JP2012231351A - Image transmission device and image transmission method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image transmission device and image transmission method capable of correcting an error having occurred in a transmission line when the image transmission device which compresses and transmits image data transmits image data having an image size larger than an image size regulated currently.SOLUTION: The image transmission device which compresses and transmits image data is provided with: a compression processing part for compressing the image data; an error correction code generation part which calculates an error correction code for compressed image data; an output part which outputs the image data switching between a first period in which a data transmission amount per a prescribed time is a first data transmission amount and a second period in which the data transmission amount per the prescribed time is a second data transmission amount smaller than the first data transmission amount; and a control part for controlling the compression processing part, the error correction code generation part, and the output part. The control part performs control such that the image data compressed by the compression processing part is outputted from the output part in the first period and the error correction code generated by the error correction code generation part for the image data compressed by the compression processing part is outputted from the output part in the second period.

Description

  The technical field relates to transmission and reception of video information.

  In recent years, the number of pixels handled in digital image processing has been increasing year by year as broadcasting HD (High Definition: 1920 × 1080 pixels) has increased and image sensors of digital video cameras have increased in number.

  As a method for transmitting such image data between devices, there are the HDMI (High-Definition Multimedia Interface (registered trademark No. 2664032)) standard, the DisplayPort (trademark) standard established by VESA (Video Electronics Standards Association), and the like.

  In the above-mentioned HDMI data transmission system, Patent Document 1 describes that “a non-compressed video signal or a compressed video signal obtained by compressing a non-compressed video signal with a compression system that can be supported by a receiving device”. For selective transmission, a video signal having a desired bit rate can be satisfactorily transmitted within the transmission bit rate of the transmission path ”(see Patent Document 1 [0048]), and for the compression method,“ data compression ” Each of the units 121-1 to 121-n compresses the uncompressed video signal output from the codec 117 with a predetermined compression ratio, and outputs the compressed video signal. -n constitutes a video signal compression unit, and each of the data compression units 121-1 to 121-n performs a data compression process with a different compression method. RLE (Run Length Encoding) ”,“ Wavelet ”,“ SBM (SuperBit Mapping (registered trademark No. 3284640)) ”,“ LLVC (Low Latency Video Codec) ”,“ ZIP ”, etc. are considered” (Patent Document 1 [ [0077]).

  In HDMI, the data transmission format of TMDS (Transition Minimized Differential Signaling (registered trademark No. 4755037)) system is adopted for image data, and Patent Document 2 is shown as an example.

JP 2009-213110 A Japanese Patent Application No. 2003-559136

  However, none of the cited references considers transmission of data of a larger size image (also referred to as “video”; the same applies hereinafter).

In order to solve the above problems, for example, the configuration described in the claims is adopted.
The present application includes a plurality of means for solving the above-described problems. For example, in an image transmission apparatus that compresses and transmits image data, a compression processing unit that compresses image data, a compressed image data An error correction code generation unit that calculates an error correction code, a first period in which a data transmission amount per predetermined time is a first data transmission amount, and a data transmission amount per predetermined time is a first data transmission amount An output unit that switches and outputs a second period that is smaller, the compression processing unit, the error correction code generation unit, and a control unit that controls the output unit, and the control unit includes the compression process The image data compressed by the output unit is output from the output unit during the first period, and the error correction code calculated by the error correction code generation unit is pre-processed for the compressed image data by the compression processing unit. And outputs from the output unit to the second period.

  According to the above means, transmission of image data of a larger size is possible.

An example of an image transmission apparatus and an image receiving apparatus. An example of a compression processing unit. An example of a compression model code. An example of an error correction code generation unit. An example of a data transmission part. An example of a valid / blanking period of image data. An example of a data reception process part. An example of a decompression processing unit. An example of the unit of the image data to compress. An example of the flowchart which shows the concept of an expansion | extension process.

  Conventionally, in a transmission method for transmitting image data, by compressing and transmitting image data transmitted by an image transmission device, image data having a size larger than the currently specified image size is transmitted to the currently specified transmission path. In the case of transmission, the occurrence of an error in the transmission line was not considered. For this reason, even when an error of 1 bit occurs in the transmission path, the influence of the error extends to a plurality of pixels included in the unit of compression, so that many pixels may be erroneously displayed. . Hereinafter, embodiments for solving this problem will be described with reference to the drawings.

