JP2019037454A - Game machine - Google Patents

Abstract

To provide a game machine capable of displaying a symbol and a virtual reel with motion on a display unit with high accuracy as a video.MEANS FOR SOLVING THE PROBLEM: It is determined whether or not a game machine is in a blur state (ST202). In the case of a positive determination, decoding is performed from an I frame immediately before a movie frame acquired in step ST201 until the acquired movie frame, in the stopped movie data (ST203). In the case of a negative determination, decode is performed from the I frame immediately before the movie frame acquired in the step ST201 until the acquired movie frame, in rotating movie data (blur movie) (ST204)SELECTED DRAWING: Figure 11

Description

  The present invention relates to a gaming machine such as a pachislot machine (slot machine).

  A pachislot machine (slot machine) rotates and stops multiple (usually 3) reels with multiple types of symbols according to the player's operation, and the combination of symbols when the reels stop ( ) To pay out medals. In addition, the pachislot machine controls the blinking of the lamp, the sound output of the speaker, the screen display on the display, and the like in accordance with the progress of the game, thereby performing an effect process that enhances the player's mood.

  By the way, three virtual reels (sub-reels) are displayed on the display screen, and the virtual reels may be stopped and various effect images may be displayed by stopping the virtual reels.

JP 2006-204796 A

  By the way, it is necessary to perform image processing of a plurality of virtual reels based on a combination result of operations on the three virtual reels. If simply performed, the processing amount becomes enormous and the responsiveness deteriorates. is there. If the responsiveness is poor, the pushing operation cannot be performed with a sense closer to that of a real reel.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a gaming machine that can display a moving virtual reel or symbol as an image on a display unit with high accuracy.

  In addition, an object of the present invention is to provide a gaming machine that can enjoy a push operation for stopping a specific design of a virtual reel displayed as an image on a display unit at a specific position with a sense closer to that of a real reel. There is to do.

  In the gaming machine according to the first aspect of the invention, a display unit for displaying an image and a virtual reel having a plurality of types of symbols on its peripheral surface rotate while increasing the rotational speed from a stopped state, and the rotational speed is a predetermined rotation. A processing unit that displays an image composed of a plurality of frames per one rotation of the virtual reel at the predetermined rotation speed on the display unit, the image rotating at the predetermined rotation speed when the speed is reached. An instruction input unit that inputs rotation start and stop instructions of the virtual reel in the video of the display unit, and rotating movie data that displays a rotating image of at least one rotation for each of the plurality of virtual reels (Blur movie) and a memory for storing the stopped movie data for displaying the stopped video for at least one rotation, and the processing unit includes the plurality of virtual For each of the rules, the state of stopping and rotating is determined, and based on the determined state, one movie data is selected from the rotating movie data and the stopping movie data for the virtual reel. An update processing unit to select, and a drawing processing unit to perform a drawing process of decoding and drawing a frame constituting movie data selected by the update processing unit for the plurality of virtual reels.

    Preferably, the update processing unit of the processing unit enters a rotation state when a rotation start instruction is input from the instruction input unit, calculates a rotation speed of the plurality of virtual reels, and the calculated rotation speed is calculated in advance. When the determined first threshold value (blur speed) is exceeded, the movie data during rotation is selected for the virtual reel corresponding to the rotation speed, and if it is equal to or less than the first threshold value, Select the stopped movie data.

  Preferably, the update processing unit calculates an index value (maximum frame * rotation speed / speed scale) corresponding to a rotation angle amount based on the rotation speed and the rotation acceleration for the virtual reel in a rotating state. Then, based on the index value, the frame to be subjected to the drawing process next is determined.

  Preferably, the update processing unit sequentially updates the rotation speed based on a predetermined rotation acceleration until the rotation speed reaches a predetermined maximum speed in a state where the rotation speed of the virtual reel is accelerated, and the rotation speed Then, an index value (maximum frame * rotation speed / speed scale) corresponding to the rotation angle amount is calculated based on the rotation acceleration, and the next frame to be subjected to the drawing process is determined based on the index value. .

  Preferably, when a stop instruction is input from the instruction input unit, the update processing unit shifts to a slip state after the stop process, and in the slip state, the current position of the virtual reel is the stop of the virtual reel. The rotating movie data is selected until the stop position determined by the processing is reached, and when the current position of the virtual reel becomes the stop position, the stopped movie data is selected and a bounce start state is entered.

  A gaming machine according to a second aspect includes a display unit that displays an image, and a processing unit that displays an image of a plurality of types of images having a periodic motion and configured by a plurality of frames on the display unit. And a memory for storing, for each of the plurality of symbols, first movie data for displaying at least one cycle of operating video and second movie data for displaying at least one cycle of stopped video And the processing unit determines a stopped state and an operating state for each of the plurality of symbols, and based on the determined state, the first movie data for the symbol and the An update processing unit for selecting one movie data from the second movie data and a frame constituting the movie data selected by the update processing unit for the plurality of symbols are decoded and drawn. And a drawing processing unit that performs rendering processing for.

According to the present invention, it is possible to provide a gaming machine that can display a moving virtual reel or symbol as a video on the display unit with high accuracy.
In addition, an object of the present invention is to provide a gaming machine that can enjoy a push operation for stopping a specific design of a virtual reel displayed as an image on a display unit at a specific position with a sense closer to that of a real reel. can do.

It is a figure for demonstrating the display, the operation part, etc. which are arrange | positioned at the front side of the pachi-slot machine which concerns on embodiment of this invention. It is a lineblock diagram of a pachislot machine of an embodiment of the present invention. It is a functional block diagram of a sub main control part. It is a figure which shows an example of a structure of a sub sub control part. It is a flowchart for demonstrating the whole process regarding the virtual reel display of the process part shown in FIG. 5 is a flowchart for explaining an update process shown in FIG. 3 performed by a processing unit shown in FIG. It is a flowchart for demonstrating the acceleration process of step ST26 shown in FIG. It is a flowchart for demonstrating the stop process of step ST28 shown in FIG. It is a flowchart for demonstrating the slip process of step ST30 shown in FIG. It is a flowchart for demonstrating the bound process of step ST34 shown in FIG. It is a flowchart for demonstrating the 1st Example of the drawing process of step ST4 shown in FIG. It is a flowchart for demonstrating the 2nd Example of the drawing process of step ST4 shown in FIG.

Hereinafter, a pachislot machine as a gaming machine according to an embodiment of the present invention will be described.
FIG. 1 is a diagram for explaining a display, an operation unit, and the like arranged on the front side of the pachislot machine according to the present embodiment.
In the example of FIG. 1, on the front of the pachislot machine 1, a main reel unit 30, a display 35 such as a liquid crystal panel, a medal insertion unit 11, a 1-bet button 201, a 3-bet button 203, a start lever 205, a left stop button 207L, middle stop button 207M, and right stop button 207R are arranged.
The display 35 is an example of a display unit in the present invention.

The main reel unit 30 includes three reels (main reels) each having a plurality of types of symbols on the peripheral surface, and a reel rotating unit 17 (FIG. 2) that rotationally drives the three main reels. For example, 21 symbols are drawn side by side on the peripheral surface of each main reel. Three adjacent symbols of each reel are displayed through a transparent display window provided in front of the pachislot machine. When all main reels are stopped, nine symbols arranged in 3 rows and 3 columns are displayed in the display window.
The medal insertion unit 11 includes a mechanism for inserting and storing medals in a pachislot machine, and a sensor for detecting the insertion of medals.

A 1-bet button 201 and a 3-bet button 203 are input devices for setting the number of medals to bet in one game. One medal is used for one game when the one-bet button 201 is pressed, and three medals are used for one game when the three-bet button 203 is pressed. When the bet number of medals is one, the presence / absence of a winning is determined according to the combination (outcome) of symbols in one line in the horizontal direction of the middle row in the above-mentioned 3 rows and 3 columns symbols. When the number of medals bet is 3, in the 3 rows and 3 columns design described above, the combination of the 3 lines in the upper, middle, and lower rows and the 2 lines in the diagonally lower right direction and the diagonally upward left direction (outward) The presence or absence of a prize is determined according to the eye). A line in which the presence / absence of a winning is determined in the 3 × 3 symbol array is referred to as a “winning line”.
Note that the number of medals to bet in one game is not limited to the above example, and may be, for example, only one, or the player can freely select one, two, or three. In addition, the number of winning lines is arbitrary, and may be, for example, only one line in the middle stage, or five lines in the diagonal direction of the upper, middle, and lower stages.

  The start lever 205 is an input device for inputting an instruction to start rotation of the main reel unit 30. When a medal is inserted from the medal insertion unit 11 and the start lever 205 is hit in a state where the number of medals is set by the 1-bet button 201 or the 3-bet button 203, the main reel starts rotating in the main reel unit 30. .

  The left stop button 207L, middle stop button 207M, and right stop button 207R are input devices for inputting a stop instruction for each main reel of the main reel section 30, and correspond to the instruction input section in the present invention. Pressing the left stop button 207 stops the left main reel, pressing the middle stop button 207M stops the central main reel, and pressing the right stop button 207R stops the right main reel.

  The display 35 is a display device for displaying a video for production, and includes, for example, a liquid crystal display panel, an EL display panel, and the like. As will be described later, the display 35 displays an image in which a production reel (virtual reel) simulating a main reel rotates and stops, an animation image of a character, and the like.

  The pachislot machine has a touch sensor 33 that detects an object (such as a player's finger) on the screen of the display 35. The touch sensor 33 detects an object in a detection area covering the video display surface of the display 35, and generates data indicating the position of the detected object.

FIG. 2 is a diagram illustrating an example of the configuration of the pachislot machine 1 according to the present embodiment.
The pachi-slot machine 1 according to the present embodiment includes a main control unit 3, a sub main control unit 5, and a sub sub control unit 7, for example, as shown in FIG.

[Main control unit 3]
The main control unit 3 is a circuit block that comprehensively controls the overall progress of the game, and includes, for example, a processor that executes processing according to a program and a memory. For example, the main control unit 3 sets the betting number of medals, starts the rotation of the main reel according to the operation of the start lever 205, the internal lottery of the lottery that determines the combination (outcome) of symbols on the main reel winning line, A series of operations such as reel stop according to the result of the internal lottery, determination of the winning result according to the outcome on the winning line, and the medal payout are controlled.

  In the example of FIG. 2, the main control unit 3 includes a medal insertion unit 11, a medal payout unit 13, a lottery drawing unit 15, a reel rotation unit 17, and operation button groups 20 (201, 203, 205, 207L, 207M, 207R). Is connected. A display 35 and a speaker 37 are connected to the sub-sub control unit 7.

  The main control unit 3 monitors the medal insertion detection signal from the medal insertion unit 11 and records the number of medals stored for use in the game. When an appropriate number of medals are inserted in the medal insertion unit 11 and the start lever 205 is hit in a state where the bet number of medals is set by the bet buttons (201, 203), the main control unit 3 causes the lottery drawing unit 15 to be struck. The lottery of the main lottery is carried out to acquire the lottery that has been lottery, and the reel rotating unit 17 of the main reel unit 30 is controlled to start the rotation of the three main reels.

The lottery lottery unit 15 generates a random number according to the control of the main control unit 3, and determines the main lottery by performing a lottery based on the generated random number. The main lottery indicates one game combination selected by lottery from a plurality of predetermined game combinations. The game combination is a combination relating to the provision of a game value such as a medal, and mainly determines a combination (outcome) of symbols on a winning line. For the game role indicated by the main lottery, for example, a small role in which medals are paid out for each game, a bonus role in which medals are repeatedly paid out in multiple games, and medals are inserted in the game There is a replay role that makes it unnecessary. The lottery lottery unit 15 randomly selects one game combination as a main lot from a plurality of such predetermined game combinations.
In the present embodiment, the gaming combination selected by the lottery lottery unit 15 as the lottery result also includes “out of winning combination” in which no gaming value is given (medal is not paid out).

  The main control unit 3 starts rotation of the main reel in response to an instruction from the start lever 205, and then issues an instruction to stop reel rotation by pressing one of the three reel stop buttons (207L, 207M, 207R). When input, the left, middle or right main reel corresponding to the pressed reel stop button is stopped.

