JP5443021B2 - Game machine - Google Patents

Description

  The present invention relates to a gaming machine having a host control device and a lower control device that operates under the control of the host control device.

  A gaming machine such as a pachinko machine is provided with a host control device and a lower control device controlled by the host control device as control means. The host control device outputs a command to the lower control device, and the lower control device performs a game process specified by the command from the host control device. For example, in a pachinko gaming machine, a game control device that performs main control such as setting of the internal state of the gaming machine and lottery, an effect control device that performs effect control by image display, a payout control device that performs payout control of payout balls, A plurality of control devices such as an image / sound control device and a lamp control device that operate under the control of the effect control device are provided. When the game control device is a host control device, the effect control device and the payout control device are subordinate control devices, and when the effect control device is a host control device, the image / sound control device and the lamp control device are subordinate control devices.

  In the above configuration, the processing of the host control device is based on the assumption that the lower control device is operating normally. However, when the lower-level control device is reset due to an abnormal state, there is a possibility that an inconsistency in operation or state may occur between the higher-level control device and the restored lower-level control device. Therefore, there is a conventional technique for preventing such a situation and returning the lower control device to a normal state while preventing inconsistency between the upper control device and the lower control device (see, for example, Patent Document 1).

  According to the technique disclosed in Patent Document 1, the lower-level control device performs a game processing circuit that performs a game process designated by a command from the higher-level control device, and a signal while the game processing circuit is normally processing. A signal output circuit. The host control device also outputs a signal receiving circuit that receives a signal output from the signal output circuit, and a reset signal that resets the processing of the game processing circuit when the signal input to the signal receiving circuit is interrupted. And a signal output circuit. Since the lower level control device is reset by the higher level control device, it is possible to prevent inconsistency between the higher level control device and the lower level control device.

JP 2003-296143 A

  A gaming machine having a host control device and a lower control device that operates under the control of the host control device is reset by the host control device and returned even if the lower control device is in an abnormal state. For this reason, an abnormality that has occurred in the lower level control device rarely affects the entire gaming machine. However, when performing maintenance work on such a gaming machine, it is difficult to specify under what circumstances an abnormal state has occurred in which lower level control device.

  In view of the above, an object of the present invention is to make it possible to acquire information related to the occurrence state of an abnormal state in each control device in a gaming machine having a higher control device and a lower control device that operates under the control of the higher control device.

The present invention that achieves the above object is realized as the following gaming machine. This gaming machine includes a host control device 10 and a lower control device 20 that operates under the control of the host control device 10. The upper control device 10 outputs a reset signal for resetting the lower control device 20 to be reset . The lower control device 20 is reset by receiving the reset signal output from the higher control device 10. In addition, a log creation device 30 provided separately from the host control device 10 and the lower control device 20 and a log storage device 40 that stores log information created by the log creation device 30 are provided. The upper control device 10 transmits a reset signal to the lower control device 20 and the log creation device 30 to be reset. When the log creation device 30 receives the reset signal transmitted from the host control device 10 , the log creation device 30 includes information for specifying the lower control device 20 reset by the reset signal and information for specifying the time when the reset is performed. Create log information including.

  The gaming machine of the present invention may further be configured as follows. In this gaming machine, the lower level control device 20 outputs a ready / busy signal indicating whether or not the control by the higher level control device 10 is acceptable to the higher level control device 10. The host control device 10 controls the lower control device 20 in accordance with the operation state of the lower control device 20 indicated by the ready / busy signal received from the lower control device 20. When the lower level control device 20 is reset, the log creation device 30 receives the ready / busy signal output from the reset lower level control device 20, and operates the lower level control device 20 indicated by the ready / busy signal. Information indicating the status is added to the log information.

  More specifically, in the above gaming machine, the log creating device 30 receives the ready / busy signal output from the lower control device 20 when the reset signal output from the higher control device 10 to the lower control device 20 is received. Receive.

  In addition, the said code | symbol in this column is attached | subjected illustratively in the description of this invention, and this invention is not reduced by this code | symbol.

