JP2020099741A - Game machine - Google Patents

Abstract

To detect a fraudulent act that a game is played by causing a game machine to erroneously recognize that a legitimate game medium is used.SOLUTION: Template generation means groups a plurality of pieces of image data into groups of image data that are the same or similar to each other to a predetermined degree, selects a group within a predetermined number from a higher rank having a large number of image data belonging to the group, and generates the template data on the basis of the image data belonging to the group, for each of the selected groups. One of the template data in the plurality of types of template data is pattern template data regarding patterns of the game medium. In a generation process of color template data, the image data is converted into color space image data, one element in the converted color space image data is generated by a predetermined process, and then a conversion value obtained by performing coordinate conversion of the generated data is used.SELECTED DRAWING: Figure 34

Description

The present invention relates to a gaming machine.

Conventionally, a game called a pachi-slot provided with a plurality of reels having a plurality of symbols arranged on their respective surfaces, a start switch, a stop switch, a stepping motor provided corresponding to each reel, and a control unit. The machine is known. The start switch detects that the start lever has been operated by the player (hereinafter also referred to as "start operation") after a game medium such as a medal has been inserted into the game machine, and starts the rotation of all reels. Output the requested signal. The stop switch detects that a stop button provided corresponding to each reel is pressed by the player (hereinafter, also referred to as "stop operation"), and outputs a signal requesting stop of rotation of the corresponding reel. To do. The stepping motor transmits the driving force to the corresponding reel. Further, the control unit controls the operation of the stepping motor based on the signals output by the start switch and the stop switch, and performs the rotation operation and the stop operation of each reel.

In such a gaming machine, when a start operation is detected, a lottery process using random numbers on the program (hereinafter referred to as “internal lottery process”) is performed, and the result of the lottery (hereinafter, “internal winning combination”). That is) and the rotation of the reel is stopped based on the timing of the stop operation. Then, when the rotation of all reels is stopped and the symbol combination relating to the establishment of the winning combination is displayed, the privilege corresponding to the symbol combination is given to the player.

In addition, such a gaming machine is provided with a medal selector for detecting a medal inserted at the tip of the medal insertion slot. Also, for this medal selector, you can insert a medal (illegal medal) that is not a proper medal (regular medal) into the medal insertion slot, or insert a device into the medal insertion slot, and the regular medal will be displayed on the gaming machine. Measures have been taken against fraudulent acts of playing games by misidentifying that they have been thrown.

For example, in Patent Document 1, two proximity sensors for detecting medals are provided in the medal passage, and it is determined whether or not a gaming medal has passed through the medal passage based on the output of each proximity sensor. A slot machine for detecting fraudulent activity in which a device such as a shape is used is described.

JP, 2002-342814, A

However, the slot machine described in Patent Document 1 cannot detect an illegal act performed using an illegal medal without using an instrument such as a plate-shaped body. For example, if a medal with a loan unit price of 20 yen and a medal of 5 yen each with the same diameter are lent in the hall where this slot machine is installed and have different colors and markings (patterns), the slot machine Cannot be determined. Therefore, in a gaming machine that handles a medal with a loan unit price of 20 yen as a regular medal, it is not possible to detect an illegal act of playing a game using a medal with a loan unit price of 5 yen (illegal medal). ..

In addition, in the slot machine described in Patent Document 1, a medal lent in a hall in which a gaming machine is installed, a medal lent in another hall, and a gaming machine purchased at a used machine store are attached. When a medal that is present or a counterfeit medal (including a device that looks like a medal) has the same diameter but only the color and the marking (pattern), these cannot be distinguished. Therefore, it is difficult to detect (detect) an illegal act of playing a game using a medal (illegal medal) other than the regular medal.

The present invention has been made to solve the above problems, and an object of the present invention is to make it possible to detect a fraudulent act of playing a game by misidentifying that a legitimate game medium is used in a gaming machine. Providing a gaming machine.

In order to achieve the above object, the present invention provides a gaming machine having the following configuration.

A slot for inserting a game medium (for example, a medal slot 21 described later),
A game machine comprising: a game medium detecting means (for example, a medal selector 701 described later) for detecting a game medium inserted from the slot.
The game medium detecting means,
A passage forming portion (for example, a medal rail 210 described later) that forms a passage through which a game medium passes,
An image pickup means (for example, a camera unit 209 described later) for picking up an image of the passage,
Based on the image data captured by the image capturing means, a game medium determining means (for example, a color recognition circuit 247 and an image to be described later) that performs a determining process of determining whether or not an object passing through the passage is a regular game medium. Recognition DSP circuit 242),
A template generation unit that generates template data used for the determination processing (for example, a color recognition circuit 247 and an image recognition accelerator circuit 249 of a control LSI 234 described later),
The game medium determining means determines whether or not the object passing through the passage is a regular game medium based on whether the image data and the template data match or are similar to each other to a predetermined degree. Then
The template generation unit groups a plurality of the image data into groups of the image data that are the same or similar to each other to a predetermined degree, and selects the group within a predetermined number from the upper rank in which the number of the image data belonging to the group is large. Then, for each of the selected groups, the template data is generated based on the image data belonging to the group,
The template data has a plurality of types of template data,
One of the plurality of types of template data is pattern template data relating to the pattern of the game medium,
In the generation processing of the pattern template data by the template generation means, the image data is converted into color space image data (for example, YUV image data described later), and one element in the converted color space image data is predetermined. A game machine characterized by using a conversion value obtained by performing coordinate conversion of the generated data after being generated by the processing of.

According to the present invention, it is possible to misidentify that a legitimate game medium is used in a gaming machine and detect a fraudulent act of playing a game.

It is explanatory drawing explaining the function flow in the game machine of one Embodiment of this invention. It is a perspective view showing an example of appearance composition in a game machine of one embodiment of the present invention. It is a perspective view showing an internal structure in a game machine of one embodiment of the present invention, and showing a state in which a middle door is closed. It is a perspective view showing an internal structure in a game machine of one embodiment of the present invention, and showing a state in which a middle door is opened. It is an explanatory view showing the inside of the cabinet in the game machine of one embodiment of the present invention. It is an explanatory view showing the back side of the front door in the game machine of one embodiment of the present invention. It is the perspective view which looked at the medal selector in the game machine of one embodiment of the present invention from diagonally back of the game machine. It is an exploded view of the medal selector in the gaming machine of one embodiment of the present invention. It is the perspective view which looked at the medal selector in the game machine of one embodiment of the present invention from the slanting front of the game machine. It is a rear view of the base plate portion of the medal selector in the gaming machine of one embodiment of the present invention. It is a perspective view of the select plate of the medal selector in the gaming machine of one embodiment of the present invention. It is a figure which shows the path|route of the medal when the medal selector in the gaming machine of one embodiment of the invention guides the medal to the hopper device. It is a figure showing a course of a medal when a medal selector in a game machine of one embodiment of the invention guides a medal to a medal shoot. It is a block diagram showing a control system in a game machine of one embodiment of the present invention. It is a block diagram showing an example of composition of a main control circuit in a game machine of one embodiment of the present invention. It is a block diagram showing an example of composition of a sub control circuit in a game machine of one embodiment of the present invention. It is a block diagram showing an example of circuit composition of a medal selector in a game machine of one embodiment of the present invention. It is a block diagram showing an example of circuit composition of control LSI in a game machine of one embodiment of the present invention. It is a figure for explaining distortion of a lens in a game machine of one embodiment of the present invention. FIG. 9 is a diagram for explaining the projective transformation process in the gaming machine according to the embodiment of the present invention, where A shows an RGB Bayer image before projective transformation and B shows an RGB Bayer image after projective transformation. It is a figure for explaining a threshold graph in the game machine of one embodiment of the present invention. It is a figure (the 1) for explaining the judgment field in the game machine of one embodiment of the present invention. It is a figure (the 2) for explaining the judgment field in the game machine of one embodiment of the present invention. It is a figure (the 3) for explaining the judgment field in the game machine of one embodiment of the present invention. It is a figure (the 4) for explaining the judgment field in the game machine of one embodiment of the present invention. It is a figure showing an example of judgment area judgment result data memorized by SRAM in a game machine of one embodiment of the present invention. It is a figure for explaining the medal count determination table in the gaming machine of one embodiment of the present invention. It is a figure for explaining the Gaussian filter in the game machine of one embodiment of the present invention. It is a figure for explaining circle area detection processing in a game machine of one embodiment of the present invention. It is a figure for demonstrating the 3(sigma) correction process in the game machine of one Embodiment of this invention. It is a figure for explaining filter processing in a game machine of one embodiment of the present invention, A shows typically circle field image data after 3σ correction processing, B shows a coefficient for edge image X, C indicates the coefficient for the edge image Y. It is a figure showing an example of a regular medal used for a game machine of one embodiment of the present invention, A shows one side of a regular medal, and B shows gradient average image data of a regular medal. It is a figure for explaining HOG conversion processing in a game machine of one embodiment of the present invention. It is a flow chart of processing which control LSI in a game machine of one embodiment of the present invention performs. It is a timing chart (the 1) of the processing which the control LSI in the game machine of one embodiment of the present invention performs. It is a timing chart (the 2) of the processing which the control LSI in the game machine of one embodiment of the present invention performs. It is a figure for explaining the medal selector in the game machine of the modification 1 of the present invention. It is a block diagram which shows the circuit structural example of the medal selector in the game machine of the modification 2 of this invention. It is a block diagram showing an example of circuit composition of control LSI in a game machine of modification 2 of the present invention. It is a block diagram which shows the control system in the game machine of the modification 3 of this invention. It is a block diagram which shows the circuit structural example of the medal selector in the game machine of the modification 3 of this invention. It is a figure for demonstrating the installation position of the double photo sensor of the medal selector in the game machine of the modification 3 of this invention. It is a block diagram which shows the circuit structural example of the medal selector in the game machine of the modification 4 of this invention. It is a rear view of the medal selector in the game machine of the modification 5 of the present invention. It is a block diagram which shows the circuit structural example of the medal selector in the game machine of the modification 5 of this invention. It is a block diagram which shows the circuit structural example of the medal selector in the game machine of the modification 6 of this invention.

Hereinafter, a pachi-slot which is a gaming machine showing an embodiment of the present invention will be described with reference to FIGS. 1 to 36.

<Function flow>
First, the functional flow of the pachi-slot will be described with reference to FIG.
In the pachi-slot of the present embodiment, medals are used as game media for playing games. As the game medium, coins, game balls, game point data, tokens or the like can be applied in addition to medals.

When a player inserts a medal and operates the start lever, one value (hereinafter, a random number value) is extracted from random numbers in a predetermined numerical value range (for example, 0 to 65535).

The internal lottery means performs lottery based on the extracted random number value and determines an internal winning combination. This internal lottery means is carried out by the main control circuit described later. By the determination of the internal winning combination, the combination of symbols that is allowed to be displayed along the winning determination line described later is determined. The types of symbol combinations include those related to "winning prizes" in which benefits such as payout of medals, operation of replays, operation of bonuses, etc. are given to the player, and those related to other so-called "losses". Is provided.

Further, when the start lever is operated, the plurality of reels are rotated. After that, when the player presses the stop button corresponding to the predetermined reel, the reel stop control means performs control for stopping the rotation of the corresponding reel based on the internal winning combination and the timing when the stop button is pressed. To do. This reel stop control means is carried out by a main control circuit described later.

In the pachi-slot, basically, control is performed to stop the rotation of the corresponding reel within a specified time (190 msec or 75 msec) from when the stop button is pressed. In the present embodiment, the number of symbols that move with the rotation of the reel within this specified time is called the “number of sliding pieces”. When the prescribed period is 190 msec, the maximum number of sliding pieces is set to 4 symbols, and when the prescribed period is 75 msec, the maximum number of sliding pieces is set to 1 symbol.

The reel stop control means, when the internal winning combination permitting the combination display of the symbols related to the winning is determined, the combination of the symbols is usually within the specified time of 190 msec (4 symbols), and the winning combination is the winning determination line. Stop the rotation of the reel so that it is displayed along with as much as possible. Further, the reel stop control means defines, for example, one or more reels at the time of the operation of the challenge bonus (CB) and the middle bonus (MB) of continuously operating the second type special accessory. Within 75 msec (one frame of the symbol), the rotation of the reel is stopped so that the symbol combination is displayed as much as possible along the winning determination line. Furthermore, the reel stop control means uses various prescribed times corresponding to the gaming state to rotate the reels so that a combination of symbols which is not permitted to be displayed by the internal winning combination is not displayed along the winning determination line. Stop.

In this way, when the rotation of the plurality of reels is all stopped, the winning determination means determines whether or not the symbol combination displayed along the winning determination line is related to winning. The winning determination means is carried out by the main control circuit described later. When it is determined by the prize determination means that the prize is related to the prize, a bonus such as payout of medals is given to the player. In the pachi-slot, a series of flows as described above is performed as one game.

In addition, in the pachi-slot, in the above-described series of flows, image display performed by a display device such as a liquid crystal display device, light output performed by various lamps, sound output performed by a speaker, or a combination thereof is used. Various productions are performed.

When the start lever is operated, a random number value for rendering (hereinafter, a random number value for rendering) is extracted in addition to the random number value used for determining the internal winning combination described above. When the random number value for effect is extracted, the effect content determination means randomly determines, from among a plurality of types of effect content associated with the internal winning combination, the effect content to be executed this time. The sub-control circuit described later plays a role of this effect content determination means.

When the effect content is determined, the effect execution means executes the corresponding effect in association with each trigger such as the start of rotation of the reels, the stop of rotation of each reel, the determination of the presence or absence of a prize. In this way, in the pachi-slot, the player has an opportunity to know or anticipate the determined internal winning combination (in other words, the combination of the symbols to be aimed) by executing the effect contents associated with the internal winning combination. It is provided, and the interest of the player can be improved.

<Pachislot structure>
Next, the structure of the pachi-slot 1 according to the embodiment will be described with reference to FIGS.

[Appearance structure]
FIG. 2 is a perspective view showing an external structure of the pachi-slot 1.

As shown in FIG. 2, the pachi-slot 1 includes an exterior body 2. The exterior body 2 has a cabinet 2a that accommodates a hopper device 51, a medal auxiliary storage 52, and the like (see FIG. 5) described later, and a front door 2b that is openably and closably attached to the cabinet 2a.
Handles 7 are provided on both sides of the cabinet 2a (only one handle 7 is shown in FIG. 2). The handle 7 is a recess for holding the pachi-slot 1 when carrying it.

Inside the exterior body 2, three reels 3L, 3C, 3R are provided side by side. Hereinafter, the reels 3L, 3C, 3R are referred to as the left reel 3L, the middle reel 3C, and the right reel 3R, respectively. Each of the reels 3L, 3C, and 3R has a reel body formed in a cylindrical shape, and a translucent sheet material mounted on the peripheral surface of the reel body. On the surface of the sheet material, a plurality of (for example, 20) patterns are drawn at predetermined intervals along the circumferential direction.

The front door 2b includes a door body 9, a front panel 10, and a liquid crystal display device 11 showing a specific example of a display device.

The door body 9 is attached to the cabinet 2a using a hinge (not shown), and opens and closes the opening of the cabinet 2a. The hinge is provided at the left end of the door body 9 when the door body 9 is viewed from the front of the pachi-slot 1. The liquid crystal display device 11 is attached to the upper part of the door body 9. The liquid crystal display device 11 includes a display unit (display screen) 11 a, and the liquid crystal display device 11 is used to perform an effect by displaying an image.

The front panel 10 is arranged so as to overlap the display portion 11a side of the liquid crystal display device 11, and is formed in a frame shape having a panel opening 10a that exposes the display portion 11a of the liquid crystal display device 11. A lamp group 18 is provided on the front panel 10. The lamp group 18 includes LEDs (Light Emitting Diodes) and the like, and turns on and off the light in a pattern corresponding to the effect contents.

A pedestal portion 12 is formed at the center of the front door 2b. The pedestal portion 12 is provided with the symbol display area 4 and various devices to be operated by the player.

The symbol display area 4 is arranged on the front side overlapping the three reels 3L, 3C, 3R when viewed from the front, and is provided corresponding to the three reels 3L, 3C, 3R. The symbol display area 4 functions as a display window and is configured to be able to pass through the reels 3L, 3C, 3R provided behind it. Hereinafter, the symbol display area 4 is referred to as a reel display window 4.

When the reels 3L, 3C, 3R provided behind the reel display window 4 are stopped from rotating, the reel display window 4 has, among the plurality of types of symbols of the reels 3L, 3C, 3R, an upper stage, a middle stage and a lower stage in the frame. One pattern is displayed in each area (3 in total). In the present embodiment, a pseudo line configured by combining any one of the three predetermined areas, namely, the upper, middle, and lower rows of the reel display window 4, is a target for determining whether or not to win. Is defined as a line (winning determination line).

The reel display window 4 is formed by a frame member 13 provided on the pedestal portion 12. The frame member 13 has a reel display window 4, an information display window 14, and a stop button mounting portion 15.

The information display window 14 is provided continuously to the lower portion of the reel display window 4 and opens upward. That is, the reel display window 4 and the information display window 14 are formed as one continuous opening. The information display window 14 and the reel display window 4 are covered with a transparent window cover 16.

The window cover 16 is arranged on the inner surface side of the frame member 13 and cannot be removed from the front surface side of the front door 2b. Further, the frame member 13 has a sheet mounting portion 17 that faces the opening of the information display window 14 with the window cover 16 interposed therebetween. Then, a sheet member (information sheet) in which information regarding a game is written is arranged between the sheet placing portion 17 and the window cover 16. Therefore, the information sheet is covered with the window cover 16 having a smooth surface without irregularities or gaps.

Since the window cover 16 constituting the mounting portion of the information sheet cannot be removed from the front side of the front door 2b and has a smooth surface without irregularities or gaps, the pachi-slot 1 can be used by using the mounting portion of the information sheet. You can prevent fraudulent activities that access the inside of the.

The stop button mounting portion 15 is provided below the information display window 14 and is formed on a plane facing the front. The stop button mounting portion 15 is provided with a through hole through which the stop buttons 19L, 19C, 19R penetrate. The stop buttons 19L, 19C, 19R are associated with each of the three reels 3L, 3C, 3R, and are provided to stop the rotation of the corresponding reels. Hereinafter, the stop buttons 19L, 19C, and 19R are referred to as the left stop button 19L, the middle stop button 19C, and the right stop button 19R, respectively.

The stop buttons 19L, 19C, and 19R represent examples of various devices that are targets of operations by the player. In addition, the pedestal portion 12 is provided with a medal insertion slot 21, a BET button 22, and a start lever 23, which are various devices to be operated by the player.

The medal slot 21 is provided to receive medals that are dropped from the outside by the player. The medals received in the medal insertion slot 21 will be inserted into one game with a predetermined number (for example, 3) set in advance as an upper limit, and the amount exceeding the prescribed number will be deposited inside the pachi-slot 1. It becomes possible (a so-called credit function).

The BET button 22 is provided to determine the number of medals deposited in the pachi-slot 1 for one game. The start lever 23 is provided to start rotation of all reels (3L, 3C, 3R).

A 7-segment display 24 including a 7-segment LED (Light Emitting Diode) is provided on the left side of the reel display window 4 when the front door 2b is viewed from the front. The 7-segment display 24 digitally displays information such as the number of medals to be paid out to the player as a privilege (hereinafter, the number of payouts) and the number of medals deposited in the pachi-slot (hereinafter, the number of credits). ..

A settlement button 27 is provided on the left side of the pedestal portion 12 when the front door 2b is viewed from the front. The settlement button 27 is provided for pulling out (discharging) to the outside stored in the pachi-slot 1. A waist panel unit 31 is provided below the pedestal portion 12. The waist panel unit 31 has a decorative panel on which an arbitrary image is drawn, and a light source that emits light for illuminating the decorative panel from the back side.

Below the waist panel unit 31, a medal payout opening 32, speaker holes 33L and 33R, and a medal tray unit 34 are provided. The medal payout port 32 guides the medals discharged from the medal selector 201 described later and the medals discharged by driving the hopper device 51 described later to the outside. The medals discharged from the medal payout opening 32 are stored in the medal tray unit 34. The speaker holes 33L and 33R are provided to output a sound effect or a sound such as music corresponding to the effect contents.

[Internal structure]
3 and 4 are perspective views showing the internal structure of the pachi-slot 1. In FIG. 3, the front door 2b is opened, and the middle door 41 provided on the back surface side of the front door 2b is closed with respect to the front door 2b. Further, FIG. 4 shows a state in which the front door 2b is opened and the middle door 41 is opened with respect to the front door 2b.
Further, FIG. 5 is an explanatory diagram showing the inside of the cabinet 2a. FIG. 6 is an explanatory diagram showing the back surface side of the front door 2b.

The cabinet 2a has a top plate 20a, a bottom plate 20b, left and right side plates 20c and 20d, and a back plate 20e (see FIG. 5). A cabinet-side speaker 42 is provided on the upper side inside the cabinet 2a. The cabinet-side speaker 42 is attached to the back plate 20e of the cabinet 2a via mounting brackets 43L and 43R. The cabinet side speaker 42 is, for example, a speaker for outputting a sound effect.

A cabinet-side relay board 44 is disposed on the left side of the cabinet-side speaker 42 when the inside of the cabinet 2a is viewed from the front. The cabinet side relay board 44 is attached to the left side plate 20c of the cabinet 2a. The cabinet side relay board 44 includes a main control board 71 (see FIG. 14), which will be described later, attached to the middle door 41 (see FIGS. 3 and 4), a hopper device 51, a medal auxiliary storage switch (not shown), and a medal payout. The wiring for connecting to a count switch (not shown) is relayed.

An amplifier board 45 that controls the output of sound from the cabinet-side speaker 42 is arranged in the center of the cabinet 2a. The amplifier board 45 is attached to a mounting shelf 46 fixed to the left and right side plates 20c and 20d.

Further, when the inside of the cabinet 2a is viewed from the front, an external concentrated terminal board 47 is arranged on the right side of the amplifier board 45 (see FIG. 5). The external centralized terminal board 47 is attached to the right side surface board 20d of the cabinet 2a. The external centralized terminal board 47 is provided for outputting signals such as a medal insertion signal, a medal payout signal, and a security signal to the outside of the pachi-slot 1.

A sub power supply device 48 is disposed on the left side of the amplifier board 45 when the inside of the cabinet 2a is viewed from the front. The sub power supply device 48 is attached to the left side plate 20c of the cabinet 2a. The sub power supply device 48 supplies electric power of 100 V AC voltage to the power supply device 53 described later. Further, the AC voltage of 100 V is converted into the DC voltage and supplied to the amplifier board 45.

A medal payout device (hereinafter referred to as a hopper device) 51, a medal auxiliary storage 52, and a power supply device 53 are arranged below the inside of the cabinet 2a.

The hopper device 51 is attached to the central portion of the bottom plate 20b of the cabinet 2a. The hopper device 51 has a structure capable of accommodating a large amount of medals and discharging them one by one. For example, when the settlement button 27 (see FIG. 2) is pressed and the medals stored in the pachi-slot are settled, the hopper device 51 discharges the stored medals by the number of credits. The medals paid out by the hopper device 51 are discharged from the medal payout opening 32 (see FIG. 2).

The medal auxiliary storage 52 stores the medals overflowing from the hopper device 51. The medal auxiliary storage 52 is arranged on the right side of the hopper device 51 when the inside of the cabinet 2a is viewed from the front. The medal auxiliary storage 52 is engaged with the bottom plate 20b of the cabinet 2a and is configured to be attachable to and detachable from the bottom plate 20b.

The power supply device 53 is arranged on the left side of the hopper device 51 when the inside of the cabinet 2a is viewed from the front, and is attached to the left side face plate 20c. The power supply device 53 has a power switch 53a and a power board 53b (see FIG. 14). The power supply device 53 converts the power of the AC voltage 100V supplied from the sub power supply device 48 into the power of the DC voltage required by each unit, and supplies the converted power to each unit.

As shown in FIG. 3, FIG. 4 and FIG. 6, the middle door 41 is arranged in the center of the back surface of the front door 2b, and is configured to open and close the reel display window 4 (see FIG. 4) from the back side. Door stoppers 41a, 41b, 41c are provided on the upper and lower portions of the middle door 41. The door stoppers 41a, 41b, 41c fix (prohibit) the opening operation of the middle door 41 with the reel display window 4 closed from the back side. That is, in order to open the middle door 41, it is necessary to rotate the door stoppers 41a, 41b, 41c to release the fixation of the middle door 41.

A main control board case 55 accommodating a main control board 71 (see FIG. 14) and three reels 3L, 3C, 3R are attached to the middle door 41. A stepping motor is connected to the three reels 3L, 3C, 3R via a gear having a predetermined reduction ratio.

As shown in FIG. 6, the main control board case 55 is provided with a setting key type switch 56. The setting key type switch 56 is used when the setting of the pachi-slot 1 is changed or the setting of the pachi-slot 1 is confirmed.
In the present embodiment, the main control board case 55 and the main control board 71 housed in the main control board case 55 constitute a main control board unit.

The main control board 71 housed in the main control board case 55 constitutes a main control circuit 91 (see FIG. 15) described later. The main control circuit 91 is a circuit for controlling the main flow of the game in the pachi-slot 1, such as determination of internal winning combination, rotation and stop of the reels 3L, 3C, 3R, and determination of presence or absence of winning. The specific configuration of the main control circuit 91 will be described later.

A sub-control board case 57 that accommodates the sub-control board 72 (see FIG. 14) is provided above the middle door 41, and a center speaker 58 is provided above the sub-control board case 57. The sub control board 72 housed in the sub control board case 57 constitutes a sub control circuit 101 (see FIG. 16). The sub-control circuit 101 is a circuit that controls execution of effects such as display of images. The specific configuration of the sub control circuit 101 will be described later.

A sub relay board 61 is disposed on the right side of the sub control board case 57 when the front door 2b is viewed from the back side. The sub relay board 61 relays the wiring connecting the sub control board 72 and the main control board 71. The sub-control board 72 is a board that relays a wiring that connects the sub-control board 72 and a board arranged around the sub-control board 72. It should be noted that examples of the boards arranged around the sub-control board 72 include LED boards 62A, 62B, and 62C described later.

