JP4306095B2 - Data transmission method, data transmission device, data reception method, and data reception device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The invention described in the claims of the present application performs a multiplexing process on a plurality of digital video signals or a combination of a plurality of digital video signals and a bit additional signal to obtain word string data. Data transmission method for performing processing such as 8-bit / 10-bit conversion, insertion of word synchronization data, and the like, further converting to serial data and transmitting the data for transmission, and data transmission apparatus provided for the implementation, And data receiving method for receiving data transmitted in accordance with the data transmission method, and data receiving apparatus for use in the methodAbout.
[0002]
[Prior art]
In the field related to the transmission of digital data including information data representing various signal information such as image information, the digital data is converted into serial data, an electrical signal based on the serial data is obtained, and this is used as a coaxial cable or twisted pair line. A system that transmits through a transmission line formed by using optical fiber or the like, or digital data is converted into serial data, the serial data is converted into an optical signal, and transmitted through a transmission line formed by using an optical fiber. Systems etc. have been proposed.
[0003]
One of such digital data transmission systems is known as a fiber channel system. Digital data handled under a digital data transmission system such as this fiber channel system is converted into 10 bits every 8 bits on the transmission side, for example, and a conversion table prepared in advance for the conversion. 8 bit / 10 bit conversion (8B / 10B conversion) processing is performed, and 10 or 20 bit word string data is formed. Then, what is actually transmitted is parallel / serial conversion (P / S conversion) processing for converting parallel data into serial data into 10 or 20-bit word string data formed by performing 8B / 10B conversion. Is the serial data obtained by applying.
[0004]
On the other hand, on the receiving side, serial / parallel conversion (S / P conversion) processing for converting the serial data into parallel data is performed on the received serial data to form 10- or 20-bit word string data. The 10 or 20 bit word string data is converted into 8 bits every 10 bits, and the conversion is performed in accordance with a conversion table prepared in advance. Conversion) processing is performed. Then, the original digital video signal is reproduced from the word string data formed by the 10B / 8B conversion.
[0005]
Data transmission performed by performing 8B / 10B conversion on the digital data to be transmitted is recognized as providing good transmission quality by using a 10-bit word having a selected content. Yes.
[0006]
Also, for example, digital data transmitted as 10-bit word string data under a digital data transmission system such as a fiber channel system is, for example, a “frame” as shown in FIG. According to the data format in which the smallest independent packet called is formed. In the “frame” shown in FIG. 16, the whole is composed of 2148 bytes, and its contents are a frame start part of 4 bytes, a frame header part of 24 bytes, and an optional header part of 64 bytes. , A 2048-byte payload portion, a 4-byte error check portion, and a 4-byte frame end portion are sequentially connected.
[0007]
A 2048-byte payload portion of each portion constituting these “frames” stores 10-bit word string data representing signal information. That is, when 10-bit word string data is transmitted, a large number of “frames” storing 10-bit word string data of 2048 bytes at the maximum are formed in the payload portion on the transmitting side, and these are sequentially transmitted to the receiving side. In FIG. 4, 10-bit word string data is extracted from the payload portion of each of a number of “frames” that arrive sequentially.
[0008]
In each of the 10-bit words in the 10-bit word string data, the number of 10 bits constituting the 10-bit word string data is greater than the number of “0” s, and the number of “0” s is “1”. Or the number of “1” and the number of “0” are equal. In expressing the states of the numbers “1” and “0”, for example, the concept of running disparity (RD) is introduced, and the number of “1” is a number of “0”. When it is larger, it is said that the running disparity (RD) is positive, and when the number of “0” is larger than the number of “1”, it is said that RD is negative, and further, the number of “1”. And the number of “0” are equal, the RD is said to be neutral. Then, word data in which the number of “1” is larger than the number of “0” is word data in which RD is positive, word data in which the number of “0” is larger than the number of “1” is word data in which RD is negative, Word data in which the number of “1” is equal to the number of “0” is referred to as word data (neutral word data) having RD as neutral.
[0009]
In addition, when 10-bit word string data is transmitted as described above, it is possible to accurately grasp each word data having a 10-bit configuration for the 10B / 8B conversion performed on the 10-bit word string data on the receiving side. Therefore, on the transmission side, 10-bit word string data transmitted as serial data is appropriately inserted with word synchronization data. This word synchronization data is a 10-bit word data, but has a specific code that is not used as a 10-bit word data for transmitting information. When the word synchronization data is inserted, when the immediately preceding word data has a negative RD, the word synchronization data has a positive RD, and the immediately preceding word data has a positive RD. In some cases, RD is assumed to be negative.
[0010]
Such word synchronization data is, for example, 10-bit word data DS10 called by a code name of K28.5. FIG. 17 shows the 10-bit word data DS10 called by the code name K28.5, and this word data DS10 has a negative (-) CRD which is an RD according to the word data arranged immediately before the word data DS10. When the RD is positive, “00111111010”, and when the CRD that is the RD according to the word data arranged immediately before is positive (+), the RD is negatively set to “1100000101” (hereinafter, “00111111010”). "Is called + K28.5, and" 1100000101 "is called -K28.5).
[0011]
On the other hand, in the field of video signals, digital transmission of video signals has been attempted from the viewpoint of realizing diversification of transmission information and high quality of reproduced images in connection with the transmission. Standardized digital video signals for digital transmission of video signals have been proposed. For example, 4: 2: 2 component digital video signal (D1 signal), 4fsc composite digital video signal (D2 signal), etc. It has been known. These D1 signal, D2 signal, and the like are, for example, a Y data series that is 10-bit word string data that represents a luminance signal component in a video signal and a C data that is 10-bit word string data that represents a color difference signal component in a video signal._B/ C_RThe data series is subjected to word multiplexing processing, and a predetermined portion of the resulting word multiplexed data series is determined by timing reference code data (SAV: Start of Active Video and EAV: End of Active Video). It is supposed to be obtained by substitution. SAV and EAV serve as word synchronization data.
[0012]
For example, the data series constituting the D1 signal takes the form of 10-bit word string data, for example, according to the data format as shown in FIG. FIG. 18 shows a portion corresponding to a part of the line blanking period in each line period in the D1 signal and a part of the video data period before and after the line blanking period. In such a portion, immediately before the portion corresponding to each video data period, SAV which is timing reference code data composed of 4 words (3FF, 000,000, XYZ) each having 10 bits is arranged. In addition, immediately after the portion corresponding to each video data period, EAV which is timing reference code data composed of 4 words (3FF, 000,000, XYZ) each having 10 bits is arranged. 3FF and 000 are fixed value information displayed in hexadecimal, and XYZ is variable value information displayed in hexadecimal, which indicates field identification, field blanking period identification, and SAV and EAV identification.
[0013]
When the D1 signal forming such 10-bit word string data as shown in FIG. 18 is transmitted, it is converted into serial data by a P / S conversion process and transmitted. On the receiving side, a portion based on SAV or EAV in the received serial data is detected, so that S / P conversion processing is performed under the word synchronization, and the D1 signal is reproduced. .
[0014]
In addition, digital data representing image information, that is, digital image information data usually has a huge amount of data. For example, when the data is transmitted or recorded, the quality of the data is substantially reduced. It is desired that data compression is performed that can reduce the amount of data without reducing the amount of data. Therefore, various researches and developments have been made on data compression techniques for reducing the amount of digital image information data. As one of those achievements, digital information representing image information, particularly moving image information, has been developed. Data compression of digital image information data, which is data, was studied by the Moving Picture Experts Group (MPEG), a working group under the technical committee under an international standardization organization, as a standard. An approved standard system called MPEG has been proposed.
[0015]
In this standard system called MPEG, digital image information data is subjected to data compression by high-efficiency encoding. However, data for digital image information data by high-efficiency encoding according to MPEG is used. When compression is performed, data compression with an extremely high compression rate can be realized, and an image reproduced based on the digital image information data subjected to data compression can be improved in quality. can get. Therefore, digital image information data (MPEG image information data) subjected to data compression by high-efficiency encoding according to MPEG in the field of business or household electronic devices such as digital video cameras and digital video tape recorders. There is a tendency for the number of people to handle to increase. The MPEG image information data generally forms 8-bit word string data.
