JP2013131042A - Image processing device and controlling method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology capable of performing image processing on a plurality of divided images without making a boundary part conspicuous by a simple structure, when the plurality of divided images to which images of end portions are not added are inputted.SOLUTION: An image processing device has a plurality of image processing processors for performing image processing on a plurality of inputted divided images. The image processing processor has obtaining means for obtaining an image of an end portion adjacent to an object divided image of an adjacent divided image, from an image processing processor for processing the adjacent divided image which is the divided image adjacent to the object divided image, among the plurality of the image processing processors; adding means for adding the image of the end portion adjacent to an end of the object division image, which is obtained by the obtaining means, to the end of the object division image, thereby generating a composite image; and image processing means for performing image processing on the composite image generated by the adding means.

Description

  The present invention relates to an image processing apparatus and a control method thereof.

In recent years, the resolution of displays has been increased (for example, 4096 × 2160 pixels), and high-resolution image content has been produced. Conventionally, since only one image processor (image processing LSI) is insufficient in image processing capability, one input image is divided into a plurality of divided images, and a plurality of divided images are simultaneously obtained using a plurality of image processing processors. A technique for performing image processing has been proposed (Patent Document 1).
Further, a technique has been proposed in which the boundary portion between a plurality of divided images is inconspicuous when an input image is divided into a plurality of divided images and image processing is performed (Patent Document 2). Specifically, Patent Document 2 discloses a technique for performing image processing by adding a partial image (image of an adjacent end) of a divided image adjacent to the divided image to the divided image.

JP 2000-20481 A JP 2011-97474 A

However, instead of a single image (high-resolution image), a plurality of divided images (a plurality of divided images to which no end image is added) may be input to such a display. Since the conventional techniques (the techniques disclosed in Patent Document 1 and Patent Document 2) do not correspond to such a case, the boundary portions of a plurality of divided images cannot be made inconspicuous.
In the technique disclosed in Patent Document 1 described above, the master processor holds an image for one sheet, adds a divided image to an end image, and transfers the image to the slave processor. Therefore, in the technique disclosed in Patent Document 1, a master processor and a memory (a memory for holding at least one image) that generate a plurality of divided images to which end images are added from high-resolution images. I need it.

  Therefore, the present invention provides a technology that can perform image processing with a simple configuration without conspicuous boundary portions when a plurality of divided images to which no edge image is added are input. The purpose is to provide.

The first aspect of the present invention is:
An image processing apparatus that performs image processing on a plurality of divided images obtained by dividing one image,
A plurality of image processing processors for performing image processing on a plurality of input divided images;
The image processor is
An image of an edge adjacent to another divided image is extracted from a target divided image that is a divided image to be processed, and the extracted edge image is extracted from the plurality of image processing processors to the other divided image. Extracting means for sending an image to an image processor to be processed;
Out of the plurality of image processors, an image of an end portion of the adjacent divided image adjacent to the target divided image is selected from an image processor that processes an adjacent divided image that is a divided image adjacent to the target divided image. Acquisition means for acquiring;
An adding unit that generates a composite image by adding an image of an end adjacent to the end acquired by the acquiring unit to an end of the target divided image;
Image processing means for performing image processing on the composite image generated by the adding means;
An image processing apparatus comprising:

The second aspect of the present invention is:
A control method for an image processing apparatus having a plurality of image processing processors for performing image processing on a plurality of divided images obtained by dividing one image,
The image processor extracts an image of an edge adjacent to another divided image from a target divided image that is a divided image to be processed, and extracts the extracted edge image of the plurality of image processors. Among these, an extraction step of sending the other divided image to an image processor to be processed;
The image processor is adjacent to the target divided image of the adjacent divided image from an image processor that processes an adjacent divided image that is a divided image adjacent to the target divided image among the plurality of image processing processors. An acquisition step of acquiring an image of an end portion to be performed;
An addition step in which the image processor adds an image of an edge adjacent to the edge acquired in the acquisition step to an edge of the target divided image to generate a composite image;
An image processing step in which the image processor performs image processing on the composite image generated in the adding step;
A control method for an image processing apparatus, comprising:

