JP5883026B2 - Video data transmission / reception method, video transmission device, and video reception device - Google Patents

Description

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

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

  Regarding the method of transmitting these video data between devices, DisplayPort (VESA registered trademark or VESA (registered trademark of HDMI Licensing, LLC)) standard or VESA (Video Electronics Standards Association) Trademark) standards.

  In the HDMI video signal transmission method, Japanese Patent Application Laid-Open No. H10-228561 describes “Uncompressed video signal or a compressed video signal obtained by compressing the uncompressed video signal with a compression method that the receiving apparatus can handle. The video signal of a desired bit rate can be transmitted satisfactorily within the transmission bit rate of the transmission path ”(see Patent Document 1 [0048]), and the compression method is“ data The compression units 121-1 to 121-n respectively compress the uncompressed video signal output from the codec 117 with a predetermined compression ratio, and output the compressed video signal. 121-n constitutes a video signal compression unit, and each of the data compression units 121-1 to 121-n performs data compression processing using different compression methods. "RLE (Run Length Encoding)", "Wavelet", "SBM (Super Bit Mapping (registered trademark of Sony))", "LLVC (Low Latency Video Codec)", "ZIP", etc. are considered "(Patent Document 1) [0077]).

  Also, in HDMI, video data adopts a data transmission format of TMDS (Transition Minimized Differential Signaling (registered trademark of Silicon Image, Inc.)), and Patent Document 2 is shown as an example.

JP 2009-213110 A JP 2005-514873 A

  However, none of the prior art documents considers reducing power consumption in transmission or reception of video data.

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 the video data transmission / reception method in which the video data transmitted from the video transmission device is received by the video reception device, the video transmission device transmits the video data. The clock frequency of the data output from the video transmission device is changed based on the video data to be processed.

  As another example, in a video transmission device that transmits video data to a video reception device, the video transmission device has an output circuit that outputs video data, and after the video data is transmitted from the output circuit, power consumption in the output circuit It is characterized by reducing.

  According to the above means, video data can be transmitted with less power consumption.

An example of the video transmission part of 1st Example, and a video reception part. An example of the compression video signal and input video signal of 1st Example. An example showing the timing of sending a packet and video data of the first embodiment. An example showing timing of sending a packet and video data of the second embodiment. An example of the compression video signal period of 1st Example. An example of the video transmission apparatus and video reception apparatus of 1st Example. An example of the information packet header regarding the compression of 1st Example. An example of the information packet body regarding the compression transmitted in the vertical packet period of 1st Example. An example of the information packet body regarding the compression transmitted in the horizontal packet period of 1st Example. An example of EDID description of the video receiver of 1st Example. An example of the video transmitter of 3rd Example, and a video receiver. An example of Opcode of the communication message of 3rd Example. An example of Parameter of the communication message of 3rd Example. An example of communication message transmission / reception of the third embodiment

  Conventionally, there is an uncompressed video data transmission system as a video data transmission system that minimizes the delay time, but a high-speed transmission path is required to send large-size video data. On the other hand, a method of compressing and transmitting video data has been proposed, but the compression rate changes depending on the video data when trying to maintain a constant high image quality, so it matches the expected compressed video data A high-speed transmission path is required, and for this reason, the power consumption of the high-speed transmitter and the high-speed receiver is large, and it is difficult to reduce the power consumption.

  In the following embodiments, when video data transmitted by the video transmission device is compressed and transmitted in video data transmission, the transmission clock frequency is controlled in real time or valid data is transmitted based on the compressed video data. In addition, during a period of no reception, the operation mode is switched to a mode in which power consumption is suppressed by reducing the clock frequency of the transmission unit or the reception unit, stopping the clock, or stopping the power supply. Hereinafter, this embodiment will be described with reference to the drawings.

  The video transmission device and video reception device in this embodiment will be described below.

  FIG. 6 is a block diagram illustrating a video transmission system according to the present embodiment, in which a video transmission device 901 and a video reception device 903 are connected by cables 902, 905, and 906.

  The video transmission device 901 is a video transmission device that transmits video data. The video data decoded so that the digital broadcast can be received and viewed, or the video data captured by a camera or the like can be transmitted to another device via an HDMI cable or the like. A device that outputs data. Examples of the video transmission device 901 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 video reception device 903 is a display device that inputs video data and outputs an image to a monitor using an HDMI cable or the like. Examples of the video reception device 903 include a digital TV, a display, and a projector.

  Although the cables 902 and 905 and 906 may be independent, handling them as bundled cables is convenient. A cable obtained by bundling cables 902, 905, and 906 is a data transmission path for performing data communication such as video data between the devices of the video transmission device 901 and the video reception device 903. As an example of the bundled cable, there is a wired cable corresponding to the HDMI standard or the DisplayPort standard. Further, instead of the bundled cables, data communication may be performed by a wireless method.

First, the configuration of the video transmission device 901 will be described.
Input units 911, 912, and 913 are input units for inputting video data to the video transmission apparatus 901. An example of video data that is input to the input unit 911 and processed by the tuner reception processing unit 915 is digital broadcasting that is input as radio waves from a relay station such as a broadcasting station or a broadcasting satellite. The input unit 911 receives radio waves from a relay station such as this broadcasting station or broadcasting satellite.

  Examples of video data that is input to the input unit 912 and processed by the network reception processing unit 916 include digital broadcasts distributed via a network and information content using a broadband connection of the Internet.

  An example of video data that is input to the input unit 913 and processed by the recording media control unit 917 is content recorded on an external recording medium connected to the input unit 913. Further, as an example of the video data processed by the recording media control unit 917, there is content recorded in the recording media 918 incorporated in the video transmission device 901. Examples of an external recording medium connected to the input unit 913 or a recording medium 918 built in the video transmission device 901 include an optical disk, a magnetic disk, and a semiconductor memory.

  The tuner reception processing unit 915 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 915 further detects and corrects a code error that occurs 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 915 is supplied to the stream control unit 921. The stream control unit 921 stores a PTS (Presentation Time Stamp) which 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 915 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 to which the time stamp is added is supplied to the decoder 922 in the viewing process, and to the recording medium control unit 917 at the time of recording on the recording medium.

  The content input to the input unit 912 is received by the network reception processing unit 916 and input to the stream control unit as MPEG2-TS.

  A digital broadcast or digital content recorded on an external recording medium connected to the input unit 913 or a recording medium 918 incorporated in the video transmission device 901 is read out as MPEG2-TS by the recording medium control unit 917. Are input to the stream control unit 921. The stream control unit 921 selects at least one of these inputs and outputs it to the decoder 922.