  Embodiments of an image transmission apparatus and an image reception apparatus according to this embodiment will be described below.

  FIG. 1 is a block diagram illustrating an image transmission system according to this embodiment, in which an image transmission apparatus 100 and an image reception apparatus 200 are connected by a cable 300.

  The image transmission apparatus 100 is an image transmission apparatus that compresses and transmits image data. The image data decoded so that the digital broadcast can be received and viewed, or the image data captured by a camera or the like is transmitted to another device using an HDMI cable or the like. This is an image recording / playback device that outputs image data. Examples of the image transmitting apparatus 100 include a recorder, a digital TV with a built-in recorder function, a personal computer with a built-in recorder function, a camcorder, and a mobile phone with a camera function.

  The image receiving apparatus 200 is a display device that inputs image data and outputs an image to a monitor using an HDMI cable or the like. Examples of the image receiving apparatus 200 include a digital TV, a display, and a projector.

  The cable 300 is a data transmission path for performing data communication such as image data between the devices of the image transmission device 100 and the image reception device 200. As an example of the cable 300, there is a wired cable corresponding to the HDMI standard or the DisplayPort standard, or a data transmission path for performing wireless data communication.

First, the configuration of the image transmission device 100 will be described.
The input units 101, 102, and 103 are input units for inputting image data to the image transmission apparatus 100. An example of image data input to the input unit 101 is digital broadcasting input as radio waves from a relay station such as a broadcasting station or a broadcasting satellite. The input unit 101 receives radio waves from a relay station such as this broadcasting station or broadcasting satellite.

  As an example of the image data input to the input unit 102, there are digital broadcasting distributed via a network using an Internet broadband connection, information content, and the like.

  As an example of the image data input to the input unit 103, there is digital broadcast or digital content recorded on an external recording medium connected to the input unit 103. Examples of an external recording medium connected to the input unit 103 or a recording medium 108 built in the image transmission apparatus 100 include an optical disk, a magnetic disk, and a semiconductor memory.

  The tuner reception processing unit 105 is a reception processing unit that converts an input radio wave into a bit stream. Here, the radio wave of the RF band (Radio Frequency) is frequency-converted to an IF band (Intermediate Frequency) and does not depend on the reception channel. A modulation operation applied to the demodulated bit stream for transmission as a fixed band signal is demodulated.

  As an example of the bit stream, there are an MPEG2 transport stream (hereinafter referred to as MPEG2-TS), a bitstream of a format conforming to MPEG2-TS, and the like. The subsequent bit stream will be described with MPEG2-TS as a representative.

  The tuner reception processing unit 105 further detects and corrects a code error occurring during transmission, and after the descrambling of the error-corrected MPEG2-TS, a program for viewing or recording is multiplexed. One transponder frequency is selected, and the bit stream in the selected one transponder is separated into audio and video packets of one program.

  The MPEG2-TS from the tuner reception processing unit 105 is supplied to the stream control unit 111. The stream control unit 111 includes a PTS (Presentation Time Stamp) that is time management information from the received packet and a standard decoding of the MPEG system in order to maintain an interval when the tuner reception processing unit 105 receives the packet. An internal STC (System Time Clock) is detected, and a time stamp is added at a timing corrected according to the detection result. The packet with the time stamp added is supplied to either one or both of the decoder 112 and the recording media control unit 107.

  The data path of the decoder 112 corresponds to processing when viewing image data, and the data path of the recording media control unit 107 corresponds to processing when recording image data on a recording medium. Another input of the stream control unit 111 is MPEG2-TS input from the input unit 102 via the network reception processing unit 106. The data path is an input unit that acquires digital broadcast or digital content distributed via a network.

  Furthermore, as another input of the stream control unit 111, an external recording medium connected to the input unit 103, or a digital broadcast or digital content recorded on the recording medium 108 built in the image transmitting apparatus 100, There is MPEG2-TS read by the recording media control unit 107. The stream control unit 111 selects at least one of these inputs and outputs it to the decoder 112.

  The decoder 112 decodes the MPEG2-TS input from the stream control unit 111 and outputs the generated image data to the display processing unit 113. The display processing unit 113 performs, for example, OSD (On Screen Display) superimposition processing or enlargement / reduction processing on the input image data, and outputs the result to the compression processing unit 114.

