JP6830250B2 - Image processing device, image processing method, image processing program, game machine - Google Patents

Description

The present invention relates to a technique for processing an image to be displayed on a plurality of display means.

Conventionally, there is a technique for displaying separate images in a plurality of display means for displaying separate images or one display means for displaying separate images for each part. Here, in the field of gaming machines such as pachinko and slots, it is possible to perform lottery and production using images by mounting an image processing device and displaying the processed image on the display device according to the progress of the game. It has become mainstream. Further, in the field of gaming machines, there is also known a technique in which a gaming machine is equipped with a plurality of display devices for the purpose of obtaining various effects, and each display device collaborates to display a lottery and a display. There is.

The following are known as other techniques related to this. That is, the game machine has a first symbol display device having a screen resolution of SVGA (Super Video Graphics Array), a second symbol display device having a screen resolution of VGA (Video Graphics Array), a first symbol display device, and a second symbol. It is possible to drive and control each of the display devices, and it is provided with a plurality of symbol control boards provided corresponding to each of the first symbol display device and the second symbol display device. Then, on the symbol control board of the game machine, a clock frequency generating means capable of generating two dot clock frequencies corresponding to each of the first symbol display device and the second symbol display device, and dots generated by the clock frequency generating means. This is a technique for providing a clock frequency selection means for selecting a clock frequency (see, for example, Patent Document 1).

Utility Model Registration No. 3121052

Here, when displaying an image generated by a plurality of image generation devices on the display means, each image generation device is temporarily stored in a separate storage means, for example, a separate frame buffer, and then displayed on the display means. Then, in the image processing device having the image processing technique described in Patent Document 1, the image data stored in the storage device is rendered according to the progress of the game, and then the generated image is stored in the frame buffer. It will be. Therefore, in the invention described in Patent Document 1, a plurality of frame buffers having a storage capacity corresponding to a plurality of image data for temporarily storing an image to be displayed on a plurality of display devices are mounted. There is a problem that the capacity of the is increased.

The present invention has been made in view of the above problems, and is an image processing apparatus capable of displaying an image on a plurality of display means and obtaining various visual effects while suppressing an increase in the storage capacity of the storage means. An object of the present invention is to provide an image processing method, an image processing program, and a game machine.

In order to solve such a problem, the invention according to claim 1 is an image processing device that generates a plurality of images to be displayed on a plurality of image display means, and is a first image as one or more image display means. a first image to be displayed on the display means, for displaying the second image display means as an image display unit other than the first image display unit, before Symbol second even smaller data amount than the first image An image generation means for generating an image is provided, and the image generation means acquires a plurality of divided images obtained by dividing the first image into a plurality of block units, and uses the images generated by the acquired divided images. A first storage means for storing the first image and a storage capacity of the first storage means, which comprises an image changing means for generating a plurality of the second images that can be displayed on the second image display means. The image generating means includes a second storage means having a smaller storage capacity and a storage capacity large enough to store the second image and storing the second image. At least one of the one image and the plurality of the second images is output so as to be simultaneously displayed on the first image display means and the second image display means, and the plurality of the second images are displayed. It is characterized in that each of the images is configured to be output so as to be displayed on the second image display means at different timings .

In the invention according to claim 2 , in addition to the configuration according to claim 1 , the image changing means reduces the amount of data of the first image by a predetermined standard to generate the second image. The storage capacity of the second storage means is characterized in that it is formed in a size capable of storing the second image.

In the invention according to claim 3 , in addition to the configuration according to claim 1 or 2 , the first image display means is a liquid crystal display, and the first image is an image displayed on a liquid crystal screen. The second image display means is an LED display in which a plurality of LEDs are arranged according to a predetermined rule, the second image is an image displayed on an LED screen, and the image generation means is the first. An image of a predetermined area which is at least a part of the first image displayed on one image display means is acquired, and the image of the predetermined area is changed to an image which can be displayed on the other second image display means. said second image comprising an image modification means for generating of the image changing means, wherein the second image, was characterized thereby lit point based on the rules of arrangement of the LED by And.

The invention according to claim 4 is a gaming machine, characterized in that it includes the image processing device according to any one of claims 1 to 3 .