  The decoder 922 decodes the MPEG2-TS input from the stream control unit 921 and outputs the generated video data to the display processing unit 923. The display processing unit 923 performs, for example, OSD (On Screen Display) superimposition processing or enlargement / reduction processing on the input video data, and then outputs it to the video transmission unit 924.

  The video transmission unit 924 converts the video data into a signal in a format suitable for transmission and outputs the signal from the output unit 927. As an example of a signal in a format suitable for transmission, a format suitable for transmission by cable is described in the HDMI standard. In HDMI, the TMDS data transmission format is adopted for video data.

  The input unit 914 is an input unit for inputting a signal for controlling the operation of the video transmission apparatus 901. As an example of the input unit 914, there is a receiving unit for a signal transmitted from a remote controller, a button provided on the apparatus main body, or the like. A control signal from the input unit 914 is supplied to the user IF 919. The user IF 919 outputs a signal from the input unit 914 to the control unit 910.

  The control unit 910 controls the entire video transmission device 901 according to the signal from the input unit 914. An example of the control unit 910 is a microprocessor. Video data from the video transmission device 901 is supplied to the video reception device 903 via the cable 902.

  The reading unit 925 reads information regarding the video reception device 903 via the terminal 928. This information uses, for example, a configuration of EDID (Extended Display Identification Data) defined by VESA. Information about the read video advancing device 903 is transmitted to the control unit 910, and the control unit 910 determines the format of video data to be provided to the video receiving device 903 based on this information, and the display processing unit 923 and the video transmission unit 924 Control.

  The bidirectional communication unit 926 is a communication unit that exchanges messages with the video reception device 903 through the terminal 929, and the communication content is controlled by the control unit 910. By this message exchange, the video transmission device 901 and the video reception device 903 can perform a linked operation. For example, it is defined as CEC (Consumer Electronics Control) in the HDMI standard.

Next, the configuration of the video reception device 903 will be described.
The input unit 931 receives a signal in a format suitable for transmission. The signal input to the input unit 931 is supplied to the video receiving unit 935. The video receiving unit 935 converts a signal in a format suitable for transmission into video data and outputs the video data to the display processing unit 936.

  The display processing unit 936 performs display processing on the input video data. As an example of display processing, OSD superimposition processing, enlargement or reduction processing for conversion to the resolution of the display unit 937, frame rate conversion processing, high image quality processing (noise suppression, color correction, gradation correction, contour correction, etc.) and so on. The output of the display processing unit 936 is output to the display unit 937.

  The display unit 937 converts the input video data into a signal in accordance with the display method and displays it on the screen. As an example of the display unit 937, there is a display unit such as a liquid crystal display, a plasma display, or an organic EL (Electro-Luminescence) display.

  The input unit 934 is an input unit for inputting a signal for controlling the operation of the video reception device 903. As an example of the input unit 934, there is a receiving unit for a signal transmitted from a remote controller, a button provided on the apparatus main body, or the like. A control signal from the input unit 934 is supplied to the user IF 940. The user IF 940 outputs a signal from the input unit 934 to the control unit 941. The control unit 941 is a control unit that controls the entire video reception device 903 in accordance with a signal from the input unit 934.

  The EDID storage unit 938 is a block for storing information related to the video reception device 903, and outputs the relevant information from the terminal 932 when the video transmission device 901 requests reading. When the information regarding the video reception device 903 changes depending on the reception state of the video reception device, the stored information may be rewritten according to an instruction from the control unit 941.

  The bidirectional communication unit 939 is a communication unit that exchanges messages with the video transmission apparatus 901 through the terminal 933, and the communication content is controlled by the control unit 941. By this message exchange, the video transmission device 901 and the video reception device 903 can perform a linked operation.

  Next, the video transmission unit 924 of the video transmission device 901 and the video reception unit 935 of the video reception device 903 will be described with reference to FIG.

  FIG. 1 is a block diagram illustrating an example of a video transmission / reception unit according to this embodiment, in which the video transmission unit 11 and the video reception unit 21 are connected by cables including electric wires 311, 312, 313, and 314.

  The video transmission unit 11 is a video transmission unit that transmits video data input from a video signal source in the video transmission device.

  The video receiving unit 21 is a video receiving unit that receives video data transmitted from the video transmitting unit 11 via a cable and outputs the video data to, for example, a display unit in the video receiving device.

  A cable including the electric wires 311, 312, 313, and 314 is a data transmission path for performing data communication such as video data from the video transmission unit 11 to the video reception unit 21. As an example of this cable, 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 video transmission unit 11 will be described.
The additional information unit 116 is an information supply unit that provides additional information such as colorimetry and format information of video data transmitted by the video transmission unit 11, information related to video compression, and audio data. For example, information relating to video such as colorimetry and format information is obtained from a video signal source in a video transmission device having the video transmission unit 11, and information relating to video compression such as a video compression method and its compression parameters transmitted by the transmission unit 11 Provide combined additional information.

  The compression unit 114 is a compression encoding unit that compresses uncompressed RGB primary color video data or YCbCr luminance color difference video data input from a video signal source in the video device. The compression may be a reversible compression or an irreversible compression.

  The rearrangement unit 115 is a rearrangement unit that distributes the compressed video data output from the compression unit 114 to each transmission path. In general, when RGB primary color video data or YCbCr luminance color difference signals are compressed, the compression rate differs between RGB primary colors or YCbCr luminance color difference signals, resulting in an imbalance in data amount. The rearrangement unit 115 can improve the use efficiency of the transmission path by rearranging the compressed video data into the three transmission paths almost evenly. In addition, when the compressed video data is as small as 2/3 or less or 1/3 or less, it is possible to stop the data provision to one or two of the three systems to reduce power consumption. This rearrangement information is transmitted to the additional information unit 116 in order to inform the receiving side of the information on how the rearrangement has occurred in an information packet regarding the compressed video.

  Selection units 111, 112, and 113 select uncompressed video data input from a video signal source in the video apparatus, compressed video data rearranged by the rearrangement unit 114, and additional information provided by the additional information unit 116. It is the selection part to do. When the video transmission unit 11 transmits non-compressed video data, the non-compressed video data is selected during the video signal period, and additional information is selected during the blanking period. When the video transmission unit 11 transmits compressed video data, the compressed video data is selected during the video signal period, and additional information is selected during the blanking period.

  The additional information unit 116 stores or temporarily stores colorimetry, video format information, information about compressed video, and audio data, and provides data so that it can be transmitted as a packet during the return period.

  The clock control unit 117 is a control unit that creates a clock necessary for each unit based on a video clock input from a video signal source in the video device. When the video transmission unit 11 transmits uncompressed video data, for example, the video clock is used as a reference clock to the output circuit 124, and a clock obtained by multiplying it by 10 is provided to the serializers 125, 126, and 127.