The third aspect of the present invention is:
An image processing apparatus that performs image processing on first and second divided images obtained by dividing one image,
A first image processing processor that performs image processing on the input first divided image; and a second image processing processor that performs image processing on the input second divided image;
The first image processor is
An image of an end portion in the first divided image and an end portion adjacent to the second divided image is extracted as a first end image and sent to the second image processor. Sending extraction means;
Obtaining from the second image processor, an image of an end portion in the second divided image, which is an end portion adjacent to the first divided image, as a second end image Means,
An adding means for adding the second end image acquired by the acquiring means to an end of the first divided image adjacent to the second divided image to generate a composite image;
Image processing means for performing image processing on the composite image generated by the adding means;
An image processing apparatus comprising:

The fourth aspect of the present invention is:
A control method for an image processing apparatus having first and second image processing processors for performing image processing on first and second divided images obtained by dividing one image.
The first image processor extracts an end image adjacent to the second divided image as an end image in the first divided image as a first end image. Extracting to the second image processor;
The first image processor receives, from the second image processor, an end image in the second divided image, an end image adjacent to the first divided image, An acquisition step of acquiring as two end images;
The first image processor adds the second end image acquired by the acquisition unit to an end of the first divided image on the side where the second divided image is adjacent, An additional step of generating a composite image;
An image processing step in which the first image processor performs image processing on the composite image generated by the adding unit;
A control method for an image processing apparatus, comprising:

  According to the present invention, when a plurality of divided images to which no edge image is added are input, it is possible to perform image processing with a simple configuration without conspicuous boundary portions in the plurality of divided images.

Example of configuration of image processing system according to embodiment 1 Example of input image and edge image according to embodiment 1 Example of configuration of image processing LSI that performs image processing on left image according to embodiment 1 Example of configuration of image processing LSI that performs image processing on right image according to embodiment 1 Example of configuration of image processing system according to embodiment 2 Example of image processing LSI processing according to the second embodiment Example of configuration of image processing LSI according to embodiment 2

<Example 1>
Hereinafter, an image processing apparatus and a control method thereof according to Embodiment 1 of the present invention will be described. The image processing apparatus according to the present embodiment performs image processing on a plurality of divided images obtained by dividing one image.

FIG. 1 is a diagram illustrating an example of a configuration of an image processing system using the image processing apparatus according to the present embodiment.
The PC 100 is a device that outputs an image such as a personal computer. The PC 100 is connected to the image processing apparatus (specifically, the video receiver 103) according to the present embodiment using communication cables 101 and 102. The PC 100 outputs two divided images obtained by dividing one image in the horizontal direction to the image processing apparatus via the two communication cables 101 and 102. Specifically, the left half image (left image) of one image is output via the communication cable 101. The right half image (right image) of one image is output via the communication cable 102. The communication cables 101 and 102 are, for example, a display port cable, a USB cable, or a PCI express cable.

An image processing apparatus (image display apparatus) according to the present embodiment includes a video receiver 103, image processing LSIs (Large Scale Integration) 106 and 107 (a plurality of image processing processors that perform image processing on a plurality of input divided images), A display panel 112 and the like are included.

  The video receiver 103 converts the format of the input divided image into a format suitable for processing in the image processing apparatus, and outputs the divided image whose format has been converted to the image processing LSIs 106 and 107. Specifically, the video receiver 103 converts the Displayport signal of the left image input via the communication cable 101 into an LVDS signal, and outputs it to the image processing LSI 106 via the communication line 104. Further, the video receiver 103 converts the Displayport signal of the right image input via the communication cable 102 into an LVDS signal, and outputs it to the image processing LSI 107 via the communication line 105.

The image processing LSI 106 is a processor (first image processing processor) that performs image processing on the left image (first divided image) input via the communication line 104. The image processing is filter processing that performs, for example, image enlargement / reduction, noise reduction, enhancer, deformation, frame rate conversion, and the like. However, image processing is not limited to this. Image processing may not be filter processing.
In order to suppress the conspicuous boundary portion with the right image by performing image processing on the left image, an image at the end of the right image (within the second divided image) is provided at the right end of the left image. It is necessary to add an edge image adjacent to the left image. By adding the edge image to the left image, it is possible to perform image processing on the left image in consideration of the pixel value of the right image, so that the image on the left image is not conspicuous at the boundary with the right image. Processing can be performed.
Therefore, in this embodiment, the image processing LSI 106 acquires the above-described end image (second end image) from the image processing LSI 107 via the communication line 108, and adds the acquired end image to the left image. To do. Then, the image processing LSI 106 performs image processing on the left image to which the edge image is added, and outputs the left image subjected to the image processing to the display panel 112 via the communication line 110.