  The compression processing unit 114 performs simple compression processing on the image data from the display processing unit 113 and outputs the image data to the data transmission unit 115.

  The data transmission unit 115 converts the image data into a signal in a format suitable for cable transmission and outputs the signal from the output unit 116. An example of a signal in a format suitable for cable transmission is described in the HDMI standard. In HDMI, TMDS (Transition Minimized Differential Signaling (registered trademark No. 4755037)) data transmission format is adopted for image data.

  The input unit 104 is an input unit for inputting a signal for controlling the operation of the image transmission apparatus 100. An example of the input unit 104 is a remote control receiver. A control signal from the input unit 104 is supplied to the user IF 109. The user IF 109 outputs a signal from the input unit 104 to the control unit 110. The control unit 110 controls the entire image transmission apparatus 100 according to the signal from the input unit 104. An example of the control unit 110 is a microprocessor. Image data from the image transmission device 100 is supplied to the image reception device 200 via the cable 300.

Next, the configuration of the image receiving apparatus 200 will be described.
The input unit 201 receives a signal in a format suitable for cable transmission. The signal input to the input unit 201 is supplied to the data reception processing unit 205.

  The data reception processing unit 205 performs processing for converting a signal in a format suitable for cable transmission into predetermined digital data, and outputs the converted digital data to the expansion processing unit 206.

  The decompression processing unit 206 decompresses the compression processing performed by the compression processing unit 114 in the image transmission apparatus 100, generates image data, and outputs the image data to the display processing unit 207.

  The display processing unit 207 performs display processing on the input image data. Examples of display processing include OSD superimposition processing, enlargement / reduction processing for conversion to the resolution of the display unit 208, frame rate conversion processing, and the like. The output of the display processing unit 207 is output to the display unit 208.

  The display unit 208 converts the input image data into a signal that matches the display method and displays it on the screen. Examples of the display unit 208 include a display unit such as a liquid crystal display, a plasma display, and an organic EL (Electro-Luminescence) display.

  The input unit 202 is an input unit for inputting a signal for controlling the operation of the image receiving apparatus 200. An example of the input unit 202 is a remote control receiver. A control signal from the input unit 202 is supplied to the user IF 203. The user IF 203 outputs a signal from the input unit 202 to the control unit 204. The control unit 204 is a control unit that controls the entire image receiving apparatus 200 in accordance with a signal from the input unit 202.

FIG. 2 is a block diagram illustrating an example of the configuration of the compression processing unit 114.
The input unit 130 is an input unit for inputting image data to the compression processing unit 114. The input image data is supplied to the correlation detection unit 132, the horizontal compression unit 133, and the vertical compression unit 134.

  FIG. 9 is a diagram illustrating an example of image data input to the input unit 130. A luminance signal of n pixels in the horizontal direction and m lines in the vertical direction is shown. In the case of the 444 format, the color difference signal has the same format as the luminance signal. As an example of the number of pixels n and the number of lines m, there are so-called full HD images with n = 1920 and m = 1080 and so-called 4k2k images with n = 3840 and m = 2160.

  Here, the unit of the image data compressed by the compression unit 114 is assumed to be 1 pixel in the horizontal direction and k pixels in the vertical direction. Reference numerals 501 and 502 show examples of l = 32 and k = 1, and are constituted by data of 32 pixels continuous in the same line. The horizontal compression unit 133 compresses this image data unit.

  On the other hand, reference numerals 503 and 504 show examples of l = 16 and k = 2, and are composed of 16-pixel data continuous between two lines that rise and fall. The vertical compression unit 134 compresses this image data unit. That is, k1 and k2 (k1 <k2) image data units having different numbers of k pixels in the vertical direction are prepared, the horizontal compression unit 133 compresses the k1 image data unit, and the vertical compression unit 134 compresses the k2 image data unit. .

If k is large, the amount of line memory increases, the circuit cost increases, the processing time increases, and the video display is delayed. In the following description, an example in which cost and processing time are suppressed by using k1 = 1 and k2 = 2 will be used. In addition to the horizontal compression unit 133 and the vertical compression unit 134, a compression unit having a different k3 is added, and the output of three or more compression units can be selected and used to further increase the compression efficiency. 422 format color difference signal In this case, the U component and V component of the color difference signal become nested data for each pixel. For example, at 4k2k, the U component and V component may be combined and handled as image data of n = 3840 and m = 2160. In general, since the correlation between U components and V components is high, the U component and the V component are separated and handled as n = 960 and m = 1080, so that the unit of image data to be compressed only with the same component is obtained. Compression efficiency can be increased.