  The same may be applied when the video transmission unit 11 transmits the compressed video data. For example, when the video data is 1 / n or less in the compression unit 114, a reference clock obtained by dividing the video clock by n is output to the output circuit 124. A clock obtained by multiplying the reference clock by 10 may be provided to the serializers 125, 126, and 127. By setting the clock frequency to 1 / n, the power consumption of the serializers 125 and 126 and 127 and the output circuits 121 and 122 and 123 can be reduced.

  Serializers 125, 126, and 127 are serializers that serialize parallel data output from the selection units 111, 112, and 113, respectively. For example, the TMDS method may be used.

  The output circuits 121, 122, and 123 are output circuits that output data input from the serializers 125, 126, and 127 to the electric wires 311, 312, and 313, respectively, according to a predetermined signal level and impedance. The output circuit 124 is an output circuit that outputs a clock input from the clock control unit 116 to the electric wire 314. To improve reliability, these output circuits include differential output, pre-emphasis that compensates in advance for high-frequency components attenuated by cables, and de-emphasis that attenuates low-frequency components that are less attenuated in cables. It may have a function.

  As described above, when the rearrangement unit stops providing data to one system or two systems, the serializer 126 or / and 127 that stops providing data and the clock to the output circuit 122 or / and 123 It is also possible to reduce power consumption by stopping supply or power.

Next, the configuration of the video receiver 21 will be described.
Input circuits 211, 212, 213, and 214 are input circuits that receive signals input from electric wires 311, 312, 313, and 314, respectively. For example, the differential signal may be received by a termination circuit having a predetermined impedance and converted to a predetermined signal level. Further, it may have a function such as an equalizer for compensating for a high frequency component attenuated by the cable.

  Deserializers 215, 216, and 217 are deserializers that convert serial data output from input circuits 211, 212, and 213 into parallel data, respectively. For example, TMDS data is restored.

  The PLL 218 is a phase lock loop (PLL) that generates a data clock and a video clock having a predetermined phase and frequency relationship from the reference clock output from the input circuit 214. For example, when receiving a TMDS reference clock, a data clock is generated by multiplying the reference clock by 10. The reference clock is also used as a video clock as it is.

  The information extraction unit 224 is a signal processing unit that extracts additional information such as colorimetry and format information of video data, information related to video compression, and audio data from the output data of the deserializers 215, 216, and 217.

  The clock control unit 219 is a control unit that generates a clock required by each unit in the video reception unit based on the reference clock input from the PLL 218 and a data clock obtained by multiplying the reference clock by 10. When the information extracted by the information extraction unit 224 indicates that the data clock frequency is 1 / n, the power consumption of the deserializer is reduced by setting the data clock frequency supplied to the deserializers 215, 216, and 217 to 1 / n. can do.

  The rearrangement unit 225 is a signal processing unit that rearranges the output data of the deserializers 215, 216, and 217 based on the rearrangement information extracted by the information extraction unit 224. When the rearrangement information indicates that there is no data in the predetermined system, the power supply to the corresponding input circuit 211 or 212, 213 and the deserializer 215 or 216.217 is stopped, or the corresponding one of the clock control unit 219 The data clock output may be stopped to reduce power consumption.

  The restoration unit 226 is a signal processing unit that restores the output data rearranged by the rearrangement unit 225 and outputs an uncompressed video signal.

  The selection units 221, 222, and 223 are selection units that switch and output the output data of the deserializers 215, 216, and 217 and the output data of the restoration unit 226, respectively. When uncompressed video data is received based on the information about the compressed video extracted by the information extraction unit 224, the output of the deserializers 215, 216, and 217 is selected, and when compressed video data is received The output of the restoration unit 226 is selected.

  The selection units 221, 222, and 223 supply uncompressed video data to a display unit or the like in the video reception device having the video reception unit 21.

  In this manner, high-definition video transmission with low power consumption can be realized by reducing the clock frequency of the video transmission unit or the video reception unit, stopping the clock, or stopping the power supply.

  The case where the clock frequency is 1 / n has been described above as an example, but the condition of n will be described below.

  Considering that the pull-in time of the PLL 218 of the video receiving unit 21 becomes long, it is not preferable to change n in video line units or frame units. Therefore, the minimum value m of n is determined based on the image quality required for the video content and the compression performance of the compression unit. When the reference clock obtained by dividing the video clock by m is supplied to the output circuit 124 and the data clock obtained by multiplying the video clock by 10 / n (or the reference clock is multiplied by 10 · m / n) is provided to the serializers 125, 126, and 127, the cable 314 Since the clock frequency transmitted at the time becomes constant, the PLL 218 of the video receiver 21 becomes a steady operation and becomes stable.

  Here, if n and m are integers, the frequency dividing operation is performed as described above, but may be a rational number. In the case of rational numbers, a PLL may be used instead of a frequency divider. On the receiving side, the data clock required by the deserializer is obtained by multiplying the reference clock by 10 m / n. If n / m is set to be an integer, PLL 218 performs the same multiplying operation as that at the time of transmission of uncompressed video data, and if it is divided by n / m by clock control unit 219, a deserializer is required. A stable data clock can be obtained.

  The PLL 218 also requires a PLL that multiplies the reference clock by m for reproducing the video clock. Considering this, the PLL 218 may multiply the reference clock by 10 m, and the clock control unit 219 may divide it by n to divide the data clock required by the deserializer by 10 to obtain the video clock. Good. In this case, m must be a rational number and n must be an integer.

  As described above, when m is a rational number and n / m or n is an integer, it can be seen that stable clock transmission is possible. The values of n and m may be described and transmitted in an information packet related to compression. In addition, it is necessary to determine in advance which of n / m and n should be used for transmission.

  The case where the reference clock output from the output circuit 124 is 1 / m of the video clock has been described as an example, but a predetermined independent fixed frequency may be used. For example, the DisplayPort standard uses a fixed frequency for the reference clock, the output circuit 124, the cable 314, and the input circuit 214 are omitted, and the reference clock is superimposed on the data. When a fixed frequency is used, the data clock may be used after being divided by n (n is an integer).

  FIG. 2 shows an input video (a) input to the video transmission unit 11, uncompressed transmission (b) or compressed transmission 1 (c), and compressed transmission 2 (output) from the video transmission unit 11 in the first embodiment. d) shows an example of the timing of the compressed transmission 3 (e). Reference numerals 551 and 553 denote horizontal video periods, and reference numerals 552 and 554 denote horizontal blanking periods. The timing of video data and additional data will be described with reference to FIG.

  The input video (a) is composed of video signals 506 and 507 in the horizontal video period and horizontal synchronization signals 501, 502 and 503 in the horizontal blanking period.

