JP2011223395A - Error-correction encoding apparatus, error-correction decoding apparatus, receiving apparatus, and transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To recognize an HD-SDI signal in a transmission system of the HD-SDI signal.SOLUTION: An error-correction encoding apparatus 10 comprises: error-correction encoding data extraction means 102 which extracts data to be encoded from HD-SDI data; error-correction encoding means 105 which encodes the data to be encoded through the use of an abbreviated RS code to generate parity data; error-correction parity rearrangement means 106 which rearranges bits of parity data and identification code to generate rearranged data in order to avoid predetermined prohibited words; and error-correction parity insertion means 103 which inserts the rearranged data into an auxiliary data region of an HD-SDI signal. In this way, the HD-SDI signal is multiplexed and transmitted to a receiving apparatus 2. The receiving apparatus 2 extracts the identification code from the auxiliary data region, generates identification information, and displays the information on HD-SDI signal identification information display means 209.

Description

  The present invention relates to an error correction coding apparatus, error correction decoding apparatus, receiving apparatus, and transmission system that perform error correction of a digital video signal, and in particular, an HD configured in a data format of HD-SDI, which is a serial digital interface standard. -It relates to a technique for multiplexing and transmitting SDI signals.

  Conventionally, for example, a device described in Non-Patent Document 1 is known as a device for transmitting a large-capacity digital video signal. This apparatus wirelessly transmits a plurality of uncompressed digital hi-vision signals using radio waves. Specifically, in a transmission system including three transmission devices and three reception devices, the three transmission devices have 16 HD-SDI signals that are dual green super hi-vision signals. Is encoded and multiplexed, and transmitted to the three receivers via the transmission path. Then, the three receiving devices receive the HD-SDI signal multiplexed from the transmitting device via the transmission path, and separate and decode each HD-SDI signal to obtain the original 16 HD-SDI signals. Output a signal.

  In such a transmission system, the transmission device inputs a plurality of HD-SDI signals, and the reception device outputs a plurality of HD-SDI signals. In order to input a plurality of HD-SDI signals to the transmitting device, cables corresponding to the number of HD-SDI signals are connected, and in order to output a plurality of HD-SDI signals to the receiving device as well, HD-SDI signals are output. As many cables as there are signals are connected. Here, it is necessary that the plurality of cables for outputting the HD-SDI signal correspond to the plurality of output terminals provided in the receiving apparatus, and the user connects each cable to an appropriate output terminal. Thus, a transmission system is established.

  On the other hand, as a transmission system that realizes transmission of a highly reliable HD-SDI signal, for example, the one described in Patent Document 1 is known. This transmission system includes a transmission device that performs error correction coding on an HD-SDI signal, multiplexes and transmits the signal, and a reception device that separates an HD-SDI signal and performs error correction decoding. Specifically, the transmission apparatus encodes the HD-SDI signal, and generates a bit unit for each predetermined number of generated parity data so that the parity data of the error correction code generated by the encoding does not match the data of the prohibited word. The rearranged parity data is inserted into the auxiliary data area of the HD-SDI signal, and a plurality of HD-SDI signals are multiplexed and transmitted to the receiving apparatus. The receiving device receives the multiplexed HD-SDI signals, separates them into HD-SDI signals, extracts the parity data from the auxiliary data area of the HD-SDI signal, rearranges the original parity data, The HD-SDI signal is error-corrected and decoded using the parity data. Thereby, since error correction of the HD-SDI signal is performed, highly reliable transmission can be realized.

JP 2009-89130 A

Okabe and 7 others, “SHV transmission experiment using 120 GHz band wireless transmission device”, August 2009, 2009 Annual Conference of the Institute of Image Information and Television Engineers, 16-5

  In the transmission system described in Non-Patent Document 1 described above, 16 HD-SDI signals are input to three transmission apparatuses via 16 cables, and 16 HD-SDI signals are 16 in number. Are output from three receivers via the cable. However, in such a transmission system, there is no means for specifically identifying which of the 16 HD-SDI signals the HD-SDI signal is in the receiving apparatus. That is, in the conventional transmission system, individual HD-SDI signals cannot be distinguished from a plurality of HD-SDI signals. For this reason, when connecting a plurality of cables that output HD-SDI signals to the output terminal of the receiving device, the user needs to perform cable connection work while contacting the user who operates the transmitting device. There was a problem that the cable could be connected by mistake.

  In order to solve the above problems, an object of the present invention is to provide an error correction encoding device, an error correction decoding device, a receiving device, and a device capable of identifying an HD-SDI signal in a system for transmitting an HD-SDI signal. It is to provide a transmission system.

  In order to solve the above-mentioned problems, an error correction coding apparatus according to claim 1 of the present invention provides error correction to an HD-SDI signal configured in an HD-SDI data format that is a standard of a serial digital interface for high-definition signals. In an error correction encoding apparatus that multiplexes parity data generated by encoding the HD-SDI signal with a code, the serial signal format HD-SDI signal is converted into parallel signal format HD-SDI data. A parallel conversion unit; an encoding target data extraction unit that extracts encoding target data of the error correction encoding from the HD-SDI data converted by the serial / parallel conversion unit; and the encoding target data extraction unit. The extracted encoding target data is encoded by the error correction code, and the Paris Encoding unit that generates data, the parity data generated by the encoding unit, and the identification code for identifying the HD-SDI signal are arranged in bit units so as not to match the data of a predetermined prohibited word. Rearrangement means for generating rearrangement data including the rearranged parity data and identification code, and rearrangement data including the parity data and the identification code generated by the rearrangement means, Parity insertion means for inserting into a predetermined area secured in the auxiliary data area in the data, and parallel signal format HD-SDI data including the rearranged data inserted by the parity insertion means are converted into serial signal format HD-SDI signals. And a parallel / serial conversion means for converting the data into a serial data.

  An error correction encoding apparatus according to claim 2 of the present invention is the error correction encoding apparatus according to claim 1, wherein the rearranging means is identical in a predetermined number of parity data generated by the encoding means. By connecting bit data at a bit position and a prohibited word avoidance bit for avoiding a predetermined prohibited word, rearrangement data including at least the bit data and the prohibited word avoidance bit is generated, and the rearrangement data Of these, an identification code for identifying the HD-SDI signal is inserted into a spare data area other than the bit data and the prohibited word avoidance bit.

  According to a third aspect of the present invention, there is provided an error correction coding apparatus according to the first or second aspect of the present invention, wherein in the error correction coding apparatus according to the first or second aspect, the encoding means sets an information data length when performing the error correction coding. The encoding target data is encoded by a shortened Reed-Solomon code shortened to the data length of the encoding target data extracted from the HD-SDI data.

  According to a fourth aspect of the present invention, there is provided an error correction coding apparatus according to the third aspect, wherein the coding means shortens the Reed-Solomon (1023, 1003) code. The encoding target data is encoded by a Solomon (986,966) code.

  An error correction coding apparatus according to a fifth aspect of the present invention is the error correction coding apparatus according to any one of the first to fourth aspects, wherein the rearranging means includes the parity data and 1 Sorting data including a plurality of identification codes is generated.

  An error correction coding apparatus according to a sixth aspect of the present invention is the error correction coding apparatus according to any one of the first to fourth aspects, wherein the rearranging means includes the parity data and a plurality of identifications. Rearrangement data including a code is generated, and the plurality of identification codes are all the same code.

  An error correction coding apparatus according to a seventh aspect of the present invention is the error correction coding apparatus according to any one of the first to fourth aspects, wherein the serial-to-parallel conversion means is a predetermined word unit. Converting into HD-SDI data in a parallel signal format, the encoding unit generates the parity data in word units by the error correction code, and the rearranging unit is based on the parity data in word units and one word length Rearrangement data including an identification code having a small number of bits is generated.