  The correlation detection unit 132 calculates the frequency component in the horizontal direction and the vertical direction of the image data and detects which component has high correlation. Correlation detection includes, for example, a detection method of calculating a difference value between pixels in the horizontal and vertical directions in addition to calculation of frequency components.

  The horizontal compression unit 133 includes a compression circuit that compresses a plurality of image data in the horizontal direction. As an example of the compression method, the Hadamard transform is calculated in the horizontal direction, and the calculation result is configured by an encoded compression method or the like.

  The vertical compression unit 134 includes a compression circuit that compresses a plurality of pieces of image data in the vertical direction. As an example of the compression method, as a unit of image data for compressing image data of 2 lines in the vertical direction and 16 pixels in the horizontal direction, a difference is first taken in the vertical direction, and then a difference is taken in the horizontal direction. The result is configured by a compression method for encoding the result.

  The compression ratio of the horizontal compression unit 133 and the vertical compression unit 134 may be any compression method that can compress the compressed image data from about 2/3 to about 1/2 of the original image data (however, The present invention is not limited to this compression rate).

  The unit of image data to be compressed by the horizontal compression unit 133 and the vertical compression unit 134 is composed of the number of pixels that reduces the amount of delay due to compression processing. As an example of the unit of image data to be compressed, 32 pixels have been described as an example. However, a unit of 64 pixels or 128 pixels may be used.

  The selection unit 135 selects the output of the horizontal compression unit 133 or the vertical compression unit 134 according to the detection result of the correlation detection unit 132 and supplies the selected output to the error correction code generation unit 136. The selection unit 135 may select the smaller output data amount of the horizontal compression unit 133 and the vertical compression unit 134 instead of the detection result of the correlation detection unit 132.

  The error correction code generation unit 136 calculates an error correction code for each unit of image data to be compressed, and outputs the compressed image data and the error correction code to the encoding unit 137. One of error correction methods includes a CRC (Cyclic Redundancy Check) method and a parity check method.

  The encoding unit 137 outputs the compressed image data during a later-described effective period 406 of the image data before compression, and outputs a flag indicating a compression method and an error correction code during the subsequent horizontal blanking period 404. Further, as another method, when all of the compressed image data for one line, the flag indicating the compression method, and the error correction code can be transmitted within the effective period 406 for one line, within the effective period 406 It may be transmitted.

  The output unit 138 outputs the compressed image data, the flag indicating the compression method, and the error correction code from the encoding unit 137.

  The input unit 131 switches the control mode of each block according to the control signal of the control unit 110.

  Since the above configuration does not require complicated arithmetic processing, it becomes a small circuit, and an error correction code addition function can be realized at low cost.

  FIG. 3 is a diagram illustrating a code example of the compression model. The compression model indicates a compression method of the compression processing unit 114, and includes a horizontal compression unit 133 and a vertical compression unit 134. The compression model code is a signal for indicating which compression method the image data is compressed. When compressed by the horizontal compression unit 133, “0” is indicated, and when compressed by the vertical compression unit 134, “1” is indicated.

FIG. 4 is a block diagram illustrating an example of the configuration of the error correction code generation unit 136. The input unit 150 receives compressed image data. The compressed image data is input to the delay unit 152 and the error correction code adding unit 153. The error correction code adding unit 153 performs a cyclic operation on the input compressed image data using a generator polynomial.
An example of a generator polynomial is
(Equation 1) G (X) = X ¹⁶ + X ¹² + X ⁵ +1
There is. This generator polynomial takes an exclusive OR for each bit in the input image data and performs a cyclic operation. The unit of calculation is a unit of image data to be compressed.

  The input unit 151 receives a signal indicating a period during which compressed image data is input and supplies the signal to the timing generation unit 154. The timing generation unit 154 counts the compressed image data valid period and outputs a signal indicating that the calculation for the unit of image data to be compressed has been processed to the data holding unit 155 as a data holding signal.

  The data holding unit 155 receives digital data and a data holding signal, and holds the digital data input at the timing when the data holding signal becomes valid. The data holding signal is a signal from the timing generation unit 154, and the digital data is a calculation result from the error correction code adding unit 153.