  The uncompressed video transmission (b) includes uncompressed video data 516 and 517 in the horizontal video period and audio data 511, 512, and 513 in the horizontal blanking period. Uncompressed video data 516 and 517 are serialized video signals 506 and 507 using, for example, the TMDS system. The audio packets 511, 512, and 513 are used to transmit the audio signal input to the video transmission unit 11 together with the input video (a), for example, as an audio packet determined by HDMI. Although not shown in the non-compressed video transmission (b), the horizontal synchronization data is similarly transmitted at the timing of the horizontal synchronization signals 501, 502, and 503.

  The compressed transmission 1 (c) is composed of compressed video data 526 and 527 that extend beyond the horizontal video period, information packets 521 and 522 and 523 relating to compression within the horizontal blanking period, and audio packets 511 and 512 and 513. The compressed video data 526 and 527 are assigned compressed video data transmission periods 561 and 563 longer than the horizontal video periods 551 and 553 for transmitting the uncompressed video data 516 and 517. This is because when lossless compression is assumed, the amount of data increases due to additional data indicating non-compressed data when the compression fails. When the amount of compressed video data is small, dummy data may be allocated for the remaining period of the compressed video data area.

  Information packets and voice packets related to compression, and other packets not shown are transmitted in the packet transmission periods 562 and 564. The packet transmission period is shorter than the horizontal blanking period. Since the horizontal synchronization signal cannot be transmitted in the compressed video data period, it is necessary to transmit the horizontal synchronization signal in the packet transmission period. The minimum packet transmission period is determined by a longer period of either the number of packets to be sent or the horizontal synchronization signal period. When the video clock and the transmission reference clock have the same frequency, for example, assuming that a total of 3 packets of 1 information packet and 2 audio packets related to compression are transmitted, the identification period 32 is 32 clocks per packet. A total of 128 clocks corresponds to the period. On the other hand, since the horizontal synchronization period is, for example, 88 clocks in the case of a 4k2k video signal, the minimum packet transmission period is a period corresponding to 128 clocks. For example, if the total number of horizontal pixels of a 4k2k video signal is 4400, the maximum compressed video data transmission period can be a period corresponding to 4272 clocks. Since the number of horizontal display pixels of the 4k2k video signal is 3840, the horizontal video period is equivalent to 3840 clocks. Therefore, the maximum compressed video data transmission period can be increased by about 11% from the horizontal video period.

  If information indicating a compressed video data transmission period is placed in an information packet related to compression, the length of the compressed video data transmission period of each video line can be changed. Since the video receiving unit needs a period to extract information indicating the compressed video data transmission period from the information packet related to compression and prepare for setting to receive the compressed video data, the information packet related to compression is transmitted from the start of the compressed video data transmission period. Since it is necessary to complete transmission by a predetermined number of clocks earlier, it is preferable to transmit a packet such as a voice packet prior to transmission.

  FIG. 5 is a diagram illustrating that the amount of compressed video data changes for each line when video data is compressed. 400 is a vertical period, 401 is a vertical packet period, 402 is a vertical video data period, 403 is a horizontal period, 404 is a horizontal packet period, 405 is a horizontal video data period, 411 is a vertical synchronization signal, 412 is a horizontal synchronization signal, and 407 408 is a packet transmission area, 409 is compressed video data, and 410 is no data. As described above, it is conceivable that the amount of compressed video data varies greatly in units of lines.

  Compressed transmission 2 (d) in FIG. 2 is an example when the compressed video data period is changed in line units. In the compressed transmission 1 (c), the compressed video data 526 and 527 using the periods 538 and 539 without the compressed data as dummy data were transmitted. In the compressed transmission 2 (d), the compressed video data 536 with a reduced transmission period was transmitted. 537 is transmitted. All or part of the serializers 125 and 126 and 127, the output circuits 121 and 122 and 123, the input circuits 211 and 212 and 213, and the deserializers 215 and 216 and 217 in FIG. By shifting to the power saving mode, power consumption can be reduced. For the transition to the power saving mode, it is preferable to use a technique such as stopping power supply to each block, reducing the power supply voltage, stopping the clock, and reducing the clock frequency. Even during the periods 538 and 539 when there is no compressed video data, the output circuit 124, the input circuit 214, and the PLL 218 are continuously operated, so that stable clock reproduction from the PLL can be continued even during the subsequent packet transmission period.

  Compressed transmission 3 (e) is an example of a case where the transmission clock of compressed video data is halved in a line where the amount of compressed video data is less than half. The transmission clock is a clock indicating a transmission unit of parallel compressed video data, and is 1/10 the frequency of the data clock used for the serializer in the TMDS system. The compressed video data 536 exceeding half of the maximum amount that the compressed video data can be transmitted is transmitted in the same manner as the compressed transmission 2 (d). Compressed video data 537 that is less than half of the maximum amount of compressed video data that can be transmitted is transmitted as compressed video data (clock half) 547 by halving the transmission clock and data clock frequency and doubling the time.

  During the transmission clock frequency half-life period 563, the clock control units 117 and 219 in FIG. 1 reduce the power consumption by halving the data clock frequency supplied to the serializers 125 and 126 and 127 and the deserializers 215 and 216 and 217. . Further, since the transmission speed is lowered, the reliability of the compressed video data is also improved. Information for halving the transmission clock frequency may be described in information packets 541, 542, and 543 regarding compression.

  The transmission clock frequency may be halved during the subsequent packet transmission period, but since the amount of transmission data during the packet transmission period is small, the transmission clock frequency may always be halved during the packet transmission period. Even in the compressed video data period 563 in which the transmission clock frequency is halved, the output circuit 124, the input circuit 214, and the PLL 218 are operated in a steady manner without changing the reference clock frequency, so that even in the transmission period immediately after the change of the transmission clock frequency, Stable clock recovery is continued from the PLL.

  During the period when there is no compressed video data, the power saving mode may be set as in the case of the compressed transmission 2 (d). The compressed transmission 3 (e) shows an example in which predetermined dummy data 548 and 549 are transmitted. For transmission / reception of dummy data, the output circuits 121 and 122 and 123 and the input circuits 211 and 212 and 213 are continuously operated, and all or part of the serializers 125 and 126 and 127 and the deserializers 215 and 216 and 217 are set in the power saving mode. do it. By continuously operating the output circuit and the input circuit by transmission / reception of dummy data, it is possible to expect stable operation of, for example, emphasis or an equalizer that takes time to enter a stable steady state.

  FIG. 3 shows an example of the timing for sending packets and video data. The time axis is enlarged centering on the packet transmission period of FIG. (B) corresponds to uncompressed transmission (b) in FIG. 2, and (C) corresponds to compressed transmissions 1 to 3 (c), (d), and (e) in FIG. Hereinafter, the timing of FIG. 3 will be described.