  According to the present invention, in a gaming machine having a higher-level control device and a lower-level control device that operates under the control of the higher-level control device, it is possible to acquire information related to the occurrence state of an abnormal state in each control device.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
[Control of lower-level control device by higher-level control device]
First, a mechanism in which the upper control device controls the operation of the lower control device will be described.
FIG. 1 is a diagram showing a simplified configuration of a control system of a pachinko gaming machine according to the present embodiment.
Various electric devices such as a symbol display for displaying game images, an audio output device for outputting sound effects, a lamp device for outputting effect light, and a payout device for paying out pachinko balls according to game results Is provided. These electric devices are controlled devices that are controlled by the control system of the pachinko gaming machine shown in FIG.

  A pachinko gaming machine is generally provided with a plurality of control devices such as a game control device and an effect control device. These control devices have an upper-lower relationship as shown in FIG. That is, the low-order control device 20 shown in FIG. 1 is a control device for the above-described electric device and a controlled device for the high-order control device 10. Further, in the entire control system of the pachinko gaming machine, each control device has a hierarchical structure in which the gaming control device responsible for main control such as control of the internal state of the pachinko gaming machine is the highest level. Therefore, a predetermined control device can be either the upper control device 10 or the lower control device 20 in relation to other control devices.

As shown in FIG. 1, the host controller 10 includes command output means 11, reset signal output means 12, and abnormality notification accepting means 13.
The command output means 11 outputs a command for controlling the lower level control device 20.
The reset signal output means 12 is a circuit that outputs a reset signal for resetting the processing of the lower control device 20, and outputs a reset signal when the abnormality notification accepting means 13 notifies the occurrence of an abnormality in the lower control device 20.
The abnormality notification accepting unit 13 receives a notification (abnormality notification) that notifies the occurrence of an abnormality from the lower control device 20.

  The command output unit 11 and the reset signal output unit 12 are configured by an IC circuit including, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. In addition, the abnormality notification accepting unit 13 is configured by a receiving circuit that receives a predetermined signal output for abnormality notification from the lower control device 20, for example. These circuits can be configured using flip-flops and other known various electronic elements.

The lower control device 20 includes a processing unit 21 and an abnormality notification unit 22.
When the processing means 21 receives the command output from the host controller 10, the processing means 21 executes processing according to the received command. Specifically, for example, a command signal (drive signal) for driving a controlled device (electric device or the like, not shown) of the lower-level control device 20 is output to the controlled device to be controlled.

  The abnormality notification unit 22 performs abnormality notification for notifying the host control device 10 of the occurrence of an abnormality when an abnormal state occurs in the processing of the processing unit 21. As an abnormality notification method, for example, while the processing means 21 is performing normal processing, a signal is periodically output to the host control device 10 and an abnormality occurs by disconnecting the signal when an abnormal state occurs. Can be notified. Conversely, a predetermined signal may be output to the host controller 10 when the abnormality notifying unit 22 detects the occurrence of an abnormality in the processing unit 21. Alternatively, a signal may be output that goes high when the lower level control device 20 is operating normally, and goes low when it does not operate normally.

  Furthermore, a watchdog timer may be provided in the host controller 10 so that a reset signal is output from the reset signal output means 12 of the host controller 10 when the watchdog timer is not cleared within a set time. In this case, when the low order control device 20 is operating normally, a signal (clear signal) for clearing the watch dog timer of the high order control device 10 is output by the abnormality notification means 22 to an appropriate time within the set time of the watch dog timer. It is repeatedly output at the timing and transmitted to the host controller 10. When an abnormal state occurs in the lower level control device 20, no clear signal is output from the abnormality notifying means 22, and the watchdog timer is not cleared within the set time. For this reason, a reset signal is output from the reset signal output means 12, and the processing means 21 of the lower level control device 20 is reset.

FIG. 2 is a diagram illustrating another configuration example of a control system by the host control device 10 and the lower control device 20.
In the configuration example shown in FIG. 2, one upper control device 10 and a plurality of lower control devices 20a, 20b, and 20c are connected. When an abnormal state occurs in any of the lower control devices 20a, 20b, and 20c, an abnormality notification is made from the abnormality notification means 22 of the lower control devices 20a, 20b, and 20c that are in the abnormal state. And the high-order control apparatus 10 outputs a reset signal with respect to the low-order control apparatuses 20a, 20b, and 20c which performed abnormality notification.