  The delay unit 152 is a delay circuit for adding a delay time generated by the processing of the error correction code adding unit 153 and the data holding unit 155 to the data path from the input unit 151 to the output unit 156. Examples of the delay unit 152 include a flip-flop and a delay element.

  The output of the delay unit 152 is output from the output unit 156. The output of the data holding unit 155 is output from the output unit 157.

  The output from the output unit 156 is output during the effective period 406 in which the image data described in FIG. 6 is transmitted, and the output from the output unit 157 is output during the horizontal blanking period 404 in which the image data described in FIG. 6 is not transmitted. Is done.

FIG. 5 is a block diagram illustrating an example of the configuration of the data transmission unit 115.
The input unit 170 outputs the compressed image data to the serializer 174. The input unit 172 receives a clock of image data and outputs the clock to the PLL 173 and the output unit 177.

  The PLL 173 generates a clock obtained by multiplying or dividing the input clock. Examples of multiplication include 5 times and 10 times the frequency of the input clock. The clock generated by the PLL 173 may be one type of clock or two types of clocks. An example of one type of clock is 10 times the input clock. Examples of the two types of clocks include a first clock speed that prioritizes the amount of data transmission and a second clock speed that is slower than the first clock speed that prioritizes lowering the frequency of error occurrence. is there. As an example of the speed, the first clock speed is multiplied by 10 of the input clock, and the second clock speed is multiplied by 5 of the input clock.

  The multiplied clock generated by the PLL 173 is output to the serializer 174. The serializer 174 serializes the RGB or YUV compressed image data of the input image data into three 1-bit data with a clock multiplied by 10 and outputs the serial data to the level conversion unit 175.

  As an example of serialization, 8-bit RGB or YUV image data is output in the order of MSB or LSB from the top with a 10-fold clock.

The level conversion unit 175 outputs a signal in a format suitable for cable transmission via the output unit 176. An example of a format suitable for standardized cable transmission is a TMDS differential signal format. In this format, since it is not necessary to transmit image data during the image blanking period, the data to be serialized by the serializer 174 is used only for 4 bits in the 10-fold clock, and the remaining 6 bits are not used.
It is possible to increase the strength against transmission errors and transmit data other than image data.

  Further, by using two types of clocks, the same effect can be obtained by reducing the clock generated by the PLL 173 to ½ or less of the clock for transmitting image data.

  FIG. 6 is a diagram illustrating an effective region in which image data for one frame period is superimposed and a blanking period in which image data is not superimposed.

  A region indicated by 400 indicates a vertical period, and the vertical period 400 includes a vertical blanking period 401 and a vertical effective period 402. In the vertical blanking period, there is a VSYNC signal as a vertical blanking signal. The VSYNC signal is a 1-bit signal in which 1 is set between the number of lines defined from the top of the vertical blanking period 401 and 0 is set between the other vertical blanking periods and the vertical effective period 402. An example of the prescribed number of lines is 4 lines.

  An area indicated by 403 indicates a horizontal period, and the horizontal period 403 includes a horizontal blanking period 404 and a horizontal effective period 405. The HSYNC signal is a 1-bit signal in which 1 is set between the number of pixels defined from the head of the horizontal blanking period 404 and 0 is set between the other horizontal blanking periods and the horizontal effective period 405. An example of the prescribed number of pixels is 40 pixels.

  An effective period 406 indicates an area surrounded by a vertical effective period 402 and a horizontal effective period 405, and image data is allocated to this period. The blanking period 407 is an area surrounded by a vertical blanking period 401 and a horizontal blanking period 404.

  In the present embodiment, in the above configuration, the compressed image data is transmitted during the effective period 406, and the error correction code of the previous line is transmitted during the next horizontal blanking period 404 of the line. In the blanking period 407, data obtained by packetizing audio data and other attached data is transmitted, so that it is not necessary to transmit image data as in the effective period 406.

  An example of the data transmission amount of audio data is linear PCM audio (maximum 192 kHz / 24 bits), and the data transmission amount is about 4.6 Mbps. On the other hand, as an example of the data transmission amount of image data, there is a display size of 1920 pixels, vertical 1080 lines, a signal bit accuracy of 8 bits, a signal format of luminance and color difference 422 format, and a data transmission amount of 2 Gbps. . In the present embodiment, this image data is compressed to, for example, 1/2 of 1 Gbps or 2/3 of 1.33 Gbps.