  When stopping the main reel, the main control unit 3 stops the main reel so that the main reel to be stopped stops at a symbol corresponding to the game combination indicated by the main lottery drawn by the lottery lottery unit 15. The rotation angle). For example, when the game combination indicated by the main lottery is a bonus combination, the main control unit 3 determines a predetermined sliding piece from the reel reference position (for example, the lower position in the display window of the main reel) when the reel stop button is pressed. If there is a bonus combination symbol within the range of numbers, the reel rotating unit 17 is controlled (pull-in control) so that the symbol stops on the winning line. In addition, when the game combination indicated by the main lottery is an out-of-game combination, the main control unit 3 performs the main operation at a position (rotation angle) at which a combination (out) of a symbol that gives a game value (performs a medal payout) is not established. The reel rotating unit 17 is controlled (kicking control) so that the rotation of the reel is stopped.

  When the three main reels are stopped according to the player's operation, the main control unit 3 determines the winning result based on the combination of symbols on the winning line. Then, the main control unit 3 controls the medal paying unit 13 so as to pay out the number of medals according to the number of medals when the predetermined number that causes the medals to be paid out is aligned on the winning line.

  Further, the main control unit 3 sequentially outputs data (commands) relating to the progress of the game, such as the start and stop of the rotation of the main reel, the lottery result of the lottery drawing unit 15, and the insertion and payout of medals, to the sub main control unit 5 .

  For example, when a medal is inserted in the medal insertion unit 11, the main control unit 3 displays data indicating the number of inserted medals, the number of medals stored in the medal insertion unit 11, and the like. 5 is output.

  When the bet button (201, 203) is pressed, the main control unit 3 outputs data indicating the press to the sub-main control unit 5.

  When the start lever 205 is struck in a state where the bet number of medals is set by the bet buttons (201, 203), the main control unit 3 displays data indicating that the start lever 205 has been struck (start of rotation of the main reel). Data indicating the operation) is output to the sub-main control unit 5.

  When the lottery lottery unit 15 draws the main lottery in response to the start lever 205 being hit, the main control unit 3 sub-data (main lottery data) indicating the main lottery lottery lottery unit 15 has drawn. Output to the main controller 5.

  When the reel stop button (207L, 207M, 207R) is pressed while any of the main reels is rotating in the main reel unit 30, the main control unit 3 confirms that the corresponding reel stop button has been pressed. The indicated data (data indicating the rotation stop operation of the corresponding main reel) is output to the sub main control unit 5. Further, the main control unit 3 outputs data related to the symbol (stop symbol) indicated by the main reel stopped by the pull-in control or kicking control to the sub main control unit 5.

  When the stop symbols of the three main reels are confirmed, the main control unit 3 outputs the winning result data indicated by the combination of symbols on the winning line (the outcome) to the sub main control unit 5. When the medal payout is performed from the medal payout unit 13 according to the winning result, the main control unit 3 outputs data indicating the number of payout medals to the sub main control unit 5.

[Sub-main control unit 5]
Next, the sub main control unit 5 will be described.
The sub-main control unit 5 is a circuit block that receives data (commands) related to the progress of the game from the main control unit 3 and determines the production contents in the production unit (display 35, speaker 37, etc.) according to the inputted data. For example, it is configured to include a processor that executes processing according to a program and a memory.

  The sub main control unit 5 selects one production pattern from a plurality of predetermined production patterns according to the main lottery data output from the main control unit 3. Then, each time the sub-main control unit 5 inputs data related to the progress of the game from the main control unit 3, the sub-main control unit 5 designates the production content (the video on the display 35 and the sound of the speaker 37) based on the decided production pattern. Data is generated and output to the sub-sub control unit 7.

For example, the sub-main control unit 5 includes data that is a trigger (trigger) for the output of the effect among the data relating to the game progress input from the main control unit 3, and data related to the content of the effect to be output in accordance with this data Are stored in the storage device.
When the main lottery data is input from the main control unit 3, the sub-main control unit 5 selects one trigger table from a plurality of trigger tables stored in the storage device according to the game combination indicated by the main lottery data. . The sub-main control unit 5 generates data for designating the content of the effect with reference to the selected trigger table each time data relating to the progress of the game is input from the main control unit 3. Output.

  Further, the sub main control unit 5 detects an object (such as a player's finger) near the screen of the display 35 by the touch sensor 33 and generates data indicating the position of the object based on the generated data. Is acquired, and information on the state of the object such as whether or not a plurality of objects have been detected near the screen, the moving distance of the object per predetermined time, and the moving direction of the object is acquired. When the sub-main control unit 5 obtains information on the position and state of the object based on the input data from the touch sensor 33, the sub-main control unit 5 displays the contents of the effect to be output with the acquisition of such information as a trigger (trigger). Based on the above, data for designating the determined production content is generated and output to the sub-sub control unit 7.

  FIG. 3 is a functional block diagram of the sub-main control unit.

When the sub-main control unit 5 inputs data related to the progress of the game from the main control unit 3 or acquires coordinate data of an object near the screen based on the detection output of the touch sensor 33, the main lot indicates By referring to the effect pattern (trigger table) determined according to the game role, data (command) specifying the effect content to be output using these data as a trigger (trigger) is generated, and the sub-sub control unit 7 Output to.
For example, the sub-main control unit 5 outputs data specifying a video such as an animation to be displayed on the display 35, data specifying a sound to be reproduced on the speaker 37, and the like to the sub-sub control unit 7. Further, the sub main control unit 5 outputs data related to control of the virtual reels to be displayed as video on the display 35 to the sub sub control unit 7. Furthermore, the sub-main control unit 5 performs blink control of the notification lamp 31 as part of the effect.

  When the sub-sub control unit 7 receives the data (command) designating the production contents from the sub-main control unit 5, the sub-sub control unit 7 displays an image such as an animation on the display 35 or a sound effect on the speaker 37 according to the input data (command). Play back. Further, when the sub-sub control unit 7 receives data related to the control of the virtual reels from the sub-main control unit 5, the sub-sub control unit 7 controls the video of the virtual reels displayed on the display 35 in accordance with the input data. When the rotation of the virtual reel of the display 35 is stopped, the sub-sub control unit 7 outputs data (stop result data) regarding the combination (outcome) of the symbols of the stopped virtual reels to the sub-main control unit 5.

  When the sub-main control unit 5 inputs stop result data related to the appearance of the stopped virtual reel from the sub-sub control unit 7, the sub-main control unit 5 changes the content of the effect determined according to the main lottery according to the stop result data. That is, the sub-main control unit 5 selects a new trigger table from a plurality of trigger tables stored in the storage device in accordance with the appearance of the stopped virtual reel.

  Examples of commands output from the sub main control unit 5 to the sub sub control unit 7 include basic common display commands (error, setting change, stop button request, setting confirmation commands), timing instruction commands (main control unit 3 side) Commands related to operations such as betting, main reel rotation start, left / middle / right main reel stop commands, medal related commands (credit number, inserted number, paid out number related commands), sound related commands (sound generation) And virtual reel related commands (virtual reel rotation start instruction data, left virtual reel rotation stop instruction data, middle virtual reel rotation stop instruction data, right virtual reel rotation stop instruction data, for production Random number data for selecting combination data and stop pattern Stop order data related to the stop order of reels), model-specific production commands (commands for managing productions that differ for each model), special operation commands (commands related to external input for menu display, for example, external input button operation commands, touch panel operations Command) and system commands (commands for changing the stop output of the virtual reel, commands for increasing the reel, etc.). In response to these commands, the sub-sub control unit 7 controls screen display on the display 35 and output of sound effects on the speaker 37.

  On the other hand, examples of commands output from the sub-sub control unit 7 to the sub-main control unit 5 include, for example, commands related to bidirectional communication (system commands for communication), and state commands for performances by type (results of effects) And a command for issuing a virtual reel result command (information on a combination of symbols arranged in the virtual reel, for example, a command for sending information on a winning symbol combination and a winning line on which the symbol combination is established). is there.

  Here, data to be output from the sub-main control unit 5 to the sub-sub control unit 7 regarding the control of the virtual reel of the display 35 (effect data and random number data, stop order determination data, virtual reel rotation start instruction data, virtual reel stop instruction Data) will be described in detail.

FIG. 3 is a diagram illustrating an example of the configuration of the sub-main control unit 5.
The sub-main control unit 5 illustrated in FIG. 3 includes a processing unit 50, communication interface units 51 and 52, an effect information storage unit 55, and a system storage unit 56.

The communication interface unit 51 is a circuit that inputs data from the main control unit 3.
The communication interface unit 52 is a circuit that outputs data to the sub-sub control unit 7 and inputs data from the sub-sub control unit 7.

  The effect information storage unit 55 stores information related to the contents of the effect (video displayed on the display 35, sound output from the speaker 37, etc.) according to the progress of the game, and stores, for example, the trigger table described above.

  The system storage unit 56 stores a program for executing processing in the processing unit 50 and data used for the processing.

The processing unit 50 is a circuit that controls the overall processing of the sub-main control unit 5, and performs the process of determining the production contents according to the instructions of the program stored in the system storage unit 56.
For example, when the main lottery data indicating the main lottery drawn in the lottery lottery unit 15 is input in the communication interface unit 51, the processing unit 50 reads the main lottery from a plurality of trigger tables stored in the effect information storage unit 55. Select the trigger table according to the data. In this case, the processing unit 50 may select one trigger table by lottery from a plurality of trigger table candidates corresponding to the main lottery data. When the processing unit 70 inputs data (command) that is a trigger (trigger) of the output of the effect from the main control unit 3, the processing unit 70 refers to the selected trigger table and specifies the effect content corresponding to the input data. (Production designation data) is generated at any time and output from the communication interface unit 52 to the sub-sub control unit 7. For example, at the timing set in the trigger table, the processing unit 50 generates data (command) designating the video of the display 35 and the sound of the speaker 37 to be reproduced at that time, and outputs the data (command) to the sub-sub control unit 7.

  Further, the processing unit 50 determines whether or not an object is detected in a detection region covering the screen of the display 35 based on data generated by the touch sensor 33, and if an object is detected, the position of the object is detected. The coordinate data indicating is acquired. The processing unit 50 analyzes the data generated by the touch sensor 33 to determine whether or not an object is detected at a plurality of locations in the detection area, start and end of object detection, and the movement distance of the object. Various information related to the state of the object in the detection area, such as the moving direction and the presence / absence of double tapping / repetitive hitting, is acquired.

[Sub-sub control unit 7]
Next, the sub-sub control unit 7 will be described.
When the sub-sub control unit 7 receives data (command) designating the content of the effect from the sub-main control unit 5, the sub-sub control unit 7 generates a video displayed on the display 35 or a sound output from the speaker 37 in accordance with the input data (command). Control. For example, the sub-sub control unit 7 reads video data and sound data corresponding to the input data (command) from the video / sound storage unit 74 (FIG. 9), generates a video signal and an audio signal corresponding thereto, and displays the display 35. And supplied to the speaker 37.

The sub-sub control unit 7 also receives virtual reel control data (production effect data, random number data, stop order determination data, virtual reel rotation start instruction data, virtual reel stop instruction data) input from the sub main control unit 8. In response to this, an image in which the virtual reel rotates / stops is displayed on the display 35.
That is, when the sub-sub control unit 7 receives rotation start instruction data indicating the operation of the start lever 205 from the sub-main control unit 5, the sub-sub control unit 7 displays a video on the display 35 in which a plurality of virtual reels start rotating all at once.
When the rotation stop instruction data of one virtual reel is input from the sub main control unit 5, the sub sub control unit 7 outputs the rotation angle of the one virtual reel at the input timing and the effect input from the sub main control unit 5. A rotation angle at which the one virtual reel is stopped is determined according to the combination data, random number data, and stop order determination data, and an image in which the one virtual reel stops at the determined rotation angle is displayed on the display 35. .

Furthermore, when the sub-sub control unit 7 stops all virtual reels according to the virtual reel stop instruction data, the sub-sub control unit 7 sub-data (stop result data) regarding the combination (outcome) of symbols indicated by the stopped virtual reels. Output to the control unit 5.
For example, the sub-sub control unit 7 determines whether or not the combination (outcome) of the symbols indicated by the stopped virtual reels satisfies the winning condition defined in the stop pattern specified by the effect role data and the random number data. Make a winning decision. Then, the sub-sub control unit 7 outputs stop result data including information on the winning determination result and information on the winning line on which the winning determination is performed to the sub-main control unit 5.
In the case where the sub-sub control unit 7 does not perform the winning determination and outputs only the information of the virtual reel stop symbol as the stop result data to the sub-main control unit 5, the sub-main control unit 5 performs the winning determination. May be.

FIG. 4 is a diagram illustrating an example of the configuration of the sub-sub control unit 7.
4 includes a processing unit 70, a communication interface unit 71, a video signal output unit 72, an audio signal output unit 73, a video / sound storage unit 74, a frame buffer 75, and a system storage. Part 76.
The processing unit 70 of the sub-sub control unit 7 is an example of a processing unit in the present invention.

