JP2013211608A - Video receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video receiver which receives compressed video data, can perform scaling processing even with a small memory amount and suppresses electrical power consumption required when a partial video of the compressed video data is accessed.SOLUTION: A video receiver includes: a data reception section which receives data U in which a first data size Z after compression, which is obtained by compressing data of a fist data size P before compression, is guaranteed to be equal to or less than a data size B determined by a worst compression rate; and a memory which stores the data U. The data U is stored for each memory area W in a fixed size which becomes equal to or more than B of the memory.

Description

  The present invention relates to an apparatus for receiving video.

  As background art of this technical field, for example, there is Patent Document 1. Patent Document 1 states that “[Problem] Eliminating trade-off between high image quality and low power consumption while considering user convenience [Solution] Data compression unit (Encode) 13 has transmitted Data compression is performed on the data by using, for example, coding compression used in image coding theory such as DCT processing, quantization processing, Wavelet transform, etc. At this time, the host processor 20 performs the above-described data compression. When performing coding compression, the compression rate (the amount of data after compression / the amount of data before compression) when the compression efficiency is reduced is designated as the upper limit value (worst value: worst ratio) of the compression rate. With reference to the value, the data compression unit 13 compresses the compression rate so that the compression rate is equal to or lower than the upper limit (worst value) (≦ Worst Ratio). “When the data is stored in the external memory (SDRAM) 16, the worst compression rate (Worst Ratio) × n burst (n is an integer) instructed by the data compression (Encode) unit 13 in the image data area” The amount of data that was n bursts of data before compression is stored for each area delimited by ().

JP 2010-171609 A

  There is a configuration in which an image or video stored in a certain device is transmitted to another device and displayed. For example, HDMI (HIGH DEFINITION MULTIMEDIA INTERFACE) (registered trademark) is used for connection between devices, and video data including digitally sampled pixel values, that is, a so-called baseband signal is transmitted. With the recent increase in resolution and resolution of images and videos, there is a possibility that so-called 4K2K video signals composed of horizontal 4096 pixels and vertical 2048 pixels are transmitted at 30 frames / second. The bit rate of the video at this time reaches 4096 × 2048 × 8 × 30 = 2,013,265,920 bps when one pixel is sampled at 8 bits. This is about four times the bit rate of 497,664,000 bps generated at HD (High definition) image quality of horizontal 1920 pixels, vertical 1080 pixels, and 30 frames / second.

  After receiving the 4K2K video signal, the device that receives the video stores it in the memory and scales it to a resolution that matches the display panel. When performing, for example, an FIR (Finite Impulse Response) filter in each of the horizontal direction and the vertical direction, it is common to perform processing by having as many line memories as the number of taps of the vertical FIR filter. For example, when a 5-tap vertical FIR filter is used, a memory of 4096 × 4 × 8 = 131,072 bits is required.

  Among devices that receive video, there are so-called embedded devices that require low power consumption because they are driven by batteries for a long time, and devices that use a limited amount of memory to reduce costs. For example, some digital photo frames are battery powered. When a 4K2K video signal is received as a baseband signal and stored in a memory, it is necessary to process the above bit rate, and the power consumption is increased as compared with HD processing. Further, when the panel to be displayed is, for example, horizontal 800 pixels and vertical 600 pixels, the above line memory is required even when a 4K2K video signal is received and scaled. Further, when the video is rotated and displayed, or when the video is cut out and displayed, it is necessary to perform processing after storing the baseband signal in the memory, which increases power consumption.

  In addition, when data loss occurs due to noise generated randomly during transmission, there is a possibility that the next line can be restored, but there is a problem that the number of affected pixels increases due to the length of one line. .

  The technique of Patent Document 1 discloses a technique of compressing video data and cutting out and accessing it. However, a technique for transmitting compressed data in accordance with the processing configuration of a video receiver, and a transmission path error. No technology for increasing resistance is disclosed.

  In view of the above problems, the present invention provides a video receiving apparatus that receives compressed video data and can perform scaling processing with a small amount of memory. It is another object of the present invention to provide a video receiving apparatus that suppresses power consumption necessary for accessing a partial video of compressed video data.