The LED boards 62A, 62B, and 62C are arranged on both sides of the sub control board case 57 when viewed from the back surface side of the front door 2b. These LED boards 62A, 62B, and 62C include a plurality of LEDs (Light Emitting Diodes) 85 (see FIG. 14) showing a specific example of a light source according to the effect executed by the control of the sub control circuit 101 (see FIG. 16). ) Is lit to display the blinking pattern. The pachi-slot 1 of the present embodiment includes a plurality of LED boards in addition to the LED boards 62A, 62B, 62C.

Below the sub relay board 61, a 24h door opening/closing monitoring unit 63 is arranged. The 24h door opening/closing monitoring unit 63 stores a history of opening/closing of the middle door 41. Further, when the middle door 41 is opened, a signal for displaying an error on the liquid crystal display device 11 is output to the sub control board 72 (sub control circuit 101).

A board speaker 64 and lower speakers 65L and 65R are disposed below the middle door 41. The board speaker 64 faces the waist panel unit 31 (see FIG. 2), and the lower speakers 65L and 65R face the speaker holes 33L and 33R (see FIG. 2), respectively.

A medal selector 201, a medal chute 202, and a door opening/closing monitoring switch 67 are arranged above the lower speaker 65L. The medal selector 201 is a device that determines whether or not the material and shape of the medal are appropriate, and guides the medal inserted into the medal insertion slot 21 to the hopper device 51 via the slope 203, or Guide to the chute 202. The specific configuration of the medal selector 201 will be described later.

The medal chute 202 is a substantially Y-shaped tubular member, and guides the medals guided by the medal selector 201 and the medals discharged from the hopper device 51 to the medal payout outlet 32 (see FIG. 2).

The door opening/closing monitoring switch 67 is arranged on the left side of the medal selector 201 when the front door 2b is viewed from the back side. The door opening/closing monitoring switch 67 outputs a security signal for notifying the opening/closing of the front door 2b to the outside of the pachi-slot 1.

Further, a door relay terminal plate 68 is arranged in a region below the reel display window 4 and opened/closed by the middle door 41 (see FIG. 4). The door relay terminal board 68 includes a main control board 71 (see FIG. 14) in the main control board case 55, various buttons and switches, a sub control board 72 (see FIG. 14), a medal selector 201, and a game operation display board. 81 is a substrate that relays the wiring with 81 (see FIG. 14). The various buttons and switches include, for example, the BET button 22, the settlement button 27, the door opening/closing monitoring switch 67, the BET switch 77, the start switch 79, and the like, which will be described later.

<Medal selector configuration>
Next, a specific configuration of the medal selector 201 will be described with reference to FIGS. FIG. 7 is a perspective view of the medal selector 201 as seen obliquely from the rear of the pachi-slot 1. FIG. 8 is an exploded view of the medal selector 201. FIG. 9 is a perspective view of the medal selector 201 as seen obliquely from the front of the pachi-slot 1. FIG. 10 is a rear view of a base plate portion 204, which will be described later, of the medal selector 201. FIG. 11 is a perspective view of a later-described select plate 207 of the medal selector 201. FIG. 12 is a diagram showing a route of medals when the medal selector 201 guides the medals to the hopper device 51. FIG. 13 is a diagram showing a route of medals when the medal selector 201 guides the medals to the medal shoot 202. 7 to 13, the arrow X indicates the left-right direction of the pachi-slot 1, the arrow Y indicates the front-back direction of the pachi-slot 1, and the arrow Z indicates the vertical direction.

As shown in FIGS. 7 to 9, the medal selector 201 includes a base plate portion 204, a sub plate 205, a cancel shooter 206, a select plate 207, a medal solenoid 208 (see FIG. 9 ), a camera unit 209, Equipped with.

The base plate portion 204 is a substantially plate-shaped member that constitutes the outer frame housing of the medal selector 201, and is formed so that both left and right ends of the pachi-slot 1 are bent rearward of the pachi-slot 1. The base plate portion 204 has a rear surface 204b, which is one plane orthogonal to the front-back direction of the pachi-slot 1, and a front surface 204a (see FIG. 9), which is the other plane. A medal rail 210 is formed on the rear surface 204b so as to be recessed forward of the pachi-slot 1 and in a substantially L shape. Plural ridges 210 a are formed on the surface of the medal rail 210.

A medal entrance 211 for receiving medals inserted from the medal insertion slot 21 (see FIG. 2) is provided at the upper end of the base plate portion 204. The medals inserted into the medal selector 201 from the medal entrance 211 move from the upper side to the lower side along the medal rails 210. A medal exit portion 204c (see FIG. 8) is provided below the base plate portion 204. The medals that have moved inside the medal selector 201 are discharged from the medal exit portion 204c and are housed in the hopper device 51 via the slope 203 (see FIG. 4).

A center hole 212 penetrating in the front-rear direction is formed at a substantially intermediate position of the medal rail 210, and an end portion of the medal pressure 213 (see FIG. 8) is exposed from the center hole 212. As shown in FIG. 9, the medal pressure 213 is rotatably supported by a shaft portion 214 provided on the front surface 204 a of the base plate portion 204. A coil spring 215 is attached to the shaft portion 214, and the medal pressure 213 is biased by the coil spring 215 so that the medal pressure 213 projects from the central hole 212.

As shown in FIG. 9, a magnet 217 is provided on the front surface 204 a of the base plate portion 204. The magnet 217 attracts (magnetizes) an illegal medal which is not made of an appropriate material among the medals moving on the medal rail 210.

In addition, as shown in FIG. 8, an upper exposure hole 219 that penetrates in the front-rear direction and that exposes a rear end portion of an after medal pressure 218 to be described later is formed in a substantially central portion of a downstream region of the medal rail 210. .. A lower exposure hole 220 that penetrates in the front-rear direction and exposes a medal stopper portion 227 of the select plate 207, which will be described later, is formed in the lower part of the downstream region of the medal rail 210.

Further, as shown in FIG. 10, six reference markers 260 are formed on the medal rail 210. The reference marker 260 is arranged in an imaging area A1 (indicated by a chain line in FIG. 10) which is an area on the medal rail 210 captured by the camera unit 209.

The reference marker 260 is composed of an upper reference marker 261 and a lower reference marker 262, and the upper reference marker 261 is arranged above the medal rail 210 so as to be inclined and arranged side by side in three rows. Further, three lower reference markers 262 are arranged below the medal rail 210 so as to be aligned in the left-right direction while being inclined.

In the reference marker 260, in the image data of the imaging region imaged by the camera unit 209, the luminance of the pixel where the reference marker 260 is formed and the luminance of the pixel where the reference marker 260 is not formed, Are formed so as to differ by a predetermined value or more. In the present embodiment, each reference marker 260 is formed by forming a triangular hole in the medal rail 210. The form of the reference marker 260 is not limited to this, and the shape of the hole can be selected as appropriate. Further, for example, the reference marker 260 may be formed on the medal rail 210 by printing a graphic having a color different from the background color of the medal rail 210.

As shown in FIG. 9, the medal solenoid 208 is formed in a plate shape with a solenoid main body 208a, and one end portion and the other end portion are movable plate portions 208b supported by the solenoid main body portion 208a so as to be movable in the front-rear direction. Equipped with. The after medal pressure 218 is rotatably supported by the front surface 204 a of the base plate portion 204. When the front end of the after medal pressure 218 is pressed to the rear of the pachi-slot 1 by the movable plate portion 208b of the medal solenoid 208, the after medal pressure 218 rotates, and the rear end of the after medal pressure 218 has the upper exposure hole 219 ( (See FIG. 8).

As shown in FIGS. 7 and 8, the cancel shooter 206 is a substantially plate-shaped member, and is formed such that the left and right ends of the pachi-slot 1 are bent forward of the pachi-slot 1. The cancel shooter 206 is detachably fixed to the base plate portion 204 and covers the lower portion of the base plate portion 204 from the rear side. The cancel shooter 206 guides the medals discharged without passing through the medal exit portion 204c to the medal chute 202 (see FIG. 4). A notch portion 206a, which is cut out in a substantially rectangular shape downward, is formed in an upper portion of a substantially central portion in the left-right direction of the cancel shooter 206.

Further, the cancel shooter 206 is provided with a notification LED 206c. The notification LED 206c constitutes a notification unit that lights up and notifies that an error has occurred in the AE correction process described later.

As shown in FIGS. 7 and 8, the sub plate 205 is a plate-shaped member that covers the medal rail 210 from the rear side. The sub-plate 205 has a flat plate-shaped main body portion 221 and a shaft portion 222 provided on the upper portion of the main body portion 221. A through hole 221a penetrating in the front-rear direction is provided at a substantially central portion of the main body portion 221, and a downstream region is exposed from the substantially central portion of the medal rail 210 through the through hole 221a.

The shaft portion 222 is supported by the base plate portion 204, and the sub-plate 205 is attached to the base plate portion 204 so as to be rotatable around the shaft portion 222. A coil spring 223 is attached to the shaft portion 222. Normally, the sub-plate 205 is pressed against the base plate portion 204 side by the biasing force of the coil spring 223. At this time, a space through which medals can pass is formed between the sub plate 205 and the upper portion of the medal rail 210 covered by the sub plate 205. That is, the sub plate 205 functions as a guide plate that allows medals to pass through.

Here, for example, when a medal jam occurs in the medal selector 201, the sub plate 205 can be rotated against the biasing force of the coil spring 223 to eliminate the medal jam.

As shown in FIG. 7, the select plate 207 is a member that guides medals that move in a substantially central portion of the medal rail 210 that is not covered by the sub-plate 205. As shown in FIG. 11, the select plate 207 includes a plate body 224 having a substantially trapezoidal plate shape, and a pair of bearing portions formed by bending the left and right ends of the plate body 224 toward the front of the pachi-slot 1. 225 and. Further, a flange portion 226 formed by bending the pachi-slot 1 forward and bending the rear end portion upward is formed on the upper portion of the plate body 224. Further, a medal stopper portion 227 extending downward is formed on one bearing portion 225.

As shown in FIG. 7, the plate body 224 faces the substantially central portion of the medal rail 210 not covered by the sub-plate 205 in the front-back direction of the pachi-slot 1.

As shown in FIG. 9, the select plate 207 is rotatably supported by a shaft portion 228 provided on the front surface 204 a of the base plate portion 204. The shaft portion 228 is provided with a coil spring 229 and biases the flange portion 226 toward the front of the pachi-slot 1. The flange portion 226 is in contact with one end of the movable plate portion 208b of the medal solenoid 208. When the medal solenoid 208 is in the ON state, the flange portion 226 is pressed by one end of the movable plate portion 208b of the medal solenoid 208 and moves to the rear of the pachi-slot 1 against the biasing force of the coil spring 229. The rotation position of the select plate 207 at this time is referred to as a “guide position”. The distance between the plate body 224 of the select plate 207 at the guide position and the medal rail 210 is set to a predetermined distance that allows the medal rail 210 to be guided to the hopper device 51 without discharging the medal to the cancel shooter 206 side. Further, at this time, the medal stopper portion 227 does not protrude from the lower exposed hole 220 (see FIG. 8).

Further, when the medal solenoid 208 is in the OFF state, the flange portion 226 is released from the pressure of the medal solenoid 208, and moves to the front of the pachi-slot 1 by the biasing force of the coil spring 229. The rotation position of the select plate 207 at this time is referred to as a “discharge position”. The distance between the plate body 224 of the select plate 207 at the ejection position and the medal rail 210 is set to be longer than a predetermined distance. At this time, the flange portion 226 moving to the front of the pachi-slot 1 is pressed, and one end of the movable plate portion 208b of the medal solenoid 208 moves to the front of the pachi-slot 1. Along with this, the other end of the movable plate portion 208b of the medal solenoid 208 moves to the rear of the pachi-slot 1 and presses the front end of the after medal pressure 218. As a result, the after medal pressure 218 is rotated, and the rear end portion of the after medal pressure 218 is exposed from the upper exposure hole 219 (see FIG. 8).

The medal stopper portion 227 does not protrude from the lower exposure hole 220 (see FIG. 8) when the select plate 207 is in the guide position, and protrudes from the lower exposure hole 220 when it is in the ejection position.

As shown in FIG. 12, when the medal moving on the medal rail 210 meets the standard size, the select plate 207 in the guide position contacts the upper part of the moving medal and moves the medal to the medal exit portion 204c (see FIG. 8). ) To. The medal pushes the medal pressure 213 toward the front of the pachi-slot 1 when being guided by the select plate 207. Note that, in FIG. 12, the sub-plate 205 of the medal selector 201 and the cancel shooter 206 are omitted.

On the other hand, as shown in FIG. 13, even if the medals moving on the medal rails 210 satisfy the standard size, the select plate 207 in the ejection position has a distance between the plate body 224 and the medal rails 210. Therefore, the medal cannot be guided to the medal exit portion 204c (see FIG. 8). Further, the medal is pushed out to the medal pressure 213, the after medal pressure 218 protruding from the upper exposure hole 219, or the medal stopper portion 227 protruding from the lower exposure hole 220, and is ejected toward the cancel shooter 206. Note that, in FIG. 13, as in FIG. 12, the sub-plate 205 and the cancel shooter 206 of the medal selector 201 are not shown.

Further, in the present embodiment, the select plate 207 is normally positioned at the guide position, but under a predetermined condition (for example, when a specified number of medals are inserted, when an error occurs, when a game is started, etc.), the select plate 207 is placed at the discharge position. It is positioned.

Further, when the medal moving on the medal rail 210 has a diameter smaller than the standard size, even if the select plate 207 is at the guide position, the medal is not guided to the select plate 207 but pushed out to the medal pressure 213 and the cancel shooter 206. Is discharged toward.

As shown in FIGS. 7 and 8, the camera unit 209 includes a first substrate 230, a second substrate 231, and a lens (not shown). Whether the object moving on the medal rail 210 is a regular medal or not. Is a unit which outputs the determination result to the main control circuit 91. A CMOS image sensor 232 (see FIG. 17) and an LED 233 (see FIG. 17) are provided on the first substrate 230. A control LSI 234 (see FIG. 17) that is communicably and controllably connected to the CMOS image sensor 232 and the LED 233 is provided on the second substrate 231.

The first substrate 230 and the second substrate 231 are connected by a BtoB (Board-to-Board) type connector (not shown), and by the leg portions 235 provided at the corners of the respective substrates 230 and 231. It is fixed. The specific configuration of the circuit of the camera unit 209 will be described later. Further, in the present embodiment, the mode in which the camera unit 209 is configured with the two substrates 230 and 231 and the lens has been described, but instead of this, one substrate provided with the CMOS image sensor 232, the LED 233, and the control LSI 234 is used. You may comprise a camera unit. Further, a diaphragm mechanism may be added.

The camera unit 209 is fixed by screwing the first substrate 230 into a screw hole 206b provided around the notch 206a in the upper portion of the cancel shooter 206.

The CMOS image sensor 232 (see FIG. 17) is provided in a substantially central portion of the first substrate 230. The CMOS image sensor 232 captures an image of the image capturing area A1 (see FIG. 10) on the medal rail 210 via the cutout portion 206a (see FIG. 8) of the cancel shooter 206, and captures the captured image data to the control LSI 234 (see FIG. 17). Output).

The LED 233 (see FIG. 17) emits surface light around the CMOS image sensor 232 and illuminates an object moving on the medal rail 210 with light. The control LSI 234 (see FIG. 17) determines whether the object moving on the medal rail 210 is a regular medal based on the image data output from the CMOS image sensor 232, and outputs the determination result to the main control circuit 91. To do. In the present embodiment, the mode in which the camera unit 209 is fixed to the cancel shooter 206 by screwing in the screw hole 206b formed around the notch 206a has been described, but the fixing mode of the camera unit is not limited to this. Not done. For example, a mounting rail is provided between the first substrate 230 and the second substrate 231, a recess is provided in the upper portion of the cancel shooter 206, and the mounting rail is fitted in this recess, and then the mounting rail and the cancel shooter 206 are provided. May be fixed with screws or an adhesive.

<Circuit structure of pachi-slot>
Next, the configuration of the circuit included in the pachi-slot 1 will be described with reference to FIGS.
First, the outline of the entire circuit of the pachi-slot 1 will be described with reference to FIG. FIG. 14 is a block configuration diagram of the entire circuit included in the pachi-slot 1.

The pachi-slot 1 has a main control board 71 arranged on the middle door 41 and a sub-control board 72 arranged on the front door 2b.
On the main control board 71, there are a reel relay terminal board 74, a setting key type switch 56, an external centralized terminal board 47, a hopper device 51, a medal auxiliary storage switch 75, and a power supply board 53b of the power supply device 53. It is connected. The setting key type switch 56, the external centralized terminal board 47, the hopper device 51, and the medal auxiliary storage switch 75 are connected to the main control board 71 via the cabinet side relay board 44. Since the external centralized terminal board 47 and the hopper device 51 have been described above, the description thereof will be omitted.

The reel relay terminal plate 74 is arranged inside the reel body of each reel 3L, 3C, 3R. The reel relay terminal plate 74 is electrically connected to a stepping motor (not shown) of each reel 3L, 3C, 3R and relays a signal output from the main control board 71 to the stepping motor.

The medal auxiliary storage case switch 75 penetrates a switch through hole (not shown) of the medal auxiliary storage case 52. The medal auxiliary storage switch 75 detects whether or not the medal auxiliary storage 52 is full of medals.

A power switch 53a is connected to a power board 53b of the power supply device 53. The power switch 53a is turned on when the pachi-slot 1 is supplied with necessary power.

Further, on the main control board 71, via the door relay terminal board 68, a medal selector 201, a door opening/closing monitor switch 67, a BET switch 77, a settlement switch 78, a start switch 79, a stop switch board 80, a game operation display board 81. And the sub relay board 61 is connected. The door open/close monitor switch 67 and the sub relay board 61 have been described above, and thus description thereof will be omitted. The circuit configuration of the medal selector 201 will be described later.

The BET switch 77 detects that the BET button 22 has been pressed by the player. The settlement switch 78 detects that the settlement button 27 is pressed by the player. The start switch 79 detects that the player has operated the start lever 23 (start operation).

The stop switch board 80 is a board that constitutes a circuit for stopping the spinning reel and a circuit for displaying the reel that can be stopped by using an LED or the like. The stop switch board 80 is provided with a stop switch. The stop switch detects that the stop buttons 19L, 19C, 19R have been pressed by the player (stop operation).

The game operation display board 81 displays the number of inserted medals on the 7-segment display 24 when accepting the insertion of medals, when the three reels 3L, 3C, 3R are rotatable and when replaying. It is a substrate for making. The 7-segment display 24 and the LED 82 are connected to the game operation display board 81. The LED 82 lights, for example, a mark indicating the start of a game, a mark for performing a replay, or the like.

The sub control board 72 is connected to the main control board 71 via the door relay terminal board 68 and the sub relay board 61. A sound I/O board 84, LED boards 62A, 62B, 62C, and a 24h door opening/closing monitoring unit 63 are connected to the sub control board 72 via a sub relay board 61. The LED boards 62A, 62B, 62C and the 24h door opening/closing monitoring unit 63 have been described above, and thus description thereof will be omitted.

The sound I/O board 84 outputs sound to a center speaker 58, a board speaker 64, lower speakers 65L and 65R, and a speaker (not shown) provided on the front door 2b.

A ROM cartridge substrate 86 and a liquid crystal relay substrate 87 are connected to the sub control substrate 72. The ROM cartridge substrate 86 and the liquid crystal relay substrate 87 are housed in the sub control substrate case 57 together with the sub control substrate 72.
The ROM cartridge board 86 is a board for managing images (video) for presentation, sound, LED boards 62A and 62B, other LED boards (not shown), and communication data. The liquid crystal relay board 87 is a board that relays the wiring that connects the sub-control board 72 and the liquid crystal display device 11.

<Main control circuit>
Next, the main control circuit 91 configured by the main control board 71 will be described with reference to FIG.
FIG. 15 is a block diagram showing a configuration example of the main control circuit 91 of the pachi-slot 1.

The main control circuit 91 has a microcomputer 92 installed on the main control board 71 as a main component. The microcomputer 92 includes a main CPU 93, a main ROM 94 and a main RAM 95. The main CPU 93 and the above-mentioned hopper device 51 constitute the game medium payout device of the present invention.

In the main ROM 94, a control program executed by the main CPU 93 (for example, a program for executing the above-mentioned internal lottery process), a data table, and various control commands (commands) to the sub-control circuit 101 are transmitted. Data and the like are stored. The main RAM 95 is provided with a storage area for storing various data such as an internal winning combination determined by executing the control program.

A clock pulse generation circuit 96, a frequency divider 97, a random number generator 98, and a sampling circuit 99 are connected to the main CPU 93. The clock pulse generation circuit 96 and the frequency divider 97 generate clock pulses. The main CPU 93 executes the control program based on the generated clock pulse. The random number generator 98 generates a random number within a predetermined range (for example, 0 to 65535). The sampling circuit 99 extracts one value from the generated random numbers.

The main CPU 93 counts the number of times a pulse is output to the stepping motor of each reel 3L, 3C, 3R after detecting the reel index. As a result, the main CPU 93 manages the rotation angle of each reel 3L, 3C, 3R (mainly, how many symbols the reel has rotated).
The reel index is information indicating that the reel has made one rotation. This reel index is provided, for example, with an optical sensor having a light emitting part and a light receiving part, and is provided at a predetermined position of each reel 3L, 3C, 3R. It is detected by a reel position detection unit (not shown) having a detection piece interposed therebetween.

Here, the management of the rotation angle of each reel 3L, 3C, 3R will be specifically described. The number of pulses output to the stepping motor is counted by a pulse counter provided in the main RAM 95. Then, each time the pulse counter counts the output of a predetermined number of pulses (for example, 16 times) required for rotating one symbol, the symbol counter provided in the main RAM 95 is incremented by one. The symbol counter is provided for each reel 3L, 3C, 3R. The value of the symbol counter is cleared when the reel index is detected by the reel position detector (not shown).

That is, in the present embodiment, by managing the symbol counter, the number of symbols rotated after the reel index is detected is managed. Therefore, the position of each symbol on each reel 3L, 3C, 3R is detected with reference to the position at which the reel index is detected.

As described above, when the maximum number of sliding pieces is set to 4 symbols, the symbol of the left reel 3L in the middle stage of the reel display window 4 when the left stop button 19L is pressed, and its 4 symbols Each symbol within the range up to the previous symbol is a symbol that can be stopped in the middle stage of the reel display window 4.

Further, when the determination result is input from the control LSI 234 of the medal selector 201, as will be described later, the main CPU 93 causes the gaming machine to mistakenly recognize that the regular game medium is used based on the input determination result. Detects fraudulent acts of playing games.

<Sub control circuit>
Next, the sub control circuit 101 configured by the sub control board 72 will be described with reference to FIG.
FIG. 16 is a block diagram showing a configuration example of the sub control circuit 101 of the pachi-slot 1.

The sub control circuit 101 is electrically connected to the main control circuit 91, and performs processing such as determination and execution of effect contents based on a command transmitted from the main control circuit 91. The sub control circuit 101 basically includes a sub CPU 102, a sub RAM 103, a rendering processor 104, a drawing RAM 105, and a driver 106.

The sub CPU 102 controls the output of video, sound, and light according to the control program stored in the ROM cartridge board 86 in response to the command transmitted from the main control circuit 91. The ROM cartridge board 86 basically includes a program storage area and a data storage area.

A control program executed by the sub CPU 102 is stored in the program storage area. For example, in the control program, a main board communication task for controlling communication with the main control circuit 91, and an effect registration task for extracting effect random number values and determining and registering effect contents (effect data). Is included. Further, a drawing control task for controlling the display of an image by the liquid crystal display device 11 (see FIG. 2) based on the decided effect contents, a lamp control task for controlling the output of light by a light source such as the LED 85, and the speakers 58, 64, 65L. , 65R, and the like, including a voice control task for controlling the output of sound by a speaker.

The data storage area includes a storage area for storing various data tables, a storage area for storing effect data forming each effect content, and a storage area for storing animation data related to image creation. Further, a storage area for storing sound data regarding BGM and sound effects, a storage area for storing lamp data regarding a pattern of turning on/off light, and the like are included.

The sub RAM 103 is provided with a storage area for registering the determined effect contents and effect data, and a storage area for storing various data such as an internal winning combination transmitted from the main control circuit 91.

The sub CPU 102, the rendering processor 104, the drawing RAM (including a frame buffer) 105, and the driver 106 create a video according to the animation data specified by the effect contents, and display the created video on the liquid crystal display device 11.

Further, the sub CPU 102 causes the speakers 58, 64, 65L, 65R and the like to output sounds such as BGM according to the sound data specified by the effect contents. In addition, the sub CPU 102 controls the turning on and off of the light source such as the LED 85 according to the lamp data specified by the effect contents.

<Circuit configuration of medal selector>
Next, the circuit configuration of the medal selector 201 will be described with reference to FIG.
FIG. 17 is a block diagram showing a circuit configuration example of the medal selector 201.

As shown in FIG. 17, the medal selector 201 includes a camera unit 209 and a medal solenoid 208.
Further, the medal selector 201 is connected to the main control board 71 via the door relay terminal plate 68. That is, the medal selector 201 is electrically connected to the main control circuit 91. Therefore, the main control circuit 91 can set the medal solenoid 208 of the medal selector 201 to the ON state or the OFF state.

The camera unit 209 includes a control LSI 234, a CMOS image sensor 232, and an LED 233. The control LSI 234 of the camera unit 209 is composed of an ASIC (Application Specific Integrated Circuit) and includes a CMOS image sensor 232.
And the LED 233 are electrically connected. The control LSI 234 controls the light emission of the LED 233. Further, the control LSI 234 determines whether or not the object moving on the medal rail 210 is a regular medal based on the image data output from the CMOS image sensor 232, and outputs the determination result from the output PORT assigned to the GPIO 250. When a predetermined output condition, which will be described later, is satisfied, the signal is output to the main control board 71 via the door relay terminal board 68.