The image processing LSI 107 is a processor (second image processing processor) that performs image processing (image processing similar to the image processing LSI 106) on the right image (second divided image) input via the communication line 105. is there.
Specifically, the image processing LSI 107 is an end image (an image at the end in the left image (in the first divided image) via the communication line 109 from the image processing LSI 106, and is adjacent to the right image. An end image (first end image) is acquired, and the acquired end image is added to the right image (the left end of the right image). Then, the image processing LSI 107 performs image processing on the right image to which the edge image is added, and outputs the right image subjected to the image processing to the display panel 112 via the communication line 111.

The edge image preferably includes at least an image of a region that is referred to when the image processing LSI performs image processing on a divided image to be processed (target divided image). For example, when the image processing is filter processing, the edge image includes an image of an area (included in the filter tap) that is referred to when filtering is applied to the pixel at the end of the target divided image. Is preferred. By using such an image as an edge image, the pixel value of the divided image adjacent to the target divided image (adjacent divided image) can be considered to the maximum, and the boundary between the target divided image and the adjacent divided image It can suppress that a part stands out more.
In order to reduce the capacity of the memory in the image processing LSI, it is preferable that the edge image is small. Therefore, it is preferable that the image at the edge is an image of a region that is referred to when the image processing LSI performs image processing on a divided image to be processed (target divided image).
In the present embodiment, the left image and the right image obtained by dividing one image in the horizontal direction are input. However, the present invention is not limited to this. An upper image (upper half image of the original image) and a lower image (lower half image of the original image) obtained by dividing one image in the vertical direction may be input. Two images obtained by obliquely dividing one image may be input. The sizes of the plurality of input divided images may be different from each other.

The display panel 112 acquires a plurality of divided images that have been subjected to image processing. Then, the display panel 112 generates a single image by combining the acquired plurality of divided images and displays the image. Specifically, the display panel 112 acquires a left image on which image processing has been performed via the communication line 110, and acquires a right image on which image processing has been performed via the communication line 111. Then, the display panel 112 combines the acquired left image and right image to form one image (the left half is a left image subjected to image processing and the right half is a right image subjected to image processing). A certain image) is generated and displayed.
The display panel 112 is, for example, a liquid crystal display panel, a plasma display panel, an organic EL display panel, or the like. The display panel 112 may be a part of the image processing apparatus or may be a separate device from the image processing apparatus.

An example of the input image and the edge image according to the first embodiment will be described with reference to FIG.
In FIG. 2, a left image 201 and a right image 204 obtained by dividing the original image 200 in the horizontal direction from the PC 100 (the left image 201 and the right image 204 obtained by dividing the image by the image dividing line in the figure) are input. This is an example of the case.
In the example of FIG. 2, an image for a predetermined number of pixels from the right end of the left image 201 to the inside of the left image 201 is an end image 202, and the end image 202 is added to the left end of the right image 204.
In the example of FIG. 2, an image for a predetermined number of pixels from the left end of the right image 204 to the inside of the right image 204 is set as the end image 203, and the end image 203 is added to the right end of the left image 201.
Then, after the image processing is performed on the left image 201 to which the end image 203 is added, the end image 203 added to the left image 201 is removed, and the left image 201 (end image) on which the image processing has been performed is performed. The image from which the partial image 203 is removed is output to the display panel 112.
Further, after the image processing is performed on the right image 204 to which the end image 202 is added, the end image 202 added to the right image 204 is removed, and the right image 204 (end image) on which the image processing has been performed is performed. The image from which the partial image 202 has been removed is output to the display panel 112.

  The configuration of the image processing LSI according to the present embodiment will be described in detail with reference to FIGS. FIG. 3 is a block diagram illustrating an example of the configuration of the image processing LSI 106. FIG. 4 is a block diagram illustrating an example of the configuration of the image processing LSI 107.

First, the image processing LSI 106 will be described with reference to FIG.
The data bus 6 is used for high-speed data transfer between functional blocks.
The memory 7 stores data input via the data bus 6.