  Uncompressed video transmission (B) is a conventional transmission method. For example, the HDMI standard includes CTL Periods 626 and 628, Data island period 627, and Video Data period 629.

  The CTL period 626 includes non-data 611 in which no valid data exists and a preamble 613 indicating an attribute of the next period. Data island period 627 is composed of two packets, Packet 1 616 and Packet 2 617, and guard bands GB 614 and 618 arranged before and after the packets, respectively. The two packets are, for example, voice packets and correspond to the voice packets 511 or 512, 513 in the uncompressed transmission (b) of FIG.

  The CTL period 628 includes no data 619 and a preamble 620 indicating an attribute of the next period. The Video Data period 629 includes a guard band GB 621 and video data Video 622. Video data Video 622 corresponds to the uncompressed video data 516 or 517 in the uncompressed transmission (b) of FIG. Accordingly, the Video Data Period 629 is longer by the guard band GB 621 than the video period 553 of the uncompressed transmission (b) in FIG.

  The compressed video transmission (C) of this embodiment is composed of CTL Periods 646 and 648, Data island period 647, and Video Data periods 649 and 645, as in the conventional uncompressed video transmission (B). The difference from uncompressed video transmission (B) is that Packet 0 635 is added as an information packet related to compression before Packet 1 636, which is an audio packet, and the period occupied by the video data period Video 642 and 630 is increased. A guard band GB 632 indicating the end of the no-data period or the end of the clock frequency half-life period is added.

  For example, the information packet Packet 0 635 relating to compression is an information packet 542 relating to compression of the compressed transmission 3 (e) in FIG. 2, and the voice packet Packet 1 636 and Packet 2 637 are voice packets 512 of the compressed transmission 3 (e) in FIG. The video data Video 642 is the compressed video data 547 of the compressed transmission 3 (e) in FIG. 2, the video data Video 630 is the compressed video data 536 of the compressed transmission 3 (e) in FIG. 2, and the no data 631 is the compressed transmission 3 of FIG. This corresponds to the dummy data 548 of (e).

  After compression information packet Packet 0 635 indicating transmission clock frequency halved, video data period 649 guard band GB 641 and video data Video 642, followed by no data in CTL period and guard band GB (not shown) are transmitted. The clock frequency is halved. When the video data Video 630, no data 631, and the guard band GB 632 are targeted for transmission clock frequency halving, the transmission clock frequency halving is canceled from the subsequent preamble 633. Accordingly, stable packet transmission can always be maintained by always canceling the transmission clock frequency halved during the period from Preamble 633 to 640 including Data island Period 647. Furthermore, since the Data island period does not become long, there is an advantage that it is easy to ensure a long Data island Period period even when the compressed video data suddenly increases.

  The guard band GB 632 in the CTL Period 646 is provided for the purpose of reliably transmitting the Preamble 633 indicating the attribute of the next period, and the low power mode such as the transmission data stop in the no-data 631 and the transmission clock frequency halved. It will be easier to return from. Therefore, the guard band GB 632 may use a pattern that becomes “0101010101” after the clock frequency is halved and “0011001100” and “1100110011” after the clock frequency is halved so that the guard band GB 632 can be received both before and after the clock frequency is halved.

  The return timing from the low-power mode on the receiving side is, for example, a clock that is continuously transmitted even during the low-power mode based on the information about the maximum compressed video data period extracted from the information packet related to the previous compression. Obtained by counting the number.

  As video content protection, it is considered that encrypted video data is supplied only to a video receiving device that has been subjected to predetermined device authentication by the video transmitting device, and video data is not supplied to a video receiving device that cannot perform predetermined device authentication. It is done. Since the decryption key of the video data is synchronized during the device authentication, the configuration of the video receiving unit is simplified when the device authentication is performed during a period when the video data is not transmitted / received. For this reason, the device authentication is started during a period in which the video data is not transmitted / received, but it is considered that the authentication may not be completed during a period in which the video data is not transmitted / received. Furthermore, if device authentication is performed bidirectionally using a cable that is different from the cable used to transmit and receive video data, it becomes difficult to decrypt the code, and content protection can be enhanced.

  FIG. 7 shows an example of a header of an information packet related to compression. In the first header block HB0, a common header type 0Bh indicating that it is information relating to the compression coding transmission system of the present invention is described. Bits 4 to 7 of HB1 and Bits 0 to 6 of HB2 are set to 0 for future expansion. Bits 0 to 3 of HB2 indicate the version number of the data structure of this packet. 1 means. H / V shown in Bit 7 of HB2 identifies a data packet in units of lines or frames. H / V = “0” indicates a frame unit and is transmitted in the vertical packet period. When there is a frame in which the packet is lost on the receiving side, the packet data received immediately before is used. H / V = "1" is transmitted in the horizontal packet period, and when there is a frame in which the packet is lost on the receiving side, the packet data received immediately before is used. If there is no packet with HB0 = "0Bh" in the frame on the receiving side, it may be determined that the transmission is the conventional uncompressed video transmission.

  FIG. 8 shows an example of the body of an information packet related to compression. This is 28-byte data transmitted following the header shown in FIG. 7, and is the body of an information packet related to compression in units of frames of H / V = “0”. PB0 and PB1 indicate the number of effective lines of the compressed video data. PB2 and PB3 indicate the number of lines from the end of the compressed video data to the packet transmission, PB4 and PB5 indicate the number of lines for transmitting the vertical packet, and PB6 and PB7 indicate the number of lines from the packet transmission to the start of the compressed video data. Yes.

  PB8 and PB9 indicate the reference clock number of the maximum transmission period of the compressed video data, and correspond to the maximum values of Video Data Periods 649 and 645 in FIG. PB10 and PB11 indicate the number of reference clocks from the end of the maximum transmission period of the compressed video data to the packet transmission, and correspond to the minimum value of CTL Period 646 in FIG. PB12 and PB13 indicate the number of reference clocks in the horizontal packet transmission period, and correspond to Data island Period 647 in FIG. PB14 and PB15 indicate the number of reference clocks from the packet transmission to the start of the compressed video data, and correspond to the CTL Period 648 in FIG. PB16 indicates a compression method, and PB17 to PB27 are reserved areas for future expansion.

  FIG. 9 shows an example of the body of an information packet related to compression. This is 28-byte data transmitted following the header shown in FIG. 7, and is the body of an information packet related to compression in units of lines with H / V = “1”. PB0 and PB1 indicate the number of reference clocks in the effective data transmission period of the compressed video data, and correspond to Data island Period 649 in FIG.