  The communication interface unit 71 is a circuit for exchanging data with the sub main control unit 5, and inputs data from the sub main control unit 5 and outputs data to the sub main control unit 5.

The video signal output unit 72 generates a video signal having a predetermined signal format according to the video data supplied from the processing unit 70 and inputs the video signal to the display 35.
The audio signal output unit 73 generates an audio signal whose amplitude and pulse density are adjusted according to the sound data supplied from the processing unit 70 and inputs the audio signal to the speaker 37.

  The video / sound storage unit 74 stores video data used to configure the screen of the display 35 and sound data used to output sound at the speaker 37. The video data and the sound data stored in the video / sound storage unit 74 are associated with identification information, respectively. The sub-sub control unit 7 reads the video data / sound data from the video / sound storage unit 74 by referring to the identification information included in the data (command) from the sub-main control unit 5 that designates the production content.

  The video / sound storage unit 74 stores image data of a plurality of types of symbols provided on the peripheral surface of the virtual reel displayed on the display 35.

  The frame buffer 75 is a memory for storing video information displayed on the display 35 in units of screens, and stores one or a plurality of screens.

  The system storage unit 76 stores a program for executing processing in the processing unit 70, data used for processing, and data temporarily held in the course of processing. For example, the system storage unit 76 stores a table including data such as the number of sliding symbols used for control (stop control, kick control) of the virtual reel stop position.

  The processing unit 70 is a circuit that controls the overall processing of the sub-sub control unit 7, and processes the video displayed on the display 35 and the sound output from the speaker 37 in accordance with the instructions of the program stored in the system storage unit 76. I do.

  The processing unit 70 displays an image of a virtual reel having a plurality of types of symbols on its peripheral surface on the display 35 as with the main reel. For example, the processing unit 70 constructs a video of a three-dimensional virtual reel having a depth by computer graphics processing, and data for virtual reel control (virtual reel rotation start instruction data, virtual virtual) input from the sub-main control unit 5. In response to the reel stop instruction data or the like, the video image of rotating or stopping the three-dimensional virtual reel is displayed on the display 35.

  That is, when the virtual reel rotation start instruction data is input from the sub-main control unit 5, the processing unit 70 starts rotating from the stopped state and gradually increases the rotation speed, and the rotation speed reaches a predetermined maximum rotation speed. Then, an image that rotates while maintaining the maximum rotation speed (that is, at a constant speed) is displayed on the display 35.

  Specifically, the processing unit 70 configures an image including a three-dimensional virtual reel for each predetermined frame period on the frame buffer 75, and in parallel with this, configures the image configured on the frame buffer 75. It is displayed on the display 35 as one frame for every predetermined frame period.

  In constructing the virtual reel video, the processing unit 70 first calculates the rotation angle of the virtual reel for each frame. For example, when the virtual reel is stopped, the processing unit 70 keeps the rotation angle of the virtual reel constant even when the frame is switched. When the virtual reel is rotating, the processing unit 70 changes the rotation angle every time the frame is switched. Let Further, when the rotation speed is accelerated immediately after the start of rotation, the processing unit 70 calculates the rotation angle so that the amount of change in the angle increases every time the frame is switched. When the rotation speed becomes constant at a predetermined maximum rotation speed, the processing unit 70 calculates the rotation angle so that the amount of change in angle at the time of frame switching is kept constant. As will be described later, when the rotation speed reaches a predetermined maximum rotation speed, the processing unit 70 corrects the rotation angle so as to facilitate the visual recognition of a predetermined symbol that serves as a guide for pressing the virtual reel. I do.

  When the rotation angle of the virtual reel is obtained, the processing unit 70 maps a plurality of types of symbols on the surface based on the image data of a plurality of types stored in the video / sound storage unit 74 and the rotation angle. A computer graphics image of the reel body (left, middle, right) having a predetermined three-dimensional shape is generated and written in the frame buffer 75.

  When left, center, or right virtual reel stop instruction data is input from the sub-main control unit 5 while the virtual reel rotates at a constant speed, the processing unit 70 corresponds to the left, center, or right virtual reel. An image in which the rotation of is stopped is displayed on the display 35.

When stopping the virtual reel, the processing unit 70 determines the rotation angle (design position) of the virtual reel at the timing when the virtual reel stop instruction data is input, and the stop pattern specified by the effect combination data and random number data. Based on this, the rotation angle (symbol position) at which the virtual reel stops is controlled.
That is, when the virtual reel stop instruction data is input from the sub-main control unit 5 while the virtual reel rotation image is displayed, the processing unit 70 stops the virtual object to be stopped at the timing when the virtual reel stop instruction data is input. Based on the rotation angle (design position) of the reel and the stop pattern specified by the effect data and random number data input from the sub-main control unit 5, the rotation angle (design) for stopping the virtual reel to be stopped ) Is determined, and an image in which the virtual reel to be stopped stops at the rotation angle (symbol position) is displayed on the display 35.

For example, the processing unit 70 selects a specific table from a plurality of virtual reel stop position control tables stored in advance in the system storage unit 76 based on the effect combination data and random number data input from the sub-main control unit 5. select. This table includes, for example, data associating the rotation angle (design position) of the virtual reel at the timing when the virtual reel stop instruction data is input with the rotation angle at which the rotation of the virtual reel is stopped. The data registered in the table is to stop the symbols allowed by the stop pattern specified by the presentation role data and random number data on the winning line (withdrawal control), and not to stop the symbols prohibited by the rendering role on the winning line. (Kicking control) is adjusted in advance.
When the virtual reel stop instruction data is input from the sub-main control unit 5, the processing unit 70 refers to the above table selected based on the effect combination data and the random number data, and the rotation angle at which the rotation of the virtual reel is stopped. (Symbol position) is determined, and an image in which the rotation of the virtual reel stops at the determined rotation angle is displayed on the display 35.

The processing unit 70 realizes the sub reel (AG reel) in real time 3D. The processing unit 70 displays the sub reel using movie data.
The processing unit 70 switches and uses the rotating movie data for each of the three sub reels and the stopped movie data for each of the three sub reels, thereby realizing a rotated and stopped video. The six movie data are loopable movie data in which the beginning and the end are seamlessly connected.
In the present embodiment, the rotating movie data is composed of a plurality of frames for displaying a rotating image for at least one rotation for the corresponding virtual reel. The stopped movie data is composed of a plurality of frames for displaying the stopped video for at least one rotation for the corresponding virtual reel.

FIG. 5 is a flowchart for explaining the overall processing relating to virtual reel display of the processing unit 70 shown in FIG.
Step ST1:
When detecting the frame synchronization, the processing unit 70 proceeds to step ST2.

Step ST2:
When the rotation start instruction and the stop instruction are input, the processing unit 70 sets the state STS to start and stop process start, respectively.
Further, when the reverse rotation setting instruction is input, the processing unit 70 sets the rotation direction to be reverse.
In addition, when the speed scale setting instruction is input, the processing unit 70 receives a speed scale setting operation.

Step ST3:
The processing unit 70 performs update processing according to the state STS.
FIG. 6 is a flowchart for explaining the update process shown in FIG. 5 performed by the processing unit 70.

Step ST4:
The processing unit 70 performs a drawing process for decoding and drawing a frame constituting the movie frame specified by the update process in step ST3.
The drawing process shown in FIG. 5 performed by the processing unit 70 will be described in detail with reference to FIGS. z

Hereinafter, the update process illustrated in FIG. 5 performed by the processing unit 70 will be described in detail with reference to FIG. 6.
The following update process is performed for each of the three virtual reels.
Step ST21:
The processing unit 70 determines whether or not the state STS is in an idle state. If the determination is affirmative, the process proceeds to step ST22. If the determination is negative, the process proceeds to step ST23.

Step ST22:
The processing unit 70 sets the rotating state (blur state) to off during rotation (blur off) and sets it to the reverse rotating state.

Step ST23:
The processing unit 70 determines whether or not the state STS is “starting state”. If the determination is affirmative, the process proceeds to step ST24. If the determination is negative, the process proceeds to step ST25.

Step ST24:
The processing unit 70 initializes the stop position of the virtual reel and sets the rotation speed to the initial value (0).
In the present embodiment, the stop position indicates a rotation angle (design position) at which the virtual reel is stopped. More specifically, the stop position is a symbol position having 20 or 21 on each reel. The stop position is expressed by a number from 0 to 19, or from 0 to 20, for example.
Further, the processing unit 70 sets the state STS to the “accelerated state”.

Step ST25:
The processing unit 70 determines whether or not the state STS is the “acceleration state”. If the determination is affirmative, the process proceeds to step ST26, and if the determination is negative, the process proceeds to step ST27.

Step ST26:
The processing unit 70 performs a virtual reel acceleration process.
The processing unit 70 updates the rotation speed by adding a predetermined rotation acceleration, determines a frame to be drawn next (an index value for specifying a frame such as a frame number) based on the updated rotation speed, Proceed to ST35.
FIG. 7 is a flowchart for explaining the acceleration process of step ST26 shown in FIG.

Step ST27:
The processing unit 70 determines whether or not the state STS is a stop processing state. If the determination is affirmative, the process proceeds to step ST28. If the determination is negative, the process proceeds to step ST29.

Step ST28:
The processing unit 70 performs a virtual reel stop process.
The processing unit 70 sequentially sets the fixed positions of the three reels according to the first to third stop operations, sets the state STS to “sliding”, and proceeds to step ST29.
FIG. 8 is a flowchart for explaining the stop process of step ST28 shown in FIG.

Step ST29:
The processing unit 70 determines whether or not the state STS is a slipping state. If the determination is affirmative, the process proceeds to step ST30. If the determination is negative, the process proceeds to step ST31.

Step ST30:
The processing unit 70 performs a virtual reel slip process.
The processing unit 70 sequentially sets the stop positions of the three reels according to the first to third stop operations, and proceeds to step ST29.
FIG. 9 is a flowchart for explaining the slip processing in step ST30 shown in FIG.

Step ST31:
The processing unit 70 determines whether or not the state STS is a bound start state. If the determination is affirmative, the process proceeds to step ST32. If the determination is negative, the process proceeds to step ST33.

Step ST32:
The processing unit 70 initializes the bound variable and shifts the state STS to “being bound”.

Step ST33:
The processing unit 70 determines whether or not the state STS is in a bound state. If the determination is affirmative, the process proceeds to step ST34, and if the determination is negative, the process proceeds to step ST35.

Step ST34:
The processing unit 70 performs virtual reel bound processing.
FIG. 10 is a flowchart for explaining the bound process in step ST34 shown in FIG.

Step ST35:
The processing unit 70 performs a process of rounding the movie frame to the maximum frame.
Specifically, the rounding process is a process of “movie frame = (movie frame + maximum frame)% maximum frame (% is a remainder calculation symbol)”.

Hereinafter, the acceleration process of step ST26 shown in FIG. 6 will be described with reference to FIG.
The processing unit 70 adds a predetermined rotational acceleration to the current rotational speed (ST41).
The processing unit 70 determines whether or not the rotational speed is greater than a predetermined maximum speed (ST42), and sets the predetermined maximum speed to the rotational speed when an affirmative determination is made (ST43). On the other hand, in the case of negative determination, the processing unit 70 determines whether or not the rotational speed is greater than a predetermined blur speed (first threshold value) (ST44). ", That is, set to select the movie data during manual stop.

Next, the processing unit 70 determines whether or not it is in the “reverse rotation state”. If the determination is affirmative, the process proceeds to step ST47. If the determination is negative, the process proceeds to step ST48.
If the determination is affirmative, the processing unit 70 calculates “movie frame number = movie frame number + (maximum frame number * (rotational speed / speed scale) / 360)”.
When the determination is negative, the processing unit 70 calculates “movie frame number = movie frame number− (maximum frame number * (rotational speed / speed scale) / 360)”. Here, (rotational speed / speed scale) is an example of the index value of the present invention.

Hereinafter, the stop process of step ST28 shown in FIG. 6 will be described with reference to FIG.
The processing unit 70 determines whether or not the reel stop operation is the first stop operation of three reels (ST51). If the determination is affirmative, the first stop stop corresponding to the timing of the reel stop operation is performed. A position is set (ST52). If a negative determination is made, the process proceeds to step ST53.

  Next, the processing unit 70 determines whether or not the reel stop operation is the second stop operation of three reels (ST53). If the determination is affirmative, the second stop corresponding to the timing of the reel stop operation is performed. The stop position is set (ST54). If a negative determination is made, the process proceeds to step ST55.

