specific winning opening 5, and if a hit ball passes through the V zone 5a while the specific winning opening 5 is open, a continuation right is established and the specific winning opening 5 is closed. After that, the specific winning opening 5 is opened again for a predetermined time (or until a predetermined number of hit balls are won in the specific winning opening 5). The opening / closing operation of the specific winning opening 5 can be repeated up to 16 times (16 rounds), and the state in which the opening / closing operation can be performed is a state in which a so-called predetermined game value is given (special game state). is there.
0011
FIG. 2 is a block diagram showing the electrical configuration of the pachinko machine P. On the main control board C of the pachinko machine P, the MPU 11 which is an arithmetic unit, the ROM 12 which stores various control programs and fixed value data executed by the MPU 11, and various data are temporarily stored. A RAM 13 which is a memory is mounted. The flowchart programs shown in FIGS. 9 to 11 are stored in the ROM 12 as a part of the control program.
0012
The RAM 13 includes a transmission buffer 13a, a command counter 13b, and an error command transmission completed flag 13c. The transmission buffer 13a is a buffer for storing control commands transmitted from the main control board C to the display control board D for controlling the fluctuation display of the LCD display 3. Since the control command is composed of 2 bytes, the transmission buffer 13a is also composed of 2 bytes. The control command set (written) in the transmission buffer 13a is transmitted to the display control board D byte by byte by the timer interrupt process.
0013
FIG. 3 is a diagram showing a state in which the display screen of the LCD display 3 is divided into nine display areas. As described above, the variation display of the present embodiment is performed while scrolling in the arrow A direction in the three display areas 3a, 3b, and 3c divided into three in the horizontal direction. The three display areas 3a, 3b, 3c divided into three in the horizontal direction are further divided into three in the vertical direction to form nine display areas 3a1, ..., 3c3, and the nine display areas 3a1, ... As shown in FIG. 3, nine symbol numbers 32a of "symbols 1 to symbol 9" are attached to, 3c3.
0014.
The command counter 13b shown in FIG. 2 is a counter for indicating the display areas 3a1 to 3c3 of the LCD display 3 designated by the stop symbol designation command 32 (see FIG. 5), which is a kind of control command, and is "1 to 10". Is updated by "1" in the range of ". When the value of the command counter 13b is within the range of "1 to 9", the display areas 3a1 to 3c3 of the symbol number 32a (see FIG. 5) corresponding to the value of the command counter 13b are designated. Further, when the value of the command counter 13b is "10", none of the display areas is specified.
0015.
The error command transmitted flag 13c is a flag for indicating that the error command 81 shown in FIG. 8 has been transmitted from the main control board C to the display control board D when an error occurs, and the error command transmission shown in FIG. 11 is transmitted. In the process (S20), the error command 81 is set to the transmission buffer 13a and then turned on (S85). When the error command transmitted flag 13c is turned on, transmission of all other control commands except the error release command 82 is waited for (S83: Yes, S30: Yes). The error command transmitted flag 13c once turned on is turned off after the error release command 82 is set in the transmission buffer 13a due to the resolution of the error (S88). As described above, the control command set in the transmission buffer 13a is transmitted byte by byte to the display control board D by the timer interrupt process. Details of the error command 81 and the error release command 82 will be described later.
0016.
As shown in FIG. 2, these MPU 11, ROM 12, and RAM 13 are connected to each other via a bus line 14, and the bus line 14 is also connected to an input / output port 15. The input / output port 15 is connected to the display control board D and other input / output devices 16. The main control board C sends various commands to the display control board D and other input / output devices 16 via the input / output ports 15 to control each of these devices. The main control board C and the display control board D are connected via two buffers (inverter gates) 17 and 28 having fixed inputs and outputs. Therefore, transmission / reception of control commands between the main control board C and the display control board D is performed only in one direction from the main control board C to the display control board D, and the main control is performed from the display control board D. It is not possible to send a control command or the like to the board C.
[0017]
The display control board D includes an MPU 21, a program ROM 22, a work RAM 23, a video RAM 24, a character ROM 25, an image controller 26, an input port 29, and an output port 27. The output of the inverter gate 28 is connected to the input of the input port 29, and the output of the input port 29 is connected to the bus line connecting the MPU 21, the program ROM 22, and the work RAM 23. An image controller 26 is connected to the input of the output port 27, and an LCD display 3 is connected to the output of the output port 27.
0018
The MPU 21 of the display control board D is for controlling the (variable) display of the LCD display 3 based on the control command transmitted from the main control board C, and is executed by the MPU 21 in the program ROM 22. Various control programs to be executed are stored. The flowchart programs shown in FIGS. 12 and 13 are stored in the program ROM 22 as a part of the control program.
0019
The work RAM 23 is a memory for storing work data and flags used when executing various programs by the MPU 21, and includes a reception buffer 23a, a command reception flag 23b, nine stop symbols 1 to 9 memories 23c to 23k, and so on. It has an error display flag 23l.
0020
The reception buffer 23a is a buffer for receiving a control command transmitted from the main control board C. Since the control command is composed of 2 bytes, the receive buffer 23a is also composed of 2 bytes. The command reception flag 23b is a flag that is turned on when a new control command is stored in the reception buffer 23a. When the command reception flag 23b is turned on, the control command stored in the reception buffer 23a is read, and the fluctuation display of the LCD display 3 is controlled based on the read control command. The command reception flag 23b once turned on is turned off when the control command is read from the reception buffer 23a.
0021.
The stop symbols 1 to 9 memories 23c to 23k are memories for storing the stop symbol symbol code 32b (see FIG. 5) transmitted by the stop symbol designation command 32, which is a kind of control command, and are the LCD display 3 A total of nine stop symbols 1 to 9 memories 23c to 23k are provided, one for each of the nine display areas 3a1 to 3c3 (see FIG. 3). The details of the stop symbols 1 to 9 memories 23c to 23k will be described later.
0022.
The error display flag 23l is a flag that is turned on when an error is displayed on the LCD display 3. When the display control board D receives the error command 81 transmitted from the main control board C, an error display is displayed on the LCD display 3, and the error display flag 23l is turned on while the error display is being performed. Will be done. When the error display flag 23l is turned on, even if the error command 81 is received, the error display has already been performed, so the execution of each process (S60, S61) for error display is skipped. Will be done. On the contrary, when the error display flag 23l is turned off, the error display is not performed. Therefore, even if the error release command 82 is received, each process (S63, S64) for returning the error display is performed. Execution is skipped. The error display flag 23l, which has been turned on once, is turned off after returning the error display to the state before the error display by receiving the error release command 82 (S64).