  Furthermore, an error correction decoding apparatus according to an eighth aspect of the present invention is such that parity data is multiplexed by the error correction encoding apparatus according to any one of the first to seventh aspects, and the HD-SDI signal is In an error correction decoding apparatus for inputting an HD-SDI signal in a serial signal format in which an identification code for identification is multiplexed and decoding the HD-SDI signal by the error correction code, the HD-SDI in the serial signal format is used. From the serial / parallel conversion means for converting the signal into HD-SDI data in a parallel signal format, and the predetermined area secured in the auxiliary data area in the HD-SDI data converted by the serial / parallel conversion means Arrangement including parity data and identification code that has been rearranged bit by bit so that it does not match the data of the prohibited word Parity extraction means for extracting data, decoding target data extraction means for extracting decoding target data for error correction decoding from the HD-SDI data converted by the serial / parallel conversion means, and extraction by the parity extraction means For the rearranged data, a process reverse to the rearrangement is performed, using the parity rearrangement means for generating the original parity data and the identification code, and the parity data generated by the parity rearrangement means, Decoding target data extracted by the decoding target data extraction means is decoded by the error correction code to generate decoded data; decoding target data of the HD-SDI data is converted to the decoding process Data replacement means for replacing the decrypted data generated by the means, and the data replacement Identifying the HD-SDI signal generated by the parallel-serial conversion means for converting the HD-SDI data replaced with the decoded data by the means into an HD-SDI signal in a serial signal format, and the parity rearranging means And an identification code output means for outputting an identification code for the purpose.

  The error correction decoding device according to claim 9 of the present invention is the error correction decoding device according to claim 8, wherein the serial-to-parallel conversion means multiplexes the parity data, and the HD-SDI signal. A serial signal format HD-SDI signal in which a plurality of identification codes, all of which are the same identification code are multiplexed, is converted into parallel signal format HD-SDI data, and the identification code output means A plurality of identification codes generated by the parity rearranging means is specified by a majority decision, and the specified identification code is output.

  Furthermore, a receiving apparatus according to claim 10 of the present invention is the receiving apparatus provided with one or a plurality of error correction decoding apparatuses according to claim 8 or 9, and is output by the identification code output means of the error correction decoding apparatus. And a display for displaying the identification code.

  According to the 11th aspect of the present invention, there is provided a receiving apparatus comprising a plurality of the error correction decoding apparatuses according to the 8th or 9th aspect, wherein the identification code output by the identification code output means is A switching control device that generates a switching signal for each error correction decoding device according to a predetermined table that is input for each error correction decoding device and that defines the correspondence between identification codes and output terminals, and the parallel-serial conversion means The converted serial signal format HD-SDI signal is input to each error correction decoding device, the switching signal for each error correction decoding device generated by the switching control device is input, and based on the switching signal, The HD-SDI signal for each error correction decoding device is switched to select one HD-SDI signal and defined in the predetermined table. The HD-SDI signals of the identification code has, characterized in that and a switching device for outputting to the outside from an output terminal corresponding to the identification code.

  Furthermore, a transmission system according to a twelfth aspect of the present invention includes a transmission device including one or a plurality of the error correction encoding devices according to any one of the first to seventh aspects, and the error correction according to the eighth or ninth aspect. The reception apparatus includes one or more decoding devices.

  As described above, according to the present invention, the error correction encoding apparatus encodes the HD-SDI data by error correction, rearranges the parity data generated by the encoding, and the identification code of the HD-SDI signal. And inserted into a predetermined area secured in the auxiliary data area in the HD-SDI data to generate an HD-SDI signal including parity data and an identification code. Further, the error correction decoding apparatus inputs an HD-SDI signal including parity data and an identification code, extracts the parity data and the identification code from a predetermined area secured in the auxiliary data area in the HD-SDI data, and stores the parity data. Using this, error correction decoding was performed and an identification code was output. Thereby, it is possible to identify what kind of signal the HD-SDI signal is based on the identification code. Therefore, by recognizing the identification information of the HD-SDI signal by displaying on the display unit or the like, the user can correctly connect the cable when connecting the cable that outputs the HD-SDI signal. Connection can be prevented.

1 is a diagram illustrating an overall configuration of a transmission system according to an embodiment of the present invention. It is a figure explaining the structure of an HD-SDI signal. It is a block diagram which shows the structure of the transmitter and receiving apparatus by embodiment of this invention. It is a block diagram which shows the structure of the error correction coding apparatus by embodiment of this invention. It is a figure explaining the example of arrangement | positioning of the parity data after rearrangement. It is a figure explaining the example which stored the identification code of 1 word in the reserve area | region. It is a figure explaining the example which stored the identification code of 5 words in the reserve area | region. It is a figure explaining the example which stored the identification code of 1/2 word in the reserve area | region. It is a block diagram which shows the structure of the error correction decoding apparatus by embodiment of this invention. It is a figure which shows the display of HD-SDI signal identification information, and the output terminal of HD-SDI signal. It is a block diagram which shows the modification of a receiver. It is a figure explaining the 1st application example of a transmission system. It is a figure explaining the 2nd application example of a transmission system. It is a figure explaining the 3rd application example of a transmission system. It is a figure which shows the display of other HD-SDI signal identification information, and the output terminal of HD-SDI signal. It is a flowchart which shows the process sequence of an error correction coding apparatus. It is a flowchart which shows the process sequence of an error correction decoding apparatus.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
[Transmission system]
First, the overall configuration of a transmission system that transmits a digital video signal will be described. FIG. 1 is a diagram showing an overall configuration of a transmission system according to an embodiment of the present invention. The transmission system 3 is a system that multiplexes and transmits a plurality of HD-SDI signals configured in the HD-SDI data format, which is the standard of a serial digital interface for high-definition signals. Composed. The transmission device 1 and the reception device 2 are connected by a transmission path 7.

  The transmission device 1 encodes each of the plurality of HD-SDI signals using an error correction code. Then, the parity data generated by encoding and the code (identification code) for identifying the HD-SDI signal are multiplexed and inserted into the HD-SDI signal, and a plurality of HD-SDI signals are multiplexed. A transmission signal is generated and transmitted to the receiving device 2 via the transmission path 7.

  The reception device 2 receives the transmission signal transmitted from the transmission device 1 and separates a plurality of HD-SDI signals multiplexed from the transmission signal. Then, error correction decoding is performed using parity data with the same error correction code used in the transmission apparatus 1, an identification code is extracted, and an identification code of the original plurality of HD-SDI signals and HD-SDI signals is output. To do.

  The transmission path 7 is a communication path through which a plurality of multiplexed HD-SDI signals are transmitted as transmission signals from the transmission apparatus 1 to the reception apparatus 2. For example, a unidirectional wireless or wired communication path.

[HD-SDI signal]
The HD-SDI signal is a serial digital interface standard signal that multiplexes and transmits uncompressed HDTV video and audio signals, which is standardized by SMPTE (Society of Motion Picture and Television Engineers) 292M.

  FIG. 2 is a diagram illustrating the configuration (format) of the HD-SDI signal. As shown in FIG. 2, the HD-SDI signal includes EAV (End of Active Video), LN (Line Number), CRCC (Cyclic Redundancy Check Code), auxiliary data, SAV (Start of Active Video) data. Active line). EAV is an identifier indicating the end of a valid video data period, and the size is 4 words. LN is data indicating a line number and has a size of 2 words. CRCC is error detection code data and has a size of 268 words. SAV is an identifier indicating the start of a period of valid video data and has a size of 4 words.

  The auxiliary data is audio data, time code data, parity data, identification code, and the like, and the size is 268 words. In this auxiliary data area (auxiliary data area, ancillary area, HANC area), as described in Patent Document 1, an area for storing parity data is secured. The parity data area in the auxiliary data area includes an area where rearranged parity data is stored and a spare area where rearranged parity data is not stored. The spare area is used to identify an HD-SDI signal. A code (identification code) is stored. Note that predetermined data (prohibited words) cannot be stored in the auxiliary data area. For this reason, when the parity data and the identification code are stored in the parity data area, the parity data and the identification code are rearranged so as not to coincide with the data of the prohibited word (to avoid the prohibited word). That is, the parity data and the identification code are rearranged and multiplexed so as to avoid the prohibited word, and the multiplexed data is stored as rearranged data in the parity data area in the auxiliary data area. Details will be described later.