  The first writing unit 3 adds the dummy image 300 to the left end of the left image 201 so that the right end and the left end of the left image 201 coincide with the word alignment boundary (word boundary) of the memory 7. The left image 201 is written into the memory 7. For example, when storing pixel data of 8 pixels per word (here 32 bytes), the total number of horizontal pixels of the dummy image 300 is divisible by 8 in the horizontal direction of the left image 201 and the dummy image 300. The number is a value.

The edge generation unit 4, the second writing unit 5, and the communication unit 8 make an image of an edge adjacent to another divided image from a target divided image that is a divided image to be processed by itself (the image processing LSI 106). The extracted edge image is sent to the image processing LSI that processes the other divided image among the plurality of image processing LSIs.
In the present embodiment, the edge generation unit 4 generates an edge image 202 from the left image 201 and outputs it to the second writing unit 5.
The second writing unit 5 outputs the end image 202 to the communication unit 8.
The communication unit 8 transmits the end image 202 output from the second writing unit 5 to the image processing LSI 107.
Further, the communication unit 8 acquires an image of an edge adjacent to the target divided image of the adjacent divided image from the image processing LSI that processes the adjacent divided image among the plurality of image processing LSIs. In the present embodiment, the communication unit 8 receives the end image 203 from the image processing LSI 107 and stores the received end image 203 in the memory 7 via the data bus 6. The end image 203 is word-aligned so as to be continuously connected to the right end of the left image 201 written by the first writing unit 3 and stored in the memory 7.

The reading unit 9 and the dummy image cutout unit 10 add the image of the end adjacent to the end acquired by the communication unit 8 to the end of the target divided image, and generate a composite image.
In the present embodiment, the reading unit 9 combines the left image 201 to which the dummy image 300 is added and the end image 203 to read out from the memory 7. That is, the left image 201 to which the dummy image 300 is added is read from the memory 7 with the end image 203 added. The read image (the left image with the dummy image and the end image added) is output to the dummy image cutout unit 10.
The dummy image cutout unit 10 deletes (cuts out) the dummy image 300 added to the left image 201. Thereby, an image in which the end image 203 is added to the left image 201 is obtained as the composite image. The dummy image cutout unit 10 outputs the composite image (the left image 201 with the end image 203 added) to the image processing unit 11.

The image processing unit 11 performs image processing (image enlargement / reduction, noise reduction, enhancer, deformation, frame rate conversion) on the composite image generated by the dummy image cutout unit 10 (the composite image output from the dummy image cutout unit 10). Etc.) is performed.
The edge cutout unit 12 deletes (cuts out) the end image 203 portion from the composite image that has been subjected to image processing, and the composite image from which the end image 203 portion has been deleted (that is, the left image that has been subjected to image processing). The image 201) is output to the display panel 112 via the communication line 110.

Next, the image processing LSI 107 will be described with reference to FIG. The processing of each functional block of the image processing LSI 107 is the same as that of the image processing LSI 106. This will be described in detail below.
The data bus 16 is used for high-speed data transfer between functional blocks.
The memory 17 stores data input via the data bus 16.

  The first writing unit 13 adds the dummy image 350 to the right end of the right image 204 so that the right end and the left end of the right image 204 coincide with the word alignment boundary of the memory 17, and the right image 204 to which the dummy image 350 is added. Is written into the memory 17.

The end generation unit 14 generates an end image 203 from the right image 204 and outputs the end image 203 to the second writing unit 15.
The second writing unit 15 outputs the end image 203 to the communication unit 18.
The communication unit 18 transmits the end image 203 output from the second writing unit 15 to the image processing LSI 106.
Further, the communication unit 18 receives the end image 202 from the image processing LSI 106 and stores the received end image 202 in the memory 17 via the data bus 16.

The reading unit 19 combines and reads the right image 204 to which the dummy image 350 is added and the end image 202 from the memory 17 and outputs the combined image to the dummy image cutting unit 20.
The dummy image cutout unit 20 deletes the dummy image 350 added to the right image 204. As a result, an image in which the end image 202 is added to the right image 204 is obtained as a composite image. The dummy image cutout unit 20 outputs the composite image (the right image 204 with the end image 202 added) to the image processing unit 21.