  Next, the processing unit 70 determines whether or not the reel stop operation is a third stop operation of three reels (ST55). If the determination is affirmative, the third stop according to the timing of the reel stop operation is performed. The stop position is set (ST56). If a negative determination is made, the process proceeds to step ST57.

Next, the processing unit 70 determines whether or not it is in the “reverse rotation state” (ST57). If the determination is affirmative, the process proceeds to step ST58, and if the determination is negative, the process proceeds to step ST59.
If the determination is affirmative, processing unit 70 sets the current position to the stop position set in ST52, ST54, and ST56 (ST58).
On the other hand, in the case of a negative determination, processing unit 70 sets “(maximum position−stop position) / maximum position” as the stop position (ST59).
Next, processing unit 70 updates state STS to “sliding” (ST60).

Hereinafter, it is a flowchart for demonstrating the slip process of step ST30 shown in FIG. 6, referring FIG.
The processing unit 70 determines whether or not it is in the “reverse rotation state” (ST61). If the determination is affirmative, the process proceeds to step ST63, and if the determination is negative, the process proceeds to step ST62.
In the case of negative determination, the processing unit 70 determines whether or not the current position matches the stop position. If the determination is affirmative, the processing unit 70 proceeds to step ST65. If the determination is negative, the processing unit 70 proceeds to step ST64.

In step ST64, the processing unit 70 sets “maximum frame number * (rotational speed / speed scale) / 360)” as the “frame addition value”.
Next, the processing unit 70 sets “movie frame + frame addition value” as the movie frame number.

In step ST65, the processing unit 70 switches the setting so as to set the blur state to OFF, that is, to select the stopped movie data.
Further, the processing unit 70 sets “stop position * (maximum frame number / maximum number of frames)” as the movie frame number. Here, the maximum number of frames is “maximum stop position value + 1”.
Next, the processing unit 70 sets the state STS to “bound start state”.

In step ST <b> 66, the processing unit 70 sets “−maximum frame number * (rotational speed / speed scale) / 360)” to “frame added value”.
Next, the processing unit 70 sets “movie frame + frame addition value” as the movie frame number.

In step ST67, the processing unit 70 switches the setting so that the blur state is set to OFF, that is, the stopped movie data is selected.
Further, the processing unit 70 sets “stop position * (maximum frame number / maximum number of frames)” as the movie frame number.
Next, the processing unit 70 sets the state STS to “bound start state”.

Hereinafter, with reference to FIG. 10, the bound process of step ST34 shown in FIG. 6 will be described.
In FIG. 10, the bounce angle is used to express the shake by adding it to the rotation angle. The bounce process is a process of calculating a bounce angle and a bounce frame for expressing the reel swing by adding to the stopped movie frame.

  In the bound process, when the rotation speed of the virtual reel is outside the predetermined range including the rotation stop, the processing unit 70 sequentially decreases the rotation speed and decreases the bound angle by a magnitude corresponding to the rotation speed. Processing for determining the next frame to be rendered from the movie data according to the bound angle is performed.

The processing unit 70 determines whether or not the rotation angle of the virtual reel is less than a predetermined first threshold (for example, 0.5) (ST81). If the determination is affirmative, the bounce angle is 0. If the determination is affirmative, a value obtained by subtracting the bound width from the rotation angle is set as a new rotation angle (ST83), and the process proceeds to step ST88.
On the other hand, if the determination is negative in step ST82, processing unit 70 proceeds to step ST88.
On the other hand, if the determination is negative in step ST81, the processing unit 70 proceeds to step ST84.

The processing unit 70 determines whether or not the rotation angle of the virtual reel is less than a predetermined second threshold value (for example, −0.5) opposite in sign to the first threshold value (ST84). In the case of affirmative determination, it is determined whether or not the bounce angle exceeds 0 (ST86). In the case of affirmative determination, a value obtained by subtracting the bounce width from the rotation angle is set as a new rotation angle (ST87). Proceed to step ST88.
On the other hand, the process part 70 progresses to step ST88, when negative determination is made at step ST86.
On the other hand, in the case of negative determination in step ST84, the processing unit 70 sets the rotation speed to “0”, sets the state STS to “idling”, and proceeds to step ST88.

In step ST88, the processing unit 70 sets “bound angle−rotational speed / speed scale value” as a new bound angle.
Next, processing unit 70 determines whether or not it is in the reverse rotation state (ST89), and in the case of an affirmative determination, sets “−maximum frame * bound angle / 360” as a new bound frame (ST90). On the other hand, in the case of a negative determination, processing unit 70 sets “maximum frame * bound angle / 360” as a new bound frame (ST90).
Here, the bound frame is “a value obtained by calculating the number of frames corresponding to the bound angle when the maximum frame is 360 degrees”.

Hereinafter, the drawing process of step ST4 shown in FIG. 3 will be described.
First embodiment of the drawing process:
FIG. 11 is a flowchart for explaining a first embodiment of the drawing process in step ST4 shown in FIG.
The example shown in FIG. 9 shows a case where all movie frames are composed of I frames.
Processing unit 70 acquires a movie frame (ST101). Here, the movie frame is obtained by adding a bound frame to the movie frame specified by the update process shown in FIG.

The processing unit 70 determines whether or not the state STS is a blur state (ST102). If the determination is affirmative, the processing unit 70 decodes only one frame of the movie frame acquired in step ST101 in the stopped movie data (ST103). .
On the other hand, in the case of negative determination, the processing unit 70 decodes only one movie frame acquired in step ST101 in the rotating movie data (blur movie) (ST104).

The processing unit 70 renders the movie frame decoded in step ST103 or ST104 (ST105).
The processing unit 70 performs the above-described processing of steps ST101 to ST104 for each of the three virtual reels, and performs drawing processing so that the decoded four frames are combined into one frame and displayed.

  In the method shown in FIG. 11, since all movie frames are composed of I frames, it is possible to zip all frames. For this reason, an operation in which the reel rotates once can be created with 360 frames, for example, and the value of the frame can be controlled as an angle.

Second embodiment of the drawing process:
FIG. 12 is a flowchart for explaining a second embodiment of the drawing process in step ST4 shown in FIG.
In the example shown in FIG. 9, the movie frame is composed of three types of frames of I, P, and B.
Processing unit 70 acquires a movie frame (ST201). Here, the movie frame is obtained by adding a bound frame to the movie frame specified by the update process shown in FIG.

The processing unit 70 determines whether or not the state STS is a blur state (ST202). If the determination is affirmative, the acquisition is performed from the I frame immediately before the movie frame acquired in step ST201 in the stopped movie data. Up to the movie frame is decoded (ST203).
On the other hand, in the case of negative determination, the processing unit 70 decodes from the I frame immediately before the movie frame acquired in step ST201 to the acquired movie frame in the rotating movie data (blur movie) (ST204).

The processing unit 70 renders the movie frame decoded in step ST203 or ST204 (ST205).
The processing unit 70 performs the above-described processing of steps ST201 to ST204 for each of the three virtual reels, and performs drawing processing so that the decoded four frames are combined into one frame and displayed.

  In the method shown in FIG. 12, since the movie frame is composed of three types of frames of I, P, and B, high compression efficiency can be obtained.

As described above, according to the pachislot machine 1, for example, in the display processing of each virtual reel, by using one movie data during rotation, acceleration at the start of rotation, deceleration at the time of stop, display of reel bounce Processing can be realized.
Further, according to the pachislot machine 1, the position of the symbol at the time of stopping can be stopped at a fixed position even when the rotating movie data is reproduced so as to rotate the virtual reel at an arbitrary speed. Further, since the image can be displayed with high accuracy, it can be pushed.

  While various embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and includes other various variations.

  For example, the specific numerical values (the maximum rotation speed of the virtual reel, the frame rate of the display 35, the number of virtual reels, the number of symbols provided on the virtual reel, etc.) in the above-described embodiments are examples, and the present invention It is not limited by the numerical value.

  Further, the configuration of the rendering hardware in the above-described embodiment is an example, and the present invention is not limited to this. For example, in the above-described embodiment, the speaker 37 is connected to the sub-sub control unit 7. However, in another embodiment of the present invention, the speaker 37 may be connected to the sub-main control unit 5. In this case, an audio signal processing circuit may be mounted in the sub main control unit 5 and a program (driver) for controlling audio reproduction may be operated in the sub main control unit 5.

  In the embodiment described above, an example in which the sub-main control unit 5 has data for production (trigger table) has been described, but the present invention is not limited to this. In another embodiment of the present invention, the sub-sub control unit 7 may have a trigger table. In this case, when the sub-main control unit 5 inputs information (information such as bet button detection, start lever detection, first to third reel stop detection, etc.) from the main control unit 3 as a trigger for the production, It may be outputted to the unit 7 so that the sub-sub control unit 7 generates an effect corresponding to the trigger table.

In the embodiment described above, an example in which the present invention is applied to a pachislot machine is given, but the present invention is not limited to this. That is, the present invention is widely applicable to various gaming machines that stop the rotation of the reel displayed as an image on the display by the player's operation.
That is, the processing unit 70 performs a process of displaying an image of a plurality of types of images having a periodic motion and composed of a plurality of frames instead of the three virtual reels. In this case, for each of the plurality of symbols, the first movie data for displaying at least one cycle of operating video and the second movie data for displaying at least one cycle of stopped video are stored in memory. To remember.
The processing unit 70 determines the stopped and operating states for each of the plurality of symbols, and based on the determined state, from among the first movie data and the second movie data for the symbol. , Select one movie data. Then, the processing unit 70 performs a drawing process for decoding and drawing frames constituting movie data selected for a plurality of symbols.

DESCRIPTION OF SYMBOLS 1 ... Pachi slot machine, 3 ... Main control part, 5 ... Sub main control part, 7 ... Sub sub control part, 11 ... Medal insertion part, 13 ... Medal paying part, 15 ... Lottery lottery part, 17 ... Reel rotation part, 20 ... Operation button group, 33 ... touch sensor, 35 ... display, 37 ... speaker, 50, 70 ... processing unit, 51, 52, 71 ... communication interface unit, 55 ... production information storage unit, 56, 76 ... system storage unit, 72 ... Video signal output unit, 73 ... Audio signal output unit, 74 ... Video / sound storage unit, 75 ... Frame buffer, 201 ... Single bet button, 203 ... Three bet button, 205 ... Start lever, 207L ... Left stop button 207M ... Middle stop button, 207R ... Right stop button.

  The present invention relates to a gaming machine such as a pachislot machine (slot machine).

  A pachislot machine (slot machine) rotates and stops multiple (usually 3) reels with multiple types of symbols according to the player's operation, and the combination of symbols when the reels stop ( ) To pay out medals. In addition, the pachislot machine controls the blinking of the lamp, the sound output of the speaker, the screen display on the display, and the like in accordance with the progress of the game, thereby performing an effect process that enhances the player's mood.

  By the way, three virtual reels (sub-reels) are displayed on the display screen, and the virtual reels may be stopped and various effect images may be displayed by stopping the virtual reels.

JP 2006-204796 A

  By the way, it is necessary to perform image processing of a plurality of virtual reels based on a combination result of operations on the three virtual reels. If simply performed, the processing amount becomes enormous and the responsiveness deteriorates. is there. If the responsiveness is poor, the pushing operation cannot be performed with a sense closer to that of a real reel.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a gaming machine that can display a moving virtual reel or symbol as an image on a display unit with high accuracy.

  In addition, an object of the present invention is to provide a gaming machine that can enjoy a push operation for stopping a specific design of a virtual reel displayed as an image on a display unit at a specific position with a sense closer to that of a real reel. There is to do.

In the gaming machine of the present invention, a display unit that displays an image and a virtual reel having a plurality of types of symbols on its peripheral surface rotate while increasing its rotational speed from a stopped state, and the rotational speed reaches a predetermined rotational speed. Then, a processing unit for displaying on the display unit a video that is rotated while maintaining the predetermined rotational speed, and is configured to display a video composed of a plurality of frames per one rotation of the virtual reel at the predetermined rotational speed, An instruction input unit that inputs an instruction to start and stop the rotation of the virtual reel in the video of the display unit, rotating movie data that displays a rotating image of at least one rotation for each of the plurality of virtual reels, and at least A memory for storing stopped movie data for displaying a stopped image for one rotation, and the processing unit stops each of the plurality of virtual reels. And an update processing unit that determines a rotating state, and selects one movie data from among the rotating movie data and the stopped movie data for the virtual reel, based on the determined state, possess a rendering processing unit which performs a drawing process for drawing decodes the frames constituting the movie data selected for a plurality of virtual reels in the update processing unit, the update processing unit, a stop instruction from the instruction input unit When input, after the stop process, the slide state is entered, and in the slip state, the rotating movie data is selected until the current position of the virtual reel reaches the stop position determined by the virtual reel stop process. Then, when the current position of the virtual reel becomes the stop position, the stopped movie data is selected and a bounce start state is entered.