The following is a brief description of an outline of typical inventions disclosed in the present application.
(1) A video receiving apparatus that receives video data, and receives data obtained by compressing data having a first data size to a second data size equal to or smaller than a data size determined by a preset worst compression rate. The data compressed to the second data size received by the receiving unit and the data receiving unit is stored in an external storage unit for each fixed size area that is equal to or larger than the data size determined by the worst compression rate. And a control unit that controls the video receiving apparatus.

  According to the present invention, it is possible to provide a video receiving apparatus capable of scaling processing with a small amount of memory. In addition, it is possible to provide a video receiving apparatus that suppresses power consumption required when accessing a partial video of compressed video data.

It is a figure which shows the structure of the video transmission apparatus in a 1st Example, and a video reception apparatus. It is a figure which shows compression of the video data by a data compression part in a 1st Example. It is a figure which shows arrangement | positioning of the video data in an external memory in a 1st Example. It is a figure which shows arrangement | positioning of the video data in a line memory in a 2nd Example. It is a figure which shows the structure of the video transmitter in a 2nd Example, and a video receiver. It is a figure which shows the compressed video data output from a video transmission apparatus in a 1st Example. It is a figure which shows arrangement | positioning of the video data in an external memory in a 1st Example. It is a figure which shows the structure of the video transmitter in a 3rd Example, and a video receiver. It is a figure which shows the read-out position of the video data in the external memory of a video transmission apparatus in a 3rd Example.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic diagram illustrating an example of a video transmission / reception system, which includes a video transmission device 100 and a video reception device 200. The video transmission apparatus 100 is configured by appropriately using a decoder 110, a data compression unit 120, a memory I / F unit 130, a data transmission / reception unit 140, and a control unit 150, and has a configuration connected to an external memory 160. Have. The control unit 150 controls the entire video transmission device 100 and outputs a control signal.

  The decoder 110 receives a compressed stream such as MPEG-2 from the outside of the video transmission apparatus 100, performs decoding processing, and outputs video data. The data compression unit 120 receives the video data from the decoder 110, performs data compression according to the control signal of the worst compression rate received from the control unit 150 for each predetermined data length, and stores the compressed video data and stuffing data described later in the memory I / O. Request writing to F130. The memory I / F unit 130 arbitrates a write request from the data compression unit 120 and a read request from the data transmission / reception unit 140, and reads / writes data from / to the external memory 160. The data transmission / reception unit 140 receives a control signal of the worst compression rate from the control unit 150, outputs a signal having a data size determined by the worst compression rate, and uses the compressed video data and stuffing data as the output of the video transmission device 100.

The data compression of the data compression unit 120 will be described in detail with reference to FIG. In this embodiment, the data size Q for data compression is 64 bits (8 pixels). The data compression unit 120 receives the video data from the decoder 110 and divides the data into a plurality of data blocks such as a data block 310, a data block 320,. Next, the data compression unit 120 performs data compression by a technique such as DCT + quantization or ADPCM + bit shift using the control signal of the worst compression rate. The worst compression rate is a compression rate (data size after compression / data size before compression) when the compression efficiency is the lowest when performing data compression.
The data compression unit 120 performs feedback control based on the output bit amount to control the quantization accuracy so that the bit amount of the compressed video data to be output is equal to or less than the data compression data size Q × the worst compression rate. In this embodiment, when the data compression unit 120 performs data compression with the worst compression rate being 75%, the data size after compression is 48 bits (= 64 bits × 75%). In FIG. 2, the data block 310 is compressed into a data block 340 having a size of 32 bits, the data block 320 is compressed into a data block 350 having a size of 40 bits, and the data block 330 is compressed into a data block 360 having a size of 42 bits.

