JP2015024244A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a game machine, in which a load on a reel or a stepping motor is reduced.SOLUTION: When a stop command of a rotating reel 61 (61L, 61M and 61R) is outputted in a slot machine 10, a stop pattern to be displayed at a predetermined position on an effective line at the stopping time of the reel 61 is decided. On the basis of the relations between the stop-scheduled pattern decided and the predetermined position on the effective line, there is selected either a first stop condition, under which the reel 61 is stopped, or a second stop condition, under which the reel 61 is not decelerated but stopped under the selected stop condition. For the first stop condition, there are prepared a plurality of deceleration patters, in which the reel deceleration time periods are different. When the reel is stopped under the first stop condition, in the case where the stop pattern can be stopped and displayed at said predetermined position, one deceleration pattern is selected from the deceleration patterns of the first stop condition.

Description

  The present invention relates to a slot machine and other gaming machines.

In a slot machine as a gaming machine, when a player inserts a medal and operates a start lever, an internal lottery is executed and a reel (circular body) rotates.
As a result of the internal lottery, if the winning combination (combination) is won, it will be displayed in the display window when all reels stop rotating due to the operation of the stop button by the player thereafter. In addition, a predetermined number of medals are paid out on condition that the combination of symbols on each reel matches the combination of symbols of the winning prize winning combination.

Here, the rotation and stop of the reel are executed by controlling excitation phase switching and switching timing in the stepping motor.
In the slot machine, when an instruction to stop rotation of the reel is input by operating the stop button, the reel is not stopped when the instruction is input, and an arbitrary timing from that point until a predetermined time elapses. It is allowed to stop the reel at.
Therefore, if the winning combination is won as a result of the internal lottery performed when the start lever is operated, the symbol displayed in the display window when the rotation of each reel is stopped is the symbol of the winning combination. The timing to stop the reels is adjusted to match the combination as much as possible.

  As a result, in the slot machine, the reel can be stopped by sliding from a symbol displayed in the display window to a symbol separated by a predetermined symbol when an instruction to stop the rotation of the reel is received. Yes.

Japanese Utility Model Publication No. 62-36787

For this reason, in the slot machine, the reel is rotated at a constant speed even after an instruction to stop the rotation of the reel is received, and all the phases of the stepping motor are excited when the symbol to be displayed in the display window reaches a predetermined position. The reel is stopped suddenly.
Therefore, in the conventional slot machine, since the reels rotating at a constant speed repeatedly stop suddenly, a load is applied to the reels and the stepping motor.

  Therefore, it is required to reduce the load on the reel and the stepping motor when the reel is stopped.

The present invention
A orbital body with multiple designs drawn on it,
A multi-phase stepping motor that rotates the rotating body, and
Motor control means for sequentially switching the excitation phase of the stepping motor to control rotation / stop of the rotating body;
Game control means for controlling the progress of the game;
When the stop button is operated, stop instruction means for outputting a stop command of the rotating circuit body,
When a stop command is output, a stop symbol determining means for determining a stop symbol to be displayed at a predetermined position when the orbiting body stops is provided,
In the gaming machine in which the stepping motor control means stops the circulating body within a predetermined time from the output of the stop command and stops and displays the stop symbol at a predetermined position.
Stop condition selecting means for selecting a first stop condition for stopping the circulating body after decelerating the circulating body until the stop symbol reaches the predetermined position based on the relationship between the stop symbol and the predetermined position; Prepared,
The first stop condition includes a plurality of decelerations in which at least one of the deceleration time and the deceleration of the orbiting body is different and the excitation phase to be excited and the excitation time are associated with an identification number indicating the switching order of the excitation phases. Patterns are available,
Stop condition selection means
When it is possible to stop and display the stop symbol at a predetermined position when the orbiting body is stopped under the first stop condition, a stop command is output from a plurality of deceleration patterns of the first stop condition. Is a deceleration pattern that can stop the orbiting body within a predetermined time, and selects one deceleration pattern with the longest slowdown period based on the relationship between the stop pattern and the predetermined position,
The motor control means uses the deceleration pattern selected by the stop condition selection means, and sequentially stops the circuit body after decelerating it while sequentially changing the excitation phase and the excitation time for excitation according to the order of the identification numbers. This was a gaming machine.

  With this configuration, since one deceleration pattern corresponding to the positional relationship between the stop symbol and the predetermined position is selected, the determined stop symbol is stopped and displayed at a predetermined position as much as possible, The load on the stepping motor can be reduced.

  In addition, since the orbiting body can be completely stopped after being smoothly decelerated, the load on the orbiting body and the stepping motor can be reduced.

  When stopping the reel, the load acting on the reel and the stepping motor can be reduced.

It is a front view of a slot machine. It is a perspective view of the state which closed the front door of the slot machine. FIG. 3 is a perspective view of the slot machine with a front door opened. It is a front view of the housing body of the slot machine. It is a disassembled perspective view of a left reel. It is a figure which shows the operation principle of a stepping motor. It is a connection diagram which shows the drive system of a stepping motor. It is explanatory drawing which shows the relationship between excitation data and an excitation order pointer. It is a figure explaining the arrangement | positioning of a 1st and 2nd sensor cut van, and the detection signal of a reel index sensor. It is a figure which shows the relationship between the symbol arrangement | sequence drawn on the outer periphery of a reel, the combination of a symbol arrangement | sequence, and a combination. It is a block diagram explaining the structure of a main control board. It is a flowchart of the NMI interruption process which a main control board performs. It is a flowchart of the timer interruption process which a main control board performs. It is a flowchart of the process at the time of a power failure which a main control board performs. It is a flowchart of the main process at the time of power activation which a main control board performs. It is a flowchart of the normal game process which a main control board performs. It is a flowchart of the lottery process of a normal game process. It is a flowchart of the reel control process of a normal game process. It is a flowchart of the medal payout process of the normal game process. It is a flowchart of special game state processing of normal game processing. It is a flowchart of the bonus symbol determination process of a special game state process. It is a RB game initial value table. It is a BB game initial value table and a JAC in initial value table. It is a figure which shows the drive characteristic of a stepping motor. It is a figure which shows an acceleration table. It is a flowchart of a stepping motor control process. It is a flowchart of a motor control process. It is a flowchart of a motor control process. It is a flowchart of a rotation position detection process. It is a flowchart of a reel stop process. It is a flowchart of a stop control process. It is a flowchart of a stop control process. It is a figure which shows a 1st deceleration table. It is a figure which shows a 2nd deceleration table. It is a flowchart of the reel stop process concerning 2nd Embodiment. It is a figure which shows a sliding table. It is a flowchart of the reel stop process concerning 3rd Embodiment. It is a figure which shows the 3rd and 4th deceleration table.

[Game machine]
Hereinafter, embodiments of the present invention will be described by taking a case where the gaming machine is a slot machine as an example.
1 is a front view of the slot machine 10, FIG. 2 is a perspective view of the slot machine 10 with the front door 12 closed, and FIG. 3 is a state of the slot machine 10 with the front door 12 opened. FIG. 4 is a front view of the housing body 11.

As shown in FIG. 3, the housing of the slot machine 10 includes a box-shaped housing body 11 that opens on the front side, and a front door 12 that closes the opening.
The front door 12 is attached to the housing main body 11 by hinges at a plurality of upper and lower positions on the left end side, swings horizontally around the hinge, and can open and close the opening of the housing main body 11.
As shown in FIG. 1, a locking mechanism 20 is provided at the right end of the front door 12 to close the front door 12 in a locked state in cooperation with the housing body 11 side.

  As shown in FIG. 4, the housing body 11 of the slot machine 10 includes a top plate 11a, a bottom plate 11b, a back plate 11c, a left side plate 11d, and a right side plate 11e. The inside of the housing body 11 includes a partition plate 11f. Is divided into two in the vertical direction.

  On the upper part of the partition plate 11f, a left reel 61L and a middle reel arranged side by side in a one-to-one correspondence with the display windows 31L, 31M, and 31R (hereinafter also referred to as the display window 31) of the front door 12. A reel unit 60 that supports a 61M, right reel 61R (hereinafter also referred to as a reel 61) rotatably on the same axis is attached.

  Further, a control board accommodation box 51 is attached above the reel unit 60 of the back plate 11c when viewed from the front, and the main control for controlling the slot machine 10 is provided in the control board accommodation box 51. A substrate 80 is accommodated.

A hopper device 52, a power supply device 56, and a medal storage box 57 are disposed below the partition plate 11f.
The hopper device 52 includes a storage tank 53 that stores medals and a payout device 55 that pays out medals to a player. The payout device 55 rotates a medal payout rotating plate (not shown) to rotate the front door. The medal is discharged to the opening 68 of the discharge passage 67 on the back surface of the twelve, and the medal is paid out to the medal tray 18 (see FIG. 2) through the discharge passage 67.
Further, on the right side of the hopper device 52, a medal storage box 57 for avoiding a predetermined amount or more of medals from being stored in the storage tank 53 is provided. The storage tank 53 of the hopper device 52 is provided with a guide plate 54 for discharging medals from the storage tank 53 to the medal storage box 57. When the medals stored in the storage tank 53 become excessive, the storage tank 53 becomes excessive. The formed medals are discharged and stored in the medal storage box 57.

As shown in FIG. 1, on the upper side of the front door 12, an upper lamp 13 that is lit and blinks as the game progresses is provided along the upper side. A pair of speakers 14 for outputting various notification sounds (sound effects) are provided.
Between the pair of speakers 14, a liquid crystal display 15 for displaying various information such as images and videos is provided.

  Below the liquid crystal display 15, a display panel 30 through which the left reel 61L, the middle reel 61M and the right reel 61R can be seen through, and various buttons 41 to 44, 46 to 49, a start lever 45, and a medal are inserted near the middle stage. An operation unit 40 provided with a mouth 50, a lower plate 16 on which a model name, a character related to a game, and the like are displayed, and a medal tray 18 for receiving medals paid out from a medal discharge port 17 are provided. .

  As shown in FIG. 1, the display panel 30 includes a display window 31 (31L, 31M, 31R) that allows the left reel 61L, the middle reel 61M, and the right reel 61R to be visually recognized when stopped or rotating, and the display window 31L. Five bet lamps 32, 33, 33, 34, and 34 arranged on the left side of the display window, and three display units (credit number display unit 35) arranged below the display window 31 (31L, 31M, and 31R) A game number display unit 36 and an acquired number display unit 37).

  The display window 31 (31L, 31M, 31R) is formed in a size that allows three symbols to be simultaneously viewed in the vertical direction for each of the stopped left reel 61L, middle reel 61M, and right reel 61R. Therefore, 3 × 3 = 9 symbols are visible to the player when all of the left reel 61L, middle reel 61M, and right reel 61R are stopped. Note that the display windows 31 (31L, 31M, 31R) may be combined into a single exposure window.

In addition, a total of five lines including upper, middle, and lower horizontal lines a, b, and c and a pair of diagonal lines d and e indicated by chain lines in FIG. 1 are set as winning determination lines. At least one of the placed lines is appropriately activated according to the number of medals bet.
The activated line is an activated line, and a “winning” is awarded when a combination that gives a predetermined prize is aligned with the activated line. For example, if “Cherry” is on the symbol on the active line among the three symbols of the stopped left reel 61L, “winning” is obtained.

  As shown in FIG. 1, a bet lamp 32 that lights when one medal is bet is disposed on the left side of the middle horizontal line b, and is a bet lamp 33 that lights when two medals are bet. , 33 are arranged on the left side of the upper horizontal line a and the lower horizontal line c. The bet lamps 34, 34 that are lit when three medals are bet are located on the left of the pair of diagonal lines d, e. It is arranged sideways.

  The credit number display unit 35 displays the number stored in the slot machine 10 when a credit function described later is valid.

  The number-of-games display unit 36 displays, for example, how many times JAC (jack) in can be performed at the time of the big bonus, and how many times the JAC symbol formation remains at the time of the JAC game.

  The acquired number display section 37 displays the number of coins paid out when the same symbols are aligned on the active line.

As shown in FIGS. 1 and 2, the operation unit 40 includes a plane part 40 a extending from the lower end of the display panel 30 toward the front side, a vertical wall part 40 b extending vertically from the front end part of the plane part 40 a, and have.
On the left side of the flat surface portion 40a, a single bet button 41, a double bet button 42, and a max bet button 43 are provided, and on the right side, a medal slot 50 is provided.

  Each bet button 41, 42, 43 is a button for determining the number of medals to bet in the game before the game starts, and the bet lamps 32 to 34 are turned on according to the number of medals bet. Can be confirmed.

The medals inserted from the medal insertion slot 50 are guided to either the storage passage 66 or the discharge passage 67 by a selector 65 (see FIG. 3) as passage switching means provided on the back surface of the front door 12. That is, the selector 65 is provided with a medal passage switching solenoid (not shown). When the medal passage switching solenoid is not excited, the medal is guided to the discharge passage 67 side, and when excited, the medal is placed on the storage passage 66 side. Is to be induced.
The medal guided to the storage passage 66 is guided to the hopper device 52 housed inside the housing body 11. On the other hand, the medal guided to the discharge passage 67 is guided to the medal tray 18 from the medal discharge port 17 (see FIG. 1) provided in the lower front portion of the front door 12 and returned to the player.

  As shown in FIG. 1, on the vertical wall portion 40b, in order from the left side to the right side, a credit settlement button 44, a start lever 45, a stop button 46 for the left reel 61L, and a stop for the middle reel 61M. A button 47, a stop button 48 for the right reel 61R, and a return button 49 are provided.

  The credit settlement button 44 is configured to be a toggle type that is turned on when pressed once, turned off when pressed again, and switched on / off each time the button is operated.

  When the credit check button 44 is in the OFF state, the display of the credit number display unit 35 disappears, and medals inserted from the medal insertion slot 50 and medals paid out when winning a prize are paid out from the medal discharge slot 17 to the medal tray 18. .

  When the credit check button 44 is on, a number (“0” when turned off from on) is displayed on the credit number display section 35, and the credit function is enabled.

  Here, the credit function is a function for storing the number of coins inserted from the medal slot 50 within the slot machine when the number of max bets (three here) is exceeded. Is displayed on the credit number display section 35 described above. When one or more credits are displayed on the credit number display unit 35 and the credit settlement button 44 is pressed to turn it off, the displayed number of medals are paid out from the medal outlet 17 to the medal tray 18, and medals are received. Each time the payout is made, the value on the credit number display section 35 is decremented (subtracted) one by one, and the display disappears after the value becomes zero.

The start lever 45 is a lever that is operated by pushing down or pushing up when the player starts a game, and projects from the vertical wall portion 40b toward the front side.
When the start lever 45 is operated while a medal is bet, a start command is generated, and the reels 61 (61L, 61M, 61R) start to rotate simultaneously by the start command.

The stop buttons 46 to 48 are buttons that the player presses to stop the rotating left reel 61L, middle reel 61M, and right reel 61R, respectively.
When each stop button 46, 47, 48 is pressed, a stop command is generated.
Each stop button 46, 47, 48 is turned on by a lamp (not shown) while each reel 61 (61L, 61M, 61R) is rotating at a constant speed, and is turned off when the rotation is stopped.

Here, a procedure for betting medals will be described.
When the credit settlement button 44 is in an off state (when the credit amount display unit 35 is turned off), or when the credit settlement button 44 is in an on state and the number of stored medals is zero (the number of credits displayed) If a medal is inserted from the medal insertion slot 50 when “0” is displayed on the portion 35), a bet is placed.

  That is, when the first medal is inserted into the medal insertion slot 50, the bet lamp 32 is turned on, and the middle horizontal line b corresponding to this becomes the active line, and the second medal becomes the medal insertion slot 50. , The two bet lamps 33 and 33 are turned on, and a total of three lines including the upper and lower horizontal lines a and c corresponding thereto become effective lines, respectively. Is inserted into the medal slot 50, two more bet lamps 34 and 34 are lit, and each of a total of five lines including a pair of diagonal lines d and e corresponding thereto becomes an active line. .

  When four or more medals are inserted into the medal slot 50, the medal is returned from the medal outlet 17 to the medal tray 18 when the credit check button 44 is off (the credit function is not valid). When the credit check button 44 is on (when the credit function is valid), the number of medals inserted is stored in the slot machine with the active line as it is, and the stored number is displayed on the credit number display section 35. Is done. The upper limit of the number of credits is determined (for example, 50), and when more medals are inserted, they are returned to the medal tray 18 from the medal outlet 17.

  When three or more medals are stored, if the one-bet button 41 is pressed, the numerical value displayed in the credit number display section 35 is decremented by one, and the bet lamp 32 is lit and the middle stage is displayed. When the horizontal line b becomes an active line and the two-sheet bet button 42 is pressed, the numerical value displayed on the credit number display section 35 is decremented by two, and the bet lamp 32 and the bet lamps 33 and 33 are lit. When a total of three horizontal lines a, b and c are activated and the max bet button 43 is pressed, the numerical value displayed on the credit amount display section 35 is decremented by three and all bet lamps 32 and 33 are displayed. , 33, 34, and 34 are turned on, and a total of five lines a to e become effective lines.

  On the other hand, when two medals are stored, if the one-bet button 41 or the two-bet button 42 is pressed, the operation is the same as before, but if the max-bet button 43 is pressed, the two-bet button 42 is When the single bet button 41 is pressed when only one medal is stored, the same operation is performed as before, but the two bet button 42 and the maximum bet button 43 are operated. When is pressed, the operation is the same as when the single bet button 41 is pressed.

[Reel unit]
The reel unit 60 will be described.
As shown in FIG. 4, in the reel unit 60, the left reel 61L, the middle reel 61M, and the right reel 61R are provided so as to be rotatable around a common rotation axis X, and each is rotated by a dedicated stepping motor. It has become so.

Here, since the left reel 61L, the middle reel 61M, and the right reel 61R have the same configuration, the configuration will be described by taking the case of the left reel 61L as an example, and the middle reel 61M and the right reel 61R will be described. The description about is omitted.
FIG. 5 is an exploded perspective view of the left reel 61L.

  The left reel 61L is a rotating body in which a belt on which 21 symbols (identification elements) are drawn at equal intervals is wound around the outer peripheral surface of a cylindrical skeleton member 70 forming a cylindrical car. A boss portion 71 of the cylindrical skeleton member 70 is connected to a drive shaft of a stepping motor 79 via a disk-like boss reinforcing plate 72, and the left reel 61 </ b> L is rotated by the stepping motor 79. .

  The stepping motor 79 is fixed to a motor plate 73 suspended from the inside of the housing body 11 (FIG. 2) with screws 74, and a drive signal (hereinafter, referred to as a drive signal output from the main control board 80 of the slot machine 10). Based on the excitation signal or excitation pulse), the motor driver 100 drives the motor.

[Stepping motor]
FIG. 6 is a connection diagram showing an operation principle of the stepping motor 79, and FIG. 7 is a connection diagram showing a drive system of the stepping motor.
In the embodiment, a hybrid (HB) type two-phase stepping motor employing a 1-2 phase excitation method is employed.
However, the stepping motor is not limited to the hybrid type or the two-phase, and various stepping motors such as a four-phase or five-phase stepping motor may be used.

  The hybrid type stepping motor 79 includes a rotor (rotor) 790 disposed in the center as well known, and a first pole 793 to a fourth pole 796 disposed around the rotor 790.

  The rotor 790 is composed of a front rotor 791 magnetized to the N pole and a back rotor 792 magnetized to the S pole, and teeth (small teeth) and teeth provided around the front rotor 791. In between, it is attached to the rotating shaft in a state of being relatively shifted by ½ pitch so that the teeth provided around the back rotor 792 are positioned. A cylindrical magnet (not shown) is attached between the front rotor 791 and the back rotor 792.

As shown in FIGS. 6 and 7, exciting coils L0 and L2 are bifilar wound around the first pole 793 and the third pole 795, respectively, and the winding end of the exciting coil L0 and the winding start of the exciting coil L2 are wound. And a predetermined DC power source + B (for example, +24 volts) is applied thereto.
Similarly, the excitation coils L1 and L3 are bifilar wound around the second pole 794 and the fourth pole 796, respectively, and the winding end of the excitation coil L1 and the winding start of the excitation coil L3 are connected to each other. The DC power source + B described above is applied.

