JP2011009812A - Video data transmitter and receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently transmit a non-compression video signal in a long distance by using a public optical communication network.SOLUTION: Frame conversion portions 11-18 of a transmitter 1 input Dual Link HD-SDI signals, discard parity bits and staff bits of HANC data and pixel data, convert data sequences of the HD-SDI signals by SDI clocks into data sequences by SONET clocks and house the data sequences in an OC-192 frame for transmission to a wide area network 3. Frame reconversion portions 21-28 of a receiver 2 convert the data sequences by the SONET clocks into data sequences of the HD-SDI signals by the SDI clocks for the OC-192 frame received from the wide area network 3, reproduce data discarded in the transmitter 1, and generate the original Dual Link HD-SDI signals and output the generated signals. Thus, a non-compression SHV signal can be transmitted at a long distance by using an existing public optical communication network such as the wide area network 3 to achieve cost reduction.

Description

  The present invention relates to an apparatus for transmitting and receiving video data, and more particularly, to a technique for transmitting large-capacity ultra-high-definition video data over a long distance in real time using an existing wide area network without compression. .

  Conventionally, in the field of general high-definition video (HDTV), a method of quantizing the luminance / color difference signal (YPbPr) of each pixel constituting the video with 10 bits or less is used. In particular, the SMPTE (American Film and Television Engineers Association) standardized the 292M standard with 10 bits as one word, and the HD-SDI (High Definition-Serial Digital Interface) standard has become widely used. . In addition, due to the demand for higher definition and advances in computer graphics technology, imaging / display devices, etc., a 12-bit quantization method, color signals that do not decimate the number of spatial samples (RGB 4: 4: 4 system) A large-capacity video system that incorporates a method that uses, etc. has come to be used.

  In order to transmit such 4: 4: 4 sampled video or 12 bit quantized video in accordance with the conventional HD-SDI standard based on 10 bits / word, 2 HD-SDI signals are transmitted. The SMPTE 372M standard (Dual Link HD-SDI) that bundles the systems and transmits them in parallel is defined.

  When transmitting video data in accordance with the SMPTE 372M standard, the video data transmitting apparatus transmits pixel data, HANC data (horizontal auxiliary area data), and VANC data (vertical auxiliary area data) to two channels of A channel and B channel. The auxiliary data and the data of the synchronization byte are mapped, and a Dual Link HD-SDI signal is transmitted to the video data receiving apparatus. Here, pixel data of each pixel is composed of 40 bits in total by adding 4 bits (2 parity bits and 2 stuffing bits) to each 12 bits representing pixel information of three colors. Accordingly, effective pixel data can be accommodated in 10 bits × 4 words (2 words of A channel and 2 words of B channel) of the HD-SDI signal.

  Also, as a future television system, research and development of an ultra-high-definition video system (Super Hi-Vision, SHV) having 16 times the number of pixels (7680 × 4320 pixels) of Hi-Vision is underway (see Non-Patent Document 1). ). The SHV video parameters are still being studied, but as a candidate for this, a 4: 4: 4 scheme that does not perform 12-bit quantization and the number of spatial samples is being studied. In the progressive scanning method with a frame frequency of 60 Hz, the SHV image is a large-capacity image signal of about 72 Gbps with only effective pixel data. Similarly to the Dual Link HD-SDI signal, when the 12-bit SHV effective pixel data is accommodated in the 10-bit / word HD-SDI signal, 64 HD-SDI signals (32 Dual Link HD- SDI signals can be used to transmit SHV video data.

  As a system for transmitting SHV video data, a system that realizes long-distance transmission of an uncompressed SHV signal has been proposed (see Non-Patent Document 2). This system converts DG (Dual-Green) uncompressed SHV signal, which consists of 16 HD-SDI parallel signals, into 16-wavelength optical signal, and transmits it via single-core optical fiber by wavelength multiplexing To do.

  There is a digital cinema as a high-definition video other than the SHV video. As in the case of SHV video, HD-SDI parallel signals are used for digital cinema video as an interface for uncompressed signals. There has been proposed a technique of converting such an uncompressed digital cinema signal into a 10 Gbps serial signal and transmitting it (see Patent Document 1).

  On the other hand, in the field of communication, as a wide area network capable of transmitting high-speed and large-capacity data, there is known a communication network that performs transmission using the SONET (Synchronous Optical Network) format standardized by the American National Standards Institute (ANSI) ( (Refer nonpatent literature 3). In the International Telecommunication Union (ITU), a similar format is recommended as Synchronous Digital Hierarchy (SDH) (see Non-Patent Document 4). Here, the wide area network refers to a wide area network (WAN) provided by a telecommunications carrier.

  The SONET standard is hierarchically determined according to the transmission rate, and an optical interface that realizes a transmission rate of about 10 Gbps is referred to as OC-192 (Optical Carrier-Level 192). A wide area network based on SONET OC-192 is already in widespread use, and components and equipment applied to this wide area network are also widely used. Therefore, it has been desired to realize inexpensive long-distance transmission by transmitting video data using such a wide area network.

JP 2006-74646 A

"4000 scanning lines, 4-plate ultra high definition video camera", Journal of the Institute of Image Information and Television Engineers, Vol.58 No.3 pp.383-391, 2004 "Long-distance transmission of uncompressed Super Hi-Vision signals using 16-wave high-density wavelength multiplexing", Journal of the Institute of Image Information and Television Engineers, Vol.60 No.9 pp.1490-1495, 2006 ANSI T1.105, American National Standards Institute (ANSI) ITU-T G. 707, International Telecommunication Union (ITU)

  As described above, the system for transmitting the SHV video signal in Non-Patent Document 2 converts the DG system uncompressed SHV signal composed of 16 parallel HD-SDI signals into an optical signal of 16 wavelengths, Transmission is performed by a single-core optical fiber by wavelength multiplexing. However, assuming that this system is expanded to transmit 64 HD-SDI signals, laser light sources and light receivers are required as many as the number of HD-SDI signal lines, and inexpensive long-distance transmission is realized. There is a problem that can not be.