  PB2 indicates a compression method when a different compression method is used for each line. When using the compression method described in frame units, 00h is described. PB3 indicates a reference clock ratio with respect to the video clock. Bits 4 to 7 are numerators and Bits 0 to 3 are denominators. PB4 indicates the frequency division ratio of the transmission clock of the compressed video data with respect to the reference clock. PB5 to PB27 are reserved areas for future expansion.

  FIG. 10 shows a data description example of EDID read from the EDID storage unit 938 of FIG. The compression encoding transmission system and the power saving function supported by the video receiving apparatus are extended to an area called HDMI-VSDB. A Compressed flag indicating whether or not it is possible to support the compression encoding transmission system of the present embodiment is provided in Bit 2 of the 6th byte. Since this area has been treated as a reserved area, it is described as 0 for non-compliant legacy devices, and backward compatibility can be maintained by describing only 1 for compatible devices. When the Compressed flag is 1, the description of Byte 9 and Byte 10 is valid.

  Bits 2 to 7 of Byte 9 describe “1” when corresponding to predetermined six types of compression methods, and “0” when not supporting. Byte 9 Bit 0 and Max Dividing number of 1 enter the number obtained by subtracting 1 from the maximum frequency dividing ratio of the transmission clock of the compressed video data with respect to the reference clock. For example, “1” indicates that only frequency division by 2 is supported, and “3” indicates that it is possible to correspond to any of frequency divisions of 2, 3, and 4.

  Byte 10 describes “1” when it can cope with each ratio of the reference clock to the video clock, and “0” when it does not correspond.

  In this way, by notifying the video transmission device that the video reception device supports compressed video data capable of reducing the transmission clock frequency, the video transmission device can improve the image quality of the video content, the power consumption reduction effect, and the video data. By comprehensively judging from transmission reliability and the like, it is possible to select an appropriate video data transmission method and transmit the video data to the video receiver.

  As described above, in the transmission method in which video data is compressed and transmitted, when the video data transmitted by the video transmission device is compressed and transmitted, the transmission clock frequency is set in accordance with the amount of the compressed video data. By switching to an operation mode in which power consumption is suppressed by reducing the clock frequency of the transmission unit or the reception unit or stopping the clock, or stopping the power supply during a period when control or real data is not transmitted or received in real time, High definition video can be transmitted with low power consumption.

  In the first embodiment, reduction of power by reducing or stopping a common transmission clock frequency for a plurality of data transmission paths and stopping power supply to some circuits has been described. In the second embodiment, an example will be described in which when the amount of data transmission is small, the power consumption is reduced by stopping compressed video data transmission on a predetermined transmission path.

  FIG. 4 shows an example showing the timing of sending a packet and video data. FIG. 3 shows an example in which a plurality of data transmission lines are operated at the same timing. In FIG. 4, for example, the timing of channel 0 is (a), the timing of channel 1 is (b), and channel 2 is taken as an example. The timing of (c) is shown.

  Channel 0 in (a) transmits a guard band (GB), a preamble, and the like while transmitting a synchronization signal Sync 663 in CTL Periods 646 and 648 and Data island Period 647. For this reason, it is appropriate to collect and send the compressed video data to channel 0 in (a). Channel 1 in (b) and channel 2 in (c) are designed to reduce the power consumption of the serializer, deserializer, output circuit, and input circuit of each unit by sequentially stopping transmission of compressed video data according to the amount of compressed video data. The mode can be shifted to lower power.

  Packets Packet 0 635 and Packet 1 636 and Packet 2 637 shown in FIG. 3C are shown in FIG. 4 as Header 0 655 and Body 0 675 and 695, Header 1 656 and Body 1 676 and 696, and Header 2 657, respectively. And Body 2 677 and 697. Since this Data island Period 647 needs to transmit information packets and voice packets related to compression, it is preferable to operate all channels 0, 1 and 2.

  In the example of FIG. 4, it is assumed that the amount of video data can be reduced to 2/3 or less by compression, and channel 2 shown in (c) is operated during the period from guard band GB 692 to guard band GB 698. Data transmission of the output circuit (123 in FIG. 1) in the period 699 when there is no data is stopped or the frequency of the transmission clock is reduced. By stopping the data transmission or reducing the transmission clock frequency, the circuit related to the channel 2 can be shifted to the low power mode, so that power consumption can be reduced. Of course, even if data transmission in the period 699 when there is no valid data is continued without reducing the transmission clock frequency, the serializer (127 in FIG. 1) and the deserializer (217 in FIG. 1) are set to the standby low power mode. There is an effect of reducing power consumption.

  When the video data compressed in channel 2 is not transmitted, the video transmission unit 11 in FIG. 1 does not distribute the video data to the selection unit 113 that shares channel 2 by the rearrangement unit 115, but the selection unit that shares channel 0. The data is collected to 112 which shares 111 with channel 1. In the video receiving unit 21, based on the rearrangement information extracted by the information extraction unit 224 from the information packet regarding compression, the rearrangement unit 225 rearranges and the decompression unit 226 reproduces the uncompressed video data.

  If the amount of video data can be reduced to 1/3 due to compression, channel 1 may be shifted to the low power mode like channel 2 and the video data may be concentrated on channel 0. By shifting both channel 1 and channel 2 to the low power mode, the low power effect is doubled compared to the case where only channel 2 is shifted to the low power mode.

  By always operating channel 0 normally, the video receiver can return channel 2 and channel 1 from the low power mode after detecting guard band GB 652 of channel 0. In the first embodiment, the reference clock is counted in order to know the return timing from the low power mode. However, since the counting is unnecessary, the circuit scale can be reduced and the power consumption can be minimized.

  As video content protection, it is considered that encrypted video data is supplied only to a video receiving device that has been subjected to predetermined device authentication by the video transmitting device, and video data is not supplied to a video receiving device that cannot perform predetermined device authentication. It is done. When using the control signal for channel 0 as the device authentication timing, it is convenient to always operate channel 0 in this way. Furthermore, if device authentication is performed bidirectionally using a cable that is different from the cable used to transmit and receive video data, it becomes difficult to decrypt the code, and content protection can be enhanced.

  By using the low power technology described in the first embodiment in combination with the channel 0, it is possible to realize a reduction in power when the data amount can be further compressed.

  As described above, in the transmission method in which video data is compressed and transmitted, when the video data transmitted by the video transmission device is compressed and transmitted, the video data transmission channel is matched with the compressed video data amount. By controlling the number in real time and switching to an operation mode that reduces power consumption by reducing or stopping the clock frequency of the transmitter or receiver of channels that do not transmit or receive valid data, or stopping power supply, etc. High-definition video can be transmitted with low power consumption.

  Next, reduction of power consumption of the video transmission / reception unit in transmission of still image content will be described.