[0023]
The video RAM 24 is a memory for storing display data displayed on the LCD display 3, and the display contents of the LCD display 3 are changed by rewriting the contents of the video RAM 24. That is, the variable display of the symbol in each display area 3a1 to 3c3 is performed by rewriting the contents of the video RAM 24. The character ROM 25 is a memory for storing character data such as a symbol displayed on the LCD display 3. The image controller 26 adjusts the timings of the MPU 21, the video RAM 24, and the output port 27 to intervene in reading and writing data, and displays the display data stored in the video RAM 24 on the LCD at a predetermined timing with reference to the character ROM 25. It is to be displayed on the display 3.
0024
Next, a control command transmitted from the main control board C to the display control board D for controlling the fluctuation display will be described with reference to FIGS. 4 to 8. The control command is composed of a variation pattern designation command 31, a stop symbol designation command 32, a symbol stop command 33, an error command 81, and an error release command 82, for a total of five types of commands. Since the control command is composed of 2 bytes, the most significant bit is set in the command code of the 1st byte in order to distinguish the command code of the 1st byte and the 2nd byte, and the command of the 2nd byte is set. The code has the most significant bit reset.
0025
FIG. 4 is a diagram showing the command code of the variation pattern designation command 31 and the contents of the command. The variation pattern designation command 31 is a command for starting the variation display and designating a series of variation patterns from the start to the end of the variation display. The command code of the first byte is "C0H" or "C1H", and a total of 56 types of fluctuation patterns are prepared.
0026
Since the control of the fluctuation display specified by the fluctuation pattern designation command 31 is performed by the display control board D that has received the fluctuation pattern designation command 31, the content of the control program of the display control board D should be changed. Therefore, the content of the variation display for the variation pattern designation command 31 of the same code can be changed. That is, the content of the variable display can be changed only by changing the control program of the display control board D without changing the control program of the main control board C.
[0027]
FIG. 5A is a diagram showing the correspondence between the command code of the stop symbol designation command 32 and the symbol number 32a designated by the command code. As described above, each display area 3a1 to 3c3 shown in FIG. 3 is associated with each symbol number 32a. Further, FIG. 5B is a diagram showing a correspondence relationship between 20 types of symbol codes 32b and symbol names 32c.
[0028]
The stop symbol designation command 32 is a command for designating a symbol to be stopped and displayed in each of the display areas 3a1 to 3c3 of the LCD display 3 at the end of the fluctuation display of the fluctuation pattern specified by the fluctuation pattern designation command 31. .. The stop symbol designation command 32 is a display control board D from the main control board C for each of the nine display areas 3a1 to 3c3 of the LCD display 3 after the fluctuation pattern designation command 31 is transmitted and the fluctuation display is started. Will be sent to.
[0029]
The stop symbol designation command 32 is composed of 2 bytes like the variation pattern designation command 31. A command code for designating the display areas 3a1 to 3c3 of the symbols 1 to 9 is set in the first byte of the stop symbol designation command 32. As shown in FIG. 5A, if the command code of the first byte of the stop symbol designation command 32 is "90H", the display area 3a1 of the symbol 1 is displayed, and if it is "A0H", the display area 3b1 of the symbol 2 is displayed. , ..., If it is "B2H", the display area 3c3 of the symbol 9 is designated, respectively. In the second byte of the stop symbol designation command 32, the symbol code 32b of the symbol to be stopped and displayed is set in the display areas 3a1 to 3c3 of the symbols 1 to 9 specified by the command code of the first byte. That is, as shown in FIG. 5 (b), when the stop-displayed symbol is "octopus", "10H" is used, and when it is "harisenbon", "11H" is ..., "shark". In the case of "(2)", "23H" is set as the code of the second byte of the stop symbol designation command 32, respectively.
[0030]
When the display control board D receives the stop symbol designation command 32, the variation display ends with the symbol of the symbol code 32b specified by the stop symbol designation command 32 after considering the variation pattern being executed. Replace the changing symbol. Since this symbol replacement is performed only when the fluctuation display is fluctuating at high speed, the player does not notice that the symbol has been replaced.
0031
As shown in FIG. 5B, different symbol codes 32b are assigned to each symbol. In particular, the symbol names 32c "shark (1)" and "shark (2)" are displayed as exactly the same symbol on the LCD display 3, but as shown in FIG. 5 (b), both symbols have "13H". And "23H" are given different symbol codes 32b. Similarly, the symbol names 32c "shell (1)" to "shell (10)" are also displayed as exactly the same symbol on the LCD display 3, but as shown in FIG. 5 (b), "19H" to "22H". A different symbol code 32b is assigned.
[0032]
FIG. 6 is a diagram schematically showing the configuration of the virtual symbol reels 41 to 43 in each of the upper, middle, and lower stages. FIG. 6A schematically illustrates the configuration of the upper virtual symbol reel 41 that is variablely displayed in the upper display area 3a of the LCD display 3. As shown in FIG. 6 (a), the virtual symbol reel 41 in the upper stage has 18 kinds of symbols of "shell (9)", "crab", "shell (8)", ..., "Octopus". They are arranged in order, and after the final "octopus" symbol, the symbols of "shellfish (9)", "crab", "shellfish (8)", etc. are arranged back to the first symbol. Will be done. The virtual symbol reel 41 in the upper row is variably displayed in the display area 3a in the upper row of the LCD display 3 in the order of arrangement of the symbols.
0033
Similarly, FIG. 6C schematically illustrates the configuration of the lower virtual symbol reel 43 that is variablely displayed in the lower display area 3c of the LCD display 3. As shown in FIG. 6 (c), the lower virtual symbol reel 43 has an arrangement completely opposite to the arrangement of the upper virtual symbol reel 41, and 18 kinds of symbols are "octopus", "shell (1)", They are arranged in the order of "harisenbon", ..., "shellfish (9)". After the final "shellfish (9)" symbol, the symbols "octopus", "shellfish (1)", "porcupinefish", and so on are arranged back to the first symbol. The lower virtual symbol reel 43 is variably displayed in the lower display area 3c of the LCD display 3 in the order of arrangement of the symbols.
0034
FIG. 6B schematically illustrates the configuration of the virtual symbol reel 42 in the middle stage, which is variablely displayed in the display area 3b in the middle stage of the LCD display 3. As shown in FIG. 6B, the virtual symbol reel 42 in the middle stage has two types of symbols, "shark (2)" and "shell (10)", at the end of the array of the virtual symbol reel 43 in the lower stage. A total of 20 types of added symbols are arranged in order. As in the case of the virtual symbol reels 41 and 43 in the upper and lower rows, after the final "shell (10)" symbol, return to the first symbol and return to the "octopus", "shell (1)", and "harisenbon". , ... Each symbol is arranged. The virtual symbol reel 42 in the middle stage is variably displayed in the display area 3b in the middle stage of the LCD display 3 in the order of arrangement of the symbols.
0035.