  When the HD-SDI signal is a Dual Link HD-SDI signal, the pixel data area includes redundant bits (parity bits and stuff bits) other than the pixel information, and the auxiliary data area includes invalid HANC data. Exists. And since these invalid data will be transmitted as it is, there exists a problem that transmission efficiency is bad. In addition, since SDI frame format conversion and clock frequency conversion are not performed, transmission to a public optical communication network such as a wide area network by SONET OC-192 is impossible, and transmission is limited to only an optical fiber dedicated line. There is a problem that is.

  As described above, the system for transmitting a digital cinema video signal in Patent Document 1 converts an uncompressed digital cinema signal into a serial signal of 10 Gbps and transmits it. Here, by using this method in parallel with a plurality of devices, it can be applied as a system for transmitting an SHV video signal, and the number of laser light sources and light receivers can be reduced. However, since processing is performed based on the clock frequency of the SDI signal, transmission to a public optical communication network such as a wide area network by SONET OC-192 is impossible as in the above-described system, and it is dedicated to optical fiber. There is a problem that the transmission is limited to only a line.

  Therefore, the present invention has been made under such a technical background, and an object of the present invention is to provide a video data transmitting apparatus capable of efficiently transmitting a non-compressed video signal over a long distance using a public optical communication network. And providing a receiving apparatus.

  In order to solve the above-described problem, a video data transmitting apparatus according to the present invention is a transmitting apparatus that accommodates uncompressed video signal data in a predetermined frame and transmits the data to a wide area network. An SDI deframer that is input as an SDI signal, discards predetermined HANC data (horizontal auxiliary area data) in the HD-SDI signal, and discards parity bits and stuff bits constituting pixel data in the HD-SDI signal; Clock converter for storing HD-SDI signal data in which HANC data, parity bits, and stuff bits are discarded by the SDI deframer in a storage device according to the clock of the HD-SDI signal, and reading out from the storage device in accordance with the clock of the frame And frame frame based on the frame clock. An output instruction is output to the clock conversion unit at a timing of storing data in the load, and the data read from the memory of the clock conversion unit is input using the output instruction as a clock of the frame, and the input data And a framer for accommodating the frame in the payload of the frame.

  In the video data transmitting apparatus according to the present invention, the SDI deframer inputs uncompressed video signals as four lines of Dual Link HD-SDI signals A1 to A4 and B1 to B4, and HD-SDI signals A2 to A4 and B1. When the valid data is included in the HAC data of ~ B4, the valid data is moved to the HANC data area of the HD-SDI signal A1, and the HANC data of the HD-SDI signals A2 to A4, B1 to B4 is discarded. The parity bit and the stuff bit constituting the pixel data in the SDI signals B1 to B4 are discarded.

  A video data receiving apparatus according to the present invention is a receiving apparatus that receives data of an uncompressed video signal composed of a plurality of HD-SDI signals as a predetermined frame from a wide area network. Predetermined HANC data in the HD-SDI signal is discarded, pixel information, parity bits and stuff bits out of pixel information, parity bits and stuff bits constituting the pixel data in the HD-SDI signal are discarded, and the HANC data, parity When the HD-SDI signal data in which bits and stuff bits are discarded is stored in a payload together with identification information indicating the position of the discarded HANC data and transmitted as a frame to the wide area network, the received frame A deframer that extracts data from the payload; The frame data extracted by the deframer is stored in the memory according to the clock of the frame, and is read from the memory according to the clock of the HD-SDI signal, and is stored in the memory of the clock converter. A clock control unit that determines a clock timing of the HD-SDI signal based on the amount of the data and generates a clock of the HD-SDI signal; a clock of the HD-SDI signal generated by the clock control unit; Based on the above, an output instruction is output to the clock converter at a timing when the data is stored in the HD-SDI signal area, and is read from the memory of the clock converter according to the output instruction and the clock of the HD-SDI signal. HANC input data and discarded by the video data transmitter A framer for restoring HANC data based on the identification information of the data, restoring parity bits and stuff bits from the pixel information constituting the pixel data, and generating an original HD-SDI signal. And

  Further, in the video data receiving device according to the present invention, a time stamp signal including a time difference between the clock of the frame and the clock of the HD-SDI signal is accommodated in the frame by the video data transmitting device, and the clock control unit includes: The clock timing of the HD-SDI signal is determined based on the time stamp signal transmitted by the video data transmitting apparatus and the clock of the frame, and the clock of the HD-SDI signal is generated. To do.

  As described above, according to the present invention, an uncompressed video signal can be transmitted over a long distance using a public optical communication network such as a wide area network. In addition, since wide area networks are already in widespread use, the equipment and components used there can be used as they are, and a reduction in cost can be realized as compared with the case of transmission to a dedicated optical fiber line. Therefore, the wide area network can be used as it is, and efficient long-distance transmission can be realized.

1 is a block diagram illustrating a configuration of a transmission system including a transmission device and a reception device according to an embodiment of the present invention. It is a block diagram which shows the structure of the frame conversion part in a transmitter. It is a flowchart explaining the process of the SDI deframer in the frame conversion part of a transmitter. It is a figure which shows the structure of OC-192 frame. It is a block diagram which shows the structure of the frame re-conversion part in a receiver.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram illustrating a configuration of a transmission system including a transmission device and a reception device according to an embodiment of the present invention. The transmission system includes a transmission device 1 that transmits video data and a reception device 2 that receives video data. The transmission device 1 and the reception device 2 are connected by a wide area network 3. In the following description, it is assumed that the wide area network 3 is a public optical communication network through which 8 frames (hereinafter referred to as OC-192 frames) defined by the SONET OC-192 standard are transmitted.

  The transmission apparatus 1 inputs an uncompressed SHV signal as 32 Dual Link HD-SDI signals. The 32 systems of Dual Link HD-SDI signals are grouped into 4 systems of signals (8 signals) and input as signal groups G1 to G8. The signal group G1 is composed of four lines of Dual Link HD-SDI signals A1 to A4 and B1 to B4. The same applies to the signal groups G2 to G8. Moreover, in each signal group G1-G8, one system is comprised by Dual Link HD-SDI signal A1, B1. The same applies to the Dual Link HD-SDI signals A2, B2, etc.

  The transmission device 1 converts the four Dual Link HD-SDI signals into one OC-192 frame for each signal group G1 to G8, and sets the clock frequency of the HD-SDI signal serving as a processing reference to OC-192. Convert to frame clock frequency. At this time, predetermined data included in the Dual Link HD-SDI signal is discarded. Then, the transmission device 1 transmits eight OC-192 frames to the wide area network 3. Details of the predetermined data to be discarded will be described later.