[0016]
Compressed digital video signal data such as MPEG image information data, and further compressed digital video and audio signal data obtained by adding audio data to the digital video signal data are used for transmission through a transmission line as serial data. An interface called SDTI (Serial Data Transport Interface) has been proposed as an interface developed as much as possible. This SDTI is standardized as “SMPTE 305M” by SMPTE (Society of Motion Picture and Television Engineers) in the United States.
[0017]
Even in the signal format (SDTI signal format) under the SDTI, timing reference code data is arranged during each line period as necessary. A digital signal (SDTI signal) formed in accordance with the SDTI signal format used for transmission of compressed digital video signal data or video and audio signal data is also converted from parallel data to serial data, and is converted into an electric signal or an optical signal. Is transmitted in the form of a transmitted signal.
[0018]
As for the transmission of digital video signals such as the D1 signal, D2 signal, and SDTI signal as described above, the transmission side performs 8B / 10B conversion and addition of word synchronization data to the digital video signal to be transmitted. Transmission of 8B / 10B conversion processing based on a digital video signal to be performed and forming word string data including word synchronization data, which is converted into serial data and transmitted For example, in constructing a transmission / reception circuit, it is desired from the viewpoint that an existing integrated circuit (IC) element or the like can be used effectively.
[0019]
[Problems to be solved by the invention]
As described above, the 8B / 10B conversion process is performed on the transmission side based on the digital video signal to be transmitted, and the word string data including the word synchronization data is formed. Is desired to transmit digital video signals such as D1 signal, D2 signal, SDTI signal, etc., with a transmission system that is converted into serial data and transmitted, and not only one digital video signal but also a plurality of digital video signals Digital video signals can be multiplexed and transmitted, especially when multiple digital video signals are bit-synchronized, but horizontal synchronization (line synchronization) and vertical synchronization (frame synchronization) are not taken. If they can be multiplexed and transmitted, digital video signals such as D1 signals, D2 signals, and SDTI signals can be used efficiently. Furthermore, so that the expansion of the application range can be achieved. Further, efficient use of digital video signals such as D1 signal, D2 signal, and SDTI signal, or expansion of the range of use, for example, will lead to further development of technology in the field of business or household electronic devices. .
[0020]
However, conventionally, on the transmission side, based on the data to be transmitted, 8B / 10B conversion processing and word string data including word synchronization data are formed, and the word string A digital video signal such as a plurality of D1 signals, D2 signals, and SDTI signals is bit-synchronized with a transmission method in which data is converted into serial data and transmitted, but horizontal synchronization and vertical synchronization are taken. Even if it is not, there is no specific example that realizes a transmission system capable of multiplex transmission by means that can be arranged relatively easily. In addition, a plurality of digital video signals such as D1 signals, D2 signals, and SDTI signals can be compared even if they are bit-synchronized but not horizontal-synchronized and vertical-synchronized. There is no document or the like describing a technique related to a transmission system capable of multiplex transmission by means that can be easily arranged.
[0021]
  In view of such a point, the invention described in the claims of the present application is based on the data to be transmitted. The word string data is subjected to 8B / 10B conversion processing and includes word synchronization data. Are formed, and the bit string is synchronized but the horizontal synchronization and the vertical synchronization are not performed, respectively, with a transmission method in which the word string data is converted into serial data and transmitted, and each of them is, for example, D1 signal, D2 Data transmission method capable of transmitting a plurality of digital video signals, such as signals, SDTI signals, etc., by means that can be arranged relatively easily, and a data transmission apparatus provided for the implementation, And data receiving method for receiving data transmitted in accordance with the data transmission method, and data receiving apparatus for use in the methodI will provide a.
[0022]
[Means for Solving the Problems]
  In the data transmission method according to the invention described in any one of claims 1 to 10 in the claims of the present application, a plurality of bits in which horizontal synchronization and vertical synchronization are not taken are achieved. Multiplexing processing is performed on the digital video signal or a combination of these and the bit addition signal to obtain first word string data, and the first word string data is subjected to 8B / 10B conversion processing and 8B / 10B conversion processing. To form second word string data based on the 10-bit word data obtained sequentially, and set in advance in a portion corresponding to a specific position for one of a plurality of digital video signals in the second word string data By inserting an additional word data group including word synchronization data having a coded code, a complex word including word synchronization data is inserted. Form column data, and converts the composite word sequence data to serial data, is assumed to be transmitted in order to transmit the serial data.
  A data receiving method according to the invention described in claim 14 in the claims of the present application is based on the invention described in any one of claims 1 to 10 in the claims of the above-mentioned application. Receiving serial data sent in accordance with the data transmission method, and from the received serial data, a plurality of digital video signals that are bit-synchronized but not horizontal-synchronized and vertical-synchronized, or bit addition signals thereof To play.
[0023]
In particular, the data transmission method according to the invention described in claim 3 in the scope of claims of the present application relates to one of a plurality of digital video signals in the second word string data into which the additional word data group is inserted. A portion corresponding to a specific position is set to a portion corresponding to immediately before the timing reference code data in one line blanking period among a plurality of digital video signals in the second word string data.
[0024]
Further, in particular, in the data transmission method according to the invention described in claim 5 of the present application, a combination of a plurality of digital video signals and a bit additional signal is converted to data of 10-bit word string data of 3 channels. A digital video signal having a format and 2-bit additional data, the first word string data based thereon being 16-bit word string data, the second word string data being 20-bit word string data, and an additional word data group being Assuming that the word synchronization data forms a 20-bit word, the composite word string data is assumed to be a composite 20-bit word string data.
[0025]
  In the data transmission device according to any one of claims 11 to 13 in the claims of the present application, the bit synchronization is performed, but the horizontal synchronization and the vertical synchronization are not performed. A data multiplexing means for obtaining a first word string data by performing a multiplexing process on a plurality of digital video signals or a combination of these and a bit additional signal, and the first word string data obtained from the data multiplexing means is 8B / 8B / 10B conversion / word string data forming means for performing 10B conversion processing and forming second word string data based on 10-bit word data sequentially obtained by 8B / 10B conversion processing; and 8B / 10B conversion / word string A specific position for one of the plurality of digital video signals in the second word string data obtained from the data forming means A data insertion unit for forming composite word string data including word synchronization data by inserting an additional word data group including word synchronization data having a preset code in a corresponding portion; Data transmission means for converting the obtained composite word string data into serial data and transmitting the serial data for transmission.
  A data receiving device according to the invention described in claim 15 in the claims of the present application is based on the invention described in any one of claims 1 to 10 in the claims of the present application. Receiving serial data sent in accordance with the data transmission method, and from the received serial data, a plurality of digital video signals that are bit-synchronized but not horizontal-synchronized and vertical-synchronized, or bit addition signals thereof To play.
[0026]
In particular, in the data transmission device according to the invention described in claim 12 of the present application, the data insertion unit includes the additional word data group, the plurality of digital video signals in the second word string data, The timing reference code data is inserted into a portion corresponding to the immediately preceding timing reference code data within one line blanking period.
[0027]
  A data transmission method according to any one of claims 1 to 10 in the claims of the present application as described aboveAnd a data receiving method according to the invention described in claim 14 in the claims of the present applicationAccording toOn the sending side,Bit synchronization is performed but horizontal synchronization and vertical synchronization are not performed, each of which is, for example, a plurality of digital video signals such as D1 signal, D2 signal, SDTI signal, or the like. The composite word string data formed through the 8B / 10B conversion process and the additional word data group insertion process based on the combination of the signal and the bit additional signal, converted into serial data, and transmitted, includes a plurality of digital images An additional word data group including word synchronization data is inserted into a portion corresponding to a specific position of one of the signals. The word synchronization data is, for example, + K28.5, which is word data DS10 in which RD is positive, or -K28.5, which is word data DS10 in which RD is negative.
[0028]
A portion corresponding to a specific position of one of the plurality of digital video signals in the second word string data into which the additional word data group is inserted is, for example, in claim 3 of the claims of the present application. As in the case of the data transmission method according to the described invention, it is set to a portion corresponding to immediately before the timing reference code data in one line blanking period among a plurality of digital video signals in the second word string data Is done.