The invention according to claim 5 includes a first storage means and a second storage means formed with a storage capacity smaller than the storage capacity of the first storage means, and is displayed on a plurality of image display means. An image processing method executed by an image processing apparatus for generating a plurality of images to be generated, wherein a first image to be displayed on the first image display means as one or more image display means is generated, and the first image is generated . get the divided images to generate a plurality of divided images obtained by dividing an image in a plurality of blocks, the image generated by the divided images respectively acquired, first as an image display unit other than the first image display unit displaying the second image display means, before Symbol the second image to generate a plurality smaller data amount than the first image, and storing the first image in the first storage means, said first The second image is stored in the second storage means formed in a storage capacity smaller than the storage capacity of the storage means and having a storage capacity large enough to store the second image, and the first image is stored. And at least one of the plurality of the second images is output so as to be simultaneously displayed on the first image display means and the second image display means, and each of the plurality of the second images. Is configured to be output so as to be displayed on the second image display means at different timings .
The invention according to claim 6 is an image process executed by a processor of an image processing apparatus including a first storage means and a second storage means and generating a plurality of images to be displayed on a plurality of image display means. A program that generates a first image to be displayed on a first image display means as one or more image display means , and generates a plurality of divided images obtained by dividing the first image into a plurality of block units. get the divided images, the image generated by the divided images respectively acquired, and displays the second image display means as an image display unit other than the first image display means, from the previous SL first image Also generates a plurality of second images having a small amount of data, stores the first image in the first storage means, and has a storage capacity smaller than the storage capacity of the first storage means and said the second. The second image is stored in the second storage means formed to have a storage capacity large enough to store the image, and at least one of the first image and the plurality of second images is said. It is output so that it is displayed simultaneously on the first image display means and the second image display means, and each of the plurality of the second images is displayed on the second image display means at different timings. It is characterized in that it is configured to be output as follows.
The invention according to claim 7 is a second display device having a first display device for displaying an image and a plurality of light emitting elements arranged vertically and horizontally, and displaying an image by lighting each light emitting element in a line unit in a timely manner. A display device, an image processing device that processes an image to be displayed on the image, a storage unit that stores an image identifier that identifies the first image and designated information that specifies an area of the first image in association with each other, and the first image. 1 When displaying the first image on the display device, if there is designated information associated with the image identifier of the first image to be displayed, an extraction unit for extracting the second image in the area designated by the designated information, and the first An acquisition unit that acquires a line image of each line to be lit by the second display device from two images, and a lighting unit that uses the line image to illuminate a plurality of light emitting elements of the second display device in line units. It is characterized by having.
In the invention according to claim 8, in addition to the configuration according to claim 7, the image processing apparatus further generates a modified image in which the resolution of the line image is changed to the resolution of the line of the second display device. The lighting unit includes a generation unit, and the lighting unit is characterized in that a plurality of light emitting elements included in the second display device are lit in line units by using the modified image instead of the line image.
The invention according to claim 9 has, in addition to the configuration according to claim 8, a first buffer for storing the first image and a second buffer for storing the modified image having a storage capacity smaller than that of the first buffer. A buffer is provided, and the lighting unit is characterized in that a plurality of light emitting elements included in the second display device are lit in line units by using the line image stored in the second buffer.
The invention according to claim 10 has, in addition to the configuration according to claim 8, a first buffer for storing the first image and a second buffer for storing the modified image having a storage capacity smaller than that of the first buffer. A buffer is provided, and the lighting unit is characterized in that a plurality of light emitting elements included in the second display device are lit in line units by using the modified image stored in the second buffer.
The invention according to claim 11 is a second display device having a first display device for displaying an image and a plurality of light emitting elements arranged vertically and horizontally, and displaying an image by lighting each light emitting element in a line unit in a time-divided manner. An image processing device that processes an image to be displayed on the display device, the image identifier that identifies the first image, designated information that specifies an area of the first image, and the first image on the first display device. A storage unit that stores the first timing to be displayed and the second timing for displaying the second image of the area designated by the designated information on the second display device in association with each other, and the storage unit displayed on the first display device. When the first image is determined, if there is designated information associated with the image identifier of the determined first image, the extraction unit that extracts the second image in the area designated by the designated information and the extraction unit The second display is used at the second timing associated with the acquisition unit that acquires the line image of each line to be lit by the second display device and the first image from which the line image is acquired. It is characterized by including a lighting unit for lighting a plurality of light emitting elements included in the device in line units.
In the invention according to claim 12, in addition to the configuration according to claim 11, the image processing apparatus further generates a modified image in which the resolution of the line image is changed to the resolution of the line of the second display device. The second display device includes a generation unit, and instead of the line image, the second display device uses the modified image at a second timing associated with the first image from which the line image is acquired. It is characterized in that a plurality of light emitting elements are lit in line units.
The invention according to claim 13 is a second display device having a first display device for displaying an image and a plurality of light emitting elements arranged vertically and horizontally, and displaying an image by lighting each light emitting element in a line unit in a timely manner. An image processing device that processes an image to be displayed on the display device, and includes an image processing unit that stores an image identifier that identifies the first image and designated information that specifies an area of the first image in association with each other. In the image processing method of the device, when the first image is displayed on the first display device, if there is designated information associated with the image identifier of the first image to be displayed, the first of the area designated by the designated information. Two images are extracted, a line image of a line unit to be lit by the second display device is acquired from the second image, and a plurality of light emitting elements possessed by the second display device are displayed in line units using the line image. It is characterized by turning it on.
The invention according to claim 14 is a second display device having a first display device for displaying an image and a plurality of light emitting elements arranged vertically and horizontally, and displaying an image by lighting each light emitting element in a line unit in a time-divided manner. An image processing device that processes an image to be displayed on a display device, and includes a storage unit that stores an image identifier that identifies the first image and designated information that specifies an area of the first image in association with each other. In a display control program to be executed by the computer of the device, when the first image is displayed on the first display device, if there is designated information associated with the image identifier of the first image to be displayed, the designated information is designated. A second image of the region to be used is extracted, a line image of each line to be lit by the second display device is acquired from the second image, and the line image is used to obtain a plurality of light emitting elements included in the second display device. It is characterized in that a computer executes a process of lighting a line unit.