  The transmission device 1 includes frame conversion units 11 to 18. The frame conversion units 11 to 18 receive the Dual Link HD-SDI signals of the signal groups G1 to G8, respectively, discard predetermined data and store it in the OC-192 frame, convert the clock frequency, and convert the electrical signal into an optical signal. The signal is converted into a signal and transmitted to the wide area network 3.

  The receiving device 2 receives the eight OC-192 frames transmitted from the transmitting device 1 via the wide area network 3, converts the OC-192 frames into Dual Link HD-SDI signals for each system, and performs processing. The clock frequency of the reference OC-192 frame is converted to the clock frequency of the HD-SDI signal. At this time, the predetermined data discarded in the transmission apparatus 1 is restored. And the receiver 2 outputs Dual Link HD-SDI signals for each of the signal groups G1 to G8, that is, a total of 32 Dual Link HD-SDI signals in the signal groups G1 to G8.

  The receiving device 2 includes frame reconversion units 21 to 28. The frame re-conversion units 21 to 28 each receive OC-192 frames, convert optical signals into electrical signals, extract data, and convert the signals into dual link HD-SDI signals of signal groups G1 to G8. Restore and output data.

  The wide area network 3 is composed of eight OC-192 lines. The wide area network 3 may be configured by a subordinate connection of an 8-core optical fiber dedicated line and eight OC-192 lines. In the present invention, the public optical communication network of the wide area network 3 is not limited to eight OC-192 lines.

  As described above, according to the transmission system including the transmission device 1 and the reception device 2, when transmitting the uncompressed SHV signal, the transmission device 1 inputs the uncompressed SHV signal as a Dual Link HD-SDI signal, The data is discarded and converted into an OC-192 frame, the clock frequency of the HD-SDI signal is converted into the clock frequency of the OC-192 frame, and the OC-192 frame is transmitted to the wide area network 3. Then, the receiving device 2 receives the OC-192 frame from the wide area network 3, converts the OC-192 frame into a Dual Link HD-SDI signal, and converts the clock frequency of the OC-192 frame to the clock frequency of the HD-SDI signal. The data was converted to the default data. Thereby, the receiver 2 can reproduce the uncompressed SHV signal input by the transmitter 1. That is, with this transmission system, an uncompressed SHV signal can be transmitted over a long distance using the wide area network 3 instead of the optical fiber dedicated line. In addition, the wide area network 3 using OC-192 line is already widespread, and since the equipment and parts used there can be used as they are, the cost can be reduced as compared with the case of transmitting to the dedicated optical fiber line. be able to. Therefore, the existing wide area network 3 can be used as it is, and efficient long-distance transmission can be realized.

(Transmitter / frame converter)
Next, the frame conversion unit 11 in the transmission apparatus 1 shown in FIG. 1 will be described in detail. Since the configuration and processing of the frame conversion units 12 to 18 are the same as those of the frame conversion unit 11, the description thereof is omitted. FIG. 2 is a block diagram illustrating a configuration of the frame conversion unit 11. The frame conversion unit 11 includes an SDI input unit 111, an SDI deframer 112, a clock conversion unit 113, a SONET framer 114, a scrambler 115, a parity generation unit 116, a serializer 117, and an E / O conversion unit 118.

  The SDI input unit 111 inputs a signal group G1 composed of four Dual Link HD-SDI signals (hereinafter referred to as HD-SDI signals) A1 to A4 and B1 to B4, and performs processing for compensating frequency characteristics, and Impedance conversion processing is performed, and phase synchronization between the signals is established with reference to the line numbers included in the HD-SDI signals A1 to A4 and B1 to B4. Here, when it is necessary to reduce the frequency of the clock for signal processing in the subsequent stage, the serial signal is converted into a parallel signal of 10 bits or 20 bits, for example. The SDI input unit 111 outputs the HD-SDI signals A1 to A4 and B1 to B4 in which phase synchronization is established to the SDI deframer 112.

  The SDI deframer 112 receives the HD-SDI signals A1 to A4 and B1 to B4 whose phase synchronization has been established from the SDI input unit 111, performs data extraction, and discards predetermined data. Then, the SDI deframer 112 outputs the processed signal to the clock conversion unit 113.

  FIG. 3 is a flowchart for explaining processing of the SDI deframer 112. Here, a synchronization byte, pixel data, and auxiliary data (HANC data and VANC data) are mapped to the HD-SDI signal. First, the SDI deframer 112 determines whether the data extracted from the input HD-SDI signals A1 to A4 and B1 to B4 is HANC data (step S301). Whether or not the extracted data is HANC data is determined by detecting the position of the extracted data with reference to the position of the synchronization byte in the HD-SDI signal to which the synchronization byte, pixel data, and auxiliary data are mapped. Determined. When it is determined that the extracted data is HANC data (step S301: Y), the HANC data is the HANC data of the HD-SDI signals A2 to A4 and B1 to B4 excluding the HD-SDI signal A1, and It is determined whether the data is valid data such as audio data (step S302). Whether or not the HANC data is valid data is set in advance for each of the HD-SDI signals A1 to A4 and B1 to B4, including the area in which the valid data is accommodated.

  When the SDI deframer 112 determines in step S302 that the HANC data is the HANC data of the HD-SDI signals A2 to A4 and B1 to B4 and is valid data (step S302: Y), the valid Signal processing is performed to move the data to an area that does not contain valid data in the HANC of the HD-SDI signal A1 (step S303), and the process proceeds to step S304. Note that the capacity of HD-SDI signals A1 to A4, B1 to B4 in all valid data in the HANC plus the capacity of location data of the source and destination of valid data described later is HD-SDI signal A1. It is assumed that it is less than the data capacity of the HANC. In addition, it is assumed that the SDI deframer 112 recognizes the position of valid data stored in the HANC in advance. In this case, the SDI deframer 112 accommodates the location information of the source and destination of the valid data in the HANC of the HD-SDI signal A1 as the valid data is moved to the HANC of the HD-SDI signal A1. On the other hand, when it is determined that the HANC data is not the HANC data of HD-SDI signals A2 to A4 and B1 to B4 or is not valid data (step S302: N), the process proceeds to step S304. The SDI deframer 112 discards the HANC data of the HD-SDI signals A2 to A4 and B1 to B4 excluding the HD-SDI signal A1 (step S304), and proceeds to step S307. As a result, the HD-SDI signal A1 is transmitted as it is.