[0029]
  On the receiving side that receives the serial data obtained by converting the composite word string data, the word synchronization data in the composite word string data that is converted into serial data and transmitted is a plurality of digital video signals or a plurality of digital data. It is assumed that the word synchronization data required for processing for reproducing the video signal and the bit addition signal is appropriately detected. In addition, the word string data included in the composite word string data is obtained through 8B / 10B conversion processing, so that it is formed using 10-bit words having the selected content, and good transmission quality. Will bring. therefore,A data receiving method according to the invention described in claim 14 in the claims of the present applicationTherefore, it is necessary for processing for reproduction of a plurality of digital video signals or a plurality of digital video signals and a bit additional signal based on composite word string data received with good transmission quality being obtained. This ensures a state where the data synchronization state to be obtained can be reliably obtained.
[0030]
  In particular,According to the data transmission method according to any one of claims 1 to 10 in the claims of the present application, composite word string data in which an additional word data group including word synchronization data is inserted Conversion to serial data, transmission of converted serial data, reception of serial data on the receiving side, conversion of received serial data to composite word string data, etc. The transmission circuit device used for transmission and reception of the original digital video signal can be used. Therefore, based on the data to be transmitted, 8B / 10B conversion processing is performed and word string data including the word synchronization data is formed, and the word string data is converted into serial data and transmitted. A plurality of digital video signals, each of which is, for example, a plurality of D1 signals, D2 signals, SDTI signals, etc., in which bit synchronization is taken but horizontal synchronization and vertical synchronization are not taken. Therefore, it can be transmitted by means that can be arranged relatively easily.
[0031]
  A data transmission apparatus according to any one of claims 11 to 13 in the claims of the present application.According to the data receiving device according to the invention described in claim 15 in the claims of the present application,In the present invention, a plurality of digital video signals converted into serial data by a data transmission means and transmitted, for example, a plurality of digital video signals such as D1 signals, D2 signals, SDTI signals, or the like, or a plurality of such digital video signals and bits Based on the combination with the additional signal, the composite word string data formed through the 8B / 10B conversion process and the additional word data group insertion process includes word synchronization data in which RD is predetermined positive or negative. Will be. Such word synchronization data is, for example, + K28.5, which is word data DS10 in which RD is positive, or -K28.5, which is word data DS10 in which RD is negative.
[0032]
The data insertion means for performing the additional word data group insertion process, for example, in the case of the data transmission device according to the invention described in claim 12 in the claims of the present application, Of the plurality of digital video signals in the word string data, it is inserted into a portion corresponding to the timing reference code data immediately before the line blanking period.
[0033]
  On the receiving side that receives the serial data obtained by converting the composite word string data, the word synchronization data in the composite word string data that is converted into serial data and transmitted is a plurality of digital video signals or a plurality of digital data. It is assumed that the word synchronization data required for processing for reproducing the video signal and the bit addition signal is appropriately detected. In addition, the word string data included in the composite word string data is obtained through 8B / 10B conversion processing, so that it is formed using 10-bit words having the selected content, and good transmission quality. Will bring. therefore,A data receiving device according to the invention described in claim 15 in the claims of the present applicationTherefore, it is necessary for processing for reproduction of a plurality of digital video signals or a plurality of digital video signals and a bit additional signal based on composite word string data received with good transmission quality being obtained. This ensures a state where the data synchronization state to be obtained can be reliably obtained.
[0034]
  In particular,According to the data transmission device according to any one of claims 11 to 13 in the claims of the present application, composite word string data into which an additional word data group including word synchronization data is inserted Conversion to serial data, transmission of converted serial data, reception of serial data on the receiving side, conversion of received serial data to composite word string data, etc. The transmission circuit device used for transmission and reception of the original digital video signal can be used. Therefore, based on the data to be transmitted, 8B / 10B conversion processing is performed and word string data including the word synchronization data is formed, and the word string data is converted into serial data and transmitted. In this transmission method, bit synchronization is performed but horizontal synchronization and vertical synchronization are not performed. For example, a plurality of digital video signals each of which is a D1 signal, a D2 signal, an SDTI signal, etc. It can be transmitted by means that can be easily arranged.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an embodiment of the data transmission method according to any one of claims 1 to 10 in the claims of the present application. An example of a data transmission apparatus according to the invention described in any one of claims 13 to 13 is shown.
[0036]
In the example shown in FIG. 1, a data multiplexing unit 11 includes three channels of D1 signals DVP1, DVP2, and DVP3 that are digital video signals, and 2-bit additional data DAB (2) that is a bit additional signal. To be supplied. Each of the three-channel D1 signals DVP1 to DVP3 is a digital signal that forms 10-bit word string data taking the form of a data sequence as shown in FIG. 18, for example, and its word transmission rate is set to 27 MBps, for example. And parallel data. The 2-bit additional data DAB (2) is 2-bit word string data in which 2-bit words are connected, and the word transmission rate is selected to be 27 MBps, for example.
[0037]
The D1 signals DVP1 to DVP3 of the three channels are supplied to the data multiplexing unit 11 in a state where the bit synchronization is established between them but the horizontal synchronization and the vertical synchronization are not established, and the 2-bit additional data DAB (2) is supplied to the data multiplexing unit 11 in a state where bit synchronization is established with each of the D1 signals DVP1 to DVP3 of the three channels.
[0038]
The data multiplexing unit 11 multiplexes the combination of the 3-channel D1 signals DVP1 to DVP3 and the 2-bit additional data DAB (2), whereby the 3-channel D1 signals DVP1 to DVP3 and the 2-bit additional data are processed. 16-bit word string data DU (16) based on the combination with DAB (2) is obtained. In such a case, each word (10 bits) in each of the three-channel D1 signals DVP1 to DVP3 and each word (2 bits) in the 2-bit additional data DAB (2) supplied to the data multiplexing unit 11 simultaneously. The total of 10 × 3 + 2 = 32 bits is sequentially divided into 2 words each of 16 bits, thereby forming 16-bit word string data DU (16) with a word transmission rate of 27 MBps × 32/16 = 54 MBps. The
[0039]
As shown in FIG. 2, the 16-bit word string data DU (16) is, for example, the first word of the timing reference code data SAV in a certain line blanking period of the D1 signal DVP1 with reference to the D1 signal DVP1. 8 bits of the 10 bits forming the first 2 bits of the D1 signal DVP1 and the remaining 2 bits of the 10 bits forming the first word of the timing reference code data SAV of the D1 signal DVP1 and 6 bits of the 10 bit words of the D1 signal DVP2 The remaining 4 bits of the 10-bit word of the D1 signal DVP2 and 4 bits of the 10-bit word of the D1 signal DVP3, and the remaining 6 bits and 2 of the 10-bit word of the D1 signal DVP3. 2 bits forming a 2-bit word of bit additional data DAB (2); A 16-bit word comprising: 8 bits out of 10 bits forming the second word of the timing reference code data SAV in the D1 signal DVP1, and 10 bits forming the second word of the timing reference code data SAV in the D1 signal DVP1 A 16-bit word consisting of the remaining 2 bits and 6 bits of the 10-bit word of the D1 signal DVP2; of the remaining 4 bits of the 10-bit word of the D1 signal DVP2 and of the 10-bit word of the D1 signal DVP3 A 16-bit word consisting of 4 bits and the remaining 6 bits of the 10-bit word of the D1 signal DVP3 and the 2 bits forming the 2-bit word of the 2-bit additional data DAB (2); timing reference code in the D1 signal DVP1 1 forming the third word of data SAV It consists of 8 bits of 0 bits, the remaining 2 bits of 10 bits forming the third word of the timing reference code data SAV of the D1 signal DVP1, and 6 bits of the 10-bit word of the D1 signal DVP2. A 16-bit word; In FIG. 2, t represents the elapsed time (the same applies hereinafter).
[0040]
The 16-bit word string data DU (16) obtained from the data multiplexing unit 11 is supplied to the 8B / 10B conversion / word string data forming unit 12. In the 8B / 10B conversion / word string data forming unit 12, first, the 16-bit word string data DU (16) from the data multiplexing unit 11 is subjected to 8B / 10B conversion processing. Such 8B / 10B conversion processing is performed by dividing the 16 bits forming each word into two 8-bit bit groups for 16-bit word string data DU (16). And each of the divided 8-bit data is sequentially converted into 10-bit data according to a conversion table prepared in advance.