According to the inventions of claim 1, claim 5 , and claim 6 , a second image having a smaller amount of data than the first image is generated depending on the first image, and the first image. By forming the storage capacity of the second storage means for storing the second image smaller than the storage capacity of the first storage means for storing the first image, the first storage means and the second storage means are respectively made. It can be formed into a storage capacity corresponding to the amount of data of the first image and the amount of data of the second image. As a result, it is possible to obtain various visual effects by displaying an image on a plurality of display means while suppressing an increase in the storage capacity of the storage means.

According to the first, fifth, and sixth aspects of the invention, at least a part of the first image is supported by acquiring a predetermined region of the first image and generating the second image. It is possible to generate a second image whose data amount is less than or equal to the data amount of the first image. Then, since the second storage means can be formed with a storage capacity corresponding to the amount of data of the second image, it is possible to prevent the second storage means from becoming excessively large and to increase the storage capacity of the storage means. Can be suppressed.

According to the first, fifth, and sixth aspects of the invention, the data of the second image is obtained by generating the second image by dividing the first image into a plurality of block units. The amount can be reliably generated less than the amount of data in the first image. Then, since the second storage means can be formed with a storage capacity corresponding to the amount of data of the second image, it is possible to prevent the second storage means from becoming excessively large and to increase the storage capacity of the storage means. Can be suppressed.

According to the invention of claim 2 , by reducing the data amount of the first image by a predetermined standard to generate the second image, the data amount of the second image is surely the first. It can be generated below the amount of image data. Then, since the second storage means can be formed with a storage capacity corresponding to the amount of data of the second image, it is possible to prevent the second storage means from becoming excessively large and to increase the storage capacity of the storage means. Can be suppressed.

According to the invention of claim 3 , by generating an image displayed on the LED screen based on the liquid crystal image, when the liquid crystal display and the LED display are used in combination, the image is generated based on the image of a predetermined area. The present invention can be applied to a dynamic lighting type LED display by lighting the second image in a time-divided manner based on the rules of LED arrangement. Further, the storage capacity of the second storage means can be set to a size based on a predetermined arrangement unit of the LEDs, and the second storage means for storing the image to be displayed on the LED screen becomes excessively large. It is possible to suppress and prevent the storage capacity of the storage means from becoming excessive. Furthermore, since the resolution when changing the first image to the second image can be changed based on the time division range based on the LED arrangement rule, the processing load when generating the second image is reduced. it can.

According to the fourth aspect of the present invention, it is possible to provide a gaming machine capable of obtaining various visual effects by displaying an image on a plurality of display means while suppressing an increase in the storage capacity of the storage means.

It is a functional block diagram which shows the image processing apparatus of this embodiment. It is a figure which shows schematic structure of the lighting part in the same-mentioned image forming apparatus. It is a block diagram which shows an example of area information in the same image processing apparatus. It is a figure which shows typically the game machine, the 1st display device, and the 2nd display device in the same image processing apparatus. It is explanatory drawing which shows an example of the extraction process in the same image processing apparatus. It is explanatory drawing which shows an example of the acquisition process in the same image processing apparatus. It is the flowchart which shows the rectangular transfer process in the same image processing apparatus.

1 to 7 show embodiments of the present invention.

[Basic configuration]
FIG. 1 is a functional block diagram showing the overall structure of the image processing system 1A according to this embodiment.

[Image processing system]
The image processing system 1A shown in FIG. 1 includes an image processing device 1, a first display device 19, and a second display device 20.

The image processing device 1 is for generating and supplying an image to be displayed on the first display device 19 as the "first image display means" and the second display device 20 as the "second image display means". Perform various processes. Specifically, it will be described in detail in the section of [Image Processing Device] described later.

The first display device 19 is a liquid crystal display such as an LCD, and is a moving image for a liquid crystal screen as a "first image" (hereinafter, simply referred to as a "moving image". The same shall apply in the present specification. Good.) Is displayed. In this embodiment, in the first display device 19, the pixels of the liquid crystal are arranged according to a predetermined rule (for example, in a matrix shape), and the coordinates (for example, the horizontal axis direction (X-axis)) used for lighting control are performed on each pixel. Direction) and vertical axis direction (Y-axis direction) coordinates) are set.

The second display device 20 is a display composed of an aggregate of a large number of light emitting elements, and here is an LED display. In the second display device 20, a plurality of LEDs (for example, color LEDs) are arranged in a predetermined rule (for example, in a matrix). The second display device 20 displays a modified image as a "second image" depending on the lighting state of each of the constituent LEDs (the modified image will be described later). In the second display device 20, the coordinates (for example, the horizontal axis direction (X-axis direction)) and the vertical axis direction (for example) used when each LED is arranged according to a predetermined rule (for example, in a matrix shape) and lighting control is performed on each LED. (Y-axis direction) coordinates) are set.

The image processing system 1A is used in the game machine 100 shown in FIG. The gaming machine 100 of this embodiment is a pachinko machine, but any gaming machine such as a pachislot machine may be used.

[Image processing device]
The image processing device 1 performs processing for displaying an image on the first display device 19 and the second display device 20 arranged in the game machine 100.