  Preferably, after the transition to the bounce start state, when the rotation speed of the virtual reel is outside a predetermined range including rotation stop, the rotation speed is decreased in order, and the bounce angle is increased according to the rotation speed. Next, a frame to be subjected to a drawing process is determined from the movie data in accordance with the bound angle.

According to the present invention, it is possible to provide a gaming machine that can display a moving virtual reel or symbol as a video on the display unit with high accuracy.
In addition, an object of the present invention is to provide a gaming machine that can enjoy a push operation for stopping a specific design of a virtual reel displayed as an image on a display unit at a specific position with a sense closer to that of a real reel. can do.

It is a figure for demonstrating the display, the operation part, etc. which are arrange | positioned at the front side of the pachi-slot machine which concerns on embodiment of this invention. It is a lineblock diagram of a pachislot machine of an embodiment of the present invention. It is a functional block diagram of a sub main control part. It is a figure which shows an example of a structure of a sub sub control part. It is a flowchart for demonstrating the whole process regarding the virtual reel display of the process part shown in FIG. 5 is a flowchart for explaining an update process shown in FIG. 3 performed by a processing unit shown in FIG. It is a flowchart for demonstrating the acceleration process of step ST26 shown in FIG. It is a flowchart for demonstrating the stop process of step ST28 shown in FIG. It is a flowchart for demonstrating the slip process of step ST30 shown in FIG. It is a flowchart for demonstrating the bound process of step ST34 shown in FIG. It is a flowchart for demonstrating the 1st Example of the drawing process of step ST4 shown in FIG. It is a flowchart for demonstrating the 2nd Example of the drawing process of step ST4 shown in FIG.

Hereinafter, a pachislot machine as a gaming machine according to an embodiment of the present invention will be described.
FIG. 1 is a diagram for explaining a display, an operation unit, and the like arranged on the front side of the pachislot machine according to the present embodiment.
In the example of FIG. 1, on the front of the pachislot machine 1, a main reel unit 30, a display 35 such as a liquid crystal panel, a medal insertion unit 11, a 1-bet button 201, a 3-bet button 203, a start lever 205, a left stop button 207L, middle stop button 207M, and right stop button 207R are arranged.
The display 35 is an example of a display unit in the present invention.

The main reel unit 30 includes three reels (main reels) each having a plurality of types of symbols on the peripheral surface, and a reel rotating unit 17 (FIG. 2) that rotationally drives the three main reels. For example, 21 symbols are drawn side by side on the peripheral surface of each main reel. Three adjacent symbols of each reel are displayed through a transparent display window provided in front of the pachislot machine. When all main reels are stopped, nine symbols arranged in 3 rows and 3 columns are displayed in the display window.
The medal insertion unit 11 includes a mechanism for inserting and storing medals in a pachislot machine, and a sensor for detecting the insertion of medals.

A 1-bet button 201 and a 3-bet button 203 are input devices for setting the number of medals to bet in one game. One medal is used for one game when the one-bet button 201 is pressed, and three medals are used for one game when the three-bet button 203 is pressed. When the bet number of medals is one, the presence / absence of a winning is determined according to the combination (outcome) of symbols in one line in the horizontal direction of the middle row in the above-mentioned 3 rows and 3 columns symbols. When the number of medals bet is 3, in the 3 rows and 3 columns design described above, the combination of the 3 lines in the upper, middle, and lower rows and the 2 lines in the diagonally lower right direction and the diagonally upward left direction (outward) The presence or absence of a prize is determined according to the eye). A line in which the presence / absence of a winning is determined in the 3 × 3 symbol array is referred to as a “winning line”.
Note that the number of medals to bet in one game is not limited to the above example, and may be, for example, only one, or the player can freely select one, two, or three. In addition, the number of winning lines is arbitrary, and may be, for example, only one line in the middle stage, or five lines in the diagonal direction of the upper, middle, and lower stages.

  The start lever 205 is an input device for inputting an instruction to start rotation of the main reel unit 30. When a medal is inserted from the medal insertion unit 11 and the start lever 205 is hit in a state where the number of medals is set by the 1-bet button 201 or the 3-bet button 203, the main reel starts rotating in the main reel unit 30. .

  The left stop button 207L, middle stop button 207M, and right stop button 207R are input devices for inputting a stop instruction for each main reel of the main reel section 30, and correspond to the instruction input section in the present invention. Pressing the left stop button 207 stops the left main reel, pressing the middle stop button 207M stops the central main reel, and pressing the right stop button 207R stops the right main reel.

  The display 35 is a display device for displaying a video for production, and includes, for example, a liquid crystal display panel, an EL display panel, and the like. As will be described later, the display 35 displays an image in which a production reel (virtual reel) simulating a main reel rotates and stops, an animation image of a character, and the like.

  The pachislot machine has a touch sensor 33 that detects an object (such as a player's finger) on the screen of the display 35. The touch sensor 33 detects an object in a detection area covering the video display surface of the display 35, and generates data indicating the position of the detected object.

FIG. 2 is a diagram illustrating an example of the configuration of the pachislot machine 1 according to the present embodiment.
The pachi-slot machine 1 according to the present embodiment includes a main control unit 3, a sub main control unit 5, and a sub sub control unit 7, for example, as shown in FIG.

[Main control unit 3]
The main control unit 3 is a circuit block that comprehensively controls the overall progress of the game, and includes, for example, a processor that executes processing according to a program and a memory. For example, the main control unit 3 sets the betting number of medals, starts the rotation of the main reel according to the operation of the start lever 205, the internal lottery of the lottery that determines the combination (outcome) of symbols on the main reel winning line, A series of operations such as reel stop according to the result of the internal lottery, determination of the winning result according to the outcome on the winning line, and the medal payout are controlled.

  In the example of FIG. 2, the main control unit 3 includes a medal insertion unit 11, a medal payout unit 13, a lottery drawing unit 15, a reel rotation unit 17, and operation button groups 20 (201, 203, 205, 207L, 207M, 207R). Is connected. A display 35 and a speaker 37 are connected to the sub-sub control unit 7.

  The main control unit 3 monitors the medal insertion detection signal from the medal insertion unit 11 and records the number of medals stored for use in the game. When an appropriate number of medals are inserted in the medal insertion unit 11 and the start lever 205 is hit in a state where the bet number of medals is set by the bet buttons (201, 203), the main control unit 3 causes the lottery drawing unit 15 to be struck. The lottery of the main lottery is carried out to acquire the lottery that has been lottery, and the reel rotating unit 17 of the main reel unit 30 is controlled to start the rotation of the three main reels.

The lottery lottery unit 15 generates a random number according to the control of the main control unit 3, and determines the main lottery by performing a lottery based on the generated random number. The main lottery indicates one game combination selected by lottery from a plurality of predetermined game combinations. The game combination is a combination relating to the provision of a game value such as a medal, and mainly determines a combination (outcome) of symbols on a winning line. For the game role indicated by the main lottery, for example, a small role in which medals are paid out for each game, a bonus role in which medals are repeatedly paid out in multiple games, and medals are inserted in the game There is a replay role that makes it unnecessary. The lottery lottery unit 15 randomly selects one game combination as a main lot from a plurality of such predetermined game combinations.
In the present embodiment, the gaming combination selected by the lottery lottery unit 15 as the lottery result also includes “out of winning combination” in which no gaming value is given (medal is not paid out).

  The main control unit 3 starts rotation of the main reel in response to an instruction from the start lever 205, and then issues an instruction to stop reel rotation by pressing one of the three reel stop buttons (207L, 207M, 207R). When input, the left, middle or right main reel corresponding to the pressed reel stop button is stopped.

  When stopping the main reel, the main control unit 3 stops the main reel so that the main reel to be stopped stops at a symbol corresponding to the game combination indicated by the main lottery drawn by the lottery lottery unit 15. The rotation angle). For example, when the game combination indicated by the main lottery is a bonus combination, the main control unit 3 determines a predetermined sliding piece from the reel reference position (for example, the lower position in the display window of the main reel) when the reel stop button is pressed. If there is a bonus combination symbol within the range of numbers, the reel rotating unit 17 is controlled (pull-in control) so that the symbol stops on the winning line. In addition, when the game combination indicated by the main lottery is an out-of-game combination, the main control unit 3 performs the main operation at a position (rotation angle) at which a combination (out) of a symbol that gives a game value (performs a medal payout) is not established. The reel rotating unit 17 is controlled (kicking control) so that the rotation of the reel is stopped.

  When the three main reels are stopped according to the player's operation, the main control unit 3 determines the winning result based on the combination of symbols on the winning line. Then, the main control unit 3 controls the medal paying unit 13 so as to pay out the number of medals according to the number of medals when the predetermined number that causes the medals to be paid out is aligned on the winning line.

  Further, the main control unit 3 sequentially outputs data (commands) relating to the progress of the game, such as the start and stop of the rotation of the main reel, the lottery result of the lottery drawing unit 15, and the insertion and payout of medals, to the sub main control unit 5 .

  For example, when a medal is inserted in the medal insertion unit 11, the main control unit 3 displays data indicating the number of inserted medals, the number of medals stored in the medal insertion unit 11, and the like. 5 is output.

  When the bet button (201, 203) is pressed, the main control unit 3 outputs data indicating the press to the sub-main control unit 5.

  When the start lever 205 is struck in a state where the bet number of medals is set by the bet buttons (201, 203), the main control unit 3 displays data indicating that the start lever 205 has been struck (start of rotation of the main reel). Data indicating the operation) is output to the sub-main control unit 5.

  When the lottery lottery unit 15 draws the main lottery in response to the start lever 205 being hit, the main control unit 3 sub-data (main lottery data) indicating the main lottery lottery lottery unit 15 has drawn. Output to the main controller 5.

  When the reel stop button (207L, 207M, 207R) is pressed while any of the main reels is rotating in the main reel unit 30, the main control unit 3 confirms that the corresponding reel stop button has been pressed. The indicated data (data indicating the rotation stop operation of the corresponding main reel) is output to the sub main control unit 5. Further, the main control unit 3 outputs data related to the symbol (stop symbol) indicated by the main reel stopped by the pull-in control or kicking control to the sub main control unit 5.

  When the stop symbols of the three main reels are confirmed, the main control unit 3 outputs the winning result data indicated by the combination of symbols on the winning line (the outcome) to the sub main control unit 5. When the medal payout is performed from the medal payout unit 13 according to the winning result, the main control unit 3 outputs data indicating the number of payout medals to the sub main control unit 5.

[Sub-main control unit 5]
Next, the sub main control unit 5 will be described.
The sub-main control unit 5 is a circuit block that receives data (commands) related to the progress of the game from the main control unit 3 and determines the production contents in the production unit (display 35, speaker 37, etc.) according to the inputted data. For example, it is configured to include a processor that executes processing according to a program and a memory.

  The sub main control unit 5 selects one production pattern from a plurality of predetermined production patterns according to the main lottery data output from the main control unit 3. Then, each time the sub-main control unit 5 inputs data related to the progress of the game from the main control unit 3, the sub-main control unit 5 designates the production content (the video on the display 35 and the sound of the speaker 37) based on the decided production pattern. Data is generated and output to the sub-sub control unit 7.

For example, the sub-main control unit 5 includes data that is a trigger (trigger) for the output of the effect among the data relating to the game progress input from the main control unit 3, and data related to the content of the effect to be output in accordance with this data Are stored in the storage device.
When the main lottery data is input from the main control unit 3, the sub-main control unit 5 selects one trigger table from a plurality of trigger tables stored in the storage device according to the game combination indicated by the main lottery data. . The sub-main control unit 5 generates data for designating the content of the effect with reference to the selected trigger table each time data relating to the progress of the game is input from the main control unit 3. Output.

  Further, the sub main control unit 5 detects an object (such as a player's finger) near the screen of the display 35 by the touch sensor 33 and generates data indicating the position of the object based on the generated data. Is acquired, and information on the state of the object such as whether or not a plurality of objects have been detected near the screen, the moving distance of the object per predetermined time, and the moving direction of the object is acquired. When the sub-main control unit 5 obtains information on the position and state of the object based on the input data from the touch sensor 33, the sub-main control unit 5 displays the contents of the effect to be output with the acquisition of such information as a trigger (trigger). Based on the above, data for designating the determined production content is generated and output to the sub-sub control unit 7.