[0041]
Subsequently, in the 8B / 10B conversion / word string data forming unit 12, two 10-bit data sequentially obtained by the 8B / 10B conversion process are superposed and derived, and the word transmission rate is set to 54 MBps. Word string data DM (20) is formed.
[0042]
As shown in FIG. 3, the 20-bit word string data DM (20) is, for example, the first word of the timing reference code data SAV in a certain line blanking period of the D1 signal DVP1 with reference to the D1 signal DVP1. 8 bits out of 10 bits forming the signal form 10 bits data obtained by 8B / 10B conversion, “10 bits of 8 bits of DVP1,” and the first word of the timing reference code data SAV of the D1 signal DVP1 The remaining 2 bits of the 10 bits and 6 bits of the 10-bit word of the D1 signal DVP2 are 10-bit data obtained by the 8B / 10B conversion, “DVP1 2 bits + DVP2 6-bit 10X” A 20-bit word consisting of: the remainder of the 10-bit word of the D1 signal DVP2 4 bits of the 10 bits word of the D1 signal DVP3 and the D1 signal DVP3 are 10 bits data obtained by the 8B / 10B conversion “DVP2 4 bits + DVP3 4 bits 10X” and the D1 signal DVP3 10 bits word The remaining 6 bits and the 2 bits forming the 2-bit word of the 2-bit additional data DAB (2) are 10-bit data obtained by the 8B / 10B conversion “6 bits of DVP3 + 10X of DAB (2)” A 20-bit word consisting of "8 bits of 10 bits forming the second word of the timing reference code data SAV in the D1 signal DVP1 is 10-bit data obtained by 8B / 10B conversion" 8-bit 10X "and D1 signal DVP1 timing reference code data SA The remaining 2 bits of the 10 bits forming the second word and 6 bits of the 10-bit word of the D1 signal DVP2 are 10-bit data obtained by the 8B / 10B conversion, “DVP1 2 bits + DVP2 20 bits word consisting of 6 bits 10X ″; the remaining 4 bits of the 10 bits word of the D1 signal DVP2 and the 4 bits of the 10 bits word of the D1 signal DVP3 are obtained by performing 8B / 10B conversion 10 The bit data “4 bits of DVP2 + 10 bits of 4 bits of DVP3”, the remaining 6 bits of the 10-bit word of the D1 signal DVP3, and the 2 bits forming the 2-bit word of the 2-bit additional data DAB (2) , Which is 10-bit data obtained by 8B / 10B conversion, “6 bits of DVP3 + DA B (2) 10X "and a 20-bit word; 10 bits obtained by performing 8B / 10B conversion of 8 bits among the 10 bits forming the third word of the timing reference code data SAV in the D1 signal DVP1 "DVP1 8-bit 10X" as data, the remaining 2 bits of 10 bits forming the third word of the timing reference code data SAV of the D1 signal DVP1, and 6 bits of the 10-bit word of the D1 signal DVP2 Is a 20-bit word composed of “2 bits of DVP1 + 10 bits of 6 bits of DVP2”, which is 10-bit data obtained by 8B / 10B conversion;
[0043]
The 20-bit word string data DM (20) formed in the 8B / 10B conversion / word string data formation unit 12 is supplied to the speed conversion / data insertion unit 13. In addition to the 20-bit word string data DM (20), the speed conversion / data insertion unit 13 includes two 20-bit word data including word synchronization data forming 10-bit word data from the word data transmission unit 14. And an additional word data group DWP having a word transmission rate of, for example, 54.0315 MBps is supplied, and the word data sending unit 15 includes two pieces of word synchronization data forming 10-bit word data. An additional word data group DWN configured by 20-bit word data and having a word transmission rate of, for example, 54.0315 MBps is supplied. Furthermore, in the speed conversion / data insertion unit 13, a clock pulse signal CA having a frequency of 27 MHz, synchronized with the word clock signal of the horizontal synchronization signal SH and the vertical synchronization signal SV for the D1 signal DVP1, and the D1 signal DVP1, and A clock pulse signal CB having a frequency of 54.0315 MHz is also supplied.
[0044]
Then, the speed conversion / data insertion unit 13 sets the word transmission rate for the 20-bit word string data DM (20) from the 8B / 10B conversion / word string data formation unit 12 with a word transmission rate of 54 MBps. In addition to performing speed conversion from 54 MBps to, for example, 54.0315 MBps, the portion corresponding to immediately before the timing reference code data SAV in each line blanking period of the D1 signal DVP1 in the 20-bit word string data DM (20) The additional word data group DWP consisting of two 20-bit word data including the word synchronization data forming the 10-bit word data from the word data sending unit 14 or the 10-bit word data from the word data sending unit 15 Form word synchronization data An additional word data group DWN consisting of only two 20-bit word data is inserted, so that the word transmission rate based on the combination of the D1 signals DVP1 to DVP3 of 3 channels and the 2-bit additional data DAB (2) is increased. The composite 20-bit word string data DZ (20) having 54.0315 MBps is formed.
[0045]
Here, the word transmission rate of the composite 20-bit word string data DZ (20) is set to 54.0315 MBps for the following reason.
[0046]
The D1 signal is composed of 1716 samples of data for one line period according to the standard. Further, one frame (two fields) period is 1 / 29.97 seconds, and one frame period corresponds to 525 line periods. Therefore, one line period is 1 / 29.97 × 1/525 = 63.555. . . μs. Under such circumstances, 8B / 10B is applied to 16-bit word string data DU (16) obtained by multiplexing the combination of the 3-channel D1 signals DVP1 to DVP3 and 2-bit additional data DAB (2). The number of 20-bit words included in the portion corresponding to one line period of the 20-bit word string data DM (20) formed by the conversion is 1716 × 4/2 = 3432 words. The composite 20-bit word string data DZ (20) is obtained by adding an additional word data group DWP or DWN consisting of two 20-bit word data to the line blanking period corresponding to the 20-bit word string data DM (20). Therefore, the number of 20-bit words included in the composite 20-bit word string data DZ (20) corresponding to one line period is 3432 + 2 = 3434 words. Therefore, the word transmission rate of the composite 20-bit word string data DZ (20) is 3434 / 63.555. . . ≈54.0315 MBps.
[0047]
Under such circumstances, the 8B / 10B conversion / word string data forming unit 12 applies the 8B / 10B conversion process to the 16-bit word string data DU (16) and sequentially obtains the 10-bit word obtained by the 8B / 10B conversion process. In obtaining the 20-bit word string data DM (20) based on the data, the additional word data group DWP or DWN after the speed conversion in the speed conversion / data insertion unit 13 in the 20-bit word string data DM (20) is performed. 20-bit word data that will be located immediately before the portion to be inserted is formed, and the 10-bit word data immediately before the additional word data group DWP or DWN is linked makes its RD positive (+). RD data DRD indicating whether it is negative or negative (−) is sent, and the RD data Supplying data DRD to speed conversion data insertion unit 13.
[0048]
Thereby, the speed conversion / data insertion unit 13 adds the additional word to the 20-bit word string data obtained by performing the speed conversion for converting the word transmission rate from 54 MBps to 54.0315 MBps to the 20-bit word string data DM (20). When the data group DWP or DWN is inserted, when the RD data DRD indicates that the immediately preceding 10-bit word data has a negative (-) RD, the additional word data group DWP from the word data sending unit 14 is When the RD data DRD indicates that the immediately preceding 10-bit word data has RD positive (+), the additional word data group DWN from the word data sending unit 15 is inserted.
[0049]
FIG. 4 shows a specific configuration example of the speed conversion / data insertion unit 13. In the example shown in FIG. 4, 20-bit word string data DM (20) with a word transmission rate of 54 MBps from the 8B / 10B conversion / word string data forming unit 12 is supplied to the switch 16. A control signal CSA from the switch control signal forming unit 17 is also supplied to the switch 16.