  On the other hand, when the SDI deframer 112 determines in step S301 that the data extracted from the input HD-SDI signals A1 to A4 and B1 to B4 is not HANC data (step S301: N), the input HD-SDI signal A1. It is determined whether or not the data extracted from .about.A4, B1 to B4 is VANC data (step S305). Whether or not the extracted data is VANC data is detected based on the line number and the position of the sync byte in the HD-SDI signal to which the sync byte, pixel data and auxiliary data are mapped. It is determined by doing. When it is determined that the extracted data is not VANC data (step S305: N), parity bits (2 bits) and stuff bits (2 bits) that are not pixel information itself are discarded from the pixel data of the HD-SDI signals B1 to B4. (Step S306). Then, the process proceeds to step S307. Since the HD-SDI signals A1 to A4 do not include parity bits and stuff bits, no discard processing is performed. On the other hand, when the SDI deframer 112 determines that the extracted data is VANC data (step S305: Y), the SDI deframer 112 proceeds to step S307. As a result, all VANC data of the HD-SDI signals A1 to A4 and B1 to B4 are transmitted as they are.

  The SDI deframer 112 determines whether or not the processing of all the data of the HD-SDI signals A1 to A4 and B1 to B4 has been completed (step S307), and determines that it has not been completed (step S307: N), When the process proceeds to step S301 and it is determined that the process is completed (step S307: Y), the HD-SDI signals A1 to A4 and B1 to B4 after the process of steps S301 to S307 are output (step S308).

  As described above, the SDI deframer 112 converts the HD-SDI signals A1 to A4 and B1 to B4 from the HD-SDI signals A2 to A4 and B1 to B4 other than the HD-SDI signal A1 into the HD-SDI. Move to HANC of signal A1, discard HANC data of HD-SDI signals A2 to A4, B1 to B4 other than HD-SDI signal A1, and store parity bits and stuff bits in pixel data of HD-SDI signals B1 to B4 Discard. As a result, in the SONET framer 114 described later, the data sequence accommodated in the OC-192 frame has a speed of 9.561672 Gbps when the frequency of the uncompressed SHV signal is 60 Hz, and the frequency of the uncompressed SHV signal is 59.94 Hz. In this case, the speed becomes 9.552110 Gbps. That is, the speed of about 12 Gbps (1.5 Gbps × 8 groups) of the HD-SDI signals A1 to A4 and B1 to B4 is about 9.5 Gbps due to the data discard processing by the SDI deframer 112, and the OC-192 frame Can be within the allowable speed range.

  Returning to FIG. 2, the clock conversion unit 113 inputs a signal in which predetermined data is discarded from the SDI deframer 112 and also inputs an output instruction from the SONET framer 114, and receives an HD-SDI signal (input signal) based on the SDI clock. ) Is converted into a data string based on the SONET clock and output to the SONET framer 114. Specifically, the clock conversion unit 113 includes a FIFO (First in First Out) type buffer storage device, and stores the data of the input HD-SDI signal in the FIFO type buffer storage device according to the SDI clock. Then, the clock conversion unit 113 reads data from the FIFO buffer according to the timing when the output instruction is input, and outputs the data as a data string based on the SONET clock. This output instruction is a signal generated by the SONET framer 114 using the SONET clock. Details will be described later.

  Note that when the SDI clock control unit 218 in the frame re-conversion unit 21 of the receiving apparatus 2 described later generates an SDI clock using the SRTS (Synchronous Residual Time Stamp) method, the clock conversion unit 113 includes the SONET framer 114. A time stamp signal request instruction is input, and at that timing, a time stamp signal, which is time information based on the SDI clock, is generated and output to the SONET framer 114. In this case, the SONET framer 114 outputs a time stamp signal request instruction at a predetermined timing in the SOH of the OC-192 frame, which will be described later, based on the SONET clock, and inputs a time stamp signal corresponding to the request instruction. It is accommodated in a predetermined area. Therefore, the time stamp signal accommodated in the SOH of the OC-192 frame is a signal reflecting the time difference between the SONET clock and the SDI clock. Regarding the SRTS method, refer to the document of “ITU-T I.363.1 recommendation 2.5.2.2 Source clock frequency recovery method”.

  The SONET framer 114, based on the SONET clock, uses a timing clock for storing data in each block of the OC-192 frame in an OC-192 frame consisting of a block of 1080 columns × 9 rows constituting the header and payload described later. A timing clock for generating and storing data in the payload is output to the clock conversion unit 113 as an output instruction. In addition, the SONET framer 114 receives a data string based on the SONET clock from the clock conversion unit 113 according to the output instruction, and also inputs a SONET parity signal from the parity generation unit 116, and converts the input data string and the SONET parity signal to OC. The OC-192 frame is generated and the parallel signal is output to the scrambler 115.

  FIG. 4 is a diagram showing the configuration of the OC-192 frame. The OC-192 frame is composed of a section overhead (Section OverHead: SOH), a path overhead (Path OverHead: POH), and a payload, and is a block (1 block = 128 bits) whose processing unit is 1 clock (1 SONET clock). Data are arranged in 1080 columns × 9 rows. Of the block of 1080 columns × 9 rows, the first 36 columns × 9 rows are SOH, the next 4 columns × 9 rows are POH, and the next 1040 columns × 9 rows are payload. That is, the header (overhead part) is composed of SOH and POH from the first column to the 40th column. The payload is composed of the areas from the 41st column to the 1080th column, specifically, the steady effective data area for 1036 columns from the 41st column to the 1076th column and 2 columns of the 1077th and 1078th columns. The non-stationary effective data area and the auxiliary data area for two columns of the 1079th and 1080th columns are configured.

  Here, an output instruction output from the SONET framer 114 to the clock conversion unit 113 will be described. The SONET framer 114 generates a block unit timing clock corresponding to a plurality of blocks constituting the OC-192 frame shown in FIG. 4 based on the SONET clock, and outputs 1040 × 9 timing clocks in the payload as an output instruction. Output to the clock converter 113. This output instruction is in the order corresponding to each block from the first row to the ninth row, and in each row, a block in the steady valid data area, a block in the non-stationary valid data area, and a block in the auxiliary data area Are output in the order corresponding to.