  Next, a method for storing the data blocks 340 to 360 in the external memory 160 will be described with reference to FIG. FIG. 3 shows a memory area of the external memory 160. When the external memory 160 is configured by SDRAM, the address is represented by a combination of row and column. An area indicated by row = 000 and column = 00 in the figure indicates a burst length (64 bits) which is a write length of one time. The data compression unit 120 bundles the compressed data blocks U in units of M = 8 and stores them in the area X. The area 410 has an area of 64 bits × 8 × 75% = 384 bits, and can be stored in a size C × M (48 bits × 8 = 384 bits) when all eight data blocks have the worst compression ratio of 75%. It has a size. In this embodiment, the area is set to 384 bits equal to C × M. However, an area of 384 bits or more may be taken and stored depending on the configuration of the external memory 160. The data compression unit 120 stores the first 8 data blocks in the area 410. If the length of the 8 data blocks is less than the area 410, the data compression unit 120 fills the area with the stuffing data (for example, 0xFF), and compresses the next 8 data blocks. Stored in 420. When the data compression of one line of the video data is completed and the data block of the next line is compressed, one row address is added and stored in the area 450.

  The data transmitter / receiver 140 reads out the compressed video data and stuffing data written in the area 410 and outputs them. Subsequently, the area 420 is sequentially read and output.

Next, the operation of the video reception device 200 in FIG. 1 will be described. The video receiving apparatus 200 is configured by appropriately using a data transmission / reception unit 210, a data decompression unit 220, a line memory 230, a scaler unit 240, a memory I / F unit 250, a display unit 260, and a control unit 270, and is connected to an external memory 280. With the configuration.
The data transmitting / receiving unit 210 receives a signal having a data size determined by the worst compression rate output from the video transmitting apparatus 100, and compressed video data and stuffing data, and outputs a signal having a data size determined by the worst compression rate to the control unit 270. The compressed video data and the stuffing data are output to the data decompression unit 220 based on the address control signal of the external memory 280 output from the control unit 270.
The control unit 270 controls the entire video receiving apparatus 200 and outputs a control signal.
The data decompression unit 220 reads the compressed video data stored in the external memory 280 via the memory I / F unit 250, performs decompression processing according to the worst compression rate control signal, and outputs the video data to the line memory 230.
The line memory 230 is a memory for storing video data.
The scaler unit 240 reads the video data from the line memory 230, performs scaling processing according to the scaling magnification control signal received from the control unit 270, and outputs the scaled video data.
The memory I / F unit 250 arbitrates the data transmission / reception unit 210, the write request of the scaler unit 240, and the read request of the display unit 260, and reads / writes the external memory 280.
The display unit 260 reads the scaled video data stored in the external memory 280 through the memory I / F unit 250 and performs display.
Further, FIG. 3 showing the compressed video data storage of the video transmission apparatus will be described with reference to the external memory 280 since it is stored in the same manner. The control unit 270 calculates the data size C at the time of the worst compression of the compressed video data following the header from the worst compression rate. The data transmission / reception unit 210 communicates with the video transmission device 100 and stores the compressed video data in an area 410 having a data size of C × M or more using a predetermined number M of data blocks in a transmission unit. The data transmitter / receiver 210 stores the compressed video data received after storing the M compressed video data and the stuffing data in the area 420 by advancing the column address by C × M. When the compressed video data for one line is stored, the data transmitting / receiving unit 210 adds one row address and stores it in the area 450.

  In the above example, when the control unit 270 calculates the address that the data transmitting / receiving unit 210 writes to the external memory 280, the row and column addresses are calculated from the size C of the compressed video data obtained from the minimum compression rate and the number of data blocks M in the transmission unit. Was calculated. The present invention is not limited to the above, and the compressed video data may be calculated using the coordinate information included in the header, and the row and column addresses may be calculated and output to the external memory 280 via the memory I / F unit 250.

  In the example shown in FIG. 3, the transmission unit is bundled in units of eight data blocks after compression. However, the effect of the present invention can be obtained even in units of one data block as shown in FIG. In FIG. 2, the data size before compression is P, and the data size after compression is Z. It is assumed that the compressed data size Z does not exceed the data size B determined by the worst compression rate. In FIG. 7, when the transmission unit is a data size W greater than or equal to B, the data compression unit 120 stores Z in the memory area of the area 411.