  The video data is composed of a digital signal having a luminance (Y) signal of 10 bits and a color difference (Pb · Pr) signal of 10 bits per pixel of video, and has a size of 1920 words. As described above, the HD-SDI signal is transmitted in the form of a serial signal by multiplexing video data and auxiliary data with EAV, LN, CRCC, and SAV synchronization signals.

[Transmitting device and receiving device]
Next, the configuration of the transmission device 1 and the reception device 2 illustrated in FIG. 1 will be described. FIG. 3 is a block diagram illustrating configurations of the transmission device 1 and the reception device 2. First, the configuration of the transmission device 1 will be described. The transmission apparatus 1 includes error correction encoding apparatuses 10-1 to 10-6, a multiplexing apparatus 11, and a transmitter 12. The transmission apparatus 1 inputs six HD-SDI signals, encodes each HD-SDI signal, multiplexes HD-SDI signals including parity data generated by encoding and identification codes of the respective signals, and transmits them. The data is transmitted to the receiving device 2 via the path 7.

  The error correction encoding device 10-1 of the transmission device 1 receives the first system HD-SDI signal and encodes the HD-SDI signal with a predetermined error correction code. Then, the error correction coding apparatus 10-1 inserts the parity data generated by the coding into the parity data area secured in the auxiliary data area of the HD-SDI signal and also the identification code of the HD-SDI signal. The data is inserted into the parity data area (a spare area where no parity data is stored in the parity data area), and the HD-SDI signal including the parity data and the identification code is output to the multiplexer 11.

  Error correction encoders 10-2 to 10-6 each receive second to sixth HD-SDI signals, perform the same processing as error correction encoder 10-1, and perform parity data and identification. The HD-SDI signal including the code is output to the multiplexer 11. Since the identification code is a code for identifying the HD-SDI signals of the first system to the sixth system, the receiving apparatus 2 to be described later uses the HD-SDIs of the first system to the sixth system based on this identification code. Among the SDI signals, it is possible to specify which type of HD-SDI signal.

  The multiplexer 11 receives HD-SDI signals including parity data and identification codes from the error correction encoders 10-1 to 10-6, multiplexes these six HD-SDI signals, and generates a multiplexed signal. To the transmitter 12.

  The transmitter 12 receives the multiplexed signal from the multiplexer 11, converts it into a signal of a preset transmission format, and transmits it as a transmission signal to the receiver 2 via the transmission path 7. Here, converting to a preset transmission format signal means, for example, processing such as parallel / serial conversion and signal amplification, converting an electrical signal into an optical signal, or converting into a radio signal. Say.

  Next, the configuration of the receiving device 2 will be described. Referring to FIG. 3, the receiving device 2 includes a receiver 20, a separating device 21, and error correction decoding devices 22-1 to 22-6. The receiving device 2 receives a transmission signal from the transmitting device 1 via the transmission path 7, separates six multiplexed HD-SDI signals from the transmission signal, extracts parity data and an identification code, and extracts the parity data. Error correction decoding is performed, and the original 6-system HD-SDI signals and identification codes are output.

  The receiver 20 of the receiving device 2 receives a transmission signal from the transmitting device 1 via the transmission path 7, and performs an electrical signal for performing processing described later on the received transmission signal in the form of electricity, light, or radio wave. And output to the separation device 21.

  The demultiplexer 21 receives a signal from the receiver 20, performs a demultiplexing process that is the reverse of the multiplexing process performed by the demultiplexer 11 of the transmission apparatus 1, and performs error correction coding apparatuses 10-1 to 10-10 of the transmission apparatus 1. It returns to the HD-SDI signal for 6 systems after the error correction coding by -6. Then, the separation device 21 outputs the first to sixth HD-SDI signals after error correction coding, which are separated signals, to the error correction decoding devices 22-1 to 22-6, respectively.

  The error correction decoding device 22-1 receives the HD-SDI signal of the first system after error correction coding, and receives parity data and an identification code from the parity data area secured in the auxiliary data area of the HD-SDI signal. Extraction is performed, error correction decoding is performed using the parity data, and the original first-system HD-SDI signal and identification code are output.

  The error correction decoding devices 22-2 to 22-6 receive the second to sixth HD-SDI signals after error correction coding, respectively, and perform the same processing as the error correction decoding device 22-1. The original second to sixth HD-SDI signals and identification codes are output.

[Error correction coding device]
Next, error correction encoding apparatuses 10-1 to 10-6 (hereinafter collectively referred to as error correction encoding apparatus 10) shown in FIG. 3 will be described. FIG. 4 is a block diagram showing the configuration of the error correction coding apparatus 10. This error correction encoding apparatus 10 includes a serial / parallel conversion unit 101, an error correction encoding target data extraction unit 102, an error correction parity insertion unit 103, a parallel / serial conversion unit 104, an error correction encoding unit 105, an error correction parity. Rearranging means 106, HD-SDI signal identification information input means 107, and HD-SDI signal identification code generation means 108 are provided.

  As described above, the error correction encoding apparatus 10 encodes the HD-SDI signal configured in the HD-SDI data format using the error correction code, and converts the parity data generated by the encoding into auxiliary data of the HD-SDI signal. The HD-SDI signal identification code is also inserted into the parity data area (empty area in which no parity data is stored) in the auxiliary data area of the HD-SDI signal. An HD-SDI signal including the identification code is output.

  The serial / parallel conversion means 101 receives an HD-SDI signal in a serial signal format that is a serial digital signal, converts serial data into parallel data in units of one word (10 bits), and a parallel signal format that is a parallel digital signal. The HD-SDI data is output to the error correction encoding target data extraction unit 102.

  The error correction encoding target data extraction means 102 receives the HD-SDI data from the serial / parallel conversion means 101, extracts preset error correction encoding target data, and encodes the encoding target data with error correction encoding. The data is output to the means 105 and the input HD-SDI data is output to the error correction parity insertion means 103. Specifically, the error correction encoding target data extraction unit 102 includes a total 1932 of EAV, LN, CRCC, SAV and video data (digital active line) among the data for one video line of the input HD-SDI data. A word is extracted as data to be encoded. Then, the error correction encoding target data extraction unit 102 outputs the extracted encoding target data to the error correction encoding unit 105. Further, the error correction encoding target data extraction unit 102 outputs the input HD-SDI data to the error correction parity insertion unit 103 as it is.

  The error correction parity insertion unit 103 receives HD-SDI data from the error correction encoding target data extraction unit 102 and also inputs rearrangement data (parity data and identification code) from an error correction parity rearrangement unit 106 described later. . Then, the error correction parity insertion means 103 inserts the rearranged data into the parity data area secured in the auxiliary data area in the HD-SDI data in accordance with the auxiliary data multiplexing standard defined in the HD-SDI standard, The HD-SDI data including the parity data and the identification code is output to the parallel / serial conversion means 104.

  The parallel / serial conversion means 104 receives the parallel signal format parity data, which is a parallel digital signal, and HD-SDI data including the identification code from the error correction parity insertion means 103, converts the parallel data into serial data, and converts the serial data into serial digital data. A serial signal format HD-SDI signal as a signal is output to the outside.

  The error correction encoding unit 105 receives the encoding target data from the error correction encoding target data extraction unit 102, encodes the encoding target data with a predetermined error correction code, and generates error correction parity data. Then, the error correction encoding unit 105 outputs the generated parity data to the error correction parity rearranging unit 106. Here, the error correction encoding means 105 uses a Reed-Solomon (986,966) code as the error correction code, divides the 1932-word encoding target data into two parts, performs encoding for each 966 words, 20-word parity data is generated for 966-word encoding target data. The RS (986,966) code is a shortened RS code obtained by shortening the information data length of the RS (1023, 1003) code. For details of the encoding method using the RS (986,966) code, refer to Patent Document 1.

  As described above, the error correction encoding unit 105 performs encoding for each 966 (= 1932/2) obtained by dividing the 1932-word encoding target data into two by the RS (986,966) code which is a shortened RS code. I did it. Thereby, since the encoding process suitable for the size of the encoding target data can be performed, the efficiency of the encoding process can be improved, and the processing load can be reduced.