FIG. 7 is a diagram showing the command code of the symbol stop command 33 and the contents of the command. The symbol stop command 33 is a command for stopping and displaying (determining) a symbol that is variablely displayed in the display areas 3a1 to 3c3 of the designated symbol number 32a. When the display control board D receives the symbol stop command 33, the stop symbol already specified by the stop symbol designation command 32 is stopped and displayed in the display areas 3a1 to 3c3 designated by the symbol stop command 33, and the display area thereof is displayed. The symbols of 3a1 to 3c3 are confirmed. That is, the variable display of the display areas 3a1 to 3c3 designated by the symbol stop command 33 ends. When the symbols in all nine display areas 3a1 to 3c3 are confirmed by the symbol stop command 33, the variation display of the series of variation patterns started by the variation pattern designation command 31 ends.
0036
The display control board D considers the contents of the variation pattern designation command 31 and the stop symbol designation command 32, and displays the display areas 3a1 to 3c3 to which the symbol designated by the stop symbol designation command 32 corresponds at the timing of the end of the variation display. As shown in, the symbol is replaced in advance during the high-speed fluctuation of the fluctuation display. Moreover, the main control board C controls to transmit the symbol stop command 33 to the display control board D at the timing when the fluctuation pattern of the fluctuation display specified by the fluctuation pattern designation command 31 ends. Therefore, the stop display (confirmation) of the symbol by the symbol stop command 33 is smoothly performed without giving a sense of discomfort to the player.
0037
As a result of the transmission timing of the symbol stop command 33 from the main control board C being accelerated, the display control board D is issued with the symbol stop command even though it is before the end of the variation pattern specified by the variation pattern specification command 31. When 33 is received, the display control board D stops the stop symbol already specified by the stop symbol designation command 32 in the center of the corresponding display areas 3a1 to 3c3 even before the end of the fluctuation pattern. Display and determine the symbols in the display areas 3a1 to 3c3.
[0038]
The symbol stop command 33 includes nine types of commands for individually determining the symbols in the nine display areas 3a1 to 3c3, one type of command for determining all the symbols in the nine display areas 3a1 to 3c3 at once, and the upper row. There are three types of commands that individually determine the symbols of the three display areas 3a, 3b, and 3c divided into the middle and lower stages, and a total of 13 types of commands are prepared. Of these, the symbol stop command 33 ((1) "80H, 0BH", (2) "80H, 0CH" that fixes three symbols at once for each of the upper, middle, and lower stages that are the scroll units. , (3) "80H, 0DH"), the scrolling of the virtual symbol reels 41 to 43 displayed on the display of the LCD display 3 is performed in the same manner as the scrolling of the actual symbol reels. It is possible to further improve the interest of the player.
[0039]
FIG. 8 is a diagram showing the command codes of the error command 81 and the error release command 82, and the command contents thereof. The error command 81 is a command for notifying the display control board D of the occurrence of the error when an error occurs during the control of the main control board C. On the other hand, the error release command 82 is a command for notifying the display control board D of the resolution of the error once the error has been resolved.
0040
As an error, for example, when a big hit occurs and the big winning opening 5 is opened, but the 10 count switch for detecting the winning of a hit ball to a place other than the V zone 5a of the big winning opening 5 is never turned on. Or, conversely, when the 10 count switch continues to be on for a predetermined time or longer, or when the payout switch for detecting the paid out prize ball is never turned on even though the prize ball is being paid out. and so on. These errors are detected in the count abnormality monitoring process (S9) in the reset interrupt process of FIG. 9, and the detection result is stored in the state flag. That is, when an error is occurring, the status flag indicates that an error is occurring, and when the error is resolved, the status flag indicates that the status flag is normal.
[0041]
As shown in FIG. 8, the first byte of the error command 81 is set to "F3H", and the most significant bit of the second byte is reset to indicate that it is the control command of the second byte. Moreover, it is said that "55H (01010101B)" is set and reset every other bit. As described above, since the control command is transmitted to the display control board D one byte (8 bits) at a time by the timer interrupt process, the "55H" set and reset every other bit is the display control board D. If it can be received accurately with, it can be confirmed that there is no bridge (short circuit) between the signal lines in the signal line for transmitting the control command. If there is a bridge in the signal line, the bridged signal lines output the same data of "0" or "1". Since the bridge of this signal line occurs in the adjacent signal line, if there is a bridge in the signal line for transmitting the control command, it is not possible to receive "55H (01010101B)" set and reset every other bit. Is.
[0042]
The arrangement of signal lines for transmitting control commands, that is, the hard arrangement of signal lines on the board or cable connecting the main control board C and the display control board D is the hardware of MPU11,21. If the bit arrangement order is different, the second byte data of the error command 81 resets the most significant bit and 1 bit based on the hard arrangement of the signal lines on the board or cable. It is configured as data that is set and reset everywhere.
[0043]
For example, when eight "0 to 7" signal lines that transmit control commands one byte (8 bits) at a time are arranged in the order of "76543201" on the board, the second byte of the error command 81. The data of is "56H (01010110B)" in which the data of the 0th bit and the data of the 1st bit are exchanged with respect to "55H". The command code of "56H" is output as the data of "01010101" on the board in which the signal lines are arranged in the order of "76543201". Therefore, if the command code of "56H" can be accurately received by the display control board D, , It is possible to confirm that there is no bridge (short circuit) between signal lines at least in the signal lines for transmitting control commands, especially adjacent signal lines.
[0044]
The first byte of the error release command 82 is set to "F3H" as in the error command 81, and the most significant bit of the second byte is reset and the other 7 bits are for the error command 81. It is said to be bit-inverted "2AH (00101010B)". If the error release command 82 can be accurately received by the display control board D together with the error command 81, it is necessary to confirm whether or not the signal line is short-circuited and that the signal line for transmitting the control command is not broken. Can be done. If the signal line is broken, the output of that signal line remains set or reset, and all bits except the most significant bit of the signal line are set and set by the error command 81 and the error release command 82. This is because it will be reset.
0045
Since the most significant bit of the signal line for transmitting the control command is set by the command code of the first byte and reset by the command code of the second byte, either the error command 81 or the error release command 82 is used. If the signal line of the most significant bit can be received accurately, it can be confirmed that there is no disconnection in the signal line of the most significant bit.
[0046]
By using the error display by the error command 81 and the return of the error display by the error release command 82, it is possible to detect an abnormality in the signal line for transmitting the control command. For example, by intentionally generating an error and checking whether or not an error is displayed on the LCD display 3, it is possible to determine at least whether or not there is a short circuit in the signal line. This is because the error display is displayed on the LCD display 3 only when the error command 81 is normally received. Further, by confirming whether or not the error display is restored to the original display when the error is resolved after the error is intentionally generated and the LCD display 3 is displayed with the error. , It is possible to determine whether or not there is a disconnection in the signal line. This is because the error display is restored only when the error release command 82 is normally received.
[0047]
Next, each process executed by the pachinko machine P configured as described above will be described with reference to the flowcharts of FIGS. 9 to 13. FIG. 9 is a flowchart of a reset interrupt process executed every 4 ms on the main control board C of the pachinko machine P. The main control of the pachinko machine P is executed by this reset interrupt process.