  FIG. 11 is a block diagram illustrating an example of a video reception device and a video reception device according to the present embodiment. A video transmission device 904 that outputs still image content and a video reception device 905 are configured. Blocks that perform the same operations as those in the block diagram of FIG. 6 are assigned the same numbers, and descriptions thereof are omitted. The difference from FIG. 6 is that a frame memory 951 and a device authentication unit 952 are added to the video reception device, and a device authentication unit 953 is added to the video transmission device.

  The frame memory 951 stores video data for one frame, and may also serve as a frame memory that the display processing unit 936 has for display processing. Further, when the display unit 937 itself has a memory function, the memory function and the frame memory 951 can be combined. An example of the display unit having a memory function is electronic paper.

  The device authentication units 952 and 953 are used to authenticate each other's devices for the purpose of confirming that the video receiving device is adapted to predetermined content protection and transmitting the video by the video transmitting device. Authentication is obtained by exchanging messages using a shared EDID cable. As a content protection mechanism, for example, there is HDCP (High-bandwidth Digital Content Protection) defined by DCP (Digital Content Protection).

  Assume that the video content input to the input units 911, 912, and 913 of the video transmission device 904 or the video content recorded on the recording medium is a still image and is transmitted from the video transmission unit 924 as a still image. To do. When the video transmission device 904 reports that it is a still image, the video reception device 905 stores the received still image video in the frame memory 951 and supplies it to the display unit 937, and also transmits that the still image has been stored. The information is transmitted to the apparatus, and the video receiver is shifted to the standby mode to reduce the power consumption. The video transmission device 904 that has been notified that the still image has already been stored shifts the video transmission unit 924 to the standby mode to reduce power consumption. As described above, after the still image video is stored in the frame memory 951, the video transmission / reception unit can be shifted to the standby state until the video is switched to another still image or moving image, so that low power can be realized.

  As a method for reducing power consumption, for example, there are methods such as dividing the frequency of the clock signal and stopping a part of the circuit as described in other embodiments. You may plan.

  If the transmission video of the video transmission device 904 is the target of content protection, the initial authentication is performed between the device authentication units 952 and 953 to confirm that the video is an appropriate video device, and then the target still image video is transmitted. . Even after the frame memory 951 stores the still image, the device authentication units 952 and 953 periodically continue the intermediate authentication, for example, every about 2 seconds.

  It is possible to make use of the content protection function by storing in the frame memory while the intermediate authentication continues, and immediately deleting the still image from the frame memory if the intermediate authentication fails or the cable connection is disconnected. Further, video transmission / reception may be performed at predetermined time intervals, for example, about every 1 minute, and the memory in the frame memory may be updated. With this memory update, even if the memory on the frame memory deteriorates with time, it can be refreshed.

  Further, when the frame memory storage update by video transmission / reception is not executed at each predetermined time, the storage of the frame memory may be deleted and replaced with a video displaying a warning to that effect. Even if the device authentication partner is switched and device authentication continues, the memory of the frame memory can be erased, so that the content protection function can be enhanced.

  FIG. 12 and FIG. 13 show an example of a communication message exchanged between the bidirectional communication units 926 and 939 with the still image storage instruction and the storage completion information in the frame memory. The communication message is composed of Opcode and Parameter. FIG. 12 shows an example of Opcode and FIG. 13 shows an example of Parameter.

  <Save Image> is an Opcode in which the video transmission device 904 requests still image storage in the frame memory 951 of the video reception device 905, and Parameter [Memory Action] is assigned. [Memory Action] is 1 byte long, 0x00 indicates normal video reception, 0x01 indicates a reply request to report the current status without changing the frame memory status, 0x02 indicates a still image storage request, and other values in the future Reserved for expansion.

<Report Image Memory> is an Opcode in which the video reception device 905 reports the state of the frame memory 951 to the video transmission device 904, and Parameter [Memory State] is assigned. [Memory State] is 1 byte long, 0x00 is normal video reception, 0x01 has no memory function for frame memory, 0x02 has a memory function, but this time it has failed, 0x03 is in memory preparation or execution, and memory is not finished 0x04 indicates the completion of storage, and other values are reserved for future expansion.
<Request Normal Image> is an Opcode that the video reception device 905 requests to shift to the normal moving image transmission / reception mode, and there is no Parameter. This is used when the video receiver 905 uses the frame memory for other purposes or when it is determined that the stored video is damaged.

  FIG. 14 is a diagram illustrating an example of message transmission / reception. Initial authentication succeeds (801) between the video transmission device 904 and the video reception device 905. After the initial authentication is successful, the video transmission device 904 starts transmitting a video signal (841). Reference numeral 844 denotes a video transmission period of the video transmission device 904. In response to the video signal transmission start of the video transmission device 904, reception of the video signal is started (851).

  The video transmission device 904 requests the video reception device 905 to store the frame memory with a message <Save Image> [“Memory Image”] 802. If the video reception device 905 requires a predetermined time for frame memory storage preparation, for example, 0.5 seconds or more, the message <Report Image Memory> [“Wait to Save”] 803 is used to continue video transmission to the video transmission device 904. Request. When the video display device 905 completes the frame memory storage (852), a message <Report Image Memory> [“Success to Save”] 804 reports to the video transmission device 904. Upon receiving the report, the video transmission device 904 stops transmission of the video signal (843), and the video transmission unit is set in the standby mode to reduce power consumption. The video transmission device 905 also reduces power during the frame memory storage period 853 by setting the video reception unit in the standby mode.

  During the frame memory storage period 853, the intermediate authentication is continued at a predetermined interval, for example, every 2 seconds, and it is confirmed that the predetermined video transmission device 904 and the video reception device 905 are continuously connected. If the intermediate authentication successes 805 and 806 are repeated, the frame memory storage is continued. If the intermediate authentication fails (807), initial authentication is started.

  When the initial authentication is successful (808), the video transmission device 904 starts video signal transmission (845). Reference numeral 846 denotes a video transmission period of the video transmission device 904. In response to the video signal transmission start of the video transmission device 904, reception of the video signal is started (854). Note that if the time from the intermediate authentication failure 807 to the video signal transmission start 845 is within a predetermined time, for example, 30 seconds, the frame memory storage may be continued to prevent the display unit screen from blacking out. Good. However, if the predetermined time is exceeded, the frame memory storage may be erased from the viewpoint of content protection, and a display may be made to inform the user that there is no input video.

  Again, the video transmission device 904 requests the video reception device 905 to store the frame memory with a message <Save Image> [“Memory Image”] 809. When the video display device 905 completes the frame memory storage (855), a message <Report Image Memory> [“Success to Save”] 810 reports to the video transmission device 904. Upon receiving the report, the video transmission device 904 stops transmission of the video signal (847), and sets the video transmission unit in the standby mode to reduce power consumption. Reference numeral 856 denotes a frame memory storage period.