  The error correction parity rearranging means 106 receives the parity data from the error correction encoding means 105 and also receives the HD-SDI signal identification code from the HD-SDI signal identification code generation means 108 described later. Then, the error correction parity rearranging means 106 rearranges the bits constituting the parity data according to a predetermined rearrangement rule in order to avoid that the parity data and the identification code become the same data as the predetermined prohibited word. The identification code is inserted into the empty area generated by the rearrangement, the rearrangement data (parity data and the identification code) is generated by multiplexing the parity data and the identification code, and is output to the error correction parity insertion means 103. . That is, the error correction parity rearranging means 106 rearranges the bits constituting the parity data and the identification code, and generates rearranged data (parity data and identification code) in which the parity data and the identification code are multiplexed.

  For example, as shown in FIG. 5 to be described later, the error correction parity rearranging unit 106 sets the bit (first to ninth bits) of the same bit position and the prohibited word for each parity data of 9 words. Forbidden word avoidance bits (tenth bit) for avoidance are concatenated, and rearranged data in units of words in which parity data of 9 words are rearranged is sequentially generated. Similarly, the error correction parity rearranging means 106, for 4 words of parity data, the bit at the same bit position (first to fourth bits) and the prohibited word avoidance bit (tenth bit) for avoiding the prohibited word. And the rearranged data in units of words obtained by rearranging the parity data of 4 words. In this case, a 5-word spare area is generated at the fifth to ninth bits, and an identification code is inserted into this spare area. In FIG. 5, the data before rearrangement is horizontally arranged data arranged in units of one word, and the rearranged data is vertically arranged data arranged in units of one word. Details will be described later.

  Here, the error correction parity rearrangement means 106 inputs 40-word parity data for the data to be encoded of 1932 words for the data for one line of video, and performs a predetermined rearrangement in order to avoid prohibited words. According to the rule, the bits constituting the parity data are rearranged, the identification code is inserted into the spare data area, and 50-word rearrangement data (parity data and identification code) is generated as will be described later. That is, in the auxiliary data area of the HD-SDI signal, a parity data area of 50 words for storing rearrangement data is secured for one line of video.

  FIG. 5 is a diagram for explaining an arrangement example of the parity data after the rearrangement process by the error correction parity rearrangement unit 106. The error correction parity rearrangement means 106 uses 50-word rearrangement data (vertical arrangement arranged in units of one word) from 40-word parity data (horizontal arrangement data arranged in units of one word) for 1932-word encoding target data. The parity data is arranged in the RS area shown in FIG. The error correction parity rearranging means 106 arranges parity data in the RS (Parity 1) to RS (Parity 40) region in which the bits are arranged side by side. Further, the error correction parity rearranging means 106 avoids forbidden words, and an RS (Parity 9, 18, 27, 36) region corresponding to the ninth bit when 10 bits in the vertical arrangement are defined as one word, and The data of the reserved area (Reserved) is inverted, and the inverted data is arranged in the area of the inverted word of the 9th bit (area corresponding to the 10th bit when 10 bits vertically aligned are 1 word). To do.

  An area of 50 words in which the rearranged data is stored is secured as a parity data area in the auxiliary data area of the HD-SDI signal. In this 50-word area, 40-word parity data, 5-word data (data generated by inverting the 9th bit) to avoid prohibited words, and any 5-word data (in the spare area) Stored spare data). The spare area is an area in which parity data (including an inverted word area of the 9th bit) is not stored, and an identification code for identifying the HD-SDI signal is stored as will be described later.

  In the HD-SDI standard, a predetermined prohibited word is defined in order to avoid overlapping with other control codes in the auxiliary data area. The same data as the predetermined prohibited word cannot be stored in the auxiliary data area. As 10 bits / 1 word, data of 000h, 001h, 002h, 003h, 3FCh, 3FDh, 3FEh, and 3FFh are prohibited words (h indicates a hexadecimal number). In this case, in order not to store the same data as these prohibited words in the auxiliary data area, only the first bit of the word data for nine words to be stored is collected according to a predetermined rearrangement rule. The 1-bit data obtained by inverting the first bit of the 9th word data to the 9-bit data is connected as the prohibited word avoidance bit to generate 1-word rearranged data. As a result, the rearranged data becomes 1xxh or 2xxh (data in which the 9th and 10th bits are "01" or "10"). Therefore, parity data having the same value as that of the prohibited word is converted into rearranged data other than the prohibited word. The same applies to parity data for 9 words, or parity data for 9 words and an identification code. That is, the error correction parity rearranging means 106 performs rearrangement processing for avoiding the forbidden words, and converts the parity data and the identification code into 1xxxh or 2xxh rearranged data.

  FIG. 6 is a diagram for explaining an example in which a 1-word identification code is stored in the spare area, FIG. 7 is a diagram for explaining an example in which a 5-word identification code is stored in the spare area, and FIG. It is a figure explaining the example which stored the identification code of 1/2 word in the reserve area | region. As described above, the 50-word area shown in FIGS. 6, 7 and 8 (50-word area in which the rearrangement data is stored) is secured as a parity data area in the auxiliary data area of the HD-SDI signal. Is done.

  Referring to FIG. 6, error correction parity rearranging means 106 avoids a prohibited word to avoid a bit (first to ninth bits) at the same bit position for every nine words of parity data. Bits (tenth bit) are concatenated, and rearranged data in units of words obtained by rearranging parity data is sequentially generated. As shown in FIG. 6, the generated rearranged data is data from the first word to the 40th word from the left to the right with 10 bits in the vertical direction as one word.

  Further, the error correction parity rearranging means 106 avoids the bits (first to fourth bits) at the same bit position and the forbidden words in the 4-word parity data (RS (Parity 37) to RS (Parity 40)). Forbidden word avoidance bits (the 10th bit) for this purpose are concatenated, and rearranged data in units of words obtained by rearranging parity data of 4 words is sequentially generated. Spare data is generated in a 5-word area (spare area) from the fifth bit to the ninth bit. As shown in FIG. 6, the generated rearranged data is data from the 41st word to the 50th word from the left to the right with 10 vertical bits as one word. Then, the error correction parity rearranging means 106 receives the HD-SDI signal identification code (one-word identification code) from the HD-SDI signal identification code generating means 108 described later, and the inputted one-word identification code is Stored in the spare area (identification code 1) of the fifth bit from the 41st word to the 50th word. In this case, a 4-word spare area out of a 5-word spare area is an empty area, but separate data may be stored.

  Referring to FIG. 7, error correction parity rearranging section 106 converts the input identification code of one word into the reserved areas (5th to 9th bits from the 41st word to the 50th word) (5 You may make it store in the spare area | region of a word: identification code | cord | chord 1), respectively. Thus, even when a transmission error occurs at the position of the identification code 1 when the transmission signal is transmitted wirelessly or by wire, the receiving device 2 makes a majority decision on the five identification codes. Thus, the HD-SDI signal can be correctly identified, and the tolerance to transmission errors can be increased.

  Referring to FIG. 8, error correction parity rearranging section 106 converts the input identification code into a fifth bit spare area (1/2 word = 5 bit spare) from the 46th word to the 50th word. You may make it store in area | region: identification code | symbol 1). When the identification code of the HD-SDI signal can be expressed by 5 bits, the identification code can be stored in this spare area, and many spare areas can be left. Thereby, data for other purposes can be stored in the spare area, and the spare area can be used effectively.

  The error correction parity rearranging means 106 generates rearranged data by inserting an identification code according to a rearrangement rule for arranging serial parity data in parallel as shown in FIG. 6, FIG. 7 or FIG. However, other sort rules may be used. For example, forbidden word avoidance bits (10th bit) are added to serial parity data (9-bit data), and an identification code is inserted into the spare area to generate rearranged data sequentially. Good. In this case, the forbidden word avoidance bit is added to the serial parity data, so that the data is shifted bit by bit. For details of the rearrangement process, refer to Patent Document 1.

  Also, as shown in FIG. 8, the error correction parity rearranging means 106 stores the input identification code in the spare area of 1/2 word = 5 bits, but can represent the identification code. Within the range, the data may be stored in a spare area having a bit number smaller than one word length.