  Here, an excitation signal is applied to the first excitation coil L0 to excite the first pole 793 to the S pole, and the phase exemplified by the third pole 795 as the N pole is set to the A phase. An excitation signal is applied to the third excitation coil L2 to excite the first pole 793 to the N pole, the phase for exciting the third pole 795 to the S pole is the A-phase, and the second excitation coil L1. The excitation signal is applied to the second pole 794 to the south pole, the phase for exciting the fourth pole 796 to the north pole is the B phase, and the excitation signal is applied to the fourth excitation coil L3. The phase in which the second pole 794 is excited to the N pole and the fourth pole 796 is excited to the S pole is referred to as a B-phase.

  In the case of the one-phase excitation drive method, the rotor 790 is rotated in the clockwise direction (or counterclockwise) by sequentially applying excitation signals to the A phase, B phase, A-phase and B-phase. can do.

  That is, for example, when the A phase is first energized, the protrusion of the first pole 793 and the teeth of the front rotor 791 that are the S pole, the protrusion of the third pole 795 that is the N pole and the teeth of the back rotor 792 are attracted respectively. When facing each other by force and then energizing the B phase, the protrusion of the second pole 794 and the teeth of the front rotor 791 that are the S pole, the protrusion of the fourth pole 796 that is the N pole and the teeth of the back rotor 792 are When facing each other by the attractive force and then energizing the A-phase, the projection of the first pole 793 and the teeth of the back rotor 792 that are N poles, the projection of the third pole 795 that is the S pole and the front rotor 791 When the teeth of each of the teeth face each other by the attractive force and then the B-phase is energized, the protrusion of the second pole 794 and the teeth of the back rotor 792 that are N poles, the protrusion of the fourth pole 796 that is the S pole and the front side Side rotor 791 teeth Each face by the suction force. By exciting in this order, the rotor 790 rotates clockwise in FIG. 6 (one-phase excitation drive).

  On the other hand, in this embodiment, 1-2 phase excitation drive that alternately performs 1-phase excitation and 2-phase excitation is employed. In the 1-2 phase excitation drive, excitation is performed according to the following excitation sequences (excitation order) 1) to 8).

  That is, since excitation of only one phase is one-phase excitation, and two-phase excitation is an example of two phases simultaneously, as shown in FIG. Energize (1 phase excitation), (2) Energize both A phase and B phase (2 phase excitation), (3) Energize B phase in the same way, (4) Both B phase and A-phase (5) A-phase is energized, (6) A-phase and B-phase are both energized, (7) B-phase is energized, and (8) B-phase and A-phase are energized. This is a drive system in which both are energized and then return to (1).

  By adopting this 1-2 phase excitation drive, the angle change of the rotor 790 per step of excitation drive is about 0.714 °.

Here, the stepping motor 79 is set to rotate the left reel 61L once by a drive signal of 504 pulses, and the stepping motor 79 is driven around the rotation axis X of the left reel 61L by driving with the excitation pulse. The rotational position is controlled.
That is, when the left reel 61L makes one rotation, 21 symbols can be visually recognized in order from the display window 31L. Therefore, the symbols visible at the uppermost position of the display window 31L are the symbols of the left reel 61L. 24 pulses (= 504 pulses / 21 symbols) are required before switching to the next symbol by rotation.

  As shown in FIG. 5, the rotation position of the left reel around the rotation axis X is determined by attaching the sensor cut buns (first sensor cut bun 76 and second sensor cut bang 77) attached to the cylindrical skeleton member 70 to the motor plate 73. It can be specified by detecting with the reel index sensor 75. For example, which symbol is visible from the display window 31L depending on the number of pulses from the time when the detection signal of the reel index sensor 75 is output. Can be recognized. Further, when the rotation of the left reel 61L is stopped, the rotation control of the left reel 61L is performed based on the detection signal of the reel index sensor 75 so that an arbitrary symbol can be visually recognized from the display window 31L at the time of the stop. Can be done.

The detection of the rotation position of the left reel will be described.
FIG. 9A is a diagram showing the positional relationship between the first sensor cut bun 76 and the second sensor cut bang 77 in the left reel 61L, and is viewed from the side in which the rotation direction of the left reel 61L is counterclockwise. FIG. (B) is a diagram illustrating a signal (on signal / off signal) output from the reel index sensor 75 when the left reel 61L rotates.

As shown in FIG. 9A, the left reel 61L is provided with two sensor cut buns, a first sensor cut bang 76 and a second sensor cut bang 77, extending in the radial direction.
The first sensor cut bun 76 and the second sensor cut bang 77 have a fan shape when viewed from the axial direction. As shown in FIG. 5, the base end portions 76b and 77b are integrated with the left reel 61L. The boss reinforcing plate 72 is fixed with screws 78.

As shown in FIG. 9 (a), the tip portions 76a and 77a of the first sensor cut bun 76 and the second sensor cut bang 77 are bent by approximately 90 ° to form the axial direction of the rotation axis X (FIG. 9 (a)). The tip portions 76a and 77a as viewed from the direction of the rotation axis of the left reel 61L form an arc shape along the rotation direction of the left reel 61L.
The first sensor cut bun 76 and the second sensor cut bang 77 are positioned so that the end portions 76 a and 77 a can pass through the gap between the pair of photo sensors (the light emitting element 75 a and the light receiving element 75 b) of the reel index sensor 75.

  The angle range (15 °) around the rotation axis X of the first sensor cut bun 76 is set to be smaller than the angle range (30 °) of the second sensor cut bang 77, and the arc length (starting end) of the distal end portion 76a is set. The length L1 from the portion 76s to the end portion 76e) is shorter than the arc length of the tip portion 77a (the length from the start end portion 77s to the end portion 77e) L2.

  In the left reel 61L, the first sensor cut bun 76 and the second sensor cut bang 77 have a start end portion 76s of the tip end portion 76a and a start end portion 77s of the tip end portion 77a spaced apart by 180 ° in the circumferential direction around the rotation axis X. It is provided to be arranged.

In the embodiment, the left reel 61L is partitioned at 30 ° intervals in the circumferential direction around the rotation axis X, and a total of 12 areas (first area to twelfth area) are set.
When the position of the start end portion 76s of the tip end portion 76a is 0 ° (reference position) and the area where the first sensor cut van 76 is located is the first area, the tip end portion 77a is moved six times in the clockwise direction from the first area. It is located in the seventh area.

As described above, the stepping motor 79 is set to rotate the left reel 61L once by a drive signal (excitation pulse) of 504 pulses, and the angle change (1 step) of the left reel 61L based on the drive signal of 1 pulse. (Angle change) is about 0.714 °.
Here, the output of the drive signal is executed in a port output process (FIG. 13, step 214) of a timer interrupt process to be described later, and the execution interval of this timer interrupt process is 1.49 msec. The time required for one rotation is 750.96 msec (= 1.49 msec × 504 pulses).

Here, when the reel index sensor 75 detects the passage of the sensor cut bun (the first sensor cut bang 76 and the second sensor cut bang 77) at the position of 0 ° in FIG. 9, the time when the first sensor cut bang 76 is detected. (First detection time) t1 corresponds to the time required for the start portion 76s to the end portion 76e of the front end portion 76a to pass through the 0 ° position.
Here, the length L1 of the front end portion 76a is a length corresponding to a predetermined rotation angle of 15 ° of the left reel 61L, and 21 pulses are required to rotate the left reel by 15 °. The time t1 at which 76 is detected is 31.29 msec (= 1.49 msec × 21 pulses).

  Similarly, the length L2 of the tip 77a of the second sensor cut bun 77 is a length corresponding to a predetermined rotation angle 30 ° of the left reel 61L, and 22 pulses are required to rotate the left reel by 30 °. Therefore, the time (second detection time) t3 at which the second sensor cut bang 77 is detected is 62.58 msec (= 1.49 msec × 42 pulses).

Also, the time (first non-detection time) t2 from when the first sensor cut bang 76 is no longer detected until the second sensor cut bang 77 is detected is the position where the end portion 76e of the first sensor cut bang 76 is 0 °. This corresponds to the time from when the first end portion 77s of the second sensor cut van 77 passes through the 0 ° position after passing through.
In such a case, it is necessary to rotate the left reel by 165 ° (180 ° -15 °), and 231 pulses are necessary to rotate the 165 °, so the first non-detection time t2 is 344.19 msec (= 1. 49 msec × 231 pulses).

Furthermore, the time (second non-detection time) t4 from when the second sensor cut bang 77 is no longer detected until the first sensor cut bang 76 is detected is the position where the end portion 77e of the second sensor cut bang 77 is 0 °. It corresponds to the time from when the first end portion 76s of the first sensor cut van 76 passes through the 0 ° position after passing through the first position.
In such a case, the left reel needs to be rotated by 150 ° (360 ° -210 °), and 210 pulses are required to rotate it by 150 °. Therefore, the second non-detection time t4 is 312.9 msec (= 1.2. 49 msec × 210 pulses).

In the embodiment, every time the left reel 61L rotates halfway, the leading end portions 76a and 77a of the first sensor cut bun 76 and the second sensor cut bang 77 are detected by the reel index sensor 75, and the reel index sensor 75 The ON signal is output to the main control board 80 while any one of the tip portions 76a and 77a is detected, and the OFF signal is output to the main control board 80 when it is not detected.
Therefore, while the left reel 61L is rotating at a constant speed, a signal having a waveform as shown in FIG. 30B is input to the main control board 80, so the time during which the ON signal is input ( The rotation angle (angular position) of the left reel 61L can be specified based on the on-time (t1, t3) and the time (off-time t2, t4) when the off signal is input.

  In the embodiment, when the left reel 61L rotates at a constant speed, the on times t1, t3, and the off times t2, t4 are set together with the on time and the off time of the other reels (the middle reel 61M and the right reel 61R). , Stored in advance in the ROM 83 and referred to when detecting the rotational position of the reel 61 (61L, 61M, 61R).

As with the other reels (the middle reel 61M and the right reel 61R), a belt on which a pattern is drawn is attached to the outer periphery of the left reel 61L. In this belt, a plurality of belts are arranged in the long side direction (circumferential direction). Individual, specifically, 21 symbols are drawn at predetermined intervals.
Therefore, for example, to switch the symbol displayed at the top of the display window 31L to the next symbol, it is necessary to rotate the left reel 61L by 24 pulses (= 504 pulses / 21 symbols).
Then, which symbol is visible from the display window 31L depending on the number of pulses from the time when the rotational position of the left reel 61L is detected (for example, the time when the start end 76s of the first sensor cut bun 76 (tip 76a) is detected). It is possible to recognize whether it is possible. Furthermore, by performing control to stop the rotation of the left reel 61L based on the pulse signal, the left reel 61L can be stopped in a state where an arbitrary symbol is visible from the display window 31L.

  Of the symbols attached to each reel 61 (left reel 61L, middle reel 61M, right reel 61R), the number of symbols that can be seen through the display window 31 (31L, 31M, 31R) is mainly the display window 31. It is limited to a predetermined number determined by the vertical length of (31L, 31M, 31R). In this embodiment, three reels are provided. Therefore, when all the reels 61 (the left reel 61L, the middle reel 61M, and the right reel 61R) are stopped, 3 × 3 = 9 symbols are visible to the player.

Here, the symbols attached to each reel 61 (left reel 61L, middle reel 61M, right reel 61R) will be described. FIG. 10 shows a symbol arrangement drawn on the belt wound around each of the left reel 61L, the middle reel 61M, and the right reel 61R, and the relationship between the combination of the symbol arrangement and the combination.
As shown in FIG. 10, each of the reels 61 (left reel 61L, middle reel 61M, right reel 61R) is provided with 21 symbols in a row. Numbers from 0 to 20 are assigned to the respective reels 61 (left reel 61L, middle reel 61M, right reel 61R), but these are given for convenience of explanation, and each reel 61 (left reel 61L). The middle reel 61M and the right reel 61R) are not actually attached. However, in the following description, the number is used for explanation.

As a symbol, a “7 (super)” symbol (for example, the 6th left reel) as a first special symbol for shifting to a big bonus game, and a second special symbol for shifting to a regular bonus game There is a “7” symbol (for example, left reel 20th).
In addition, there is a “replay” symbol (for example, the 18th reel on the left reel) as a third special symbol for shifting to the replay game. Also, a “watermelon” symbol (for example, reel 16th), a “bell” symbol (for example, left reel 15th), and a “cherry” symbol (for example, left reel) as small character symbols from which the small character is paid out 17th).
As shown in FIG. 10, in the belt wound around the reel 61 (left reel 61L, middle reel 61M, right reel 61R), the number and arrangement order of various symbols are completely different.

As described above, the display panel 30 is provided with a total of five combination lines, with three display windows 31L, 31M, and 31R connected in parallel, three in the horizontal direction and two in the diagonal direction. Has been. At the time of a game, at least one of these combination lines is set as an active line according to the number of medals bet.
When the reels 61 (61L, 61M, 61R) are stopped by operating the stop button or the like, the combination of symbols of the reels 61 (left reel 61L, middle reel 61M, right reel 61R) located on the effective line is changed. When the combination of symbols of the combination shown in FIG. 10 is matched, a predetermined number of medals are paid out, a transition to a specific gaming state, or the like is executed.

Here, the payout number regarding each symbol when winning is explained.
With regard to the small role symbol, when the “watermelon” symbol is aligned with the left, middle, and right on the active line, eight medals are paid out. When the “bell” symbol is aligned with the left, middle and right on the active line, 10 medals are paid out. When the “cherry” symbol on the left reel 61L stops on the active line, two medals are paid out. In this case, the “cherry” symbols on the middle reel 61M and the right reel 61R are irrelevant to the medal payout.
In addition, for the “cherry” symbol, medals are paid out regardless of the combination with other symbols, so that the multiple effective lines of the left reel 61L overlap (specifically, the upper or lower level). When the “cherry” symbol is stopped, medals are paid out by multiplying the number of overlapping active lines, and as a result, in this embodiment, four medals are paid out.

  As for other symbols, 15 medals will be paid out when the “7 (super)” symbol, which is a combination of the first special symbol (big bonus symbol), is aligned with the left, middle and right on the active line. It is. 15 medals are also paid out when the “7” symbol, which is a combination of the second special symbol (regular bonus symbol), is aligned with the left, middle and right on the active line.

Further, when the “replay” symbol, which is a combination of the third special symbol, is aligned with the left, middle, and right on the active line, the medal is not paid out.
In other cases, that is, when the “cherry” symbol of the left reel 61L does not stop on the active line, and the same symbol as the left, middle and right does not align on the active line, no medals are paid out. .
Each stop button 46, 47, 48 (see FIG. 1) can be stopped when a predetermined time has elapsed after the reel 61 (61L, 61M, 61R) starts to rotate. A lamp (not shown) is turned on to notify that a stop operation is possible, and is turned off when the rotation stops.

Next, the main control board 80 of the slot machine 10 disposed in the control board storage box 51 will be described.
FIG. 11 is a block diagram illustrating the configuration of the main control board 80 of the slot machine 10.

  As shown in FIG. 11, the main control board 80 performs the main control processing of the game, and is connected to the MPU 81 as a one-chip microcomputer that is an arithmetic unit, and sensors, switches, etc. An input / output port 82 connected to the various input / output means is mounted.

  The MPU 81 includes a ROM 83 that stores a control program executed by the MPU 81 and fixed value data, and a RAM 84 that is a memory for temporarily storing various data when executing the control program stored in the ROM 83. Various circuits such as an interrupt circuit, a timer circuit, a data transmission / reception circuit, and a clock circuit 85 that outputs a rectangular wave having a predetermined frequency are incorporated.

  The ROM 83 stores the programs of the flowcharts shown in FIGS. 12 to 21, 26 to 32, 35, and 37 as a part of the control program.

In addition to the counters and flags described above, the RAM 84 is a stack area for storing the contents of the internal registers of the MPU 81 and the return address of the control program executed by the MPU 81, various flags and counters, I / O, etc. Is provided with a work area (work area) in which the value is stored.
In the embodiment, the RAM 84 is configured so that the backup voltage is supplied from the power supply device 56 even after the power of the slot machine 10 is shut off, and data can be held (backed up). Backed up.

When the power is shut down due to the occurrence of a power failure or the like, the stack pointer and the value of each register when the power is shut off (including when the power failure occurs, the same applies hereinafter) are stored in the RAM 84. On the other hand, at the time of power-on (including power-on due to power failure cancellation, the same applies hereinafter), the state of the slot machine 10 is restored to the state before power-off based on information stored in the RAM 84.
Writing to the RAM 84 is executed when the power is shut off by the timer interrupt process (FIG. 13), and the restoration of each value written to the RAM 84 is executed in the start-up process (see FIG. 15) when the power is turned on. The NMI terminal (non-maskable interrupt terminal) of the MPU 81 is configured to receive a power failure occurrence signal from the power failure monitoring circuit 56b when the power is interrupted due to the occurrence of a power failure or the like. Is input immediately, the NMI interrupt process (FIG. 12) as a process at the time of a power failure is immediately executed, and information on occurrence of power interruption is stored in the RAM 84.

  In the input / output port 82, a bet operation detection that detects the operation of the inserted medal detection sensor 50a for detecting a medal inserted from the medal insertion slot 50 (see FIG. 1) and the bet buttons 41, 42, and 43 (see FIG. 1). Sensors 41a, 42a, 43a, lever operation detection sensor 45a for detecting the operation of the start lever 45 (see FIG. 1), stop operation detection sensors 46a, 47a for detecting the operation of the stop buttons 46, 47, 48 (see FIG. 1) 48a, a reel index sensor 75 for detecting the passage of the first sensor cut bun 76 and the second sensor cut bang 77 (see FIG. 5) of the reel 61 (left reel 61L, middle reel 61M, right reel 61R), a credit check button 44 ( Switching operation detection sensor 44a for detecting on / off switching by the operation of FIG. A medal payout detection sensor 52a for detecting medals paid out from the device 52 (see FIG. 4), a reset operation detection sensor 123a for detecting an operation of the reset switch 123 (see FIG. 4), and a setting key insertion hole 124 (see FIG. 4). A setting key operation detection sensor 124a for detecting that a setting key has been inserted is connected, and signals from these various sensors are input to the MPU 81 via the input / output port 82.

Further, a power supply device 56 is connected to the input / output port 82.
The power supply device 56 is provided in a power supply box. In addition to the main control board 80, a power supply unit 56a that supplies driving power to each electronic device of the slot machine 10 and a power failure monitoring circuit that monitors the occurrence of power failure Various circuits such as 56b are provided. After the slot machine 10 is powered off, a backup voltage is supplied from the power supply unit 56a to the RAM 84.

The power failure monitoring circuit 56b is connected to the NMI terminal and the input / output port 82 of the main control board 80 and the NMI terminal of the sub control board 90 when the power is cut off due to the occurrence of a power failure or the like (including turning off the power switch). It is a circuit for outputting a power failure occurrence signal.
The power failure monitoring circuit 56b monitors the voltage of 24 VDC, which is the largest voltage output from the power supply device 56, and determines that a power failure (power failure) has occurred when this voltage is less than 22 volts. The power failure occurrence signal is output. Based on the output of the power failure occurrence signal, the main control board 80 is configured to recognize the occurrence of the power failure and to execute the process at the time of the power failure. The power failure occurrence signal of the power failure monitoring circuit 56b may be configured to be input to the INT terminal instead of the NMI terminal of the main control board 80.

  In addition, the power supply device 56 sets the output of 5 volts, which is the drive voltage of the control system, to a normal value for a time sufficient for the execution of the power failure process even after the DC stable voltage of 24 volts becomes less than 22 volts. Configured to maintain. For example, in this embodiment, the drive power supply is output for 30 msec. Therefore, the main control board 80 can normally execute the power failure process. Further, the power failure monitoring circuit 56b may be provided not on the power supply device 56 but on the main control board 80, for example.

  In addition, the power supply device 56 sets the output of 5 volts, which is the drive voltage of the control system, to a normal value for a time sufficient for the execution of the power failure process even after the DC stable voltage of 24 volts becomes less than 22 volts. Configured to maintain. For example, in this embodiment, the drive power supply is output for 30 msec. Therefore, the main control board 80 can normally execute the power failure process.