0048
In the reset interrupt process, first, the stack pointer is set (S1), and the pattern written in the predetermined area of the RAM 13 is checked (S2). As a result of the check, if a predetermined pattern is written in the predetermined area, there is no abnormality in the RAM 13 and it is normal (S2: normal), so the process is shifted to S3. On the other hand, if the predetermined pattern is not written in the predetermined area as a result of the check in S2, it means that the reset interrupt process is executed first after the power is turned on, or there is an abnormality in the RAM 13 (S2: abnormality). In this case, the process is shifted to S22, the contents of the RAM 13 are once cleared, the initial value is written in the RAM 13 (S22), and the next reset interrupt process is waited for. The initial value written to the RAM 13 in the process of S22 includes a predetermined pattern checked in the process of S2.
[0049]
In the process of S3, the timer interrupt is set (S3). The timer interrupt set here includes a timer interrupt that generates a strobe signal for transmitting a control command for controlling the fluctuation display of the LCD display 3 to the display control board D. After setting the timer interrupt, each interrupt is enabled (S4). After the interrupt is permitted, the output data updated in the previous reset interrupt process can be processed at once by the special symbol variation process (S15), display data creation process (S17), lamp / information processing (S18), etc. The port output process for outputting to the port is executed (S5).
0050
Further, the random number update process (S6) for updating the value of the random number counter for determining the jackpot by "+1" is executed, and the storage timer subtraction process is executed (S7). The storage timer subtraction process shortens the time for displaying the fluctuation of the symbol when there are a predetermined number or more of the reserved balls for the jackpot determination and the variation of the symbol is being displayed on the LCD display 3.
0051
The switch reading process (S8) reads the value of each switch, wins a prize in the winning opening 2 and the large winning opening 5 (including the V zone 5a) of the hit ball hit into the game area 1, and passes through the symbol operating opening 4. Furthermore, it is a process for detecting prize balls and rental balls. The count abnormality monitoring process (S9) is a process for monitoring whether or not there is an abnormality in the switch data read by the switch reading process in S8. For example, even though the large winning opening 5 is opened and the hit ball is detected by the V count switch that detects the passage of the hit ball through the V zone 5a, the winning of the large winning opening 5 other than the V zone 5a is detected10. If the count switch cannot detect even one hit ball, the 10 count switch is pulled out, and some abnormality has occurred in the 10 count switch. Further, if even one prize ball is not paid out even though the motor for paying out the prize ball is driven, some abnormality has occurred in the prize ball payout device. In this way, the count abnormality monitoring process (S9) monitors the presence or absence of the above-mentioned abnormality based on the switch data read by the switch read process (S8).
[0052]
When an error is detected by the count abnormality monitoring process (S9), the status flag is set to an error state as if an error has occurred, and the error command 81 is controlled for display by the error command transmission process (S20) described later. It is transmitted to the substrate D. When the error once generated is resolved, the error status of the status flag is canceled, and the error cancel command 82 is transmitted to the display control board D by the error command transmission process (S20) in response to the cancellation. To.
[0053]
In the symbol counter update process (S10), as a result of the fluctuation display performed on the LCD display 3, the counter update process for determining the symbol to be stopped and displayed is performed. Further, in the symbol check process (S11), the jackpot symbol, the missed symbol, and the reach symbol used in the special symbol variation process (S15) are based on the value of the counter updated in the symbol counter update process (S10). Etc. are decided.
0054
If no error has occurred in the processes from S3 to S11 (S12: normal), the 7-segment LED (not shown) is displayed as a variation by the normal symbol variation process (S13), and the result of the variation display is performed. , When a hit occurs, a hit process is performed in which the normally electric accessory (not shown) is opened for a predetermined time. After that, the state flag is checked (S14), and if the LCD display 3 is in the process of starting or displaying the fluctuation of the symbol (S14: the symbol is changing), the hit ball presses the symbol operating port 4 by the special symbol variation process (S15). Based on the value of the random number counter read at the timing of passing, it is determined whether or not it is a big hit, and the LCD display 3 executes a symbol variation process. On the other hand, as a result of checking the status flag, if the jackpot is in progress (S14: jackpot in progress), the jackpot process (S16) such as opening the jackpot 5 is executed. Further, as a result of checking the state flag, if the symbol is neither fluctuating nor a big hit (S14: other), the processing of S15 and S16 is skipped, and the process proceeds to the display data creation processing of S17. If an error is confirmed in the process of S12 (S12: error), each process of S13 to S16 is skipped, and the process proceeds to the display data creation process of S17.
0055
In the display data creation process (S17), demo data displayed on the LCD display 3 and display data of the 7-segment LED are created in addition to the variable display of the symbol, and in the lamp / information processing (S18), the lamp of the holding ball is created. Various lamp data including data are created. In the sound effect processing (S19), sound effect data according to the situation of the game is created. The display data and the sound effect data are output to each device by the port output process (S5) and the timer interrupt process described above.
0056
After the sound effect processing (S19) is completed, an error command 81 is transmitted when any error occurs, and conversely, an error release command 82 is transmitted when the generated error is resolved, respectively, to the display control board D. The process (S20) is executed. After the error command transmission process (S20) is executed, the symbol counter update process (S21), which is the same process as S10, is repeatedly executed during the remaining time until the next reset interrupt process occurs. Since the execution time of each process of S1 to S20 changes according to the state of the game, the remaining time until the next reset interrupt process occurs is not a constant time. Therefore, the stopped symbol can be randomly changed by repeatedly executing the symbol counter update process (S21) using the remaining time. The details of the error command transmission process (S20) will be described later with reference to FIG.
[0057]
FIG. 10 is a flowchart showing a command setting process executed in the special symbol variation process (S15) of the reset interrupt process in FIG. In this command setting process, the fluctuation pattern designation command 31, the stop symbol designation command 32, and the symbol stop command 33, which are control commands for controlling the fluctuation display of the LCD display 3, are transmitted from the main control board C to the display control board D. This is a process for writing (setting) each command 31 to 33 to the transmission buffer 13a.
0058.
In the command setting process, first, it is confirmed whether or not the error command transmitted flag 13c is turned on (S30). If the error command transmitted flag 13c is turned on (S30: Yes), one of the errors has occurred and the error command 81 has already been transmitted to the display control board D. In this state, an error display is displayed on the entire surface of the LCD display 3, and the variable display is not performed until the generated error is resolved and the error release command 82 is transmitted. Therefore, in such a case, each process of S31 to S38 is performed in order to wait for the transmission of the fluctuation pattern designation command 31, the stop symbol designation command 32, and the symbol stop command 33, which are control commands for controlling the fluctuation display. Skip and end this process.