  Returning to FIG. 4, the HD-SDI signal identification information input means 107 inputs information (identification information) for identifying the HD-SDI signal when the user operates a dip switch (DIPSW), a rotary switch, or the like. Then, the HD-SDI signal identification information is output to the HD-SDI signal identification code generation means 108. For example, when 16 HD-SDI signals are transmitted together, a number that can identify one HD-SDI signal from 16 (any one number between 1 and 16) Is input as identification information.

The HD-SDI signal identification code generation means 108 receives the identification information of the HD-SDI signal from the HD-SDI signal identification information input means 107, encodes the identification information, and generates an identification code. Then, the HD-SDI signal identification code generation unit 108 outputs the identification code of the HD-SDI signal to the error correction parity rearrangement unit 106. For example, when “1” is input as the identification information from the HD-SDI signal identification information input unit 107, the HD-SDI signal identification code generation unit 108 is data of 1 word / 10 bits from the identification information “1”. An identification code of “0000000001” is generated. In this example, since one word has 10 bits, the receiving apparatus 2 can identify 2 ¹⁰ HD-SDI signals.

(Processing procedure of error correction coding apparatus)
Next, the processing procedure of the error correction coding apparatus 10 shown in FIG. 4 will be described. FIG. 16 is a flowchart showing the processing procedure of the error correction coding apparatus 10. First, the serial / parallel conversion unit 101 of the error correction coding apparatus 10 converts the HD-SDI signal in the serial signal format into HD-SDI data in the parallel signal format in units of one word (step S1601). Then, the error correction encoding target data extraction unit 102 extracts a predetermined 1932 words as encoding target data from the data for one line of video of the HD-SDI data (step S1602).

  The error correction encoding means 105 encodes the data to be encoded by RS (986,966), which is a shortened RS code, and generates parity data of 40 words for one line of video data (step S1603). Then, the error correction parity rearranging means 106 performs parity in a bit unit according to a predetermined rearrangement rule in order to avoid that the parity data and the identification code become the same data as the predetermined prohibited word. The data and the identification code are multiplexed to generate rearranged data (step S1604). The rearrangement data is 50 words long for 40 words of parity data.

  The error correction parity insertion unit 103 inserts the rearranged data into the parity data area secured in the auxiliary data area in the HD-SDI data (step S1605). The parallel / serial conversion unit 104 converts the HD-SDI data in the parallel signal format into the HD-SDI signal in the serial signal format (step S1606).

  As described above, according to the error correction encoding apparatus 10, the parity data generated by encoding the HD-SDI signal with the error correction code and the identification code of the HD-SDI signal are stored in the auxiliary data area of the HD-SDI signal. An HD-SDI signal that is inserted into the reserved parity data area and includes parity data and an identification code is transmitted to the receiving device 2 by the transmitting device 1. Since the identification code of the HD-SDI signal is multiplexed with the parity data and stored in the parity data area, there is no need to newly secure an area for storing the identification code in the auxiliary data area. Can be effectively used for other purposes.

  The receiving device 2 receives the HD-SDI signal including the parity data and the identification code, and extracts the parity data and the identification code from the parity data area secured in the auxiliary data area of the HD-SDI signal. HD-SDI signals and identification codes can be output, and HD-SDI signals can be identified based on the identification codes. Therefore, when the receiving device 2 displays the identification code (identification information) of the HD-SDI signal on the display, the user can recognize the identification information of the HD-SDI signal, and the HD-SDI signal is output. When the cable is connected, the cable can be correctly connected and erroneous connection can be prevented.

[Error correction decoding device]
Next, error correction decoding apparatuses 22-1 to 22-6 (hereinafter collectively referred to as error correction decoding apparatus 22) shown in FIG. 3 will be described. FIG. 9 is a block diagram showing a configuration of the error correction decoding apparatus 22. The error correction decoding device 22 includes a serial / parallel conversion unit 201, an error correction parity extraction unit 202, an error correction decoding target data extraction unit 203, an error correction data replacement unit 204, a parallel / serial conversion unit 205, an error correction parity rearrangement. Means 206, error correction decoding processing means 207, HD-SDI signal identification information generation means 208, and HD-SDI signal identification information display means 209 are provided.

  As described above, the error correction decoding device 22 extracts the parity data and the identification code from the parity data area secured in the auxiliary data area of the HD-SDI signal after error correction coding, and uses the parity data to perform error correction decoding. To output the original HD-SDI signal and the identification code.

  The serial / parallel conversion unit 201 inputs an HD-SDI signal in a serial signal format that is a serial digital signal, converts serial data into parallel data in units of one word (10 bits), and a parallel signal format that is a parallel digital signal. The HD-SDI data is output to the error correction parity extraction means 202.

  The error correction parity extraction unit 202 receives HD-SDI data from the serial / parallel conversion unit 201, and rearranges data (parity data and identification code) from the parity data area secured in the auxiliary data area in the HD-SDI data. Is output to the error correction parity rearranging means 206 and the input HD-SDI data is output to the error correction decoding target data extracting means 203 as it is.

  The error correction decoding target data extraction unit 203 receives the HD-SDI data from the error correction parity extraction unit 202, extracts preset error correction decoding target data, and sends the decoding target data to the error correction decoding processing unit 207. At the same time, the input HD-SDI data is output to the error correction data replacement means 204. Specifically, the error correction decoding target data extraction unit 203 is similar to the error correction encoding target data extraction unit 102 described above, among the data of one line of video of the input HD-SDI data, EAV, LN, A total of 1932 words of CRCC, SAV and video data (digital active line) is extracted as data to be decoded. Then, the error correction decoding target data extraction unit 203 outputs the extracted decoding target data to the error correction decoding processing unit 207. Further, the error correction decoding target data extraction unit 203 outputs the input HD-SDI data to the error correction data replacement unit 204 as it is.

  The error correction data replacement unit 204 receives the HD-SDI data from the error correction decoding target data extraction unit 203 and also receives the decoding data from an error correction decoding processing unit 207 described later, and decodes the HD-SDI data. The data portion is replaced with decoded data subjected to error correction decoding, and the HD-SDI data subjected to error correction decoding is output to the parallel / serial conversion means 205.

  The parallel / serial conversion unit 205 receives HD-SDI data in parallel signal format, which is a parallel digital signal subjected to error correction decoding, from the error correction data replacement unit 204, converts the parallel data into serial data, and converts the serial data into serial digital data. A serial signal format HD-SDI signal as a signal is output to the outside.

  The error correction parity rearrangement unit 206 receives the rearrangement data (parity data and identification code) from the error correction parity extraction unit 202 and performs a rearrangement process opposite to the process of the error correction parity rearrangement unit 106 described above. Parity data and identification code are generated. Then, the error correction parity rearrangement unit 206 outputs the parity data to the error correction decoding processing unit 207 and outputs the identification code to the HD-SDI signal identification information generation unit 208. For example, the error correction parity rearrangement unit 206 extracts the parity data and the identification code from the arrangement of the rearrangement data (parity data and the identification code) shown in FIGS.

  In the case of the arrangement shown in FIG. 6, the error correction parity rearranging unit 206 performs parity data from the RS region from the first bit to the ninth bit for the rearranged data from the first word to the 40th word. And the parity data is extracted from the RS region from the first bit to the fourth bit for the rearranged data from the 41st word to the 50th word. Further, the error correction parity rearranging means 206 extracts one identification code from the spare area (identification code 1) of the fifth bit from the 41st word to the 50th word. In the case of the arrangement shown in FIG. 7, the error correction parity rearranging means 206 extracts parity data as in the case of FIG. 6, and the rearranged data from the 41st word to the 50th word Five identification codes are extracted from the reserved area (5-word reserved area: identification code 1) from the 5th bit to the 9th bit. In the case of the arrangement shown in FIG. 8, the error correction parity rearranging means 206 extracts the parity data in the same manner as in FIGS. 6 and 7, and rearranges data from the 46th word to the 50th word. , One identification code is extracted from the fifth bit spare area (1/2 word spare area: identification code 1). For details of the rearrangement processing by the error correction parity rearrangement unit 206, refer to Patent Document 1.