The CMOS image sensor 232 includes an exposure time setting mechanism that sets the exposure time (shutter speed) in 1 to 25 steps. The exposure time is set to be extended by 7 μs for each step. In this embodiment, the initial value of the exposure time (the value when the power of the pachi-slot 1 is turned on) is set to step 10, that is, 70 μsec. Therefore, in the present embodiment, the exposure time can be set within the range of 70 μsec to a maximum of 175 μsec (exposure time corresponding to step 25).
In this embodiment, the CMOS image sensor 232 used is a CMOS image sensor having a resolution of 648×488 pixels and a frame rate of 240 fps (Frames Per Second).

The control LSI 234 is electrically connected to the notification LED 206c. The notification LED 206c is turned on and off according to an instruction from the control LSI 234.

<Circuit configuration of control LSI>
Next, the circuit configuration of the control LSI 234 will be described with reference to FIG.
FIG. 18 is a block diagram showing a circuit configuration example of the control LSI 234.

The control LSI 234 includes a host controller 241, an image recognition DSP (digital signal processor) circuit 242, an SRAM (Static Random Access Memory) 243 to which a backup power supply (not shown) is connected, a flash memory 244, and an ISP (Image Signal Processing) circuit 245. And a medal counting circuit 246. The control LSI 234 also includes a color recognition circuit 247, a fisheye correction scaler circuit 248, an image recognition accelerator circuit 249, and a GPIO (General Purpose Input/Output) 250. The devices constituting the control LSI 234 are connected to each other via a bus. In the control LSI 234 of the present embodiment, AXI (Advanced eXtensible Interface) is used as a bus protocol.
Has been adopted.

The control LSI 234 also includes an ISI (Image Sensor Interface) circuit 251. The ISI circuit 251 is electrically connected to the CMOS image sensor 232 and the ISP circuit. The ISI circuit 251 converts the image data transmitted from the CMOS image sensor 232 by the LVDS (Low voltage differential signaling) method into an RGB Bayer image and outputs it.

<ISP circuit>
When the RGB Bayer image is output from the ISI circuit 251 (the RGB Bayer image is input), the ISP circuit 245 outputs a VSYNC (Vertical Synchronization) interrupt signal to the host controller 241.
Further, the ISP circuit 245 performs an image correction process of performing a lens distortion correction process and a projective transformation (homography) process on the RGB Bayer image output from the ISI circuit 251.

The lens distortion correction process is a process for correcting the distortion caused by the characteristics of the lens in the camera unit 209 on the image data captured by the CMOS image sensor 232 in order to improve the accuracy of various determination/determination processes described later. is there.

For example, when a convex lens is used as the lens of the camera unit 209, the thickness at the end of the lens is smaller than the thickness at the center of the lens, so that distortion as shown in FIG. 19 occurs. In FIG. 19, the image pickup area A1 of the CMOS image sensor 232 and the image data G1 of the image pickup area A1 picked up by the CMOS image sensor 232 are schematically shown. The black dots in the image data G1 represent the locations corresponding to the vertices of each lattice in the imaging area A1.

As shown in FIG. 19, in the image data G1, a relatively large amount of distortion is generated at the end portion as compared with the central portion. The ISP circuit 245 processes the image data G1 (the RGB Bayer image output from the ISI circuit 251) by performing lens distortion correction processing based on various preset correction parameters. Specifically, the image data G1 is complemented so that the positions of the black dots of the image data G1 are at the same positions as the vertices of the grid of the corresponding imaging region A1. This suppresses the influence of this distortion on various determination processes described later.

It should be noted that various correction parameters are preliminarily defined in a program on the basis of prior characteristic evaluation of the lens adopted in the camera unit 209. The various correction parameters may be stored in the flash memory 244 and referred to by the ISP circuit 245 during the lens distortion correction processing.

The projective transformation process is a process of correcting the image data so that the displacement of the mounting position of the camera unit 209 does not affect the accuracy of various determination/determination processes described later.
For example, when the camera unit 209 is attached to the cancel shooter 206 at an angle that is not a suitable angle, as shown in FIG. 20A, an image area A2 necessary for various determination/determination processes described later is distorted and imaged. There are cases where In the projective transformation process, this distortion is corrected and the image data is complemented in a form suitable for various discrimination/judgment processes described later.

Specifically, in the projective transformation process, the ISP circuit 245 analyzes the RGB Bayer image after the lens distortion correction process and detects the position (coordinates: x, y) of at least four reference markers 260 in this RGB Bayer image. To do.

Next, at the position (coordinates: u, v) of the reference marker 260 in the image data suitable for improving the accuracy of various determination processes, which will be described later and which are defined in advance on the program, corresponding to the detected four reference markers. Based on the above, the conversion coefficients a, b, c, d, e, f, g, and h in the following equations 1 and 2 are calculated.
u=(x*a+y*b+c)/(x*g+y*h+1)... Formula (1)
v=(x×d+y×e+f)/(x×g+y×h+1) Equation (2)

Then, the calculated conversion coefficients a, b, c, d, e, f, g, and h and the coordinate values of each pixel in the RGB Bayer image after the lens distortion correction processing are substituted into the above equations 1 and 2. , The coordinate after conversion for each pixel is calculated, and this RGB Bayer image is processed so that each pixel is positioned at the calculated coordinate after conversion. FIG. 20B schematically shows the image area A2 shown in FIG. 20A in the RGB Bayer image after the projective transformation process.

In the present embodiment, a mode has been described in which the position (coordinates: u, v) of the reference marker 260 in the image data suitable for improving the accuracy of various determination processes is defined on the program. However, instead of this, for example, the position of the reference marker 260 may be stored in the flash memory 244 and referred to by the ISP circuit 245 during the projective conversion process.

Next, the ISP circuit 245 performs color conversion processing for converting the RGB Bayer image after lens distortion correction processing and projective conversion processing into various formats. In the color conversion processing, the ISP circuit 245 converts the RGB Bayer image into image data (YUV image data) corresponding to the YUV color space, and data relating to the luminance in this YUV image data (hereinafter, “grayscale image data”). May be called) is output to the medal count circuit 246 (output to a predetermined area of the SRAM 243 referred to by the medal count circuit 246). Further, the grayscale image data is stored in the SRAM 243. The SRAM 243 is provided with a storage area capable of storing a predetermined number of grayscale image data. When the number of gray scale image data stored in the SRAM 243 reaches the upper limit number, the stored order is overwritten from the old gray scale image data.

In the color conversion process, the ISP circuit 245 converts the RGB Bayer image into image data (HSV color space) corresponding to a color space (HSV color space) including three components (H: hue, S: saturation, V: lightness). Image data) and outputs the HSV image data to the color recognition circuit 247 (outputs to a predetermined area of the SRAM 243 referenced by the color recognition circuit 247).

Further, when the ISI circuit 251 outputs the RGB Bayer image (the RGB Bayer image is input) when the pachi-slot 1 is turned on, the ISP circuit 245 determines whether the output image includes a predetermined image. AE (Auto Exposure) determination processing for determining whether or not is performed. In the present embodiment, the predetermined image is an image of the protrusion 210a (see FIG. 8) formed on the surface of the medal rail 210. That is, in the present embodiment, the ISP circuit 245 constitutes an image determination unit that determines whether or not a predetermined image is included in the image data.

When the ISP circuit 245 can extract a linear component having a predetermined length or more from the image output from the ISI circuit 251, the ISP circuit 245 determines that the output image includes the image of the ridge portion 210a, and extracts the linear component. If not possible, it is determined that the output image does not include the image of the ridge portion 210a. Note that the extraction of the linear component having a predetermined length or more from the output image is performed, for example, by subjecting the output image to a Hough transform process, but the present invention is not limited to this, and another feature extraction method is used. Good.

When the ISP circuit 245 determines that the image output from the ISI circuit 251 includes the image of the ridge 210a, the ISP circuit 245 does not output the determination result of the AE determination process to the host controller 241, and thereafter , AE determination processing is not performed on the image output from the ISI circuit 251.

On the other hand, when the ISP circuit 245 determines that the image output from the ISI circuit 251 does not include the image of the ridge 210a, the ISP circuit 245 outputs the determination result of the AE determination process to the host controller 241. Further, the ISP circuit 245 outputs the image from the ISI circuit 251 until the exposure time of the CMOS image sensor 232 is set to the upper limit of 175 μsec (exposure time corresponding to step 25) in the present embodiment. AE determination processing is performed on the output image.

In addition, in the present embodiment, the mode in which the predetermined image is the protruding portion 210a formed on the surface of the medal rail 210 has been described. However, the present invention is not limited to this, and the predetermined image may be the reference marker 260 formed on the medal rail 210, for example. Moreover, although the aspect of determining whether or not the linear component can be extracted from the output image has been described, the present invention is not limited to this, and the determination may be performed based on the angle of view intensity of the extracted linear component.

<Color recognition circuit>
The color recognition circuit 247 performs color determination processing based on the hue and saturation in the HSV image data output from the ISP circuit 245. The color determination processing includes medal detection processing, threshold determination processing, saturation/hue multiplication processing, color template generation processing, and color template comparison processing.

(1) Medal Detection Processing In the color determination processing, the color recognition circuit 247 stores the HSV image data output from the ISP circuit 245 in the SRAM 243. The SRAM 243 is provided with a storage area capable of storing a predetermined number of HSV image data. When the number of HSV image data stored in the SRAM 243 reaches the upper limit number, the stored HSV image data is overwritten from the oldest one.

Further, the color recognition circuit 247 performs medal detection processing for determining whether or not the HSV image data output from the ISP circuit 245 includes a medal image. Specifically, this time, the difference between the HSV image data output from the ISP circuit 245 and the background HSV image data stored in the SRAM 243 is detected, and if the difference portion matches the shape of the medal, the medal shape is determined. It is determined that the image of is included. The background HSV image data is HSV image data that does not include the image of the medal, and when the medal is not moving on the medal rail 210, for example, the image captured by the CMOS image sensor 232 immediately after the power is turned on. It is obtained by converting the data into HSV image data by the ISP circuit 245. In the present embodiment, the ISP circuit 245 stores the obtained background HSV image data in the SRAM 243. Whether or not the detected difference portion matches the medal shape is determined by comparing with the HSV image data of the medal shape stored in advance in the flash memory 244.

(2) Threshold value determination processing When it is determined that the HSV image data includes a medal image, the color recognition circuit 247 performs the threshold value determination processing based on the HSV image data. In the threshold determination process, the color recognition circuit 247 determines whether a predetermined area of the medal image in the HSV image data, for example, a substantially square area including the center of the medal in the present embodiment (hereinafter, may be referred to as “medal area”). The values of saturation of all pixels are also integrated, and the values of hue are integrated. Then, the integrated value is divided by the number of pixels in the medal area to calculate the average saturation value and the average hue value, and the position on the threshold graph shown in FIG. 21 is specified based on the calculated values.

Here, the threshold graph of FIG. 21 is a graph in which the vertical axis represents the saturation value and the horizontal axis represents the hue value. In the threshold graph, the graph is divided into a permissible region and a non-permissible region based on a predetermined formula. In FIG. 21, the background of the permissible area is shown in white and the background of the non-permissible area is shown in shade.

If the position on the threshold graph based on the average saturation value and the average hue value is within the allowable region, the color determination process is continued. On the other hand, if it is within the non-permissible area, “threshold value determination not possible” is stored in the color determination storage area of the SRAM 243 as the determination result of the color determination processing, and the color determination processing ends. Note that a predetermined number of determination results can be stored in the color determination storage area of the SRAM 243, and when the stored determination results reach the upper limit number, the stored determination results are overwritten from the earlier determination result.

Instead of the above, for each pixel in the medal area, the color recognition circuit 247 specifies the position on the threshold graph shown in FIG. 21 based on the saturation value and the hue value of the pixel. Good. In this case, it is determined whether or not the number of pixels positioned in the non-allowable area exceeds a predetermined number, for example, 20% of the number of pixels in the medal area. If not, the color determination process is continued and exceeded. In this case, as the determination result of the color determination process, “threshold determination not possible” may be stored in the SRAM 243 and the color determination process may be ended.

Further, the allowable area and the non-allowable area in the threshold graph can be set appropriately. For example, in addition to the non-permissible region in FIG. 21, when the saturation value is equal to or more than a predetermined value, for example, 90 or more, the non-permissible region may be provided so as to be located in the non-permissible region.

(3) Saturation/Hue Multiplication Processing After the threshold determination processing, the color recognition circuit 247 performs saturation/hue multiplication processing in the threshold determination processing. In the saturation/hue multiplication processing, the saturation value and the hue value of each pixel in the medal area are multiplied, and the value calculated by the multiplication is stored in the SRAM 243 in association with the position of the pixel. In the following description, a group of data stored by associating the multiplication value of the saturation value and the hue value of each pixel in the medal area with the position of the pixel is referred to as “color determination data”. There is.

(4) Color Template Generation Process The color template generation process is a process of generating a color template used in the color template comparison process described later. In the color template generation process, the color recognition circuit 247 mutually compares the color determination data for each medal until the number of medals thrown after the power is turned on reaches the prescribed initial number of medals, which is 50 in the present embodiment, and matches. Yes, or color determination data that is similar to a predetermined degree is grouped.

For example, the color recognition circuit 247 compares, with respect to the color determination data relating to the 50 medals, the multiplication value of the saturation value and the hue value for each corresponding pixel position. Then, when the number of multiplication values that match or are within a predetermined error range (for example, ±5) is a predetermined number or more (for example, 80% or more of all multiplication values), these color determination data are grouped. ..

Next, the color recognition circuit 247 selects the upper four groups in descending order of the number of pieces of color determination data to which they belong. Then, one arbitrary color determination data is selected for each of the selected upper four groups, and the four color determination data are stored as a color template in the storage area of the SRAM 243 storing the color template. It should be noted that instead of selecting one arbitrary color determination data for each of the selected upper four groups, the average value of the color determination data belonging to the same group (the average value of the multiplication values for each pixel) is selected. ) May be calculated to generate the color template. Further, the color template stored in the SRAM 243 may be erased by initialization processing (not shown) of the host controller 241 when the power of the game machine is turned on.

By generating the color template as described above, for example, when two types of medals having different markings (patterns) and colors on the front and back sides are used as regular medals, and the color template is stored in the storage area of the SRAM 243. If not stored, by inserting 50 regular medals after the power is turned on, it is possible to generate four types of color templates for the front and back of these two types of medals. If the color template is not stored in the storage area of the SRAM 243 and only one type of 50 regular medals has been thrown in after the power is turned on, two types of colors for the front and back of this regular medal are provided. A template is generated, and two types of generated color templates are used in the color template comparison process described below.

When the color template is not stored in the storage area of the SRAM 243, the color determination data for each medal until the number of medals thrown after the power is turned on reaches the specified initial number of medals, which is 50 in this embodiment, is It is generated according to an instruction from the host controller 241. When the medal counting circuit 246, which will be described later, determines that “a medal has passed” on the medal rail 210, the host controller 241 triggers the HSV image data a predetermined time before (that is, a predetermined frame before) the judgment. Is used to instruct the color recognition circuit 247 to generate the color determination data. The predetermined time is set in advance based on experiments and simulations so that the HSV image data before the predetermined time always contains the image of the medal.

The color determination data is generated through the medal detection process, the threshold determination process, and the saturation/hue multiplication process described above, and is stored in the color determination data storage area of the SRAM 243. The color recognition circuit 247 executes the color template generation process when the number of color determination data stored in the color determination data storage area reaches 50, that is, when the color determination data for 50 medals is created. To do.

(5) Color Template Comparison Processing When it is determined that the medal image is included in the medal detection processing after the color template generation processing, the color recognition circuit 247 performs the color template comparison processing.

In the color template comparison processing, the HSV image data determined to include the image of the medal is compared with the color determination data created through the threshold determination processing and the saturation/hue multiplication processing and the color template. Whether or not they match or similar to each other is determined, and “OK” or “NO” is stored in the color determination storage area of the SRAM 243 as a determination result. In this embodiment, since a maximum of four color templates are used, the determination results for the maximum of four templates are stored in the SRAM 243. In the color template comparison process, the color determination result is stored in the color determination storage area of the SRAM 243. Here, as the color determination result, “Yes” is stored when at least one “Yes” is stored as the determination result for up to four templates, and when all “No” is stored. “No” is stored. Therefore, in one color template comparison process, a maximum of four determination results for a maximum of four color templates and one color determination result based on these determination results are stored. Note that a predetermined number of determination results can be stored in the color determination storage area of the SRAM 243, and when the stored determination results reach the upper limit number, the stored determination results are overwritten from the earlier determination result.

For example, the color recognition circuit 247 compares the product of the color determination data, the saturation value in the color template, and the hue value for each associated pixel position. Then, when the number of multiplication values that match or are within a predetermined error range (for example, ±5) is a predetermined number or more (for example, 80% or more of all multiplication values), it is determined that they match or are similar to a predetermined degree. It should be noted that, in this processing, the criterion for determining whether they match or are similar to a predetermined degree can be set as appropriate.

As described above, in the color determination process, the threshold determination process is performed, the color template comparison process is performed, the color determination data and the color template are compared, and it is determined whether they match or are similar to each other to a predetermined degree. The color recognition circuit 247 constitutes a game medium determination means for determining whether or not the object passing on the medal rail 210 is a regular medal.

<Medal counting circuit>
The medal counting circuit 246 performs counting processing based on the grayscale image data output from the ISP circuit 245. The counting process includes a medal image determination process, a medal position detection process, and an order determination process.

(1) Medal Image Discrimination Processing In the count processing, the medal count circuit 246 first performs medal image discrimination processing. In the medal image discrimination processing, the medal count circuit 246 discriminates whether or not the image of the medal is included in the grayscale image data output from the ISP circuit 245. Specifically, this time, the difference between the grayscale image data output from the ISP circuit 245 and each pixel of the background grayscale image data stored in the SRAM 243 is detected, and the difference is detected. When the formed shape matches the template data of the medal shape stored in the flash memory 244, it is determined that the image of the medal is included. The background grayscale image data is grayscale image data that does not include a medal image, and when the medal is not moving on the medal rail 210, for example, immediately after the power is turned on, the CMOS image sensor 232 takes an image. The obtained image data is obtained by the ISP circuit 245 converting it into grayscale image data. In the present embodiment, the ISP circuit 245 stores the obtained background grayscale image data in the SRAM 243. In the present embodiment, the medal count circuit 246 detects the difference between the background grayscale image data and the grayscale image data output from the ISP circuit 245, and determines whether the detected difference matches the medal shape. It was determined whether the image was included. However, the present invention is not limited to this, and it may be determined that the image of the medal is included when the number of pixels of the detected difference is a certain number or more.

(2) Medal Position Detection Processing Next, the medal count circuit 246 performs medal position detection processing on the grayscale image data output from the ISP circuit 245. In the medal position detection process, the medal counting circuit 246 determines whether or not a medal image is present in a predetermined determination area in the output grayscale image data, and stores the determination result in the SRAM 243.

The predetermined determination area is a plurality of rectangular areas in the grayscale image data G2, and in this embodiment, as shown in FIGS. 22 to 24, the determination areas A1 to A4, B1 to B4, C1 and C2. , D1 to D4, E and F, a total of 16 determination areas are set. 22A to 22C, 23D to F, and 24G are diagrams for explaining the relationship between the medal M passing through the medal rail 210 and ejected from the medal exit portion 204c and the determination area. Further, FIG. 24H is a diagram for explaining the relationship between the medal guided by the medal shoot 202 and the determination area.

Each determination area is defined in advance by a program by defining the coordinate values (X, Y) of the corners of each determination area in the grayscale image data G2 so that a plurality of pixels are included in the determination area. ing. For example, as shown in FIG. 25, the determination area of C1 includes eight pixels in the area, and the coordinate values of four corners (450,95), (454,95), (450,96), (450 454, 96), the position is defined. In addition, in FIG. 25, one grid represents one pixel.

As shown in FIGS. 22A to 22C, 23D to F, and 24G, the determination areas A1 to A4 and B1 to B4 pass through the medal rail 210 and are the lower portion of the image of the medal M discharged from the medal exit portion 204c. Are placed so that they overlap. The determination areas C1 and C2 are arranged so as to overlap with the upper portion of the image of the medal M that passes through the medal rail 210 and is ejected from the medal exit portion 204c. Further, the determination areas E and F are arranged so as not to overlap the image of the medal M that passes through the medal rail 210 and is ejected from the medal exit portion 204c.

Further, as shown in FIG. 24H, the determination area F is arranged below the grayscale image data G2 so as to overlap the image of the medal M when the medal is guided by the medal shoot 202. The determination area E is located above the path of the medal M, and is arranged above the grayscale image data G2 so as to overlap the images of various instruments used for cheating.

The medal count circuit 246 calculates the difference value of the brightness of each pixel in each determination region of the grayscale image data to be processed and the background grayscale image data, and the calculated difference value is the number of pixels having a threshold value or more, Count for each judgment area. Then, the medal counting circuit 246 determines, for each determination area, whether or not the number of counted pixels is equal to or more than a predetermined number. If it is determined that the number of pixels is equal to or more than the predetermined number, the medal image is displayed in the determination area. Is present (there is a medal). On the other hand, when it is determined that the number of counted pixels is less than the predetermined number, it is determined that the image of the medal does not exist in the determination area (there is no medal). In the present embodiment, the mode in which the grayscale image data is used in the present process has been described, but the present invention is not limited to this. For example, for the color determination generated by multiplying the saturation and the hue used in the color determination process described above. Data may be used.

Further, the medal count circuit 246 performs the medal edge detection process on the determination area determined to have the image of the medal (there is the medal) in the medal position detection process.

The medal edge detection process is a process of detecting the outer edge of the medal based on the arrangement of pixels whose luminance difference value does not reach the threshold value in the determination area in which it is determined that a medal image is present. In the present embodiment, the moving direction of the medal is from left to right in FIGS. Therefore, if there is even one pixel on the right side of which the brightness difference value does not reach the threshold value in the determination area in which the medal image is present, the medal counting circuit 246 causes the medal counting circuit 246 to determine the outer edge of the front side in the moving direction of the medal (moving direction It is determined that there is a medal edge).

On the other hand, in the determination area in which the medal image is present, if there is even one pixel on the left side whose brightness difference value does not reach the threshold value, the medal counting circuit 246 causes the outer edge of the rear side in the moving direction of the medal (after movement). Direction medal edge) is present. If there is no pixel whose brightness difference value does not reach the threshold value, the medal counting circuit 246 determines that there is no outer edge of the medal in the determination area.

For example, in the determination area C1 shown in FIG. 25, if any one of the pixels 5C to 8C located on the right side has a brightness difference value less than the threshold value, the moving direction token Judge that there is an edge. On the other hand, if any one of the pixels 1C to 4C located on the left side has a brightness difference value less than the threshold, it is determined that there is a post-movement direction medal edge.

In addition, regarding the determination areas E and F, since the moving direction of the medal or the various appliances is considered to be from the top to the bottom in FIGS. 22 to 24, the luminance is lower than the pixels whose luminance difference value is the threshold value or more. When there is at least one pixel whose difference value is less than the threshold value, the medal counting circuit 246 determines that there is a lower outer edge (movement destination direction medal edge) in the moving direction of the medal. On the other hand, when there is at least one pixel whose luminance difference value is less than the threshold value above the pixel whose luminance difference value is greater than or equal to the threshold value, the medal counting circuit 246 causes the medal count circuit 246 to determine the upper outer edge (after movement) Direction medal edge) is present. In addition, when there is no pixel whose luminance difference value is lower than or equal to the threshold value with respect to the pixels whose luminance difference value is equal to or higher than the threshold value, the medal counting circuit 246 causes the medal count circuit 246 to determine whether the medal count circuit 246 is in the determination area. It is determined that there is an image, but there is no outer edge of the medal.

Then, the medal counting circuit 246, for each judgment area of the grayscale image data output from the ISP circuit 245, the above judgment result, that is, the judgment result of whether or not a medal image exists in the judgment area, and the movement. The determination result as to whether or not there is a forward medal edge or a post-movement medal edge is stored in the SRAM 243 in the order of input. For example, the medal counting circuit 246 stores the data “OFF” in the determination area in which it is determined that the image of the medal does not exist. Further, the data “IN” is set for the determination area determined to include the destination direction medal edge, the data “OUT” is set for the determination area determined to be the post-movement direction medal edge, and the medal image. However, the data “ON” is stored in the determination area determined to have no outer edge of the medal. If it is determined in the medal image discrimination process that the image of the medal is not included, the medal count circuit 246 omits the medal position detection process and stores the data “OFF” in all the discrimination regions. May be.

Further, the medal counting circuit 246 omits the judgment of the judgment areas A1 to A4, B1 to B4, C1, C2, D1 to D4 when the medal cannot be inserted, for example, when the credit counter has the maximum value as described later. To do. Further, in this case, the medal counting circuit 246 indicates in the SRAM that the above determination is omitted for the determination areas A1 to A4, B1 to B4, C1, C2, and D1 to D4, that is, it is undetermined. *" data (specifically, hexadecimal number "FF") is stored.

Therefore, the determination area determination result data as shown in FIG. 26 is stored in the SRAM 243 for the eight grayscale image data G2 shown in FIGS. 22A to 22C, 23D to F, 24G, and H. For example, with respect to the grayscale image data G2 of FIG. 22A, since it is determined that the destination direction medal edge exists in the determination areas A1 and A2, the data “IN” (specifically, a hexadecimal number) "01") is stored, and it is determined that no medal image exists in the other determination areas. Therefore, the data "OFF" (specifically, "00" in hexadecimal) is stored. Remembered.

In the grayscale image data of FIG. 23E, since it is determined that the medal image does not exist in the determination areas A1 to A4, E and F, the data “OFF” is stored. Further, for the determination areas B1, B2, C1 and C2, since it is determined that the post-movement direction medal edge exists, the data “OUT” (specifically, the hexadecimal number “02”) is stored. To be done. Further, the determination areas B3, B4, D1 to D4 have a medal image, but since it is determined that there is no outer edge of the medal, the data "ON" (specifically, a hexadecimal number " 03”) is stored.

Further, regarding the grayscale image data G2 shown in FIG. 24H, it is determined that the medal image exists in the determination area F, but the outer edge of the medal does not exist, so the data “ON” is stored. In addition, for the determination areas A1 to A4, B1 to B4, C1, C2, and D1 to D4, data “*” indicating that the determination has not been made is stored.