  Further, on the output side of the input / output port 82, bet lamps 32, 33, and 34 that display an effective line, a credit number display unit 35, a game number display unit 36, an acquired number display unit 37, a motor driver 100, and a hopper device 52 The sub control board 90, the external concentrated terminal board 91, and the like are connected.

The motor driver 100 controls the stepping motor 79 that rotates the reel 61 (left reel 61L, middle reel 61M, right reel 61R) based on excitation data input from the main control board 80.
Here, the excitation data is stored in the RAM 84, and in the stepping motor control process (step 206) of the timer interrupt process (FIG. 13) described later, the input / output port 82 (see FIG. 11) based on a command from the MPU 81. ), Appropriate excitation data is output. The excitation data determines the excitation phase for the stepping motor 79, and an excitation signal (current) is supplied to the excitation phase.

The sub control board 90 receives a command transmitted from the main control board 80 and performs an auxiliary control process other than a game, and is provided separately from the main control board 80.
The sub-control board 90 controls lighting / flashing of the upper lamp 13, output control of notification sound from the speaker 14, etc., and controls the display control board (not shown) to display effects on the liquid crystal display 15. It is configured.

  The external concentrated terminal board 91 has a plurality of terminals (not shown), and the main control board 80 and a hall computer (not shown) for monitoring the state of the slot machine are connected to the external concentrated terminal board 91. It is comprised so that it can connect via each terminal.

  A terminal (not shown) in the external concentrated terminal plate 91 is constituted by a photocoupler, a light emitting diode which is the primary side of the photocoupler is connected to the main control board 80 of the slot machine 10, and a light receiving element which is the secondary side. (Phototransistor) is connected to the hall computer.

  Therefore, the communication between the slot machine 10 and the hall computer performed through the external concentrated terminal board 91 is performed from the slot machine 10 connected to the primary side of the photocoupler constituting the terminal to the secondary side of the photocoupler. One-way communication with the hall computer connected to the slot computer 10 prevents unauthorized transmission of electrical signals (such as pulse signals) from the hall computer to the slot machine 10 side.

Next, each process performed in the main control board 80 will be described with reference to the flowcharts shown in FIGS. 12 to 21 and FIGS. 26 to 32.
In the embodiment, as a process performed in the main control board 80, a main process activated upon power-on, a timer interrupt process activated periodically (in this embodiment, 1.49 ms cycle), An NMI interrupt process activated by input of a power failure occurrence signal to the NMI terminal is set.
In the following description, for convenience, the NMI interrupt process and the timer interrupt process will be described, and then the main process will be described.

[NMI interrupt processing]
FIG. 12 is a flowchart showing an example of the NMI interrupt process.
When the power is shut off due to the occurrence of a power failure or the like, a power failure occurrence signal is input from the power failure monitoring circuit 56b to the MPU 81 of the main control board 80. When a power failure occurrence signal is input via the NMI terminal, the MPU 81 immediately executes the NMI interrupt process.
As described above, when the main control board 80 is configured to provide the INT terminal instead of the NMI terminal, the power failure occurrence signal of the power failure monitoring circuit 56b is input via the INT terminal.

In the NMI interrupt process, in step 101, a process (register save process) is executed to save the data of the used register provided in the MPU 81 to the stack area provided in the RAM 84.
In step 102, a power failure flag is set, and power failure occurrence information is set in a predetermined work area provided in the RAM 84.
In step 103, a process of restoring the data saved in the stack area to a use register mounted on the MPU 81 (register return process) is executed, and the process of this routine is terminated.
If the power failure flag can be set without destroying the data in the register used, the register saving process and the register restoring process can be omitted.

[Timer interrupt processing]
FIG. 13 is a flowchart of a timer interrupt process that is periodically executed by the main control board 80 (every 1.490 ms in the present embodiment).

In the register saving process in step 201, the values of all registers in the MPU 81 used in the normal game process (see FIG. 16) are saved in the stack area of the RAM 84.
In step 202, it is confirmed whether or not the power failure flag is set. If it is set, the power failure process shown in FIG. 14 is executed (step 203). If it is not set, the power failure process is executed. Instead, it is skipped.
And the process after step 204 is performed sequentially.

In step 204, a watchdog timer clear process for initializing (clearing) the value of the watchdog timer that monitors the occurrence of malfunction is executed.
In step 205, an interrupt end declaration process for giving an interrupt permission to the MPU 81 itself is executed.

In step 206, a driving process (stepping motor control process) of the stepping motor 79 that rotates each reel 61 (61L, 61M, 61R) of the reel unit 60 is executed.
In the stepping motor control process, a drive signal (excitation data) for driving the stepping motor 79 is output. Details of this process will be described later with reference to the flowcharts of FIGS.

  In step 207, a switch state reading process for reading the states of various switches and buttons 41 to 49 connected to the input / output port 82 is executed.

In step 208, sensor monitoring processing for monitoring the state of various sensors connected to the input / output port 82 is executed.
In step 209, timer subtraction processing for subtracting the value of each counter or timer is executed.

In step 210, the number of medals inserted from the medal insertion slot 50, the number of medals bet in the game (the number of bets), and the number of medals paid out from the slot machine 10 (the number of payouts) are counted. IN / OUT counter processing is executed.
In step 211, command output processing for transmitting a command to the sub control board 90 or the like is executed.

In step 212, a segment data setting process (segment data setting process) displayed on each of the credit number display unit 35, the game number display unit 36, and the acquired number display unit 37 is executed.
In step 213, the set segment data is output to the credit number display unit 35, the game number display unit 36, and the acquired number display unit 37 to display character information such as numbers and symbols (segment data display processing). Is executed.
In step 214, port output processing for outputting output data (command data, excitation data, etc.) from the input / output port 82 is executed.

In step 215, a process of restoring the value of each register saved in the stack area to the corresponding register in the MPU 81 (register return process) is executed.
In step 216, an interrupt permission process for permitting subsequent timer interrupts is performed, and the series of timer interrupt processes is terminated.

[Processing during power failure]
FIG. 14 is a flowchart of a power failure process executed by the main control board 80.
As described above, the power failure process is executed in the timer interrupt process (step 203 in FIG. 13).

Since this power failure process is executed immediately after the register saving process (step 201) of the timer interrupt process, other interrupt processes can be executed without interruption.
Therefore, during the process of sending a power recovery command or the like, during the reading of the switch status (on / off), the contents of the counter are being updated, and this power failure process is not executed by interrupting each process. . That is, since the power failure processing is not executed at irregular timing, it is not necessary to create a power failure processing program that takes into account that the processing is performed at irregular timing. This simplifies the processing program for power failure processing and reduces the program capacity. The same applies to the power recovery process.

  In addition, the process may be returned (returned) to the timer interrupt process after the power failure process, but the power failure process is executed immediately after the register save process. There is no need to perform the return processing. Accordingly, the processing program for power failure processing is simplified, and the program capacity can be reduced.

  In the power failure process, in step 301, whether or not a command is being transmitted is confirmed based on whether or not the value of a command counter (not shown) that handles a normal command is an odd number. If the command is being transmitted (Yes in step 301), the power failure process is terminated and the process returns to the timer interrupt process (FIG. 13).

  Since command data is transmitted in 1-byte units, one command transmission is completed with two timer interrupts. When the value of the command counter used for buffering the command is an odd number, the command data transmission of the second byte of the command data is not completed. In this case, the command is being transmitted. If it is determined that there is, the process returns to the timer interrupt process, and the power failure process is not executed.

  The command data of the second byte that has not been transmitted is transmitted in the command output process (FIG. 13, step 211) that occurs during the next timer interrupt process executed after the return. At the next timer interrupt processing timing, this command transmission processing is completed.

  In this way, at the beginning of the power failure process, it is determined whether or not the command transmission has been completed. When the transmission is incomplete, the transmission process is given priority. After the unit command transmission process is completed, the power failure process is performed. If executed, there is no need to construct a power failure processing program or a power recovery processing program that takes into account that the power failure processing is executed in the middle of command transmission. As a result, the power failure processing program can be simplified and the capacity of the program memory (ROM 83) can be reduced.

  Here, since it is necessary to execute the timer interrupt process twice in order to complete the transmission of the unit command, the timer interrupt process can be executed at least three times or more. The output of the stabilization voltage (5 volts) used as the drive voltage of the control system needs to be maintained for a time sufficient to execute the processes described above.

In the embodiment, since the period of the timer interrupt process is 1.49 msec, the power supply of the power supply device 56 is not less than + α after the power failure occurs (1.49 msec × 3 times = 4.47 msec), for example, for 30 msec. The drive voltage is continuously output from the unit 56a.
Therefore, even if a power failure occurs during the transmission of the command, the main control board 80 can normally execute the power failure process.

When the command is not being transmitted in step 301, the interruption process after step 302 is executed.
In step 302, the value of the stack pointer of the MPU 81 is stored in the stack pointer storage memory area 84b in the RAM 84. In step 303, the value of the checksum correction value memory area 84a is cleared (= 0), and In step 304, the output state of the output port in the input / output port 82 is cleared, and all actuators (not shown in FIG. 11) are turned off.

In step 305, all the values in the RAM 84 are added to calculate a checksum. In step 306, a two's complement is obtained from the calculated checksum, and this is newly used as a checksum correction value memory. Write to area 84a.
By using the correction value obtained by this calculation process, the checksum of the RAM 84 becomes zero. By setting the checksum of the RAM 84 to zero, subsequent writing to the RAM 84 is prohibited (step 307).

In step 308, it is confirmed whether or not a power failure occurrence signal is still input.
The processing in step 308 is repeated until the drive voltage of the control system becomes equal to or lower than the stabilization voltage (5 volts), and during that time, infinite loop processing is performed.

  In step 308, if the power failure occurrence signal is not input before the drive voltage of the control system becomes equal to or lower than the stabilization voltage (5 volts), the power failure state is recovered in this case. In step 310, the power failure flag is reset, and then the process returns to the timer interrupt process (FIG. 13).

  Since this power failure process is performed immediately after the register saving process (step 201 in FIG. 13) of the timer interrupt process, the saving process from a plurality of registers provided in the MPU 81 is not performed. Therefore, since the return processing to these registers is not required when the return instruction is executed, the capacity of the power failure processing program can be reduced.

  The power failure occurrence signal is checked not only during the processing during power failure, but also after the execution until the drive voltage drops below the stabilization voltage (5 volts). For example, the power failure flag is incorrect due to noise, etc. Even if it has been set, control can be returned to normal without entering an infinite loop.

[Main processing]
FIG. 15 is a flowchart of main processing executed by the main control board 80 when power is turned on. When the power switch is turned on and the slot machine 10 is turned on (including power-on due to recovery from a power failure), this process is executed.
First, as an initialization process, a stack pointer value is set (step 401), an interrupt mode is set (step 402), and a CTC / built-in register setting process is performed (step 403).

When the initialization process is completed, in step 404, it is confirmed whether or not the reset switch 123 (see FIG. 4) is turned on.
If it is turned on, a RAM clear process is executed in step 405, and all the data written in the RAM 84 is cleared (cleared to 0).

  If the reset switch 123 is not turned on in step 404, the on / off state of the setting key switch 122 (see FIG. 4) is confirmed in step 406.

  If it is in the ON state in step 406, the RAM clear process is executed in step 407, and all the data written in the RAM 84 is cleared (cleared to 0). In step 408, the operation position of the setting key switch 122 is set. A corresponding six-stage probability setting process is executed.

If it is determined in step 406 that the setting key switch 122 is not in the on state, that is, in the off state, it is confirmed in step 409 whether or not the power failure flag is set.
When the RAM clear process (steps 405 and 407) is executed, the backup data in the RAM 84 is cleared and the power failure flag is reset.
Therefore, when the power failure flag is not set (reset), the process shifts to a normal game process (step 410) described later, whereby the normal game process is repeatedly executed in the slot machine 10.

If the power failure flag is set in step 409, the process proceeds to power recovery processing in step 411 and thereafter.
Here, when the power failure flag is set, the RAM clear process (steps 405 and 407) is not executed, and the data in the RAM 74 is not rewritten at all. In the processing, it is confirmed whether or not the data in the RAM 84 is normal.

In the power recovery process, in step 411, the checksum value in the RAM 84 is checked to determine whether or not the value is normal.
Specifically, if the checksum value including the checksum correction value is zero, it is determined to be normal.
This is because when the backup data is written to the RAM 84 in the power failure process (FIG. 14), the correction value is set so that the checksum value of the RAM 84 becomes zero, and the checksum value is zero. This is because the backup process to the RAM 84 is normally performed.

If the checksum value is not normal in step 411, that is, if the checksum value is not zero, there is a high possibility that the data has been destroyed during the backup process to the RAM 84. Is executed.
Specifically, in step 412, the next timer interrupt process is prohibited, and in step 413, all output ports in input / output port 82 are cleared, and all actuators connected to input / output port 82 are disconnected. In step 317, an error display process is executed to notify the occurrence of a backup error, and then an infinite loop is entered.

  If it is determined in step 411 that the checksum value is normal, the stack pointer value stored in the backup area of the RAM 84 is written in the stack pointer of the MPU 81 in step 415, and the stack status is changed to the power supply. Processing for returning to the state before disconnection (stack pointer return processing) is executed.

In step 416, a command (recovery command) used at the time of power recovery processing is set and stored in the RAM 84.
In step 417, the game state is stopped and automatic settlement setting processing is executed. In step 418, initialization of the switch state and the like are executed.

  In step 419, the power failure flag is reset, the power failure occurrence information is initialized, and then the address before the power interruption is restored. Specifically, the process returns to the timer interrupt process (FIG. 13), and the watchdog timer clear process (step 204) is executed.

[Normal game processing]
Next, normal game processing for performing main control related to the game will be described based on the flowchart of FIG.

  When the start lever 45 is operated after a bet is placed (Yes in Step 501 and Step 502), a lottery process in Step 503, a reel control process in Step 504, a medal payout process in Step 505, and a step After the special game state process of 506 is executed in order, the process returns to the process of step 501.

  Note that if no medal is bet in step 501, or if the start lever 45 is not operated in step 502 even if a medal is bet in step 501, the process returns to step 501. Thus, until the bet of medals and the operation of the start lever 45 are performed, the determination processing of step 501 and step 502 is repeatedly executed.

[Lottery processing]
The lottery process in step 503 will be described based on the flowchart of FIG.

In step 601, a random number table for determination of success / failure is selected based on the current setting state of the slot machine 10, the number of medals bet, the degree of small role probability, and the like.
Here, the setting state of the slot machine 10 is any one of “setting 1” to “setting 6” set using a setting key (not shown), and the random number having the lowest winning probability of the combination when “setting 1” is set. A table is selected, and when “setting 6” is selected, the random number table having the highest winning probability of the combination is selected.
The number of medals bet is any one of 1 to 3, and a random number table is selected such that as the number of bets increases, the winning probability of winning combination increases. For example, the winning probability of a combination when three bets are bet is three times higher than the winning probability of a combination when one bet is placed.
In addition, there are two types of small role probabilities, and when the current medal payout rate (play rate) is below a predetermined expected value, a random number table with a high small role winning probability is selected, and the predetermined expected value When the number exceeds the random number table, the random number table with the low probability of winning the small role is selected.

  In step 602, the lottery of the winning combination is executed by comparing the random number table selected in this way with the random number latched by the random number counter when the start lever 45 is operated. In step 603, it is confirmed whether or not any of a plurality of preset winning combinations has been won. If no winning combination has been won, the processing is terminated.

  If any winning combination is won, in step 604, the winning winning combination flag (winning flag) is set, and the effective line to which the symbols should be aligned is determined. Therefore, when the winning winning combination is BB (Big Bonus), the BB winning flag is set.

In step 605, a slip table for reel stop control is determined and stored in the slip table storage area of the RAM 84.
Here, the slip table means that when the symbol on the predetermined effective line at the timing when the stop buttons 46 to 48 are pressed differs from the symbol to be stopped on the effective line, the symbol to be stopped is predetermined. It is a table that defines how much the reel slides so as to stop on the active line.

  When the lottery process is completed, the reel control process (step 504) is executed in the normal game process of FIG.

[Reel control processing]
Next, the reel control process (FIG. 16, step 504) of the normal process will be described with reference to the flowchart of FIG.

In the reel control process, a wait process is first executed in step 701. This wait process is a process of waiting for a predetermined time (eg, 4.1 seconds) from the start of reel rotation in the previous game without starting reel rotation in the current game. .
For this reason, even if the player bets a medal and operates the start lever 45, the reels 61 (61L, 61M, 61R) may not immediately rotate.

  When the weight process of step 701 is executed, the reel rotation process of step 702 is executed, and the reels 61 (61L, 61M, 61R) rotate. The reel rotation process will be described later in detail.

In step 703, it is confirmed whether or not a stop command for the reels 61L to 61R is generated by pressing one of the stop buttons 46 to 48. If no stop command has been issued, it is checked in step 704 whether a predetermined maximum rotation time (for example, 40 seconds) of each reel 61 (61L, 61M, 61R) has elapsed.
If the maximum rotation time has not elapsed, the process returns to step 703. If the maximum rotation time has elapsed, in step 705, all the reels 61 (61L, 61M, 61R) that are rotating are rotated. A forced stop process for forcibly stopping is executed.

If a stop command has been issued in step 703, reel stop processing is performed in step 706.
In this reel stop process, the reels 61 (61L, 61M, 61R) corresponding to the pressed stop buttons 46 to 48 are stopped according to the operation timing of the stop buttons 46 to 48. At this time, if any of the winning combinations is won in the above-described lottery process (FIG. 16, step 503) and the winning flag is set, refer to the sliding table 84c stored in the RAM 84. The stop of the reel 61 is controlled as much as possible so that the symbol of the winning combination stops on the active line.

For example, the “watermelon” symbol is placed on the lower horizontal line c (lower effective line), and the stop button is pressed at the timing when the “watermelon” symbol stops on the upper horizontal line a. In this case, the reel is stopped after sliding by two symbols so that the “watermelon” symbol stops on the lower effective line c. That is, the reel is rotated after being rotated a lot.
However, since the range that can be slid is determined in advance (for example, up to four symbols), depending on the timing of pressing the stop button, the “watermelon” symbol may not stop on the lower effective line c. There is also.
Even in the forced stop process in step 705, if the winning flag is set, the same process may be performed.

Subsequently, in step 707, it is confirmed whether or not the current stop command is the first stop command. Here, the first stop command is a command that is output when the stop button is pressed while all the three reels 61 (61L, 61M, 61R) are rotating.
If the stop command is the first stop command in step 707, the slip table changing process is executed in step 708.

In this slide table change process, for example, when the symbol of the winning combination is stopped on the active line, it is confirmed whether or not the combination of the combination is generated. If the combination of the combination does not occur, the next step is continued. When a combination of combinations occurs, the effective line is changed to another effective line, and after changing to the sliding table for the changed effective line, the process proceeds to the next step.
Here, the combination of roles is a plurality of combinations, for example, when “watermelon” symbols appear on the upper horizontal line “a” and the “cherry” symbols appear on the lower horizontal line “c” on the left reel. This is the case where the roles occur simultaneously. The slip table changing process may be performed other than when avoiding the combination of the combinations.

If it is determined in step 707 that the stop command is not the first stop command, it is confirmed in step 709 whether or not it is a second stop command.
Here, the second stop command is a command that is output when one of the three reels is stopped and the stop button is pressed while the two reels are rotating.

If the stop command is the second stop command in step 709, stop eye determination processing is executed in step 710.
In the stop eye determination process, after the second reel is stopped, whether the symbols located on the same active line of the two reels that are stopped are the same bonus symbols such as the symbol “7” or not. To check. If it is not a bonus symbol, the process proceeds to the next step as it is. If it is a bonus symbol, the player confirms that the bonus winning is confirmed when the bonus symbol of the reel to be stopped last stops on the active line. For example, after performing a notification process such as generating a sound effect from the speaker 14, for example, the process proceeds to the next step.
In the stop eye determination process, it may be determined whether another condition other than two bonus symbols is satisfied, or an effect using the liquid crystal display 15 may be performed in addition to the sound effect.