FIG. 3 is a diagram illustrating still another configuration example of the control system by the host control device 10 and the lower control device 20.
In the configuration example illustrated in FIG. 3, the primary control device A, the secondary control device B, and the tertiary control device C are connected in a hierarchical manner. That is, in the relationship between the primary control device A and the secondary control device B, the primary control device A is the high-order control device 10 and the secondary control device B is the low-order control device 20. Further, in the relationship between the secondary control device B and the tertiary control device C, the secondary control device B is the higher order control device 10 and the tertiary control device C is the lower order control device 20.

  In the case of the configuration shown in FIG. 3, the primary control device A outputs a command to the secondary control device B. The secondary control device B outputs a command to the tertiary control device C as processing according to the command output from the primary control device A. The tertiary control device C performs processing according to the command output from the secondary control device B. When an abnormal state occurs in the secondary control device B, an abnormality notification is made from the abnormality notification means 22 of the secondary control device B in the abnormal state. And the primary control apparatus A which is the high-order control apparatus 10 outputs a reset signal with respect to the secondary control apparatus B which performed abnormality notification. Further, when an abnormal state occurs in the tertiary control device C, an abnormality notification is given from the abnormality notification means 22 of the tertiary control device C that has entered the abnormal state. And the secondary control apparatus B which is the high-order control apparatus 10 outputs a reset signal with respect to the tertiary control apparatus C which performed abnormality notification.

[Functional configuration of pachinko machines]
FIG. 4 is a diagram showing the overall configuration of the control unit of the pachinko gaming machine.
As shown in FIG. 4, the control unit includes a game control unit 200 that performs various controls relating to the number of prize balls to be paid out, such as internal lottery and determination of winning, as main control means. In addition, as sub-control means, an effect control unit 300 that comprehensively controls effects, an image / sound control unit 310 that controls effects using images and sounds, and effects using various lamps and movable accessories. A lamp control unit 320 for controlling and a payout control unit 400 for performing payout control of the payout ball are provided. Each of the game control unit 200, the effect control unit 300, the image / sound control unit 310, the lamp control unit 320, and the payout control unit 400 includes a game control board as a main board disposed on the rear surface of the game board, and further a sub The effect control board, the image control board, the lamp control board, and the payout control board as the boards are individually configured.

  The game control unit 200 includes a CPU 201 that performs arithmetic processing when performing various controls related to the number of paid-out prize balls, such as internal lottery and winning determination, and a ROM 202 that stores programs executed by the CPU 201, various data, and the like. And a RAM 203 used as a working memory for the CPU 201. The game control unit 200 performs a special symbol lottery according to the winning of a game ball at the start opening, sets the internal state and the operation of the electric tulip, and controls the electric device according to the setting. Further, the game control unit 200 sends these setting contents to the effect control unit 300. Furthermore, the game control unit 200 instructs the payout control unit 400 to pay out the prize ball according to the winning of the game ball. Further, the information regarding the number of prize balls paid out from the payout control unit 400 is acquired, and the number of prize balls paid out is managed.

  The effect control unit 300 includes a CPU 301 that performs calculation processing when controlling the effect, a ROM 302 that stores programs executed by the CPU 301 and various data, a RAM 303 that is used as a work memory of the CPU 301, and the like. And a real-time clock (RTC) 304 for measuring. The production control unit 300 sets production content based on, for example, the setting content sent from the game control unit 200. In addition, the effect control unit 300 sends a command for instructing execution of the set effect contents to the image / sound control unit 310 and the lamp control unit 320.

  The image / sound control unit 310 is a CPU 311 that performs arithmetic processing for controlling the image and sound representing the content of the effect, a ROM 312 that stores programs executed by the CPU 311, various data, and the like. And a RAM 313 used as a memory or the like. The image / sound control unit 310 controls the image display by the image display unit 510 and the sound output by the sound output unit 520 based on the command sent from the effect control unit 300. The ROM 312 of the image / sound control unit 310 stores various image data used in the production, and music data, sound data such as sound effects. Then, the image / sound control unit 310 reads out desired image data and sound data from the ROM 312 according to the contents of the effect set by the effect control unit 300, and sends them to the image display unit 510 and the sound output unit 520.

The image display unit 510 includes a controller for controlling display and switching of images based on image data and a display screen such as a liquid crystal display. The image display unit 510 displays a display screen based on image data received from the image / acoustic control unit 310. A background image or a design image is displayed.
The sound output unit 520 includes a controller that reproduces sound data and a speaker, and outputs music, sound effects, sound, and the like from the speaker based on the sound data received from the image / sound control unit 310.