22A to C, 23D to F, and 24G, the grayscale image data G2 is output from the ISP circuit 245 when the medal passes through the medal rail 210 and is ejected from the medal exit portion 204c. For the convenience of description, seven gray scale image data G2 are extracted from the gray scale image data G2. That is, in the same case, the grayscale image data output from the ISP circuit 245 exists in addition to the grayscale image data G2 shown in FIGS. 22A to 22C, 23D to F, and 24G.

Further, the SRAM 243 is provided with a storage area for storing the above-described determination result for a predetermined number of grayscale image data as the determination area determination result data. When the judgment result stored in the SRAM 243 reaches the upper limit number, the stored order is overwritten with the judgment result relating to the old grayscale image data.

(3) Order determination processing After the medal image detection processing and the medal position detection processing, the medal count circuit 246 performs order determination processing. In the order determination process, in a predetermined number of grayscale image data arranged in time series, the transition mode of the data of “IN”, “OUT”, “ON”, “OFF” for each determination region is a predetermined transition. It is determined whether the medals have passed through the medal rail 210 or not.

Here, as a mode of the predetermined transition, in the present embodiment, the medal count determination table shown in FIG. 27 is converted into a numerical value and stored in the flash memory 244. In the medal count determination table, “IN”, “in” in each determination region on the 14 grayscale image data arranged in time series when the medals pass on the medal rail 210 and are ejected from the medal exit section 204c. The mode of transition of data of “OUT”, “ON”, and “OFF” is defined. The mode of transition of these data is specified in advance by simulation or experiment.

In the order determination process, the medal count circuit 246 determines the transition state of data in each determination region of the latest 14 grayscale image data stored in the SRAM 243 and the time series 1 defined in the medal count determination table. The transition states of the data corresponding to #14 to #14 are compared, and if they completely match, it is determined that “the medal has passed”. If they do not match, it is determined that “an abnormality has occurred”. When they do not match, for example, the first half of the data transition mode in each determination region of the latest 14 grayscale image data (hereinafter, may be referred to as “comparison target data transition mode”) Corresponds to the transition mode of the data corresponding to the time series 1 to 8 defined in the medal count determination table, but the following part is the data corresponding to the time series 8 to 4 defined in the medal count determination table. There is a case where it matches the transition mode (hereinafter, this case may be referred to as “time-series backward movement”). If they do not match, for example, the first half of the transition mode of the comparison target data matches the transition mode of the data corresponding to the time series 1 to 7 defined in the medal count determination table, When the following part matches the transition mode of the data corresponding to the time series 10 to 14 specified in the medal count judgment table, that is, the data corresponding to the time series 8 and 9 specified in the medal count judgment table May be missing. If they do not match, for example, the first half of the transition mode of the comparison target data matches the transition mode of the data corresponding to the time series 1 to 8 defined in the medal count determination table, There is a case where the following portions all match the transition mode of the data corresponding to the time series 9 defined in the medal count determination table, that is, the same transition mode overlaps. The above-described time-series backward movement corresponds to an existing medal backward error, and when the same transition mode is duplicated, corresponds to an existing medal jamming error. Further, if the above data is missing, it is an error that cannot be detected by the existing medal selector, and the medal selector 201 that can detect the error is superior in error detection performance to the existing medal selector. Can be said.

In the order determination process, the mode of data transition in each determination area of the latest 14 grayscale image data and the mode of data transition corresponding to the time series 1 to 14 defined in the medal count determination table. , And when they do not match, instead of determining that “an abnormality has occurred”, based on the most recent 14 pieces of grayscale image data, the above-described time series backward movement and the same transition mode May be determined to have occurred, and if it is determined that there has occurred, “abnormality has occurred” may be determined. For example, in the medal count circuit 246, there is a change in continuous grayscale image data, and the mode of the change is reversed in time series as compared with the mode of data transition defined in the medal count determination table. In this case, it is determined that time-series retrogression has occurred. In addition, as described above, the first half of the transition mode of the data to be compared matches the transition mode of the data corresponding to the time series 1 to 7 defined in the medal count determination table, but the following portion is When the data transition mode corresponding to the time series 10 to 14 specified in the medal count determination table matches the data transition mode, it is determined that the data omission has occurred. In addition, the first half of the transition mode of the data to be compared matches the transition mode of the data corresponding to the time series 1 to 8 defined in the medal count determination table, but all the following portions are medal count determinations. When the transition mode of the data corresponding to the time series 9 specified in the table matches, it is determined that duplication of the same transition mode has occurred.

Also, the medal count circuit 246 defines the mode of data transition in each judgment area of the latest four grayscale image data stored in the SRAM 243 and the medal count judgment table when medals cannot be inserted. The transition states of the data corresponding to the time series E1 to E4 that are present are compared, and if they completely match, it is determined that “the medal was guided by the medal shoot 202”.

Note that if the number of grayscale image data stored in the SRAM 243 is less than a predetermined number, for example, less than 4 or 14, the transition mode does not match due to the insufficient number of data. In the comparison process, it is not determined that the medal has passed or that the medal has been guided by the medal shoot 202. In this case, the comparison process may be omitted.

Further, the medal counting circuit 246 determines whether any one of “IN”, “OUT”, and “ON” data is stored in the determination area E of the most recent grayscale image data stored in the SRAM 243. , It is determined that an abnormality has occurred.

Further, in the order determination process, the medal counting circuit 246 stores the above determination result in the order determination process in the SRAM 243 as the determination result of the counting process. That is, in the SRAM 243, as the determination result of the counting process, “a medal has passed” (a hexadecimal number is “01” as a concrete numerical value) and “a medal has been guided to the medal shoot 202” (a concrete numerical value). Is stored as a hexadecimal number "02") and "abnormality has occurred" (specifically, a hexadecimal number "10") is stored. Note that, here, the case where it is determined that the medal has passed is, for example, the case where the main control circuit 91 inserts a medal while the medal can be inserted. Further, when it is determined that the medal has been guided to the medal shoot 202, the main control circuit 91 is in a state where the medal can be inserted and an illegal medal having an outer diameter smaller than that of the prescribed medal is inserted, or This is a case where a medal is inserted while the control circuit 91 cannot insert the medal. In addition, when it is determined that “an abnormality has occurred”, it is compared with the case where some foreign matter is detected outside the range where the medal passes, and the mode of data transition defined in the above medal counter determination table. This is a case where the transition mode of the target data does not match.

As a result of the comparison, instead of determining that the medal has passed or the medal has been guided by the medal shoot 202 in the case of a complete match, a predetermined degree, for example, a degree of match of 80% or more. In this case, it may be determined in consideration of a predetermined determination margin that “the medal has passed” or “the medal shot 202 has been guided”.

Further, in the medal position detection process, the medal edge detection process may be omitted. In this case, the medal count circuit 246 causes the SRAM 243 to store the data “OFF” for the determination area determined to have no medal image and the “ON” for the determination area determined to have the medal image. Data is stored. Then, the medal count determination table shown in FIG. 27 defines the manner of transition of the “ON” and “OFF” data in each determination region.

Further, in the order determination processing, instead of the comparison using the medal count determination table shown in FIG. 27, the order of the determination areas in which the data of “ON” is stored is defined in advance, and the predetermined order and the actual The passage of the medal may be determined by comparing with the order of the determination areas in which the data of “ON” is stored. In this case, the order defined in advance is grouped into the determination areas A1 to A4 as the A area, the determination areas B1 to B4 as the B area, the determination areas C1 and C2 as the C area, and the determination areas D1 to D4 as the D area. May be specified in. For example, in the order defined in advance, all of the areas A to D are “OFF”, then only the area A is “ON”, then the areas A, B and C are “ON”, then the areas B, C and D. May be “ON”, only the D area may be “ON”, and finally all of the A to D areas may be “OFF”. In this case, the area A being “ON” means that “ON” data is stored in any of the determination areas A1 to A4.

Further, the number, shape, and arrangement location of the determination areas set on the grayscale image data can be appropriately set according to the allowable required determination time and the required accuracy of the determination. For example, in FIGS. 22A to C, FIGS. 23D to F, and FIGS. 24G and 24H, the determination region may be set to extend in the vertical direction from the upper end to the lower end of the grayscale image data G2.

<Fish-eye correction scaler circuit>
The fisheye correction scaler circuit 248 acquires grayscale image data from the SRAM 243 and performs fisheye correction processing for correcting the acquired grayscale image data.

Further, the fisheye correction scaler circuit 248 performs equalization processing on the grayscale image data subjected to the fisheye correction processing. In the equalizing process, the fish-eye correction scaler circuit 248 creates reduced image data reduced to 1/2, 1/4, and 1/8.

Further, the fisheye correction scaler circuit 248 performs a bilateral conversion process on each of the reduced image data created in the equalization process. In the present embodiment, a Gaussian filter of a 3×3 kernel (a kernel in image processing, not a kernel indicating an OS function) shown in FIG. 28 is used to remove noise from reduced image data. However, the Gaussian filter has a drawback that edges in the image data are inconspicuous (blurred). Therefore, in order to eliminate this drawback, the bilateral filter shown in the following Expression 3 is adopted as the processing algorithm of the bilateral conversion processing. That is, the bilateral filter is a filter that removes noise in image data by using a kernel of a Gaussian filter and performs edge correction and enhancement.

In Equation 1, the array of image data before the bilateral conversion process is f(i, j), and the array of the image data after the process is g(i, j). Further, w represents the kernel size, σ represents the standard deviation, and d represents the difference in brightness value.

Then, the fisheye correction scaler circuit 248 causes the SRAM 243 to store the reduced image data that has been subjected to the equalization processing. Note that the SRAM 243 is provided with a storage area capable of storing a predetermined number of reduced image data. When the number of reduced image data stored in the SRAM 243 reaches the upper limit number, the stored order is overwritten from the oldest reduced image data.

<Image recognition DSP circuit>
When the medal counting circuit 246 determines that the medal has passed on the medal rail 210, the host controller 241 uses the reduced image data for a predetermined time period (that is, before a predetermined frame) from the time of the determination. Then, the image recognition DSP circuit is instructed to perform preprocessing. The predetermined time is set in advance based on experiments and simulations so that the reduced image before the predetermined time always includes the image of the medal.

The image recognition DSP circuit 242 acquires reduced image data (reduced image data reduced to 1/4 in this embodiment) from the SRAM 243 in the preprocessing, and detects a circular region from the acquired reduced image data. Filtering processing is performed and nonlinear diffusion filter processing is performed to create an edge image and the edge image is stored in the SRAM 243. Further, the image recognition DSP circuit 242 performs various determination processes described later. In the present embodiment, the image data reduced to 1/4 is used, but the present invention is not limited to this, and the flash memory 244 stores the setting for selecting the reduced image data to be used and stores the setting according to the setting. The image data reduced to ½ or the image data reduced to ⅛ may be selected.

(1) Circle Area Detection Processing In the circle area detection processing, the image recognition DSP circuit 242 generates a background difference image indicating a difference between the acquired reduced image data and the reduced background grayscale image data corresponding to the reduced image data. To do. Here, the reduced background grayscale image data is image data obtained by subjecting the background grayscale image data stored in the SRAM 243 to fisheye correction processing and equalization processing by the fisheye correction scaler circuit 248, which is used for the circular area detection processing. Previously stored in SRAM 243.

Next, the image recognition DSP circuit 242 binarizes the generated background difference image. Then, as shown in FIG. 29, template matching is performed on the binary background difference image G3 using the binary outline template T1 indicating the outline of the medal. That is, the image recognition DSP circuit 242 specifies where in the background difference image G3, a region similar to the outer shape template T1 exists. In other words, the image recognition DSP circuit 242 specifies where, in the background difference image G3, an area that matches the outer shape of the medal indicated by the outer shape template T1 exists. The outline template T1 is stored in the flash memory 244 in advance.

In template matching, the outline template T1 is gradually moved (for example, one pixel (pixel) at a time) in the raster scan direction on the background difference image G3. In other words, the image recognition DSP circuit 242 raster-scans the outer shape template T1 on the background difference image G3. At this time, the image recognition DSP circuit 242 generates an AND image of the outline template T1 and the partial region of the background difference image G3 that overlaps with the outline template T1 at each position of the outline template T1. As a result, a plurality of binary AND images are generated. Then, the image recognition DSP circuit 242, among the generated AND images, the background difference of the outer shape template T1 used in the generation of the AND image having the largest number of pixels (high-luminance pixels) having the pixel value of “1”. The position on the image G3 is specified. This position is a position where a region similar to the outer shape template T1 exists in the background difference image G3.

Then, the image recognition DSP circuit 242 detects a partial area in the acquired reduced image data existing at the same position as the specified position as a circular area. In other words, the image recognition DSP circuit 242 detects, as a circular area, a partial area in the reduced image data that overlaps the outer shape template T1 when the outer shape template T1 is arranged in the reduced image data at the same position as the specified position. .. At this time, in the partial region, a region in which the pixel value of each pixel outside the circle indicated by the outer shape template T1 on the partial region is zero may be set as the circular region. The circular area extracted by the image recognition DSP circuit 242 is a grayscale image. In the present embodiment, the outer shape of the circular area is a quadrangle, but it may be another shape such as a circle.

It should be noted that another method may be adopted as a method for extracting the circular region from the acquired reduced image data. For example, an extraction method that utilizes the outer shape of a medal may be adopted. In this extraction method, first, edge detection is performed on the acquired reduced image data to generate an edge image. As a method of generating an edge image, for example, the Sobel method, Laplacian method, Canny method or the like is used. Next, a circular area is extracted from the generated edge image. As a method for extracting the circular area, for example, Hough transform is used. Then, the circular area in the acquired reduced image data that exists at the same position as the position of the circular area in the edge image is set as the circular area.

Further, an extraction method of extracting a circular area from the reduced image data acquired by using the background subtraction method and labeling may be adopted. In this extraction method, first, a background difference image indicating the difference between the acquired reduced image data and the reduced background grayscale image data is generated, and the generated background difference image is binarized. Then, labeling such as 4-connection is performed on the binary background difference image. Then, the partial area of the acquired reduced image data existing in the same position as the position of the connected area (independent area) obtained as a result of labeling in the binary background difference image is set as the circular area.

(2) Filter processing The image recognition DSP circuit 242 performs filter processing after the circular area detection processing. The filter process includes a 3σ correction process and a non-linear diffusion filter process.
First, in the 3[sigma] correction process, the image recognition DSP circuit 242 cuts out the image data of the circular region in the acquired reduced image data based on the circular region detected by the circular region detection process. Hereinafter, the cut-out image data may be referred to as circular area image data.

Next, the image recognition DSP circuit 242 creates a normal distribution (see FIG. 30) with respect to the luminance value in the cut out circular area image data, centered on the average value of the data in a certain range. Here, 3σ is three times the standard deviation, and almost all the data belong to the range of the average value ±3σ (when the variation is a normal distribution, 99.7% of the data are within this range). Belong to).
Then, the brightness of a pixel whose brightness value is smaller than −3σ, for example, the brightness of a pixel of −4σ is replaced with the brightness value of −3σ. Further, the brightness of a pixel whose brightness value is larger than 3σ, for example, the brightness of a pixel of 4σ is replaced with the brightness value of 3σ. By doing this, it is possible that pixels with extremely large brightness values (pixels that are too bright) and pixels with extremely small brightness values (pixels that are too dark), which are irregular data, affect subsequent processing. Can be suppressed.

Next, the image recognition DSP circuit 242 performs non-linear diffusion filter processing on the circular region image data after the 3σ correction processing to create an edge image X in the X (vertical) direction and an edge image Y in the Y (horizontal) direction. To do.

FIG. 31A schematically shows the circular area image data after the 3σ correction processing. In FIG. 31A, each square in the grid represents a pixel. Further, FIG. 31B shows the coefficients for the edge image X. Here, assuming that the brightness values of the pixels A1 to A8 and P in FIG. 31A are a1 to a8 and p, respectively, the brightness value of the target pixel P in the edge image X is calculated by using the coefficient for the edge image X as follows. It is calculated by the equation 4 below.
P luminance (PX)=a1*(-3)+a2*0+a3*3+a4*(-10)+p*0+a5*10+a6*(-3)+a7*0+a8*3...Equation (4)

The image recognition DSP circuit 242 creates the edge image X by calculating the brightness using Expression 4 for all the pixels of the circular area image data after the 3σ correction processing.

FIG. 31C shows the coefficients for the edge image Y. Here, assuming that the brightness values of the pixels A1 to A8 and P in FIG. 31A are a1 to a8 and p, respectively, the brightness value of the pixel of interest P in the edge image Y is calculated by using the coefficient for the edge image Y as follows. It is calculated by the following equation 5.
P luminance (PY)=a1*(-3)+a2*(-10)+a3*(-3)+a4*0+P*0+a5*0+a6*3+a7*10+a8*3...Equation (5)

The image recognition DSP circuit 242 creates the edge image Y by calculating the brightness using Expression 5 for all the pixels of the circular area image data after the 3σ correction processing.

After creating the edge image X and the edge image Y, the image recognition DSP circuit 242 creates the edge image XY from both images. The brightness PXY of each pixel in the edge image XY is calculated by the following equation 6 when the brightness value of the pixel in the edge image X is PX and the brightness value of the pixel in the edge image Y at the same position is PY. be able to.

The image recognition DSP circuit 242 creates the edge image XY by calculating the brightness PXY using the above equation 6 for all the pixels of the edge image X and the edge image Y, and stores the created edge image XY in the SRAM 243. Let
The various determination processes performed by the image recognition DSP circuit 242 will be described later.

<Image recognition accelerator circuit>
The image recognition accelerator circuit 249 performs processing related to the gradient average image data and processing related to the edge gradient image.

[Processing relating to gradient average image data]
The processing related to the gradient average image data includes a rotation image generation processing, a gradient average image data generation processing, and a gradient average image template generation processing.

(1) Rotated Image Generation Process In the rotated image generation process, the image recognition accelerator circuit 249 acquires the edge image XY from the SRAM 243, rotates the acquired edge image XY in 1 degree units, and outputs a 360 degree rotated image. To generate.

(2) Gradient Average Image Data Generation Process In the gradient average image data generation process, the image recognition accelerator circuit 249 cumulatively adds (overlaps) the rotated images for 360 degrees generated in the rotated image generation process to obtain the gradient average. Generate image data. As an example of the gradient average image data, FIG. 32B shows the gradient average image data of the regular medal shown in FIG. 32A. Then, the image recognition accelerator circuit 249 causes the SRAM 243 to store the generated gradient average image data.

(3) Gradient Average Image Template Generation Process The gradient average image template generation process is a process of generating a gradient average image template which is image data used in the determination process of the image recognition DSP circuit 242 described later.

In the gradient average image template generation process, the image recognition accelerator circuit 249 compares 50 pieces of gradient average image data stored in the SRAM 243 (that is, relating to 50 medals) with each other, and agrees or is similar to a predetermined degree. The gradient average image data to be grouped. Next, the image recognition accelerator circuit 249 selects the upper four groups in descending order of the number of gradient average image data to which they belong. Then, arbitrary one gradient average image data is selected for each of the selected upper four groups, and the four gradient average image data are used as the gradient average image template in the storage area of the SRAM 243 that stores the gradient average image template. Remember. It should be noted that instead of selecting any one gradient average image template for each of the selected upper four groups, the average value of the gradient average image data belonging to the same group (the average value of the brightness of each pixel) The gradient average image template may be generated by calculating Further, the gradient average image template stored in the SRAM 243 may be erased by initialization processing (not shown) of the host controller 241 when the power of the gaming machine is turned on.

As described above, by generating the gradient average image template, for example, when two types of medals having different markings (patterns) on the front and back are used as regular medals, 50 regular medals are input after the power is turned on. By doing so, a maximum of four types of gradient average image templates for the front and back of these two types of medals can be generated. If 50 regular medals are input after the power is turned on, two types of gradient average image templates for the front and back of the regular medals are generated, and the gradient average image template comparison process described below is performed. Then, two types of generated gradient average image templates are used.

Here, when the gradient average image template is not stored in the storage area of the SRAM 243, the gradient average image template generation processing is performed until the number of medals thrown after the power is turned on reaches a prescribed initial number, 50 in this embodiment. Of the gradient average image data. The image recognition accelerator circuit 249 stores the generated gradient average image data in the gradient average image template generation data storage area of the SRAM 243 until the number of the gradient average image data generated in the gradient average image data generation process reaches 50 pieces. Further, the image recognition accelerator circuit 249 performs the gradient average image template generation processing when 50 pieces of the gradient average image data are stored in the gradient average image template generation data storage area of the SRAM 243. The image recognition accelerator circuit 249 stores the gradient average image data generated by the gradient average image data generation processing in the determination target gradient average image data storage area of the SRAM 243 after executing the gradient average image template generation processing. It should be noted that the present embodiment has described the mode in which, when 50 pieces of gradient average image data are stored in the SRAM 243, the gradient average image data that match or are similar to a predetermined degree are grouped to generate a gradient average image template. However, not limited to this, each time the gradient average image data is generated, it is compared with the previously stored gradient average image data, and the gradient average image data that match or are similar to each other by a certain degree are grouped to obtain the gradient average image data. Image templates may be generated.

[Processing related to edge gradient image]
The processing related to the edge gradient image includes polar coordinate conversion processing, Scharr conversion processing, HOG conversion processing, and HOG template generation processing.

(1) Polar Coordinate Conversion Processing In the polar coordinate conversion processing, the image recognition accelerator circuit 249 acquires the edge image XY from the SRAM 243, converts the acquired edge image XY from orthogonal coordinates to polar coordinates, and creates polar coordinate image data. Specifically, the image recognition accelerator circuit 249 polar coordinates (r, φ) that represents the orthogonal coordinates (x, y) of each pixel of the edge image XY by the length r of the radius vector and the angle φ from the reference position. ). The relationship between polar coordinates (r, φ) and Cartesian coordinates (x, y) is expressed by the following equations 7 and 8.
x＝r cos(φ)・・・Equation (7)
y＝r sin(φ)・・・Equation (8)

Then, the image recognition accelerator circuit 249 stores the created polar coordinate image data in the SRAM 243.

(2) Scharr conversion processing In the Scarr conversion processing, the image recognition accelerator circuit 249 acquires polar coordinate image data from the SRAM 243 and creates an edge polar coordinate image X in the X (vertical) direction and an edge polar coordinate image Y in the Y (horizontal) direction. To do. Therefore, the image recognition accelerator circuit 249 that performs the Scharr conversion process constitutes a directional image separation unit that separates the polar coordinate image into a vertical image and a horizontal image.
The aspect of creating the edge polar coordinate image X and the edge polar coordinate image Y in the Scharr conversion process is the same as the aspect of creating the edge image X and the edge image Y in the above-described nonlinear diffusion filter process, including the coefficient used. The description is omitted here.

(3) HOG conversion process In the HOG conversion process, the image recognition accelerator circuit 249 creates an edge gradient image, and performs HOG conversion on the created edge gradient image. Here, the HOG (Histograms of Oriented Gradients) conversion is to histogram the direction of the gradient of the brightness of the local area (cell) in the image data, and for image matching involving HOG conversion, a local shape change ( It has the characteristics that it is strong against geometrical transformations and is not easily affected by fluctuations in lighting.

Specifically, an edge gradient image is created from the edge polar coordinate image X and the edge polar coordinate image Y created by the Scharr conversion process. The brightness of each pixel in the edge gradient image, that is, the gradient strength, is expressed by the following equation 9 when the brightness value of the pixel in the edge polar coordinate image X is QX and the brightness value of the pixel in the edge polar coordinate image Y at the same position is QY. Can be calculated by

Further, the gradient angle of each pixel in the edge gradient image can be calculated by the following Expression 10.
Gradient angle=tan-1(QY/QX)...Equation (10)

In FIG. 33, the created edge gradient image G4 is schematically shown. The image recognition accelerator circuit 249 creates a histogram in the direction of the brightness gradient in the local area for each local area with the rectangular frame S indicated by the chain double-dashed line in the created edge gradient image G4 as the local area (cell). .. Then, the set of created histograms is stored in the SRAM 243.

[HOG template generation process]
The HOG template generation process is a process of generating a HOG template used in the determination process of the image recognition DSP circuit 242 described later.

In the HOG template generation processing, the image recognition accelerator circuit 249 compares the 50 sets of histograms (that is, relating to 50 medals) stored in the SRAM 243 with each other, and sets the histograms that match or are similar to each other to a predetermined degree. To group. Next, the image recognition accelerator circuit 249 selects the upper four groups in descending order of the number of histogram sets to which they belong. Then, for each of the selected upper four groups, any one set of histograms is stored as a HOG template in the storage area of the SRAM 243 storing the HOG template. It should be noted that instead of selecting one arbitrary set of histograms for each of the selected top four groups, the average value of the set of histograms belonging to the same group (the average value of the gradient strength in the same local region) is calculated. Therefore, the HOG template may be generated. Further, in the present embodiment, when 50 sets of histogram sets are stored in the SRAM 243, the stored histogram sets are compared with each other and the set of matching or similar to each other is grouped to generate a HOG template. Aspects have been described. However, the present invention is not limited to this, and every time a set of histograms is generated, a set of histograms stored in advance is compared, and a set of histograms that match or are similar to a predetermined degree are grouped to generate a HOG template. ..

As described above, by generating the HOG template, for example, when two types of medals having different markings (patterns) on the front and the back are used as regular medals, and the HOG template is stored in the storage area of the SRAM 243. If not, by inserting 50 regular medals after the power is turned on, four kinds of HOG templates for the front and back of these two kinds of medals can be generated. Further, when the HOG template is not stored in the storage area of the SRAM 243 and the number of the 50 regular medals thrown after the power is turned on is one, the two types of HOG for the front and back of the regular medals are used. A template is generated, and two types of generated HOG templates are used in the HOG template comparison process described later.

The matching of the set of histograms or the determination of the degree of similarity is performed by comparing the histograms at the same position (local regions at the same position in the edge gradient image) in the set of histograms. Further, the criteria for determination can be set as appropriate. For example, it is possible to determine that the two histogram sets match each other on the condition that all histograms completely match. Alternatively, it may be determined that the two histogram sets are similar on the condition that there is no histogram whose degree of coincidence is a predetermined degree or less, for example, 80% or less.