Then, following the forced stop process in step 705, the slip table change process in step 708, or the stop eye determination process in step 710, or in step 709, if the stop command is not the second stop command, It is confirmed whether all the reels 61 (61L, 61M, 61R) are stopped.
If all the reels 61 are not stopped, the process returns to step 703. If all the reels 61 are stopped, the payout determination process is executed in step 712, and the process ends. To do.

In the payout determination process, it is confirmed whether or not the winning symbols are arranged on the effective line. If the symbols are not arranged on the effective line, the value of the payout scheduled number counter 84d in the RAM 84 is set to “0”, If the symbols are arranged on the active line, it is confirmed whether or not the symbol matches the symbol of the winning combination in the lottery process (FIG. 16, step 503).
If they do not match, an error is displayed by the upper lamp 13 and the like, and “0” is set to the value of the scheduled payout counter 84d.
On the other hand, if they match, the payout number corresponding to the combination of symbols arranged on the active line is set to the value of the payout number counter 84d.
As shown in FIG. 10, when three bell symbols are aligned on the effective line, “10” is set to the value of the scheduled payout counter 84d.

  When this reel control process ends, a medal payout process (step 505) is executed in the normal game process of FIG.

[Medal payout processing]
Details of the medal payout process will be described with reference to the flowchart of FIG.
In this medal payout process, it is checked in step 801 whether or not the planned number of medals to be paid out from the gaming machine (scheduled payout number) matches the number of medals paid out (payout number).
Here, the payout number is specified by the value of the payout number counter 84e in the RAM 84, and the planned payout number is specified by the value of the payout number counter 84d in the RAM 84.

If it is determined in step 801 that the payout number does not match the planned payout number, it is checked in step 802 whether or not the game is performed in the credit mode.
Whether or not the credit mode is set is specified based on the output signal of the switching operation detection sensor 44a.

  If it is in the credit mode, it is confirmed in step 803 whether or not the number of medals (credit number) electronically stored on the gaming machine side has reached the upper limit number (for example, 50).

If the upper limit number has not been reached, in step 804, the value of the credit number counter and the value of the payout number counter 84e are respectively incremented (incremented) by “1”.
Accordingly, the number of medals displayed on the credit number display unit 35 and the acquired number display unit 37 of the display panel 30 is added by “1” respectively.

On the other hand, if the game is not performed in the credit mode in step 802 (when the game is performed in the direct mode), or if the credit number has reached the upper limit number in step 803, the hopper device 52 is determined in step 805. The medal payout rotating plate (not shown) is driven to pay out the medals in the hopper device 52 to the medal tray 18 of the front door 12.
Here, since the hopper device 52 is provided with a sensor (medal payout detection sensor 52a) for counting the number of paid out medals, it corresponds to the medal detection signal output from the medal payout detection sensor 52a. Then, “1” is added to the value of the payout number counter 84e that counts the number of payout medals. As a result, “1” is added to the number of acquired medals displayed on the acquired number display portion 37 of the display panel 30.

When the process of step 804 or step 806 ends, the process returns to step 801. If it is determined in step 801 that the payout number matches the planned payout number, the medal payout process is terminated.
Therefore, the processing from step 802 to step 804 or step 806 is repeated until the number of payouts from the hopper device 52 or the sum of the number of payouts from the hopper device 52 and the number of credits matches the planned payout number. Executed.

When the payout number matches the planned payout number, in step 807, the medal payout rotating plate (not shown) of the hopper device 52 is stopped, and the medal payout process is ended.
Note that the values of the payout number counter 84e and the planned payout number counter 84d are reset when the start lever 45 is operated in the next game.

  When the medal payout process is completed, the special game state process (step 506) is executed in the normal game process of FIG.

[Special gaming state processing]
The special game state process will be described with reference to the flowchart of FIG.
Here, in the embodiment, RB (regular bonus) and BB (big bonus) are set as the winning combination in the special gaming state.
In the special gaming state process of FIG. 20, in step 901, it is confirmed whether or not the gaming state of the gaming machine is a special gaming state (RB, BB).

Here, RB (regular bonus) is composed of 12 JAC games.
The JAC game is a game in which only one medal can be betted, and is a game with a very high probability that a JAC symbol (here, a replay symbol is substituted) is aligned on an active line (probability of establishing a JAC symbol).
In this JAC game, when the JAC symbols are aligned on the active line (the JAC symbols are established), the maximum number (for example, 15) of medals is paid out. In addition, when the JAC symbol is established eight times, the RB is ended even before 12 JAC games are consumed.

BB (Big Bonus) is composed of 30 small role games and 3 JAC ins.
The small role game is a game with a high probability that the small role formation symbols (for example, “bell”) are aligned on the active line.
The JAC in means that 12 JAC games are entered, and the JAC game is started when the JAC symbols are aligned on the active line during the small role game.
The content of the JAC game in the BB is the same as that of the RB JAC game described above, and a maximum of three JAC ins are possible during the BB.
Note that when the JAC game by the third JAC in is finished, the BB is finished even before the 30 small-games are digested.

  In step 901, if the gaming state is not the special gaming state (not in the bonus game), a bonus symbol determination process is executed in step 902.

[Bonus symbol determination processing]
FIG. 21 is a flowchart of the bonus symbol determination process. FIG. 22 is a table (RB initial value table) showing initial values of values set in the respective counters when a winning in RB is confirmed. (A) of FIG. 23 is a table (BB initial value table) showing initial values of values set in the respective counters when it is determined whether or not winning to BB is confirmed, and (b) is a jack-in during BB. It is a table (JAC-in initial value table) showing the initial values of the values set in each counter.

In the bonus symbol determination process shown in FIG. 21, it is confirmed in step 1001 whether or not the RB winning flag is set.
This is because, as a result of the lottery process (step 503 in FIG. 16) described above, if the RB is won, the RB winning flag is set.

When the RB winning flag is set (Yes in Step 1001), in Step 1002, an RB symbol (for example, symbol “7”) is placed on the active line in order to confirm whether or not winning in the RB is confirmed. Check if they are ready.
This is because even if the RB is won in the internal lottery, if the RB winning symbols are not on the active line when the reels 61 (61L, 61M, 61R) are stopped, the RB winning is not fixed. .

In step 1002, if the RB winning symbols are not aligned on the active line, the processing is terminated.
On the other hand, if they are on the active line (Yes in Step 1002), in Step 1003, after resetting the RB winning flag and setting the RB setting flag indicating that the RB winning is confirmed, Initial values defined in the RB initial value table (FIG. 22) are set to the values of the counters used during the RB.
Specifically, as shown in FIG. 22, since there is no small role game in RB, the value of the remaining small role game counter is set to “0”, the value of the remaining JAC in-counter is set to “1”, The value of the remaining JAC establishment counter is set to “8”, and the value of the remaining JAC game counter is set to “12”.

If the RB winning flag is not set in step 1001, it is checked in step 1004 whether or not the BB winning flag is set.
This is because, as a result of the lottery process (step 503 in FIG. 16) described above, if the BB is won, the BB winning flag is set.

If the BB winning flag is not set, the process is terminated.
On the other hand, when the BB winning flag is set (Yes in Step 1004), in Step 1005, in order to confirm whether or not the BB winning is confirmed, the BB symbol (for example, the symbol “7 (super)” )) On the active line.
This is because even if the BB is won by the internal lottery, if the BB winning symbols are not on the active line when the reel 61 (61L, 61M, 61R) is stopped, the winning to the BB is not confirmed. .

In step 1005, if the BB winning symbols are not aligned on the active line, the process is terminated.
On the other hand, if they are on the active line (Yes in step 1005), after resetting the BB winning flag and setting the BB setting flag indicating that the BB winning has been confirmed in step 1006, The initial values defined in the BB initial value table ((a) of FIG. 23) are set to the values of the counters used during BB.
Specifically, the value of the remaining small role game counter is set to “30”, and the value of the remaining JAC in-counter is set to “3”.

Here, the contents of each counter defined in the RB initial value table (FIG. 22) and the BB initial value table ((a) of FIG. 23) will be described.
The remaining small role game counter indicates the number of remaining games of the small role game, the remaining JAC in counter indicates the remaining number of times that JAC can be performed, the remaining JAC establishment counter indicates the remaining number of times that the JAC symbol can be established, The JAC game counter indicates the number of remaining JAC games.
In the embodiment, the values of these counters are appropriately displayed on the game number display section 36 of the display panel 30 (see FIG. 1).

Incidentally, as a result of the lottery process of the normal process (step 503 in FIG. 16), when the small role or replay is won and the small role winning flag or the replay winning flag is set, the reel 61 (61L, 61M, 61R), if the winning symbols for the small combination or replay are not on the active line, the small combination winning flag or the replay winning flag is reset.
On the other hand, in the case of the RB winning flag and the BB winning flag, the flag is not reset even if the winning symbols are not aligned on the active line when the reel 61 (61L, 61M, 61R) is stopped. However, it is left set and carried over to the next game.

  In the lottery process (step 503 in FIG. 16) in the next game in which the BB winning flag or the RB winning flag is carried over, the lottery for the small role or replay is performed, but the lottery for the BB or RB is not performed. Further, in the game in which the BB winning flag or the RB winning flag is carried over, when a small combination or replay is won, a sliding table is stored so that the small combination or replay is preferentially arranged.

Returning to the description of the special game state processing in FIG. 20, if the special game state is in step 901 (in the case of a bonus game), it is confirmed in step 903 whether or not the JAC game is in progress.
If it is not during the JAC game, it means that it is during the small role game of the BB game, so the process proceeds to step 904, where it is confirmed whether or not the JAC symbols are aligned on the active line.

If the JAC symbols are aligned on the active line (Yes in Step 904), in Step 905, the value of each counter used during the JAC game in BB is added to the initial value table for the JAC game in BB ( The initial value defined in (b) of FIG. 23 is set, and the JAC game is started.
Specifically, the value of the remaining JAC establishment counter is set to “8”, and the value of the remaining JAC game counter is set to “12”.

On the other hand, if the JAC symbols are not aligned on the active line in Step 904, No) in Step 904 means that one small role game has been consumed, so the value of the remaining small role game counter is set in Step 906. Subtract "1" (decrement).
In step 907, in order to confirm whether or not the small-combination game has been executed a predetermined number of times that defines the end of the BB, it is confirmed whether or not the value of the remaining small-combination game counter is “0”.

  If the value of the remaining small role game counter is not “0” in step 907, the process ends. If it is “0”, a special gaming state end process is executed in step 908. Specifically, various setting flags (for example, BB setting flag) are reset, various counters (for example, the remaining small role game counter, see FIG. 23A), the special game state is terminated on the liquid crystal display 15. Processing for displaying an effect screen for telling the user is executed.

If it is determined in step 903 that a JAC game is in progress, it is checked in step 909 whether JAC symbols are aligned on the active line.
If they are present, in step 910, the value of the remaining JAC establishment counter is decremented (decremented) by 1, and then the process proceeds to step 911.
If not, the process of step 910 is skipped and the process proceeds to step 911.

  In step 911, since one JAC game has been consumed at this point, “1” is subtracted from the value of the remaining JAC game counter.

In step 912, it is confirmed whether any of the remaining JAC establishment counter and the remaining JAC game counter is “0”.
If neither the remaining JAC establishment counter nor the remaining JAC game counter is “0”, the JAC game has not been consumed the upper limit number (12 times), and the establishment of the JAC game symbol has not reached the upper limit number (8 times). Therefore, the process is terminated as it is.

  When the remaining JAC game counter is “0” (when the JAC game is consumed by the upper limit number (12 times)), or when the remaining JAC establishment counter is “0” (the number of times the JAC game symbol is established becomes the upper limit number) If it has reached, the value of the remaining JAC in-counter is decremented (decremented) by “1” in step 913.

  In step 914, it is confirmed whether or not the value of the remaining JAC in-counter is “0”. If it is “0”, the special gaming state end process in step 908 is executed.

  If the current special gaming state is RB, the RB setting flag indicating that the gaming machine state is RB is reset and various counters ( For example, the remaining JAC game counter or the like (see FIG. 22) is cleared to zero, and the liquid crystal display 15 is caused to display an effect process for informing the end of the special game state.

If the value of the remaining JAC in counter is not “0” in step 914, JAC in has not been digested three times in the BB game. Therefore, in step 915, JAC game end processing is executed, and the JAC game setting flag is set. It will be reset.
In addition, at the time of this JAC in, since one small game has been consumed, in step 906, the value of the remaining small role game counter is decremented (decremented) by “1”.
In step 907, in order to confirm whether or not the small-combination game has been executed a predetermined number of times that defines the end of the BB, it is confirmed whether or not the value of the remaining small-combination game counter is “0”.

  If the value of the remaining small role game counter is “0” in step 907, special game state end processing is executed in step 908. Specifically, various setting flags (for example, BB setting flag) are reset, various counters (for example, the remaining small role game counter, see FIG. 23A), the special game state is terminated on the liquid crystal display 15. A process for displaying the effect process for telling the user is executed.

  On the other hand, if the value of the remaining small role game counter is not “0” in step 907, the number of small role games in the BB has not reached the upper limit number (30 times), and the JAC in has not been digested three times. Therefore, the process is ended and the game in the next special game state is continued.

Next, motor control processing when the reel is rotated and when the reel is stopped will be described.
First, drive characteristics required when the stepping motor 79 is used as the drive motor of the slot machine 10 will be described with reference to FIG.

  This drive characteristic can be broadly divided into an acceleration period Ta from when the start lever 45 is operated until the stepping motor 79 starts rotating until reaching a constant constant speed rotation, and a constant speed rotation period. A maintenance period (constant speed time) Tb that continues to maintain the rotation speed until the stop buttons 46 to 48 are pressed, and a stop period Tc that stops with a predetermined slip on the basis of the pressing operation of the stop buttons 46 to 48. It is divided into.

  While there is no restriction on the length of the acceleration period Ta, when the stop buttons 46 to 48 are not operated, the time obtained by adding the constant speed period Tb to the acceleration period Ta must be 30 msec or more. There is a regulation. During the stop period Tc, it is required to fix the excitation phase of the stepping motor 79 within about 190 msec at the maximum after the stop buttons 46 to 48 are operated.

  Here, it is desirable that the stepping motor 79 is shifted from the acceleration state to the constant speed rotation state as soon as possible. To that end, it is only necessary to speed up the interruption to the excitation phase for the stepping motor 79 (switching from the excitation phase 1-phase excitation to 2-phase excitation and switching from 2-phase excitation to 1-phase excitation). As described above, there is a risk of causing step-out and rotation instability. Therefore, it is necessary to perform an optimum interrupt process that realizes the shortest acceleration process within a range not involving such a concern.

  In this embodiment in which an excitation signal is applied to the excitation coil by interrupt processing, it is necessary to set an appropriate interrupt timing for the excitation phase. For this reason, first, until the rotational fluctuation of the rotor 790 during motor acceleration is suppressed, the excitation state is fixed by the same excitation phase.

Basically, it is considered that step-out and rotational instability are difficult to resolve unless the state of initial excitation (excitation at zero initial speed) is maintained to some extent.
This is because the rotation of the rotor 790 generated when the teeth of the rotor 790 are attracted to the protrusions of the first pole 793 to the fourth pole 796 by the attraction force generated by the initial excitation (micro vibration with reciprocation). It depends on the degree of convergence.
Although it differs depending on the inertia of the reel 61 (61L, 61M, 61R), etc., according to the experiment, the rotor 790 stopped after the swing that reciprocated once in 30 msec repeated 5 to 6 reciprocating positions.
Accordingly, it has been found that, in order to perform acceleration processing while eliminating rotational fluctuation, it takes 150 to 180 msec at least after initial excitation as the time for fixing in the same excitation phase.

Therefore, a time exceeding this time may be set as the initial excitation holding period for fixing the initial excitation phase.
In the embodiment, since the timer interrupt process for the MPU 81 is executed every 1.49 msec, the initial excitation holding period is set to 1.49 msec × 130 interrupts = 193.7 msec (see FIG. 25). The reel acceleration control is executed. In addition, since it is only necessary to exceed 180 msec, 1.49 msec × 121 interrupt = 180.29 msec may be set as the initial excitation holding period.

  As a result, during the initial excitation holding period of 130 interrupts, excitation data for excitation signals shown in FIG. 8 (for example, excitation data 09H shown in excitation order 2) (H is hexa-digital display) is output from the input / output port 82. It is continuously output to the motor driver 100.

  In the acceleration period Ta, if the acceleration period for initial excitation is the first acceleration period and the acceleration period until the constant speed rotation is the second acceleration period, for example, as shown in FIG. In the acceleration period, interruption processing of the excitation signal to the excitation phase is frequently performed in order to reach constant speed rotation.

  Here, there is a problem whether the excitation phase of initial excitation is one-phase excitation or two-phase excitation. The initial excitation requires the rotor 790 to rotate with a high torque, and the excitation phase of the initial excitation is preferably two-phase excitation that can obtain a higher torque than the one-phase excitation. This is because of the following reasons.

First, in a hybrid (HB) type two-phase stepping motor adopting a 1-2 phase excitation method as a stepping motor, two-phase excitation can be considered in addition to one-phase excitation as an initial excitation phase during acceleration.
One-phase excitation drives only a specific excitation phase, and the rotational torque at the initial speed is obtained by this one-phase excitation. On the other hand, the two-phase excitation drives two specific excitation phases simultaneously, and the rotational torque at the initial speed is obtained by the two-phase excitation. Although it differs depending on the size of the reel, inertia, etc., it is possible to accelerate the reel from the initial speed zero even with one-phase excitation if it is a normal slot machine.

  However, in the case of one-phase excitation, a sufficient initial speed may not be obtained because the rotational torque generated is smaller than that in two-phase excitation. Since the possibility of step-out increases if sufficient initial speed cannot be obtained, initial excitation is preferably two-phase excitation. In addition, after applying the brake (braking) to the reel 61 (61L, 61M, 61R) based on the pressing operation of the stop buttons 46 to 48, it slides by a predetermined step angle and stops. When slipping and stopping, it is necessary to perform the next acceleration process while absorbing the deviation of this angle, and it is preferable that the electromagnetic attraction force in the initial excitation is as large as possible. In the case of two-phase excitation, the electromagnetic attraction force is larger than that in the one-phase excitation, so that it is possible to quickly absorb the rotational fluctuation caused by this angle shift. Considering the above comprehensively, the initial excitation is preferably the two-phase excitation rather than the one-phase excitation.

  A timing example as shown in FIG. 25 is suitable as an interrupt timing for quickly reaching a predetermined rotational speed within the second acceleration period when the initial excitation is set to two-phase excitation. Further, for the two-phase excitation as the initial excitation, the earliest excitation order 2 can be selected from the excitation orders shown in FIG. Of course, different excitation orders (excitation order 4, excitation order 6 or excitation order 8) may occur depending on the excitation phase when rotation is stopped. The excitation state is maintained for 130 interrupts (193.7 msec) after applying the excitation signal in synchronization with the interrupt timing every 1.49 msec.

  In the second acceleration period, 1-2 phase excitation is alternately repeated. As an interrupt timing (phase excitation holding period) to the excitation phase, as shown in FIG. 25, the excitation holding period of one phase excitation and the two-phase excitation are The excitation holding period is finely controlled. In this example, when entering the second acceleration period, the interrupt is gradually shortened so that the one-phase excitation following the two-phase excitation is performed for eight interrupts, and the next two-phase excitation is performed for seven interrupts. And the excitation time is gradually shortened, and finally, normal 1-2 phase excitation in which excitation phases are sequentially switched at the minimum interruption interval is set.

Therefore, as shown in FIG. 25, when the last excitation phase in the second acceleration period is two-phase excitation and this is one interrupt, the first excitation phase in the next constant speed rotation period is one-phase excitation. The interrupt interval is 1 interrupt.
In this way, the interrupt processing timing in the second acceleration period is shortened sequentially as it approaches constant speed rotation, so that high-speed acceleration processing can be realized in a short time, and smooth transition to constant speed rotation is possible. Is possible.
The second acceleration period shown in FIG. 25 is an example when the entire acceleration period Ta is set to 317.370 msec, and when the entire acceleration period Ta is set to a different time, It goes without saying that the second acceleration period is selected according to the time and interrupt processing different from that in FIG. 25 is performed.