  FIG. 3 is a functional block diagram of the sub-main control unit.

When the sub-main control unit 5 inputs data related to the progress of the game from the main control unit 3 or acquires coordinate data of an object near the screen based on the detection output of the touch sensor 33, the main lot indicates By referring to the effect pattern (trigger table) determined according to the game role, data (command) specifying the effect content to be output using these data as a trigger (trigger) is generated, and the sub-sub control unit 7 Output to.
For example, the sub-main control unit 5 outputs data specifying a video such as an animation to be displayed on the display 35, data specifying a sound to be reproduced on the speaker 37, and the like to the sub-sub control unit 7. Further, the sub main control unit 5 outputs data related to control of the virtual reels to be displayed as video on the display 35 to the sub sub control unit 7. Furthermore, the sub-main control unit 5 performs blink control of the notification lamp 31 as part of the effect.

  When the sub-sub control unit 7 receives the data (command) designating the production contents from the sub-main control unit 5, the sub-sub control unit 7 displays an image such as an animation on the display 35 or a sound effect on the speaker 37 according to the input data (command). Play back. Further, when the sub-sub control unit 7 receives data related to the control of the virtual reels from the sub-main control unit 5, the sub-sub control unit 7 controls the video of the virtual reels displayed on the display 35 in accordance with the input data. When the rotation of the virtual reel of the display 35 is stopped, the sub-sub control unit 7 outputs data (stop result data) regarding the combination (outcome) of the symbols of the stopped virtual reels to the sub-main control unit 5.

  When the sub-main control unit 5 inputs stop result data related to the appearance of the stopped virtual reel from the sub-sub control unit 7, the sub-main control unit 5 changes the content of the effect determined according to the main lottery according to the stop result data. That is, the sub-main control unit 5 selects a new trigger table from a plurality of trigger tables stored in the storage device in accordance with the appearance of the stopped virtual reel.

  Examples of commands output from the sub main control unit 5 to the sub sub control unit 7 include basic common display commands (error, setting change, stop button request, setting confirmation commands), timing instruction commands (main control unit 3 side) Commands related to operations such as betting, main reel rotation start, left / middle / right main reel stop commands, medal related commands (credit number, inserted number, paid out number related commands), sound related commands (sound generation) And virtual reel related commands (virtual reel rotation start instruction data, left virtual reel rotation stop instruction data, middle virtual reel rotation stop instruction data, right virtual reel rotation stop instruction data, for production Random number data for selecting combination data and stop pattern Stop order data related to the stop order of reels), model-specific production commands (commands for managing productions that differ for each model), special operation commands (commands related to external input for menu display, for example, external input button operation commands, touch panel operations Command) and system commands (commands for changing the stop output of the virtual reel, commands for increasing the reel, etc.). In response to these commands, the sub-sub control unit 7 controls screen display on the display 35 and output of sound effects on the speaker 37.

  On the other hand, examples of commands output from the sub-sub control unit 7 to the sub-main control unit 5 include, for example, commands related to bidirectional communication (system commands for communication), and state commands for performances by type (results of effects) And a command for issuing a virtual reel result command (information on a combination of symbols arranged in the virtual reel, for example, a command for sending information on a winning symbol combination and a winning line on which the symbol combination is established). is there.

  Here, data to be output from the sub-main control unit 5 to the sub-sub control unit 7 regarding the control of the virtual reel of the display 35 (effect data and random number data, stop order determination data, virtual reel rotation start instruction data, virtual reel stop instruction Data) will be described in detail.

FIG. 3 is a diagram illustrating an example of the configuration of the sub-main control unit 5.
The sub-main control unit 5 illustrated in FIG. 3 includes a processing unit 50, communication interface units 51 and 52, an effect information storage unit 55, and a system storage unit 56.

The communication interface unit 51 is a circuit that inputs data from the main control unit 3.
The communication interface unit 52 is a circuit that outputs data to the sub-sub control unit 7 and inputs data from the sub-sub control unit 7.

  The effect information storage unit 55 stores information related to the contents of the effect (video displayed on the display 35, sound output from the speaker 37, etc.) according to the progress of the game, and stores, for example, the trigger table described above.

  The system storage unit 56 stores a program for executing processing in the processing unit 50 and data used for the processing.

The processing unit 50 is a circuit that controls the overall processing of the sub-main control unit 5, and performs the process of determining the production contents according to the instructions of the program stored in the system storage unit 56.
For example, when the main lottery data indicating the main lottery drawn in the lottery lottery unit 15 is input in the communication interface unit 51, the processing unit 50 reads the main lottery from a plurality of trigger tables stored in the effect information storage unit 55. Select the trigger table according to the data. In this case, the processing unit 50 may select one trigger table by lottery from a plurality of trigger table candidates corresponding to the main lottery data. When the processing unit 70 inputs data (command) that is a trigger (trigger) of the output of the effect from the main control unit 3, the processing unit 70 refers to the selected trigger table and specifies the effect content corresponding to the input data. (Production designation data) is generated at any time and output from the communication interface unit 52 to the sub-sub control unit 7. For example, at the timing set in the trigger table, the processing unit 50 generates data (command) designating the video of the display 35 and the sound of the speaker 37 to be reproduced at that time, and outputs the data (command) to the sub-sub control unit 7.

  Further, the processing unit 50 determines whether or not an object is detected in a detection region covering the screen of the display 35 based on data generated by the touch sensor 33, and if an object is detected, the position of the object is detected. The coordinate data indicating is acquired. The processing unit 50 analyzes the data generated by the touch sensor 33 to determine whether or not an object is detected at a plurality of locations in the detection area, start and end of object detection, and the movement distance of the object. Various information related to the state of the object in the detection area, such as the moving direction and the presence / absence of double tapping / repetitive hitting, is acquired.

[Sub-sub control unit 7]
Next, the sub-sub control unit 7 will be described.
When the sub-sub control unit 7 receives data (command) designating the content of the effect from the sub-main control unit 5, the sub-sub control unit 7 generates a video displayed on the display 35 or a sound output from the speaker 37 in accordance with the input data (command). Control. For example, the sub-sub control unit 7 reads video data and sound data corresponding to the input data (command) from the video / sound storage unit 74 (FIG. 9), generates a video signal and an audio signal corresponding thereto, and displays the display 35. And supplied to the speaker 37.

The sub-sub control unit 7 also receives virtual reel control data (production effect data, random number data, stop order determination data, virtual reel rotation start instruction data, virtual reel stop instruction data) input from the sub main control unit 8. In response to this, an image in which the virtual reel rotates / stops is displayed on the display 35.
That is, when the sub-sub control unit 7 receives rotation start instruction data indicating the operation of the start lever 205 from the sub-main control unit 5, the sub-sub control unit 7 displays a video on the display 35 in which a plurality of virtual reels start rotating all at once.
When the rotation stop instruction data of one virtual reel is input from the sub main control unit 5, the sub sub control unit 7 outputs the rotation angle of the one virtual reel at the input timing and the effect input from the sub main control unit 5. A rotation angle at which the one virtual reel is stopped is determined according to the combination data, random number data, and stop order determination data, and an image in which the one virtual reel stops at the determined rotation angle is displayed on the display 35. .

Furthermore, when the sub-sub control unit 7 stops all virtual reels according to the virtual reel stop instruction data, the sub-sub control unit 7 sub-data (stop result data) regarding the combination (outcome) of symbols indicated by the stopped virtual reels. Output to the control unit 5.
For example, the sub-sub control unit 7 determines whether or not the combination (outcome) of the symbols indicated by the stopped virtual reels satisfies the winning condition defined in the stop pattern specified by the effect role data and the random number data. Make a winning decision. Then, the sub-sub control unit 7 outputs stop result data including information on the winning determination result and information on the winning line on which the winning determination is performed to the sub-main control unit 5.
In the case where the sub-sub control unit 7 does not perform the winning determination and outputs only the information of the virtual reel stop symbol as the stop result data to the sub-main control unit 5, the sub-main control unit 5 performs the winning determination. May be.

FIG. 4 is a diagram illustrating an example of the configuration of the sub-sub control unit 7.
4 includes a processing unit 70, a communication interface unit 71, a video signal output unit 72, an audio signal output unit 73, a video / sound storage unit 74, a frame buffer 75, and a system storage. Part 76.
The processing unit 70 of the sub-sub control unit 7 is an example of a processing unit in the present invention.

  The communication interface unit 71 is a circuit for exchanging data with the sub main control unit 5, and inputs data from the sub main control unit 5 and outputs data to the sub main control unit 5.

The video signal output unit 72 generates a video signal having a predetermined signal format according to the video data supplied from the processing unit 70 and inputs the video signal to the display 35.
The audio signal output unit 73 generates an audio signal whose amplitude and pulse density are adjusted according to the sound data supplied from the processing unit 70 and inputs the audio signal to the speaker 37.

  The video / sound storage unit 74 stores video data used to configure the screen of the display 35 and sound data used to output sound at the speaker 37. The video data and the sound data stored in the video / sound storage unit 74 are associated with identification information, respectively. The sub-sub control unit 7 reads the video data / sound data from the video / sound storage unit 74 by referring to the identification information included in the data (command) from the sub-main control unit 5 that designates the production content.

  The video / sound storage unit 74 stores image data of a plurality of types of symbols provided on the peripheral surface of the virtual reel displayed on the display 35.

  The frame buffer 75 is a memory for storing video information displayed on the display 35 in units of screens, and stores one or a plurality of screens.

  The system storage unit 76 stores a program for executing processing in the processing unit 70, data used for processing, and data temporarily held in the course of processing. For example, the system storage unit 76 stores a table including data such as the number of sliding symbols used for control (stop control, kick control) of the virtual reel stop position.

  The processing unit 70 is a circuit that controls the overall processing of the sub-sub control unit 7, and processes the video displayed on the display 35 and the sound output from the speaker 37 in accordance with the instructions of the program stored in the system storage unit 76. I do.

  The processing unit 70 displays an image of a virtual reel having a plurality of types of symbols on its peripheral surface on the display 35 as with the main reel. For example, the processing unit 70 constructs a video of a three-dimensional virtual reel having a depth by computer graphics processing, and data for virtual reel control (virtual reel rotation start instruction data, virtual virtual) input from the sub-main control unit 5. In response to the reel stop instruction data or the like, the video image of rotating or stopping the three-dimensional virtual reel is displayed on the display 35.

  That is, when the virtual reel rotation start instruction data is input from the sub-main control unit 5, the processing unit 70 starts rotating from the stopped state and gradually increases the rotation speed, and the rotation speed reaches a predetermined maximum rotation speed. Then, an image that rotates while maintaining the maximum rotation speed (that is, at a constant speed) is displayed on the display 35.

  Specifically, the processing unit 70 configures an image including a three-dimensional virtual reel for each predetermined frame period on the frame buffer 75, and in parallel with this, configures the image configured on the frame buffer 75. It is displayed on the display 35 as one frame for every predetermined frame period.

  In constructing the virtual reel video, the processing unit 70 first calculates the rotation angle of the virtual reel for each frame. For example, when the virtual reel is stopped, the processing unit 70 keeps the rotation angle of the virtual reel constant even when the frame is switched. When the virtual reel is rotating, the processing unit 70 changes the rotation angle every time the frame is switched. Let Further, when the rotation speed is accelerated immediately after the start of rotation, the processing unit 70 calculates the rotation angle so that the amount of change in the angle increases every time the frame is switched. When the rotation speed becomes constant at a predetermined maximum rotation speed, the processing unit 70 calculates the rotation angle so that the amount of change in angle at the time of frame switching is kept constant. As will be described later, when the rotation speed reaches a predetermined maximum rotation speed, the processing unit 70 corrects the rotation angle so as to facilitate the visual recognition of a predetermined symbol that serves as a guide for pressing the virtual reel. I do.

  When the rotation angle of the virtual reel is obtained, the processing unit 70 maps a plurality of types of symbols on the surface based on the image data of a plurality of types stored in the video / sound storage unit 74 and the rotation angle. A computer graphics image of the reel body (left, middle, right) having a predetermined three-dimensional shape is generated and written in the frame buffer 75.

  When left, center, or right virtual reel stop instruction data is input from the sub-main control unit 5 while the virtual reel rotates at a constant speed, the processing unit 70 corresponds to the left, center, or right virtual reel. An image in which the rotation of is stopped is displayed on the display 35.