  The lamp control unit 320 includes a CPU 321 that performs arithmetic processing when controlling the light emission of the panel lamp and the frame lamp and the operation of the movable accessory, and the ROM 322 that stores programs executed by the CPU 321 and various data, And a RAM 323 used as a working memory for the CPU 321. The lamp control unit 320 controls the lighting / flashing of the panel lamp and the frame lamp, the emission color, and the like based on the command sent from the effect control unit 300. Also, the operation of the movable accessory is controlled.

  The payout control unit 400 includes a CPU 401 that performs arithmetic processing for controlling payout of payout balls, a ROM 402 that stores programs executed by the CPU 401, various data, and the like, and a RAM 403 that is used as a work memory for the CPU 401 and the like. And. The payout control unit 400 controls the payout of the payout ball based on the command sent from the game control unit 200.

  The configuration, function, and operation of these game control unit 200, effect control unit 300, image / sound control unit 310, lamp control unit 320, payout control unit 400, image display unit 510, and sound output unit 520 are the same as those of existing pachinko gaming machines. Since it is the same as that of a thing, detailed description is abbreviate | omitted.

[Application example of this embodiment in a pachinko machine]
FIG. 5 is a diagram illustrating a functional configuration example in which the above control system is applied to an effect control device of a pachinko gaming machine. Here, the effect control device includes an effect control unit 300, an image / sound control unit 310, a lamp control unit 320, an image display unit 510, and a sound output unit 520 among the control units shown in FIG. And In FIG. 5, a reset IC 600 is an IC chip for resetting the system when the pachinko gaming machine is activated.

  In the relationship between the effect control unit 300, the image / sound control unit 310, and the lamp control unit 320, the effect control unit 300 corresponds to the host control device 10 shown in FIG. 1, and the image / sound control unit 310 and the lamp control unit. 320 corresponds to the lower control apparatus 20. Further, in the relationship between the image / sound control unit 310, the image display unit 510, and the sound output unit 520, the image / sound control unit 310 corresponds to the host control device 10, and the image display unit 510 and the sound output unit 520 are lower. This corresponds to the control device 20.

  In the configuration shown in FIG. 5, the host control device 10 (for example, the effect control unit 300 for the image / sound control unit 310) includes a watch dog timer (not shown). If the watchdog timer is not cleared within the set time, a reset signal is output to the lower level control device 20. In addition, the lower level control device 20 (for example, the image / sound control unit 310 for the effect control unit 300) sends a clear signal for clearing the watch dog timer of the higher level control device 10 to an appropriate time within the set time of the watch dog timer. It is repeatedly output at the timing and transmitted to the host controller 10. In FIG. 5, transmission of a command from the upper control device 10 to the lower control device 20, which is a normal control operation, is not shown.

  Therefore, as long as the low order control device 20 is operating normally, a clear signal is transmitted from the low order control device 20 to the high order control device 10, and the process of clearing the watch dog timer of the high order control device 10 is repeated. On the other hand, when an abnormal state occurs in the lower level control device 20, the clear signal is not transmitted from the lower level control device 20 to the higher level control device 10. For this reason, the watchdog timer of the host controller 10 is not cleared, the host controller 10 outputs a reset signal, and the lower controller 20 is reset.

  In the configuration shown in FIG. 5, for example, there are two lower control devices 20, an image / sound control unit 310 and a lamp control unit 320, with respect to the effect control unit 300 that is the higher control device 10. Therefore, the effect control unit 300 is provided with two watchdog timers corresponding to the image / sound control unit 310 and the lamp control unit 320, respectively. The states of the image / sound control unit 310 and the lamp control unit 320 are individually monitored and controlled. The same applies to the relationship between the image / sound control unit 310 that is the host control device 10 and the image display unit 510 and the sound output unit 520 that are the lower control devices 20.

  Further, in this application example, a ready / busy signal (RDY / BSY) indicating the operation state of the lower control device 20 is transmitted from the lower control device 20 to the higher control device 10. The ready / busy signal informs the host controller 10 whether the lower control device 20 receives a command from the host controller 10 and can execute processing (ready state) or cannot execute processing (busy state). Signal. Here, it is assumed that the ready state is set when the ready / busy signal is at a high level, and the busy state is set when the ready / busy signal is at a low level. In the initial state after the power is turned on to the pachinko gaming machine, the ready / busy signal is at a low level. Then, when each of the lower level control devices 20 finishes the initial operation and can execute the process based on the command from the higher level control device 10, it becomes high level. Further, when the reset is performed, the ready / busy signal becomes low level, and when the low order control device 20 returns and processing based on the command from the high order control device 10 can be executed again, the ready / busy signal becomes high level. Become.