Returning to the description of the drive characteristics of the stepping motor 79 in FIG. 24, when the reel 61 (61L, 61M, 61R) is stopped, as described above, the slip process (rotation process for 1 to 4 symbols) and the brake process are performed. Must be performed within a predetermined time ts (= 190 msec).
When brake processing is performed, four-phase excitation is performed immediately after two-phase excitation. When the braking process is performed only by the two-phase excitation, there is a possibility that the rotation speed is drastically decreased due to a strong braking force and the rotation is distorted. However, by performing the four-phase excitation immediately after the two-phase excitation, the reels 61 (the left reel 61L, the middle reel 61M, and the right reel 61R) can be stopped smoothly without disturbing the rotation. Further, since it is easier to specify the rotational position in the case of the two-phase excitation than in the case of the one-phase excitation, the stop position accuracy can be improved by performing the four-phase excitation immediately after the two-phase excitation. Therefore, the stop position accuracy can be improved by performing the four-phase excitation immediately after the two-phase excitation.

A drive signal generation process for driving the stepping motor 79 is performed by a timer interrupt process (FIG. 13) periodically executed by the MPU 81.
As the drive signal, the excitation data of the excitation table 83a (see FIG. 8) stored in the ROM 83 is used. As shown in FIG. 8, the excitation table 83a defines the order in which excitation data is used (excitation order), and the excitation data is supplied to the motor driver 100 in accordance with the excitation order.
Therefore, the excitation data of the excitation table 83a is read in order and written to the output port of the input / output port 82 every time a timer interrupt occurs.
The excitation data written in the input / output port 82 is immediately supplied to the motor driver 100, and energization processing is performed on the excitation coils L0 to L3.

Here, the control related to the rotation of the reel executed in the main control board 80 will be described.
Specifically, the reel rotation process (step 702 in FIG. 18) executed in the reel control process (FIG. 16, step 504) of the normal game process, and the stepping motor control process (step in FIG. 13) executed in the timer interrupt process. 206) will be described.
For convenience of explanation, the stepping motor control process will be described first, and then the reel rotation process will be described.

[Stepping motor control processing]
FIG. 26 is a flowchart showing details of the stepping motor control process (step 206 in FIG. 13) executed in the timer interrupt process.
In this stepping motor control process, when the initialization process related to the control of the stepping motor 79 is completed in step 1101, a drive signal (excitation data) generation process for controlling the rotation of the stepping motor 79 is performed in the motor control process of step 1102. Is executed, and the generated excitation data is temporarily stored in the RAM 84. In the motor control process, in addition to the excitation data generation process, a symbol offset process, a symbol number update process, and the like are executed.

A drive signal (excitation data) generation process for rotation control (excitation data acquisition process from the RAM 84) and the like are sequentially executed for each reel 61 (61L, 61M, 61R). Excitation data generation processing for one reel 61, for example, the left reel 61L, is performed using rotation control data (described later) for the left reel 61L provided in the work area of the RAM 84, and the generation processing is performed. When the process is completed, the process proceeds to excitation data generation processing for the next reel, for example, the middle reel 61M.
Therefore, in step 1103, a transition process (address change process) to the next work area is performed in software, and in the subsequent step 1104, it is confirmed whether or not the excitation data generation process for all reels has been completed. If the excitation data generation processing for all the reels has not been completed, the process returns to step 1102, and excitation data generation processing for the remaining reels is performed.

  When rotation control processing for all three reels 61 (61L, 61M, 61R), that is, generation of excitation data, is completed, in step 1105, each reel 61 (61L, 61M, 61R) among the data stored in the RAM 84 is stored. ) Is output to the input / output port 82.

  Since the output to the input / output port 82 is a data writing process to the corresponding output port of the input / output port 82, the excitation data is supplied to the motor driver 100 simultaneously with the writing of the excitation data to the input / output port 82. It will be. As a result, the stepping motor 79 is immediately energized to the excitation phase specified by the excitation data, and the rotor 790 is excited.

27 and 28 are specific processing examples of the motor control processing (step 1102) in the stepping motor control processing.
In this motor control process, at least a wait timer 84f, an acceleration counter 84g, and an excitation order pointer 84h (all software processes using the RAM 84) are used.

Here, when one timer interruption period is defined as a unit excitation time T, an excitation time (number of timer interruptions) in the same excitation mode is set in the wait timer 84f.
An example is shown in FIG. In the first acceleration period, the two-phase excitation mode (acceleration order 1) is continuously executed for 130 units, that is, 130 interrupts. Therefore, “130” is set in the wait timer 84f. Incidentally, the total excitation time at that time is 130 × 1.49 msec = 193.7 ms. This is because the timer interruption is performed every 1.49 msec.
Similarly, for example, in the second acceleration period, in the acceleration sequence 2, the one-phase excitation mode is continuously executed over 8 units (= 8 interrupts = 8 excitation times). 8 "is set.

  The acceleration counter 84g is for designating the acceleration order in FIG. In the case of FIG. 25, the acceleration process is composed of 25-step excitation patterns (acceleration order 1 to 25). In order to designate a specific acceleration position, a counter value (acceleration counter value) from “0” to “24” may be designated as shown in FIG. 25, so that the initial value of the acceleration counter is originally “24” or Although “0”, as will be described later, in the software configuration in this embodiment, the initial value set in the acceleration counter is “25”.

  Since the contents of the acceleration table in FIG. 25 are stored in the ROM 83, FIG. 25 may be referred to as an excitation time and acceleration counter table.

  The excitation order pointer 84h is a pointer used when determining the excitation phase for the stepping motor 79. When the stepping motor 79 for 1-2 phase excitation is used, 1-phase excitation and 2-phase excitation are performed alternately. The phase excitation pattern at that time is 8 patterns as shown in the excitation table 83a of FIG. Which excitation data is acquired at which phase excitation is designated by the value (0 to 7) of this excitation order pointer.

  The value of the excitation order pointer 84h at the start of rotation differs depending on which pattern the excitation phase used when the motor was stopped immediately before, as will be described later. During rotation, it is used while sequentially updating the excitation order pointer value.

  Subsequently, the motor control process will be described in relation to the operation of the start lever 45 and the stop buttons 46 to 48. The following description is merely an example of processing for the stepping motor 79 for controlling one reel.

[No. Processing before operation of start lever 45]
The value of the wait timer 84f before the start lever 45 is operated is “0 (zero)”, and the value of the acceleration counter 84g is also “0 (zero)”.
Therefore, when the motor control process is called, since the value of the wait timer 84f is zero (step 1201), the process proceeds to step 1211 to check the value of the acceleration counter 84g. Since the value of the acceleration counter 84g is also zero, in this case, the output excitation data is set to “0 (zero)” in step 1212 and stored.
Thereafter, the process returns to the timer interrupt process of FIG. Since the output excitation data is zero, in the mode before the operation of the start lever 45, the stepping motor 79 is in a rotation stopped state.

[No.2. Processing when start lever 45 is operated]
The operation of the start lever 45 is detected in the normal game process (step 502 in FIG. 16). When the operation of the start lever 45 is detected, the value of the acceleration counter 84g is set to “25” in a reel rotation process described later.

Even if the start lever 45 is operated, the value of the wait timer 84f is still “0 (zero)”. In this case as well, the routine proceeds to step 1211 through step 1201 to determine the value of the acceleration counter 84g.
When the start lever 45 is operated, “25” is set to the value of the acceleration counter 84g. In this case, a subtraction process is executed in step 1221. As a result, since the value of the acceleration counter 84g is not “0 (zero)” (step 1222), the setting process of the wait timer 84f is executed in step 1231. In step 1231, the excitation time value corresponding to the value of the acceleration counter 84 g after the subtraction process is executed in step 1221 is acquired from the acceleration table of FIG. 25, and the acquired excitation time value is the weight timer 84 f. Set to

  Since the subtraction process in step 1221 is a process of decrementing (subtracting) by 1, the value of the acceleration counter after the subtraction is “24”. In this case, as apparent from the table of FIG. 25, the value (= 130) of the excitation time (130 interrupt) corresponding to the acceleration counter value “24” is set in the wait timer 84f. Thus, the continuous phase excitation time (= 130 × 1.49 msec) corresponding to the first acceleration period is set.

When the process for setting the wait timer is completed, an update process for incrementing the value of the excitation order pointer 84h by “1” is executed (step 1232). Then, the excitation data corresponding to the updated value of the excitation order pointer 84h (in this example, “5”) is obtained from the excitation table 83a shown in FIG. 8, and the excitation data (06H) is for the left reel 61L. Is stored in the RAM 84 as output excitation data (step 1233).
The stored excitation data is simultaneously output to the input / output port 82 as shown in step 1105 of FIG. 26 after acquiring the excitation data for the stepping motors of the other reels 61M and 61R.

When the process of step 1233 is completed, the symbol offset value is updated (step 1234), the reel rotation position detection process (step 1235), and the reel rotation detection process (step 1235) by the reel index sensor 75 (see FIG. 3). 1236).
Steps 1244 and 1245 are reel abnormality processing, which is performed when the reel does not rotate normally despite the excitation data being applied.
Steps 1251 and 1252 are rotation stop processing (brake processing) for the stepping motor 79.

  As will be described later, if the motor acceleration process is normal, the processes in steps 1244 and 1245 are skipped, and the process returns to the timer interrupt process shown in FIG.

As described above, when the start lever 45 is operated, the counter value “25” is set in the acceleration counter 84g, and the motors are applied to the stepping motors 79 corresponding to the three reels 61 (61L, 61M, 61R). Each of the rotors 790 is started by supplying excitation data for starting.
When the next timer interruption time comes, the motor control process is called again. The processing at this time will be described next.

In this case, the value of the wait timer 84f is “130” (step 1201). At this time, a subtraction process (step 1202) for subtracting 1 from the value of the wait timer 84f is executed, and a timer interrupt process ( Returning to the stepping motor control process (FIG. 26) of FIG.
As a result, the values of the acceleration counter 84g and the excitation order pointer 84h are held at the same values as in the previous timer interruption. That is, the motor acceleration process by the same excitation phase (in this example, two-phase excitation) is continued. The motor acceleration process using the same excitation phase is continuously performed for a total of 130 interrupts, and the value of the wait timer 84f is subtracted every time the timer interrupt occurs. As a result, when 130 interrupt is performed, the value of the wait timer 84f becomes zero (step 1201).

On the other hand, the value of the acceleration counter 84g does not change at all during the first acceleration period. When the 130 interrupt is completed and the value of the wait timer 84f becomes 0, the process proceeds to step 1221 through step 1211. In this step 1221, the value of the acceleration counter 84g is subtracted for the first time. The
Then, the excitation time (8 interrupts) corresponding to the value “23” of the acceleration counter 84g subtracted by 1 is acquired from the acceleration table of FIG. 25, and the acquired value (= 8) of this excitation time is the wait timer. 84f is set (steps 1222, 1231).
At the same time, the value of the excitation order pointer 84h (see FIG. 8) is incremented to “6” (step 1232), and excitation data “02H” (one-phase excitation) corresponding to the value “6” of the excitation order pointer 84h is obtained. The output excitation data is stored in the RAM 84 (step 1233).
Thereafter, similar output excitation data acquisition processing is executed for the other reels 61 (middle reel 61M, right reel 61R), and output to all reels 61 (left reel 61L, middle reel 61M, right reel 61R). At the stage where the excitation data acquisition process is completed, these output excitation data are output to the input / output port 82, respectively, and the process relating to the second acceleration period is started (FIG. 26, steps 1104 and 1105 of the stepping motor control process). ).
Therefore, as is apparent from the acceleration table of FIG. 25, at the beginning of the second acceleration period, one-phase excitation is continuously performed for 8 interrupts.

The beginning of the second acceleration period is a process corresponding to the acceleration order 2 (see FIG. 25). When the timer interruption is completed for 8 interruptions in the acceleration process in the acceleration order 2 (Yes in Step 1201), the value of the acceleration counter 84g is further subtracted in Step 1221.
As a result, the excitation data “03H” in which the value of the excitation order pointer 84h is “7” is read from the excitation table of FIG. 8, and therefore, continuous acceleration processing for 7 interrupts is executed by two-phase excitation.

Thus, while the acceleration counter 84g is sequentially subtracted, the excitation data designated by the excitation order pointer 84h is sequentially read out and the acceleration process is executed during the second acceleration period, so that the value of the acceleration counter 84g is final. Therefore, it becomes “0 (zero)”.
When the value of the acceleration counter 84g becomes “0”, this value is checked in step 1222. Therefore, the process proceeds to step 1223, and processing for setting the value of the acceleration counter 84g to “1” is executed.
Thereafter, the process proceeds to step 1231, and a value (= 1) corresponding to the excitation time (one interrupt) corresponding to the value “0” of the acceleration counter 84g when subtracted in step 1221 is set in the wait timer 84f. .
Thereafter, the excitation order pointer 84h is updated, and in this example, excitation data “01H” corresponding to the pointer “0” is read from the excitation table of FIG. 8 and set as output excitation data (step 1232, 1233). Therefore, when the value of the acceleration counter becomes “0” as a result of the subtraction process in step 1221, excitation is performed for one timer interrupt.

Even if the value of the acceleration counter 84g becomes “0” as a result of the subtraction process in Step 1221, “1” is set to the value of the acceleration counter 84 g in the process of Step 1223. Therefore, in the next timer interrupt process, as the next process step of the acceleration order 25 (FIG. 25) which is the excitation order, the process proceeds to step 1221 via step 1211 and the value of the acceleration counter 84g is subtracted again. Executed.
As a result, the value of the acceleration counter 84g becomes “0” again. Therefore, in step 1231, the excitation time (= 1) corresponding to the acceleration order 25 in FIG. 25 is set in the wait timer 84f. Further, as a result of the excitation order pointer 84h being updated to “2” in the process of step 1232, the excitation phase is changed to the two-phase excitation and the excitation process for one interrupt is performed.

  In other words, after the acceleration order 25, the value of the acceleration counter 84g is alternately changed between “0” and “1” in steps 1221 and 1223, and excitation is always performed by one interrupt. The stepping motor 79 is in a rotation mode in which one-phase excitation and two-phase excitation are alternately repeated. This is nothing but the constant speed process. In other words, when the excitation process proceeds to the acceleration order 25, the mode changes to the constant speed rotation mode thereafter.

The reel rotation position detection processing (FIG. 28, step 1235) executed while the reel 61 is rotating (acceleration, low-speed rotation) will be described by taking the case of the left reel 61L as an example.
In the motor control process (FIG. 27), when the value of the excitation order pointer 84h is updated (step 1232) and the excitation data is acquired (step 1233), the value update process of the symbol offset value 84i (step 1234) is performed. Then, the rotation position detection process (step 1235) of the reel 61 is executed.

In this rotation detection process, the first sensor cut bun 76 and the second sensor cut bang 77 (see FIG. 3) are detected by the reel index sensor 75, and the symbol offset value 84i and the symbol number 84j updated when the reel rotates. The angular position around the rotation axis X of the reel 61 is specified.
In the following description, the case of the left reel 61L will be described as an example.

FIG. 29 is a flowchart for explaining the rotational position detection processing in step 1235.
In the rotational position detection process, in step 1301, it is confirmed whether the signal input from the reel index sensor 75 is an on signal or an off signal.
Here, when the rotation position of the reel 61 is in a position where the first sensor cut bang 76 or the second sensor cut bang 77 (hereinafter also referred to as sensor cut bangs 76 and 77) is detected by the reel index sensor 75, the reel 61 is turned on. When the signal is in a position where it is not detected, an off signal is input.

If it is an ON signal in step 1301, it is checked in step 1302 whether an ON signal flag is set.
This is to determine whether or not the sensor cut buns 76 and 77 have been detected during the rotational position detection process in the previous timer interrupt process.

If the ON signal flag is set in step 1302, in step 1303, addition processing for incrementing the value of the time counter 84k by “1” is executed.
If the ON signal flag is already set, it means that the sensor cut buns 76 and 77 are detected subsequent to the previous rotational position detection process, and therefore an OFF signal is input in the subsequent rotational position detection process. Thus, when the sensor cut buns 76 and 77 are no longer detected, the time during which the sensor cut buns 76 and 77 were detected can be counted.

  When the process of step 1303 is executed, the process returns to the process of step 1236 in the motor control process (FIG. 28).

Here, the time counter is a counter for calculating the time when the sensor cut buns 76 and 77 were detected or not detected by the reel index sensor 75.
When the signal input from the reel index sensor 75 is switched from the on signal to the off signal, or when the signal from the reel index sensor 75 is switched from the off signal to the on signal, the value of the time counter is determined by the processing in step 1308 or step 1315 described later. Reset to “0”.

If the on signal flag is not set in step 1302, the on signal flag is set in step 1304.
This is because the time during which the ON signal flag is input can be calculated in the subsequent rotational position detection processing.

  Here, when the ON signal flag is not set when the ON signal is input, one of the first sensor cut bun 76 and the second sensor cut bang 77 is caused by the rotation of the reel 61 and the reel index sensor 75. This means that the position detected at the time has been reached.

  Therefore, in order to confirm which of the first sensor cut bang 76 and the second sensor cut bang 77 has reached the detected position, in step 1305, the OFF signal that was input before the ON signal was input. The input time (off time) is calculated.

Here, the off time is calculated based on the value of the time counter that is added at every execution interval of the timer interrupt process while the off signal before the on signal is continuously inputted. .
For example, when the value of the time counter is “210”, 312.90 msec (1.49 msec × 210) is the off time calculated in step 1305.

  When the off time is calculated in step 1305, the sensor cut bang detected by the reel index sensor 75 based on the calculated off time in step 1306 is selected from the first sensor cut bang 76 and the second sensor cut bang 77. Identify which one.

  Specifically, referring to an on / off time table (not shown) stored in the ROM 83, the calculated off time is the first non-detection time t2 (the end of the tip 76a) of FIG. Time corresponding to the section from the portion 76e to the start end 77s of the tip 77a) and a second non-detection time t4 (time corresponding to the section from the end 77e of the tip 77a to the start 76s of the tip 76a). It is determined which one of them matches, and it is determined that the sensor cut bang to be detected next to the matching non-detection time is the sensor cut bang detected by the reel index sensor 75.

In the embodiment, in the on / off time table, the first non-detection time t2 corresponding to the section from the end portion 76e of the tip end portion 76a to the start end portion 77s of the tip end portion 77a is 344.19 msec, and the end portion 77e of the tip end portion 77a. The second non-detection time t4 corresponding to the section from the first end portion 76a to the start end portion 76s is stored as 312.90 msec.
Therefore, when the off time calculated in step 1305 is, for example, 312.90 msec, it is determined to be the second non-detection time t4.

  Since the sensor cut bang detected after the second non-detection time t4 is the first sensor cut bang 76 as shown in FIG. 9, it is specified in step 1306 as the first sensor cut bang 76.

  When the position of the sensor cut bang is specified, the position of the symbol drawn on the outer periphery of the reel can be specified. Therefore, in step 1307, the rotational position of the reel is specified.

  In step 1308, the value of the time counter is reset to “0” in order to calculate the input time of the ON signal.

On the other hand, if no ON signal is input in step 1301, that is, if an OFF signal is input, it is checked in step 1309 whether an OFF signal flag is set.
This is for confirming whether the input of the off signal in step 1301 is the input of the off signal immediately after the sensor cut buns 76 and 77 pass through the reel index sensor 75.

If the off signal flag is set in step 1309, an addition process for incrementing the value of the time counter 84k by “1” is executed in step 1310.
If the off signal flag is already set, it means that the sensor cut buns 76 and 77 have not been detected following the previous rotational position detection process, so an on signal is input in the subsequent rotational position detection process. Thus, when the sensor cut buns 76 and 77 are detected, the time when the sensor cut buns 76 and 77 are not detected can be calculated.

If the off signal flag is not set in step 1309, the off signal flag is set in step 13111.
This is because the time during which the OFF signal flag has been input can be calculated in the subsequent rotational position detection processing.

  Here, when the off signal flag is not set when the off signal is input, one of the first sensor cut bun 76 and the second sensor cut bang 77 is caused by the rotation of the reel 61 and the reel index sensor 75. It means that it was out of the position detected.