  When the output instruction is input, the clock conversion unit 113 counts the output instruction, and determines which region of the payload of the OC-192 frame is the output instruction. In response to the output instruction for the steady valid data area of the OC-192 frame, the clock conversion unit 113 outputs data corresponding to one block from the FIFO buffer according to the timing (in the example of FIG. 4, 1 block = 128-bit data) is read out and output to the SONET framer 114 as a data string based on the SONET clock. Further, the clock conversion unit 113 is preset with the amount of data (data amount) stored in the FIFO buffer memory according to the timing in response to the output instruction for the non-stationary valid data area of the OC-192 frame. When the amount of data is equal to or greater than the threshold value, the data corresponding to one block is read from the FIFO buffer and output to the SONET framer 114 as a data string based on the SONET clock. On the other hand, when the data amount is smaller than the threshold value, the data is not read and the data string is not output. Further, the clock conversion unit 113 does not read data from the FIFO buffer and does not output a data string in response to an output instruction for the auxiliary data area of the OC-192 frame.

  As described above, the SONET framer 114 outputs an output instruction based on the SONET clock to the clock conversion unit 113 for each block in the payload (steady valid data area, non-stationary valid data area, and auxiliary data area) of the OC-192 frame. To do. When the SONET framer 114 receives a data string corresponding to an output instruction for a block in the steady valid data area, the SONET framer 114 stores the input data string in the block. As a result, the SONET framer 114 can reliably input a data string corresponding to the output instruction of the steady effective data area. In addition, when the SONET framer 114 inputs a data string in response to an output instruction for a block in the non-stationary effective data area, the SONET framer 114 stores the input data string in the block, and identification information including information on the stored block Are stored in the auxiliary data area. On the other hand, when the data string is not input, the accommodation process is not performed. That is, in order to identify whether the non-stationary valid data area is valid or invalid, a part or all of the auxiliary data area is assigned as the identification area. In this case, the receiving device 2 identifies whether the block of the non-stationary valid data area is valid or invalid based on the identification information assigned to part or all of the auxiliary data area.

  In addition, when the SONET framer 114 is to accommodate the SOH in the OC-192 frame, the SONET parity signal and the frame synchronization signal input from the parity generation unit 116 at the timing of a predetermined block in the SOH based on the SONET clock. A1 and A2 are accommodated in a predetermined block in the SOH. The SONET framer 114 generates and stores POH data at the POH timing, and generates and stores auxiliary data at the auxiliary data area timing. In this way, the SONET framer 114 performs the above-described processing at the timing of each block of OC-192 based on the SONET clock.

  When the SDI clock control unit 218 in the frame re-conversion unit 21 of the receiving apparatus 2 described later generates an SDI clock using the SRTS method, the SONET framer 114 performs a time stamp at a predetermined block timing in the SOH. The signal request signal is output to the clock converter 113, the time stamp signal is input from the clock converter 113, and the input time stamp signal is accommodated in a predetermined block in the SOH.

  By the way, the number of words of data accommodated in one OC-192 frame is a value that varies depending on the design value of the frequency variation of the HD-SDI signal and the OC-192 frame. Hereinafter, in order to simplify the description, the design values of the frequency fluctuations of the HD-SDI signal and the OC-192 frame are both set to ± 100 ppm. When the frame frequency of the uncompressed SHV signal is 60 Hz and the frequency drift is +100 ppm, the clock frequency of the HD-SDI signal is 1.195328 GB (bytes) / s (9.556228 Gbps), which is the maximum speed. When the frame frequency is 59.94 Hz and the frequency drift is −100 ppm, the minimum speed is 1.193894 GB / s (9.5551155 Gbps). On the other hand, the number of OC-192 frames per second fluctuates from 7999.2 Hz to 8000.8 Hz when the frequency drift is ± 100 ppm, so if it is 128 bits / word, it is accommodated in one OC-192 frame. Of the data, the number of words that hold the data of the uncompressed SHV signal varies from 9326.4 to 9339.4. In the case where the number of words to be accommodated is 9326.4, the number of words to be accommodated is 9327 = 9324 (1036 columns × 9 rows) +3 when the decimal part is rounded up. Therefore, the accommodated data is a steady valid data area (9324 words = 1036). Column × 9 rows) and a non-stationary effective data area for 3 words are required. In addition, when the number of words to be accommodated is 9339.4, the number of words to be accommodated is 9340 = 9324 (1036 columns × 9 rows) +16 when the decimal part is rounded up. = 1036 columns × 9 rows) and a 16-word non-stationary valid data area.

  Therefore, when both the HD-SDI signal and the OC-192 frame frequency variation design value are set to ± 100 ppm, when the data is accommodated in the OC-192 frame payload, the data is reliably accommodated regardless of the frequency variation. In addition to the steady effective data area of 1036 columns × 9 rows, a non-stationary effective data area of 2 columns × 9 rows for absorbing frequency fluctuations is required. In other words, in the OC-192 frame, the overflow of data is avoided by securing a steady valid data area of 1036 columns × 9 rows and a non-steady valid data region of 2 columns × 9 rows as areas for storing data. can do. Incidentally, the design value ± 100 ppm of the frequency fluctuation of the HD-SDI signal and the OC-192 frame is a value having a margin, and the OC-192 frame is configured in consideration of this design value, thereby enabling the non-stationary effective data region. The frequency fluctuation can be reliably absorbed.

  For this reason, as shown in FIG. 4, 1036 columns × 9 rows of the payload are set as the steady valid data region, 2 columns × 9 rows are set as the non-stationary valid data region, and the remaining 2 columns × 9 rows. Is an auxiliary data area.

  Thereby, in the clock conversion unit 113 that performs clock conversion based on the output instruction from the SONET framer 114, the data stored in the FIFO buffer memory does not overflow or the FIFO buffer memory becomes empty. The data sequence of the HD-SDI signal based on the SDI clock can be converted into the data sequence based on the SONET clock, and clock conversion can be realized.

  The invalid part in the non-stationary valid data area and the unused part in the auxiliary data area may be extended slots and used for other purposes. If it is not necessary to use them, all of them should be staffed with a fixed value of 1 or 0.