According to the present embodiment, compared to the case where video data is transmitted without compression, the amount of data is reduced along with compression, so that power consumption associated with bus driving can be reduced.
In the system using the video transmission apparatus and the video reception apparatus according to the present embodiment, the maximum size of the compressed video data flowing in the transmission path per unit time can be determined before transmission, which facilitates the system design of the transmission path. .

  The data transmission / reception unit 140 of the video transmission device 100 in this embodiment transmits the worst compression rate in advance, so that the video reception device 200 determines the buffer amount when storing the compressed video data in the external memory 280 from the worst compression rate in advance. Can be calculated. According to the present embodiment, the buffer amount of the video receiving apparatus 200 can be made a constant size, and buffer management becomes easy. In addition, it is possible to provide a video transmission apparatus that can have an appropriate capacity according to the compressed video data to be transmitted and has high memory utilization efficiency.

  The control unit 270 in the video reception apparatus 200 of the present embodiment can calculate in advance the buffer amount for storing the compressed video signal calculated from the worst compression rate from the worst compression rate. According to the present embodiment, the buffer amount of the video receiving apparatus 200 can be made a constant size, and buffer management becomes easy. In addition, it is possible to provide a video receiving apparatus that can have an appropriate capacity according to the compressed video data to be transmitted and has high memory utilization efficiency.

  The video receiving apparatus 200 according to the present embodiment can prepare a buffer having a certain size according to the data amount calculated from the worst compression rate transmitted from the video transmitting apparatus 100. According to the present embodiment, it is possible to provide a video receiving apparatus that can secure an appropriate buffer according to the compressed video data transmitted by the video transmitting apparatus 100 and facilitates buffer management.

  The video receiver 200 of this embodiment stores compressed video data in units of a fixed size memory area obtained from the data size C at the worst compression rate and the number of data blocks M in the transmission unit. When an arbitrary position of the video data is cut out and displayed, the compressed video data can be read out by calculating a memory area close to the cut start coordinate. According to the present embodiment, it is possible to provide a video receiving apparatus that reduces the memory access amount of the video receiving apparatus 200 and consumes less power due to memory access.

  The data compression unit 120 of the video transmission apparatus 100 in this embodiment outputs compressed video data corresponding to the worst compression rate by performing data compression according to the control signal for the worst compression rate. The data compression unit 120 not only outputs the compressed video data stored in the external memory 160 in advance, but also transmits video that writes the compressed video data to the external memory 160 even when uncompressed video is input to the video transmission device 100. Equipment can be provided.

The data transmission / reception unit 140 in the video transmission apparatus 100 according to the present embodiment outputs a signal having a data size determined by the worst compression ratio before transmitting the compressed video data, but is determined by the worst compression ratio at predetermined intervals. A data size signal may be output. For example, when the worst compression rate is changed during the transmission of the compressed video data by outputting a signal having a data size determined by the worst compression rate for each transmission unit of a frame indicating one screen of the video, the video receiving device 200 Can change the buffer amount secured in the external memory 280, and can reduce the buffer usage of the external memory 280.
In addition, the video transmission apparatus 100 can change the worst compression rate during transmission of compressed video data, can select a compression rate suitable for the input video, and reduce power consumption by reducing the bit amount of the communication channel. Can be provided. Alternatively, the frame synchronization signal may be output at predetermined intervals. By outputting the frame synchronization signal, even when data is lost due to a data transmission / reception error between the video transmission device 100 and the video reception device 200, the head of the frame can be detected and the error can be recovered.

The data transmission / reception unit 140 in the video transmission apparatus 100 of the present embodiment may perform transmission by adding information indicating coordinates to the header for each compressed data block Y. An example is shown in FIG. As a result of the data compression performed by the data compression unit 120 with the worst compression rate being 75%, the data block 310 is compressed into the data block 340, the data block 320 is compressed into the data block 350, and the data block 330 is compressed into the data block 370. To do. The data transmitting / receiving unit 140 adds a header 610 to the data block 340 and a header 620 to the data block 350, and outputs the data block 340.
Since the information indicating the coordinates is added to the header, the transmission unit can be associated with the coordinates of the video, so that the data transmitting / receiving unit 210 can restore the normal reception of the video including the coordinate position for each compressed data block. Thus, it is possible to provide a video transmission apparatus that can recover from an error in a frame even when an error occurs during transmission.