Here, the HOG template generation process is performed using a set of histograms related to the edge gradient image until the number of medals thrown after the power is turned on reaches a prescribed initial number of medals, 50 in this embodiment. The image recognition accelerator circuit 249 stores the created histogram set in the HOG template generation data storage area of the SRAM 243 until the set of histogram created in the HOG conversion process reaches 50 sets. Further, the image recognition accelerator circuit 249 performs the HOG template generation process when the set of 50 sets of histograms is stored in the HOG template generation data storage area of the SRAM 243. The image recognition accelerator circuit 249 stores the set of histograms created by the HOG conversion process in the determination target histogram storage area of the SRAM 243 after the HOG template creation process is executed.

<Judgment process by image recognition DSP circuit>
Next, the determination process executed by the image recognition DSP circuit 242 will be described. The determination process includes a gradient average image template comparison process and a HOG template comparison process.

(1) Gradient Average Image Template Comparison Processing In the gradient average image template comparison processing, the image recognition DSP circuit 242 acquires the gradient average image data generated by the image recognition accelerator circuit 249 from the determination target gradient average image data storage area of the SRAM 243. ..

Next, the image recognition DSP circuit 242 calculates the difference between the acquired gradient average image data and the gradient average image template stored in the SRAM 243. Then, the image recognition DSP circuit 242 determines whether or not the gradient average image data and the gradient average image template match or are similar to each other to a predetermined degree based on the calculated difference value and the threshold value for marking determination. , “Yes” or “No” is stored in the SRAM 243 as the determination result. In the present embodiment, since maximum four gradient average image templates are used, maximum four determination results are stored in the SRAM 243. Further, in the gradient average image template comparison processing, the gradient average determination result is stored in the SRAM 243. Here, when at least one “OK” is stored as the determination result for the maximum four templates, “OK” is stored in the SRAM 243 as the gradient average determination result, and all “NO” is stored. “No” is stored in the SRAM 243 as the gradient average determination result. Therefore, in a single gradient average image template comparison process, a maximum of four determination results for a maximum of four gradient average image templates and one gradient average determination result based on these determination results are stored.

For example, the image recognition DSP circuit 242 compares the brightness of each pixel of the acquired gradient average image data and the gradient average image template (calculates the difference), and determines whether the brightness of these pixels matches from the difference value. Alternatively, it is determined whether the difference is within a predetermined range, and if the pixels match or the difference is within a predetermined number of pixels, it is determined that the gradient average image data and the gradient average image template match or are similar to each other by a predetermined degree. .. On the other hand, when the number of matching pixels is less than a certain number, it is determined that the gradient average image data and the gradient average image template match or are not similar to a predetermined degree.

(2) HOG Template Comparison Processing In the HOG template comparison processing, the image recognition DSP circuit 242 acquires a set of histograms to be determined from the determination target histogram storage area. Next, it is determined whether or not the obtained set of histograms and the HOG template stored in the SRAM 243 match or are similar to each other to a predetermined degree, and the SRAM 243 stores “OK” or “NO” as the determination result. In the present embodiment, a maximum of four HOG templates are used, so a maximum of four determination results are stored in the SRAM 243. In the HOG template comparison process, the HOG determination result is stored in the SRAM 243. Here, in the case where even one “OK” is stored as the determination result for the maximum four templates, “OK” is stored in the SRAM 243 as the HOG determination result, and all “NO” is stored. “No” is stored in the SRAM 243 as the HOG determination result. Therefore, in one HOG template comparison process, up to four determination results for up to four HOG templates and one HOG determination result based on these determination results are stored.

Note that the determination of the match or similarity between the acquired set of histograms and the HOG template is the same as the determination of the match or similarity between the set of histograms in the above-described HOG template generation processing, and therefore the description thereof is omitted here.

As described above, the image recognition DSP circuit 242 that performs the gradient average image template comparison process and the HOG template comparison process constitutes a game medium determination unit that determines whether the object passing on the medal rail 210 is a regular medal. To do.

<GPIO>
The GPIO 250 (see FIG. 18) is a device for inputting/outputting each device connected to the medal selector 201 and the control LSI 234. Further, it is a device for inputting/outputting the control LSI 234 and various devices forming the medal selector 201.
For example, the medal count output PORT and the medal determination output PORT of the GPIO 250 are connected to the main control circuit 91 via the door relay terminal board 68 (the door relay terminal board 68 is not shown in FIG. 18). .. The LED control output PORT of the GPIO 250 is connected to the LED 233, and the control LSI 234 can control the turning on and off of the LED 233. Further, the notification LED control output PORT of the GPIO 250 is connected to the notification LED 206c, and the control LSI 234 can control lighting and extinction of the notification LED 206c. Further, the AE setting port of the GPIO 250 is connected to the CMOS image sensor 232, and the control LSI 234 can control the exposure time setting mechanism of the CMOS image sensor 232 (set the exposure time).

<Host controller>
The host controller 241 controls each device constituting the control LSI 234, for example, the medal count circuit 246, the color recognition circuit 247, the fisheye correction scaler circuit 248, the image recognition DSP circuit 242, the image recognition accelerator circuit 249, and the GPIO 250.

When the host controller 241 receives the determination result of the AE determination process from the ISP circuit 245, first, it refers to the area in the SRAM 243 in which the value of the exposure time stage is stored. Next, when the exposure time stage is “25”, that is, when the exposure time is not set to the upper limit of 175 μsec, the exposure time setting mechanism of the CMOS image sensor 232 is set to the AE setting PORT of the GPIO 250. A signal for instructing to increase the exposure time by one step is output. Then, 1 is added to the value of the area where the value of the exposure time stage is stored in the SRAM 243. In this embodiment, since the initial value of the exposure time is set to 70 μsec, the initial value stored in the area storing the value of the exposure time stage is set to 10. That is, in the present embodiment, the host controller 241 of the control LSI 234 constitutes exposure time setting means for setting the exposure time of the CMOS image sensor 232.

On the other hand, when the stage of the exposure time is “25”, that is, when the exposure time is set to the upper limit of 175 μsec, the host controller 241 instructs the notification LED 206c to turn on via the notification LED control output PORT of the GPIO 250. Output the signal. The host controller 241 also outputs a medal abnormality signal to the main control board 71 via the medal determination output PORT of the GPIO 250.
Further, the host controller 241 is pressed by an initialization switch (not shown) arranged on a switch substrate (not shown) provided at an arbitrary position of the medal selector 201 (for example, near the first substrate 230). Then, the step of the exposure time is set to the initial value “10”, that is, the exposure time is set to 70 μsec. Thereby, for example, an employee of the game hall can reset the proper exposure time of the CMOS image sensor 232 by pressing the initialization switch after performing maintenance (cleaning or the like) of the lens of the camera unit 209. Become.

Further, the host controller 241 outputs a signal related to a lighting instruction or a light extinction instruction to the LED 233 via the GPIO 250. In addition, the host controller 241 determines, via the GPIO 250, the determination result relating to the count processing stored in the SRAM 243, that is, “the medal has passed”, “the medal has been guided to the medal shoot 202”, and “abnormality”. Has occurred” is output. Specifically, when the determination result is "a medal has passed", a medal count signal is output from the medal count output PORT, and when it is "an abnormality has occurred", a medal abnormality signal is output from the medal determination output PORT. Is output. Also, the determination result relating to the color determination processing is output. Specifically, when “threshold judgment not possible” is stored in the SRAM 243 as the judgment result of the threshold judgment processing, or when “no” is stored as the color judgment result, the medal judgment output assigned to the GPIO 250 is output. An abnormal medal signal is output from the PORT when a predetermined output condition is satisfied. Further, it outputs the determination result related to the determination processing by the image recognition DSP circuit 242. Specifically, when the SRAM 243 stores “NO” as the gradient average determination result or the HOG determination result, a medal abnormality signal is output from the medal determination output PORT assigned to the GPIO 250 as a predetermined output condition. Output when established.

The predetermined output condition of each determination result can be set as appropriate. For example, the determination result regarding the count process may be set to “when an abnormality has occurred” is stored in the SRAM 243 as the determination result of the count process, or continuously or immediately after. It is also possible to set when the “abnormality has occurred” is stored for a predetermined number (for example, 10 times) or more of the total number of predetermined determinations (for example, 50 times) in the counting process. The determination result of the threshold determination process may be set to “when the threshold determination is not possible” is stored in the SRAM 243 as the determination result, or continuously or in the latest threshold determination process. It may be set to “when the threshold value determination is impossible” is stored for a predetermined number (for example, 10 times) or more of the total number of predetermined determination times (for example, 50 times). Further, the color determination result of the color determination processing may be set to be “when “No” is stored in the SRAM 243, or may be set continuously or in a predetermined determination number of the latest color determination processing ( For example, a total of 50 times may be set as “when no” is stored a prescribed number of times (for example, 10 times) or more. In addition, the slope average determination result or the HOG determination result of the marking determination process may be set to "when "no" is stored in the SRAM 243, or continuously or immediately. It may be set to “when no” is stored for a predetermined number (for example, 10 times) or more of the total number of predetermined determinations (for example, 50 times) in the marking determination process.

A backup power supply (not shown) is connected to the SRAM 243, and the contents stored in the SRAM 243 are retained for a certain period (for example, about one week) even when the power of the pachi-slot 1 is cut off. Further, the host controller 241 can delete various templates stored in the SRAM 243, such as a color template, a gradient average image template, and a HOG template, by an initialization switch (not shown) provided in the medal selector 201. .. Specifically, by turning on the power of the pachi-slot 1 with the initialization switch pressed, the area in the SRAM 243 in which various templates are stored is initialized (value of 0 is set during initialization processing of the host controller 241). Write), that is, erase various templates.

<Flash memory>
In the flash memory 244, various devices constituting the control LSI 234, such as the host controller 241, the image recognition DSP circuit 242, the fisheye correction scaler circuit 248, and the image recognition accelerator circuit 249, are necessary for various parameters and various processes. The data is stored. Further, the flash memory 244 is provided with an area for storing the value of the above-described exposure time stage.

<Processing flow of control LSI>
Next, the processing performed by the control LSI 234 will be described with reference to FIG. FIG. 34 is a process flow diagram for explaining the process performed by the control LSI 234.
As shown in FIG. 34, the control LSI 234 roughly performs an input process, a conversion process, a color determination process, a count process, and a marking determination process.

<Input processing>
The input process is performed by the ISI circuit 251. In the input processing, as described above, the ISI circuit 251 converts the image data transmitted from the CMOS image sensor 232 by the LVDS method into an RGB Bayer image and outputs it to the ISP circuit 245.

<AE correction processing>
The AE correction process is performed by the ISP circuit 245 and the host controller 241 when the power of the pachi-slot 1 is turned on. The AE correction process is performed in parallel with the conversion process, the color determination process, and the count process described later.

In the AE correction process, the ISP circuit 245 determines whether or not the RGB Bayer image output from the ISI circuit 251 includes an image of the ridge 210a (see FIG. 8) formed on the surface of the medal rail 210. AE determination processing is performed. When the ISP circuit 245 determines that the output image does not include the image of the rib portion 210a, the ISP circuit 245 outputs the determination result of the AE determination process to the host controller 241.

Further, in the AE correction process, when the determination result of the AE determination process is output from the ISP circuit 245, the host controller 241 first refers to the area in the SRAM 243 in which the value of the exposure time stage is stored. Next, when the exposure time level is “25”, that is, when the exposure time is not set to the upper limit of 175 μsec, the exposure time setting mechanism of the CMOS image sensor 232 is set to the AE setting PORT of the GPIO 250. A control signal for instructing to increase the exposure time by one step (extending 7 μs) is output. Then, 1 is added to the value of the area where the value of the exposure time stage is stored in the SRAM 243.

By doing so, the image subjected to the AE determination processing by the ISP circuit 245 next becomes an RGB Bayer image based on the image acquired by the CMOS image sensor 232 with the exposure time increased by one step. The AE correction process is repeatedly performed until the ISP circuit 245 determines in the AE determination process that the image of the rib portion 210a is included in the image, or until the exposure time is set to the upper limit of 175 μsec.

In the AE determination process, when the ISP circuit 245 determines that the image output from the ISI circuit 251 includes the image of the rib 210a, the ISP determination process does not output the determination result of the AE determination process to the host controller. After that, the AE determination process is not performed on the image output from the ISI circuit 251. That is, the exposure time of the CMOS image sensor 232 is set to the exposure time when the ISP circuit 245 determines that the image output from the ISI circuit 251 includes the image of the protrusion 210a. When the ISP circuit 245 determines that the image output from the ISI circuit 251 first includes the image of the protrusion 210a after the power is turned on, the exposure time of the CMOS image sensor 232 is set to the initial value. It becomes 70 microseconds (step 10).

In the AE correction process, when the ISP circuit 245 outputs the determination result of the AE determination process, the host controller 241 sets the exposure time stage to “25”, that is, when the exposure time is set to the upper limit of 175 μsec. The host controller 241 outputs a control signal for instructing the notification LED 206c to turn on via the notification LED control output PORT of the GPIO 250. The host controller 241 also outputs a medal abnormality signal to the main control board 71 via the medal determination output PORT of the GPIO 250.

As described above, when the host controller 241 outputs the control signal for instructing the notification LED 206c to turn on and outputs the medal abnormality signal to the main control board 71, the exposure time is set to the upper limit value of 175 μsec. Even if the projection 210a of the medal rail 210 could not be imaged. In such a case, it is conceivable that some trouble (for example, dirt such as dust adheres to the lens) has occurred in the camera unit 209. Therefore, in this state, the detection of the insertion of the game medal using the camera unit 209 and the detection of the illegal activity cannot be effectively performed, and therefore the main control circuit 91 is similar to the various processing in the case of the illegal activity. Perform processing. For example, the main control circuit 91 forcibly interrupts the game, displays an error code on the 7-segment display 24, transmits an error command to the sub control circuit 101, and outputs an error via the sub control circuit 101. A notification is given (for example, a predetermined error screen is displayed on the liquid crystal display device 11).

<Conversion process>
The conversion process is performed by the ISP circuit 245. In the conversion process, the ISP circuit 245 performs the image correction process of performing the lens distortion correction process and the projective conversion (homography) process on the RGB Bayer image output from the ISI circuit 251. Next, the ISP circuit 245 performs the color conversion process of converting the corrected RGB Bayer image into YUV image data and outputting the grayscale image data to the medal count circuit 246. Further, the RGB Bayer image is converted into HSV image data, and color conversion processing is performed to output this HSV image data to the color recognition circuit 247.

After the conversion processing, the control LSI 234 performs color determination processing, counting processing, and marking determination processing. It should be noted that these processes are executed in parallel at each executable timing because the circuits that execute the respective processes are configured as separate circuits.

<Color judgment processing>
The color determination processing is performed by the color recognition circuit 247. The color determination processing includes medal detection processing, threshold determination processing, saturation/hue multiplication processing, color template generation processing, and color template comparison processing.

First, the color recognition circuit 247 performs medal detection processing to determine whether or not the HSV image data output from the ISP circuit 245 includes a medal image. When it is determined that the HSV image data includes a medal image, the color recognition circuit 247 performs a threshold determination process based on the HSV image data. In the threshold determination process, if the position on the threshold graph (see FIG. 21) based on the average saturation value and the average hue value is within the allowable region, the color determination process is continued. On the other hand, if it is within the non-permissible area, “threshold determination not possible” is stored in the SRAM 243 as the determination result, and the color determination processing ends.

After the threshold value determination processing, the color recognition circuit 247 performs saturation/hue multiplication processing to create color determination data. Then, the created color determination data is compared with the color template to determine whether they match or are similar to each other to a predetermined degree, and the determination result is stored in the SRAM 243.

The color template comparison process is not executed until the number of medals inserted after the power is turned on reaches the specified initial insertion number, which is 50 in this embodiment, because the color template is not generated.

Further, the color recognition circuit 247 determines that the number of medals thrown after the power is turned on reaches the prescribed initial number of medals of 50 and the number of color determination data stored in the color determination data storage area reaches 50, that is, 50 medals. When the color determination data relating to the medal is created, the color template generation process is executed.

<Count processing>
The counting process is performed by the medal counting circuit 246. Count processing includes medal detection processing and order determination processing. The medal image determination process and the medal position detection process described above correspond to the medal detection process. In the medal detection process, the medal count circuit 246 determines whether or not the grayscale image data output from the ISP circuit 245 includes a medal image. Further, it is determined whether or not a medal image is present in a predetermined determination area in the grayscale image data output from the ISP circuit 245, and the determination result (“IN”, “OUT”, “ON”, “OFF” Data) is stored in the SRAM 243.

In the order determination process, the medal count circuit 246 causes the transition of the data of “IN”, “OUT”, “ON”, “OFF” for each determination region in a predetermined number of grayscale image data arranged in time series. It is determined whether or not the mode of (1) matches the mode of the predetermined transition. Then, as the determination result, one of “a medal has passed”, “a medal was guided to the medal shoot 202”, or “an abnormality has occurred” is stored in the SRAM 243. Further, when it is stored in the SRAM 243 that “a medal has passed”, the host controller 241 outputs a medal count signal from the medal count output PORT allocated to the GPIO 250. Based on this medal count signal, the main control circuit 91 detects that a medal has been inserted, and counts the number of inserted medals or the number of credits. That is, in the present embodiment, the medal count circuit 246 that performs the order determination process constitutes a passage determination unit that determines whether or not an object has passed through the passage based on the image data obtained via the image capturing unit.

<Engraving judgment processing>
The marking determination processing includes fisheye correction processing and equalization processing performed by the fisheye correction scaler circuit 248, and circle area detection processing, filter processing, gradient average image template comparison processing and HOG template comparison performed by the image recognition DSP circuit 242. Processing is included. Further, it includes a rotation image generation process, a gradient average image data generation process, a gradient average image template generation process, a polar coordinate conversion process, a Scharr conversion process, a HOG conversion process, and a HOG template generation process performed by the image recognition accelerator circuit 249.

In the fisheye correction processing, the fisheye correction scaler circuit 248 acquires grayscale image data from the SRAM 243 and performs fisheye correction processing of correcting the acquired grayscale image data. Next, in the equalization processing, the fisheye correction scaler circuit 248 performs equalization processing on the grayscale image data that has undergone the fisheye correction processing, creates reduced image data, and stores it in the SRAM 243.

When it is determined in the counting process that the medal has passed on the medal rail 210, the host controller 241 instructs the image recognition DSP circuit 242 and the image recognition accelerator circuit 249 to execute the processes after the circle area detection process in the marking determination process. To do.

In the circle area detection process, the image recognition DSP circuit 242 acquires the reduced image data from the SRAM 243 and detects the circle area from the reduced image data. Further, in the filter processing, the image recognition DSP circuit 242 performs nonlinear diffusion filter processing on the detected circular region to create an edge image XY, and stores it in the SRAM 243.

Next, in the rotation image generation process, the image recognition accelerator circuit 249 acquires the edge image XY from the SRAM 243 and generates a rotation image for 360 degrees from the edge image XY. Further, in the gradient average image data generation process, the image recognition accelerator circuit 249 cumulatively adds (overlaps) the rotated images for 360 degrees to generate gradient average image data, and stores the gradient average image data in the SRAM 243. Let The image recognition accelerator circuit 249 stores the gradient average image data in the gradient average image template generation data storage area before generating the gradient average image template, and after the gradient average image template is generated, the determination target It is stored in the gradient average image data storage area.

Next, in the gradient average image template comparison process, the image recognition DSP circuit 242 determines whether the gradient average image data to be determined and the gradient average image template match or are similar to each other by a predetermined degree, and the determination result is stored in the SRAM 243. Remember. Here, if the gradient average image template is not generated at the time of executing the gradient average image template comparison processing (in the present embodiment, less than 50 medals have been thrown after the power is turned on), the gradient average image template is generated. The comparison process is not executed.

As described above, at the timing when the number of medals thrown after the power is turned on reaches the prescribed initial number of medals, 50, and the gradient average image data is stored in the gradient average image data generation data storage area of the SRAM 243. The image recognition accelerator circuit 249 performs gradient average image template generation processing.

Further, the image recognition accelerator circuit 249 performs polar coordinate conversion processing in parallel with the rotation image generation processing. In the polar coordinate conversion process, the edge image XY is acquired from the SRAM 243, the orthogonal coordinates of the acquired edge image XY are converted into polar coordinates, polar coordinate image data is created, and the polar coordinate image data is stored in the SRAM 243.

Next, in the Scharr conversion process, the image recognition accelerator circuit 249 acquires the polar coordinate image data from the SRAM 243 and performs the nonlinear diffusion filter process to create the edge polar coordinate image X and the edge polar coordinate image Y.

Next, in the HOG conversion process, the image recognition accelerator circuit 249 creates an edge gradient image based on the edge polar coordinate image X and the edge polar coordinate image Y, performs the HOG conversion on the created edge gradient image, and performs a local region for each local region. A histogram in the gradient direction of the luminance in is created. Then, the set of created histograms is stored in the SRAM 243. The image recognition accelerator circuit 249 stores the set of histograms in the HOG template generation data storage area before generating the HOG template, and stores it in the determination target histogram storage area after generating the HOG template.

Next, in the HOG template comparison processing, the image recognition DSP circuit 242 determines whether the set of histograms to be determined and the HOG template stored in the SRAM 243 match or are similar to each other by a predetermined degree. Then, the determination result is stored in the SRAM 243. If the HOG template is not generated (in this embodiment, less than 50 medals have been thrown after the power is turned on), the HOG template comparison process is not executed.

As described above, at the timing when 50 medals have been thrown in after the power is turned on and a set of 50 sets of histograms are stored in the HOG template generation data storage area of the SRAM 243, the image recognition accelerator circuit 249 causes the HOG Perform template generation processing.

<Timing of control LSI processing>
Next, the timing of various processes performed by the control LSI 234 will be described with reference to FIG.
FIG. 35 shows a time-series relationship of processing in the host controller 241, the ISP circuit 245, the medal count circuit 246, and the color recognition circuit 247, which are the devices constituting the control LSI 234. The relatively thick line portion of the line extending below each device name indicates that the device is in the state of performing the above-described various processes.

Further, broken line arrows between the lines corresponding to the respective devices indicate signals input/output between the respective devices. In addition, a dashed arrow between a line extending below “IN” and a line extending below “OUT” in the host controller indicates a signal detected by the host controller 241 and a signal output from the host controller 241. Shows the correspondence with.
The AE correction processing performed by the host controller 241 and the ISP circuit 245 is not shown.

First, when the CMOS image sensor 232 (see FIG. 17) outputs image data to the control LSI 234, the ISP circuit 245 acquires the image data via the ISI circuit 251, and the VSYNC (Vertical Synchronization) interrupt signal #0 (1IH). ) Is output to the host controller 241. The ISP circuit 245 also performs conversion processing for converting the RGB Bayer image into various formats. Then, the grayscale image data and the HSV image data are output to the SRAM 243, the medal count circuit 246, and the color recognition circuit 247. The detailed description of the conversion process is omitted because it has been described above.

When the VSYNC interrupt signal #0 is input, the host controller 241 outputs a start request signal (1HC, 1HM) to the color recognition circuit 247 and the medal count circuit 246 after a predetermined time has elapsed. It should be noted that this predetermined time is set to be longer than the time required for the conversion processing in the ISP circuit 245 based on experiments and simulations.

When the activation request signal is input, the color recognition circuit 247 also performs color determination processing on the HSV image data output from the ISP circuit 245, stores the determination result in the SRAM 243, and causes the host controller 241 to perform color determination. Output an interrupt signal (1CH). The detailed description of the color determination process has been described above, and will be omitted.

When the activation request signal is input, the medal count circuit 246 performs counting processing based on the data output from the ISP circuit 245, stores the determination result in the SRAM 243, and also causes the host controller 241 to store the medal count allocation. It outputs an embedded signal (1 MH). The detailed description of the counting process has been described above, and will be omitted.

Upon detecting the color determination interrupt signal and the count interrupt signal, the host controller 241 acquires the determination result of the count process from the SRAM 243. Then, it is determined whether or not any one of "a medal has passed", "a medal was guided by the medal shoot 202", and "an abnormality has occurred" is stored as the determination result. If neither is stored, the host controller 241 omits the process of outputting the determination result to the main control board 71 (main control circuit 91) via the GPIO 250. Here, in the present embodiment, as described above, in the order determination process of the count process, it is necessary that the mode of data transition in each determination region of a plurality of grayscale image data is stored in the SRAM 243. The process of outputting the determination result to the main control board 71 is omitted at least until the number of grayscale image data received by the medal counting circuit 246 reaches a predetermined number (14 or 4 when medals cannot be inserted). There are cases.

Regarding the timing of the processing of each device triggered by the input of the VSYNC interrupt signals #1 to 4 (2IH to 5IH) and the input/output of signals shown in FIG. 35, the input of the VSYNC interrupt signal #0 (1IH Since the processing timing and signal input/output of each device triggered by () are the same, description thereof will be omitted here.

Next, the processing timing and signal input/output of each device, which is triggered by the input of the VSYNC interrupt signal #n(nIH), which is the nth VSYNC interrupt signal after power-on shown in FIG. 35, will be described. .. It should be noted that the ISP circuit 245 outputs the VSYNC interrupt signal #n to the host controller 241 (nIH), and then the host controller 241 acquires the count determination result from the SRAM 243 and inputs and outputs signals. With respect to the above, since the processing timing and signal input/output of each device triggered by the input of the VSYNC interrupt signal #0 (1IH) described above are the same, description thereof will be omitted here.

The host controller 241 stores, as the determination result of the counting process, any one of “a medal has passed”, “a medal was guided to the medal shoot 202”, and “an abnormality has occurred”, The determination result and the determination result of the color determination process are acquired from the SRAM 243, and these determination results are output to the allocation PORT of the GPIO 250 (nHG). That is, the host controller 241 outputs the determination result of the count determination process and the determination result of the color determination process to the main control board 71 (main control circuit 91) via the GPIO 250. There may be a plurality of judgment results of the color judgment processing output here.

Further, when the determination result of the counting process is “a medal has passed”, the host controller 241 relates to each medal until the number of medals inserted into the gaming machine reaches the specified initial number, 50 in the present embodiment. In order to generate the color determination data, the color recognition circuit 247 is instructed to generate the color determination data by using the HSV image data of a predetermined time. Further, the host controller 241 instructs the image recognition DSP circuit 242 to perform preprocessing using the reduced image data of a predetermined time.