  When the data transmission amount per predetermined time between the audio data and the image data is compared, the transmission amount of the audio data is small. Therefore, the audio data is packetized and fits in a data amount that can be divided and transmitted in the horizontal blanking period.

  Further, with respect to the clock multiplied by 10 input to the serializer 174, all 10 bits are not used as data, and the data to be transmitted can be limited by 4 bits.

  A method of sending the audio data with a reliable packet in the horizontal blanking period 407 with respect to the effective period 406 of FIG. 6 is disclosed in, for example, Japanese Patent Publication No. 2005-514873.

With this configuration, since the error correction code is included in the packet data in the blanking period, it is possible to correct an error occurring in the transmission path, and the error resistance is enhanced. In addition, the data for data transmission of the packet in the blanking period is configured to be transmitted to two physically different channels, and the channel to be transmitted is switched every certain time. Since the other channel is not affected by the error, the data error can be corrected. The error correction rate has an improvement effect of ^{10-14 in} the horizontal blanking period as compared to ^{10-9 in the} horizontal effective period.

  As one of the packets in the blanking period, an error correction code is packetized. As an example of the number of packets, a case where the number of pixels in the horizontal period is 2200 and the number of pixels in the horizontal effective period is 1920 will be described.

  If the size of an image to be compressed is 64 pixels (luminance 32 pixels, color difference 32 pixels), the size of the error correction code (2 bytes) per line needs to be 120 bytes.

  Since there is a capacity capable of transmitting 28 bytes per packet, the size can be transmitted with 5 packets. Since there are 280 pixels in the horizontal blanking period, 8 packets can be superimposed. With this configuration, an error correction code can be further transmitted in the horizontal blanking period separately from the voice packet (one packet).

  With the configuration described above, error resistance due to data transmission is increased with respect to compressed image data, and error detection and error correction can be performed.

  Although not shown, the image receiving apparatus 200 is equipped with a ROM that stores EDID (Enhanced Extended Display Identification Data) indicating the performance of the image receiving apparatus 200. Information for determining whether or not the image receiving apparatus 200 supports compression / decompression may be added to the ROM. As a result, the image transmission apparatus 100 reads information for determining whether or not it supports compression / decompression from the ROM storing the EDID of the image reception apparatus 200, and if it is a compatible apparatus, the compressed image data If the device is non-compatible, the image can be transmitted in a conventional size without being compressed, and compatibility with an image reception device not compatible with compression processing can be maintained.

  In addition, the user can be notified by displaying on the display unit 208 that the image receiving apparatus is incompatible with compression and has a conventional image size.

  In addition, when the image transmission apparatus 100 is used as a portable device, the power consumption of the image transmission apparatus 100 affects the continuous use time because it is a battery-driven apparatus. In this case, image data can be compressed and transmitted to reduce the amount of data transmission and reduce power consumption. This effect is achieved by adding a function such as “power saving mode” as an operation mode of the image transmission apparatus 100, and when power is supplied from the outside, the image transmission apparatus 100 is transmitted by non-compressed image data and driven by a battery. In this case, the continuous use time can be set longer by compressing and transmitting the image data.

FIG. 7 is a block diagram illustrating an example of the configuration of the data reception processing unit 205.
The input unit 220 outputs the signal converted by the level conversion unit 175 of the image transmission apparatus 100 to the level conversion unit 222. The level conversion unit 222 converts the signal level-converted by the image transmission apparatus 100 into a digital signal and outputs the digital signal to the deserializer 223. As an example of level conversion, a differential signal is converted into a single-ended signal.

  The input unit 221 inputs the clock output from the image transmission apparatus 100 and outputs the clock to the PLL 224. The PLL 224 generates a clock that is 10 times the input clock during the valid period 406, and similarly generates a clock that is 10 times the input clock during the blanking period 404 and outputs the generated clock to the deserializer 223. The PLL 224 outputs a pixel clock used in the image receiving apparatus 200 from the output unit 226.

  The deserializer 223 parallelizes the serialized data with the clock from the PLL 224 and outputs it from the output unit 225. The deserializer 223 parallelizes all 10-times clock data during the effective period, and uses only 4 bits of the 10-times clock during the blanking period.