[Save reset log]
In the present embodiment, the host control device 10 monitors and controls the lower control device 20 with the above-described configuration, and log information related to the reset when an abnormal state occurs in the lower control device 20 and the reset is performed. (Hereinafter referred to as reset log) is acquired and managed centrally. The reset log includes information for specifying the time when the reset is performed and the control device, information indicating the state of the ready / busy signal, and the like. In the configuration shown in FIG. 5, the acquired reset log is collected by the effect control unit 300 and stored in the internal RAM of the real-time clock (RTC) 304 of the effect control unit 300. Saving the reset log in the internal RAM of the real time clock (RTC) 304 is because the real time clock (RTC) 304 is backed up by the battery, so the stored contents are not erased even if the power of the pachinko machine is turned off. It is. Therefore, in addition to the internal RAM of the real-time clock (RTC) 304, if a non-volatile memory is prepared in which the stored contents are not erased even if the power of the pachinko machine is turned off, that memory is used as the reset / log storage destination. The configuration is not limited to the above.

  In the configuration shown in FIG. 5, the effect control unit 300 collects information related to the reset performed by each control device and creates a reset log. Here, with respect to the image / sound control unit 310 and the lamp control unit 320, the effect control unit 300 itself outputs a reset signal and receives a ready / busy signal. it can. That is, information is acquired directly from the host control device 10 itself that has reset the lower control device 20.

  On the other hand, since the image display unit 510 and the sound output unit 520 are reset by a reset signal from the image / sound control unit 310, information regarding the reset cannot be directly acquired. Therefore, as shown in FIG. 5, a reset signal output from the image / sound control unit 310 to the image display unit 510 and the sound output unit 520, and from the image display unit 510 and the sound output unit 520 to the image / sound control unit 310. The output ready / busy signal is also transmitted to the effect control unit 300. Thereby, the production control unit 300 knows that the image display unit 510 or the sound output unit 520 is reset by the reset signal from the image / sound control unit 310 and the state of the ready / busy signal when the image display unit 510 is reset. be able to.

  In the configuration shown in FIG. 5, the production control unit 300 creates the reset / log. That is, the effect control unit 300 is caused to function as the log creation device 30. According to this configuration example, the real-time clock (RTC) 304 can be referred to in order to acquire time information described later. As described above, the internal RAM of the real-time clock (RTC) 304 can be used as the log storage device 40 for the generated reset log. However, the configurations of the log creation device 30 that collects necessary information and creates a reset log and the log storage device 40 that saves the created reset log are not limited to the configuration example shown in FIG. The production control unit 300 may be provided as an independent device, or may be realized by being incorporated as a function of another control device.

FIG. 6 is a diagram illustrating a data configuration example of the reset log.
The reset log shown in FIG. 6 is composed of time information indicating the date and time when the reset was performed, and reset information including information specifying the control device where the reset was performed and information indicating the state of the ready / busy signal. ing. The time information is obtained from the value of the real time clock (RTC) 304 when the reset is performed. The reset information is acquired based on the exchange of signals between the control devices. In FIG. 6, the time information is represented by a numerical value representing the date and time, and the reset information is represented by binary data, but in actuality, both are described in the same format. The data structure shown in FIG. 6 is merely an example, and the specific data structure is not particularly limited as long as at least time information and reset information can be recorded.

  The reset information of the reset log shown in FIG. 6 is composed of fixed-length data assigned 4 bits for each control device. That is, the data size of the reset information is n × 4 bits (n is the number of control devices). As shown in FIG. 6, the 4-bit data corresponding to a predetermined control device in the reset information is an identification flag for specifying the control device in the first bit, and a reset signal is output in the second bit. The third bit indicates the ready / busy signal status (high or low). That is, in the bit string corresponding to the target control device of entry data in the reset log, the first and second bits are “1”, and in the bit strings corresponding to other control devices, these bits are “0”. . If the third bit is “1”, the ready / busy signal is at a high level when reset is performed, and if it is “0”, the ready / busy signal is at a low level. Recognize. In the example shown, the fourth bit is not used for recording information. Therefore, in the example of FIG. 6, when the image display unit 510 is reset at 12:24 on December 12, 2008, and the image display unit 510 is reset, the ready / busy signal of the image display unit 510 is high. It is recorded that it was level.