  Therefore, in order to confirm which one of the first sensor cut bang 76 and the second sensor cut bang 77 has been detected, the input time of the ON signal that was input before the OFF signal was input in step 1312. (On-time) is calculated.

Here, the ON time is calculated based on the value of the time counter 84k that is added at every execution interval of the timer interrupt process while the ON signal before the OFF signal is input is continuously input. The
For example, when the value of the time counter 84k is “21”, 31.29 msec (1.49 msec × 21) is the ON time calculated in step 1312.

  When the on time is calculated in step 1312, the sensor cut bang detected by the reel index sensor 75 based on the calculated on time in step 1313 is the first sensor cut bang 76 or the second sensor cut bang 77. It is specified which is.

  When the position of the sensor cut bang is specified, the position of the symbol drawn on the outer periphery of the reel can be specified. In step 1314, the rotational position of the reel is specified.

  In step 1308, the value of the time counter is reset to “0” in order to calculate the input time of the ON signal.

  When this rotational position detection process ends, the process returns to step 1236 of the motor control process (FIG. 28).

Returning to the motor control process of FIG. 28, in step 1235, it is confirmed whether or not the base position of the reel has passed the predetermined detection position (reel index sensor 75).
In the embodiment, since a total of four locations of the start end portion 76s of the sensor cut bun 76, the end portion 76e, the start end portion 77s of the sensor cut bang 77, and the end end portion 77e are set as the base point positions, the processing in step 1235 is performed. If any of these base point positions 76s, 76e, 77s, 77e has been detected, it means that the origin position of the reel has been determined. Therefore, the routine proceeds to step 1236, where the origin position of the reel is set to the predetermined detection position. The symbol offset counter and the symbol number counter are updated in accordance with the passing timing.

  That is, the symbol number and the symbol offset value are updated to predetermined values determined according to the respective base point positions of the reels.

More specifically, when the detected base point is the start end portion 76s (origin position) of the first sensor cut van 76, the symbol number value is set to “0” and the symbol offset value is set to “0”.
When the detected base point is the end portion 76e of the first sensor cut bun 76, the symbol number value is set to “0” and the symbol offset value is set to “21”.
If the detected base point is the start end 77 s of the second sensor cut bang 77, the symbol number value is set to “10” and the symbol offset value is set to “12”.
When the detected base point is the end portion 77e of the second sensor cut bang 77, the symbol number value is set to “12” and the symbol offset value is set to “6”.

Here, the symbol number indicates the symbol number shown in FIG. 10 as a serial number, and since a total of 21 symbols are prepared, the symbol number takes a value of “0” to “20”.
Since the symbol offset is a value obtained by dividing one symbol into 24 equal parts in the rotation direction of the reel 61, the symbol offset takes values from “0” to “23”.

The symbol offset value is incremented by “1” in the symbol offset update process (FIG. 28, step 1234).
Here, when the symbol offset value becomes 24 (the symbol offset value is updated 25 times), the symbol displayed in the display window 31 has moved by one symbol. It is necessary to update the symbol number for specifying the symbol displayed on the display window 31.

  In the embodiment, in step 1241, it is confirmed whether or not the symbol offset value is less than the maximum value (24). When the symbol offset value becomes “24” (step 1241, No), in step 1242, The symbol number is updated and the symbol offset value is reset to “0”.

[Re-acceleration processing and abnormal processing]
As described above, during the motor acceleration period, the symbol offset value is updated according to the addition / subtraction of the acceleration counter, and during constant speed rotation, the symbol offset value is updated each time the timer interrupt process is executed ( Step 1234).
When the updated symbol offset value becomes “24”, the symbol number is updated and the symbol offset value is reset to “0” (steps 1241 and 1242).
Then, after the symbol number is updated, the processing steps from step 1241 to step 1244 are performed until the value does not exceed the maximum value “21” and the symbol offset exceeds the maximum value “24”. The design number update, the design offset value update, and the reset process continue. Further, the symbol number and the symbol offset are reset each time the reel 61 rotates once (steps 1236 and 1237).

  By performing this processing, it is possible to determine which symbol has passed through the display window 31 based on the symbol number, and to determine which position of the symbol is positioned in the display window 31 based on the value of the symbol offset. be able to. For example, when the symbol number is “0” and the symbol offset is “0”, symbols of symbol numbers “0” to “2” are visible from the display window.

  The stepping motor 79 is normally accelerated by the start lever 45, and the above-described situation is reproduced in the case of normal rotation up to constant speed rotation. However, when normal rotation is not achieved without normal acceleration, or when the reel is intentionally pressed to stop the rotation, the following abnormal rotation processing is performed.

  First, since the acceleration process is completed before the reel 61 makes one rotation, in the normal case, when the acceleration process is performed, the reel index sensor 75 should detect the first rotation of the reel 61. However, if the acceleration process is abnormal, the symbol offset value and symbol number update process proceeds even if the first rotation of the reel 61 is not detected in step 1235 (steps 1234 and 1242).

  As is apparent from FIG. 10, the symbol numbers are from “0” to “20”. However, when such an abnormal state occurs, the symbol number is further updated and its value reaches the maximum value “21” ( Steps 1241 and 1242) When the next excitation phase switching timing comes, counter subtraction processing is performed in Step 1221. Then, the symbol offset value is updated as before (steps 1222 and 1234).

In this case, after step 1241, the value of the symbol number is checked in step 1243. Since the symbol numbers are from “0” to “20”, when the update maximum value “21” is exceeded, it can be regarded as an abnormal rotation state.
Even in this case, in consideration of the variation in the operation of the stepping motor 79, in this example, when the symbol offset advances by 4 offsets or more (step 1244), it is determined that the rotation state is abnormal for the first time, and abnormality processing is performed (step 1245). . In this case, the reacceleration setting process is performed, the initial value “25” is set in the acceleration counter, and the process returns to step 1211 again from the next timer interruption period to perform the reacceleration process.

  The stepping motor 79 has operational variations, and ideally one rotation = 504 pulses. However, in some cases, it is possible to make one rotation with 503 pulses or 505 pulses. Minute is set as the abnormality detection value.

Further, when the reel does not rotate for some reason, for example, when the rotation of the reel is intentionally suppressed, one reel rotation is not detected by the reel index sensor 75 in step 1235 as described above. The symbol offset value 84i and the symbol number 84j are continuously updated.
In this case, in the next timer interruption process after the value of the symbol number 84j reaches the maximum value “21”, the value of the acceleration counter 84g is subtracted or added (steps 1221 and 1222). Later, the symbol offset value is updated (step 1234), and when the updated symbol offset value 84i is equal to or less than the maximum value “24”, whether or not the symbol number 84j is less than the maximum value “21” in step 1243. Is confirmed.
When the symbol number 84j is equal to or greater than the maximum value “21”, it is regarded as an abnormal state. Further, when the updated symbol is rotated and the symbol offset value 84i is shifted by 4 or more (step 1244), the above-described operation is performed. Abnormal processing (step 1245) is executed. This abnormality process is continued until the reset switch 123 is operated.

  When the number of abnormal processes in step 1245 exceeds a specified number (for example, three times), a process for notifying this abnormal state (flashing process for an abnormal lamp provided in the hall, buzzer notification process for a hall manager, etc.) ) Can also be taken.

[3. Processing when the stop button is pressed]
When the user presses any stop button 46 to 48 to stop the rotation of the reel during the constant speed rotation mode, the reel 61 (left reel 61L, middle reel 61M, right reel 61R) stop control process is performed. (Step 1252) is executed.

  Here, even if the brake is applied, the reel 61 (rotor 790) slips and slips for 3 to 4 steps and stops. As described above, it is preferable that the excitation phase at the time of starting the motor is two-phase excitation, and the operation of the stop buttons 46 to 48 is performed so that the brake is started immediately after two-phase excitation, that is, at the timing of one-phase excitation. Regardless of the timing, it is necessary to know the motor stop time (reel stop time).

  Therefore, following the update of the symbol number 84j in step 1242 and the reset processing of the symbol offset value 84i, a processing step for determining the stop time of the reel as in step 1251 is set. In this step 1251, it is determined whether the excitation phase currently being output is two-phase excitation and whether the symbol offset value is in a range not exceeding the predetermined offset value.

  Here, whether or not the current excitation phase is two-phase excitation may be determined by referring to the value of the excitation order pointer (see FIG. 8), and whether or not the predetermined offset value has been exceeded can be determined by referring to the design offset value 84i. Good. Considering the symbol offset value 84i means that the greater the symbol offset value 84i, the greater the relative displacement of the symbol position when the adjacent reel 61 is stopped. This is because if the human discriminating power is taken into account, if the offset is 4 offset or more, it is possible to clearly recognize the shift of the symbol, and it is necessary to execute the reel stop process when the symbol offset value is 4 or less.

  Therefore, when this condition is not satisfied, the process returns to the timer interrupt processing routine of FIG. 13. However, when the reel stop condition of step 1251 is satisfied and any one of the stop buttons 46 to 48 is pressed, step In 1252, a process (stop control process) for stopping the rotation of the reels 61 (the left reel 61L, the middle reel 61M, and the right reel 61R) is executed.

  Here, in the slot machine 10 of the embodiment, as a method for stopping the reel 61, there are prepared a case where the four phases of the stepping motor are simultaneously excited and stopped, and a case where the reel 61 is stopped while being slowed down. Which method is used to stop is set in accordance with the operation timing of the stop buttons 46 to 48 in the above-described normal game process (FIG. 16).

Therefore, the setting process of the method for stopping the reel 61 will be described first.
FIG. 30 is a flowchart showing details of the reel stop process (step 706) in the reel control process (FIG. 18).
This reel stop process is executed in the normal game process (FIG. 16) relating to the game in the slot machine, and the reels 61 are excited by simultaneously exciting the four phases of the stepping motor 79 in accordance with the operation timing timing of the stop buttons 46 to 48. Whether to stop the reel 61 suddenly or stop the reel 61 while slowing down is set.

  In the reel stop process, it is detected from the output signals of the stop operation detection sensors 46a to 48a (see FIG. 11) that one of the stop buttons 46 to 48 has been operated in step 703 of the reel control process (FIG. 18). It is executed when

First, in step 2001, the reel 61 on which the stop process is executed is specified.
In the embodiment, when any one of the stop buttons 46 to 48 is operated, the flag of the operated stop button is set. Therefore, the reel 61 corresponding to the set flag is identified as the reel that executes the stop process.

When the reel for executing the stop process is specified in step 2001, the rotational position of the reel 61 at the time when the stop buttons 46 to 48 are operated is specified in step 2002.
Specifically, the rotational position (current position) of the reel 61 can be specified based on the symbol number 84j and the symbol offset value 84i stored in the RAM 84.

In step 2003, the position of the symbol (scheduled symbol to be stopped) determined as the symbol to be displayed when the reel 61 is stopped is specified.
Here, when the reel is stopped, the symbol displayed when the winning combination (winning combination or small combination) is won as a result of the lottery process (FIG. 16, step 503) of the normal game process. Since the symbol is determined according to the winning combination, the position of the symbol determined according to the winning combination is specified.

For example, when the symbol “Bell” is stopped on the effective line on the lower stage of the left reel, the left reel is extracted from the pattern located on the lower effective line when the stop button 46 is operated. The position of the “bell” at the closest position in the rotation direction is specified by the symbol number.
Further, in the left reel of FIG. 10, when the stop button 46 is operated when the “cherry” of the symbol number 3 is located on the lower effective line, the “bell” of the symbol number 5 is the closest position. Therefore, symbol number 5 is specified as the position of the symbol to be stopped.

  On the other hand, if no winning combination is won in the lottery process (FIG. 16, step 503), the position of the symbol that does not establish any winning combination is specified when all the reels 61 are finally stopped. Is done.

In step 2004, the number of steps (Nstep) required from when the stop button 46 is operated until the reel is stopped in a state where the scheduled stop symbol is positioned on the effective line is specified.
For example, the symbol (scheduled symbol to be stopped) at the lower effective line of the left reel is “bell” of symbol number 2, and the symbol located on the lower effective line when the stop button 46 is pressed is displayed. If the symbol number “7” is “7” and the symbol offset value of the symbol number 20 is “0”, the symbol is exactly three symbols away.
Here, in the embodiment, as described above, 24 steps are required to slide a symbol by one symbol, so 72 steps (= 3 × 24 steps) are required to slide 3 symbols. Therefore, “72” is specified as the distance (number of steps) Nstep to the scheduled stop symbol position, and “72” is set to the value of the remaining symbol counter 84m indicating the number of steps to the scheduled stop symbol (number of remaining symbol steps). Is done.

In step 2005, it is confirmed whether or not the number of steps Nstep up to the symbol to be stopped is 21 <Nstep ≦ 91. If it is within this range, the second slowdown setting process is executed in step 2006. The
In the second slowdown setting process, after the second slowdown flag is set, “8” is set to the value of the deceleration counter 84n.

On the other hand, if 21 <Nstep ≦ 91, it is confirmed in step 2007 whether or not the number of steps up to the symbol to be stopped is 91 <Nstep ≦ 117. The slowdown setting process is executed.
In the first slow-down setting process, after the first slow-down flag is set, “20” is set to the value of the deceleration counter 84n.

If 91 <Nstep ≦ 117 is not satisfied in step 2007, all-phase excitation stop setting processing is executed in step 2009.
In this all-phase excitation stop setting process, the slow-down setting process ends after the all-phase excitation stop flag is set.
Here, the case where 91 <Nstep ≦ 117 is not satisfied, the number of steps Nstep until the symbol to be stopped is (a) 21 or less, or (b) 118 or more. In the embodiment (a), since the reel cannot be stopped with the scheduled stop symbol positioned on the effective line unless the reel is stopped immediately, the reel should be stopped by all-phase excitation. ing. On the other hand, in the case of (b), the symbol for stoppage is separated from the predetermined position, and if the slowdown process is executed, the symbol to be stopped cannot be stopped at the predetermined position within the predetermined time. The reel is stopped by applying all-phase excitation when the symbol to be stopped reaches a predetermined position.
Thereby, as a result of the reel stop process (step 706) of the reel control process (FIG. 18), one of the first slowdown flag, the second slowdown flag, and the all-phase excitation flag is set. When the flag or the second slowdown flag is set, a predetermined value is set in the deceleration counter 84n.

FIG. 33 is a diagram illustrating the first deceleration table, and FIG. 34 is a diagram illustrating the second deceleration table.
Here, when the reel is stopped while being slowed down, the reels are not suddenly stopped by simultaneously exciting the four phases of the stepping motor, but the excitation time is gradually increased and the reel is rotating at a constant speed. A case where the reel is stopped by four-phase excitation after the reel is gradually decelerated.
In the embodiment, a first deceleration table with a long slowdown period and a second deceleration table with a shorter slowdown period are prepared.

In the first deceleration table, the relationship between the deceleration counter and the deceleration order, the excitation method (one-phase excitation or two-phase excitation) and the excitation time in each deceleration order are specified, and the reel is decelerated over 20 steps. Contents to be stipulated are specified.
For example, in the deceleration order 1 to be executed first, one-phase excitation is executed for one interrupt (1.49 msec), and in the next deceleration order 2, two-phase excitation is executed for one interrupt (1. 49 msec), and in the next deceleration order 3, 1-phase excitation is executed for 2 interrupts (2.98 msec), so that the interruption time is gradually increased while alternately repeating 1-phase excitation and 2-phase excitation. The reel 61 is set to be decelerated by making it longer.

  Also in the second deceleration table, the relationship between the deceleration counter and the deceleration sequence, the excitation method (one-phase excitation or two-phase excitation) and the excitation time in each deceleration sequence are defined. The second deceleration table is defined to decelerate the reel by taking 8 steps, and the reel is decelerated with a shorter number of steps than in the case of the first deceleration table.

The first deceleration table is referred to in the stop control process described later when the first slowdown flag is set, and the second deceleration table is referred to when the second slowdown flag is set. The deceleration counter 84n is used as a reference for reading the contents of these tables (first deceleration table, second deceleration table).
Therefore, when the first slowdown flag is set in the reel stop process (FIG. 30), “20” is set to the value of the deceleration counter 84n in the first slowdown setting process in step 2008, When the second slowdown flag is set, “8” is set to the value of the deceleration counter 84n in the second slowdown setting process in step 2006 (FIG. 30, steps 2006 and 2008). ).

  In the stop control process (step 1252) of the motor control process (FIGS. 28 and 29), the reel 61 is triggered by the setting of the first slowdown flag or the second slowdown flag and the setting of the value of the deceleration counter 84n. The process of stopping while slowing down is executed.

  This stop control process (step 1252) will be described with reference to the flowchart of FIG.

As shown in FIG. 31, in the stop control process, the remaining number of symbol steps is “0” in order to confirm whether or not it is time to stop the reel 61 and stop and display the symbol to be stopped at a predetermined value. Check whether or not.
Specifically, it is confirmed whether the value of the remaining symbol counter 84m indicating the number of steps up to the symbol to be stopped (the number of remaining symbol steps) is “0”. It is determined that the number of symbol steps is “0”.
If the number of remaining symbol steps is “0”, all-phase excitation stop processing is executed in step 2102.

In this all-phase excitation stop process, the brake phase (excitation time) is set in the deceleration weight timer 84p after the four phases of the stepping motor 79 are set to be excited simultaneously. For example, when 159 interrupts (= 236.91 msec) are set as the brake time, “159” is set to the value of the deceleration weight timer 84p.
Then, the value of the acceleration counter 84g involved in the constant speed rotation of the reel 61 is reset (= 0).

  When the brake time is set in the deceleration weight timer 84p, brake excitation data is continuously output during the brake time (159 interrupts), and the reel 61 is completely stopped.

  Then, an adjustment process is performed on the excitation order pointer used at the next rotation. The excitation order pointer adjustment process takes into account the slip of the rotor 790. As described above, at the time of the braking process, the rotor 790 almost stops after slipping for about 3 to 4 phases. Therefore, for example, when the brake is applied with the excitation order pointer “0” shown in FIG. It is estimated that the rotor 790 is stopped at the position “4”, and in this example, the adjustment of the excitation phase is advanced by “4 excitation phases”. As a result, the value of the excitation order pointer after the update is “5”.

  When the all-phase excitation process of step 2102 is executed, after the first slow-down flag, the second slow-down flag, the all-phase excitation stop flag, etc. are reset in step 2103, the timer interrupt process (FIG. 13) is executed. Return.

  If the number of remaining symbol steps is not “0” in step 2101, in order to confirm how to stop the reel 61, that is, whether the reel 61 is stopped suddenly or whether the reel 61 is stopped while being slowed down. In step 2104, it is confirmed whether or not the all-phase excitation stop flag is set.

Here, when the all-phase excitation stop flag is set in step 2104, it is confirmed that the value of the number of remaining symbol steps is not “0” in step 2101 before step 2104. This means that the current time is before the reel 61 is suddenly stopped and waiting for the symbol to be stopped to reach a predetermined position.
Therefore, in step 2105, after the value of the remaining symbol counter 84m that defines the start timing of the rotation stop of the reel 61 by all-phase excitation is decremented by “1”, the process returns to the timer interrupt process (FIG. 13).
As a result, until the value of the remaining symbol counter 84m becomes less than “0”, the value of the remaining symbol counter 84m is subtracted by “1” at the execution interval of the timer interrupt processing (FIG. 13). become.

If the all-phase excitation flag is not set in step 2104, it is confirmed in step 2106 whether the first slow-down flag is set.
If the first slowdown flag is set, in step 2107, the remaining symbol counter 84m is checked in order to confirm whether the current time is during execution of the first slowdown process or waiting before execution. It is confirmed whether or not the value of is less than or equal to “20”.

In the embodiment, the value of the remaining symbol counter 84m indicating the number of steps up to the symbol to be stopped (the number of remaining symbol steps) is also used as a counter for defining the start timing of the first slow-down process.
Here, as described above, the first slow-down process is set to execute the slow-down of the reel 61 in 20 steps before the reel 61 is stopped by all-phase excitation (see FIG. 33).
Therefore, if the value of the remaining symbol counter 84m is larger than “20”, it means that the process is waiting before the first slowdown process is executed, and if it is “20”, the first slowdown is performed. This means that the process start timing has come, and if it is smaller than “20”, it means that the first slow-down process is being executed.