[0059]
On the other hand, if the error command transmitted flag 13c is turned off (S30: No), the state of the variable display is checked by the status flag (S31). As a result of the check, if the variation display is started (S31: variation start), the variation pattern specification command 31 is written to the transmission buffer 13a (S32), the value of the command counter 13b is set to "1" (S33), and this process is performed. finish. As described above, the variation pattern designation command 31 written in the transmission buffer 13a is transmitted byte by byte to the display control board D by the timer interrupt process set in the process of S3.
[0060]
As a result of checking the state flag in the process of S31, if the fluctuation display of the symbol is in progress (S31: fluctuation display is in progress), it is checked whether or not the value of the command counter 13b is "9" or less (S34). If the value of the command counter 13b is "9" or less (S34: Yes), the first byte of the stop symbol designation command 32 corresponding to the value of the command counter 13b is written to the upper byte of the transmission buffer 13a (S35). Based on the correspondence shown in FIG. 5A, for example, if the value of the command counter 13b is "1", "90H" is set, and if the value of the command counter 13b is "2", "A0H" is set. If the value of the command counter 13b is "9", "B2H" is written to the upper byte of the transmission buffer 13a, respectively.
[0061]
Further, the symbol code 32b of the stop symbol corresponding to the value of the command counter 13b is written to the lower byte of the transmission buffer 13a (S36). For example, if the value of the command counter 13b is "1", the symbol code 32b of the symbol that is stopped and displayed in the display area of the symbol 1 (3a1) is displayed. If the value of the command counter 13b is "2", the symbol 2 (3b1) The symbol code 32b of the symbol that is stopped and displayed in the display area of () is ..., If the value of the command counter 13b is "9", the symbol code 32b of the symbol that is stopped and displayed in the display area of symbol 9 (3c3) Are written to the lower byte of the transmission buffer 13a based on the correspondence shown in FIG. 5 (b). Here, when the "octopus" symbol is specified as the stop symbol, the "10H" symbol code 32b is specified, and when the "porcupinefish" symbol is specified, the "11H" symbol code 32b is ... When the symbol of "shark (2)" is specified, the symbol code 32b of "23H" is specified, respectively.
[0062]
After writing the 2-byte stop symbol designation command 32 to the transmission buffer 13a by the processing of S35 and S36, the value of the command counter 13b is added by "1" (S37), and this processing is terminated. The stop symbol designation command 32 written in the transmission buffer 13a is transmitted to the display control board D byte by byte by the timer interrupt processing set in the processing of S3, as in the case of the fluctuation pattern designation command 31. Will be done.
[0063]
On the other hand, if the value of the command counter 13b is "10" or more (S34: No), it means that the stop symbol designation command 32 has been transmitted for all nine display areas 3a1 to 3c3. Therefore, in such a case, each process from S35 to S37 is skipped and this process is terminated.
[0064]
As a result of checking the status flag in the processing of S31, if it is the timing of the end of the variation display (S31: end of the variation display), the symbol stop that stops and displays (confirms) all the symbols in the nine display areas 3a1 to 3c3 at once. The command 33 (80H, 0AH) is written to the transmission buffer 13a (S38), and this process is terminated. The symbol stop command 33 written in the transmission buffer 13a is transmitted to the display control board D byte by byte by the timer interrupt process set in the process of S3, as in the case of the variation pattern designation command 31. When the symbol stop command 33 is transmitted to the display control board D, a series of fluctuation displays started by the fluctuation pattern designation command 31 ends.
[0065]
It should be noted that the stop display (confirmation) of the symbol by the symbol stop command 33 does not necessarily have to confirm all nine symbols at once, for example, each of the nine symbols is confirmed separately, or scrolling is performed. The symbol may be fixed for each unit of the unit, that is, the upper symbol, the middle symbol, and the lower symbol. In the former case, as shown in FIG. 7, the symbol stop commands 33 of "80H, 01H" to "80H, 09H" are used, and in the latter case, the symbols of "80H, 0BH" to "80H, 0DH" are used. The stop command 33 is used.
[0066]
FIG. 11 is a flowchart showing an error command transmission process (S20) executed in the reset interrupt process of FIG. In this error command transmission process, the error command 81 is transmitted when an error occurs, the error release command 82 is transmitted when the error is resolved, and the commands 81 and 82 are transmitted from the main control board C to the display control board D, respectively. This is a process for writing (setting) to 13a.
[0067]
In the error command transmission process, first, the status flag is checked to confirm whether or not the fluctuation display is in progress (S81). If the variable display is in progress (S81: Yes), each process from S82 to S88 is skipped and this process is skipped in order to wait for the transmission of the error command 81 and the error release command 82 even if an error occurs. To finish. If the error command 81 is transmitted to the display control board D during the fluctuation display, the timing of the fluctuation display control shifts due to the processing of the error command 81 by the display control board D, which hinders the fluctuation display. It ends up. Therefore, even if an error occurs, if the fluctuation display is in progress, the error command 81 is configured to wait for transmission to the display control board D to accurately perform the fluctuation display.
[0068]
Further, when an error command 81 is transmitted from the main control board C to the display control board D, the display control board D displays an error on the entire surface of the LCD display 3, but the display control board D causes an error. By receiving the release command 82, the display can be switched to the original display before the error display. If an error is displayed during the fluctuation display, when the error is resolved, the error display must be switched to the state in the middle of the fluctuation display, and a lot of processing and memory are required for such control. Needs. Therefore, even if an error occurs, if the fluctuation display is in progress, the error command 81 can be waited for transmission to the display control board D so that the display screen can be easily restored after the error is resolved. It is configured.
[0069]
As a result of checking the status flag, if the fluctuation display is not displayed (S81: No), the status flag is further checked to confirm whether or not any error has occurred (S82). If an error has occurred (S82: Yes), the error command transmitted flag 13c is checked to confirm whether or not the error command 81 has already been transmitted to the display control board D (S83). If the error command transmitted flag 13c is off (S83: No), the error command 81 has not been transmitted yet, so the error command 81 is written to the transmission buffer 13a (S84), and the error command transmitted flag 13c is turned on. (S85), this process is terminated. The error command 81 written in the transmission buffer 13a is transmitted byte by byte to the display control board D by the timer interrupt process set in the process of S3 (FIG. 9). When the error command 81 is transmitted to the display control board D, an error display is displayed on the entire surface of the LCD display 3.
[0070]
On the other hand, in the process of S83, if the error command transmitted flag 13c is turned on (S83: Yes), the error command 81 has already been transmitted. Therefore, in order to avoid transmission of the duplicate error command 81, S84 and Each process of S85 is skipped and this process ends.