  Here, when the bit indicating the ready / busy signal of the reset information is “1” in the reset log, it indicates that the ready / busy signal was at the high level when the lower-level control device 20 was reset. . This means that the lower-level control device 20 was in a ready state until it was reset. That is, it can be seen that although the abnormal state such as the runaway of the CPU processing occurred and was reset, the lower-level control device 20 itself started up normally. On the other hand, when the bit indicating the ready / busy signal in the reset information is “0”, it indicates that the ready / busy signal was at the low level when the lower level control device 20 was reset. This means that the lower level control device 20 was busy before being reset. That is, it can be seen that the lower-level control device 20 has not been normally activated for some reason.

  By the way, the ready / busy signal becomes low level when the low order control device 20 is reset. Therefore, a reset signal is sent from the host control device 10 to the lower control device 20, and the reset information is acquired after the lower control device 20 resets and the ready / busy signal becomes low level. The bit corresponding to the ready / busy signal in the information is always “0”. Therefore, the low order control device 20 needs to be designed so that after receiving a reset signal from the high order control device 10, the low order control device 20 is reset after a certain period of time and the ready / busy signal becomes low. In this way, when the reset signal is output from the higher order control device 10 and the reset information is acquired, the ready / busy signal holds the previous state, and the state of the lower order control device 20 is accurately set. The reflected reset information can be obtained. In the lower level control device 20, at least the time until the reset is received after the reset signal is received, at least the higher level control device 10 detects the output of the reset signal by the reset / log creation means (the effect control unit 300 in the example of FIG. 5). After that, it is necessary to execute an interrupt routine for generating a reset log to read the output port of the ready / busy signal and to have a sufficient time to acquire the ready / busy signal.

[Reset log creation processing]
Next, reset log creation processing will be described.
FIG. 7 is a flowchart showing an example of reset / log creation processing by the effect control unit 300.
As shown in FIG. 7, the effect control unit 300 monitors the image / sound control unit 310, the lamp control unit 320, the image display unit 510, and the sound output unit 520 belonging to the lower level (step 701). Here, the image / sound control unit 310 and the lamp control unit 320, which are their own lower level control devices 20, are monitored by receiving clear signals from the image / sound control unit 310 and the lamp control unit 320. Further, the image display unit 510 and the sound output unit 520 which are the lower-level control devices 20 of the image / sound control unit 310 are monitored by receiving a reset signal output from the image / sound control unit 310.

  Next, when the production control unit 300 detects that the reset is performed in any of the image / sound control unit 310, the lamp control unit 320, the image display unit 510, and the sound output unit 520 (Yes in step 702), Time information is acquired with reference to the real time clock (RTC) 304 (step 703). Then, reset information including information indicating the state of the ready / busy signal is added to create a reset log (step 704). The created reset log is stored in the internal RAM of the real time clock (RTC) 304 (step 705).

  Here, with respect to the image / sound control unit 310 and the lamp control unit 320, which are the lower level control devices 20, the effect control unit 300 outputs a reset signal without the clear signal being cleared and the watchdog timer being cleared. Thus, it can be detected that the image / sound control unit 310 or the lamp control unit 320 is reset. In addition, regarding the image display unit 510 and the sound output unit 520 which are the lower-level control devices 20 of the image / sound control unit 310, the image display unit 510 or the sound output unit 520 receives the reset signal output from the image / sound control unit 310. It can be detected that the sound output unit 520 has been reset.

  The information indicating the state of the ready / busy signal is received from the image / acoustic control unit 310 and the lamp control unit 320 with respect to the image / acoustic control unit 310 and the lamp control unit 320 which are their own lower-level control devices 20. Can be obtained directly by signal. Further, the image display unit 510 and the sound output unit 520 that are the lower-level control devices 20 of the image / sound control unit 310 are obtained by receiving the ready / busy signals output from the image display unit 510 and the sound output unit 520. be able to.

[Read reset log]
Next, the read operation of the accumulated reset log will be described.
FIG. 8 is a flowchart for explaining the operation at the time of starting the pachinko gaming machine including the reset / log reading operation.
In this embodiment, it is assumed that the reset / log is read by switching the setting when the pachinko gaming machine is activated.