Therefore, if the value of the remaining symbol counter 84m is larger than “20” in step 2107, the process waits before the first slow-down process is executed, so in step 2108, the value of the remaining symbol counter 84m. "1" is subtracted.
As a result, until the value of the remaining symbol counter 84m becomes “20” or less, the value of the remaining symbol counter 84m is set to “1” at the execution interval of the timer interrupt processing (FIG. 13) by the processing of step 2108. "Will be subtracted one by one.

  In step 2107, when the value of the remaining symbol counter 84m is equal to or less than “20”, the timing of starting the first slow-down process or the execution of the first slow-down process is in progress. The process proceeds to (see FIG. 32).

If the first slowdown flag is not set in step 2106, it is checked in step 2109 whether the second slowdown flag is set.
If the second slowdown flag is set, in step 2110, the remaining symbol counter 84m is used to confirm whether the current time is during execution of the second slowdown process or waiting before execution. It is confirmed whether or not the value of is less than or equal to “8”.

As described above, the second slow-down process is set so that the reel 61 is slowed down in 8 steps before the reel 61 is stopped by all-phase excitation (see FIG. 34).
Therefore, when the value of the remaining symbol counter 84m is larger than “8”, the process is waiting before the second slow-down process is executed, and therefore, in step 2108, the value of the remaining symbol counter 84m is “1”. Subtracted.
As a result, until the value of the remaining symbol counter 84m becomes “8” or less, the value of the remaining symbol counter 84m becomes “1” at the execution interval of the timer interrupt processing (FIG. 13) by the processing of this step 2108. "Will be subtracted one by one.

  In step 2110, if the value of the remaining symbol counter 84m is equal to or less than “8”, the timing of starting the second slowdown process or the execution of the second slowdown process is in progress. The process proceeds to (see FIG. 32).

  If the second slowdown flag is not set in step 2109, none of the all-phase excitation stop flag, the first slowdown flag, or the second slowdown flag is set, and the rotation of the reel 61 is stopped. Since there is no need, the process returns to the timer interrupt process (FIG. 13).

Here, the start of the first slow-down process or the second slow-down process will be described.
When the first slow-down flag is set, “20” is set to the value of the deceleration counter 84n in step 2008 of the reel stop process (see FIG. 30). If the second slowdown flag is set, “8” is set to the value of the deceleration counter 84n in step 2006 of the reel stop process (see FIG. 30).
In any case, the value of the deceleration weight timer 84p is not set and is “0”.
Therefore, since the value of the deceleration weight timer 84p is “0” in Step 2111 (FIG. 32), the process proceeds to Step 2113, and the value of the deceleration counter 84n is subtracted by “1”.

  Therefore, when the first slowdown flag is set, the value of the deceleration counter 84n becomes “19” by the processing of step 2113, and when the second slowdown flag is set, this As a result of the processing in step 2113, the value of the deceleration counter 84n becomes “7”.

  Subsequently, in step 2114, an excitation time value (see FIGS. 33 and 34) corresponding to the value of the deceleration counter 84n after subtraction is acquired, and the acquired excitation time value is set in the deceleration weight timer 84p. .

Therefore, when the first slow-down flag is set, the value of the subtraction counter after subtraction is “19”, and therefore the excitation time value “1” corresponding to the value “19” of the deceleration counter (FIG. 33) is set to the value of the deceleration weight timer 84p.
On the other hand, when the second slowdown flag is set, the excitation time value “1” (see FIG. 34) corresponding to the deceleration counter value “7” is set to the value of the deceleration weight timer 84p. .

  When the setting of the value of the deceleration weight timer 84p is completed, an update process for incrementing the value of the excitation order pointer (see FIG. 8) by “1” is executed (step 2115). Then, excitation data corresponding to the updated excitation order pointer value (for example, “5”) is acquired from the table shown in FIG. 8, and the excitation data (06H) is stored in the RAM 84 as output excitation data for the left reel 61L. (Step 2116). The stored excitation data is simultaneously output to the input / output port 82 in step 1105 of the stepping motor control process of FIG. 26 after acquiring the excitation data for the stepping motors of the other reels 61M and 61R.

  In step 2117, the value of the remaining symbol counter 84m that defines the end timing of the first or second slow-down process is subtracted by “1”.

  As described above, when the stop buttons 46 to 48 are operated, the value of the deceleration counter 84n of the reel 61 (61L, 61M, 61R) corresponding to the operated button is set to a predetermined value (depending on the slow-down time). “20” is set for the first slow-down process, and “8” is set for the second slow-down process), and the value of the remaining symbol counter 84m that defines the start timing of the slow-down process is set to the slow-down process. When a predetermined value that defines the start timing of the motor is supplied, excitation data for motor slowdown is supplied to the stepping motor 79 corresponding to the reel to be stopped, so that each rotor 790 slows down.

  When the next timer interrupt time comes, the stop control process is called again. The processing at this time will be described next.

In this case, since the first slowdown process or the second slowdown process is started immediately, the value of the remaining symbol step number (remaining symbol counter 84m) is not “0”.
Therefore, the process proceeds to step 2111 after step 2101.

Since the value of the deceleration weight timer immediately after the start of the slowdown process is “1” as described above (step 1211), a subtraction process (step 1212) for subtracting 1 from the deceleration weight timer is executed at this time. Then, the process returns to the timer interrupt process (FIG. 13).
As a result, the values of the deceleration counter 84n and the excitation order pointer 84h are held at the same values as in the previous timer interruption. That is, the motor deceleration process by the same excitation phase (1 phase excitation in this example) is continued.

In the next timer interrupt process, since the value of the deceleration wait timer 84p is “0”, the process proceeds from step 2111 to step 2113. In step 2113, the value of the deceleration counter 84n is decremented by “1”. It is processed.
Therefore, in the case of the first slow-down process, the value of the deceleration counter 84n is “18”, and in the case of the second slow-down process, the value of the deceleration counter 84n is “6”.

Then, the excitation times (one interrupt each) corresponding to the values “18” and “6” of the deceleration counter 84n after subtraction are acquired from the deceleration tables of FIGS. 33 and 34, and the acquired excitation time value ( = 1) is set in the deceleration weight timer 84p (step 2114).
At the same time, the value of the excitation order pointer (see FIG. 8) is incremented to “6” (step 2115), and excitation data “02H” (one-phase excitation) corresponding to this excitation order pointer value “6” is output. The excitation data is stored in the RAM 84 (step 1216).

  In step 2117, the value of the remaining symbol counter 84m is subtracted by “1”.

In this way, the slowdown process is executed by sequentially reading out the excitation data designated by the excitation order pointer 84h while further subtracting the deceleration counter 84n and further increasing the excitation time gradually.
When the value of the deceleration counter 84n finally becomes “0 (zero)”, the value of the remaining symbol counter 84m simultaneously becomes “0”.

Then, after the process of step 2101 described above, the all-phase excitation process of step 2102 is executed, and the reel 61 is completely stopped. That is, in the first slowdown process, the reel is stopped by 20 steps + one step of all-phase excitation, so that it takes 32.29 msec (21 × 1.49 msec) until the reel stops after the slowdown. Become.
In the second slowdown process, the reel is stopped by 8 steps + one step of all-phase excitation, and therefore it takes 13.41 msec (9 × 1.49 msec) until the reel stops after the slowdown. Become.

As described above, in the slot machine 10 of the first embodiment, the reel (circular body) 61 (61L, 61M, 61R) in which a plurality of symbols are drawn on the outer periphery along the circumferential direction is operated by operating the start lever 45. When a stop command for the rotating reel 61 is output after a predetermined time from the operation of the stop buttons 46 to 48 or the operation of the start lever 45 after being driven to rotate by the stepping motor 79, the reel 61 A stop symbol to be displayed at a predetermined position on the effective line at the time of stopping is determined, and the reel 61 is decelerated (slowed down) based on the relationship between the determined stop scheduled symbol and the predetermined position on the effective line. One of a first stop condition for stopping the reel 61 and a second stop condition for stopping the reel 61 by all-phase excitation without decelerating is selected. , In the slot machine 10 to stop the reel 61 at the selected stop condition,
The first stop condition is provided with a plurality of deceleration patterns in which at least one of the deceleration time and the deceleration of the reel is different. When the reel is stopped under the first stop condition, the stop pattern is set as the predetermined pattern. When it is possible to stop display at a position, one deceleration pattern is selected from a plurality of deceleration patterns of the first stop condition based on the relationship between the stop symbol and a predetermined position.
With this configuration, when the position of the stop symbol when the stop command is output is a position that can reach the predetermined position on the effective line even if the reel is decelerated and then stopped, the first symbol is displayed. By stopping the reel 61 under this stop condition, the load applied to the reel 61 and the stepping motor 79 can be reduced as compared with the second stop condition in which the reel 61 is locked and stopped without being decelerated.
In addition, since one deceleration pattern is selected according to the positional relationship between the stop symbol and the predetermined position, the determined stop symbol is stopped and displayed at the predetermined position as much as possible, and the load on the reel and stepping motor is reduced. it can.

The stepping motor 79 is a multi-phase stepping motor. Under the first stop condition, the excitation phase of the excitation phase after switching is set longer than the excitation time of the excitation phase before switching while sequentially switching the excitation phase. Then, after the reel 61 is decelerated stepwise, the reel 61 is stopped by exciting all phases.
With this configuration, when the reel is stopped under the first stop condition, the reel 61 and the stepping motor 79 can be reduced in load because the reel can be completely stopped after being gradually decelerated.
Here, when stopping the circulating body by all-phase excitation, considering the deviation of the stop position of the circulating body, the minimum rotation of the rotating body rotated by, for example, a stepping motor, just before the scheduled stop symbol reaches the predetermined stop position. There is a gaming machine in which all-phase excitation is performed one step or more before the unit to stop the circulating body. For example, in the case of a gaming machine that applies all-phase excitation one step before, the position one step before corresponds to the “predetermined position”.

In the first stop condition, the excitation phase is sequentially switched by the 1-2 phase excitation method.
With this configuration, the rotation angle of the reel 61 per step of the stepping motor 79 is small, so that the rotation of the reel 61 can be made smooth.

The relationship between the stop symbol and the predetermined position on the active line is a time required for moving the stop symbol to the predetermined position by the stepping motor 79.
With this configuration, the time required to move the stop symbol to a predetermined position is suppressed within a time period in which the player does not feel uncomfortable with the behavior until the reel 61 stops. Thus, the reel 61 can be stopped after being decelerated, and the load on the reel 61 and the stepping motor 79 can be reduced.

The relationship between the stop symbol and the predetermined position on the effective line is the number of steps required to move the stop symbol to the predetermined position by the stepping motor 79.
With this configuration, it is determined whether or not the first stop condition for stopping the reel 61 while decelerating is selected based on the number of steps that is the minimum rotation unit of the reel 61. Thus, the load applied to the reel 61 and the stepping motor 79 can be reduced.

Under the first stop condition, the reel 61 is decelerated based on a deceleration table (deceleration pattern) associated with a decelerating counter (identification number) indicating the excitation phase switching time and the excitation time in which the excitation is performed. Thus, the reel 61 is decelerated while sequentially changing the excitation phase to be excited and the excitation time in accordance with the order of the deceleration counter.
With this configuration, since the reel 61 can be smoothly decelerated after being smoothly decelerated, the load on the reel 61 and the stepping motor 79 can be reduced.

A plurality of deceleration tables (first deceleration table, second deceleration table) with different deceleration times of the reel 61 are prepared as the first stop condition, and are based on the relationship between the stop symbol and a predetermined position on the effective line. The reel 61 is decelerated after being decelerated according to one selected deceleration table (first deceleration table or second deceleration table).
With this configuration, the optimum deceleration table determined according to the relationship between the stop symbol and the predetermined position on the effective line is selected, so that the reel is displayed while stopping the determined stop symbol at the predetermined position as much as possible. And the load on the stepping motor can be reduced.

A second embodiment of the reel stop process will be described with reference to FIG.
In the reel stop process according to the second embodiment, whether or not to execute the slow-down process is determined based on the number of symbols from the symbol located on the active line when the stop button is operated to the symbol to be stopped. To do.

  Also in the reel stop process according to the second embodiment, stop operation detection sensors 46a to 48a (FIG. 18) indicate that any one of the stop buttons 46 to 48 is operated in step 703 of the reel control process (FIG. 18). 11) is executed when detected from the output signal.

First, in step 2201, the reel 61 on which stop processing is executed is specified.
In the embodiment, when any one of the stop buttons 46 to 48 is operated, the flag of the operated stop button is set. Therefore, the reel 61 corresponding to the set flag is identified as the reel that executes the stop process.

When the reel for executing the stop process is specified in step 2201, the rotational position of the reel 61 at the time when the stop button 46 is operated is specified in step 2202.
Specifically, the rotational position of the reel 61 can be specified based on the symbol number 84j and the symbol offset value 84i stored in the RAM 84.

In step 2203, the position of the symbol (scheduled symbol to be stopped) determined as the symbol to be displayed when the reel is stopped is specified.
Here, the symbol displayed when the reels are stopped is selected when any of the winning combinations (winning winning combination, small winning combination) is won in the lottery processing in the normal game processing (FIG. 16, step 503). Since the symbol is determined according to the winning combination, the position of the symbol determined according to the winning combination is specified.

  In step 2204, from the time when the stop button 46 is operated, the number of slips required to stop the reel in a state where the symbols to be stopped are positioned on the effective line is specified.

Here, for example, a case will be described in which a winning combination in which the symbol to be stopped at the effective line of the left reel (scheduled symbol) is “Bell” is won.
In the embodiment, the number of slips is specified based on the slip table of FIG.

In this sliding table, for each symbol to be stopped, if the number of symbols is slipped from the symbol located on the active line when the stop button 46 is pressed, the symbol to be stopped on the active line when the reel stops. Can be stopped.

  For example, in the sliding table of FIG. 36, the symbol to be stopped is “bell”, and the symbol located on the lower effective line c (see FIG. 1) at the time when the stop button is operated, The number of slips required to stop the symbol “bell” on the effective line c is known.

  For example, in FIG. 10, when the left cherry stop button is operated when the “cherry” of the symbol number 3 is located on the lower effective line c, the reel is slid by sliding by two symbols, The symbol number 5 “bell” can be stopped and displayed on the active line.

Returning to FIG. 35, when the number of slips is specified in step 2204, it is confirmed in step 2205 whether or not the number of slips is 1 or 2, and the number of slips is “1” or “2”. In step 2206, the second slow-down setting process is executed.
In the second slowdown setting process, after the second slowdown flag is set, “8” is set to the value of the deceleration counter.

If the slip number is not “1” or “2” in step 2205, it is confirmed in step 2207 whether the slip number is “3” or “4”, and the slip number is “3” or “4”. In step 2208, the first slow down setting process is executed.
In the first slow-down setting process, after the first slow-down flag is set, “20” is set to the value of the deceleration counter.

  Note that if the number of slips is not “3” or “4” in step 2207, the number of slips specified in step 2204 is “0”. Therefore, in this case, all-phase excitation stop setting processing is executed in step 2209. That is, the reel 61 is stopped without being decelerated (slowed down).

  As described above, the reel 61 is stopped after decelerating (slowing down) the reel 61 until the stop symbol reaches the predetermined position based on the number of symbol slips required to move the stop symbol to the predetermined position. The first stop condition and the second stop condition for stopping the reel 61 without decelerating (slowing down) the reel 61 until the stop symbol reaches a predetermined position are selected. Since the number of symbols on the symbol is determined by referring to a table that collects the number of symbols up to the stop symbol for each symbol of the reel 61, the number of steps and time required to move the stop symbol to a predetermined position are calculated. There is no need to calculate, and it is only necessary to refer to the sliding table, so that the processing load can be reduced and the data can be reduced.

A third embodiment of the reel stop process will be described.
In the first embodiment, when the reel 61 is decelerated (slowed down), the reel decelerating process is performed based on the first decelerating table according to the number of steps to the stop scheduled symbol (the number of remaining symbol steps). And a second slow-down process for executing the reel deceleration process based on the second deceleration table, and two deceleration tables (the first deceleration table and the second deceleration table). A deceleration table) was prepared.
In the third embodiment, by using only the first deceleration table, the method for reading the excitation time from the deceleration table is changed between the case of the first slow-down process and the case of the second slow-down process. Different deceleration times are realized.

FIG. 37 is a flowchart of the reel stop process in the third embodiment.
Also in the reel stop process according to the third embodiment, any one of the stop buttons 46 to 48 is operated in step 703 of the reel control process (FIG. 18). 11) is executed when detected from the output signal.

  In this reel stop process, as in the case of the reel stop process (FIG. 30) of the first embodiment, the reel 61 that executes the stop process is specified (step 2301), and the reel 61 at the time when the stop button 46 is operated. The position of the symbol (step 2302), the position of the symbol (scheduled to be stopped) determined as the symbol to be displayed when the reel 61 is stopped (step 2303), and the state where the scheduled stop symbol is positioned on the effective line In step 2304, the number of steps (Nstep) required to stop the reel is specified (step 2304).

In step 2305, it is checked whether or not the number of steps Nstep up to the symbol to be stopped is 21 <Nstep ≦ 91. If it is within this range, in step 2006, the second slowdown setting process is performed. Executed.
In the second slowdown setting process, after the second slowdown flag is set, “20” is set as the value of the deceleration counter 84n, and “4” is set as the value of the subtraction number 84q.

On the other hand, if 21 <Nstep ≦ 91, it is confirmed in step 2007 whether or not the number of steps up to the symbol to be stopped is 91 <Nstep ≦ 117. 1 slow-down setting process is executed.
In the first slowdown setting process, after the first slowdown flag is set, “20” is set as the value of the deceleration counter, and “1” is set as the value of the subtraction number 84q.

  If 91 <Nstep ≦ 117 is not satisfied in step 2009, all-phase excitation stop setting processing is executed in step 2011.

  As described above, when the setting of the first slowdown flag or the second slowdown flag and the setting of the value of the deceleration counter are executed, the stop control process (FIGS. 31 and 32) is executed.

In the third embodiment, only the processing in step 2112 in FIG. 32 is different from that in the first embodiment.
Specifically, when the deceleration counter 84n value is subtracted in step 2112, in the first embodiment, “1” is always subtracted. In the third embodiment, the subtraction number 84q is set. It is subtracted by a certain value.
Therefore, in the second slowdown process in which the deceleration time is shorter than the first slowdown process, since the value of the subtraction number 84q is set to “4”, the value of the deceleration counter 84n is determined by the timer interrupt process. Each time, “20” → “16” → “12” → “8” → “4” → “0” is subtracted in this order.
Therefore, in the processing from step 2113 to step 2115, the setting of the excitation phase and the excitation time and the change of the excitation order pointer 84h are sequentially performed in the order corresponding to the value of the deceleration counter 84n. The rotation will stop.

  In this way, in the first slow-down process, based on the first deceleration table (FIG. 33) associated with the deceleration counter 84n (identification number) indicating the excitation phase switching order and the excitation phase to be excited. The reel 61 is decelerated, and further, based on the relationship between the stop symbol and the predetermined position, the first slowdown process and the second slowdown process in which the deceleration time is shorter than the first slowdown process. Depending on the case, it is determined whether the reel 61 is to be decelerated. When the reel 61 is decelerated by the second slow-down process, the value of the deceleration counter 84n used in the first slow-down process is determined. According to the determined order of the deceleration counter 84n, the reel is decelerated while sequentially changing the excitation phase and the excitation time to be excited.

  With this configuration, the reels and stepping motors can be stopped completely after the reels are smoothly decelerated without having to prepare a plurality of deceleration patterns for each relationship between the stop symbol and the predetermined position. Can reduce the load on

As described above, in the embodiment, two sensor cut buns for detecting the rotation position of the reel 61 (61L, 61M, 61R) are provided for each of the reels 61 (61L, 61M, 61R) (the first sensor cut bang 76 and the first sensor cut bang 76). Although two sensor cut buns 77) are provided as an example, at least one sensor cut bang may be provided.
Therefore, the number of sensor cut buns may be one, or may be three or more, depending on the production cost and the required rotational position detection accuracy.