[0071]
In the process of S82, if the result of checking the status flag is not in error (S82: No), it is confirmed whether or not the error command transmitted flag 13c is turned on (S86). If the error command transmitted flag 13c is turned on (S86: Yes), an error has occurred in the past, the error command 81 is transmitted to the display control board D, and an error is displayed on the entire surface of the LCD display 3. ing. Therefore, in order to return the error display to the original display, the error release command 82 is written to the transmission buffer 13a (S87), the error command transmission completed flag 13c is turned off (S88), and this process is terminated. The error release command 82 written in the transmission buffer 13a is transmitted to the display control board D byte by byte by the timer interrupt process set in the process of S3 (FIG. 9). When the error release command 82 is transmitted to the display control board D, the error display displayed on the entire surface of the LCD display 3 is switched to the original display before the error display.
[0072]
On the other hand, in the processing of S86, if the error command transmitted flag 13c is turned off (S86: No), no error has occurred in the past, or even if an error has occurred, the error clearing command 82 has already been issued. Since it has been transmitted, each process of S87 and S88 is skipped and this process is terminated in order to avoid transmission of the unnecessary error release command 82.
[0073]
FIG. 12 is a flowchart of a command reception process executed in the reception interrupt process of the display control board D. This command reception process is executed when a control command is transmitted from the main control board C to the display control board D. First, the control command transmitted from the main control board C and received by the display control board D is written to the reception buffer 23a (S41), and further, the command reception flag 23b is turned on (S42), and a new control command is issued. It indicates that it is stored in the receive buffer 23a, and ends this process.
[0074]
FIG. 13 is a flowchart of a variable display process executed in the main process of the display control board D. In the variation display process, the variation display is controlled based on the control command received from the main control board C.
[0075]
First, it is confirmed whether or not the command reception flag 23b is turned on (S51). If the command reception flag 23b is turned on (S51: Yes), after turning it off (S52), the type of control command is confirmed by the data stored in the upper byte of the reception buffer 23a (S53).
[0076]
If the upper byte of the control command stored in the receive buffer 23a is "C0H" or "C1H", the control command is the variation pattern specification command 31. Therefore, in such a case (S53: fluctuation pattern designation command), after clearing the contents of all the stop symbols 1 to 9 memories 23c to 23k to 0 (S54), the fluctuation display according to the fluctuation pattern designation command 31 is displayed on the LCD. It starts on the display 3 (S55).
[0077]
In the processing of S53, if the upper byte of the control command stored in the receive buffer 23a is any of "90H to 92H", "A0H to A2H", or "B0H to B2H", the control command is a stop symbol. The designated command 32. Therefore, in such a case (S53: stop symbol designation command), first, the symbol code 32b, which is the second byte command of the stop symbol designation command 32, is written to the corresponding stop symbols 1-9 memories 23c to 23k (S56). .. As shown in FIGS. 5A and 5B, for example, if the stop symbol designation command 32 stored in the reception buffer 23a is "90H, 14H", the stop symbol 1 memory 23c corresponding to "90H" is stored. The symbol code 32b of "14H (shrimp symbol)" is written. If the stop symbol designation command 32 stored in the reception buffer 23a is "B2H, 21H", the symbol code 32b of "21H (shell symbol)" is stored in the stop symbol 9 memory 23k corresponding to "B2H". Written.
[0078]
After that, the fluctuating symbol that is fluctuating at high speed on the LCD display 3 is stored in the stop symbols 1-9 memories 23c to 23k in consideration of the fluctuation pattern and the progress of the fluctuation pattern. The changing symbol is replaced so that the variable display ends at the symbol 32b (S57). For example, when "14H" is stored in the stop symbol 1 memory 23c, the variable display of the display area 3a1 of the symbol 1 ends with the symbol of "shrimp" which is the symbol code 32b of "14H". The design is replaced. Further, when "21H" is stored in the stop symbol 9 memory 23k, the variable display of the display area 3c3 of the symbol 9 ends with the symbol of "shell" which is the symbol code 32b of "21H". The design is replaced.
[0079]
In the process of S53, if the upper byte of the control command stored in the receive buffer 23a is "80H", the control command is the symbol stop command 33. Therefore, in such a case (S53: symbol stop command), the symbol of the display areas 3a1 to 3c3 of the symbol number 32a specified by the symbol stop command 33 is determined (S58), and the symbol corresponding to the display area 3a1 to 3c3 is determined. Is stopped and displayed.
[0080]
For example, if the symbol stop command 33 of "80H, 0AH" is stored in the reception buffer 23a, the symbols of all nine display areas 3a1 to 3c3 are stopped and displayed at once and confirmed. Further, if the symbol stop command 33 of "80H, 0CH" is stored in the reception buffer 23a, the three symbols 2, 5 and 8 displayed in the display area 3b in the middle row are stopped and displayed at once and confirmed. Even before the end timing of the variable display arrives, when the symbol stop command 33 is received, the variable display of the display areas 3a1 to 3c3 instructed by the symbol stop command 33 is immediately stopped (confirmed). To do. Therefore, the variation display can be actually ended at the timing when the symbol stop command 33 is received.
[0081]
In the process of S53, if the upper byte of the control command stored in the receive buffer 23a is "F3H" and the lower byte is "55H", the control command is the error command 81. Therefore, in such a case (S53: error command), it is confirmed whether or not the error display flag 23l is turned on (S59). If the error display flag 23l is turned off (S59: No), the error display has not yet been performed on the LCD display 3, so an error display is performed on the entire surface of the LCD display 3 to indicate the occurrence of an error (S60). ), Turn on the error display flag 23l (S61), and memorize that the error display is in progress.
[882]
On the other hand, in the process of S59, if the error display flag 23l is turned on (S59: Yes), since the error display has already been performed, each process of S60 and S61 is skipped. In this way, if the error is already displayed, the error is not displayed again. Therefore, even if the error command 81 is erroneously received, the display screen restoration process performed when the error release command 82 is received. (S63) can be performed normally.
[0083].
In the process of S53, if the upper byte of the control command stored in the receive buffer 23a is "F3H" and the lower byte is "2AH", the control command is the error release command 82. Therefore, in such a case (S53: error release command), it is confirmed whether or not the error display flag 23l is turned on (S62). If the error display flag 23l is turned on (S62: Yes), the LCD display 3 is displaying an error, so the display of the LCD display 3 is returned (returned) to the display before the error display (S63). ), Turn off the error display flag 23l (S64), and remember that the error display is not in progress.
[0084]
On the other hand, in the process of S62, if the error display flag 23l is turned off (S62: No), the error display is not performed, so each process of S63 and S64 is skipped. As described above, when the error display is not performed, the display restoration process (S63) is not performed. Therefore, even if the error release command 82 is erroneously received, the display of the LCD display 3 is kept normal. Can be done.
[0085]
When the command reception flag 23b is turned off in the processing of S51, or after each processing of S55, S57, S58, S59: Yes, S61, S62: No, S64 is executed, the status of the variable display Each process is executed according to (S65), and this variable display process is terminated.
0083.