The image processing unit 21 performs image processing on the composite image generated by the dummy image cutout unit 20 (the composite image output from the dummy image cutout unit 20).
The end cutout unit 22 deletes the end image 202 portion from the composite image that has undergone image processing, and the composite image from which the end image 202 portion has been deleted (that is, the right image 204 that has undergone image processing). Is output to the display panel 112 via the communication line 111.

As described above, according to the present embodiment, each image processing LSI generates an edge image required by the other image processing LSI from the target divided image, and outputs it to the other image processing LSI. To do.
Each image processing LSI performs image processing by adding the edge image output from the other image processing LSI to the target divided image. Therefore, when a plurality of divided images to which no edge image is added are input, image processing can be performed without conspicuous boundary portions in the plurality of divided images. Further, according to the present embodiment, each image processing LSI only needs to have a memory capable of storing at least a divided image and an end image added to the divided image. Therefore, it is possible to perform image processing without conspicuous boundary portions in a plurality of divided images with a simple configuration that does not require a memory for holding one high-resolution image (all divided images).

<Example 2>
Hereinafter, an image processing apparatus and a control method thereof according to Embodiment 2 of the present invention will be described. In the first embodiment, the case where the original image is divided into two divided images and input to the image processing apparatus has been described. In the second embodiment, a case where the original image is divided into three or more divided images will be described. Specifically, a case where the original image is divided into four 2 × 2 divided images and a plurality of adjacent divided images exist for one target divided image will be described.

A configuration of an image processing system using the image processing apparatus according to the present embodiment will be described with reference to FIGS. FIG. 5A is a diagram illustrating an example of a divided image input to the image processing apparatus according to the present embodiment. FIG. 5B is a diagram illustrating an example of the configuration of the image processing system according to the present embodiment.
In this embodiment, the PC 405 outputs four 2 × 2 divided images 401 to 404 obtained by dividing one image 400 in the horizontal direction and the vertical direction to the image processing apparatus (video receiver 406).

The video receiver 406 converts the format of the four divided images 401 to 404 and outputs them to the four image processing LSIs 410 to 413. Specifically, the divided image 401 is output to the image processing LSI 410. The divided image 402 is output to the image processing LSI 411. The divided image 403 is output to the image processing LSI 412. The divided image 404 is output to the image processing LSI 413.
The bus switch 414 is used to connect the image processing LSIs and transmit an end image between the image processing LSIs.

The image processing LSIs 410 to 413 perform image processing on the input divided images.
In this embodiment, in each image processing LSI, an edge image adjacent to the adjacent divided image is extracted from the target divided image, and the extracted edge image is processed as an image processing LSI for the adjacent divided image. Is sent to each adjacent divided image. A process of acquiring an image of an edge adjacent to the target divided image of the adjacent divided image from the image processing LSI that processes the adjacent divided image is performed for each adjacent divided image. Then, the process of adding the image of the edge adjacent to the edge to the edge of the target divided image is performed for each edge of the target divided image adjacent to the plurality of adjacent divided images, and a composite image is generated.

  Specifically, as illustrated in FIG. 6A, the image processing LSI 410 sets an image corresponding to a predetermined number of pixels from the right end of the divided image 401 to the inside of the divided image 401 as an end image 600. As illustrated in FIG. 6B, the image processing LSI 410 sets an image for a predetermined number of pixels from the lower end of the divided image 401 to the inside of the divided image 401 as an end image 601. Then, as illustrated in FIG. 6C, the image processing LSI 410 sets an image for a predetermined number of pixels from the lower right end of the divided image 401 to the inside of the divided image 401 as an end image 602. The image processing LSI 410 uses the bus switch 414 to send the end image 600 to the image processing LSI 411, the end image 601 to the image processing LSI 412, and the end image 602 to the image processing LSI 413.

  As illustrated in FIG. 6D, the image processing LSI 411 sets an image corresponding to a predetermined number of pixels from the left end of the divided image 402 to the inside of the divided image 402 as an end image 603. As illustrated in FIG. 6E, the image processing LSI 411 sets an image corresponding to a predetermined number of pixels from the lower end of the divided image 402 to the inside of the divided image 402 as an end image 604. Then, as illustrated in FIG. 6F, the image processing LSI 411 sets an image corresponding to a predetermined number of pixels from the lower left end of the divided image 402 to the inside of the divided image 402 as an end image 605. The image processing LSI 411 uses the bus switch 414 to send the end image 603 to the image processing LSI 410, the end image 604 to the image processing LSI 413, and the end image 605 to the image processing LSI 412.