  In addition, the number of words in the steady valid data area and the non-steady valid data area in the OC-192 frame shown in FIG. 4 is obtained when both the HD-SDI signal and the design value of the frequency fluctuation of the OC-192 frame are ± 100 ppm. In the present invention, the design value of the frequency variation is not limited to ± 100 ppm, and the number of words is not limited to this value. Even when other frequency fluctuation design values are used, the number of words in the stationary effective data area and the non-stationary effective data area can be obtained by the same method. In the OC-192 frame shown in FIG. 4, the unit word is 128 bits. However, in the present invention, the unit word is not limited to 128 bits.

  Returning to FIG. 2, the scrambler 115 receives the parallel signal of the OC-192 frame generated by the SONET framer 114, performs the scramble processing conforming to the SONET standard of ANSI T1.105, and generates the parity generation unit 116 and the serializer. It outputs to 117.

  The parity generation unit 116 receives the OC-192 frame parallel signal scrambled by the scrambler 115, performs bit interleave parity processing in accordance with the ANSI T1.105 SONET standard, generates a SONET parity signal, and performs SONET. Output to the framer 114. The SONET parity signal fed back to the SONET framer 114 is accommodated in the SOH of the OC-192 frame.

  The serializer 117 receives the OC-192 frame parallel signal scrambled by the scrambler 115, converts the data string of the parallel signal into a serial signal, and outputs the serial signal to the E / O converter 118. When the SONET framer 114 and the scrambler 115 are not processed using the parallel signal of the OC-192 frame, the serializer 117 is not necessary.

  The E / O conversion unit 118 receives the OC-192 frame serial signal converted by the serializer 117, converts the electrical signal into an optical signal, and transmits the optical signal as an optical signal conforming to one OC-192 frame.

  As described above, the frame conversion unit 11 of the transmission apparatus 1 receives the four lines of Dual Link HD-SDI signals A1 to A4 and B1 to B4 constituting the signal group G1 which is an uncompressed SHV signal, and receives predetermined data. The data sequence of the HD-SDI signal based on the SDI clock is converted to the data sequence based on the SONET clock, accommodated in the OC-192 frame, and the electrical signal is converted to an optical signal and transmitted to the wide area network 3. . The frame conversion units 12 to 18 also perform data discarding, clock conversion, and OC-192 frame accommodation for the signal groups G2 to G8, and transmit the optical signal of the OC-192 frame to the wide area network 3.

  As a result, the transmission apparatus 1 transmits an uncompressed SHV signal to the wide area network 3 configured by eight OC-192 lines. That is, an uncompressed SHV signal can be transmitted over a long distance using a public optical communication network such as the wide area network 3. In addition, the wide area network 3 using OC-192 line is already widespread, and since the equipment and parts used there can be used as they are, the cost can be reduced as compared with the case of transmitting to the dedicated optical fiber line. be able to. Therefore, the existing wide area network 3 can be used as it is, and efficient long-distance transmission can be realized.

  In FIG. 2, the serializer 117 is provided in the subsequent stage of the scrambler 115, but may be provided in the previous stage of the scrambler 115. That is, after the parallel signal of the OC-192 frame is converted into the serial signal by the serializer 117, the scrambler 115 may input the serial signal of the OC-192 frame from the serializer 117 and perform the scramble process.

(Receiving device / frame reconversion unit)
Next, the frame reconversion unit 21 in the reception apparatus 2 illustrated in FIG. 1 will be described in detail. Since the configuration and processing of the frame reconversion units 22 to 28 are the same as those of the frame reconversion unit 21, description thereof is omitted. FIG. 5 is a block diagram showing a configuration of the frame reconversion unit 21. The frame reconversion unit 21 includes an O / E conversion unit 211, a deserializer 212, a synchronization detection unit 213, a descrambler 214, a SONET deframer 215, a parity determination unit 216, a clock conversion unit 217, an SDI clock control unit 218, and an SDI framer 219. And an SDI output unit 220. The following description assumes that the SDI clock control unit 218 uses the adaptive clock method in order to control the SDI clock. For the adaptive clock method, refer to the document of “ITU-T I.363.1 Recommendation, Chapter 2.5.2.2, Source clock frequency recovery method”.

  When the receiving device 2 receives the optical signals of the eight OC-192 frames from the wide area network 3, the O / E converter 211 receives the one OC-192 frame transmitted by the frame converter 11 of the transmitter 1. The optical signal is input, and the optical signal is converted into an electric signal and output to the deserializer 212.

  The deserializer 212 receives the electrical signal of the OC-192 frame converted by the O / E conversion unit 211, and reproduces the SONET clock by a PLL (Phase Locked Loop) circuit (not shown) based on the electrical signal. The serial signal is converted into a parallel signal and output to the synchronization detection unit 213. Further, the deserializer 212 generates a divided clock from the reproduced SONET clock. This frequency-divided clock is used by the synchronization detection unit 213, the descrambler 214, the SONET deframer 215, the parity determination unit 216, the clock conversion unit 217, and the SDI clock control unit 218.

  The synchronization detection unit 213 receives the OC-192 frame parallel signal converted by the deserializer 212, and detects the frame synchronization signals A1 and A2 compliant with the SONET standard of ANSI T1.105 from the SOH of the OC-192 frame. . Then, the synchronization detection unit 213 outputs a synchronized OC-192 frame parallel signal to the descrambler 214.

  The descrambler 214 receives the synchronized OC-192 frame parallel signal from the synchronization detection unit 213, performs descrambling processing conforming to the ANSI T1.105 SONET standard, and outputs the descrambler 215 to the SONET deframer 215.

  The SONET deframer 215 inputs the parallel signal of the OC-192 frame descrambled by the descrambler 214, performs the reverse processing of the SONET framer 114 shown in FIG. 2, and performs the processing of the OC-192 frame shown in FIG. Valid data strings stored in the steady valid data area and the non-steady valid data area are extracted. The SONET deframer 215 extracts a SONET parity signal accommodated in the SOH of the OC-192 frame. The SONET deframer 215 outputs the valid data sequence to the clock conversion unit 217 as a data sequence of the SONET clock, and outputs the SONET parity signal to the parity determination unit 216.