When the data transmission / reception unit 140 in the video transmission apparatus 100 of this embodiment transmits compressed video data in transmission units, the difference between the data size Y of the compressed video data to be transmitted and the data size C obtained from the worst compression rate is the header data. If it is smaller than the length, it may be transmitted without adding a header. This will be described with reference to FIG. The data length of the data block 370 is 48 bits, which is equal to 48 bits, which is 75% of the worst compression rate. When transmission is performed with a header added, the data size becomes 48 bits or more. In this case, the header 630 is transmitted without being added to the data block 370.
By changing the presence or absence of the header according to the length of the compressed video data, it is ensured that the compressed video data to be transmitted is less than the worst compression rate regardless of the input video even when the header is added. For this reason, it is possible to provide a video transmission apparatus in which power consumption does not increase as compared with the case where no header is added.

  When the data compression unit 120 stores the data block in the external memory 160, the data compression unit 120 stores the amount of compressed video data written in each transmission unit in the external memory 160, and the data transmission / reception unit 140 stores the compressed video data amount in each transmission unit. Alternatively, the compressed video data may be read out and output, and then the difference between the read data amount of the transmission unit and the read compressed data amount may be output as stuffing data. By storing the amount of compressed video data for each transmission unit in the external memory 160, the data transmitting / receiving unit 140 can read only the portion of the video compressed data from the external memory 160. Since the data transmission / reception unit 140 does not read out the stuffing data, the memory access amount is reduced, so that it is possible to provide a video transmission apparatus that suppresses power consumption related to transmission.

  The data compression unit 120 compresses the input video data so as not to use the correlation with data other than the transmission unit to which the data belongs when the data compression is performed using the correlation between the data like ADPCM. Also good. By closing the correlation of data in units of transmission, the video receiving apparatus 200 can decode video in units of transmission of compressed video data, so that the video does not affect multiple transmission units, and the video can be less affected by the error. A transmission device can be provided.

  The data transmitting / receiving unit 210 in the video receiving apparatus 200 of the present embodiment detects the header included in the compressed video stream, and calculates the address of the external memory 280 from the coordinate data included in the header. Provided is a video receiving apparatus in which a data transmission / reception unit 210 performs address calculation using coordinate data, so that even if an error occurs during transmission of compressed video data, a video receiver that can normally recover from the error when the next header is detected is provided. Can do.

  The video receiver 200 receives the compressed video data and stores it in the memory for each region W that is M times the size of the data size C defined by the minimum compression rate, so that the data size C determined by the video transmitter is used. In addition, the data size W of the storage unit suitable for memory storage can be selected on the receiver side, and writing with high memory use efficiency according to the write burst length of the external memory 280 can be performed.

  In the second embodiment of the present invention, a method for displaying compressed video data received by the video receiver 200 will be described. The configuration is shown in FIG. 5, components that perform the same operations as the components of the video transmission device 100 and the video reception device 200 shown in FIG.

The data transmission / reception unit 211 receives a data size signal and header determined by the worst compression rate output from the video transmission device 100, and compressed video data, and outputs a data size signal determined by the worst compression rate to the control unit 270. The compressed video data is output to the data decompression unit 220 based on the address control signal of the external memory 280 output from the control unit 270.
The data decompression unit 221 reads the compressed video data stored in the external memory 280 via the memory I / F unit 250, performs decompression processing according to the coordinates received from the control unit 270, and the control signal of the worst compression rate, and the video data Is output to the line memory 230.
The display unit 261 receives the video data output from the scaler unit 240 and displays it.

  The data compression data size Q of the video data set by the control unit 150 in the data compression unit 120 is set to be smaller than the horizontal size of the video data input to the data compression unit 120.