  As illustrated in FIG. 6G, the image processing LSI 412 sets an image corresponding to a predetermined number of pixels from the right end of the divided image 403 to the inside of the divided image 403 as an end image 606. As illustrated in FIG. 6H, the image processing LSI 412 sets an image corresponding to a predetermined number of pixels from the upper end of the divided image 403 to the inside of the divided image 403 as an end image 607. Then, as illustrated in FIG. 6I, the image processing LSI 412 sets an image corresponding to a predetermined number of pixels from the upper right end of the divided image 403 to the inside of the divided image 403 as an end image 608. The image processing LSI 412 uses the bus switch 414 to send the end image 606 to the image processing LSI 413, the end image 607 to the image processing LSI 410, and the end image 608 to the image processing LSI 411.

  As illustrated in FIG. 6J, the image processing LSI 413 sets an image corresponding to a predetermined number of pixels from the left end of the divided image 404 to the inside of the divided image 404 as an end image 609. As illustrated in FIG. 6K, the image processing LSI 413 sets an image corresponding to a predetermined number of pixels from the upper end of the divided image 404 to the inside of the divided image 404 as the end image 610. Then, as illustrated in FIG. 6L, the image processing LSI 413 sets an image corresponding to a predetermined number of pixels from the upper left end of the divided image 404 to the inside of the divided image 404 as the end image 611. The image processing LSI 413 uses the bus switch 414 to send the end image 609 to the image processing LSI 412, the end image 610 to the image processing LSI 411, and the end image 611 to the image processing LSI 410.

As illustrated in FIG. 6M, the image processing LSI 410 adds end images 603, 607, and 611 to the divided image 401. Then, the image processing LSI 410 performs image processing on the divided image 401 to which the end images 603, 607, and 611 are added, and outputs the divided image 401 subjected to the image processing to the display panel 415.
As illustrated in FIG. 6N, the image processing LSI 411 adds end images 600, 608, and 610 to the divided image 402. Then, the image processing LSI 411 performs image processing on the divided image 402 to which the end images 600, 608, and 610 are added, and outputs the divided image 402 subjected to the image processing to the display panel 415.
As illustrated in FIG. 6O, the image processing LSI 412 adds end images 601, 605, and 609 to the divided image 403. Then, the image processing LSI 412 performs image processing on the divided image 403 to which the end images 601, 605, and 609 are added, and outputs the divided image 403 subjected to the image processing to the display panel 415.
As illustrated in FIG. 6P, the image processing LSI 413 adds end images 602, 604, and 606 to the divided image 404. Then, the image processing LSI 413 performs image processing on the divided image 404 to which the end images 602, 604, and 606 are added, and outputs the divided image 404 on which the image processing has been performed to the display panel 415.

  The display panel 415 acquires a plurality of divided images that have been subjected to image processing. Then, the display panel 415 generates and displays one image (an image in which the divided images 401 to 404 subjected to image processing are arranged in 2 × 2) by combining the plurality of obtained divided images.

The configuration of the image processing LSI 410 according to the present embodiment will be described in detail with reference to FIG. Since the basic configuration of the image processing LSIs 411 to 413 is the same as that of the image processing LSI 410,
The description is omitted.

The data bus 514 is used for high-speed data transfer between functional blocks.
The memory 508 stores data input via the data bus 514.
The first writing unit 501 word-aligns the divided image 401 (adds a dummy image) and writes it in the memory 508.