When stopping the virtual reel, the processing unit 70 determines the rotation angle (design position) of the virtual reel at the timing when the virtual reel stop instruction data is input, and the stop pattern specified by the effect combination data and random number data. Based on this, the rotation angle (symbol position) at which the virtual reel stops is controlled.
That is, when the virtual reel stop instruction data is input from the sub-main control unit 5 while the virtual reel rotation image is displayed, the processing unit 70 stops the virtual object to be stopped at the timing when the virtual reel stop instruction data is input. Based on the rotation angle (design position) of the reel and the stop pattern specified by the effect data and random number data input from the sub-main control unit 5, the rotation angle (design) for stopping the virtual reel to be stopped ) Is determined, and an image in which the virtual reel to be stopped stops at the rotation angle (symbol position) is displayed on the display 35.

For example, the processing unit 70 selects a specific table from a plurality of virtual reel stop position control tables stored in advance in the system storage unit 76 based on the effect combination data and random number data input from the sub-main control unit 5. select. This table includes, for example, data associating the rotation angle (design position) of the virtual reel at the timing when the virtual reel stop instruction data is input with the rotation angle at which the rotation of the virtual reel is stopped. The data registered in the table is to stop the symbols allowed by the stop pattern specified by the presentation role data and random number data on the winning line (withdrawal control), and not to stop the symbols prohibited by the rendering role on the winning line. (Kicking control) is adjusted in advance.
When the virtual reel stop instruction data is input from the sub-main control unit 5, the processing unit 70 refers to the above table selected based on the effect combination data and the random number data, and the rotation angle at which the rotation of the virtual reel is stopped. (Symbol position) is determined, and an image in which the rotation of the virtual reel stops at the determined rotation angle is displayed on the display 35.

The processing unit 70 realizes the sub reel (AG reel) in real time 3D. The processing unit 70 displays the sub reel using movie data.
The processing unit 70 switches and uses the rotating movie data for each of the three sub reels and the stopped movie data for each of the three sub reels, thereby realizing a rotated and stopped video. The six movie data are loopable movie data in which the beginning and the end are seamlessly connected.
In the present embodiment, the rotating movie data is composed of a plurality of frames for displaying a rotating image for at least one rotation for the corresponding virtual reel. The stopped movie data is composed of a plurality of frames for displaying the stopped video for at least one rotation for the corresponding virtual reel.

FIG. 5 is a flowchart for explaining the overall processing relating to virtual reel display of the processing unit 70 shown in FIG.
Step ST1:
When detecting the frame synchronization, the processing unit 70 proceeds to step ST2.

Step ST2:
When the rotation start instruction and the stop instruction are input, the processing unit 70 sets the state STS to start and stop process start, respectively.
Further, when the reverse rotation setting instruction is input, the processing unit 70 sets the rotation direction to be reverse.
In addition, when the speed scale setting instruction is input, the processing unit 70 receives a speed scale setting operation.

Step ST3:
The processing unit 70 performs update processing according to the state STS.
FIG. 6 is a flowchart for explaining the update process shown in FIG. 5 performed by the processing unit 70.

Step ST4:
The processing unit 70 performs a drawing process for decoding and drawing a frame constituting the movie frame specified by the update process in step ST3.
The drawing process shown in FIG. 5 performed by the processing unit 70 will be described in detail with reference to FIGS. z

Hereinafter, the update process illustrated in FIG. 5 performed by the processing unit 70 will be described in detail with reference to FIG. 6.
The following update process is performed for each of the three virtual reels.
Step ST21:
The processing unit 70 determines whether or not the state STS is in an idle state. If the determination is affirmative, the process proceeds to step ST22. If the determination is negative, the process proceeds to step ST23.

Step ST22:
The processing unit 70 sets the rotating state (blur state) to off during rotation (blur off) and sets it to the reverse rotating state.

Step ST23:
The processing unit 70 determines whether or not the state STS is “starting state”. If the determination is affirmative, the process proceeds to step ST24. If the determination is negative, the process proceeds to step ST25.

Step ST24:
The processing unit 70 initializes the stop position of the virtual reel and sets the rotation speed to the initial value (0).
In the present embodiment, the stop position indicates a rotation angle (design position) at which the virtual reel is stopped. More specifically, the stop position is a symbol position having 20 or 21 on each reel. The stop position is expressed by a number from 0 to 19, or from 0 to 20, for example.
Further, the processing unit 70 sets the state STS to the “accelerated state”.

Step ST25:
The processing unit 70 determines whether or not the state STS is the “acceleration state”. If the determination is affirmative, the process proceeds to step ST26, and if the determination is negative, the process proceeds to step ST27.

Step ST26:
The processing unit 70 performs a virtual reel acceleration process.
The processing unit 70 updates the rotation speed by adding a predetermined rotation acceleration, determines a frame to be drawn next (an index value for specifying a frame such as a frame number) based on the updated rotation speed, Proceed to ST35.
FIG. 7 is a flowchart for explaining the acceleration process of step ST26 shown in FIG.

Step ST27:
The processing unit 70 determines whether or not the state STS is a stop processing state. If the determination is affirmative, the process proceeds to step ST28. If the determination is negative, the process proceeds to step ST29.

Step ST28:
The processing unit 70 performs a virtual reel stop process.
The processing unit 70 sequentially sets the fixed positions of the three reels according to the first to third stop operations, sets the state STS to “sliding”, and proceeds to step ST29.
FIG. 8 is a flowchart for explaining the stop process of step ST28 shown in FIG.

Step ST29:
The processing unit 70 determines whether or not the state STS is a slipping state. If the determination is affirmative, the process proceeds to step ST30. If the determination is negative, the process proceeds to step ST31.

Step ST30:
The processing unit 70 performs a virtual reel slip process.
The processing unit 70 sequentially sets the stop positions of the three reels according to the first to third stop operations, and proceeds to step ST29.
FIG. 9 is a flowchart for explaining the slip processing in step ST30 shown in FIG.

Step ST31:
The processing unit 70 determines whether or not the state STS is a bound start state. If the determination is affirmative, the process proceeds to step ST32. If the determination is negative, the process proceeds to step ST33.

Step ST32:
The processing unit 70 initializes the bound variable and shifts the state STS to “being bound”.

Step ST33:
The processing unit 70 determines whether or not the state STS is in a bound state. If the determination is affirmative, the process proceeds to step ST34, and if the determination is negative, the process proceeds to step ST35.

Step ST34:
The processing unit 70 performs virtual reel bound processing.
FIG. 10 is a flowchart for explaining the bound process in step ST34 shown in FIG.

Step ST35:
The processing unit 70 performs a process of rounding the movie frame to the maximum frame.
Specifically, the rounding process is a process of “movie frame = (movie frame + maximum frame)% maximum frame (% is a remainder calculation symbol)”.

Hereinafter, the acceleration process of step ST26 shown in FIG. 6 will be described with reference to FIG.
The processing unit 70 adds a predetermined rotational acceleration to the current rotational speed (ST41).
The processing unit 70 determines whether or not the rotational speed is greater than a predetermined maximum speed (ST42), and sets the predetermined maximum speed to the rotational speed when an affirmative determination is made (ST43). On the other hand, in the case of negative determination, the processing unit 70 determines whether or not the rotational speed is greater than a predetermined blur speed (first threshold value) (ST44). ", That is, set to select the movie data during manual stop.

Next, the processing unit 70 determines whether or not it is in the “reverse rotation state”. If the determination is affirmative, the process proceeds to step ST47. If the determination is negative, the process proceeds to step ST48.
If the determination is affirmative, the processing unit 70 calculates “movie frame number = movie frame number + (maximum frame number * (rotational speed / speed scale) / 360)”.
When the determination is negative, the processing unit 70 calculates “movie frame number = movie frame number− (maximum frame number * (rotational speed / speed scale) / 360)”. Here, (rotational speed / speed scale) is an example of the index value of the present invention.

Hereinafter, the stop process of step ST28 shown in FIG. 6 will be described with reference to FIG.
The processing unit 70 determines whether or not the reel stop operation is the first stop operation of three reels (ST51). If the determination is affirmative, the first stop stop corresponding to the timing of the reel stop operation is performed. A position is set (ST52). If a negative determination is made, the process proceeds to step ST53.

  Next, the processing unit 70 determines whether or not the reel stop operation is the second stop operation of three reels (ST53). If the determination is affirmative, the second stop corresponding to the timing of the reel stop operation is performed. The stop position is set (ST54). If a negative determination is made, the process proceeds to step ST55.

  Next, the processing unit 70 determines whether or not the reel stop operation is a third stop operation of three reels (ST55). If the determination is affirmative, the third stop according to the timing of the reel stop operation is performed. The stop position is set (ST56). If a negative determination is made, the process proceeds to step ST57.

Next, the processing unit 70 determines whether or not it is in the “reverse rotation state” (ST57). If the determination is affirmative, the process proceeds to step ST58, and if the determination is negative, the process proceeds to step ST59.
If the determination is affirmative, processing unit 70 sets the current position to the stop position set in ST52, ST54, and ST56 (ST58).
On the other hand, in the case of a negative determination, processing unit 70 sets “(maximum position−stop position) / maximum position” as the stop position (ST59).
Next, processing unit 70 updates state STS to “sliding” (ST60).

Hereinafter, it is a flowchart for demonstrating the slip process of step ST30 shown in FIG. 6, referring FIG.
The processing unit 70 determines whether or not it is in the “reverse rotation state” (ST61). If the determination is affirmative, the process proceeds to step ST63, and if the determination is negative, the process proceeds to step ST62.
In the case of negative determination, the processing unit 70 determines whether or not the current position matches the stop position. If the determination is affirmative, the processing unit 70 proceeds to step ST65. If the determination is negative, the processing unit 70 proceeds to step ST64.

In step ST64, the processing unit 70 sets “maximum frame number * (rotational speed / speed scale) / 360)” as the “frame addition value”.
Next, the processing unit 70 sets “movie frame + frame addition value” as the movie frame number.

In step ST65, the processing unit 70 switches the setting so as to set the blur state to OFF, that is, to select the stopped movie data.
Further, the processing unit 70 sets “stop position * (maximum frame number / maximum number of frames)” as the movie frame number. Here, the maximum number of frames is “maximum stop position value + 1”.
Next, the processing unit 70 sets the state STS to “bound start state”.

In step ST <b> 66, the processing unit 70 sets “−maximum frame number * (rotational speed / speed scale) / 360)” to “frame added value”.
Next, the processing unit 70 sets “movie frame + frame addition value” as the movie frame number.

In step ST67, the processing unit 70 switches the setting so that the blur state is set to OFF, that is, the stopped movie data is selected.
Further, the processing unit 70 sets “stop position * (maximum frame number / maximum number of frames)” as the movie frame number.
Next, the processing unit 70 sets the state STS to “bound start state”.

Hereinafter, with reference to FIG. 10, the bound process of step ST34 shown in FIG. 6 will be described.
In FIG. 10, the bounce angle is used to express the shake by adding it to the rotation angle. The bounce process is a process of calculating a bounce angle and a bounce frame for expressing the reel swing by adding to the stopped movie frame.

  In the bound process, when the rotation speed of the virtual reel is outside the predetermined range including the rotation stop, the processing unit 70 sequentially decreases the rotation speed and decreases the bound angle by a magnitude corresponding to the rotation speed. Processing for determining the next frame to be rendered from the movie data according to the bound angle is performed.

The processing unit 70 determines whether or not the rotation angle of the virtual reel is less than a predetermined first threshold (for example, 0.5) (ST81). If the determination is affirmative, the bounce angle is 0. If the determination is affirmative, a value obtained by subtracting the bound width from the rotation angle is set as a new rotation angle (ST83), and the process proceeds to step ST88.
On the other hand, if the determination is negative in step ST82, processing unit 70 proceeds to step ST88.
On the other hand, if the determination is negative in step ST81, the processing unit 70 proceeds to step ST84.

The processing unit 70 determines whether or not the rotation angle of the virtual reel is less than a predetermined second threshold value (for example, −0.5) opposite in sign to the first threshold value (ST84). In the case of affirmative determination, it is determined whether or not the bounce angle exceeds 0 (ST86). In the case of affirmative determination, a value obtained by subtracting the bounce width from the rotation angle is set as a new rotation angle (ST87). Proceed to step ST88.
On the other hand, the process part 70 progresses to step ST88, when negative determination is made at step ST86.
On the other hand, in the case of negative determination in step ST84, the processing unit 70 sets the rotation speed to “0”, sets the state STS to “idling”, and proceeds to step ST88.