[0050]
The switch control signal forming unit 17 includes a horizontal synchronizing signal SH and a vertical synchronizing signal SV for the D1 signal DVP1, RD data DRD from the 8B / 10B conversion / word string data forming unit 12, and a clock pulse having a frequency of 54.0315 MHz. A signal CB is supplied. Then, the switch control signal forming unit 17 forms a control signal CSA that changes state every predetermined period, for example, every 1 msec, and further, according to the horizontal synchronizing signal SH and the vertical synchronizing signal SV, the D1 signal DVP1. The control signal CSB synchronized with the position immediately before the timing reference code data SAV during the line blanking period and the control signal CSC corresponding to the contents of the RD data DRD are formed. For example, the control signal CSA takes a high level and a low level alternately every 1 msec. The control signal CSC takes a high level when, for example, the RD data DRD indicates that the immediately preceding 10-bit word data has a negative (-) RD, and the RD data DRD indicates that the immediately preceding 10-bit word data is RD. Is taken to be a low level when it represents that it is positive (+).
[0051]
A memory unit 18 and a memory unit 19 are connected to the switch 16. Then, the switch 16 performs switching every predetermined period, for example, every 1 msec in accordance with the control signal CSA, so that the 20-bit word string data DM (20) is transferred to the memory unit 18 every 1 msec. Alternatingly supplied to the memory unit 19, the 20-bit word string data DM (20) is distributed to the memory unit 18 and the memory unit 19.
[0052]
Further, a memory control signal forming unit 20 is provided in association with the memory unit 18 and the memory unit 19, and the memory control signal forming unit 20 has a clock pulse signal CA having a frequency of 27 MHz and a frequency of 54. A clock pulse signal CB of 0315 MHz is supplied. Then, the memory control signal forming unit 20 generates the write control signal QW having a frequency of 27 × 2 = 54 MHz based on the clock pulse signal CA, and the frequency is 54.0315 MHz based on the clock pulse signal CB. The read control signal QR is generated, and the write control signal QW and the read control signal QR are supplied to both the memory unit 18 and the memory unit 19.
[0053]
Thereby, in the memory unit 18, during the period when the 20-bit word string data DM (20) is supplied through the switch 16, the 20-bit word string data DM (20) is supplied to the write control signal QW having a frequency of 54 MHz. Accordingly, writing is performed with the word transmission rate set to 54 MBps. In the memory unit 19 as well, during the period in which the 20-bit word string data DM (20) is supplied through the switch 16, the 20-bit word string data DM (20) corresponds to the write control signal QW having a frequency of 54 MHz. Thus, it is written in a state where the word transmission rate is 54 MBps. Therefore, the writing in the state where the word transmission rate for the 20-bit word string data DM (20) is set to 54 MBps in the memory units 18 and 19 is alternately performed according to the switching of the switch 16 every 1 msec.
[0054]
The 20-bit word string data DM (20) written in the memory unit 18 for 1 msec is transmitted in a word according to the read control signal QR whose frequency is 54.0315 MHz in the next 1 msec. It is read from the memory unit 18 as 20-bit word string data DZ ′ (20) having a rate of 54.0315 MBps and supplied to the switch 21. In addition, 20-bit word string data DM (20) written in the memory unit 19 for 1 msec also corresponds to the read control signal QR with a frequency of 54.0315 MHz in the next 1 msec. It is read from the memory unit 19 as 20-bit word string data DZ ′ (20) with a word transmission rate of 54.0315 MBps and supplied to the switch 21.
[0055]
In relation to the switch 21, a switch 22 is provided. The switch 22 includes an additional word data group DWP composed of two 20-bit words including the word synchronization data forming the 10-bit word data from the word data transmission unit 14, and the 10-bit word from the word data transmission unit 15. An additional word data group DWN composed of two 20-bit words including word synchronization data forming data is supplied, and a control signal CSC from the switch control signal forming unit 17 is also supplied.
[0056]
When the control signal CSC is at a high level, the switch 22 indicates that the RD data DRD sent from the 8B / 10B conversion / word string data forming unit 12 is negative (−). When the additional word data group DWP from the word data sending unit 14 is derived and supplied to the switch 21, and when the control signal CSC is at a low level, that is, 8B. When the RD data DRD sent from the / 10B conversion / word string data forming unit 12 indicates that the immediately preceding 10-bit word data has a positive (+) RD, an additional word from the word data sending unit 15 A data group DWN is derived and supplied to the switch 21.
[0057]
Control signals CSA and CSB from the switch control signal forming unit 17 are also supplied to the switch 21. Then, in the period in which the 20-bit word string data DZ ′ (20) is read from the memory unit 18 in accordance with the control signals CSA and CSB, the switch 21 starts with the timing reference code in the line blanking period of the D1 signal DVP1. The additional word data group DWP or the word data sending unit derived from the word data sending unit 14 which is 20-bit word string data derived from the switch 22 and having a word transmission rate of 54.0315 MBps with the timing corresponding to immediately before the data SAV. The operation of taking out the additional word data group DWN from 15 and subsequently taking out the 20-bit word string data DZ ′ (20) with the word transmission rate read from the memory unit 18 being 54.0315 MBps is repeated, and the memory unit 19 In the period in which the 20-bit word string data DZ ′ (20) is read from the first, the word derived from the switch 22 with the timing corresponding to the timing reference code data SAV in the line blanking period of the D1 signal DVP1. The additional word data group DWP from the word data transmission unit 14 or the additional word data group DWN from the word data transmission unit 15 which is 20-bit word string data having a transmission rate of 54.0315 MBps is extracted. The operation of extracting the 20-bit word string data DZ ′ (20) with the read word transmission rate being 54.0315 MBps is repeated.
[0058]
As a result, the switch 21 converts the 20-bit word string data DM (20) into the 20-bit word string data DZ ′ (20) obtained by performing the speed conversion for converting the word transmission rate from 54 MBps to 54.0315 MBps. The portion of the D1 signal DVP1 corresponding to the timing reference code data SAV immediately before the line blanking period, that is, the first word of the timing reference code data SAV in the D1 signal DVP1 in the 20-bit word string data DZ ′ (20). 8 bits out of 10 bits forming the signal form 10 bits data obtained by 8B / 10B conversion, “10 bits of 8 bits of DVP1,” and the first word of the timing reference code data SAV of the D1 signal DVP1 2 bits of the remaining 10 bits 6 bits of the 10-bit word of the D1 signal DVP2 and the D1 signal DVP2 are immediately before the 20-bit word consisting of “10 bits of 10 bits data obtained by 8B / 10B conversion“ 2 bits of DVP1 + 10 bits of 6 bits of DVP2 ”. In this part, composite 20-bit word string data DZ (20) formed by inserting an additional word data group DWP or an additional word data group DWN having a word transmission rate of 54.0315 MBps is derived.
[0059]
The additional word data group DWP in which the word transmission rate from the word data sending unit 14 is 54.0315 MBps includes 10-bit word synchronization data given a predetermined code as 20-bit word data. An example is 20 bit word data D21.3 formed by overlapping two 10 bit auxiliary word data called code name D21.3: 20 bit word data K28.5: D21.4 formed by superimposing + 2K, which is 10-bit word synchronization data, and 10-bit auxiliary word data called by the code name D21.4 on D21.3. It is supposed to consist of
[0060]
Further, the additional word data group DWN having a word transmission rate of 54.0315 MBps from the word data sending unit 15 also includes 10-bit word synchronization data given a predetermined code as 20-bit word data. However, it is composed of two 20-bit word data. In one example, 20-bit word data D21.4: D21.3 formed by superimposing D21.4 and D21.3 It is assumed that 20-bit word data K28.5: D21.3 formed by superimposing + K28.5 and D21.3, which are 10-bit word synchronization data, is formed.
[0061]
As shown in FIG. 5, D21.3 is set to “1010101100” with RD being neutral when the CRD, which is the RD based on the word data arranged immediately before, is negative (−), and is arranged immediately before that. When CRD which is RD by word data is positive (+), it is set to “10101000011” which makes RD neutral. Further, D21.4 is “1010101101” in which the RD is positive (+) when the CRD that is the RD of the word data arranged immediately before is negative (−), and the word data arranged immediately before When CRD, which is RD according to, is positive (+), RD is set to negative (−), and “1010100010” is set.