The image processing device 1 includes control means (not shown) such as a processor, and performs arithmetic processing of programs and data. Then, as shown in FIG. 1, the image processing apparatus 1 of this embodiment has, as functional means, an image generation unit 11 as an "image generation means", an extraction unit 12 as an "image generation means", and an "image generation means". , The acquisition unit 13 as the "image changing means", the generating unit 14, the lighting unit 15, the first storage unit 16, the driving unit 17, and the second storage unit 18 as the "image generating means" and the "image changing means". They are connected by a connecting portion 21. The drive unit 17 is provided with a first buffer 171 as a "first storage means", and the lighting unit 15 is provided with a second buffer 151 as a "second storage means". Image generation unit 11, extraction unit 12, acquisition unit 13, generation unit 14, lighting unit 15, second buffer 151, first storage unit 16, drive unit 17, first buffer 171, second storage unit 18, connection unit 21 Are realized by the cooperation of various hardware and software such as a program (image processing program) that is arithmetically processed by a control means (not shown). However, any of these configurations may be composed only of hardware or only software. The program to be arithmetically processed may be recorded on a non-temporary recording medium such as a magnetic disk, an optical disk, or a flash memory.

The image generation unit 11 generates a moving image as an image displayed on the first display device 19 based on the image data or the like recorded in the second storage unit 18. The image generation unit 11 generates individual frames based on the data, and the moving image is composed of a plurality of frames.

When the moving image is displayed on the first display device 19, the extraction unit 12 extracts the designated image (described later) of the area designated by the designated information if there is designated information associated with the displayed moving image.

The acquisition unit 13 acquires an image to be lit by the second display device 20 from the designated image extracted by the extraction unit 12. The acquisition unit 13 divides the designated image according to a predetermined standard, and acquires an image for each divided unit. In this embodiment, a line image (described later) for each line is acquired.

When the acquisition unit 13 acquires the line image, the generation unit 14 changes the resolution of the line image to the line resolution of the second display device 20 to generate a changed image (described later).

The lighting unit 15 is an LED driver, and uses a modified image to light a plurality of light emitting elements of the second display device 20 in a time-division manner based on a predetermined reference (for example, a division unit depending on the line of the line image). See FIG. 2. Details will be described later). As a result, the lighting unit 15 can light a plurality of LEDs in a time-division manner by a dynamic lighting method (a lighting method in which a plurality of LEDs are collectively lit at one time).

The first storage unit 16 is various storage media such as RAM, EEPROM, and ROM, and stores an image identifier that identifies an image and designated information that specifies an area of each image in association with each other (see FIG. 3 for details). It will be described in detail.).

The drive unit 17 is a liquid crystal driver (LCD driver), and controls lighting (lighting / extinguishing, brightness, color, etc.) of each liquid crystal display constituting the first display device 19.

The first buffer 171 is a storage medium such as a RAM or EEPROM provided in the drive unit 17, and temporarily stores the moving image displayed by the first display device 19 before supplying the moving image to the first display device 19. Let me. The storage capacity of the first buffer 171 is formed to be large enough to store each frame of the moving image displayed on the first display device 19.

The second buffer 151 is a storage medium such as RAM and EEPROM provided in the lighting unit 15, and is temporarily before supplying the second image displayed by the second display device 20 to the second display device 20. To memorize. The storage capacity of the second buffer 151 is formed in a size capable of recording an image to be displayed on the second display device 20 in line units. Further, the storage capacity of the second buffer 151 is formed to be smaller than the storage capacity of the first buffer 171.

The second storage unit 18 is an external storage medium such as a magnetic disk or EPROM, and stores image data of moving images displayed on the first display device 19.

The connection unit 21 is, for example, a bus, and connects functional means configured by the respective hardware. However, the connection unit 21 may logically connect the functional means configured by the calculation of the program or the like.

[Configuration of second display device]
FIG. 4 schematically shows a second display device used in the gaming machine of this embodiment.

As shown in the figure, in the second display device 20 of the game machine 100 of this embodiment, a plurality of LEDs 20a are arranged in a uniform matrix in the vertical and horizontal directions on the surface of the game machine 100. However, the arrangement of the LEDs 20a of the second display device 20 may be arbitrary. For example, the LEDs 20a may be arranged radially, or may be arranged like an aggregate of triangles or hexagons, or may be arranged unevenly (for example, one side of the row has a narrow distance between the LEDs 20a and the other). The sides may be arranged (so that they are widely spaced).

[Structure of lighting part]
FIG. 2 is a diagram schematically showing the configuration of the lighting unit 15 of this embodiment.

As shown in the figure, in addition to the second buffer 151, the lighting unit 15 includes a control unit 152, drive circuits 1510, 1520, 1530, a numerical display unit 1541-1543, a switch 1551-1554, a switch 1561-1563, and a power supply voltage. It has a part Vdd.

The control unit 152 controls the operation and processing of the entire lighting unit 15. The control unit 152 may be realized as a part of the control function of the control means (not shown) of the image processing device 1, or may be realized by a processor or the like different from the control means (not shown) of the image processing device 1. It may be realized.

The drive circuits 1510, 1520, and 1530 are provided with various switch elements, and control the energization state of the second display device 20 and the number display units 1541, 1542, and 1543. Of these, the drive circuits 1510 and 1520 are connected to the second display device 20 and are used for lighting control of the LED 20a of the second display device 20. Further, the drive circuit 1530 is connected to the number display units 1541 to 1543 and used for the number display of the number display units 1541 to 1543.

The number display unit 1541-1543 is a 7-segment LED display, and each segment is turned on and off depending on the energized state to display 10 numbers from 0 to 9. The number display unit 1541-1543 displays changes in numbers and fixed numbers in a specific state (for example, a state in which probability fluctuations occur) during the game of the game machine 100.