  The error correction decoding processing unit 207 receives the decoding target data from the error correction decoding target data extraction unit 203 and also receives the parity data from the error correction parity rearranging unit 206, and the decoding target data is error-corrected by a predetermined error correction code. Correction decoding is performed to generate decoded data. Then, the error correction decoding processing means 207 outputs the generated decoded data to the error correction data replacing means 204. Here, the error correction decoding processing means 207 uses the RS (986,966) code as the error correction code, similarly to the error correction encoding means 105 described above, and divides the 1932-word decoding target data into two, Decoding is performed on the decoding target data for each 966 words using parity data of 20 words. For details of the decoding method using the RS (986,966) code, refer to Patent Document 1.

  The HD-SDI signal identification information generation unit 208 receives the identification code from the error correction parity rearrangement unit 206, decodes the identification code to generate the identification information of the HD-SDI signal, and generates the identification information of the HD-SDI signal. Output to the HD-SDI signal identification information display means 209.

  Here, in the example illustrated in FIG. 7, the HD-SDI signal identification information generation unit 208 inputs the five identification codes extracted by the error correction parity rearrangement unit 206. Then, the HD-SDI signal identification information generation unit 208 performs a majority decision on the five identification codes, identifies the identification code, decodes the identified identification code, and generates identification information. Thus, even when a transmission signal is transmitted wirelessly or by wire, even if a transmission error occurs at the position of the identification code 1, the HD-SDI signal can be correctly identified. That is, the tolerance against transmission errors can be increased by the majority decision.

  The HD-SDI signal identification information display means 209 is a display for displaying the identification information. The HD-SDI signal identification information generation means 208 receives the HD-SDI signal identification information and displays the identification information.

(Processing procedure of error correction decoding device)
Next, the processing procedure of the error correction decoding apparatus 22 shown in FIG. 9 will be described. FIG. 17 is a flowchart showing the processing procedure of the error correction decoding apparatus 22. First, the serial / parallel conversion unit 201 of the error correction decoding device 22 converts the HD-SDI signal in the serial signal format into HD-SDI data in the parallel signal format in units of one word (step S1701). Then, the error correction parity extraction unit 202 extracts rearranged data from the parity data area secured in the auxiliary data area in the HD-SDI data (step S1702). Further, the error correction decoding target data extraction unit 203 extracts predetermined decoding target data from the HD-SDI data (step S1703).

  The error correction parity rearranging unit 206 performs a rearrangement process on the rearranged data, which is the reverse of the process of step S1604 shown in FIG. 16, and generates parity data and an identification code (step S1704). Then, the error correction decoding processing means 207 performs error correction decoding on the data to be decoded using the parity data, and generates decoded data (step S1705). The HD-SDI signal identification information generating unit 208 generates identification information from the identification code, and the HD-SDI signal identification information display unit 209 displays the identification information.

  The error correction data replacement unit 204 replaces the decoding target data in the HD-SDI data with the decoded data (step S1706). Then, the parallel / serial conversion unit 205 converts the HD-SDI data in the parallel signal format into the HD-SDI signal in the serial signal format (step S1707).

  Thus, according to the error correction decoding apparatus 22, the parity data and the identification code are extracted from the HD-SDI signal, decoded to the original HD-SDI signal using the parity data, and identification information is generated from the identification code. Therefore, the HD-SDI signal can be reliably identified based on the identification information. The HD-SDI signal identification information display unit 209 displays the identification information of the HD-SDI signal input to the transmission device 1. As a result, the user who sees the identification information displayed on the HD-SDI signal identification information display means 209 can determine which HD-SDI signal is transmitted from the transmission device 1 via the transmission path 7 and output from the reception device 2. Can be recognized. In addition, the cable can be correctly connected during the connection work of the cable that outputs the HD-SDI signal, and erroneous connection can be prevented.

  As shown in FIG. 3, the receiving device 2 including six error correction decoding devices 22-1 to 22-6 has six HDs output from the error correction decoding devices 22-1 to 22-6. By combining the -SDI signal and these pieces of identification information, it is possible to identify each of the six HD-SDI signals and switch the HD-SDI signal according to a predetermined setting. Details will be described later.

(Display form of HD-SDI signal identification information)
Next, the display form of the HD-SDI signal identification information in the receiving apparatus 2 shown in FIG. 3 will be described. FIG. 10 is a diagram showing the display of HD-SDI signal identification information and the output terminal of the HD-SDI signal, and shows one side of the housing in the receiving apparatus 2 shown in FIG. As described above, the transmission system 3 illustrated in FIG. 3 includes one transmission device 1 and one reception device 2, and is a system that transmits six HD-SDI signals. In order for the receiving device 2 to output six HD-SDI signals and to display the respective identification information, on one side of the casing of the receiving device 2, there are six HD-SDI signals that are display devices. Identification information display means 209-1 to 209-6 and six output terminals 210-1 to 210-6 are provided.

  On the HD-SDI signal identification information display means 209-1, the identification information of the HD-SDI signal output from the error correction decoding device 22-1 is displayed. Also, the HD-SDI signal identification information display means 209-2 to 209-6 display the identification information of the HD-SDI signal output from the error correction decoding devices 22-2 to 22-6, respectively. In the example of FIG. 10, “01” to “06” are displayed as identification information on the HD-SDI signal identification information display means 209-1 to 209-6.

  A cable is connected to the output terminal 210-1, and the HD-SDI signal decoded by the error correction decoding device 22-1 is output from the output terminal 210-1. Also, cables are connected to the output terminals 210-2 to 210-6, respectively, and HD-SDI signals decoded by the error correction decoding devices 22-2 to 22-6 are output from the output terminals 210-2 to 210-6. Each is output. Therefore, the identification information displayed on the HD-SDI signal identification information display means 209-1 and the HD-SDI signal output from the output terminal 210-1 correspond to each other, and the HD output from the output terminal 210-1. The identification information “01” of the SDI signal is displayed on the HD-SDI signal identification information display unit 209-1. The same applies to the HD-SDI signal identification information display means 209-2 to 209-6 and the output terminals 210-2 to 210-6.

  As a result, the user can determine what kind of HD-SDI signal is output from the output terminals 210-1 to 210-6 according to the identification information displayed on the HD-SDI signal identification information display means 209-1 to 209-6. It can be recognized whether it is a signal. In the example of FIG. 10, since “01” is displayed on the HD-SDI signal identification information display unit 209-1, the user has the identification information of the HD-SDI signal output from the output terminal 210-1 “01”. Can be recognized. Similarly, since “02” to “06” are displayed on the HD-SDI signal identification information display means 209-2 to 209-6, the user outputs the HD output from the output terminals 210-2 to 210-6. -It can be recognized that the identification information of the SDI signal is "02" to "06". Therefore, when connecting a cable to the output terminals 210-1 to 210-6, the user associates the output terminals 210-1 to 210-6 with the cable, and associates the cables with the correct output terminals 210-1 to 210-6. Therefore, it is possible to prevent erroneous connection of the cables.

  In the example of FIG. 10, the identification information displayed on the HD-SDI signal identification information display means 209-1 to 209-6 is a number, but may be ASCII characters such as alphabets and symbols, Or a combination of numbers and kanji.

  FIG. 15 illustrates a case where a transmission system including three transmission devices 1-1 to 1-3 and three reception devices 2-1 to 2-3 transmits 18 HD-SDI signals. FIG. 5 is a diagram showing a display of HD-SDI signal identification information and an output terminal of an HD-SDI signal, and shows one side surface of a housing in receiving apparatuses 2-1 to 2-3. Each of the reception devices 2-1 to 2-3 outputs six HD-SDI signals. In addition, in order to display the identification information, on one side surface of the housing of the reception devices 2-1 to 2-3, there are six HD-SDI signal identification information display means 209 and six outputs. Terminals 210 are respectively provided.

  The HD-SDI signal identification information display means 209 of each of the receiving devices 2-1 to 2-3 displays the HD-SDI signal identification information. A cable is connected to each output terminal 210, and an HD-SDI signal is output from the output terminal 210. Therefore, the identification information displayed on the HD-SDI signal identification information display means 209 corresponds to the HD-SDI signal output from the output terminal 210, and the identification information of the HD-SDI signal output from the output terminal 210. Is displayed on the HD-SDI signal identification information display means 209.