The edge generation unit 502, 504, 506, the second writing unit 503, 505, 507, and the communication unit 509 extract the edge image adjacent to the adjacent divided image from the target divided image, and extract the extracted edge portion. The process of sending the image to the image processing LSI for processing the adjacent divided image is performed for each adjacent divided image.
In the present embodiment, the edge generation unit 502 generates an edge image 600 from the divided image 401 and outputs it to the second writing unit 503.
The second writing unit 503 outputs the end image 600 to the communication unit 509.
The edge generation unit 504 generates an edge image 601 from the divided image 401 and outputs it to the second writing unit 505.
The second writing unit 505 outputs the end image 601 to the communication unit 509.
The edge generation unit 506 generates an edge image 602 from the divided image 401 and outputs it to the second writing unit 507.
The second writing unit 507 outputs the end image 602 to the communication unit 509.
The communication unit 509 transmits the end image 600 output from the second writing unit 503 to the image processing LSI 411 via the bus switch 414. The communication unit 509 transmits the end image 601 output from the second writing unit 505 to the image processing LSI 412 via the bus switch 414. The communication unit 509 transmits the end image 602 output from the second writing unit 507 to the image processing LSI 413 via the bus switch 414.

Further, the communication unit 509 performs, for each adjacent divided image, processing for acquiring an image of an end adjacent to the target divided image of the adjacent divided image from the image processing LSI that processes the adjacent divided image.
In this embodiment, the communication unit 509 receives the end image 603 from the image processing LSI 411 and stores the received end image 603 in the memory 508 via the data bus 514. The end image 603 is word-aligned so as to be continuously connected to the right end of the divided image 401 written by the first writing unit 501 and stored in the memory 508.
The communication unit 509 receives the end image 607 from the image processing LSI 412 and stores the received end image 607 in the memory 508 via the data bus 514. The edge image 607 is word-aligned so as to be continuously connected to the lower end of the divided image 401 written by the first writing unit 501 and stored in the memory 508.
The communication unit 509 receives the end image 611 from the image processing LSI 413 and stores the received end image 611 in the memory 508 via the data bus 514. The end image 611 is word-aligned so as to be continuously connected to the lower right end of the divided image 401 written by the first writing unit 501 and stored in the memory 508.

By the reading unit 510 and the dummy image cutout unit 511, the process of adding the edge image adjacent to the end to the end of the target divided image is performed for each end of the target divided image where the plurality of adjacent divided images are adjacent. A composite image is generated.
In the present embodiment, the reading unit 510 reads out the combined image 401, the end image 603, the end image 607, and the end image 611 to which the dummy image is added from the memory 7, and reads out the dummy image cutting unit. To 511.
The dummy image cutout unit 511 deletes the dummy image added to the divided image 401. As a result, an image in which the end images 603, 607, and 611 are added to the divided image 401 is obtained as the composite image. The dummy image cutout unit 511 generates a composite image (end image 603).
, 607 and 611 are output to the image processing unit 512.

The image processing unit 512 performs image processing on the composite image generated by the dummy image cutout unit 511 (the composite image output from the dummy image cutout unit 511).
The end cutout unit 513 deletes the end images 603, 607, and 611 from the composite image that has undergone image processing, and the combined image from which the end images 603, 607, and 611 have been deleted (that is, image processing). Is output to the display panel 415.

In this embodiment, the case where the original image is divided into 4 × 2 × 2 divided images and input to the image processing apparatus has been described, but the same processing is performed even when the division method and the number of divisions are different. do it.
As described above, according to the present embodiment, even when there are a plurality of adjacent divided images with respect to one target divided image, a plurality of divided images with a simple configuration as in the first embodiment. The image processing can be performed without making the boundary portion conspicuous.
Specifically, also in the present embodiment, as in the first embodiment, each image processing LSI generates an edge image required by the other image processing LSI and outputs it to the other image processing LSI. Each image processing LSI performs image processing by adding the edge image output from the other image processing LSI to the target divided image. Therefore, when a plurality of divided images to which no edge image is added are input, image processing can be performed without conspicuous boundary portions in the plurality of divided images. Further, according to the present embodiment, each image processing LSI only needs to have a memory capable of storing at least a divided image and an end image added to the divided image. Therefore, it is possible to perform image processing without conspicuous boundary portions in a plurality of divided images with a simple configuration that does not require a memory for holding one high-resolution image (all divided images).