The switch 1551-1554 and the switch 1561-1563 are energizing switches formed of MOSFETs. The switches 1551-1554 control the energization state of the LEDs 20a arranged in a matrix of the second display device 20 in the row direction to control the lighting of each of the rows of the LEDs 20a. As a result, the LED 20a of the second display device 20 is dynamically lit for each row.

The lighting control of the second display device 20 by the switches 1551-1554 may be controlled by any standard other than the lighting control for each row of the LEDs 20a. For example, the LEDs 20a arranged in a matrix may be controlled to be lit for each row, the lighting may be controlled in the diagonal direction of the arrangement, the lighting may be controlled for each square-shaped section, or the central portion. Lighting control may be performed from the peripheral portion or from the peripheral portion to the central portion.

The switch 1561 to 1563 controls the energized state of each of the number display units 1541 to 1543 to display the numbers 0-9 on each of the number display units 1541 to 1543.

The power supply voltage unit Vdd is connected to the drain terminals of the MOSFETs constituting the switches 1551-1554 and the switches 1561-1563, and supplies a predetermined drive voltage to the switches 1551-1554 and the switches 1561-1563.

[Game machine configuration]
FIG. 4 is a diagram schematically showing a surface portion of the gaming machine of this embodiment.

As shown in the figure, the game machine 100 is provided with a first display device 19 above the surface portion and a second display device 20 below the surface portion.

As shown in FIG. 4, the first display device 19 and the second display device 20 may be arranged in the game machine 100 in any way. For example, the first display device 19 may be provided in the center of the game machine 100, and the second display device 20 may be provided in the periphery. Further, a plurality of first display devices 19 and second display devices 20 may be provided in the game machine 100. In this case, the same or separate moving images (described later) are displayed on each of the plurality of first display devices 19, and the same or different modified images (described later) are displayed on each of the plurality of second display devices 20. ..

[Specified information]
In this embodiment, the first storage unit 16 records designated information necessary for generating a second image from the first image.

FIG. 3 is a diagram schematically showing an example of the area information 161 recorded in the first storage unit 16 of the image processing device 1 of this embodiment. As shown in the figure, the area information 161 recorded in the storage unit 50 has image identifier information 1611 and designated information 1612.

The image identifier information 1611 is identification information of a liquid crystal image as a "first image" displayed on the first display device 19. When the image identifier information 1611 is given to the moving image, one image identifier information 1611 may be given to the entire moving image, or the image identifier information 1611 may be given to each frame constituting the moving image.

The designation information 1612 is information for specifying the area where the liquid crystal image is acquired. In this embodiment, the designated information 1612 functions as coordinate information indicating the pixel positions of the vertices of the region where the liquid crystal image is acquired.

A specific description will be given with reference to FIGS. 3 and 5. As shown in FIG. 3, the image information 1613 includes the image A and the designated information [(x1, y1) (x2, y2)]. As shown in FIG. 5, the image A is assumed to be a moving image displayed on the first display device 19. In this case, when the image A is displayed on the first display device 19, the extraction unit 12 refers to the designated information [(x1, y1) (x2, y2)] associated with the image A. Then, the extraction unit 12 diagonally aligns the first coordinates 16131 (x1, y1) and the second coordinates 16132 (x2, y2) from one or more frames of the moving image displayed on the first display device 19. An image in the range of the rectangle 1613a as the apex of is extracted as the designated image 30. The generation unit 14 uses the extracted designated image 30 to generate a second image to be displayed on the second display device 20.

The designated information 1612 may be any information as long as it can specify the range for extracting the designated image. For example, it may be three or more coordinate information, or information other than the coordinates, for example, information on a figure having a specific shape existing in a moving image, information indicating a specific character, or the like.

[Extraction of specified image]
FIG. 5 is a diagram schematically showing a mode in which the extraction unit 12 extracts designated information from a moving image displayed on the first display device 19 in the image processing device 1 of this embodiment.

As shown in FIG. 5A, a moving image is displayed on the first display device 19, and the moving image matches an image identifier specified in the designated information (see FIG. 3) (for example, FIG. 3 image information 1613). In the case of the image A) shown in FIG. 5, as shown in (A) of FIG. 5, the extraction unit 12 uses the designated information (designated information) from one or more frames of the moving image according to the procedure described in the above [designated information]. An image of a designated portion is extracted based on the designated information 1612 in FIG. 3, and this is designated as the designated image 30 shown in FIG. 5 (B).

The extraction unit 12 may extract the designated image 30 by using the moving image before being displayed on the second display device 20 or the moving image after being displayed on the second display device 20.

[Acquisition of changed image (1)]
FIG. 6 is a diagram schematically showing a mode in which the acquisition unit 13 acquires a line image from the designated image 30 in the image processing device 1 of this embodiment.

When the designated image 30 is extracted as shown in FIG. 5B, the acquisition unit 13 divides the designated image 30 according to a predetermined standard. In this embodiment, as shown in FIG. 6A, the designated images are uniformly sized in the column direction (for example, in the width a shown in FIG. 6A, that is, for example, the number of pixels in the horizontal direction). When is 4096, it is divided every 512 pixels). FIG. 6A schematically shows a state in which the first line image 31 to the eighth line image 38 are divided into eight as a “divided image”.