[0062]
The composite 20-bit word string data DZ (20) formed by inserting an example of the additional word data group DWP described above has a portion in which the additional word data group DWP is inserted as shown in FIG. An additional word data group DWP composed of bit words D21.3 (1010101100): D21.3 (1010101100) and 20-bit words K28.5 (00111111010): D21.4 (1010100010) is a timing reference code data in the D1 signal DVP1. Of the 10 bits forming the first word of SAV, 8 bits of 10 bits data obtained by 8B / 10B conversion are “10 bits of 8 bits of DVP1” and timing reference code data SAV of D1 signal DVP1. Form the first word The remaining 2 bits of the 0 bits and 6 bits of the 10-bit word of the D1 signal DVP2 are 10-bit data obtained by 8B / 10B conversion, “DVP1 2 bits + DVP2 6-bit 10X”, + K28.5 (00111111010), which is 10-bit word synchronization data with RD being positive (+), and 20-bit word data K28.5 (00111111010): D21 .4 (10101100010) is included.
[0063]
Further, in the composite 20-bit word string data DZ (20) formed by inserting one example of the additional word data group DWN, the portion where the additional word data group DWN is inserted is as shown in FIG. , 20-bit word D21.4 (1010110000): D21.3 (1010101100) and 20-bit word K28.5 (00111111010): D21.3 (1010100011) are added word data group DWN, which is a timing reference in D1 signal DVP1 8 bits out of 10 bits forming the first word of the code data SAV are 10-bit data obtained by performing 8B / 10B conversion, and “8X 10 bits of DVP1”, and timing reference code data of the D1 signal DVP1 Form the first word of SAV The remaining 2 bits of the 10 bits and 6 bits of the 10-bit word of the D1 signal DVP2 are 10-bit data obtained by the 8B / 10B conversion, “DVP1 2 bits + DVP2 6-bit 10X” The + K28.5 (00111111010), which is 10-bit word synchronization data with the RD being positive (+), is arranged in the immediately preceding portion of the 20-bit word, and 20-bit word data K28.5 (00111111010): D21.3 (1010100011) as included.
[0064]
If the composite 20-bit word string data DZ (20) has a portion where the additional word data group DWP or DWN is inserted as shown in FIG. 6 or FIG. The data group DWP or DWN is + K28.5 which is 10-bit word synchronization data in which RD is positive (+) in the portion where the additional word data group DWP or DWN is inserted in the composite 20-bit word string data DZ (20). Has been selected for inclusion. However, in some cases, the composite 20-bit word string data DZ (20) is 10-bit word synchronization data in which RD is negative (-) in the portion where the additional word data group DWP or DWN is inserted. .5 may be selected.
[0065]
Thus, the composite 20-bit word string data DZ (20) having a word transmission rate of 54.0315 MBps formed in the speed conversion / data insertion unit 13 is sent from the speed conversion / data insertion unit 13, It is supplied to the P / S converter 23. In the P / S converter 23, the composite 20-bit word string data DZ (20) is subjected to P / S conversion, and the bit transmission rate based on the composite 20-bit word string data DZ (20) is set to 54.0315MBps. Serial data DZS with x20 = 1.08 Gbps is formed, and the serial data DZS is supplied to the transmitter 24. For example, the transmission unit 24 transmits the serial data DZS as an optical signal SZ suitable for a data transmission path formed using an optical fiber in order to transmit the serial data DZS through a data transmission path formed using an optical fiber. Send it out. Thereby, the serial data DZS is transmitted.
[0066]
In the data transmission apparatus shown in FIG. 1 as described above, the P / S conversion unit 23 and the transmission unit 24 bit the composite 20-bit word string data DZ (20) with a word transmission rate of 54.0315 MBps. A data sending unit for converting the data into serial data DZS having a transmission rate of 1.08 Gbps and sending the data for transmission is configured. The P / S conversion unit 23 and the transmission unit 24 constituting the data transmission unit include, for example, an integrated circuit (IC) element provided for transmission of a digital video signal under a fiber channel system. It can be configured to be used effectively. Therefore, 8B / 10B conversion is performed based on the data to be transmitted, and 20-bit word string data to which word synchronization data is added is formed. The 20-bit word string data is converted into serial data. The D1 signals DVP1 to DVP3 of the three channels that are bit-synchronized with the transmission method to be transmitted but not horizontal-synchronized and vertical-synchronized with the 2-bit additional data DAB (2) Can be multiplexed and transmitted by means that can be arranged relatively easily.
[0067]
FIG. 8 illustrates an example of the data transmission method according to the invention described in any one of claims 1 to 6 and claims 8 to 10 in the claims of the present application. An example of a data transmission apparatus according to the invention described in claim 11 or 12 in the claims is shown.
[0068]
In the example shown in FIG. 8, three-channel D1 signals DVP1, DVP2, and DVP3, which are a plurality of digital video signals, and 2-bit additional data DAB (2), which is a bit additional signal, are input to the data multiplexing unit 31. Supplied. Each of the three-channel D1 signals DVP1 to DVP3 is a digital signal that forms 10-bit word string data taking the form of a data sequence as shown in FIG. 18, for example, and its word transmission rate is set to 27 MBps, for example. And parallel data. The 2-bit additional data DAB (2) is 2-bit word string data in which 2-bit words are connected, and the word transmission rate is selected to be 27 MBps, for example.
[0069]
The D1 signals DVP1 to DVP3 of the three channels are supplied to the data multiplexing unit 31 in a state where the bit synchronization is established between them but the horizontal synchronization and the vertical synchronization are not established, and the 2-bit additional data DAB (2) is supplied to the data multiplexing unit 31 in a state in which the D1 signals DVP1 to DVP3 of the three channels are bit-synchronized.
[0070]
In the data multiplexing unit 31, the combination of the 3-channel D1 signals DVP1 to DVP3 and the 2-bit additional data DAB (2) is multiplexed, whereby the 3-channel D1 signals DVP1 to DVP3 and the 2-bit additional data are processed. 16-bit word string data DU (16) based on the combination with DAB (2) is obtained. In such a case, each word (10 bits) in each of the three channels of D1 signals DVP1 to DVP3 and each word (2 bits) in the 2-bit additional data DAB (2) supplied to the data multiplexing unit 31 simultaneously. The total of 10 × 3 + 2 = 32 bits is sequentially divided into 2 words each of 16 bits, thereby forming 16-bit word string data DU (16) with a word transmission rate of 27 MBps × 32/16 = 54 MBps. The The 16-bit word string data DU (16) is also as shown in FIG.
[0071]
The 16-bit word string data DU (16) obtained from the data multiplexing unit 31 is supplied to the 8B / 10B conversion / word string data forming unit 32. In the 8B / 10B conversion / word string data forming unit 32, first, the 16-bit word string data DU (16) from the data multiplexing unit 31 is subjected to 8B / 10B conversion processing. Such 8B / 10B conversion processing is performed by dividing the 16 bits forming each word into two 8-bit bit groups for 16-bit word string data DU (16). And each of the divided 8-bit data is sequentially converted into 10-bit data according to a conversion table prepared in advance.
[0072]
Subsequently, in the 8B / 10B conversion / word string data forming unit 32, two 10-bit data sequentially obtained by the 8B / 10B conversion process are superimposed and derived, and the word transmission rate is set to 54 MBps. Word string data DM (20) is formed. The 20-bit word string data DM (20) is also as shown in FIG.
[0073]
The 20-bit word string data DM (20) formed in the 8B / 10B conversion / word string data formation unit 32 is supplied to the speed conversion / data insertion unit 33. In addition to the 20-bit word string data DM (20), the speed conversion / data insertion unit 33 includes two 20-bit word data including word synchronization data forming 10-bit word data from the word data sending unit 34. And an additional word data group DWS having a word transmission rate of, for example, 54.0315 MBps is supplied. Further, in the speed conversion / data insertion unit 33, a clock pulse signal CA having a frequency of 27 MHz, synchronized with the word clock signal of the horizontal synchronization signal SH and the vertical synchronization signal SV for the D1 signal DVP1, and the D1 signal DVP1, and A clock pulse signal CB having a frequency of 54.0315 MHz is also supplied.