  As shown in FIG. 8, when the power of the pachinko gaming machine is turned on (step 801), it is determined whether it is a normal activation or an activation for maintenance (step 802). This switching determination is made, for example, based on whether or not a predetermined switching operation has been performed when the power is turned on. As the switching operation, for example, an operation button or key provided on the pachinko gaming machine is operated in a predetermined pattern within a certain time from power-on. Activation for maintenance is performed when a maintenance inspection is performed in a hall or the like after the pachinko gaming machine is shipped. In addition, it is performed in a debugging operation or the like before the pachinko gaming machine is shipped.

  If it is normal activation (Yes in Step 802), the pachinko gaming machine is activated normally and can play a game (Step 803). On the other hand, if the activation is for maintenance (No in step 802), the reset log stored in the real time clock (RTC) 304 of the effect control unit 300 is read (step 804), and image / sound control is performed. The image is displayed on the display screen through the unit 310 and the image display unit 510 (step 805).

  As described above, in the present embodiment, when reset is performed in each control device, information relating to the reset is acquired, log information is created, and is managed centrally. For this reason, at the time of debugging work at the time of development of a pachinko machine or maintenance inspection after shipment, information regarding reset in each control device can be acquired, and can be used for analysis of the occurrence state of an abnormal state in each control device. .

  In the above embodiment, the production control device (FIG. 5) having the production control unit 300 as the highest control device has been described. However, the pachinko gaming machine has the game control unit 200 and payout control shown in FIG. There is a hierarchical control system in which the unit 400 is the highest-level control device. The present embodiment can also be applied to these control systems. In the above operation example, when the pachinko machine is started for maintenance when the pachinko machine is started, the reset log is displayed on the display screen of the pachinko machine. When the game is performed, the log storage device such as the real time clock (RTC) 304 is removed from the pachinko machine, and the reset / log stored in the log storage device 40 can be read using an information device such as a personal computer. Is possible.

It is a figure which shows the structure of the control system of the pachinko game machine which concerns on this Embodiment. It is a figure which shows the other structural example of the control system by the high-order control apparatus and low-order control apparatus in this Embodiment. It is a figure which shows the further another structural example of the control system by the high-order control apparatus and low-order control apparatus in this Embodiment. It is a figure which shows the whole structure of the control unit of a pachinko gaming machine. It is a figure which shows the function structural example which applied the control system of this Embodiment to the presentation control apparatus of the pachinko game machine. It is a figure which shows the example of a data structure of the reset log of this Embodiment. It is a flowchart which shows the example of the creation process of the reset log by the production | presentation control part of this Embodiment. It is a flowchart explaining the operation | movement at the time of starting of the pachinko game machine containing the reset log read-out operation | movement in this Embodiment.

DESCRIPTION OF SYMBOLS 10 ... High-order control apparatus, 20 ... Low-order control apparatus, 200 ... Game control part, 300 ... Production control part, 304 ... Real time clock (RTC), 310 ... Image / sound control part, 320 ... Lamp control part, 510 ... Image display Part, 520 ... sound output part

Claims (3)

A host control device and a lower control device that operates under the control of the host control device;
The upper control device outputs a reset signal for resetting the lower control device to be reset ,
The low order control device is a gaming machine which is reset by receiving the reset signal output from the host controller,
It provided separately from said host control device and the low order control device, a logging device to create log information including information specifying a time when the information and reset for specifying the low order control device which is reset is performed ,
And a log storage unit that stores log information created by the log creation device,
The upper control device transmits the reset signal to the lower control device to be reset and the log creation device,
The log creating device creates the log information when receiving the reset signal transmitted from the host control device . The lower-level control device outputs a ready / busy signal indicating whether the control by the higher-level control device is acceptable, to the higher-level control device,
The higher order control device performs control of the lower order control device according to the operation state of the lower order control device indicated by the ready / busy signal received from the lower order control device,
The log generation device receives the ready / busy signal output from the reset lower control device when the lower control device is reset, and the lower control device indicated by the ready / busy signal 2. The gaming machine according to claim 1, wherein information indicating an operation state of the game machine is added to the log information.   3. The log creation device receives the ready / busy signal output from the lower order control device when the reset signal output from the higher order control device to the lower order control device is received. The gaming machine described in 1.

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