  When a SDI clock control unit 218 described later generates an SDI clock using the SRTS method, the SONET deframer 215 extracts a time stamp signal from the SOH of the OC-192 frame. Then, the SONET deframer 215 outputs a type stamp signal to the SDI clock control unit 218.

  The parity determination unit 216 receives the SONET parity signal from the SONET deframer 215 and detects an error based on the SONET parity signal.

  The clock conversion unit 217 inputs a data string based on the SONET clock from the SONET deframer 215, inputs an SDI clock from the SDI clock control unit 218, and an output instruction from the SDI framer 219, and converts the data string based on the SONET clock into an HD based on the SDI clock. -Convert to a data string of SDI signal and output to SDI framer 219. Specifically, the clock conversion unit 217 includes a FIFO buffer memory, and stores the input data string based on the SONET clock in the FIFO buffer memory according to the divided clock generated from the SONET clock in the deserializer 212. To do. Then, the clock conversion unit 217 reads data from the FIFO buffer according to the input timing of the SDI clock while the output instruction is input, and outputs the data as a data string of the HD-SDI signal based on the SDI clock.

  As a result, the data string based on the SONET clock is converted into the data string of the HD-SDI signal based on the SDI clock without overflowing the data stored in the FIFO buffer memory or emptying the FIFO buffer memory. And clock conversion can be realized.

  Further, the clock conversion unit 217 obtains the amount of data (data amount) stored in the FIFO buffer memory, and outputs it to the SDI clock control unit 218 as the FIFO remaining amount. When the SDI clock control unit 218 described later generates an SDI clock using the SRTS method, the clock conversion unit 217 does not output the remaining FIFO amount to the SDI clock control unit 218.

  The SDI clock control unit 218 receives the FIFO remaining amount from the clock conversion unit 217, generates a SDI clock by controlling a variable frequency oscillator or the like (not shown), and outputs the SDI clock to the clock conversion unit 217. Specifically, the SDI clock control unit 218 compares the value of the FIFO remaining amount with a preset threshold value, and when the FIFO remaining amount value is equal to or less than the threshold value, the timing for reading data from the FIFO buffer storage is delayed. Therefore, the interval of the output timing of the SDI clock is widened. On the other hand, when the FIFO remaining amount value is larger than the threshold value, the output timing interval of the SDI clock is narrowed in order to speed up the timing for reading data from the FIFO buffer memory.

  The SDI clock control unit 218 receives a time stamp signal from the SONET deframer 215 and inputs a divided clock generated from the SONET clock in the deserializer 212 when the SDI clock is generated using the SRTS method. Based on the time stamp signal, an SDI clock is generated and output to the clock converter 217. Since the time stamp signal is a signal generated based on the SDI clock in accordance with the timing of the SONET clock in the transmission apparatus 1, the time difference between the SONET clock and the SDI clock is reflected. Therefore, the SDI clock can be generated by using the SONET frequency-divided clock and the signal reflecting the time difference between the SONET clock and the SDI clock, which are time stamp signals.

  The SDI framer 219 receives the data sequence of the HD-SDI signal based on the SDI clock from the clock conversion unit 217 and performs the reverse processing of the SDI deframer 112 shown in FIG. 3, that is, restores the data discarded in the SDI deframer 112. Then, the moved data is restored, and the four HD-SDI signals A1 to A4 and B1 to B4 are generated and output to the SDI output unit 220.

  Specifically, the SDI framer 219 detects the synchronization byte of the HD-SDI signal from the data string of the HD-SDI signal, and uses the positions of the detected synchronization byte as a reference, and the HD-SDI signals A2 to A4, B1 to B1. A BNC HANC data area is secured. The SDI framer 219 extracts the HANC data of the HD-SDI signal A1 with reference to the position of the detected synchronization byte of the HD-SDI signal A1, and from the HANC data, the HD-SDI signal A2- When the valid data in the HANC data of A4, B1 to B4 is moved to the HD-SDI signal A1, the position information of the movement source and the movement destination is extracted, and the valid data accommodated in the HANC of the HD-SDI signal A1 is the original. Return to the HANC of the HD-SDI signals A2 to A4 and B1 to B4. Thereby, the HANC data of the HD-SDI signals A2 to A4 and B1 to B4 discarded in the transmission device 1 can be restored. In addition, the SDI framer 219 extracts pixel data (pixel information) based on the positions of the detected synchronization bytes of the HD-SDI signals B1 to B4, and restores parity bits (2 bits) based on the pixel data. , Restore the original stuff bits (2 bits).

  In addition, the SDI framer 219 is used to accommodate data in the frame of the HD-SDI signal (in order to map data to the synchronization byte, pixel data, HANC data, and VANC data areas of the HD-SDI signal), that is, In order to restore the four systems of HD-SDI signals A1 to A4 and B1 to B4, a timing clock for reading data from the FIFO buffer memory of the clock converter 217 is generated by the SDI clock controller 218. It generates based on the SDI clock and outputs it to the clock converter 217 as an output instruction. Specifically, for the HD-SDI signal A1, the SDI framer 219 outputs, to the clock conversion unit 217, an instruction to output the synchronization byte, pixel data, HANC data, and VANC data, and corresponds to each output instruction. The received data is input and accommodated in each area of the HD-SDI signal A1. As for the HD-SDI signal A1, the synchronization byte, pixel data, HANC data, and VANC data can be input from the FIFO buffer memory of the clock converter 217. In addition, the SDI framer 219 outputs, to the clock conversion unit 217, an output instruction of the timing for accommodating each of the synchronization bytes, pixel data, and VANC data of the HD-SDI signals A2 to A4 and B1 to B4. Data corresponding to the output instruction is input and accommodated in a frame of HD-SDI signals A2 to A4, B1 to B4, synchronization bytes, pixel data, and VANC data. For the HD-SDI signals B1 to B4, the parity bit and the stuff bit are restored and accommodated. In addition, the SDI framer 219 does not output an output instruction to the clock conversion unit 217 at the timing of accommodating the HANC data of the HD-SDI signals A2 to A4 and B1 to B4. At this timing, as described above, a process for securing the HANC data area and moving valid data from the HANC of the HD-SDI signal A1 is performed.