The acquisition unit 13 sequentially acquires these first line images 31 to 8th line images 38 while changing the acquisition timing. For example, as shown in FIGS. 6B to 6E, the acquisition unit 13 first receives a first line image 31 and a fifth line image 35 ((B) in FIG. 6), and then a second line image 32. And the sixth line image 36 ((C) of FIG. 6), then the third line image 33 and the seventh line image 37 ((D) of FIG. 6), then the fourth line image 34 and the eighth line image 38. ((E) in FIG. 6) is acquired as shown in.

The number and mode of division of the designated image 30 by the acquisition unit 13 may be other than those shown in FIG. For example, the number of line images obtained by dividing the designated image 30 may be more than or less than eight, and the division may be in a row direction, an oblique direction, a concentric circle, or a grid shape or a honeycomb shape. It may be a division in which they have an uneven shape.

[Acquisition of changed image (2)]
The first to eighth line images 31 to 38 acquired by the acquisition unit 13 are processed by the generation unit 14 to generate a modified image. Specifically, the generation unit 14 changes the first to eighth line images 31 to 38 to a resolution that can be displayed by the second display device 70 for each line (for example, the color and brightness of a plurality of pixels). The changed image is generated by mixing the information and changing to an image with a small number of pixels. That is, the generation unit 14 reduces the amount of moving image data by a predetermined standard.

The generation unit 14 displays these changed images line by line (for example, in the order of acquisition of the first line images 31 to 8 line images 38 shown in FIGS. 6B to 6) in the second buffer of the lighting unit 15. Record at 151.

The changed images recorded in the second buffer 151 are sequentially transmitted to the second display device 20, and the images are displayed when the respective LEDs 20a of the second display device 20 are turned on.

[Processing procedure]
FIG. 7 is a flowchart showing a processing procedure in the image processing apparatus 1 of this embodiment. Hereinafter, the processing procedure of this embodiment will be described based on this flowchart.

First, the image processing device 1 acquires an image data file from the second storage unit 18, generates a moving image in the image generation unit 11 (image generation procedure), and displays the image on the first display device 19. At this time, the moving image displayed on the first display device 19 is recorded in the first buffer 171 (first storage procedure).

The extraction unit 12 detects whether or not a moving image is displayed on the first display device 19. As a result of the detection, when the moving image is displayed on the first display device 19 (“Yes” in step S101), the extraction unit 12 displays the area information 161 of the first storage unit 16 on the first display device 19. Check if the specified information associated with the image identifier of the moving image is recorded. As a result of the confirmation, when the area information 161 contains the designated information associated with the image identifier of the moving image displayed on the first display device 19 (“Yes” in step S103), the extraction unit 12 is the first. 1 The designated image 30 is extracted from a part of the frame of the moving image displayed on the display device 19 (image generation procedure) and recorded in the first storage unit 16 (step S104).

When the designated image 30 is extracted, the acquisition unit 22 divides the designated image 30 based on a predetermined standard to acquire the first line image 31 to the eighth line image 38 (step S105, image generation procedure).

When the first line images 31 to 8th line images 38 are acquired, the generation unit 14 sequentially acquires these line images 31 to 38 as shown in FIGS. 6B to 6E. To change the resolution and generate a changed image (step S106, image generation procedure).

The generated modified image is temporarily recorded in the second buffer 151 of the lighting unit 15 (second storage procedure), and then transmitted to the second display device 20. The lighting unit 15 lights the LEDs 20a constituting the second display device 20 in a time-division manner by a dynamic lighting method in a state of being dependent on the division of the first line image 31 to the eighth line image 38 (step S107). As a result, the changed image is displayed on the second display device 20.

On the other hand, when there is no designated information in the moving image displayed on the first display device 19 (“Yes” in step S101 in step S101 to “No” in step S103), the moving image is displayed on the first display device 19. When the power is on (“No” in step S101 to “No” in step S102), the extraction unit 12 stands by in the state before the designated image 30 is extracted (display of “A”).

Further, when the moving image is not displayed on the first display device 19 and the power is turned off (“No” in step S101 to “Yes” in step S102), the process ends.

As described above, in this embodiment, the second modified image is generated depending on the moving image and has a smaller amount of data than the moving image, and the modified image is stored more than the storage capacity of the first buffer 171 for storing the moving image. By forming the storage capacity of the buffer 151 small, the first buffer 171 and the second buffer 151 can be formed into storage capacities corresponding to the data amount of the moving image and the data amount of the modified image, respectively. As a result, it is possible to obtain various visual effects by displaying an image on a plurality of display means while suppressing an increase in the storage capacity of the storage means including the second buffer 151.

In this embodiment, by acquiring a predetermined region of the moving image and generating the modified image, it is possible to generate a modified image whose data amount is equal to or less than the data amount of the moving image, which corresponds to at least a part of the moving image. Then, since the second buffer 151 can be formed with a storage capacity corresponding to the amount of data of the changed image, it is possible to prevent the second buffer 151 from becoming excessively large, and to reduce the storage capacity of the storage means including the second buffer 151. It is possible to prevent overgrowth.

In this embodiment, by generating the modified image by the first line image 31 to the eighth line image 38 obtained by dividing the moving image into a plurality of block units, the data amount of the modified image is surely measured as the moving image data. Can be produced smaller than the quantity. Then, since the second buffer 151 can be formed with a storage capacity corresponding to at least a part of the data amount of the first line images 31 to the eighth line images 38, the second buffer 151 becomes excessively large. It is possible to suppress the increase in the storage capacity of the storage means including the second buffer 151.