[0074]
Then, the speed conversion / data insertion unit 33 converts the word transmission rate from the 8B / 10B conversion / word string data formation unit 32 to the 20-bit word string data DM (20) with a word transmission rate of 54 MBps. In addition to performing speed conversion from 54 MBps to, for example, 54.0315 MBps, the portion corresponding to immediately before the timing reference code data SAV in each line blanking period of the D1 signal DVP1 in the 20-bit word string data DM (20) The additional word data group DWS composed of two 20-bit word data including the word synchronization data forming the 10-bit word data from the word data transmission unit 34 is inserted, whereby the three-channel D1 signals DVP1 to DVP3 are inserted. And 2-bit additional data DAB ( ) And based on a combination of, to form a composite 20-bit word sequence data DZ (20) to 54.0315MBps word transmission rate.
[0075]
Here, the word transmission rate of the composite 20-bit word string data DZ (20) is set to 54.0315 MBps because the composite 20 obtained from the speed conversion / data insertion unit 13 in the example shown in FIG. The reason is the same as in the case of the bit word string data DZ (20).
[0076]
FIG. 9 shows a specific configuration example of the speed conversion / data insertion unit 33. In the example shown in FIG. 9, 20-bit word string data DM (20) with a word transmission rate of 54 MBps from the 8B / 10B conversion / word string data forming unit 32 is supplied to the switch 35. A control signal CSA from the switch control signal forming unit 36 is also supplied to the switch 35.
[0077]
The switch control signal forming unit 36 is supplied with a horizontal synchronizing signal SH and a vertical synchronizing signal SV for the D1 signal DVP1 and a clock pulse signal CB having a frequency of 54.0315 MHz. Then, the switch control signal forming unit 36 forms a control signal CSA that causes a state change every predetermined period, for example, every 1 msec, and further, according to the horizontal synchronizing signal SH and the vertical synchronizing signal SV, the D1 signal DVP1. The control signal CSB synchronized with the position immediately before the timing reference code data SAV during the line blanking period is formed. For example, the control signal CSA takes a high level and a low level alternately every 1 msec.
[0078]
A memory unit 37 and a memory unit 38 are connected to the switch 35. Then, the switch 35 performs switching every predetermined period, for example, every 1 msec in accordance with the control signal CSA, whereby the 20-bit word string data DM (20) is transferred to the memory unit 37 every 1 msec. Alternatingly supplied to the memory unit 38, the 20-bit word string data DM (20) is distributed to the memory unit 37 and the memory unit 38.
[0079]
In addition, a memory control signal forming unit 39 is provided in association with the memory unit 37 and the memory unit 38. The memory control signal forming unit 39 has a clock pulse signal CA having a frequency of 27 MHz and a frequency of 54. A clock pulse signal CB of 0315 MHz is supplied. Then, the memory control signal forming unit 39 generates the write control signal QW having a frequency of 27 × 2 = 54 MHz based on the clock pulse signal CA, and the frequency is 54.0315 MHz based on the clock pulse signal CB. The read control signal QR is generated, and the write control signal QW and the read control signal QR are supplied to both the memory unit 37 and the memory unit 38.
[0080]
Thereby, in the memory unit 37, during the period when the 20-bit word string data DM (20) is supplied through the switch 35, the 20-bit word string data DM (20) is supplied to the write control signal QW having a frequency of 54 MHz. Accordingly, writing is performed with the word transmission rate set to 54 MBps. Also in the memory unit 38, the 20-bit word string data DM (20) is supplied in response to the write control signal QW having a frequency of 54 MHz during the period when the 20-bit word string data DM (20) is supplied through the switch 35. Thus, it is written in a state where the word transmission rate is 54 MBps. Accordingly, the writing in the state where the word transmission rate for the 20-bit word string data DM (20) is set to 54 MBps in the memory units 37 and 38 is alternately performed according to the switching of the switch 35 every 1 msec.
[0081]
The 20-bit word string data DM (20) written in the memory unit 37 for 1 msec is word-transmitted in accordance with the read control signal QR whose frequency is 54.0315 MHz in the next 1 msec. It is read from the memory unit 18 as 20-bit word string data DZ ′ (20) with a rate of 54.0315 MBps and supplied to the switch 40. Further, the 20-bit word string data DM (20) written in the memory unit 38 for 1 msec also corresponds to the read control signal QR whose frequency is 54.0315 MHz in the next 1 msec. It is read from the memory unit 38 as 20-bit word string data DZ ′ (20) with a word transmission rate of 54.0315 MBps and supplied to the switch 40.
[0082]
The switch 40 is also supplied with an additional word data group DWS, which is 20-bit word string data with a word transmission rate of 54.0315 MBps from the word data sending unit 34, and further receives a control signal CSA from the switch control signal forming unit 36. And CSB are also supplied. Then, in the period in which the 20-bit word string data DZ ′ (20) is read from the memory unit 37 in accordance with the control signals CSA and CSB, the switch 40 first selects the timing reference code in the line blanking period of the D1 signal DVP1. An additional word data group DWS, which is 20-bit word string data with a word transmission rate from the word data transmission unit 34 of 54.0315 MBps, is taken out at a timing corresponding to immediately before the data SAV, and then read out from the memory unit 37. The operation of extracting the 20-bit word string data DZ ′ (20) with the word transmission rate of 54.0315 MBps is repeated, and in the period when the 20-bit word string data DZ ′ (20) is read from the memory unit 38, first, D1 Of signal DVP1 An additional word data group DWS, which is 20-bit word string data with a word transmission rate of 54.0315 MBps from the word data transmission unit 34, is extracted at a timing corresponding to immediately before the timing reference code data SAV within the in-blanking period, and then Then, the operation of extracting the 20-bit word string data DZ ′ (20) with the word transmission rate read from the memory unit 38 being 54.0315 MBps is repeated.
[0083]
As a result, the switch 40 converts the 20-bit word string data DM (20) to the 20-bit word string data DZ ′ (20) obtained by performing the speed conversion for converting the word transmission rate from 54 MBps to 54.0315 MBps. The portion of the D1 signal DVP1 corresponding to the timing reference code data SAV immediately before the line blanking period, that is, the first word of the timing reference code data SAV in the D1 signal DVP1 in the 20-bit word string data DZ ′ (20). 8 bits out of 10 bits forming the signal form 10 bits data obtained by 8B / 10B conversion, “10 bits of 8 bits of DVP1,” and the first word of the timing reference code data SAV of the D1 signal DVP1 2 bits of the remaining 10 bits 6 bits of the 10-bit word of the D1 signal DVP2 and the D1 signal DVP2 are immediately before the 20-bit word consisting of “10 bits of 10 bits data obtained by 8B / 10B conversion“ 2 bits of DVP1 + 10 bits of 6 bits of DVP2 ”. In this part, composite 20-bit word string data DZ (20) formed by inserting an additional word data group DWS having a word transmission rate of 54.0315 MBps is derived.
[0084]
The additional word data group DWS in which the word transmission rate from the word data sending unit 34 is 54.0315 MBps includes 10-bit word synchronization data given a predetermined code as 20-bit word data. It is composed of two 20-bit word data. In one example, + K28.5, which is 10-bit word synchronization data, and arbitrary 10-bit word data DXX · X are superimposed to form 20 bits. It is assumed that word data K28.5: DXX · X is formed by 20-bit word data DXX · X: DXX · X formed by superimposing two arbitrary 10-bit word data DXX · X.
[0085]
The composite 20-bit word string data DZ (20) formed by inserting an example of such an additional word data group DWS has a portion where the additional word data group DWS is inserted as shown in FIG. 20-bit word K28.5 (00111111010): DXX · X (xxxxxxxxxxxx) and 20-bit word DXX · X (xxxxxxxx): DXX · X (xxxxxxxxxxxx) is a timing reference code in the D1 signal DVP1. Of the 10 bits forming the first word of the data SAV, 8 bits are 10-bit data obtained by 8B / 10B conversion “10 bits of 8 bits of DVP1”, and timing reference code data SAV of the D1 signal DVP1 Form the first word of The remaining 2 bits of the 10 bits and 6 bits of the 10-bit word of the D1 signal DVP2 are 10-bit data obtained by the 8B / 10B conversion, “DVP1 2 bits + DVP2 6-bit 10X” Are arranged in the immediately preceding portion of the 20-bit word, and + K28.5 (00111111010), which is 10-bit word synchronization data, and 20-bit word data K28.5 (00111111010): DXXX · X (xxxxxxxxxxxx) are formed. To be included.