Next, the timing of the variation display based on the above description will be described with reference to the timing charts of FIGS. 14 and 15. First, with reference to FIG. 14, the timing when all nine symbols are stopped and displayed (fixed) at once will be described. When the variation pattern designation command 31 is transmitted from the main control board C to the display control board D, variation display is started for all the symbols 1 (3a1) to 9 (3c3). Following the fluctuation pattern designation command 31, the stop symbol designation command 32 is sequentially transmitted to the nine display areas 3a1 to 3c3 during the high-speed fluctuation. When the stop symbol designation command 32 is received by the display control board D, the symbols are replaced during high-speed fluctuation according to the stop symbol designated by the stop symbol designation command 32.
[0087]
After that, the fluctuation display is continued by the display control board D in the fluctuation pattern specified by the fluctuation pattern designation command 31, and at the end timing of the fluctuation display, all nine symbols are transferred from the main control board C to the display control board D. The symbol stop command 33 (80H, 0AH (see FIG. 7)) for displaying (confirming) the stop display (confirmation) at once is transmitted. When the symbol stop command 33 is received by the display control board D, a series of fluctuation displays started by the fluctuation pattern designation command 31 ends. After the end of the variation display, the display of the stop symbol designated by the stop symbol designation command 32, which is stopped and displayed in each display area 3a1 to 3c3, is switched to another display after a lapse of a predetermined time.
[0088]
If the display control board D receives the symbol stop command 33 before the end timing of the variation display has arrived, the end timing of the variation display specified by the variation pattern specification command 31 has not arrived. Also, the stop symbol designated by the stop symbol designation command 32 is immediately stopped and displayed in the designated display areas 3a1 to 3c3. By such control, the variation display can be terminated in accordance with the transmission (reception) timing of the symbol stop command 33.
[089]
Next, with reference to the timing chart of FIG. 15, the timing when the nine symbols are stopped and displayed (fixed) by three symbols in the order of the upper row, the lower row, and the middle row will be described. Until the stop symbol designation command 32 is transmitted, the timing is the same as in FIG. 14, and the symbols are replaced during the high-speed fluctuation.
[0090]
At the timing of the end of the variable display, the symbol stop command 33 for stopping and displaying (determining) the symbol displayed in the upper display area 3a is first transmitted from the main control board C to the display control board D (80H, 0BH). (See FIG. 7). When the symbol stop command 33 is received by the display control board D, the symbols 1, 4 and 7 in the upper row are stopped and displayed (confirmed) (see FIG. 3). Next, a symbol stop command 33 for stopping and displaying (determining) the symbol displayed in the lower display area 3c is transmitted (80H, 0DH (see FIG. 7)), and the lower symbols 3, 6 and 9 are stopped and displayed (see FIG. 7). Confirm) (see Fig. 3). Further, a symbol stop command 33 for stopping and displaying (confirming) the symbol displayed in the display area 3b in the middle row is transmitted (80H, 0CH (see FIG. 7)), and the symbols 2, 5 and 8 in the middle row are confirmed (FIG. 7). 3). The above three symbol stop commands 33 end a series of fluctuation displays started by the fluctuation pattern designation command 31.
[0091]
In this way, by stopping and displaying (fixing) the symbols in the order of the upper row, lower row, and middle row according to the scroll direction of the symbols, the virtual symbol reels 41 to 43 displayed on the display by control can be displayed on the actual symbol reels. Can be expressed as. When the scroll direction of the symbol is the vertical direction, the stop display (confirmation) of the symbol is performed in the order of left, right, and middle, for example.
[0092]
As described above, according to the pachinko machine P of the present embodiment, a series of fluctuation patterns can be specified at once by the fluctuation pattern designation command 31, so that the main control is performed for each point where the state of the fluctuation display changes. It is not necessary to send a control command from the board C. Therefore, it is possible to reduce the control load of the fluctuation display by the main control board C, and reduce the program capacity and the data capacity mounted on the main control board C to control the fluctuation display, so that the main control board C can be controlled. Program development can be facilitated.
[093]
Further, if the control of the variation display corresponding to the variation pattern designation command 31 is changed on the display control board D side, the variation pattern can be changed without changing the program of the main control board C. Therefore, it is possible to display different variations on the LCD display 3 by simply replacing the display control board D while sharing the main control board C.
[0094]
Further, when an error occurs, the error command 81 transmitted from the main control board C to the display control board D as a control command is "55H (01010101B)" in which the second byte is set and reset every other bit. If the error command 81 is accurately received by the display control board D, the signal line for transmitting the control command is normal and there is no abnormality (short circuit (bridge between signal lines)). .. If there is an abnormality such as a short circuit (bridge) in the signal lines, the bridged signal lines output the same data of "0" or "1". Since the bridge of this signal line occurs in the adjacent signal line, if there is a bridge in the signal line for transmitting the control command, it is not possible to receive "55H (01010101B)" set and reset every other bit. Is. On the other hand, when the error command 81 is accurately received by the display control board D, an error display is performed on the entire surface of the LCD display 3.
[0995]
Therefore, it is possible to detect an abnormality (short circuit) in the signal line for transmitting the control command by using such an error display. For example, by confirming whether or not an error is intentionally generated and an error is displayed, it is possible to determine whether or not the signal line is normal, that is, at least whether or not the signal line has a short circuit. it can.
[0906]
Further, since the error release command 82 is set to "2AH (00101010B)" in which the other 7 bits excluding the most significant bit of the second byte are bit inverted with respect to the error command 81, the error command 82 is combined with the error command 81. If the error release command 82 can be accurately received by the display control board D, it can be confirmed that there is no abnormality (disconnection) in the signal line for transmitting the control command. If the signal line is broken, the output of that signal line remains set or reset, and all bits except the most significant bit of the signal line are set and set by the error command 81 and the error release command 82. This is because it will be reset. Since the most significant bit of the signal line for transmitting the control command is set by the command code of the first byte and reset by the command code of the second byte, either the error command 81 or the error release command 82 is used. If the signal line of the most significant bit can be received accurately, it can be confirmed that there is no disconnection in the signal line of the most significant bit.
[097]
Therefore, it is possible to detect an abnormality (disconnection) in the signal line for transmitting the control command by utilizing the return of the error display. For example, by confirming whether or not the error display is restored to the original display when the error is resolved after the error is intentionally generated and the LCD display 3 is made to display the error. It is possible to determine whether or not the signal line is normal, that is, whether or not the signal line is short-circuited and whether or not the signal line is broken.
[0998]
Although the present invention has been described above based on the examples, the present invention is not limited to the above examples, and it is easy that various improvements and modifications can be made without departing from the spirit of the present invention. It can be inferred.