4, 14, 502, 504, 506 End generation unit 5, 15, 503, 505, 507 Second writing unit 8, 18, 509 Communication unit 9, 19, 510 Reading unit 10, 20, 511 Dummy image cropping unit 11 , 21, 512 Image processing unit 106, 107, 410-413 Image processing LSI

Claims (8)

An image processing apparatus that performs image processing on a plurality of divided images obtained by dividing one image,
A plurality of image processing processors for performing image processing on a plurality of input divided images;
The image processor is
An image of an edge adjacent to another divided image is extracted from a target divided image that is a divided image to be processed, and the extracted edge image is extracted from the plurality of image processing processors to the other divided image. Extracting means for sending an image to an image processor to be processed;
Out of the plurality of image processors, an image of an end portion of the adjacent divided image adjacent to the target divided image is selected from an image processor that processes an adjacent divided image that is a divided image adjacent to the target divided image. Acquisition means for acquiring;
An adding unit that generates a composite image by adding an image of an end adjacent to the end acquired by the acquiring unit to an end of the target divided image;
Image processing means for performing image processing on the composite image generated by the adding means;
An image processing apparatus comprising: The image processing apparatus according to claim 1, wherein the image at the edge includes at least an image of a region that is referred to when the image processor performs image processing on the target divided image. When there are multiple adjacent divided images,
The extraction means extracts an edge image adjacent to the adjacent divided image from the target divided image, and sends the extracted edge image to an image processor that processes the adjacent divided image as an adjacent image. Do this for each divided image,
The acquisition means performs, for each adjacent divided image, a process for acquiring an image of an end portion adjacent to the target divided image of the adjacent divided image from an image processor that processes the adjacent divided image.
The adding means performs a process of adding an image of an end adjacent to the end to the end of the target divided image for each end of the target divided image adjacent to the plurality of adjacent divided images to generate a composite image. The image processing apparatus according to claim 1, wherein the image processing apparatus is an image processing apparatus. The image processing processor cuts out an end image added by the adding unit from a composite image subjected to image processing by the image processing unit, and outputs an image obtained by cutting the end image. The image processing apparatus according to claim 1, further comprising: The image processor is
Memory,
Write means for adding a dummy image to the target divided image based on a word boundary of the memory and writing the target divided image to which the dummy image is added to the memory;
Further comprising
The adding unit reads out the target divided image to which the dummy image is added from the memory by adding the edge image acquired by the acquiring unit, and cuts the dummy image from the read image. The image processing apparatus according to any one of claims 1 to 4, wherein the composite image is generated. A control method for an image processing apparatus having a plurality of image processing processors for performing image processing on a plurality of divided images obtained by dividing one image,
The image processor extracts an image of an edge adjacent to another divided image from a target divided image that is a divided image to be processed, and extracts the extracted edge image of the plurality of image processors. Among these, an extraction step of sending the other divided image to an image processor to be processed;
The image processor is adjacent to the target divided image of the adjacent divided image from an image processor that processes an adjacent divided image that is a divided image adjacent to the target divided image among the plurality of image processing processors. An acquisition step of acquiring an image of an end portion to be performed;
An addition step in which the image processor adds an image of an edge adjacent to the edge acquired in the acquisition step to an edge of the target divided image to generate a composite image;
An image processing step in which the image processor performs image processing on the composite image generated in the adding step;
A control method for an image processing apparatus, comprising: An image processing apparatus that performs image processing on first and second divided images obtained by dividing one image,
A first image processing processor that performs image processing on the input first divided image; and a second image processing processor that performs image processing on the input second divided image;
The first image processor is
An image of an end portion in the first divided image and an end portion adjacent to the second divided image is extracted as a first end image and sent to the second image processor. Sending extraction means;
Obtaining from the second image processor, an image of an end portion in the second divided image, which is an end portion adjacent to the first divided image, as a second end image Means,
An adding means for adding the second end image acquired by the acquiring means to an end of the first divided image adjacent to the second divided image to generate a composite image;
Image processing means for performing image processing on the composite image generated by the adding means;
An image processing apparatus comprising: A control method for an image processing apparatus having first and second image processing processors for performing image processing on first and second divided images obtained by dividing one image.
The first image processor extracts an end image adjacent to the second divided image as an end image in the first divided image as a first end image. Extracting to the second image processor;
The first image processor receives, from the second image processor, an end image in the second divided image, an end image adjacent to the first divided image, An acquisition step of acquiring as two end images;
The first image processor adds the second end image acquired by the acquisition unit to an end of the first divided image on the side where the second divided image is adjacent, An additional step of generating a composite image;
An image processing step in which the first image processor performs image processing on the composite image generated by the adding unit;
A control method for an image processing apparatus, comprising:

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