In step ST88, the processing unit 70 sets “bound angle−rotational speed / speed scale value” as a new bound angle.
Next, processing unit 70 determines whether or not it is in the reverse rotation state (ST89), and in the case of an affirmative determination, sets “−maximum frame * bound angle / 360” as a new bound frame (ST90). On the other hand, in the case of a negative determination, processing unit 70 sets “maximum frame * bound angle / 360” as a new bound frame (ST90).
Here, the bound frame is “a value obtained by calculating the number of frames corresponding to the bound angle when the maximum frame is 360 degrees”.

Hereinafter, the drawing process of step ST4 shown in FIG. 3 will be described.
First embodiment of the drawing process:
FIG. 11 is a flowchart for explaining a first embodiment of the drawing process in step ST4 shown in FIG.
The example shown in FIG. 9 shows a case where all movie frames are composed of I frames.
Processing unit 70 acquires a movie frame (ST101). Here, the movie frame is obtained by adding a bound frame to the movie frame specified by the update process shown in FIG.

The processing unit 70 determines whether or not the state STS is a blur state (ST102). If the determination is affirmative, the processing unit 70 decodes only one frame of the movie frame acquired in step ST101 in the stopped movie data (ST103). .
On the other hand, in the case of negative determination, the processing unit 70 decodes only one movie frame acquired in step ST101 in the rotating movie data (blur movie) (ST104).

The processing unit 70 renders the movie frame decoded in step ST103 or ST104 (ST105).
The processing unit 70 performs the above-described processing of steps ST101 to ST104 for each of the three virtual reels, and performs drawing processing so that the decoded four frames are combined into one frame and displayed.

  In the method shown in FIG. 11, since all movie frames are composed of I frames, it is possible to zip all frames. For this reason, an operation in which the reel rotates once can be created with 360 frames, for example, and the value of the frame can be controlled as an angle.

Second embodiment of the drawing process:
FIG. 12 is a flowchart for explaining a second embodiment of the drawing process in step ST4 shown in FIG.
In the example shown in FIG. 9, the movie frame is composed of three types of frames of I, P, and B.
Processing unit 70 acquires a movie frame (ST201). Here, the movie frame is obtained by adding a bound frame to the movie frame specified by the update process shown in FIG.

The processing unit 70 determines whether or not the state STS is a blur state (ST202). If the determination is affirmative, the acquisition is performed from the I frame immediately before the movie frame acquired in step ST201 in the stopped movie data. Up to the movie frame is decoded (ST203).
On the other hand, in the case of negative determination, the processing unit 70 decodes from the I frame immediately before the movie frame acquired in step ST201 to the acquired movie frame in the rotating movie data (blur movie) (ST204).

The processing unit 70 renders the movie frame decoded in step ST203 or ST204 (ST205).
The processing unit 70 performs the above-described processing of steps ST201 to ST204 for each of the three virtual reels, and performs drawing processing so that the decoded four frames are combined into one frame and displayed.

  In the method shown in FIG. 12, since the movie frame is composed of three types of frames of I, P, and B, high compression efficiency can be obtained.

As described above, according to the pachislot machine 1, for example, in the display processing of each virtual reel, by using one movie data during rotation, acceleration at the start of rotation, deceleration at the time of stop, display of reel bounce Processing can be realized.
Further, according to the pachislot machine 1, the position of the symbol at the time of stopping can be stopped at a fixed position even when the rotating movie data is reproduced so as to rotate the virtual reel at an arbitrary speed. Further, since the image can be displayed with high accuracy, it can be pushed.

  While various embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and includes other various variations.

  For example, the specific numerical values (the maximum rotation speed of the virtual reel, the frame rate of the display 35, the number of virtual reels, the number of symbols provided on the virtual reel, etc.) in the above-described embodiments are examples, and the present invention It is not limited by the numerical value.

  Further, the configuration of the rendering hardware in the above-described embodiment is an example, and the present invention is not limited to this. For example, in the above-described embodiment, the speaker 37 is connected to the sub-sub control unit 7. However, in another embodiment of the present invention, the speaker 37 may be connected to the sub-main control unit 5. In this case, an audio signal processing circuit may be mounted in the sub main control unit 5 and a program (driver) for controlling audio reproduction may be operated in the sub main control unit 5.

  In the embodiment described above, an example in which the sub-main control unit 5 has data for production (trigger table) has been described, but the present invention is not limited to this. In another embodiment of the present invention, the sub-sub control unit 7 may have a trigger table. In this case, when the sub-main control unit 5 inputs information (information such as bet button detection, start lever detection, first to third reel stop detection, etc.) from the main control unit 3 as a trigger for the production, It may be outputted to the unit 7 so that the sub-sub control unit 7 generates an effect corresponding to the trigger table.

In the embodiment described above, an example in which the present invention is applied to a pachislot machine is given, but the present invention is not limited to this. That is, the present invention is widely applicable to various gaming machines that stop the rotation of the reel displayed as an image on the display by the player's operation.
That is, the processing unit 70 performs a process of displaying an image of a plurality of types of images having a periodic motion and composed of a plurality of frames instead of the three virtual reels. In this case, for each of the plurality of symbols, the first movie data for displaying at least one cycle of operating video and the second movie data for displaying at least one cycle of stopped video are stored in memory. To remember.
The processing unit 70 determines the stopped and operating states for each of the plurality of symbols, and based on the determined state, from among the first movie data and the second movie data for the symbol. , Select one movie data. Then, the processing unit 70 performs a drawing process for decoding and drawing frames constituting movie data selected for a plurality of symbols.

(Appendix 1)
A display unit for displaying images;
An image in which a virtual reel having a plurality of types of symbols on its peripheral surface rotates while increasing its rotation speed from a stopped state, and rotates while maintaining the predetermined rotation speed when the rotation speed reaches a predetermined rotation speed. A processing unit for displaying an image composed of a plurality of frames per rotation of the virtual reel at the predetermined rotation speed on the display unit;
An instruction input unit for inputting rotation start and stop instructions of the virtual reel in the image of the display unit;
For each of the plurality of virtual reels, a memory for storing rotating movie data for displaying a rotating image for at least one rotation and stopping movie data for displaying a stopped image for at least one rotation;
Have
The processor is
For each of the plurality of virtual reels, a state of stopping and rotating is determined, and based on the determined state, one of the rotating movie data and the stopping movie data for the virtual reel is An update processing unit for selecting movie data;
A gaming machine comprising: a drawing processing unit that performs a drawing process of decoding and drawing a frame constituting the movie data selected by the update processing unit for the plurality of virtual reels.

(Appendix 2)
The update processor of the processor is
When a rotation start instruction is input from the instruction input unit, the rotation state is entered, the rotation speeds of the plurality of virtual reels are calculated, and when the calculated rotation speed exceeds a predetermined first threshold value, The gaming machine according to claim 1, wherein the movie data being rotated is selected for the virtual reel corresponding to the rotation speed, and the movie data being stopped is selected when the virtual reel is equal to or less than the first threshold value.

(Appendix 3)
The update processing unit
About the virtual reel in a rotating state,
The gaming machine according to claim 1, wherein an index value corresponding to a rotation angle amount is calculated based on the rotation speed and the rotation acceleration, and the next frame to be subjected to the drawing process is determined based on the index value. .

(Appendix 4)
The update processing unit
In a state where the rotation speed of the virtual reel is accelerated,
Update the rotation speed in order until it reaches a predetermined maximum speed based on the predetermined rotation acceleration,
The gaming machine according to claim 1, wherein an index value corresponding to a rotation angle amount is calculated based on the rotation speed and the rotation acceleration, and the next frame to be subjected to the drawing process is determined based on the index value. .

(Appendix 5)
A display unit for displaying images;
A processing unit that displays images of a plurality of types of images with periodic movements and configured by a plurality of frames on a display unit;
For each of the plurality of symbols, a memory for storing first movie data for displaying at least one cycle of operating video and second movie data for displaying at least one cycle of stopped video;
Have
The processor is
For each of the plurality of symbols, a state of stopping and operating is determined, and based on the determined state, one of the first movie data and the second movie data for the symbol is An update processing unit for selecting movie data;
A gaming machine comprising: a drawing processing unit that performs a drawing process of decoding and drawing a frame constituting the movie data selected by the update processing unit for the plurality of symbols.

DESCRIPTION OF SYMBOLS 1 ... Pachi slot machine, 3 ... Main control part, 5 ... Sub main control part, 7 ... Sub sub control part, 11 ... Medal insertion part, 13 ... Medal paying part, 15 ... Lottery lottery part, 17 ... Reel rotation part, 20 ... Operation button group, 33 ... touch sensor, 35 ... display, 37 ... speaker, 50, 70 ... processing unit, 51, 52, 71 ... communication interface unit, 55 ... production information storage unit, 56, 76 ... system storage unit, 72 ... Video signal output unit, 73 ... Audio signal output unit, 74 ... Video / sound storage unit, 75 ... Frame buffer, 201 ... Single bet button, 203 ... Three bet button, 205 ... Start lever, 207L ... Left stop button 207M ... Middle stop button, 207R ... Right stop button.

Claims (7)

A display unit for displaying images;
An image in which a virtual reel having a plurality of types of symbols on its peripheral surface rotates while increasing its rotation speed from a stopped state, and rotates while maintaining the predetermined rotation speed when the rotation speed reaches a predetermined rotation speed. A processing unit for displaying an image composed of a plurality of frames per rotation of the virtual reel at the predetermined rotation speed on the display unit;
An instruction input unit for inputting rotation start and stop instructions of the virtual reel in the image of the display unit;
For each of the plurality of virtual reels, a memory for storing rotating movie data for displaying a rotating image for at least one rotation and stopping movie data for displaying a stopped image for at least one rotation;
Have
The processor is
For each of the plurality of virtual reels, a state of stopping and rotating is determined, and based on the determined state, one of the rotating movie data and the stopping movie data for the virtual reel is An update processing unit for selecting movie data;
A gaming machine comprising: a drawing processing unit that performs a drawing process of decoding and drawing a frame constituting the movie data selected by the update processing unit for the plurality of virtual reels. The update processor of the processor is
When a rotation start instruction is input from the instruction input unit, the rotation state is entered, the rotation speeds of the plurality of virtual reels are calculated, and when the calculated rotation speed exceeds a predetermined first threshold value, The gaming machine according to claim 1, wherein the movie data being rotated is selected for the virtual reel corresponding to a rotation speed, and the movie data being stopped is selected when the virtual reel is equal to or less than the first threshold value. The update processing unit
About the virtual reel in a rotating state,
The game according to claim 1, wherein an index value corresponding to a rotation angle amount is calculated based on the rotation speed and the rotation acceleration, and the next frame to be subjected to the drawing process is determined based on the index value. Machine. Accelerated state (Fig. 7)
The update processing unit
In a state where the rotation speed of the virtual reel is accelerated,
Update the rotation speed in order until it reaches a predetermined maximum speed based on the predetermined rotation acceleration,
The game according to claim 1, wherein an index value corresponding to a rotation angle amount is calculated based on the rotation speed and the rotation acceleration, and the next frame to be subjected to the drawing process is determined based on the index value. Machine. The update processing unit
When a stop instruction is input from the instruction input unit, after the stop process, transition to a slip state,
In the sliding state, the rotating movie data is selected until the current position of the virtual reel reaches the stop position determined by the virtual reel stop process, and when the current position of the virtual reel becomes the stop position, The gaming machine according to claim 1, wherein the stopped movie data is selected to shift to a bound start state. After transitioning to the bound start state,
When the rotation speed of the virtual reel is outside a predetermined range including rotation stop, the rotation speed is decreased in order, and the bounce angle is decreased by a magnitude corresponding to the rotation speed,
The gaming machine according to claim 5, wherein a frame to be subjected to a drawing process next is determined from the movie data in accordance with the bound angle. A display unit for displaying images;
A processing unit that displays images of a plurality of types of images with periodic movements and configured by a plurality of frames on a display unit;
For each of the plurality of symbols, a memory for storing first movie data for displaying at least one cycle of operating video and second movie data for displaying at least one cycle of stopped video;
Have
The processor is
For each of the plurality of symbols, a state of stopping and operating is determined, and based on the determined state, one of the first movie data and the second movie data for the symbol is An update processing unit for selecting movie data;
A gaming machine comprising: a drawing processing unit that performs a drawing process of decoding and drawing a frame constituting the movie data selected by the update processing unit for the plurality of symbols.

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