[00099]
For example, in the above embodiment, the control command of the present invention is directly transmitted from the main control board C to the display control board D that controls the variation display. However, instead of this, the main control board C once sends a control command to a sub-board other than the display control board D, and the sub-board sends a control command to the display control board D. The fluctuation display is controlled, or the control command is expanded in detail for each point where the fluctuation display changes depending on the sub-board, and the expanded command is transmitted from the sub-board to the display control board D to change. The display may be controlled. With the latter configuration, it is possible to reduce the control load of the variable display on the main control board C and the display control board D. In the latter case, the entire display control board D and the sub-board correspond to the display control board according to claim 1.
[0100]
Further, the control command of the present invention was used for controlling the fluctuation display of the LCD display 3, and a sound effect board that emits a sound effect and various lamps by using the control command or the command system thereof. The lamp board that blinks may be controlled.
[0101]
The error display does not necessarily have to be the LCD display 3, and the error display may be performed using another device. For example, an error is displayed by blinking the LED provided on the pachinko machine P at high speed, or the error display data is transmitted to the island management device that manages the pachinko machine P or the central management device of the pachinko hall. An error may be displayed by each management device. If an error is displayed on the central management device, the staff in the hall can be accurately notified of the error occurrence status.
[0102]
A modification of the present invention is shown below. The control device for a game machine according to claim 1, wherein the error display means displays the predetermined error on the display device.
[0103]
The control device for a game machine according to claim 1, wherein the error display means displays the predetermined error to a management device that is connected to the game machine and manages the game machine. Game machine control device 2. The error display means in this case is to transmit the error display data to the management device. Examples of the management device include an island management device and a central management device that are provided in a hall or the like and manage a plurality of game machines.
[0104]
In the control device of the game machine according to claim 1, or the control device 1 or 2 of the game machine, the main control board is an error command to the display control board by the command transmitting means during the fluctuation display. 3. A control device for a game machine, which comprises a standby means for waiting for transmission of the game machine. If an error command is transmitted to the display control board during the fluctuation display, the timing of the fluctuation display control is shifted due to the processing of the error command by the display control board, which hinders the fluctuation display. However, even if an error occurs during the fluctuation display, the transmission of the error command to the display control board is waited until the fluctuation display is completed by the standby means. Therefore, the display control is controlled by receiving the error command. It does not interfere with the variable display by the board.
[0105]
In any of the control device of the game machine according to claim 1 or the control devices 1 to 3 of the game machine, the command transmission means provided on the main control board eliminates the error when the error is resolved. The error release command is transmitted to the display control board as the control command, and when the display control board receives the error release command, the error display is performed instead of the error display. A control device 4 for a game machine, which comprises a display returning means for returning the display in front of the above. When the error is resolved, the display before the error display is restored.
[0106]
In any of the control device of the game machine according to claim 1 or the control devices 1 to 4 of the game machine, at least one byte of the error clearing command includes all the other bits except a predetermined number of bits. A control device 5 for a gaming machine, characterized in that it is composed of bit data inverted with respect to an error command. Each signal line to which control data is transmitted is set and reset by an error command and an error release command except for a predetermined number of bits. Therefore, when a part of the signal line for transmitting the control command is broken, the display control board cannot accurately receive the error command and the error release command. This is because the output of the broken signal line remains set or reset. Therefore, by transmitting the error command and the error release command, it is possible to check the disconnection of the signal line for transmitting the control command.
[0107]
In any of the control device of the game machine according to claim 1 or the control devices 1 to 5 of the game machine, the arrangement of every other bit of the error command is on the substrate of the signal line to which the control data is transmitted. Alternatively, the control device 6 of the game machine, which is characterized in that it corresponds to the arrangement on the cable. Therefore, since the data of adjacent signal lines is set and reset every other bit, when the adjacent signal lines are short-circuited (bridges between the signal lines), the display control board accurately issues an error command. I can't receive it. Therefore, with such a configuration, it is possible to detect a short circuit in the signal line for transmitting the control command.
[0108]
In any of the control device of the game machine according to claim 1 or the control devices 1 to 6 of the game machine, the control command transmitted from the main control board specifies a series of fluctuation patterns of the fluctuation display. The variation pattern specification command, the stop symbol specification command that specifies the stop symbol that is stopped and displayed on the display device at the end of the variation display, and the stop symbol specified by the stop symbol specification command are stopped and displayed on the display device ( A control device 7 for a game machine, which is at least configured by a symbol stop command for designating a timing for (confirmed display).
[0109]
The control device of the game machine according to claim 1 or any of the control devices 1 to 7 of the game machine includes a unidirectional means for transmitting the control command from the main control board in only one direction. A control device 8 for a gaming machine.
[0110]
In any of the control device of the game machine according to claim 1 or the control devices 1 to 8 of the game machine, the control command transmitted from the main control board is directly transmitted to the display control board. A control device 9 for a gaming machine.
[0111]
According to the gaming machine of the present invention, it is not necessary to transmit a control command from the main control means at each point where the state of the variable display changes.
[Simple explanation of drawings]
FIG. 1 is a front view of a game board of a pachinko machine according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an electrical configuration of a pachinko machine.
FIG. 3 is a diagram showing a state in which a display screen of a liquid crystal display is divided into nine display areas.
FIG. 4 is a diagram showing a command code of a variation pattern designation command and the contents of the command.
FIG. 5A is a diagram showing a correspondence relationship between a command code of a stop symbol designation command and a symbol number designated by the command code. (B) is a diagram showing the correspondence between 20 types of symbol codes and symbol names.
FIG. 6A is a diagram schematically showing a configuration of a virtual symbol reel that is variablely displayed in the upper display area, and FIG. 6B is a virtual symbol reel that is variablely displayed in the middle display area. It is a figure which showed typically the structure of, (c) is the figure which showed typically the structure of the virtual symbol reel which is variable-displayed in the lower display area.
FIG. 7 is a diagram showing a command code of a symbol stop command and the contents of the command.
FIG. 8 is a diagram showing command codes of an error command and an error clearing command, and their command contents.
FIG. 9 is a flowchart showing a reset interrupt process executed on the main control board.
FIG. 10 is a flowchart showing a command setting process executed in the reset interrupt process.
FIG. 11 is a flowchart showing an error command transmission process executed in the reset interrupt process.
FIG. 12 is a flowchart showing a command reception process executed in the interrupt process of the display control board.
FIG. 13 is a flowchart showing a variable display process executed in the main process of the display control board.
FIG. 14 is a variable display timing chart for fixing all symbols at once.
FIG. 15 is a timing chart of a variable display in which nine symbols are determined by three symbols.
FIG. 16 is a chart showing the timing of variation display in the prior art.
[Explanation of symbols]
3 Liquid crystal display (display means )
3a the upper display area 3b middle of the display area 3c lower display area 3a1~3c3 display area 31 fluctuation pattern specified for each symbol commands 32 stop symbol specified command 32a symbol number 32b symbol code 32c symbol name 33 symbol stop command 41 to 43 virtual design reels 81 error command 82 error release command C main control board (main control means)
D Display control board (display control means)
P pachinko machine (game machine )