Further, the host controller 241 deletes the determination result output to the main control board 71 from the SRAM 243.

When the determination result of the counting process is “a medal has passed”, the main CPU 93 of the main control circuit 91 detects the medal count signal output from the medal count output PORT of the GPIO 250 to determine the number of inserted medals. The main CPU 93 adds 1 to the value of the inserted number counter, which is a counter provided for counting. In addition, when the value of the inserted number counter is the maximum value (for example, 3), 1 is added to the value of the credit counter which is a counter provided for the main CPU 93 to count the number of credited medals. When the credit counter has the maximum value (for example, 50), the main control circuit 91 sets the medal solenoid 208 of the medal selector 201 to the OFF state. As a result, the select plate 207 is positioned at the “discharging position”, the medals cannot be inserted, and the medals inserted after the credit counter reaches the maximum value are guided to the medal chute 202 and the medal tray 32 from the medal payout opening 32. Discharge to unit 34. In the present embodiment, when the start lever is operated when the value of the thrown-in number counter is a prescribed value (for example, 2 or 3), the main CPU 93 performs the above-mentioned internal lottery process.

Further, when the determination result of the color determination process is “threshold determination is not possible”, the color determination result is “no”, and the count determination result is “abnormal”, the medal determination output of the GPIO 250 is output. With a medal abnormality signal (Judgment in FIG. 35) output when a predetermined output condition is satisfied from the PORT, the main control circuit 91 causes the gaming machine to mistakenly recognize that a regular game medium is used and plays the game. Detects fraudulent activity. Then, various processes are carried out when there is an illegal act. Here, various processing when there is an illegal act includes, for example, the main control circuit 91 forcibly interrupting the game, displaying an error code on the 7-segment display 24, and an error on the sub control circuit 101. This is a process of transmitting a command and notifying that there has been an illegal act via the sub-control circuit 101 (for example, displaying that the illegal act has occurred on the liquid crystal display device 11).

Next, the timing of other processing performed by the control LSI 234 will be described with reference to FIG.
FIG. 36 shows a time-series relationship of processes in the host controller 241, the ISP circuit 245, the fish-eye correction scaler circuit 248, the image recognition DSP circuit 242, and the image recognition accelerator circuit 249, which are the devices constituting the control LSI 234. .. Note that the meanings of various notations in FIG. 36 are the same as those in FIG. 35, and therefore description thereof is omitted here. Further, FIG. 36 shows the timing of processing after the VSYNC interrupt signal #m, which is the mth VSYNC interrupt signal after power-on, is output from the ISP circuit 245.

First, when the CMOS image sensor 232 (see FIG. 17) outputs image data to the control LSI 234, the ISP circuit 245 acquires the image data via the ISI circuit 251, and the VSYNC (Vertical Synchronization) interrupt signal #m (1IH ) Is output to the host controller 241. The ISP circuit 245 also performs conversion processing for converting the RGB Bayer image into various formats. Then, the grayscale image data is stored in the SRAM 243. The detailed description of the conversion process is omitted because it has been described above.

When the VSYNC interrupt signal #m is input, the host controller 241 detects the end of the conversion processing of the ISP circuit 245, and at the timing when the conversion processing ends, the start request signal (1HG) to the fisheye correction scaler circuit 248. Is output. It should be noted that this predetermined time is set to be longer than the time required for the conversion processing in the ISP circuit 245 based on experiments and simulations.

When the activation request signal is input, the fisheye correction scaler circuit 248 acquires the grayscale image data from the SRAM 243, performs the fisheye correction process and the equalization process, and stores the created reduced image data in the SRAM 243. A reduction end interrupt signal (1GH) is output to the host controller 241. The detailed description of the fisheye correction process and the equalization process is omitted because it has been described above.

The host controller 241 has output to the main control circuit 91 the determination result of the count processing that "the medal has passed" from the input of the previous reduction end interrupt signal to the input of the current reduction interrupt signal. Under the condition, the signal (1HD) instructing the start of the preprocessing is input to the image recognition DSP circuit 242. It should be noted that the condition for instructing the start of the pre-processing is that the determination result of the color determination process output to the main control circuit 91 is “threshold determination is not possible”, or it does not match or is similar to any of the four color templates to a predetermined degree. It may be added to the condition that it is not included, that is, that the determination result that it matches or is similar to a certain degree with any of the color templates is included.

The image recognition DSP circuit 242 performs preprocessing when the above signal is input from the host controller 241. As described above, the preprocessing includes the circular area detection processing and the filter processing. The edge image XY created in the preprocessing is stored in the SRAM 243, and the preprocessing end interrupt signal (1DH1) is output to the host controller 241. The detailed description of the preprocessing is omitted because it has been described above.

When the preprocessing completion interrupt signal is input, the host controller 241 outputs a signal (1HA) instructing the start of the correction processing to the image recognition accelerator circuit 249. Here, the correction processing is the above-described rotation image generation processing, gradient average image data generation processing, polar coordinate conversion processing, Scharr conversion processing, and HOG conversion processing. The detailed description of these processes is omitted because it has been described above.

The image recognition accelerator circuit 249 performs a correction process when the signal is input from the host controller 241. When the generated gradient average image data has already generated the gradient average image template, it is stored in the determination target gradient average image data storage area of the SRAM 243, while the gradient average image template has not been generated yet. Is stored in the gradient average image template generation data storage area. The set of generated histograms is stored in the determination target histogram storage area of the SRAM 243 when the HOG template has already been generated, while it is stored in the HOG template generation data storage area when the HOG template has not been generated yet. Remember.

Next, the image recognition accelerator circuit 249 outputs a correction processing end interrupt signal (1AD) to the image recognition DSP circuit 242 when the gradient average image template and the HOG template have already been generated. On the other hand, when the gradient average image template and the HOG template have not been generated yet, the process of outputting the correction process end interrupt signal to the image recognition DSP circuit 242 is omitted. The image recognition accelerator circuit 249 performs the gradient average image template generation process when 50 pieces of the gradient average image data are stored in the gradient average image data generation data storage area of the SRAM 243. Further, the image recognition accelerator circuit 249 performs the HOG template generation process when the set of 50 sets of histograms is stored in the HOG template generation data storage area of the SRAM 243.

The image recognition DSP circuit 242 performs the marking determination process when the correction process end interrupt signal is input. The marking determination process here includes a gradient average image template comparison process and a HOG template comparison process. Specifically, the image recognition DSP circuit 242 acquires the gradient average image data from the determination target gradient average image data storage area of the SRAM 243, and performs the gradient average image template comparison process of comparing with the gradient average image template. Then, the determination result of the gradient average image template comparison processing is stored in the SRAM 243. Further, a set of histograms is acquired from the determination target histogram storage area of the SRAM 243, and a HOG template comparison process for comparing with the HOG template is performed. Then, the determination result of the HOG template comparison processing is stored in the SRAM 243. After that, the image recognition DSP circuit 242 outputs a marking determination end interrupt signal (1DH2) to the host controller 241.

When the marking determination end interrupt signal is input, the host controller 241 acquires the slope average determination result and the HOG determination result as the determination result of the marking determination processing stored in the SRAM 243. In addition, when the host controller 241 stores “NO” as the acquired gradient average determination result or “NO” as the HOG determination result, when the above-described predetermined output condition is satisfied. Then, the medal determination output PORT of the GPIO 250 outputs a medal abnormality signal (Judgment in FIG. 36) to the main control circuit 91 (1HG). That is, the host controller 241 outputs the determination result of the marking determination process to the main control board 71 (main control circuit 91) via the GPIO 250. Further, the host controller 241 deletes the determination result of the marking determination processing output to the main control board 71 from the SRAM 243. In the present embodiment, the same output PORT of the GPIO 250 is assigned to the output of the determination result of the color determination processing to the main control circuit 91 and the output of the determination result of the marking determination processing to the main control circuit 91. Not limited to this, it may be assigned to different output PORTs. In this case, the main control circuit 91 can determine whether the medal abnormality signal is based on the determination result of the color determination process or the medal abnormality signal is based on the determination result of the marking determination process.

The main control circuit 91 erroneously recognizes that a regular game medium is used in the game machine when the determination result of the input marking determination process, that is, either the slope average determination result or the HOG determination result is “NO”. Then, it is detected that there is an illegal act of playing a game. Then, various processes are carried out when there is an illegal act. Here, various processing when there is an illegal act includes, for example, the main control circuit 91 forcibly interrupting the game, displaying an error code on the 7-segment display 24, and an error on the sub control circuit 101. This is a process of transmitting a command and notifying that there has been an illegal act via the sub-control circuit 101 (for example, displaying that the illegal act has occurred on the liquid crystal display device 11).

Note that, in FIG. 36, various processes following VSYNC#m, triggered by VSYNC#m+1, VSYNC#m+2, VSYNC#m+3, VSYNC#m+4, VSYNC#m+5, and VSYNC#m+6 are triggered by the above-mentioned VSHYC#m. With respect to the same processes as those described above, various signals output in accordance with the processes are denoted by reference numerals for changing only the leading numeral, and detailed description thereof will be omitted.

Here, after the processing of outputting the reduction end interrupt signal (2GH, 3GH, 4GH, 6GH) from the fisheye correction scaler circuit 248 to the host controller 241, the host controller 241 starts the preprocessing to the image recognition DSP circuit 242. The process of outputting the signal instructing is not performed.

This is because the host controller 241 shows the determination result of the count process that the medal has passed to the main control circuit 91 from the input of the previous reduction end interrupt signal to the input of the current reduction interrupt signal. This is because it has not been output. In this example, the host controller 241 “passes the medal” to the main control circuit 91 between the input of the reduction end interrupt signal for 4GH and the input of the reduction end interrupt signal for 5GH. It outputs the determination result of the count process. Therefore, after the reduction end interrupt signal related to 5GH is input, the host controller 241 outputs a signal (2HD) instructing the image recognition DSP circuit 242 to start the preprocessing.

Further, in the present embodiment, it is preferable that the marking determination process is performed on all the medals to be inserted. However, the host controller 241 confirms whether the image recognition DSP circuit 242 or the image recognition accelerator circuit 249 is in processing (busy state) when outputting a signal instructing the image recognition DSP circuit 242 to start preprocessing. However, the signal may not be output when any one is being processed, and the signal may be output when no one is being processed. In this case, the engraving determination process is performed intermittently for medals that have been continuously inserted. For example, when three medals are continuously inserted, the marking determination processing is performed on the first and third medals.

The processing timing of each device in the control LSI 234 shown in FIGS. 35 and 36 is merely an example. The regular medal determination process may be performed at various processing timings depending on the processing capability of each device, the processing content, and the processing procedure.

<First action>
In the pachi-slot 1 of the present embodiment, the result of the color determination processing based on the image data output from the CMOS image sensor 232, which is performed by the color recognition circuit 247, is “threshold determination not possible”, or any of the four color templates is matched. Or, if the color of the inserted medal does not match the color of the regular medal, the main control circuit 91 determines that the regular game medium is used for the gaming machine. It is detected that there is a fraudulent act of playing by misidentifying.

Further, when the result of the count process based on the image data output from the CMOS image sensor 232 is “abnormality has occurred”, the main control circuit 91 causes the gaming machine to misidentify that a regular game medium is used. It detects that there is an illegal act of playing a game.

In addition, the result of the marking determination processing (in the present embodiment, the gradient average determination result or the HOG determination result) performed by the image recognition DSP circuit 242 based on the image data output from the CMOS image sensor 232 is “NO”. In this case, that is, when the stamp of the inserted medal and the stamp of the regular medal are different, the main control circuit 91 misidentifies that the regular game medium is used in the gaming machine, and detects that there is an illegal act of playing the game. Detect.

Therefore, the main control circuit 91 performs a fraudulent act performed by inserting a special instrument into the medal insertion slot, or a fraudulent act performed using a medal having the same diameter as the regular medal but different in color and marking (pattern). It can be detected accurately.

Then, when detecting that there has been a cheating, the main control circuit 91 forcibly interrupts the game, and notifies that there has been a cheating through the sub control circuit 101. Therefore, it is possible to suppress the spread of damage caused by the above-mentioned fraudulent acts.

<Second action>
Further, in the pachi-slot 1 of the present embodiment, the control LSI 234 of the medal selector 201 passes through the medal rail 210 after the power is turned on until the number of inserted medals reaches the specified initial number, 50 in the present embodiment. A color template used in the color determination process is generated based on the image including. Similarly, the gradient average image template and the HOG template used for the marking determination process are generated.

Therefore, when the medals used as the regular medals are changed at the amusement store, the color template relating to the changed regular medals can be obtained by continuously supplying 50 changed regular medals after the power is turned on. Gradient average image templates and HOG templates can be easily created. In addition, even if the regular medal is, for example, inserted into a game machine, paid out, or deteriorated due to cleaning at a game store, and the marking is less noticeable than originally, a color template corresponding to the current state of the regular medal, Since the gradient average image template and the HOG template can be generated, the accuracy of the results of various determinations can be maintained.

<Third action>
Further, in the pachi-slot 1 of the present embodiment, the medal counting circuit 246 of the control LSI 234 performs counting processing based on the grayscale image data output from the ISP circuit 245. In the order determination process in the counting process, the medal counting circuit 246 performs “IN” based on a change in luminance of a plurality (16 in the present embodiment) of determination regions for a predetermined number of grayscale image data arranged in time series. , "OUT", "ON", "OFF" data transition mode is determined to match the transition mode of the medal count determination table (see FIG. 27). If they match, it is determined that “the medal has passed” or “the medal has been guided by the medal shoot 202” on the medal rail 210. If any of the data “IN”, “OUT”, and “ON” is stored in the judgment area E, it is judged that an abnormality has occurred.

As described above, since the passage of a medal or the like is determined based on the change in the brightness in the plurality of determination areas, the determination accuracy can be improved.

Further, the number of determination areas set on the grayscale image data can be set as appropriate according to the allowable determination required time and the required determination accuracy. Therefore, for example, even if the number of determination areas is increased in order to further improve the determination accuracy, it is not necessary to newly install a component such as a photo sensor for counting medals. Therefore, an increase in manufacturing cost can be suppressed.

Further, when the determination result of the count process is “abnormality has occurred”, the main control circuit 91 misidentifies that the game machine is using a legitimate game medium, and there is an illegal act of playing a game. To detect. That is, it is possible to detect an illegal act based on the determination result of the counting process.

<Fourth action>
Further, in the pachi-slot 1 of the present embodiment, the ISP circuit 245 of the control LSI 234 performs the image correction process of performing the lens distortion correction process and the projective transformation (homography) process on the RGB Bayer image output from the ISI circuit 251.

Therefore, the RGB Bayer image can be complemented so that the characteristics of the lens of the camera unit 209 and the displacement of the mounting position of the camera unit 209 do not affect various determination/determination processes, and the accuracy of various determination processes can be improved.

<Fifth action>
Further, in the pachi-slot 1 according to the present embodiment, the color recognition circuit 247 of the control LSI 234 performs the threshold determination processing. As a result, it is possible to prevent an erroneous determination that a hue or saturation value that is different from that of the regular medal is coincident with or similar to the color template to a predetermined degree. That is, in addition to the determination based on the degree of coincidence with the color template, it is possible to determine whether or not the color to be determined itself is a valid color, so the accuracy of the determination result of the color determination processing can be improved.

<Sixth action>
Further, in the pachi-slot 1 of the present embodiment, the fisheye correction scaler circuit 248 of the control LSI 234 performs bilateral conversion processing on each of the reduced image data created in the equalization processing.
This can reduce noise in the grayscale image data and enhance edges in the grayscale image data. Therefore, the accuracy of the determination result in the marking determination process can be improved.

<Seventh action>
Further, in the pachi-slot 1 of the present embodiment, the image recognition accelerator circuit 249 of the control LSI 234 performs the HOG conversion process. Further, the image recognition DSP circuit 242 determines whether or not the set of histograms to be determined created by the HOG conversion process and the HOG template match or are similar to each other in a predetermined degree in the marking determination process.

Therefore, the marking determination process is performed by performing image matching with the HOG conversion process, which has an advantage in the local shape change (geometric conversion), on the imaged data of the medal passing on the medal rail 210 while rotating. It is possible to improve the accuracy of the determination result of.

<Eighth action>
In the pachi-slot 1 of the present embodiment, the image recognition accelerator circuit 249 of the control LSI 234 performs polar coordinate conversion processing before the HOG conversion processing.
As a result, the characteristics of the outer peripheral area of the regular medal are easily reflected in the set of histograms created by the HOG conversion process. Therefore, it is possible to improve the accuracy of the determination result of the subsequent engraving determination process for the medals having the characteristic engraving (pattern) on the outer peripheral area.

<Ninth action>
In the conventional game machine, the count of inserted medals, the detection of clogging of medals in the selector of inserted medals, etc. is performed by the main CPU in the main control circuit by executing a program stored in the main ROM. It was done. However, in the pachi-slot 1 of the present embodiment, the control LSI 234 of the medal selector 201 performs these detections with higher accuracy than conventional. Therefore, it is not necessary to store the programs for these detections in the main ROM 94, and the storage capacity of the main ROM 94 is reduced.

<Tenth action>
In the pachi-slot 1 of the present embodiment, the AE correction processing is performed by the ISP circuit 245 of the control LSI 234 and the host controller 241. Therefore, the exposure time of the CMOS image sensor 232 can be set to the exposure time at which the protrusion 210a of the medal rail 210 can be imaged. With this, since an appropriate exposure time can be set, it is possible to ensure the accuracy of color determination processing, marking determination processing, and counting processing based on the image captured by the camera unit 209 including the CMOS image sensor 232.

Further, even if dust or the like is attached to the lens of the camera unit 209 to some extent, the exposure time is extended instead of increasing the brightness of the LED 233 to suppress the life of the LED 233 and suppress the color determination process. It is possible to ensure the accuracy of the marking determination process and the counting process. Further, since the frequency of removing the dirt of the lens can be reduced, the work load of the employee in the game hall can be reduced.

<Eleventh action>
In the pachi-slot 1 of the present embodiment, when the determination result of the AE determination process is output from the ISP circuit 245 in the AE correction process, the host controller 241 notifies when the exposure time is set to the upper limit of 175 μsec. A signal for instructing lighting is output to the LED 206c for notification, and the LED 206c for notification is turned on. As a result, a person who views the notification LED 206c, for example, the manager of the game hall, can recognize that the camera unit 209 has some trouble (for example, dirt such as dust adheres to the lens). ..

Further, in the AE correction process, when the determination result of the AE determination process is output from the ISP circuit 245, when the exposure time is set to the upper limit of 175 μsec, the host controller 241 displays the medal on the main control board 71. Output an abnormal signal. When the medal abnormality signal is output, the main control board 71 (main control circuit 91) forcibly interrupts the game, displays an error code on the 7-segment display 24, and causes an error to the sub-control circuit 101. A command is transmitted to notify the error (for example, a predetermined error screen is displayed on the liquid crystal display device 11). As a result, it is possible to prevent the game from being performed in a state where the accuracy of the color determination process, the marking determination process, and the count process cannot be ensured, that is, the fraudulent activity cannot be effectively detected.

In the present embodiment, the mode in which the AE correction process is performed when the power of the pachi-slot 1 is turned on has been described, but the execution timing of the AT correction process can be set appropriately. For example, the AE correction process may be executed when the front door 2b is opened and the security signal output from the door opening/closing monitoring switch 67 is detected by the main control circuit 91. In addition, the AE correction process may be executed when a predetermined time has elapsed after the operation on the pachi-slot 1 is no longer detected. Further, the AE correction process may be executed every time a predetermined time, for example, one hour has passed.

Further, when the host controller 241 outputs a signal for instructing the notification LED 206c to turn on, and also outputs a medal abnormality signal to the main control board 71, the output PORT for this medal abnormality signal is used as the medal determination signal. It may be provided separately from the output PORT. By doing so, the main control board 71 can distinguish the medal abnormality signal output from the medal determination output PORT and the medal abnormality signal output from the separately provided output PORT.

As a result, when the medal abnormality signal is input from the output PORT provided separately from the medal determination output PORT, the main control board 71 changes the image data acquired by the CMOS image sensor 232 even if the exposure time is adjusted. It is possible to understand that the predetermined image is not included. Therefore, the main control board 71 transmits, for example, an error command to the sub-control circuit 101, and notifies the sub-control circuit 101 of a message prompting removal of dirt on the lens (for example, to the liquid crystal display device 11). You can display that fact). This can encourage employees in the game hall to remove dirt on the lens.

<Modification>
The gaming machine according to the embodiment of the present invention has been described above, including its function and effect. However, the game machine of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the present invention described in the claims. In the following description of the modified examples, description of the same or similar components as those in the above-described embodiment will be omitted, and the same reference numerals will be given in the drawings.

<Modification 1>
For example, you may use the medal selector 301 which provided the hole in the position corresponding to the determination area|region shown in FIGS.
The configuration of the medal selector 301 according to the first modification will be described with reference to FIG. FIG. 37 is a diagram for explaining the medal selector in the first modification. 37, the cancel shooter 206 of the medal selector 301 and the camera unit 209 (see FIG. 7) are not shown.

A medal rail 310 is formed in a base plate portion 304 of the medal selector 301 so as to be recessed forward of the pachi-slot 1 and in a substantially L-shape. Plural ridges 310 a are formed on the surface of the medal rail 310.

Further, in the medal rail 310, a determination area AB hole 310b having the same shape as the combined shape of the determination areas A1 to A4 and the determination areas B1 to B4 shown in FIGS. 22 to 24 is formed. Has been done. Similarly, a determination region C hole 310c having the same shape is formed at a position corresponding to the determination regions C1 and C2, and a determination region D310d hole having the same shape is formed at a position corresponding to the determination regions D1 to D4. .. Although illustration is omitted, the base plate portion 304 has a determination region F hole 310e formed at a position corresponding to the determination region F shown in FIGS.

Further, as shown in FIG. 37, the sub-plate 305 of the medal selector 301 has a judgment area F hole 305a formed at a position corresponding to the judgment area F shown in FIGS. The determination area F hole 305a formed in the sub plate 305 and the determination area F hole 310e formed in the base plate portion 304 communicate with each other in the front-rear direction.
The other points of the medal selector 301 are similar to those of the medal selector 201, and thus the description thereof will be omitted.

In this modification, holes (judgment area AB hole 310b, judgment area C hole 310c, judgment area D310d) are provided at corresponding positions of the judgment areas A1 to A4, B1 to B4, C1, C2, D1 to D4, and F, respectively. Holes and determination area F holes 310e, 305a) are provided. Therefore, the value of the luminance at the position corresponding to each determination region of the background grayscale image data (grayscale image data not including the image of the medal) used in the medal position detection processing performed by the medal counting circuit 246 is set to these values. The value is lower than that in the case where no hole is provided (because the light of the LED 233 for the light source passes through the hole and is not reflected by the CMOS image sensor 232.) Therefore, even if a medal having a brightness close to the surface of the medal rail 310 is used, the difference between the brightness in each determination area of the background grayscale image data and the brightness of the medal image in the grayscale image data to be processed is different. Can be calculated (for example, if the value of the brightness of the surface of the medal rail 310 is 50 and the value of the brightness of the hole is 22, the value of 28 is calculated as the difference). Therefore, in the medal position detection process, medals having a brightness close to the surface of the medal rail 310 (medals whose surface is processed in black, gray, or brown colors, or whose surface is deteriorated or dirty and whose light reflection is not sufficient) It is possible to accurately detect various medals including the above). Further, similarly, the accuracy of the medal edge detection processing performed by the medal counting circuit 246 can be improved. That is, in the present modification, the medal count circuit 246 that performs the medal position detection process constitutes an object presence/absence detection means.

In addition, you may provide the hole of the same shape in the position corresponding to the determination area E shown in FIGS. The other points of this modification are the same as those of the above-described embodiment, and thus the description thereof is omitted.

<Modification 2>
Next, a gaming machine of Modification 2 will be described with reference to FIGS. 38 and 39.
FIG. 38 is a block diagram showing a circuit configuration example of the medal selector in the gaming machine of the second modification. Further, FIG. 39 is a block diagram showing a circuit configuration example of a control LSI in the gaming machine of the modification 2.
In the following description of the gaming machine according to Modified Example 2, description of configurations and functions common to the pachi-slot 1 in the above-described embodiment will be omitted.

As shown in FIGS. 38 and 39, the control LSI 234 and the medal solenoid 208 in the medal selector 401 of the second modification are electrically connected. Therefore, the control LSI 234 can set the medal solenoid 208 to the ON state or the OFF state. Specifically, the control LSI 234 outputs a control signal for setting the medal solenoid 208 to the ON state or the OFF state to the medal solenoid 208 from the output PORT assigned to the GPIO 250 via the GPIO 250.

In the above-described embodiment, in the marking determination process, the host controller 241 of the control LSI 234 determines that the medal counting circuit 246 has determined that “the medal has passed” on the medal rail 210, and then the predetermined time before the determination. The mode in which the image recognition DSP circuit is instructed to perform the preprocessing using the reduced image data (that is, before the predetermined frame) has been described. That is, the mode has been described in which the control LSI 234 performs the marking determination processing afterwards on the medals that have already passed. However, the control LSI 234 in this modified example performs the same marking determination processing, but differs from the above-described embodiment in that the marking determination processing is performed on an object moving on the medal rail 210 in real time. In the following, description of the contents common to the medal selector 201 of the medal selector 401 will be omitted.

Specifically, when the fish-eye correction scaler circuit 248 creates reduced image data and stores it in the SRAM 243, the host controller 241 of the medal selector 401 according to the present modification applies to the stored reduced image data. The image recognition DSP circuit 242 and the image recognition accelerator circuit 249 are instructed to execute the processing after the circular area detection processing in the marking determination processing. If the circle area cannot be extracted in the circle area detection processing, the subsequent processing in the marking determination processing is omitted.