FIG. 8 is a block diagram illustrating an example of the configuration of the decompression processing unit 206. FIG. 10 is a flowchart showing the processing concept of the decompression processing unit 206.
The input unit 250 is a data input unit of the decompression processing unit 206. The data input to the input unit 250 includes HSYNC (FIG. 10A) and VSYNC indicating a synchronization signal of image data, image data compressed in the valid period 406, and the previous line in the horizontal blanking period 404. There are error correction codes and compression model codes (FIG. 10B).

  HSYNC and VSYNC are supplied to the timing generation unit 251. The timing generation unit 251 controls the counter based on the input HSYNC and VSYNC, the timing of the vertical blanking period 401, the vertical effective period 402, the horizontal blanking period 404, the horizontal effective period 405, the effective period 406, etc. 252, the timing necessary for controlling the error detection and correction unit 255 and the selection unit 261 is generated and output.

  The compressed image data, the line error correction code, and the compression model code are supplied to the selection unit 252. The selection unit 252 is a selection unit that separates input data from the timing generation unit 251 into two signals at the switching timing. When the signal from the timing generation unit 251 is the horizontal blanking period 404, the selection unit 252 outputs the input data to the code detection unit 253, and when the signal from the timing generation unit 251 indicates the valid period 406, Input data is output to the line memory 254. By this processing, the error correction code and the compression model codes 512 and 514 are supplied to the code detection unit 253, and the compressed image data 511, 513 and 515 are supplied to the line memory 254.

The code detection unit 253 is a code detection unit that detects an error correction code and a compression model code from input data. The error correction code and the compression model code exist for each unit of the compressed image data, and each is output to the error correction unit 255 (FIG. 10C). The compression model code is also output to the selection unit 258.
The line memory 254 is a line memory for outputting the compressed image data by delaying it by one line. The output of the line memory 254 is output to the error correction unit 255 (FIG. 10 (d)).

  The error correction unit 255 calculates the same error correction code as the error correction code generation unit 136 for each unit of the image data compressed from the image data input from the line memory 254. The calculation result is compared with the error correction code input from the code detection unit 253, and if the comparison result is different, an error correction process is performed. An example of error correction processing is CRC calculation.

  Alternatively, only error detection may be performed, and errors may be interpolated in subsequent processing. The output of the error correction unit 255 is supplied to the horizontal expansion unit 256 and the vertical expansion unit 257. The horizontal decompression unit 256 and the vertical decompression unit 257 are decompression units that decompress the compression method installed in the image transmission apparatus 100, decompress the image data, and output the image data to the selection unit 258.

  The selection unit 258 refers to the compression model code supplied from the code detection unit 253 for each unit of image data to be compressed. If the value is 0, the output of the horizontal expansion unit 256 is selected. For example, the output from the vertical extension unit 257 is selected and output to the selection unit 261, the data holding unit 259, and the second line memory 260.

The data holding unit 259 holds image data continuous in the horizontal direction and outputs the image data to the selection unit 261. The line memory 260 has the same function as the line memory 254, and outputs an output obtained by delaying input image data by one line to the selection unit 261 (FIG. 10 (f)).
The selection unit 261 is a selection unit that selects one of the three input image data. The selection unit 261 determines which data to select and output based on the signal from the error correction unit 255. The selection unit 261 selects the image data from the selection unit 258 when the signal from the error correction unit 255 indicates no error. When the signal from the error correction unit 255 indicates that there is an error and is compressed in the horizontal direction, the data on the right side stored in the data holding unit 259 is selected and calculated in the vertical direction. In this case, the data one line before stored in the line memory 260 is selected (FIG. 10E).

  With this configuration, even when an error occurs, it is possible to replace image data with high correlation, so that it is possible to reduce the influence of the transmission error on the image. In addition, since the unit of image data to be compressed is a dozen pixels, the range of pixels to be replaced is reduced, so that the influence of transmission errors can be reduced. Further, the processing delay due to compression / decompression can be suppressed by one line as shown in FIG.

  According to the present embodiment described above, image data having a size larger than the currently specified image size is transmitted to the currently specified transmission path by compressing and transmitting the image data transmitted by the image transmission apparatus. In addition, it is possible to perform image transmission with higher error tolerance by adding error detection and correction codes to a region with higher error resistance than the image data transmission region.