Furthermore, in the embodiment, when the reel is slowed down, the first deceleration table (see FIG. 33) having a long slowdown period and the second deceleration table (see FIG. 34) having a shorter slowdown period are used. Used to switch each excitation method (one-phase excitation or two-phase excitation) and set the excitation time (number of interrupts) in each excitation method. The number of switching times “deceleration order” and “excitation time (number of interrupts)” for each excitation method (one-phase excitation or two-phase excitation) can be changed as appropriate according to the length of the slowdown period and the reel slowdown method. It is.
Further, the number of deceleration tables used when the reels are slowed down is not limited to the aspect of the embodiment. For example, the number of deceleration tables may be one, or may be three or more. Is possible.

  Therefore, for example, as shown in FIGS. 38A and 38B, the number of “deceleration order” is the same, and the speed reduction tables, that is, the reels, that have different “excitation time (number of interrupts)” in each switching order are slowed down. Prepare deceleration tables (3rd deceleration table, 4th deceleration table) with different deceleration speeds, and select one of the deceleration tables based on the relationship between the stop symbol and the predetermined position, and slow down the reel. You may make it let it.

In the embodiment, the reel slow-down control is set to be performed on the main control board 80 side, but may be performed on the sub-control board 90 side.
In this way, when the sub-control board 90 controls the effect display displayed on the liquid crystal display 15, the reel slow-down control can be executed in conjunction with the effect display, so the load on the reel is reduced. While reducing, it becomes possible to enhance the effect of the game.

Furthermore, in the embodiment, the case where the all-phase excitation is finally performed and the reel is completely stopped is illustrated, but the reel is completely stopped by extending the excitation time in the one-phase excitation or the two-phase excitation. You may do it.
When slowdown control is executed, the reel rotation speed gradually decreases. Therefore, even if the reel is stopped by extending the excitation time in one-phase excitation or two-phase excitation, all reels rotating at a constant speed are This is because the possibility of out-of-step and rotational instability is lower than when stopping by phase excitation.

In the embodiment, when the stop buttons 46 to 48 are operated and a stop command is issued (FIG. 18, step 703), in the reel stop process (step 706), whether the reel is stopped while being slowed down is determined. However, it may be determined whether to stop the reel while slowing down after a predetermined time has elapsed after the stop command is issued.
For example, when the number of steps required to move the symbol to be stopped to a predetermined position reaches “20”, it may be determined whether to stop the reel while slowing down the reel.

Furthermore, in the embodiment, the case where the gaming machine is a slot machine has been described as an example.
The present invention may be applied to a game machine of a type different from the slot machine, specifically, a ball-type game machine using a game ball as a game medium, a so-called pachinko machine or the like. For example, a pachinko machine that unlocks a predetermined number of times when a game ball enters a specific area of a special device, a pachinko machine that generates a right when a game ball enters a specific area of a special device, and other objects You may make it implement as game machines, such as a pachinko machine provided with, an arrangement ball machine, and a sparrow ball.

  In addition, a non-ballistic game machine, for example, a game machine main body that is supported so as to be openable and closable by an outer frame, is provided with a storage and take-in device, and after a predetermined number of game balls stored in the storage unit are taken in by the take-in device It may be implemented as a so-called parrot game machine in which a pachinko machine and a slot machine are fused, which starts rotating a reel by operating a start lever.

  Hereinafter, the features of the invention extracted from the above-described embodiments and modifications will be described together with effects as necessary.

The present invention
(1) An orbital body on which a plurality of symbols are drawn,
A motor for rotating the rotating body;
Motor control means for controlling the motor to control rotation / stop of the rotating body;
Game control means for controlling the progress of the game;
When the stop button is operated, stop instruction means for outputting a stop command of the rotating circuit body,
When the stop command is output, a stop symbol determining means for determining a stop symbol to be displayed at a predetermined position when the circulating body is stopped, and
In the gaming machine in which the motor control means stops the circulating body within a predetermined time from the output of the stop command, and stops and displays the stop symbol at the predetermined position.
Based on the relationship between the stop symbol and the predetermined position,
A first stop condition for stopping the circulating body after decelerating the circulating body until the stop symbol reaches the predetermined position, and deceleration of the circulating body before the stopping symbol reaches the predetermined position A stop condition selecting means for selecting any one of a second stop condition for stopping the circuit body without performing the above operation,
The stop condition selecting means is
When it is possible to stop and display the stop symbol at the predetermined position when the orbiting body is stopped under the first stop condition, the first stop condition is selected,
The gaming machine characterized in that the motor control means stops the circuit body under a stop condition selected by the stop condition selection means.

  With this configuration, when the position of the stop symbol when the stop button is operated is a position that can reach the predetermined position even if the rotating body is decelerated while decelerating, it is circulated under the first stop condition. By stopping the body, it is possible to reduce the load applied to the orbiting body and the stepping motor as compared with the second stop condition in which the orbiting body is stopped without decelerating.

(2) The motor is a multiphase stepping motor,
In the second stop condition, all the phases are excited to stop the circuit body,
In the first stop condition, while sequentially switching the excitation phase, the excitation time of the excitation phase after switching is set to a length longer than the excitation time of the excitation phase before switching, and the circulating body is decelerated stepwise. Then, the game machine according to (1), wherein all the phases are excited to stop the circuit body.

  If comprised in this way, when stopping a circulating body on the 1st stop condition, since it can be made to stop completely after decelerating gradually, the load concerning a circulating body or a stepping motor can be reduced.

  Here, when stopping the circulating body by all-phase excitation, considering the deviation of the stop position of the circulating body, the minimum rotation of the rotating body rotated by, for example, a stepping motor, just before the scheduled stop symbol reaches the predetermined stop position. There is a gaming machine in which all-phase excitation is performed one step before the unit to stop the circulating body. In the case of such a gaming machine, the position one step before corresponds to the wording “predetermined position” in the claims.

(3) The gaming machine according to (2), wherein in the first stop condition, switching of excitation phases is sequentially executed by a 1-2 phase excitation method.

  If comprised in this way, since the rotation angle of the rotation body per step is small, rotation of a rotation body can be shown smoothly.

(4) The relationship between the stop symbol and the predetermined position is a time required to move the stop symbol to the predetermined position, according to any one of (1) to (3), Game machines.

  With this configuration, the time required for moving the stop symbol to a predetermined position is suppressed within a time period in which the player does not give a sense of incongruity to the behavior until the stop of the circuit body. It is possible to stop the rotating body after decelerating without causing the load on the rotating body and the stepping motor to be reduced.

(5) The relationship between the stop symbol and the predetermined position is the number of steps required to move the stop symbol to the predetermined position, according to any one of (1) to (3) The gaming machine described.

  If comprised in this way, since it is judged whether the 1st stop condition to stop, decelerating a circulating body is selected based on the step number which is the minimum rotation unit of a circulating body, it is 1st as much as possible. The stop condition can be selected to reduce the load on the circulating body and the stepping motor.

(6) The relationship between the stop symbol and the predetermined position is the number of symbols of the symbol required to move the stop symbol to the predetermined position.
In any one of (1) to (3), the number of slips of the symbol is specified with reference to a slip table that summarizes the number of symbols up to the stop symbol for each symbol of the orbiting body. The gaming machine described.

  With this configuration, it is not necessary to calculate the number of steps and time required to move the stop symbol to a predetermined position, and it is only necessary to refer to the sliding table, so that the processing burden and data can be reduced. .

(7) In the first stop condition,
Based on the deceleration pattern in which the excitation phase to be excited and the excitation time are associated with the identification number indicating the switching order of the excitation phase, the circulating body is decelerated,
Any one of (1) to (6), wherein the motor control means decelerates the rotating body while sequentially changing the excitation phase and the excitation time for applying the excitation according to the order of the identification numbers. The gaming machine according to the item.

  If comprised in this way, since a circulating body can be stopped completely after decelerating smoothly, the load concerning a circulating body or a stepping motor can be reduced.

(8) In the first stop condition,
Based on the deceleration pattern in which the excitation phase to be excited and the excitation time are associated with the identification number indicating the switching order of the excitation phase, the circulating body is decelerated,
The stop condition selecting means is
Based on the relationship between the stop symbol and the predetermined position, from among a plurality of identification numbers set in the deceleration pattern, determine an identification number to be used in the first stop condition,
In any one of (1) to (6), the motor control means decelerates the circuit body while sequentially changing the excitation phase and the excitation time for applying the excitation according to the determined order of the identification numbers. A gaming machine according to claim 1.

  With this configuration, it is possible to completely stop the orbiting body after smoothly decelerating without having to prepare a plurality of deceleration patterns for each relationship between the stop symbol and the predetermined position. The load on the stepping motor can be reduced.

(9) In the first stop condition, a plurality of deceleration patterns having different deceleration times of the circuit body are prepared,
The stop condition selection means selects one deceleration pattern from the plurality of deceleration patterns of the first stop condition based on the relationship between the stop symbol and the predetermined position,
The game according to any one of (1) to (6), characterized in that the motor control means decelerates the circuit body with a deceleration pattern selected by the stop condition selection means and then stops the circuit. Machine.

  With this configuration, since one deceleration pattern corresponding to the relationship between the stop symbol and the predetermined position is selected, the determined stop symbol is stopped and displayed at the predetermined position as much as possible, while the circulating object or stepping is displayed. The load on the motor can be reduced.

The present invention
(10) A circulating body having a plurality of symbols drawn on the outer periphery;
A motor for rotating the rotating body;
Motor control means for controlling the motor to control rotation / stop of the rotating body;
Game control means for controlling the progress of the game;
When the stop button is operated, stop instruction means for outputting a stop command of the rotating circuit body,
When the stop command is output, a stop symbol determining means for determining a stop symbol to be displayed at a predetermined position when the circulating body is stopped, and
In the gaming machine in which the motor control means stops the circulating body within a predetermined time from the output of the stop command, and stops and displays the stop symbol at the predetermined position.
A stop for selecting a first stop condition for stopping the orbiting body after decelerating the orbiting body until the stop symbol reaches the predetermined position in accordance with the relationship between the stop symbol and the predetermined position. A condition selection means,
In the first stop condition, a plurality of deceleration patterns in which at least one of the deceleration time and the deceleration of the orbiting body is different are prepared,
The stop condition selecting means is
When it is possible to stop and display the stop symbol at the predetermined position when the orbiting body is stopped under the first stop condition, among the plurality of deceleration patterns of the first stop condition From the selection of one deceleration pattern based on the relationship between the stop symbol and the predetermined position,
The game machine according to claim 1, wherein the motor control means decelerates the circuit body with a deceleration pattern selected by the stop condition selection means and then stops the rotating body.

  With this configuration, since one deceleration pattern corresponding to the positional relationship between the stop symbol and the predetermined position is selected, the determined stop symbol is stopped and displayed at a predetermined position as much as possible, The load on the stepping motor can be reduced.

(11) The motor is a multiphase stepping motor,
In the first stop condition, while sequentially switching the excitation phase, the excitation time of the excitation phase after switching is set to a length longer than the excitation time of the excitation phase before switching, and the circulating body is decelerated stepwise. Then, the game machine according to (10), wherein all the phases are excited to stop the circuit body.

  If comprised in this way, when stopping a circulating body on the 1st stop condition, since it can be made to stop completely after decelerating gradually, the load concerning a circulating body or a stepping motor can be reduced.

  Here, when stopping the circulating body by all-phase excitation, considering the deviation of the stop position of the circulating body, the minimum rotation of the rotating body rotated by, for example, a stepping motor, just before the scheduled stop symbol reaches the predetermined stop position. There is a gaming machine in which all-phase excitation is performed one step before the unit to stop the circulating body. In the case of such a gaming machine, the position one step before corresponds to the wording “predetermined position” in the claims.

(12) The gaming machine according to (11), wherein, in the first stop condition, excitation phase switching is sequentially executed by a 1-2 phase excitation method.

  If comprised in this way, since the rotation angle of the rotation body per step is small, rotation of a rotation body can be shown smoothly.

(13) The relationship between the stop symbol and the predetermined position is a time required to move the stop symbol to the predetermined position, according to any one of (10) to (12), Game machines.

  With this configuration, the time required for moving the stop symbol to a predetermined position is suppressed within a time period in which the player does not give a sense of incongruity to the behavior until the stop of the circuit body. It is possible to stop the rotating body after decelerating without causing the load on the rotating body and the stepping motor to be reduced.

(14) The relationship between the stop symbol and the predetermined position is the number of steps required to move the stop symbol to the predetermined position, according to any one of (10) to (12), The gaming machine described.

  If comprised in this way, since it is judged whether the 1st stop condition to stop, decelerating a circulating body is selected based on the step number which is the minimum rotation unit of a circulating body, it is 1st as much as possible. The stop condition can be selected to reduce the load on the circulating body and the stepping motor.

(15) The relationship between the stop symbol and the predetermined position is the number of symbols of the symbol required to move the stop symbol to the predetermined position,
Any one of (10) to (12), wherein the number of threads of the symbol is specified with reference to a thread table that summarizes the number of threads up to the stop symbol for each symbol of the orbiting body. The gaming machine described in 1.

  With this configuration, it is not necessary to calculate the number of steps and time required to move the stop symbol to a predetermined position, and it is only necessary to refer to the sliding table, so that the processing burden and data can be reduced. .

(16) In the deceleration pattern,
The excitation phase to be excited and the excitation time are associated with an identification number indicating the switching order of the excitation phase.
Any one of (10) to (15), wherein the motor control means decelerates the orbiting body while sequentially changing the excitation phase and the excitation time for applying the excitation according to the order of the identification numbers. The gaming machine according to the item.

  If comprised in this way, since a circulating body can be stopped completely after decelerating smoothly, the load concerning a circulating body or a stepping motor can be reduced.

(17) The gaming machine according to any one of (1) to (16), wherein the gaming machine is a pachinko gaming machine.
Among other things, the basic configuration of a pachinko gaming machine is provided with an operation handle, and in response to the operation of the operation handle, a ball is launched into a predetermined game area, and the ball is disposed at a predetermined position in the game area. As a necessary condition for winning the operating port (or passing through the operating port), the identification information dynamically displayed on the display device can be confirmed and stopped by the governor nursing. In addition, when a special gaming state occurs, a variable winning device (specific winning opening) disposed at a predetermined position in the gaming area is opened in a predetermined manner so that a ball can be won, and a value corresponding to the number of winnings is obtained. There are those to which value (including data written on a magnetic card as well as premium spheres) is given.

(18) The gaming machine according to any one of (1) to (16), wherein the gaming machine is a slot machine.
In particular, as a basic configuration of the slot machine, “variable display means for confirming and displaying the identification information after dynamically displaying an identification information string composed of a plurality of identification information is provided, and a starting operation means (for example, an operation lever) is provided. The dynamic display of the identification information is started due to the operation, the dynamic display of the identification information is stopped due to the operation of the operation means for stop (for example, the stop button) or after a predetermined time, The game machine is provided with special game state generating means for generating a special game state advantageous to the player on the condition that the confirmed identification information at the time of stoppage is the specific identification information. In this case, typical examples of the game media include medals and medals.

(19) The gaming machine according to any one of (1) to (16), wherein the gaming machine is a fusion of a pachinko gaming machine and a slot machine.
In particular, the basic configuration of the merged gaming machine includes “a variable display means for confirming and displaying the identification information after dynamically displaying an identification information string composed of a plurality of identification information, and a starting operation means (for example, an operation The dynamic display of the identification information is started due to the operation of the lever), and the dynamic display of the identification information is caused by the operation of the operation means for stop (for example, the stop button) or when a predetermined time elapses. Special game state generating means for generating a special game state advantageous to the player, on condition that the confirmed identification information at the time of the stop is specific identification information, and is used as a game medium In addition, the game machine is configured such that a predetermined number of balls are required at the start of dynamic display of the identification information, and a large number of balls are paid out when a special gaming state occurs.

DESCRIPTION OF SYMBOLS 10 Slot machine 11 Case body 11a Top plate 11b Bottom plate 11c Back plate 11d Left side plate 11e Right side plate 11f Partition plate 12 Front door 13 Upper lamp 14 Speaker 15 Liquid crystal display 16 Lower plate 17 Medal outlet 18 Dish 20 Locking mechanism 24 DC stability 30 display panel 31 (30L, 30M, 30R) display window 32 bet lamp 33 bet lamp 34 bet lamp 35 credit number display part 36 game number display part 37 earned number display part 40 operation part 40a plane part 40b vertical wall part 41 1 sheet Bet button 42 Two-bed bet button 43 Max bet buttons 41a to 43a Bet operation detection sensor 44 Credit settlement button 44a Switching operation detection sensor 45 Start lever 45a Lever operation detection sensor 46 Stop button 4 Stop button 48 Stop button 46a to 48a Stop operation detection sensor 49 Return button 50 Medal insertion slot 50a Insertion medal detection sensor 51 Control board storage box 52 Hopper device 52a Medal payout detection sensor 53 Storage tank 54 Guide plate 55 Payout device 56 Power supply device 56a Power supply unit 56b Power failure monitoring circuit 57 Medal storage box 60 Reel unit 61 Reel 61L Left reel 61M Middle reel 61R Right reel 65 Selector 66 Storage passage 67 Discharge passage 68 Opening 70 Cylindrical frame member 71 Boss portion 72 Boss reinforcement plate 73 Motor plate 75 Reel Index Sensor 75a Light Emitting Element 75b Light Receiving Element 76 First Sensor Cut Van 76a Tip 76b Base End 76e Terminal (Base Point)
76s start end (base point position)
77 Second sensor cut van 77a Tip end 77e End point (base point position)
77s start end (base point position)
79 Stepping motor 80 Main control board 81 MPU
82 I / O port 83 ROM
83a Excitation table 84 RAM
84a Memory area for checksum correction value 84b Memory area for saving stack pointer 84c Slide table 84d Expected payout number counter 84e Payout number counter 84f Wait timer 84g Acceleration counter 84h Excitation order pointer 84i Symbol offset value 84j Symbol number 84k Timing counter 84m Remaining symbol Counter 84n Deceleration counter 84p Deceleration wait timer 84q Subtraction number 85 Clock circuit 90 Sub control board 91 External concentration terminal board 100 Motor driver 122 Setting key switch 123 Reset switch 123a Reset operation detection sensor 124 Setting key insertion hole 124a Setting key operation detection sensor 790 Rotor 791 Front rotor 792 Back rotor 793 1st pole 794 2nd pole 795 3rd pole 796 4th Pole L0 to L3 Excitation coil Ta Acceleration period Tb Constant speed period Tc Stop period

Claims (1)

A orbital body with multiple designs drawn on it,
A multiphase stepping motor that rotationally drives the rotating body;
Motor control means for sequentially switching the excitation phase of the stepping motor to control rotation / stop of the orbiting body;
Game control means for controlling the progress of the game;
When the stop button is operated, stop instruction means for outputting a stop command of the rotating circuit body,
When the stop command is output, a stop symbol determining means for determining a stop symbol to be displayed at a predetermined position when the circulating body is stopped, and
In the gaming machine in which the stepping motor control means stops the circulating body within a predetermined time from the output of the stop command, and stops and displays the stop symbol at the predetermined position.
Based on the relationship between the stop symbol and the predetermined position, a stop for selecting a first stop condition for stopping the orbiting body after decelerating the orbiting body until the stop symbol reaches the predetermined position. A condition selection means,
In the first stop condition, at least one of the deceleration time and the deceleration of the circling body is different, and the excitation phase to be excited and the excitation time are associated with an identification number indicating the switching order of the excitation phases. The deceleration pattern of
The stop condition selecting means is
When it is possible to stop and display the stop symbol at the predetermined position when the orbiting body is stopped under the first stop condition, among the plurality of deceleration patterns of the first stop condition From the output of the stop command, it is a deceleration pattern that can stop the orbiting body within a predetermined time, and has one deceleration pattern with the longest slowdown period in the relationship between the stop symbol and the predetermined position. Select based on
The motor control unit uses the deceleration pattern selected by the stop condition selection unit to decelerate the circuit body while sequentially changing the excitation phase and the excitation time for applying the excitation according to the order of the identification numbers. A gaming machine characterized by being stopped later.

Images