With this configuration, in this modification, the image recognition DSP circuit 242 is provided before the object moving on the medal rail 210 reaches the upper exposure hole 219 or the lower exposure hole 220 (see FIG. 8) of the medal rail 210. Can store the gradient average determination result and the HOG determination result in the SRAM 243 as the determination result of the marking determination process for this object. In addition, the host controller 241 acquires the slope average determination result and the HOG determination result as the determination result of the marking determination processing stored in the SRAM 243 in response to the marking determination end interrupt signal from the image recognition DSP circuit 242. You can

The host controller 241 that has acquired the gradient average determination result and the HOG determination result determines whether or not “NO” is stored as the acquired gradient average determination result or “NO” is stored as the HOG determination result. A control signal for setting the solenoid 208 to the OFF state is output to the medal solenoid 208. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 227 protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

In addition, the host controller 241 of the medal selector 401 in this modification obtains the latest determination result of the color determination processing stored in the SRAM 243 every time the color determination interrupt signal is input, and determines the color determination processing. According to the result, a control signal for setting the medal solenoid 208 to the ON state or the OFF state is output to the medal solenoid 208.

Therefore, in the present modification, before the object moving on the medal rail 210 reaches the upper exposure hole 219 or the lower exposure hole 220 (see FIG. 8) of the medal rail 210, the determination result of the color determination process for this object is obtained. The medal solenoid 208 can be set to an ON state or an OFF state according to the above.

Specifically, the host controller 241 stores the medal solenoid 208 in the case where “threshold judgment is impossible” is stored as the judgment result of the acquired threshold judgment processing or “no” is stored as the color judgment result. The medal solenoid 208 is output with a control signal for setting the OFF state. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 227 protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

On the other hand, when “threshold judgment not possible” is not stored as the judgment result of the threshold judgment processing and “possible” is stored as the color judgment result, and the acquired gradient average judgment result and HOG judgment result are “ When “OK” is stored, the host controller 241 keeps the medal solenoid 208 in the ON state. In this case, the object to be determined is guided to the hopper device 51.

The host controller 241 of the medal selector 401 in the modification example sets a control signal for setting the medal solenoid 208 to the ON state when the circle area cannot be detected in the circle area detection processing performed on the reduced image data stored in the SRAM 243. Is output to the medal solenoid 208. By doing so, when the next inserted object is a regular medal, this medal can be properly guided to the hopper device 51. That is, the medal solenoid 208 constitutes a driving means for arranging the select plate 207 at a guide position for guiding the regular medal to the hopper device 51 or at a discharge position for discharging the medal toward the cancel shooter 206, and the control LSI 234 is a medal solenoid. A drive control unit for controlling the drive of 208 is configured.

When a predetermined condition is satisfied, the host controller 241 of the medal selector 401 according to the present modification outputs a medal abnormality signal relating to the marking determination process and the color determination process to the door relay terminal board 68 from the medal determination output PORT of the GPIO 250. It outputs to the main control board 71 via. The predetermined output condition can be set as appropriate. For example, the SRAM 243 is provided with an area for storing the value of the number of times the medal solenoid 208 is set from the ON state to the OFF state based on the result of the marking determination process and the color determination process of this modification. In addition, the host controller 241 adds “1” to the value of this area each time the medal solenoid 208 is set from the ON state to the OFF state. Then, the host controller 241 outputs a medal abnormality signal to the main control board 71 when the stored value reaches a predetermined value, for example, “10”. That is, the host controller 241 of the control LSI 234 constitutes error notification means.

The value of the number of times stored in the area is cleared when the power is turned on or when an initialization switch (not shown) is pressed after the power is turned on. Also, it is cleared every time a predetermined time, for example, one hour elapses. The clearing condition can be set as appropriate.

In this modification, the main control circuit 91 (main control board 71) outputs a medal insertion signal to the medal selector at a predetermined cycle. Specifically, the main control circuit 91, when the pachi-slot 1 is not in a medal insertion permission state in which medals can be inserted, or when a medal abnormality signal is output from the medal selector 401, a medal insertion signal of content that cannot be inserted. Is output to the medal selector 401. In the medal abnormality signal output from the medal selector 401, the value of the number of times the medal solenoid 208 is set from the ON state to the OFF state is set to a predetermined value based on the results of the marking determination process and the color determination process described above. In addition to the medal abnormality signal that is output when the number of coins has reached, a medal abnormality signal based on the fact that the determination result related to the count process is "abnormality has occurred" is also included.

Here, when the pachi-slot 1 is not in the medal insertion permission state in which medals can be inserted, for example, after the start lever 23 is operated by the player in the unit game, the credit counter also has the maximum value (for example, 50). When.

When the main control circuit 91 outputs a medal insertion signal indicating that insertion is impossible, the host controller 241 of the medal selector 401 sets the medal solenoid 208 to the OFF state. That is, in the present modification, the host controller 241 determines whether the determination result of the color determination process is “threshold determination impossible” or “no”, the determination result of the marking determination process is “no”, and the main control When the circuit 91 outputs a medal insertion signal indicating that the medal cannot be inserted, the medal solenoid 208 is set to the OFF state. In addition, when the host controller 241 detects a medal insertion signal of the content that cannot be inserted based on the medal abnormality signal output when the result of the counting process is “an abnormality has occurred”, the medal solenoid 208 is turned off. Instead of setting, the host controller 241 may set the medal solenoid 208 to the OFF state at the time when the determination result of the counting process “abnormality has occurred” is output.

Further, when the pachi-slot 1 is in a medal insertion permission state in which medals can be inserted, and when the medal selector 401 does not output a medal abnormality signal, the main control circuit 91 outputs a medal insertion signal indicating the content of the insertion permission. It outputs to the medal selector 401. The host controller 241 sets the medal solenoid 208 to the ON state when the main control circuit 91 outputs a medal insertion signal indicating the insertion permission.

In the present modification, when the medal abnormality signal is output, the main control circuit 91 detects that some abnormality (medal clogging or the like) has occurred in the medal selector 401, or that the game machine is a regular game medium. It is detected that there is a fraudulent act of playing a game. Then, various processes are carried out when there is an illegal act. As various processing in the case of cheating, the main control circuit 91 forcibly interrupts the game, displays an error code on the 7-segment display 24, and sends an error command to the sub control circuit 101. , Through the sub-control circuit 101, informs that some abnormality has occurred in the medal selector 401, or that there is an illegal act (for example, the liquid crystal display device 11 displays that an abnormality or an illegal act has occurred. To).

Further, the main control circuit 91 maintains a game suspended state, that is, a game disabled state until an initialization switch (not shown) provided in the medal selector 401 is pressed. Further, it continues to output the medal insertion signal of the content that cannot be inserted to the medal selector 401. When the initialization switch is pressed to change from the OFF state to the ON state, the host controller 241 finishes outputting the medal abnormality signal to the main control circuit 91. When the output of the medal abnormality signal ends, the main control circuit 91 ends the various processes in the case of the above-mentioned misconduct, and restarts the game from the place where it was interrupted.
The other points of this modification are the same as those of the above-described embodiment, and thus the description thereof is omitted.

In the pachi-slot 1 of the present modified example, the marking determination process and the color determination process are performed in real time on an object passing on the medal rail 210, and the medal solenoid 208 is operated based on the result. Therefore, the object to be determined can be appropriately guided to the cancel shooter 206 or the hopper device 51 based on the result of the determination.

Further, the host controller 241 performs the main control of the medal abnormality signal when the value of the number of times the medal solenoid 208 is set from the ON state to the OFF state reaches “10” based on the result of the color determination process and the marking determination process. Output to the substrate 71. Then, when the medal abnormality signal is output, the main control circuit 91 (main control board 71) misidentifies that a regular game medium is used in the gaming machine, and detects that there is an illegal act of playing a game. Then, various processing is performed in the case of an illegal act including forcibly interrupting the game. As a result, when an unauthorized medal that is not a regular medal is frequently used for a short period of time (in this modification, the value of the number of times set from the ON state to the OFF state as described above is cleared every hour), The main control circuit 91 can detect that there has been an illegal act, and also can disable the game and prevent the continuation of the game accompanied by the illegal act.

If the value of the number of times the medal solenoid 208 is set from the ON state to the OFF state based on the results of the color determination process and the marking determination process has not reached “10”, the host controller 241 outputs the medal abnormality signal as a main signal. No output to the control board 71. Therefore, if the illegal medal is not frequently used for a short period of time, for example, if the player intentionally throws the mixed illegal medal into the pachi-slot 1, it becomes impossible to play. It is possible to prevent that.

<Modification 3>
Next, a gaming machine of Modification 3 will be described with reference to FIGS. 40, 41 and 42.
FIG. 40 is a block configuration diagram of the entire circuit included in the gaming machine of Modification 3. FIG. 41 is a block diagram showing an example of the circuit configuration of the medal selector in the gaming machine of Modification 3. In addition, FIG. 42 is a diagram for explaining the installation position of the double photo sensor of the medal selector in the gaming machine of Modification 3.
In the following description of the gaming machine according to Modification 3, description of configurations and functions common to those of the pachi-slot 1 according to the above-described embodiment will be omitted.

As shown in FIG. 40, unlike the medal selector 201 described above, the medal selector 501 is not only connected to the main control board 71 via the door relay terminal plate 68, but also via the sub relay board 61. , Is also connected to the sub control board 72.

As shown in FIG. 41, in the present modification, the medal solenoid 208 of the medal selector 501 is connected to the main control board 71 via the door relay terminal plate 68, similarly to the medal selector 201 described above. Therefore, the main control circuit 91 configured by the main control board 71 can set the medal solenoid 208 to the ON state or the OFF state.

Further, as shown in FIGS. 41 and 42, the medal selector 501 includes a double photo sensor 502 including a first photo sensor 503 and a second photo sensor 504 in addition to the constituent elements of the medal selector 201. .. The double photo sensor 502 is connected to the main control board 71 via the door relay terminal plate 68.

As shown in FIG. 42, the first photo sensor 503 is provided in the vicinity of the medal exit portion 204c of the base plate portion 204 of the medal selector 501. The first photosensor 503 has a photodiode (not shown) embedded on the medal rail 210 of the base plate portion 204, and a light emitter (not shown) for irradiating the photodiode with light (infrared light). .. The photodiode and the light emitter face each other with a thickness of the medal or more, and when the select plate 207 is at the guide position, the medal moving on the medal rail 210 can pass between the photodiode and the light emitter. Has become. Note that in FIG. 42, the sub-plate 205 and the cancel shooter 206 (see FIG. 8) of the medal selector 501 are not shown.

The light emitter always emits a predetermined amount of light. When the photodiode receives a predetermined amount of light or more from the light emitter, the first photo sensor 503 outputs a high level signal. On the other hand, when the amount of light received by the photodiode becomes less than the predetermined amount of light, the first photosensor 503 outputs a low level signal (medal detection signal). Therefore, when the light of the light emitter is blocked when the medal passes between the photodiode and the light emitter, the first photosensor 503 outputs the medal detection signal.

The second photo sensor 504 moves on the medal rail 210 in the vicinity of the medal exit portion 204c of the base plate portion 204 of the medal selector 501 and in the vicinity of the first photo sensor 503, rather than the first photo sensor 503. It is provided on the downstream side in the moving direction of the medal. Since the other points are the same as those of the first photo sensor 503, description thereof will be omitted.

As described above, the first photo sensor 503 is provided near the medal exit portion 204c, and the second photo sensor 504 is provided downstream of the first photo sensor 503 on the medal rail 210. Therefore, in the first photo sensor 503 and the second photo sensor 504, the select plate 207 is at the guide position and the medals moving toward the medal exit portion 204c (see FIG. 8) are detected, but the select plate 207 is at the ejection position. Therefore, medals guided by the medal chute 202 (see FIG. 6) are not detected.

In this modification, the medal detection signals output from the first photo sensor 503 and the second photo sensor 504 are input to the main control board 71 (main control circuit 91) via the door relay terminal plate 68. The main CPU 93 (see FIG. 15) of the main control board 71 detects the medal detection signal input from the first photo sensor 503 and then outputs the medal detection signal input from the second photo sensor 504 within a predetermined time. If detected, the main CPU 93 adds 1 to the value of the inserted number counter, which is a counter provided for counting the number of inserted medals. In addition, when the value of the inserted number counter is the maximum value (for example, 3), 1 is added to the value of the credit counter which is a counter provided for the main CPU 93 to count the number of credited medals.

When the credit counter has the maximum value (for example, 50), the main control circuit 91 sets the medal solenoid 208 of the medal selector 501 to the OFF state. As a result, the select plate 207 (see FIG. 8) is positioned at the “discharging position”, the medals cannot be inserted, and the medals inserted after the credit counter reaches the maximum value are transferred to the medal chute 202 (see FIG. 6). It guides and discharges to the medal tray unit 34 from the medal payout opening 32 (refer FIG. 2).

The main control circuit 91 sets the medal solenoid 208 of the medal selector 501 to the OFF state even after the start lever 23 is operated by the player in the unit game.

When the main CPU 93 receives the medal detection signal in the order of the medal detection signal input from the second photo sensor 504 and the medal detection signal input from the first photo sensor 503, the medals are placed on the medal rail 210. It is detected that a so-called retrograde error occurs, which is a movement direction that is different (reverse) from the proper movement direction.

Further, even after the main CPU 93 detects a medal detection signal for a predetermined time, one or both of the first photo sensor 503 and the second photo sensor 504 continue to output the medal detection signal. In this case, if the medal detection signal from the second photo sensor 504 cannot be detected even after a certain time has elapsed after the medal detection signal from the first photo sensor 503 was detected, the medals remain on the medal rail 210, so-called. Detects that a medal jam error has occurred.

When the main control circuit 91 (main CPU 93) detects a retrograde error or a medal clogging error, the game is forcibly interrupted, and an error code corresponding to the content of the detected error is displayed on the 7-segment display 24 (see FIG. 2). Is displayed, an error command corresponding to the content of the detected error is transmitted to the sub control circuit 101, and the error is notified via the sub control circuit 101. For example, when an error screen showing the content of an error is displayed on the liquid crystal display device 11 or a sub 7-segment display device (not shown) for controlling the display by the sub-control circuit 101 is provided, the sub 7-segment display device has a predetermined size. Is displayed.

As shown in FIG. 41, the control LSI 234 of the camera unit 209 in the medal selector 501 is connected to the sub control board 72 via the sub relay board 61. Therefore, in this modification, various signals output from the host controller 241 of the control LSI 234, that is, the medal count signal and the medal abnormality signal, can be detected by the sub control circuit 101 (of which the sub CPU 102 is). Has become.

When the sub-control circuit 101 detects the medal count signal or the medal abnormality signal, the sub-control circuit 101 stores the detection date and time and the detection content in the backup area of the sub RAM 103. Information related to the medal abnormality signal stored in the sub RAM 103 is displayed on the liquid crystal display device 11 by operating a setting key type switch 56 (see FIG. 6) by a game machine manager (for example, a game hall employee). When the error history menu is selected on the displayed hole menu screen (not shown), it can be referred to.

When the setting key type switch 56 is operated, the main CPU 93 outputs a predetermined command, and when the sub CPU 102 detects the predetermined command, the hall menu screen is displayed on the liquid crystal display device 11. On the hall menu screen, various selectable menus, date/time setting change menus and error history menus are displayed by operating the select button and enter button (not shown) provided on the pedestal portion 12 (see FIG. 2). When the error history menu is selected, the sub control circuit 101 causes the liquid crystal display device 11 to display the detection date and time and the detection content of the medal count signal and the medal abnormality signal stored in the sub RAM 103. For example, the liquid crystal display device 11 displays “11:10:20 on Jan. 09, 2016, medal abnormality signal”.

In addition, as described above, the medal abnormality signal based on the determination result of the color determination process, the medal abnormality signal based on the determination result of the marking determination process, the medal abnormality signal based on the AE correction process, and the determination result of the count process are “abnormal. When the output PORT is separately provided for each of the medal abnormality signals based on "Yes", for example, "color determination abnormality at 11:10:20 on January 01, 2016", "January 01, 2016" "12:00:05: Stamp judgment error", "January 02, 2016 10:01:05 AE correction error", "January 02, 2016 11:11:05: Count processing error" To be done. That is, the information relating to the medal abnormality signal stored in the sub RAM 103 is displayed in a manner that the date and time when the medal abnormality signal is output and the cause of the medal abnormality signal can be confirmed.

When a sub 7-segment indicator (not shown) for controlling the display by the sub-control circuit 101 is provided, when the sub-control circuit 101 detects a medal abnormality signal, the sub-segment 7 indicator displays a predetermined display (for example, "CC") is displayed. In addition, as described above, the medal abnormality signal based on the determination result of the color determination process, the medal abnormality signal based on the determination result of the marking determination process, the medal abnormality signal based on the AE correction process, and the determination result of the count process are “abnormal. If a separate output PORT is provided for each of the medal abnormality signals based on "Yes", a medal abnormality signal has been output to this sub 7-segment display, or a medal abnormality signal has been output. Characters or symbols that can confirm the cause (for example, "CE" when a medal abnormality signal based on the determination result of the color determination processing is detected, and "KE" when a medal abnormality signal based on the determination result of the marking determination processing is detected. ) May be displayed.

In this modification, the main control circuit 91 turns on the medal solenoid 208 of the medal selector 501 when the credit counter has the maximum value (for example, 50) or after the start lever 23 is operated by the player in the unit game. Set to OFF state.

When the weight of the inserted medal is different from the weight of the regular medal (lighter than the regular medal), the medal pushes the medal pressure 213 (see FIG. 8) in front of the pachi-slot 1 to move the medal. However, since the medal is sandwiched between the select plate 207 and the medal pressure 213 at the guide position, it is possible to prevent an illegal act using a medal having a weight different from that of the regular medal. Further, when the outer diameter of the medal is different from the outer diameter of the regular medal, for example, when the outer diameter of the medal is smaller than that of the regular medal, even if the select plate 207 is at the guide position, the medal is not guided to the select plate 207 and the medal pressure 213 is displayed. Since it is pushed out and discharged toward the cancel shooter 206, it is possible to prevent illegal acts using a medal having an outer diameter different from that of the regular medal.

In addition, by selecting the error history menu on the hole menu screen as described above, it is possible to confirm that an illegal act using medals that differ only in color and engraving (pattern) from the regular medal is performed. It can be understood by checking the display on the display.

Here, even if a regular medal is inserted, it is possible that the medal selector 501 outputs a medal abnormality signal if the regular medal is dirty or if the marking or color has changed due to wear due to use. In this case, if the game is forcibly stopped as a result of the output of the medal abnormality signal, the player will have to stop playing the game even though he/she has inserted the regular medal. May be given. In the present modification, even if the sub control circuit 101 detects a medal abnormality signal, the main control circuit 91 does not stop the game, so that it is possible to prevent the player from feeling uncomfortable.

Further, as described above, based on the signal output from the double photo sensor 502, when the main control circuit 91 detects a backward error or a medal clogging error, the main control circuit 91 forcibly interrupts the game. Therefore, it is possible to prevent a fraudulent act using a fraudulent device.

Here, in the present modification, as described above, after the main CPU 93 (see FIG. 15) of the main control board 71 (main control circuit 91) detects the medal detection signal input from the first photo sensor 503. When a medal detection signal input from the second photo sensor 504 is detected within a predetermined time, the main CPU 93 counts the number of inserted medals by 1 and adds 1 to the value of the inserted number counter. To do. When the value of the inserted number counter is the maximum value (for example, 3), 1 is added to the value of the credit counter, which is a counter provided for the main CPU 93 to count the number of credited medals. In addition to this, the sub-control circuit 101, based on the medal count signal output from the medal selector 501, in addition to the insertion number counter and the credit counter, on the sub RAM 103, the insertion number and the number of credited medals. May be managed.

Further, similarly to the medal selector 401 of the modified example 2 described above, the marking determination process may be performed on the object moving on the medal rail 210 in real time.
Since the other points of the medal selector 501 are the same as those of the medal selector 201, description thereof will be omitted.

<Modification 4>
Next, a gaming machine of Modification 4 will be described with reference to FIG.
FIG. 43 is a block diagram showing a circuit configuration example of the medal selector in the gaming machine of Modification 4.
In the following description of the gaming machine according to Modification 4, description of configurations and functions common to the pachi-slot 1 in the above-described embodiment will be omitted.

As shown in FIG. 43, in the medal selector 601 of the present modification, the control LSI 234 and the medal solenoid 208 are electrically connected, as in the medal selector 401 of the second modification described above. Therefore, the control LSI 234 can set the medal solenoid 208 to the ON state or the OFF state.
Further, the control LSI 234 in the present modified example performs the marking determination process for the object moving on the medal rail 210 in real time, similarly to the control LSI 234 in the modified example 2 described above.

That is, in this modified example, as in the modified example 2, before the object moving on the medal rail 210 reaches the upper exposed hole 219 or the lower exposed hole 220 of the medal rail 210, the image recognition DSP circuit 242 of the control LSI 234. Causes the SRAM 243 to store the gradient average determination result and the HOG determination result as the determination result of the marking determination process for this object. Further, the host controller 241 of the control LSI 234, in response to the marking determination end interrupt signal from the image recognition DSP circuit 242, outputs the gradient average determination result and the HOG determination result as the determination result of the marking determination processing stored in the SRAM 243. get.

The host controller 241 that has acquired the gradient average determination result and the HOG determination result determines whether or not “NO” is stored as the acquired gradient average determination result or “NO” is stored as the HOG determination result. A control signal for setting the solenoid 208 to the OFF state is output to the medal solenoid 208. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 227 protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

In addition, the host controller 241 acquires the determination result of the latest color determination processing stored in the SRAM 243 each time the color determination interrupt signal is input, and according to the determination result of the color determination processing, the medal solenoid 208. A control signal for setting the ON state or the OFF state is output to the medal solenoid 208.

Therefore, before the object moving on the medal rail 210 reaches the upper exposed hole 219 or the lower exposed hole 220 (see FIG. 8) of the medal rail 210, the medal is determined according to the determination result of the color determination process on the object. The solenoid 208 can be set to an ON state or an OFF state.

Specifically, the host controller 241 stores the medal solenoid 208 in the case where “threshold judgment is impossible” is stored as the judgment result of the acquired threshold judgment processing or “no” is stored as the color judgment result. The medal solenoid 208 is output with a control signal for setting the OFF state. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 227 protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

Further, when the determination result related to the latest count processing stored in the SRAM 243 is “abnormality has occurred”, the host controller 241 outputs a control signal for setting the medal solenoid 208 to the OFF state to the medal solenoid 208. To do.

On the other hand, the determination result related to the latest count process stored in the SRAM 243 is not "abnormality has occurred", "threshold determination not possible" is not stored as the determination result of the threshold determination process, and the color determination result is " When “OK” is stored and when “OK” is stored as the acquired gradient average determination result and HOG determination result, the host controller 241 maintains the state of the medal solenoid 208 in the ON state. To do so. In this case, the object to be determined is guided to the hopper device 51.

Also, the host controller 241 of the medal selector 601 in the present modification sets the medal solenoid 208 to the ON state when the circle area cannot be detected in the circle area detection processing performed on the reduced image data stored in the SRAM 243. A control signal to perform the output is output to the medal solenoid 208.

As shown in FIG. 43, the medal selector 601 includes a double photo sensor 502 including a first photo sensor 503 and a second photo sensor 504. The double photo sensor 502 is connected to the main control board 71 via the door relay terminal plate 68. It should be noted that the main control circuit 91 based on the configuration and function of the double photo sensor 502 of the present modification and the medal detection signal output from (the first photo sensor 503 and the second photo sensor 504 of) the double photo sensor 502. The mode of managing the values of the inserted number counter and the credit counter is the same as that of the modified example 3, and therefore the description thereof is omitted here.

As shown in FIG. 43, the control LSI 234 of the camera unit 209 in the medal selector 601 is connected to the sub control board 72 via the sub relay board 61. Therefore, in this modification, various signals output from the host controller 241 in the control LSI 234 of the medal selector 601, that is, the medal count signal and the medal abnormality signal, are transmitted to the sub-control circuit 101 (which is a sub-control circuit of the sub-control board 72). The CPU 102) can be detected.

When the medal count signal or the medal abnormality signal is detected, the sub control circuit 101 configured by the sub control board 72 stores the detection date and time and the detected content in the backup area of the sub RAM 103. Information related to the medal abnormality signal stored in the sub RAM 103 is displayed on the liquid crystal display device 11 by operating a setting key type switch 56 (see FIG. 6) by a game machine manager (for example, a game hall employee). When the error history menu is selected on the displayed hole menu screen (not shown), it can be referred to. The operation for selecting the error history menu and the display mode of the information related to the medal abnormality signal stored in the sub RAM 103 in the error history menu are the same as those in the modified example 3, and therefore the description thereof is omitted here.

When the pachi-slot 1 is not in the medal insertion permitted state in which the pachi-slot 1 can insert medals, for example, after the start lever 23 is operated by the player in the unit game, the main control circuit 91 configured by the main control board 71 in the present modification example Further, when the credit counter has the maximum value, a medal insertion command indicating that the medal insertion is impossible is transmitted to the sub-control circuit 101 configured by the sub-control board 72. When the pachi-slot 1 is in the medal insertion permission state in which medals can be inserted, a medal insertion command having the content of insertion permission is transmitted to the sub-control circuit 101.

The sub control circuit 101 receives the medal insertion command transmitted from the main control circuit 91 via the door relay terminal board 68 and the sub relay board 61. Upon receiving the medal insertion command, the sub control circuit 101 outputs a sub medal insertion signal having the same content as the received medal insertion command. The sub-medal insertion signal is detected by the control LSI 234 of the medal selector 601 via the sub-relay board 61.

When the sub-medal insertion signal of the content that cannot be inserted is output from the sub-control circuit 101, the host controller 241 of the control LSI 234 sets the medal solenoid 208 to the OFF state. That is, in the present modification, the host controller 241 determines whether the latest count processing result is “abnormal”, the color determination processing result is “threshold determination not possible” or “no”, and the marking When the determination result of the determination process is “NO” and when the secondary medal insertion signal output from the secondary control circuit 101 indicating the content that cannot be inserted is detected, the medal solenoid 208 is set to the OFF state.