In this embodiment, the data amount of the modified image can be surely formed to be equal to or less than the data amount of the moving image by reducing the data amount of the moving image by a predetermined standard to generate the modified image. Then, since the second buffer 151 can be formed with a storage capacity corresponding to the amount of data of the changed image, it is possible to prevent the second buffer 151 from becoming excessively large, and to reduce the storage capacity of the storage means including the second buffer 151. It is possible to prevent overgrowth.

In this embodiment, by generating a modified image displayed on the LED screen based on a moving image which is a liquid crystal image, when the liquid crystal display and the LED display are used together, the modified image is generated based on the image of a predetermined area. The present invention can be applied to a dynamic lighting type LED display by lighting the modified image as the first line image 31 to the eighth line image 38 in a timed manner based on the rules of arrangement of the LEDs 20a. Further, the storage capacity of the second buffer 151 can be made a size based on at least a part of the first line image 31 to the eighth line image 38 which is a predetermined arrangement unit of the LED 20a, and the image to be displayed on the LED screen can be displayed. It is possible to prevent the second storage means for storing from becoming excessively large, and to prevent the storage capacity of the storage means including the second buffer 151 from becoming excessively large. Further, the resolution when changing the moving image to the changed image can be changed based on the time division range based on the arrangement rule of the LED 20a by the processing of the generation unit 14, so that when the changed image is generated. Processing load can be reduced.

In the above embodiment, the first display device 19 is configured as a liquid crystal screen and the second display device 20 is configured as an LED display, but the present invention is not limited to this, and the first display device 19 and the second display device 20 are not limited thereto. Can be configured on any screen. For example, both the first display device 19 and the second display device 20 may be configured as an LED display in which a plurality of LEDs 20a are arranged, or the second display device 20 may be configured as an organic EL display. That is, any display device may be used as the second display device 20 as long as it can perform dynamic lighting control or similar lighting control.

In the above embodiment, the LED driver as the lighting unit 15 is configured as an electric circuit using a diode, but the present invention is not limited to this, and the lighting unit 15 is configured by, for example, an integrated circuit such as an IC, and the LED 20a is lit. Control may be performed.

It goes without saying that the above-described embodiment is an example of the present invention and does not mean that the present invention is limited to the above-mentioned embodiment.

1 ... Image processing device 11 ... Image generation unit (image generation means)
12 ... Extraction unit (image generation means)
13 ... Acquisition unit (image generation means, image changing means)
14 ... Generation unit (image generation means, image changing means)
19 ... First display device (first image display means)
20 ... Second display device (second image display means)
20a ... LED
30 ... Designated images 31-38 ... 1st line image to 8th line image (divided image)
100 ... Game machine 151 ... Second buffer (second storage means)
171 ... First buffer (first storage means)

Claims (14)