  Accordingly, the user can determine what kind of signal the HD-SDI signal output from the output terminal 210 is based on the identification information displayed on the HD-SDI signal identification information display unit 209, as in FIG. Can be recognized. In the example of FIG. 15, since “01” to “18” are displayed on the HD-SDI signal identification information display unit 209, the user outputs from the output terminal 210 corresponding to the HD-SDI signal identification information display unit 209. It is possible to recognize that the identification information of the HD-SDI signal being “01” to “18”. Therefore, when connecting a cable to the output terminal 210, the user can associate the output terminal 210 with the cable and connect the cable to the correct output terminal 210, so that erroneous connection of the cable can be prevented. .

[Modification]
Next, a modified example of the receiving device 2 shown in FIG. 3 will be described. This modification of the receiving device 2 selects a predetermined HD-SDI signal from six HD-SDI signals based on the identification information and outputs the selected HD-SDI signal from a predetermined output terminal, or HD in a predetermined order. This is an example of rearranging and outputting SDI signals.

  FIG. 11 is a block diagram illustrating a configuration of a modified example of the receiving device 2. The receiving device 8 includes a receiver 20, a separating device 21, error correction decoding devices 22-1 to 22-6, a switching control device 23, and a switching device 24. When the receiving device 2 shown in FIG. 3 is compared with the receiving device 8, both receiving devices 2 and 8 include a receiver 20, a separating device 21, and error correction decoding devices 22-1 to 22-6. However, the receiving device 8 is different in that it includes a switching control device 23 and a switching device 24 in addition to this. In FIG. 11, the same reference numerals as those in FIG. 3 are assigned to portions common to the receiving apparatus 2 in FIG. 3, and detailed description thereof is omitted.

  The error correction decoding devices 22-1 to 22-6 extract the parity data and the identification code from the parity data area secured in the auxiliary data area of the HD-SDI signal, perform error correction decoding using the parity data, The HD-SDI signal is output to the switching device 24 as the first to sixth HD-SDI signals. Further, the error correction decoding devices 22-1 to 22-6 generate identification information from the extracted identification codes and output the identification information to the switching control device 23 as the first to sixth system identification information.

  The switching control device 23 receives the identification information of the first system to the sixth system from the error correction decoding devices 22-1 to 22-6, and receives the switching signals of the first system to the sixth system according to a predetermined output arrangement table, respectively. Generate and output to the switching device 24. For example, the HD-SDI signal of identification information 1 is output from the first output terminal to the output arrangement table, and the HD-SDI signal of identification information 2 to identification information 6 is output from the second to sixth output terminals, respectively. When the switching control device 23 inputs the identification information 2 as the identification information of the first system and the identification information 3-6, 1 as the identification information of the second system to the sixth system, respectively. The switching control device 23 generates a switching signal for connecting the first input terminal and the second output terminal as the first system switching signal according to the output arrangement table, and the second system to the sixth system. As the switching signal, a switching signal for connecting the second to sixth input terminals and the third to sixth and first output terminals is generated. Thereby, the switching control device 23 causes the switching device 24 to output the HD-SDI signals of the identification information 1 to the identification information 6 from the first to sixth output terminals, respectively, as defined in the output arrangement table. it can.

  The switching device 24 inputs the first to sixth HD-SDI signals from the error correction decoding devices 22-1 to 22-6, and receives the first to sixth switching signals from the switching control device 23. In accordance with these switching signals, the connection between the six input terminals and the six output terminals is switched, and one HD-SDI signal of the first to sixth HD-SDI signals is switched. Each SDI signal is selected, and an HD-SDI signal according to a predetermined output arrangement table is output from each output terminal. In the above-described example, the switching device 24 outputs the HD-SDI signal of identification information 1 from the first output terminal, and the HD-SDI signal of identification information 2 to identification information 6 from the second to sixth output terminals. Output.

  As described above, according to the modification (receiving device 8) of the receiving device 2 shown in FIG. 11, the switching according to the output arrangement table is performed on the six HD-SDI signals based on the respective identification information. And a predetermined HD-SDI signal can be output from a predetermined output terminal. Thus, the user can output a desired HD-SDI signal from a desired output terminal by defining the correspondence of the HD-SDI signal desired to be output from the output terminal in the output arrangement table. Therefore, the user can surely prevent cable misconnection without recognizing what kind of signal the HD-SDI signal is. This is particularly effective when the cable is fixedly connected in advance to the output terminal of the receiving device 2 and the connection of the cable cannot be physically changed.

  The receiving device 8 shown in FIG. 11 rearranges and outputs the HD-SDI signals in a predetermined order according to the output arrangement table. However, the HD-SDI of the predetermined identification information is obtained from a plurality of HD-SDI signals. Only the SDI signal may be selected, and only the selected HD-SDI signal may be output from the output terminal.

[Application example of transmission system]
Next, an application example of the transmission system 3 shown in FIGS. 1 and 3 will be described. FIG. 12 is a diagram illustrating a first application example. The first application example is an example in which a plurality of cameras are connected to one transmission apparatus 1. A plurality of cameras 4 are connected to the transmission apparatus 1, and a plurality of monitors 5 and a recording apparatus 6 are connected to the reception apparatus 2. The transmission apparatus 1 receives HD-SDI signals from a plurality of cameras, performs error correction coding on the plurality of HD-SDI signals, inserts parity data and an identification code into the HD-SDI signal, and multiplexes the HD-SDI signals. And transmitted to the receiving device 2 via the transmission path 7. The receiving device 2 receives the multiplexed HD-SDI signal from the transmitting device 1 via the transmission path 7, separates the multiplexed HD-SDI signal, extracts the parity data and the identification code, and extracts the parity data The HD-SDI signal is subjected to error correction decoding based on the above, and the identification information of the HD-SDI signal is generated from the identification code and displayed on a display (not shown). A cable is connected to the output terminal of the receiving device 2 by the user according to the identification information. The receiving device 2 outputs the decoded HD-SDI signal from the output terminal to each of the plurality of monitors 5 and stores it in the recording device 6.

  FIG. 13 is a diagram illustrating a second application example. The second application example is an example in which one camera that outputs a plurality of HD-SDI signals separately is connected to one transmission device 1. One camera 4 is connected to the transmission apparatus 1, and a monitor 5 and a recording apparatus 6 are connected to the reception apparatus 2. The camera 4 divides the captured video signal into a plurality of HD-SDI signals and outputs them to the transmission device 1. The transmission apparatus 1 receives a plurality of HD-SDI signals, performs error correction coding, inserts and multiplexes parity data and an identification code, and transmits them to the reception apparatus 2. The receiving device 2 receives and separates the multiplexed HD-SDI signal, and performs extraction of parity data and an identification code, error correction decoding, generation and display of identification information. Then, as in the first application example, the cable is connected by the user. The receiving device 2 outputs the decoded HD-SDI signals from the respective output terminals to the monitor 5 and stores them in the recording device 6. In this case, the monitor 5 and the recording device 6 input a plurality of HD-SDI signals constituting the video signal instead of one video signal.

  FIG. 14 shows a third application example. The third application example is an example in which one camera that outputs a plurality of HD-SDI signals is connected to three transmission apparatuses 1-1 to 1-3, and the transmission system shown in FIG. 3 is an example in which three systems are provided. One camera 4 is connected to the transmission devices 1-1 to 1-3, and a monitor 5 and a recording device 6 are connected to the reception devices 2-1 to 2-3. The camera 4 is an ultra-high-definition video camera, and divides the captured video signal into a plurality of HD-SDI signals and outputs them to the transmission devices 1-1 to 1-3, respectively. The transmission apparatuses 1-1 to 1-3 receive a plurality of HD-SDI signals, perform error correction coding, and insert and multiplex parity data and identification code, and transmit the transmission lines 7-1 to 7-3. To each of the receiving devices 2-1 to 2-3. Receiving devices 2-1 to 2-3 receive and separate multiplexed HD-SDI signals, extract parity data and identification code, perform error correction decoding, and generate and display identification information. Then, as in the first and second application examples, the cable is connected by the user. Similarly to the second application example, the receiving apparatuses 2-1 to 2-3 output the decoded HD-SDI signals from the respective output terminals to the monitor 5 and store them in the recording apparatus 6. In this case, the monitor 5 and the recording device 6 input a plurality of HD-SDI signals constituting the video signal instead of one video signal.