  When the data decompression unit 221 performs reading, the control unit 270 designates the address of the external memory 280 according to the capacity of the line memory 230. FIG. 4 shows the memory area of the line memory 230 and will be described. In FIG. 4, the line memory 230 is composed of 640 pixels in the horizontal direction and 4 lines in the vertical direction. The data decompression unit 221 receives the compressed video data from the external memory 280 for each reading unit of the memory I / F unit 250, and writes the compressed video data to the line memory area 500 when the decompression is performed. Subsequently, the control unit 270 transmits a control signal designating the address of the external memory 280 to the data decompression unit 221 so as to read out the compressed video data in the horizontal direction, and the data decompression unit 221 stores the video data as a result of the decompression in the line memory. Write to area 510. Thereafter, similarly, the data decompression unit 221 reads the compressed video data in the horizontal direction. When the data decompression unit 221 writes to the line memory area 520, the control unit 270 controls the data decompression unit 221 to specify the address of the external memory 280 so as to read the compressed video data that is one line below the line memory area 500. The data decompression unit 221 writes the video data as a result of the decompression into the line memory area 550.

  In the present embodiment, the compressed video data is stored in the external memory 280 based on the coordinate information included in the header, and the control unit 270 reads the compressed video data in a strip shape according to the capacity of the line memory 230, so that the scaler unit Reference numeral 241 can perform scaling processing with 640 pixels and 4 lines as processing units. Even when the compressed video data stored in the external memory 280 has a resolution exceeding 640 pixels and 4 lines, it is possible to perform the scaling process by performing the read control of the compressed video data described in this embodiment. . In addition, since the transmission unit can be associated with the coordinates of the video, it is possible to provide a video receiving apparatus that can cut out and transmit the compressed video data at an arbitrary position.

  Also in the video transmission apparatus 100, the control unit 150 knows the capacity of the line memory 230 from the information of the line memory capacity transmitted by the control unit 270 through the data transmission / reception unit 210 and the data transmission / reception unit 140, and reads the data into the data transmission / reception unit 140. May be specified individually. For example, when the line memory 230 has only 512 bits (64 pixels) per line, the control unit 150 outputs a control signal for transmitting the region 410 to the data transmission / reception unit 140, and then sets a region 450 corresponding to a pixel one line below the region 410. Outputs the control signal to be transmitted. When the control unit 150 outputs a control signal for outputting the area 490 corresponding to the bottom of the video data, the control unit 150 outputs a control signal for outputting the area 420 to the data transmitting / receiving unit 140.

  As described above, the data transmission / reception unit 140 outputs strip-shaped data with 64 pixels as one line, so that the video reception device 200 can be used in the horizontal direction even when the scaler unit 240 has only 512 bits (64 pixels) per line. It is possible to perform a scaling process in the vertical direction of an image having a size exceeding 64 pixels. With this configuration, even when the number of pixels per line of the line memory included in the video reception device 200 is smaller than the video data output from the video transmission device 100, the scaling process can be performed.

  In the third embodiment of the present invention, a data receiving method of the video receiving apparatus will be described. In this embodiment, for example, a mode is considered in which a part of the captured data is viewed on a portable terminal such as a smartphone with a limited amount of memory by connecting to a surveillance camera system that captures and records with high definition such as 4K2K.

  The configuration is shown in FIG. 8, components that perform the same operations as the components of the video transmission device 100 and the video reception device 200 illustrated in FIG. 1 are denoted by the same reference numerals and description thereof is omitted.

  The data transmission / reception unit 212 receives a signal of a data size determined by the worst compression rate output from the video transmission device 100 and a header, compressed video data and stuffing data, and sends a signal of a data size determined by the worst compression rate to the control unit 270. The compressed video data is output to the data decompression unit 222.

  The data decompression unit 222 receives the compressed video data output from the data transmission / reception unit 212, performs decompression processing according to the coordinates received from the control unit 270 and the control signal of the worst compression rate, and outputs the video data to the line memory 230.

  The control unit 270 transmits the coordinate position of the video data to the video transmission device 100 through the data transmission / reception unit 212 according to the capacity of the line memory 230.

  The data transmitting / receiving unit 140 of the video receiving apparatus 100 receives the coordinate information and outputs it to the control unit 150. The control unit 150 calculates the coordinates of the external memory 160 that is closest to the coordinate information, reads the compressed video data through the memory I / F unit 130, and transmits the compressed video data to the video reception device 200 through the data transmission / reception unit 140.