  If the video receiving device 905 can no longer provide the frame memory storage function, or if damage is detected in the stored image, or if it continues to store in the frame memory without receiving the next video for a predetermined time, for example, 1 minute or longer, a message In <Request Normal image> 811, the video transmission device 904 is requested to return to the normal moving image transmission mode. The video transmission device 904 starts transmission of the video signal (848), and uses the message <Save Image> [“Normal Image”] 812 to request the video reception device 905 to stop storing the frame memory and to shift to normal reception. The video receiving apparatus 905 that has received this request moves to normal reception 857, and the message <Report Image Memory> [“Normal Image”] 813 deletes the frame memory storage in the video transmitting apparatus 904 and shifts to normal reception. To report. Reference numeral 849 denotes a video signal transmission period.

  In the standby mode, as described in the first and second embodiments, the power may be reduced by continuing the reference clock and reducing the transmission clock frequency, or the power may be stopped or the voltage may be reduced to reduce the power. It may be realized.

  In this way, in the still image transmission, the frame memory storage of the video reception device is utilized, and the video transmission unit of the video transmission device and the video reception unit of the video reception device are shifted to the standby mode during the frame memory storage period. It can be powered.

  Depending on the specification of content protection authentication, if all video data transmission channels are stopped during standby, intermediate authentication may fail. In this case, only the channel that transmits the synchronization signal or control signal is operated continuously. The operation of other channels may be stopped to enter the standby power mode.

  The method of the first embodiment or the second embodiment may be applied to the third embodiment at the time of video signal transmission.

11, 924 Video transmission unit 21, 935 Video reception unit 111, 112, 113, 221, 222, 223 Selection unit 114 Compression unit 115, 225 Rearrangement unit 116 Additional information unit 117, 219 Clock control unit 121, 122, 123, 124 Output circuit 125, 126, 127 Serializer 211, 212, 213, 214 Input circuit 215, 216, 217 Deserializer 218 PLL
224 Information extraction unit 225 Rearrangement unit 226 Restoration unit 311, 312, 313, 314, 902, 905, 906 Cable 501, 502 Horizontal flat sync signal 506, 507 Video signal 511, 512, 513 Audio packet 516, 517 Uncompressed video Data 521, 522, 523, 531, 532, 533, 541, 542, 543 Information packets regarding compression 526, 527, 536, 537.547 Compressed video data 538, 539 No data period 548, 549 Dummy data 551, 552 Horizontal video Period 552, 554 Horizontal blanking period 562, 563 Compressed video data period 562, 564 Packet period 626, 628, 646, 648 CTL Period
627, 647 Data island Period
629, 645, 649 Video Data Period
613, 630, 633, 640 Preamble
614, 618, 621, 632, 634, 638.641 Guard Band
616, 617, 635, 636, 637 Packet
622, 630, 642, 650, 662, 670, 682 Video Data
651, 659, 671, 679, 691, 699 No Data
652, 654, 658, 661, 672, 674, 678, 681, 692, 694, 698 Guard Band
653, 673, 680, 693 Preamble
655, 656, 657 Header
663 Sync
675,676,677,695,696,697 Body
901 Video transmission device 911, 912, 913, 914, 934, 931 Input unit 928, 929, 932, 933 Terminal 915 Tuner reception processing unit 916 Network reception processing unit 917 Recording media control unit 918 Recording media 919, 940 User IF
910, 941 Control unit 921 Stream control unit 922 Decoder 923, 936 Display processing unit 925 Reading unit 926, 939 Bidirectional communication unit 927 Output unit 937 Display unit

Claims (9)

A method for transmitting and receiving compressed video data in which a video receiver receives compressed video data transmitted from a video transmitter,
Based on the amount of data in units of lines of the compressed video data transmitted from the video transmission device, the frequency of the clock used for processing when transmitting the compressed video data from the video transmission device can be changed in units of lines,
The video transmission device transmits information regarding the change of the clock frequency in a blanking period, and transmits the compressed video data to the video reception device in a video period.
The video reception device controls the frequency of the clock used for processing the received compressed video data based on the received information on the change of the clock frequency.
A method for transmitting and receiving video data. The video data transmission / reception method according to claim 1,
The frequency of the clock for transmitting the compressed video data is m / n (m and n are integers, m <n) times the frequency of the clock of the uncompressed video data obtained by decoding the compressed video data. A method for transmitting and receiving video data, comprising: A video transmission device that transmits video data to a video reception device,
A clock control unit for controlling and outputting the clock;
A video output circuit that processes and outputs compressed video data using the clock output from the clock control unit, and
Based on the amount of data in line units of the compressed video data, the clock frequency from the clock control unit can be changed in line units,
The video output circuit is information used to generate a clock used for processing the compressed video data in the video receiving device, and transmits information regarding a change in the frequency of the clock to the video receiving device in a blanking period. And transmitting the compressed video data to the video receiver during a video period. The video transmission device according to claim 3,
The frequency of the clock for transmitting the compressed video data is m / n (m and n are integers, m <n) times the frequency of the clock of the uncompressed video data obtained by decoding the compressed video data. A video transmission device characterized by being. The video transmission device according to claim 3,
And a decoder that decodes either compressed video data received from a broadcast or network and recorded compressed video data;
A compression unit that compresses the video signal decoded by the decoder;
The transmission device, wherein the video output circuit transmits the video data compressed by the compression unit as the compressed video data. A video receiver that receives compressed video data from a video transmitter and generates uncompressed video data ,
A video input circuit that receives the compressed video data and information about a clock frequency of the compressed video data from the video transmission device;
A clock control unit that generates a data clock based on a reference clock and information on a clock frequency of the compressed video data received by the video input circuit;
A processing unit that processes the compressed video data received by the video input circuit using the data clock output from the clock control unit;
A restoring unit which generates the non-compressed video data from the compressed video data processed by the processing unit,
A video receiving apparatus comprising: The video receiving device according to claim 6,
The information about the clock frequency of the compressed video data includes information for changing the clock frequency according to the data amount of the compressed video data for each line. The video receiving device according to claim 6,
The information regarding the clock frequency of the compressed video data indicates that the clock frequency during the transmission of the compressed video data is m / n (m and n are integers, m <n) times the clock frequency of the uncompressed video data. Including information to change,
The video receiving apparatus, wherein the clock control unit generates the data clock using the change information. The video receiving device according to claim 8, wherein
The display processing unit further includes an OSD superimposition process, an enlargement / reduction process for converting the uncompressed video data into the resolution of the display unit, a frame rate conversion process, or a high- speed display unit. Perform display processing including image quality improvement processing,
The video receiving apparatus, wherein the display unit displays a video signal displayed by the display processing unit.

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