  In this way, the SDI framer 219 outputs an output instruction to the clock conversion unit 217, inputs data corresponding to the output instruction from the clock conversion unit 217, and restores data discarded in the SDI deframer 112 of the transmission device 1. By restoring the moved data, the data can be accommodated in each area of the SDI signal. In this way, the four HD-SDI signals A1 to A4 and B1 to B4 can be restored.

  The SDI output unit 220 inputs four HD-SDI signals A1 to A4 and B1 to B4 from the SDI framer 219, performs processing for compensating frequency characteristics and impedance conversion processing, and performs four HD-SDI signals. A1 to A4 and B1 to B4 are output. Further, when the deserializer 212 to the SDI framer 219 use a parallel signal such as 10 bits or 20 bits, the SDI output unit 220 converts the input parallel signal into a serial signal.

  As described above, the frame re-conversion unit 21 of the receiving device 2 converts the optical signal of the OC-192 frame received from the wide area network 3 into an electric signal, and converts the data string based on the SONET clock into the HD-SDI signal based on the SDI clock. The four data of the Dual Link HD-SDI signals A1 to A4 constituting the signal group G1 which is an uncompressed SHV signal are restored. , B1 to B4 are generated and output. The frame re-conversion units 22 to 28 also perform clock conversion and data restoration on the signal groups G2 to G8, and each of the four dual link HD-SDI signals A1 to A4 constituting the signal groups G2 to G8. B1 to B4 are generated and output.

  Thereby, the receiving device 2 can generate the original uncompressed SHV signal. That is, the transmission system can transmit the uncompressed SHV signal over a long distance using a public optical communication network such as the wide area network 3. In addition, the wide area network 3 using OC-192 line is already widespread, and since the equipment and parts used there can be used as they are, the cost can be reduced as compared with the case of transmitting to the dedicated optical fiber line. be able to. Therefore, the existing wide area network 3 can be used as it is, and efficient long-distance transmission can be realized.

  The present invention has been described with reference to the embodiment. However, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the technical idea thereof. For example, in the above-described embodiment, the transmission device 1 inputs an uncompressed SHV signal as a Dual Link HD-SDI signal, converts the signal into an OC-192 frame, transmits the frame to the wide area network 3, and the reception device 2 transmits the OC-192. The frame was received and converted to a Dual Link HD-SDI signal to obtain the original uncompressed SHV signal. The present invention does not limit the signal to be transmitted / received to an uncompressed SHV signal, but can also be applied to an uncompressed video signal such as a digital cinema. In other words, the video data handled by the transmission device 1 and the reception device 2 may be not only the SHV signal but also ultra-high definition video data such as a digital cinema.

DESCRIPTION OF SYMBOLS 1 Transmission apparatus 2 Reception apparatus 3 Wide area network 11-18 Frame conversion part 21-28 Frame reconversion part 111 SDI input part 112 SDI deframer 113 Clock conversion part 114 SONET framer 115 Scrambler 116 Parity generation part 117 Serializer 118 E / O conversion Unit 211 O / E conversion unit 212 deserializer 213 synchronization detection unit 214 descrambler 215 SONET deframer 216 parity determination unit 217 clock conversion unit 218 SDI clock control unit 219 SDI framer 220 SDI output unit

Claims (4)

A transmission device that accommodates uncompressed video signal data in a predetermined frame and transmits the data to a wide area network,
Uncompressed video signal is input as a plurality of HD-SDI signals, predetermined HANC data (horizontal auxiliary area data) in the HD-SDI signal is discarded, and parity bits and stuff constituting pixel data in the HD-SDI signal An SDI defframer that discards bits;
Clock conversion for storing HD-SDI signal data in which HANC data, parity bits and stuff bits are discarded by the SDI deframer in a memory according to the clock of the HD-SDI signal, and reading out from the memory in accordance with the clock of the frame And
Based on the clock of the frame, an output instruction is output to the clock converter at a timing when data is accommodated in the payload of the frame, and the output instruction is read from the memory of the clock converter as the clock of the frame. And a framer for receiving the input data in a payload of a frame. The video data transmission device according to claim 1,
The SDI deframer inputs uncompressed video signals as four lines of Dual Link HD-SDI signals A1 to A4 and B1 to B4, and the HANC data of the HD-SDI signals A2 to A4 and B1 to B4 includes valid data. In this case, the valid data is moved to the HANC data area of the HD-SDI signal A1, the HANC data of the HD-SDI signals A2 to A4 and B1 to B4 is discarded, and the pixel data in the HD-SDI signals B1 to B4 is configured. A video data transmitting apparatus characterized by discarding parity bits and stuff bits. A receiving device that receives uncompressed video signal data composed of a plurality of HD-SDI signals as a predetermined frame from a wide area network,
The predetermined HANC data in the HD-SDI signal is discarded by the video data transmitting device, and the parity information and the stuff bit out of the pixel information, parity bits and stuff bits constituting the pixel data in the HD-SDI signal are discarded. When the HD-SDI signal data in which the HANC data, the parity bit and the stuff bit are discarded is stored in a payload together with identification information indicating the position of the discarded HANC data and transmitted as a frame to the wide area network. ,
A deframer for extracting data from the payload of the received frame;
A clock converter that stores data of the frame extracted by the deframer in a storage device according to the clock of the frame, and reads out from the storage device according to the clock of the HD-SDI signal;
A clock control unit that determines a clock timing of the HD-SDI signal based on an amount of data stored in a memory of the clock conversion unit, and generates a clock of the HD-SDI signal;
Based on the clock of the HD-SDI signal generated by the clock control unit, an output instruction is output to the clock conversion unit at a timing of storing data in the area of the HD-SDI signal, and the output instruction and the HD-SDI The data read from the memory of the clock conversion unit is input according to the clock of the SDI signal, the HANC data is restored based on the identification information of the HANC data discarded by the video data transmitting device, and the pixel data is configured And a framer for restoring the parity bit and the stuff bit from the pixel information to generate an original HD-SDI signal. The video data receiving device according to claim 3,
By the video data transmitting device, a time stamp signal including a time difference between the clock of the frame and the clock of the HD-SDI signal is accommodated in the frame,
The clock control unit determines a clock timing of the HD-SDI signal based on the time stamp signal transmitted from the video data transmission apparatus and the clock of the frame, and generates a clock of the HD-SDI signal. A video data receiving apparatus characterized by the above.

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