  In the configuration of FIG. 8, the memory I / F unit 250 and the external memory 280 in FIG. 5 do not exist.

  The control method of the coordinate position designated by the control unit 270 will be described with reference to FIG. FIG. 9 shows a memory area of the external memory 160 of the video transmission apparatus. As in FIG. 3, the address is represented by a combination of row and column. In the present embodiment, a case will be described in which the control unit 270 reads out image data of an area of row = 050 to 052 and column = 30 to 34 corresponding to the capacity of the line memory 230 from the compressed video data. The control unit 270 obtains resolution information of video data input to the video transmission device 100 through the data transmission / reception unit 212. The control unit 270 first outputs coordinate information of a position corresponding to row = 050 and column = 30 to the video transmission device 100. When the data transmission / reception unit 212 receives the compressed video data, the control unit 270 reads the coordinate information described in the header information, confirms that it matches the transmitted coordinate information, and outputs the compressed video data to the data decompression unit 222. To do. The control unit 270 receives the width and height information of the compressed video data received from the data decompression unit 222. The control unit 270 calculates the coordinate information of the position corresponding to row = 050 and column = 31 from the width information of the compressed video data, outputs the coordinate information to the video transmission apparatus 100, and thereafter performs the same processing until column = 34. . When the data transmission / reception unit 212 receives the compressed video data at the coordinate position corresponding to column 34, the control unit 270 calculates the coordinate information at the position corresponding to row = 051 and column = 30 where the row address is one greater. And output to the video transmission apparatus 100. Thereafter, the control unit 270 similarly transmits coordinate information until it receives compressed video data of coordinate information at a position corresponding to row = 053 and column = 34.

  In this embodiment, the control unit 270 transmits the coordinate information of the compressed video data in accordance with the capacity of the line memory 230, so that a part of the compressed video data of the video transmission device 100 can be received. Even when the video transmitting apparatus 100 has a resolution exceeding the capacity of the line memory 230, the scaling process can be performed by performing the read control of the compressed video data described in the present embodiment. Compared with the configuration shown in the second embodiment, the external memory 160 is not required, so that power consumption can be suppressed. In addition, since the compressed video data is received only for the part necessary for scaling, the operation rate of the data receiving unit 212 is reduced, so that power consumption can be suppressed.

  Further, when the data decompression unit performs data decompression, if a data reception error is detected, the data transmission / reception unit 212 receives the compressed video data by transmitting the coordinate information that has failed to be received to the video transmission device 100 again. It is possible to increase resistance to errors.

  As mentioned above, although embodiment concerning this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to this example. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims. It is understood that it belongs to.

  For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. In addition, for example, a part of the configuration of a certain embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of a certain embodiment.

DESCRIPTION OF SYMBOLS 100 Video transmission apparatus 110 Decoder 120 Data compression part 130 Memory I / F part 140 Data transmission / reception part 150 Control part 160 External memory 200 Video reception apparatus 210 Data transmission / reception part 220 Data expansion part 230 Line memory 240 Scaler part 250 Memory I / F part 260 Display unit 270 Control unit 280 External memory

Claims (4)

A video receiving device for receiving video data,
A data receiver that receives data obtained by compressing data of the first data size to a second data size equal to or smaller than a data size determined by a preset worst compression rate;
A control unit that controls to store the data compressed to the second data size received by the data receiving unit in an external storage unit for each fixed size area that is equal to or larger than the data size determined by the worst compression rate When,
A video receiving apparatus comprising: The video receiving device according to claim 1,
The video receiving apparatus, wherein the data receiving unit detects a leading position of the compressed data after variable length coding. The video receiving device according to claim 1 or 2,
When storing the data compressed to the second data size consisting of an integer of 1 or more, the control unit stores the data for each fixed size area that is M times or more the data size determined by the worst compression rate. A video receiving device characterized by controlling as described above. The video receiver according to any one of claims 1 to 3,
The data receiving unit receives coordinate information including a horizontal coordinate and a vertical coordinate of the video data;
The video receiving apparatus according to claim 1, wherein the control unit performs control so as to be stored in the external storage unit based on the coordinate information.

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