  In addition, when transmitting image data of the image size currently specified, the data transmission amount per predetermined time or the data transmission clock can be lowered, so that the frequency of occurrence of errors can be lowered, and A highly reliable system can be constructed against errors in the transmission path.

  In addition, even when an error occurs in the transmission path and complete error correction cannot be performed, a system that performs error processing in which image quality deterioration due to an error is not noticeable can be realized.

100 image transmission equipment
101,102,103,104,130,131,150,151,170,172,201,202,220,221,250 Input section
105 Tuner reception processor
106 Network reception processor
107 Recording media controller
108 Recording media
109,203 user IF
110,204 Control unit
111 Stream controller
112 decoder
113,207 Display processing section
114 Compression processing section
115 Data transmission section
116,138,156,157,176,177,225,226,262 Output section
200 Image receiver
205 Data reception processor
206 Decompression processing unit
208 Display
223 Deserializer
253 Code detector
254,260 line memory
255 Error correction section
256 Horizontal stretch
257 Vertical extension
259 Data holding part
300 cables
132 Correlation detector
133 Horizontal compression section
134 Vertical compression section
135,252,258,261 selector
136 Error correction code generator
137 Encoder
152 Delay part
153 Error detection flag addition part
154,251 timing generator
173,224 PLL
174 Serializer
175,222 Level converter
400 vertical period
401 Vertical blanking period
402 Vertical validity period
403 horizontal period
404 horizontal blanking period
405 Horizontal effective period
406 Validity period
407 Blanking period
501,502,503,504 Unit of image data to compress
511,513,515 Compressed image data
512,514 error correction code and compression model code

Claims (7)

In an image transmission device for compressing and transmitting image data,
A compression processing unit for compressing image data;
An error correction code generator for calculating an error correction code for the compressed image data;
A first period in which a data transmission amount per predetermined time is a first data transmission amount;
An output unit for switching and outputting a second period in which the data transmission amount per predetermined time is less than the first data transmission amount;
The compression processing unit, the error correction code generation unit, and a control unit that controls the output unit,
The control unit outputs the image data compressed by the compression processing unit from the output unit in the first period,
An image transmission apparatus, wherein the error correction code calculated by the error correction code generation unit is output from the output unit in the second period for the image data compressed by the compression processing unit. The image transmission apparatus according to claim 1,
The image transmission apparatus according to claim 1, wherein the second period for outputting the error correction code calculated by the error correction code generation unit is a horizontal blanking period. The image transmission apparatus according to claim 1,
The compression unit is a detection unit that detects the horizontal and vertical correlation of the image data, a horizontal compression unit that performs compression processing in the horizontal direction, a vertical compression unit that performs compression processing in the vertical direction,
A selection unit that outputs either one of the output of the horizontal compression unit and the output of the vertical compression unit and a code indicating a compression method;
An image transmission apparatus for controlling an output of a selection unit in accordance with an output of the detection unit. In an image transmission method for compressing and transmitting image data,
Compress the image data, calculate the error correction code of the compressed image data,
A first period in which a data transmission amount per predetermined time is a first data transmission amount;
Switch and output the second period in which the data transmission amount per predetermined time is less than the first data transmission amount,
Outputting the compressed image data in the first period;
An image transmission method for outputting an error correction code for the compressed image data in the second period. The image transmission method according to claim 4,
2. The image transmission method according to claim 1, wherein the second period for outputting the error correction code is a horizontal blanking period. The image transmission method according to claim 4,
Calculating a first error correction code for the data of the second period;
Compressing the image data, calculating a second error correction code for the compressed image data,
A first period in which a data transmission amount per predetermined time is a first data transmission amount;
Switch and output the second period in which the data transmission amount per predetermined time is less than the first data transmission amount,
Outputting the compressed image data in the first period;
The image transmission method according to claim 1, wherein the first and second error correction codes are output in the second period. The image transmission method according to claim 4,
The compression processing has two or more compression methods, the first compression processing is horizontal compression processing that performs compression processing in the horizontal direction, and the second compression processing is vertical compression that performs compression processing in the vertical direction. This is a process for detecting whether the image data to be compressed is image data having a high correlation in the horizontal or vertical direction, and a horizontal compression process and a vertical compression process are performed based on the output of the correlation detection. An image transmission method characterized by outputting a signal for selecting either one of them and indicating which compression method is used for compression during the horizontal blanking period.

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