Further, similar to the modified example 3, the main control circuit 91 detects a retrograde error or a medal clogging error based on the medal detection signal output from the double photo sensor 502, and when these errors are detected, Force the game to end.
Since these errors can be detected by the medal selector 601 (count processing by the control LSI 234, etc.), the processing relating to the detection of the retrograde error and the medal clogging error by the main control circuit 91 may be omitted. When omitted, when a retrograde error or a medal clogging error occurs, a signal indicating that (a medal abnormality signal based on the determination result of the count result "abnormality has occurred" is detected) is output to the sub control circuit 101. When this signal is detected, the main control circuit 91 detects the occurrence of a backward error or a medal clogging error and forcibly ends the game.
Since the other points of the medal selector 601 are the same as those of the medal selector 401 described in the second modification, description thereof will be omitted.

In this modified example, when the pachi-slot 1 is not in the above-mentioned medal insertion permission state, the main control circuit 91 transmits a medal insertion command having contents that cannot be inserted, and the sub-control circuit 101 which has received the medal insertion command has the same contents. Outputs the secondary medal insertion signal. When the control LSI 234 of the medal selector 601 detects a sub-medal insertion signal indicating that the medal cannot be inserted, the medal solenoid 208 is turned off and the medal is ejected toward the cancel shooter 206. Even in the medal insertion permitted state, the control LSI 234 of the medal selector 601 determines that the determination result of the color determination process is “threshold determination not possible” or “no” when the determination result of the count process is “abnormal”. In the case of, or when the result of the marking determination process is “NO”, the medal solenoid 208 is set to the OFF state and the medal is ejected toward the cancel shooter 206. Therefore, the inserted medals can be properly counted. Further, the inserted medals can be appropriately guided to the cancel shooter 206 or the hopper device 51.

<Modification 5>
Next, a gaming machine of Modification 5 will be described with reference to FIGS. 44 and 45.
FIG. 44 is a rear view of the medal selector in the gaming machine of Modification 5. Note that in FIG. 44, the sub-plate 205, the cancel shooter 206, and the reference marker 260 of the medal selector 701 are omitted.
Further, FIG. 45 is a block diagram showing a circuit configuration example of the medal selector in the gaming machine of the modification 5.
In the following description of the gaming machine according to Modification Example 5, description of configurations and functions common to those of the pachi-slot 1 according to the above-described embodiment will be omitted.

As shown in FIG. 44, the medal selector 701 of this modified example includes two select plates, a select plate 707a and a select plate 707b. Further, as shown in FIG. 45, the medal selector 701 includes two medal solenoids, a first medal solenoid 708a and a second medal solenoid 708b. The first medal solenoid 708a and the second medal solenoid 708b include a solenoid body (not shown) and a movable plate (not shown) similar to the medal solenoid 208 (see FIG. 9).

As shown in FIG. 44, the select plate 707a includes a plate-shaped plate body 724a and a pair of bearing portions (not formed by bending both end portions of the plate body 724a in the left-right direction toward the front of the pachi-slot 1). (Shown), and. A flange portion 726a formed by bending the pachi-slot 1 forward and bending the rear end upward is formed on the upper portion of the plate body 724a.

The select plate 707a is rotatably supported by a shaft portion (not shown) provided on the front surface 204a of the base plate portion 204. The shaft portion is provided with a coil spring, and urges the flange portion 726a toward the front of the pachi-slot 1. The flange portion 726a is in contact with one end of the movable plate portion of the first medal solenoid 708a. When the first medal solenoid 708a is in the ON state, the flange portion 726a is pressed by one end of the movable plate portion of the first medal solenoid 708a and moves rearward of the pachi-slot 1 against the biasing force of the coil spring. The rotating position of the select plate 707a at this time is referred to as a "guide position". The distance between the plate main body 724a of the select plate 707a in the guide position and the medal rail 210 is set to a predetermined distance that allows the medal exit portion 204c (see FIG. 8) to be guided without ejecting the medal to the cancel shooter 206 side. Has been done.

Further, when the first medal solenoid 708a is in the OFF state, the flange portion 726a is released from the pressure of the first medal solenoid 708a and moves to the front of the pachi-slot 1 by the biasing force of the coil spring. The rotating position of the select plate 707a at this time is referred to as a "discharging position". The distance between the plate body 724a of the select plate 707a at the ejection position and the medal rail 210 is set to be longer than a predetermined distance.

When the medal moving on the medal rail 210 meets the standard size, the select plate 707a in the guide position comes into contact with the upper part of the moving medal, and moves the medal to the medal exit portion 204c (see FIG. 8) side (the right side in FIG. 44). ) To guide you. The medal pushes the medal pressure 213 toward the front of the pachi-slot 1 when being guided by the select plate 707a.

On the other hand, since the distance between the plate body 724a and the medal rail 210 is large, even if the medal moving on the medal rail 210 satisfies the standard size, the select plate 707a at the ejection position ejects the medal from the medal exit. It cannot be guided to the portion 204c (see FIG. 8). Further, the medal is pushed out by the medal pressure 213 and is ejected toward the cancel shooter 206 (see FIG. 7).

Further, when the medal moving on the medal rail 210 has a diameter smaller than the standard size, even if the select plate 707a is at the guide position, the medal is not guided to the select plate 707a and is pushed out by the medal pressure 213 to cancel the shooter 206. Is discharged toward.

As shown in FIG. 44, the select plate 707b is provided downstream of the select plate 707a in the direction in which the medals move on the medal rail 210. The select plate 707b has a plate-shaped plate body 724b, and a pair of bearing portions (not shown) formed by bending the left and right ends of the plate body 724b toward the front of the pachi-slot 1. ing. A flange portion 726b formed by bending the pachi-slot 1 forward and bending the rear end upward is formed on the upper portion of the plate body 724b. Further, a medal stopper portion 727b extending downward is formed on one bearing portion.

The select plate 707b is rotatably supported by a shaft portion (not shown) provided on the front surface 204a of the base plate portion 204. The shaft portion is provided with a coil spring, and urges the flange portion 726b forward of the pachi-slot 1. The flange portion 726b is in contact with one end of the movable plate portion of the second medal solenoid 708b. When the second medal solenoid 708b is in the ON state, the flange portion 726a is pressed by one end of the movable plate portion of the second medal solenoid 708b and moves rearward of the pachi-slot 1 against the biasing force of the coil spring. The rotating position of the select plate 707b at this time is referred to as a "guide position". The distance between the plate main body 724b of the select plate 707b in the guide position and the medal rail 210 is set to a predetermined distance that allows the medal exit portion 204c to be guided without ejecting the medal to the cancel shooter 206 side. At this time, the medal stopper portion 727b does not protrude from the lower exposed hole 220.

Further, when the second medal solenoid 708b is in the OFF state, the flange portion 726b is released from the pressure of the second medal solenoid 708b, and moves to the front of the pachi-slot 1 by the biasing force of the coil spring. The rotating position of the select plate 707b at this time is referred to as a "discharging position". The distance between the plate body 724b of the select plate 707b at the ejection position and the medal rail 210 is set to be longer than a predetermined distance. At this time, the flange portion 726b moving forward of the pachi-slot 1 is pressed, and one end of the movable plate portion of the second medal solenoid 708b moves forward of the pachi-slot 1. Along with this, the other end of the movable plate portion of the second medal solenoid 708b moves to the rear of the pachi-slot 1 and presses the front end of the after medal pressure 218 (see FIG. 8). As a result, the after medal pressure 218 is rotated, and the rear end of the after medal pressure 218 is exposed from the upper exposure hole 219. Further, the medal stopper portion 727b projects from the lower exposed hole 220.

When the medal moving on the medal rail 210 meets the standard size, the select plate 707b at the guide position contacts the upper part of the moving medal and moves the medal to the medal exit portion 204c (see FIG. 8) side (the right side of FIG. 44). ) To.

On the other hand, since the distance between the plate body 724b and the medal rail 210 is large, the select plate 707b at the ejecting position does not eject the medal even if the medal moving on the medal rail 210 satisfies the standard size. It cannot be guided to the side of the portion 204c (see FIG. 8). Further, the medal is pushed out to the after medal pressure 218 protruding from the upper exposed hole 219 or the medal stopper portion 727 b protruding from the lower exposed hole 220, and is ejected toward the cancel shooter 206.

As shown in FIG. 45, the medal selector 701 includes a double photo sensor 502 including a first photo sensor 503 and a second photo sensor 504. The double photo sensor 502 is connected to the main control board 71 via the door relay terminal plate 68.

As in the third modification, the first photo sensor 503 of the double photo sensor 502 is provided near the medal exit portion 204c (see FIG. 8), and the second photo sensor 504 is more medal rail than the first photo sensor 503. 210 is provided downstream. Therefore, the first photo sensor 503 and the second photo sensor 504 have the select plate 707b at the guide position and detect the medals moving toward the medal exit portion 204c (see FIG. 8), but do not operate the select plate 707a or the select plate. Since 707b is at the ejection position, the medal guided by the medal chute 202 (see FIG. 6) is not detected.
In addition, other configurations and functions of the double photo sensor 502 of the present modification, and a main control circuit based on the medal detection signal output from (the first photo sensor 503 and the second photo sensor 504 of) the double photo sensor 502. The manner of managing the values of the inserted number counter and the credit counter in 91 is the same as that in the third modification, and therefore the description thereof is omitted here.

Further, the first medal solenoid 708 a is connected to the main control board 71 via the door relay terminal board 68. Therefore, the main control circuit 91 including the main control board 71 can set the first medal solenoid 708a to the ON state or the OFF state.

When the pachi-slot 1 is not in the medal insertion permission state in which the pachi-slot 1 can insert medals, for example, after the start lever 23 is operated by the player in the unit game, and when the credit counter is at the maximum value, The first medal solenoid 708a is set to the OFF state. Further, when the pachi-slot 1 is in the medal insertion permission state in which medals can be inserted, the first medal solenoid 708a is set to the ON state.

Further, as shown in FIG. 45, the control LSI 234 in the medal selector 701 and the second medal solenoid 708b are electrically connected. Therefore, the control LSI 234 can set the second medal solenoid 708b to the ON state or the OFF state.
Further, the control LSI 234 in the present modified example performs the marking determination process and the color determination process on the object moving on the medal rail 210 in real time, similarly to the control LSI 234 of the medal selector 401 in the second modified example described above.

That is, in this modified example, as in the modified example 2, before the object moving on the medal rail 210 reaches the upper exposed hole 219 or the lower exposed hole 220 of the medal rail 210, the image recognition DSP circuit 242 of the control LSI 234. Causes the SRAM 243 to store the gradient average determination result and the HOG determination result as the determination result of the marking determination process for this object. Further, the host controller 241 of the control LSI 234, in response to the marking determination end interrupt signal from the image recognition DSP circuit 242, outputs the gradient average determination result and the HOG determination result as the determination result of the marking determination processing stored in the SRAM 243. get.

When the host controller 241 that has acquired the gradient average determination result and the HOG determination result stores “NO” as the obtained gradient average determination result or “NO” as the HOG determination result, A control signal for setting the second medal solenoid 708b to the OFF state is output to the second medal solenoid 708b. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 727b protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

Further, the host controller 241 acquires the determination result of the latest color determination processing stored in the SRAM 243 each time the color determination interrupt signal is input, and according to the determination result of the color determination processing, the second medal. A control signal for setting the solenoid 708b to the ON state or the OFF state is output to the second medal solenoid 708b.

Therefore, before the object moving on the medal rail 210 reaches the upper exposure hole 219 or the lower exposure hole 220 of the medal rail 210, the second medal solenoid 708b is turned on according to the determination result of the color determination process for this object. It can be set to an ON state or an OFF state.

Specifically, when the host controller 241 stores “threshold judgment impossible” as the acquired judgment result of the threshold judgment processing or stores “no” as the color judgment result, the second medal. A control signal for setting the solenoid 708b to the OFF state is output to the second medal solenoid 708b. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 727b protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

In addition, when the determination result related to the latest counting process stored in the SRAM 243 is “abnormality has occurred”, the host controller 241 sends a control signal for setting the second medal solenoid 708b to the OFF state to the second medal. Output to the solenoid 708b.

On the other hand, the determination result related to the latest count process is not "abnormality has occurred", "threshold determination not possible" is not stored as the determination result of the threshold determination process, and "permitted" is stored as the color determination result. If “Yes” is stored as the obtained gradient average determination result and HOG determination result, the host controller 241 keeps the state of the second medal solenoid 708b in the ON state. .. In this case, the object to be determined is guided to the hopper device 51.

Further, the host controller 241 of the medal selector 701 in the modified example turns on the second medal solenoid 708b when the circle area cannot be detected in the circle area detection processing performed on the reduced image data stored in the SRAM 243. The control signal to be set is output to the second medal solenoid 708b.

As shown in FIG. 45, the control LSI 234 of the camera unit 209 in the medal selector 701 is connected to the sub control board 72 via the sub relay board 61. Therefore, in the present modification, various signals output from the host controller 241 in the control LSI 234 of the medal selector 701, that is, the medal count signal and the medal abnormality signal, are sub-control circuits of The CPU 102) can be detected.
Further, the sub control circuit 101 can set the second medal solenoid 708b to the ON state or the OFF state via the host controller 241 in the control LSI 234 of the medal selector 701. Specifically, when the sub-control circuit 101 detects the medal count signal output from the host controller 241 of the medal selector 701, the sub-control circuit 101 adds 1 to the value of the insertion number counter provided in the sub RAM 103. In addition, when the value of the insertion number counter of the sub RAM 103 is the maximum value (for example, 3), the value of the credit counter which is a counter provided in the sub RAM 103 for the sub CPU 102 to count the number of credited medals. Add 1 to. The sub-control circuit 101, after the start lever 23 is operated by the player in the unit game (when a start command is received), and when the credit counter of the sub RAM 103 is at the maximum value (for example, 50), the second The medal solenoid 708b is turned off via the host controller 241 of the medal selector 701. Further, when the pachi-slot is in the medal insertion permission state in which medals can be inserted, the second medal solenoid 708b is set to the ON state via the host controller 241.

When the medal count signal or the medal abnormality signal is detected, the sub control circuit 101 configured by the sub control board 72 stores the detection date and time and the detected content in the backup area of the sub RAM 103. Information related to the medal abnormality signal stored in the sub RAM 103 is displayed on the liquid crystal display device 11 by operating a setting key type switch 56 (see FIG. 6) by a game machine manager (for example, a game hall employee). When the error history menu is selected on the displayed hole menu screen (not shown), it can be referred to. The operation for selecting the error history menu and the display mode of the information related to the medal abnormality signal stored in the sub RAM 103 in the error history menu are the same as those in the modified example 3, and therefore the description thereof is omitted here.

Further, similar to the modified example 3, the main control circuit 91 detects a retrograde error or a medal clogging error based on the medal detection signal output from the double photo sensor 502, and when these errors are detected, Force the game to end. Further, the main control circuit 91 transmits an error command according to the content of the detected error to the sub control circuit 101.
When the sub control circuit 101 receives an error command related to a backward error or a medal clogging error from the main control circuit 91, it turns off the second medal solenoid 708b via the host controller 241 in the control LSI 234 of the medal selector 701. Set to state.
Since these errors can be detected by the medal selector 701 (count processing by the control LSI 234, etc.), the processing relating to the detection of the retrograde error and the medal clogging error by the main control circuit 91 may be omitted. When omitted, when a retrograde error or a medal clogging error occurs, a signal indicating that (a medal abnormality signal based on the determination result of the count result "abnormality has occurred" is detected) is output to the sub control circuit 101. When this signal is detected, the main control circuit 91 detects the occurrence of a backward error or a medal clogging error and forcibly ends the game.

In the present modification, when the pachi-slot 1 is not in the medal insertion permission state described above, the main control circuit 91 sets the first medal solenoid 708a to the OFF state and ejects the medals toward the cancel shooter 206. Even if the first medal solenoid 708a is in the ON state, the control LSI 234 of the medal selector 701 determines that the determination result of the color determination process is "threshold determination not possible" when the determination result of the count process is "abnormal". Alternatively, when the result is "No" or the result of the marking determination process is "No", the second medal solenoid 708b is set to the OFF state and the medals are ejected toward the cancel shooter 206. Therefore, the inserted medals can be properly counted. Further, the inserted medals can be appropriately guided to the cancel shooter 206 or the hopper device 51.

<Modification 6>
Next, a gaming machine of Modification 6 will be described with reference to FIG.
FIG. 46 is a block diagram showing a circuit configuration example of the medal selector in the gaming machine of the modification 6.
In the following description of the gaming machine according to Modification 6, description of configurations and functions common to those of the pachi-slot 1 according to the above-described embodiment will be omitted.

The medal selector 801 according to the present modification includes two select plates, a select plate 707a and a select plate 707b, similarly to the medal selector 701 according to the fifth modification (see FIG. 44).

Further, as shown in FIG. 46, the second medal solenoid 708 b in the medal selector 801 and the sub control board 72 are electrically connected via the sub relay board 61. Therefore, the sub control circuit 101 configured by the sub control board 72 can set the second medal solenoid 708b to the ON state or the OFF state. On the other hand, the control LSI 234 and the second medal solenoid 708b are not electrically connected. This point is the difference from Modification 5. Hereinafter, this difference will be described, and description of points common to the modified example 5 will be omitted.

As shown in FIG. 46, similarly to the modification 5, the control LSI 234 of the camera unit 209 in the medal selector 801 is connected to the sub control board 72 via the sub relay board 61. Therefore, in this modification, the sub-control circuit 101 (of which is the sub CPU 102) configured by the sub control board 72 detects various signals output from the host controller 241 of the control LSI 234, that is, the medal count signal and the medal abnormal signal. It is possible.

In this modification, similarly to the medal selector 401 of the modification 2, before the object moving on the medal rail 210 reaches the upper exposure hole 219 or the lower exposure hole 220 of the medal rail 210, the image recognition DSP of the control LSI 234. The circuit 242 causes the SRAM 243 to store the gradient average determination result and the HOG determination result as the determination result of the marking determination process for this object. Further, the host controller 241 of the control LSI 234, in response to the marking determination end interrupt signal from the image recognition DSP circuit 242, outputs the gradient average determination result and the HOG determination result as the determination result of the marking determination processing stored in the SRAM 243. get.

The host controller 241 that has acquired the gradient average determination result and the HOG determination result determines whether or not “NO” is stored as the acquired gradient average determination result or “NO” is stored as the HOG determination result. Output an abnormal signal.

In addition, the host controller 241 acquires the determination result of the latest color determination processing stored in the SRAM 243 each time the color determination interrupt signal is input, and the acquired determination result of the threshold determination processing is “threshold determination not possible. If “” is stored, or if “no” is stored as the color determination result, the medal abnormality signal is output.

Further, the host controller 241 outputs a medal abnormality signal when the determination result related to the latest count processing stored in the SRAM 243 is “an abnormality has occurred”.

When the sub control circuit 101 (sub CPU 102 of the sub control circuit) detects a medal abnormality signal output from the host controller 241 of the control LSI 234 or receives an error command related to a retrograde error or a medal clogging error from the main control circuit 91, A control signal for setting the second medal solenoid 708b to the OFF state is output to the second medal solenoid 708b. In this case, the object to be determined can be pushed out to the after medal pressure 218 protruding from the upper exposure hole 219 or the medal stopper portion 727b protruding from the lower exposure hole 220 and discharged toward the cancel shooter 206.

On the other hand, the determination result related to the latest count process is not "abnormality has occurred", "threshold determination not possible" is not stored as the determination result of the threshold determination process, and "permitted" is stored as the color determination result. If “Yes” is stored as the acquired gradient average determination result and HOG determination result, the host controller 241 does not output the medal abnormality signal. Therefore, the state of the second medal solenoid 708b is maintained in the ON state. In this case, the object to be determined is guided to the medal exit portion 204c side, that is, to the hopper device 51.

Further, when the circle area cannot be detected in the circle area detection processing performed on the reduced image data stored in the SRAM 243, the host controller 241 of the medal selector 801 in the modified example outputs a signal to that effect. Upon detecting this signal, the sub control circuit 101 (sub CPU 102 thereof) outputs a control signal for setting the second medal solenoid 708b to the ON state to the second medal solenoid 708b.

In the present modification, when the pachi-slot 1 is not in the medal insertion permission state described above, the main control circuit 91 sets the first medal solenoid 708a to the OFF state and ejects the medals toward the cancel shooter 206. Even if the first medal solenoid 708a is in the ON state, the control LSI 234 of the medal selector 701 determines that the determination result of the color determination process is "threshold determination not possible" when the determination result of the count process is "abnormal". Alternatively, when the result is “NO” or when the result of the marking determination process is “NO”, the medal abnormality signal is output. Then, the sub-control circuit 101, which has detected the medal abnormality signal, sets the second medal solenoid 708b to the OFF state and ejects the medal toward the cancel shooter 206. Therefore, the inserted medals can be properly counted. Further, the inserted medals can be appropriately guided to the cancel shooter 206 or the hopper device 51.

<Other modifications>
Further, in the above-described embodiment, the mode in which the four color templates, the gradient average image template, and the HOG template are generated has been described, but the number of these templates can be set as appropriate according to the allowable determination required time and the required determination accuracy. Is.

Further, in the above-described embodiment, a mode has been described in which the color determination process and the marking determination process are executed for all the inserted medals. However, the present invention is not limited to this, and a switch substrate is provided at an arbitrary position of the medal selector 201 (for example, near the first substrate 230), and the color determination ON/OFF switch and the marking determination ON/OFF switch are provided on the switch substrate. May be provided so that the host controller 241 can read the state of the switch to select whether to execute the color determination process and the marking determination process.

Further, in the above-described embodiment, when “NO” is input to the main control circuit 91 as the gradient average determination result, or “NO” is input as the HOG determination result, the main control circuit 91 The aspect of detecting that there has been cheating has been described. However, instead of this, when “NO” is input to the main control circuit 91 as the gradient average determination result and “NO” is input as the HOG determination result, the main control circuit 91 determines that the misconduct has occurred. You may detect that there is.

Further, in the above embodiment, the color template, the gradient average image template, and the HOG template stored in the SRAM 243 are erased when the initialization switch is pressed when the power of the gaming machine is turned on. However, instead of this, an arbitrary operation may be set in order to delete the various templates stored in the SRAM 243. For example, various templates of the SRAM 243 may be deleted in association with the change of the settings of the gaming machine.

In addition, in the order determination process when the medals cannot be inserted, the mode of data transition in each determination region of the latest four grayscale image data stored in the SRAM 243 and the medal count determination table are defined. When the transition states of the data corresponding to E1 to E4 do not match, it may be determined that “an abnormality has occurred” and the determination result may be stored in the SRAM 243.

Further, in the above-described embodiment, the host controller 241 performs the count processing that the medal has passed to the main control circuit 91 from the input of the previous reduction end interrupt signal to the input of this reduction interrupt signal. The mode in which the image recognition DSP circuit 242 is instructed to start the preprocessing on condition that the determination result of (1) is output has been described. That is, when it is determined in the counting process that the medal has passed on the medal rail 210, the host controller 241 executes the processes subsequent to the circle area detection process in the marking determination process to the image recognition DSP circuit 242 and the image recognition accelerator circuit 249. Has been described. However, instead of this, a determination result of some counting process (that is, "medal is a medal shot") from the input of the previous reduction end interrupt signal to the input of the current reduction end interrupt signal. Alternatively, the image recognition DSP circuit 242 may be instructed to start the preprocessing on the condition that "the information is guided by 202" or "the abnormality has occurred" is output.

Further, the threshold value determination process in the color determination process may be omitted.
Further, the present invention may be adopted in another game machine using a game medium, for example, a pachinko machine.
In addition, in Modifications 3 to 6, the double photo sensor 502 is used as an example of a proximity sensor that detects an object moving on the medal rail 210, but the present invention is not limited to this. Other proximity sensors (inductive type, electrostatic capacitance type, ultrasonic type, photoelectric type, magnetic type proximity switch) that can detect the presence or absence of the contactless contact may be used.

1...Pachislot, 3L...Left reel, 3C...Middle reel, 3R...Right reel, 4...Reel display window, 21...Medal insertion slot, 23...Start lever, 32...Medal payout port, 51...Hopper device, 71...Main Control board, 72... Sub control board, 79... Start switch, 80... Stop switch board, 91... Main control circuit, 101... Sub control circuit, 140... Cancel shooter, 201... Medal selector, 202... Medal shoot, 203... Slope , 204... Base plate part, 205... Sub plate, 206... Cancel shooter, 207... Select plate, 208... Medal solenoid, 209... Camera unit, 210... Medal rail, 211... Medal entrance part, 212... Central hole, 213... Medal pressure, 217... Magnet, 218... After medal pressure, 227... Medal stopper part, 230... First substrate, 231... Second substrate, 232... CMOS image sensor, 233... LED, 234... Control LSI, 235... Legs, 241... Host controller, 242... Image recognition DSP circuit, 243... SRAM, 244... Flash memory, 245... ISP circuit, 246... Medal counting circuit, 247... Color recognition circuit, 248... Fisheye correction scaler circuit, 249 ... image recognition accelerator circuit, 250... GPIO, 251... ISI circuit

Claims (2)

An input port for inputting game media,
A game machine comprising: a game medium detecting means for detecting a game medium inserted through the slot.
The game medium detecting means,
A passage forming portion forming a passage through which the game medium passes,
Imaging means for imaging the passage,
Based on the image data captured by the image capturing means, a game medium determining means for performing determination processing for determining whether or not the object passing through the passage is a regular game medium,
A template generation unit that generates template data used in the determination process,
The game medium determining means determines whether or not the object passing through the passage is a regular game medium based on whether the image data and the template data match or are similar to each other to a predetermined degree. Then
The template generation unit groups a plurality of the image data into groups of the image data that are the same or similar to each other to a predetermined degree, and selects the group within a predetermined number from the upper rank in which the number of the image data belonging to the group is large. Then, for each of the selected groups, the template data is generated based on the image data belonging to the group,
The template data has a plurality of types of template data,
One of the plurality of types of template data is pattern template data relating to the pattern of the game medium,
In the generation processing of the pattern template data by the template generation means, the image data is converted into color space image data, and one element in the converted color space image data is generated by a predetermined processing, and then generated. A game machine characterized by using a conversion value obtained by coordinate conversion of the generated data. One element in the color space image data is a brightness value, and the conversion value is a value generated by coordinate-converting the data based on the brightness value and separating the coordinate-converted data. The gaming machine according to claim 1, wherein:

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