An image processing device that generates a plurality of images to be displayed on a plurality of image display means.
A first image to be displayed on the first image display means as one or more image display means, for displaying the second image display means as an image display unit other than the first image display unit, before Symbol first It is provided with an image generation means for generating a second image having a smaller amount of data than one image .
The image generation means can acquire a plurality of divided images obtained by dividing the first image into a plurality of block units, and display the images generated by the acquired divided images on the second image display means. An image changing means for generating a plurality of the second images is provided.
The first storage means for storing the first image and
A second storage means having a storage capacity smaller than the storage capacity of the first storage means and having a storage capacity large enough to store the second image and storing the second image.
Equipped with a,
The image generation means outputs so that at least one of the first image and the plurality of second images is displayed simultaneously on the first image display means and the second image display means. At the same time, the image processing apparatus is configured such that each of the plurality of the second images is output so as to be displayed on the second image display means at different timings . The image changing means reduces the amount of data of the first image by a predetermined standard to generate the second image.
The image processing apparatus according to claim 1, wherein the storage capacity of the second storage means is formed to a size capable of storing the second image . The first image display means is a liquid crystal display, and the first image is an image displayed on a liquid crystal screen.
The second image display means is an LED display in which a plurality of LEDs are arranged according to a predetermined rule, and the second image is an image displayed on an LED screen.
The image generation means acquires an image of a predetermined region which is at least a part of the first image displayed on the first image display means, and uses the image of the predetermined region as the second image display means. An image changing means for generating the second image by changing to an image that can be displayed is provided.
The image processing apparatus according to claim 1 or 2, wherein the image changing means lights the second image based on the rules of the arrangement of the LEDs . A gaming machine including the image processing device according to any one of claims 1 to 3. An image process that includes a first storage means and a second storage means formed with a storage capacity smaller than the storage capacity of the first storage means, and generates a plurality of images to be displayed on a plurality of image display means. An image processing method performed by the device
Generate a first image to be displayed on the first image display means as one or more image display means,
A divided image for generating a plurality of divided images obtained by dividing the first image into a plurality of block units is acquired, and an image generated by each of the acquired divided images is used to display an image other than the first image display means. A plurality of second images having a smaller amount of data than the first image to be displayed on the second image display means as means are generated.
The first image is stored in the first storage means,
The second image is stored in the second storage means formed in a storage capacity smaller than the storage capacity of the first storage means and having a storage capacity large enough to store the second image.
At least one of the first image and the plurality of second images is output so as to be simultaneously displayed on the first image display means and the second image display means, and a plurality of the first images are displayed. Each of the two images is configured to be output so as to be displayed on the second image display means at different timings.
An image processing method characterized by that. An image processing program that includes a first storage means and a second storage means and is executed by a processor of an image processing device that generates a plurality of images to be displayed on a plurality of image display means.
Generate a first image to be displayed on the first image display means as one or more image display means,
A divided image for generating a plurality of divided images obtained by dividing the first image into a plurality of block units is acquired, and an image generated by each of the acquired divided images is used to display an image other than the first image display means. A plurality of second images having a smaller amount of data than the first image to be displayed on the second image display means as means are generated.
The first image is stored in the first storage means,
The second image is stored in the second storage means formed in a storage capacity smaller than the storage capacity of the first storage means and having a storage capacity large enough to store the second image.
At least one of the first image and the plurality of second images is output so as to be simultaneously displayed on the first image display means and the second image display means, and a plurality of the first images are displayed. Each of the two images is configured to be output so as to be displayed on the second image display means at different timings.
An image processing program characterized by this. An image to be displayed on a first display device for displaying an image and a second display device having a plurality of light emitting elements arranged vertically and horizontally and displaying an image by lighting each light emitting element on a line-by-line basis. An image processing device that processes
A storage unit that stores an image identifier that identifies the first image in association with designated information that specifies an area of the first image.
When displaying the first image on the first display device, if there is designated information associated with the image identifier of the first image to be displayed, an extraction unit for extracting the second image in the area designated by the designated information, and an extraction unit.
An acquisition unit that acquires a line image of each line to be lit by the second display device from the second image, and
Using the line image, a lighting unit that lights a plurality of light emitting elements included in the second display device in line units, and
An image processing device characterized by comprising. The image processing device further
A generation unit for generating a changed image in which the resolution of the line image is changed to the resolution of the line of the second display device is provided.
The lighting part is replaced with the line image.
Using the modified image, a plurality of light emitting elements included in the second display device are lit in line units.
The image processing apparatus according to claim 7. A first buffer for storing the first image and
A second buffer for storing the modified image, which has a smaller storage capacity than the first buffer, and
With
The lighting part is
Using the line image stored in the second buffer, a plurality of light emitting elements included in the second display device are lit in line units.
The image processing apparatus according to claim 8. A first buffer for storing the first image and
A second buffer for storing the modified image, which has a smaller storage capacity than the first buffer, and
With
The lighting part is
Using the modified image stored in the second buffer, a plurality of light emitting elements included in the second display device are lit in line units.
The image processing apparatus according to claim 8. An image to be displayed on a first display device for displaying an image and a second display device having a plurality of light emitting elements arranged vertically and horizontally and displaying an image by lighting each light emitting element on a line-by-line basis. An image processing device that processes
An image identifier that identifies the first image, designated information that specifies an area of the first image, a first timing for displaying the first image on the first display device, and a second image of the area designated by the designated information. A storage unit that stores the second timing for displaying the image on the second display device in association with the second timing.
When the first image to be displayed on the first display device is determined, if there is designated information associated with the image identifier of the determined first image, the second image in the area designated by the designated information is extracted. Extraction part and
An acquisition unit that acquires a line image of each line to be lit by the second display device from the extraction unit, and
A lighting unit that uses the line image to light a plurality of light emitting elements included in the second display device on a line-by-line basis at a second timing associated with the first image from which the line image is acquired.
An image processing device characterized by comprising. The image processing device further
A generation unit for generating a changed image in which the resolution of the line image is changed to the resolution of the line of the second display device is provided.
The lighting part is replaced with the line image.
At the second timing associated with the first image from which the line image is acquired, the modified image is used to light a plurality of light emitting elements included in the second display device in line units.
The image processing apparatus according to claim 11. An image to be displayed on a first display device for displaying an image and a second display device having a plurality of light emitting elements arranged vertically and horizontally and displaying an image by lighting each light emitting element on a line-by-line basis. An image processing method for an image processing device to be processed, which is an image processing device including a storage unit that stores an image identifier that identifies the first image and designated information that specifies an area of the first image in association with each other.
When displaying the first image on the first display device, if there is designated information associated with the image identifier of the first image to be displayed, the second image in the area designated by the designated information is extracted.
A line image of each line to be lit by the second display device is acquired from the second image, and the line image is obtained.
Using the line image, a plurality of light emitting elements included in the second display device are lit in line units.
An image processing method characterized by that. An image to be displayed on a first display device for displaying an image and a second display device having a plurality of light emitting elements arranged vertically and horizontally and displaying an image by lighting each light emitting element on a line-by-line basis. A display control program that is executed by a computer of an image processing device that is an image processing device to process and has a storage unit that stores an image identifier that identifies the first image and designated information that specifies an area of the first image in association with each other. And
When displaying the first image on the first display device, if there is designated information associated with the image identifier of the first image to be displayed, the second image in the area designated by the designated information is extracted.
A line image of each line to be lit by the second display device is acquired from the second image, and the line image is obtained.
Using the line image, a plurality of light emitting elements included in the second display device are lit in line units.
An image processing program characterized by causing a computer to perform processing.

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