  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 example of FIGS. 1, 3, 12, and 13, a transmission system is configured by one transmission device 1 and one reception device 2, and in the example of FIG. 14, three transmission devices. Although it is configured by 1-1 to 1-3 and three receiving apparatuses 2-1 to 2-3, the present invention does not limit the number of transmitting apparatuses 1 and receiving apparatuses 2. In FIG. 3, the transmission apparatus 1 includes six error correction encoding apparatuses 10-1 to 10-6, and the reception apparatus 2 includes six error correction decoding apparatuses 22-1 to 22-6. However, the present invention does not limit the number of error correction encoding devices 10 and error correction decoding devices 22. Further, the present invention does not limit the number of HD-SDI signals to be multiplexed and transmitted.

DESCRIPTION OF SYMBOLS 1 Transmission apparatus 2,8 Reception apparatus 3 Transmission system 4 Camera 5 Monitor 6 Recording apparatus 7 Transmission path 10 Error correction encoding apparatus 11 Multiplexer 12 Transmitter 20 Receiver 21 Separation apparatus 22 Error correction decoding apparatus 23 Switching control apparatus 24 Switching Device 101 Serial / parallel conversion means 102 Error correction encoding target data extraction means 103 Error correction parity insertion means 104 Parallel / serial conversion means 105 Error correction encoding means 106 Error correction parity rearrangement means 107 HD-SDI signal identification information input means 108 HD-SDI signal identification code generation means 201 Serial / parallel conversion means 202 Error correction parity extraction means 203 Error correction decoding target data extraction means 204 Error correction data replacement means 205 Parallel / serial conversion means 206 Error correction parity rearrangement Stage 207 the error correction decoding processing means 208 HD-SDI signal identification information generating means 209 HD-SDI signal identification information display unit 210 output terminal

Claims (12)

Error correction for multiplexing parity data generated by encoding the HD-SDI signal with an error correction code on an HD-SDI signal configured in the HD-SDI data format, which is the standard of a serial digital interface for high-definition signals In the encoding device,
Serial / parallel conversion means for converting the HD-SDI signal in the serial signal format into HD-SDI data in the parallel signal format;
Encoding target data extraction means for extracting encoding target data for the error correction encoding from the HD-SDI data converted by the serial / parallel conversion means;
Encoding means for encoding the encoding target data extracted by the encoding target data extraction means with the error correction code and generating the parity data;
The parity data generated by the encoding means and the identification code for identifying the HD-SDI signal are rearranged in units of bits so that they do not match the data of a predetermined prohibited word, and the rearranged parity data Rearrangement means for generating rearrangement data including data and an identification code;
Parity insertion means for inserting the reordered data including the parity data and the identification code generated by the reordering means into a predetermined area secured in the auxiliary data area in the HD-SDI data;
Parallel-serial conversion means for converting HD-SDI data in parallel signal format including rearranged data inserted by the parity insertion means into HD-SDI signals in serial signal format;
An error correction coding apparatus comprising: The error correction coding apparatus according to claim 1,
The reordering means connects at least the bit data at the same bit position in the predetermined number of parity data generated by the encoding means and prohibited word avoidance bits for avoiding a predetermined prohibited word, so that at least the Rearrangement data including bit data and the prohibited word avoidance bit is generated, and the HD-SDI signal is identified in a spare data area other than the bit data and the prohibited word avoidance bit of the rearrangement data. An error correction coding apparatus for inserting an identification code for the purpose. The error correction coding apparatus according to claim 1 or 2,
The encoding means uses the shortened Reed-Solomon code in which the information data length when performing the error correction encoding is shortened to the data length of the encoding target data extracted from the HD-SDI data. An error correction encoding device characterized by encoding. The error correction coding apparatus according to claim 3,
The error correction encoding apparatus characterized in that the encoding means encodes the data to be encoded by a shortened Reed-Solomon (986,966) code obtained by shortening a Reed-Solomon (1023,1003) code. In the error correction coding apparatus according to any one of claims 1 to 4,
The error correction coding apparatus, wherein the rearrangement unit generates rearrangement data including the parity data and one identification code. In the error correction coding apparatus according to any one of claims 1 to 4,
The error correction coding apparatus, wherein the rearranging means generates rearranged data including the parity data and a plurality of identification codes, and the plurality of identification codes are all the same code. In the error correction coding apparatus according to any one of claims 1 to 4,
The serial / parallel conversion means converts the HD-SDI data into a parallel signal format in a predetermined word unit,
The encoding means generates parity data in units of words by the error correction code,
The error correction decoding apparatus, wherein the rearranger generates rearranged data including parity data in units of words and an identification code having a bit number smaller than one word length. A serial signal format in which parity data is multiplexed by the error correction encoding device according to any one of claims 1 to 7 and an identification code for identifying the HD-SDI signal is multiplexed. In an error correction decoding apparatus that inputs an HD-SDI signal and decodes the HD-SDI signal using the error correction code,
Serial / parallel conversion means for converting the HD-SDI signal in the serial signal format into HD-SDI data in the parallel signal format;
Parity data that has been rearranged in bit units from a predetermined area reserved in an auxiliary data area in the HD-SDI data converted by the serial / parallel conversion means so as not to coincide with the data of the predetermined prohibited word And parity extraction means for extracting the rearranged data including the identification code;
Decoding target data extraction means for extracting decoding target data for the error correction decoding from the HD-SDI data converted by the serial / parallel conversion means;
Parity reordering means for performing reverse processing to the reordering on the reordered data extracted by the parity extracting means, and generating original parity data and an identification code;
Decoding processing means for decoding the decoding target data extracted by the decoding target data extracting means using the parity data generated by the parity rearranging means by the error correction code and generating decoded data;
Data replacement means for replacing the decoding target data in the HD-SDI data with the decoded data generated by the decoding processing means;
Parallel-serial conversion means for converting the HD-SDI data replaced by the decoded data by the data replacement means into an HD-SDI signal in a serial signal format;
Identification code output means for outputting an identification code for identifying the HD-SDI signal generated by the parity rearrangement means;
An error correction decoding apparatus comprising: The error correction decoding device according to claim 8,
The serial-to-parallel converter has a serial signal format in which the parity data is multiplexed and a plurality of identification codes for identifying the HD-SDI signal, all of which are multiplexed with the same identification code. Convert HD-SDI signal to HD-SDI data in parallel signal format,
The error correction decoding apparatus characterized in that the identification code output means specifies one identification code by majority vote for the plurality of identification codes generated by the parity rearranging means and outputs the identified identification code . In a receiving device comprising one or a plurality of error correction decoding devices according to claim 8 or 9,
A receiving apparatus comprising: a display for displaying the identification code output by the identification code output means of the error correction decoding apparatus. In a receiving device comprising a plurality of error correction decoding devices according to claim 8 or 9,
Further, the identification code output by the identification code output means is input for each error correction decoding device, and switching for each error correction decoding device is performed according to a predetermined table in which the correspondence between the identification code and the output terminal is defined. A switching control device for generating a signal;
An HD-SDI signal in the serial signal format converted by the parallel / serial conversion means is input to each error correction decoding device, and a switching signal for each error correction decoding device generated by the switching control device is input, Based on the switching signal, switching is performed to select one HD-SDI signal among the HD-SDI signals for each error correction decoding device, and the HD-SDI signal of the identification code defined in the predetermined table is changed. A switching device that outputs to the outside from an output terminal corresponding to the identification code;
A receiving apparatus comprising:   A transmission device including one or a plurality of error correction coding devices according to any one of claims 1 to 7, and a reception device including one or a plurality of error correction decoding devices according to claim 8 or 9; A transmission system comprising:

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