[0086]
In the case where the composite 20-bit word string data DZ (20) has the portion where the additional word data group DWS is inserted as shown in FIG. 10, the additional word data group DWS is In the portion where the additional word data group DWS is inserted in the composite 20-bit word string data DZ (20), it is selected to include + K28.5 which is 10-bit word synchronization data in which RD is positive (+). Has been. However, in some cases, the composite 20-bit word string data DZ (20) is 10-bit word synchronization data in which RD is negative (-) in the portion where the additional word data group DWS is inserted. May be selected to be included.
[0087]
Thus, the composite 20-bit word string data DZ (20) having a word transmission rate of 54.0315 MBps formed in the speed conversion / data insertion unit 33 is sent from the speed conversion / data insertion unit 33, It is supplied to the P / S converter 42. In the P / S converter 42, the composite 20-bit word string data DZ (20) is subjected to P / S conversion, and the bit transmission rate based on the composite 20-bit word string data DZ (20) is 54.0315 MBps. Serial data DZS with x20 = 1.08 Gbps is formed, and the serial data DZS is supplied to the transmitter 43. The transmission unit 43 transmits the serial data DZS as an optical signal SZ suitable for a data transmission path formed using an optical fiber, for example, to transmit the serial data DZS through a data transmission path formed using an optical fiber. Send it out. Thereby, the serial data DZS is transmitted.
[0088]
Even in the data transmission apparatus shown in FIG. 8 as described above, the P / S conversion unit 42 and the transmission unit 43 have the bit rate of the composite 20-bit word string data DZ (20) with a word transmission rate of 54.0315 MBps. A data sending unit for converting the data into serial data DZS having a transmission rate of 1.08 Gbps and sending the data for transmission is configured. The P / S conversion unit 42 and the transmission unit 43 constituting such a data transmission unit include, for example, an integrated circuit (IC) element provided for transmission of a digital video signal under a fiber channel system. It can be configured to be used effectively. Therefore, 8B / 10B conversion is performed based on the data to be transmitted, and 20-bit word string data to which word synchronization data is added is formed. The 20-bit word string data is converted into serial data. The D1 signals DVP1 to DVP3 of the three channels that are bit-synchronized with the transmission method to be transmitted but not horizontal-synchronized and vertical-synchronized with the 2-bit additional data DAB (2) Can be multiplexed and transmitted by means that can be arranged relatively easily.
[0089]
  FIG. 11 is within the scope of the claims of this application.Any one of claims 1 to 10In accordance with one example of the data transmission method according to the described invention, the serial data DZS obtained by converting the composite 20-bit word string data DZ (20) sent from the transmission unit 24 in the data transmission apparatus shown in FIG. Based optical signal SZAn example of the data receiving method according to the invention described in claim 14 in the claims of the present application is implemented, and the invention described in claim 15 in the claims of the present application is implementedAn example of a data receiver is shown.
[0090]
  This figure11In the example of the data receiving apparatus shown in FIG. 1, for example, a receiving unit 45 that receives an optical signal SZ transmitted through a data transmission path formed using an optical fiber is provided. When receiving the optical signal SZ, the receiving unit 45 reproduces the serial data DZS based on the received optical signal SZ and supplies the reproduced serial data DZS to the synchronous data detection / S / P conversion unit 46.
[0091]
In the synchronous data detection / S / P converter 46, + K28.5 (or-) forming 20-bit word data K28.5: D21.4 or K28.5: D21.3 in the serial data DZS. The portion converted to serial data is detected as synchronization data, word synchronization based on the detected synchronization data is performed, S / P conversion is performed on the serial data DZS, and A or FIG. For example, composite 20-bit word string data DZ (20), which is parallel data with a word transmission rate of 54.0315 MBps, is formed as shown in 13A. The composite 20-bit word string data DZ (20) shown in FIG. 12A or FIG. 13A is selectively formed according to the contents of the additional word data group DWP or DWN. The composite 20-bit word string data DZ (20) obtained from the synchronous data detection / S / P conversion unit 46 is supplied to the word data separation / speed conversion unit 48.
[0092]
Further, in the synchronous data detection / S / P converter 46, 20 bits including + K28.5 (or -K28.5) in the additional word data group DWP or DWN in the composite 20-bit word string data DZ (20). Word data K28.5: D21.4 or K28.5: D21.3 is detected, and a K28.5 detection output signal SWS is transmitted. This K28.5 detection output signal SWS is, for example, as shown in FIG. 12B or FIG. 13B, depending on the contents of the additional word data group DWP or DWN in the composite 20-bit word string data DZ (20). can get. In this way, the K28.5 detection output signal SWS obtained from the synchronous data detection / S / P conversion unit 46 is supplied to the control signal forming unit 47. In the control signal forming unit 47, a synchronization control signal CW based on the K28.5 detection output signal SWS is formed.
[0093]
The synchronization control signal CW from the control signal formation unit 47 is also supplied to the word data separation / speed conversion unit 48 to which the composite 20-bit word string data DZ (20) is supplied from the synchronization data detection / S / P conversion unit 46. Is done. In the word data separation / speed conversion unit 48, an additional word data group DWP or DWN having a word transmission rate of 54.0315 MBps from the composite 20-bit word string data DZ (20) according to the synchronization control signal CW and The 20-bit word string data DM (20) having a word transmission rate of 54.0315 MBps is separated and extracted.
[0094]
Further, in the word data separation / speed conversion unit 48, the extracted 20-bit word string data DM (20) is subjected to speed conversion for converting the word transmission rate from 54.0315 MBps to 54 MBps to transmit the word. 20-bit word string data DM (20) with a rate of 54 MBps is formed. As a result, the word data separation / speed conversion unit 48 generates an additional word data group DWP or DWN with a word transmission rate of 54.0315 MBps and 20-bit word string data DM (20) with a word transmission rate of 54 MBps. The 20-bit word string data DM (20) is sent to the 10B / 8B conversion / 16-bit word string data forming unit 49.
[0095]
The 10B / 8B conversion / 16-bit word string data formation unit 49 is also supplied with the synchronization control signal CW from the control signal formation unit 47. The 10B / 8B conversion / 16-bit word string data forming unit 49 first performs 10B / 8B conversion processing on the 20-bit word string data DM (20) under the synchronization control by the synchronization control signal CW. Is given. Such 10B / 8B conversion processing is performed by dividing 20 bits forming each word into two 10-bit bit groups for 20-bit word string data DM (20). This is performed by sequentially converting each of the divided 10 bits into 8-bit data in accordance with a conversion table prepared in advance. Subsequently, in the 10B / 8B conversion / 16-bit word string data forming unit 49, two 8-bit data sequentially obtained by the 10B / 8B conversion process are superposed and derived, and the word transmission rate is set to 54 MBps. 16-bit word string data DU (16) is formed.
[0096]
The 16-bit word string data DU (16) obtained from the 10B / 8B conversion / 16-bit word string data forming unit 49 is supplied to the data separating unit 50.
[0097]
In the data separator 50, the 32 bits forming two consecutive words of the 16-bit word string data DU (16) with a word transmission rate of 54 MBps are divided into three groups of 10 bits and 2 bits. In addition, the state where each of the three groups of 10 bits and 2 bits is derived individually is continued. As a result, based on the 16-bit word string data DU (16), three channels of parallel data forming 10-bit word string data each having a word transmission rate of 54 MBps / 2 = 27 MBps, and a word transmission rate of 54 MBps / 2 The 3-channel D1 signals DVP1, DVP2, and DVP3, and the 2-bit additional data DAB (2), which are bit additional signals of = 27 MBps, are formed separately from each other. As a result, the reproduced three-channel D1 signals DVP1, DVP2, and DVP3 and the 2-bit additional data DAB (2) are derived from the data separation unit 50.
[0098]
In this way, each of the 3-channel D1 signals DVP1 to DVP3 and the 2-bit additional data DAB (2) each having a word transmission rate of 27 MBps is reproduced.
[0099]
  14 is within the scope of the claims of the present application.Any one of claims 1 to 6 and claims 8 to 10Serial data obtained by converting the composite 20-bit word string data DZ (20) sent from the transmitter 43 in the data transmission apparatus shown in FIG. 8 according to another example of the data transmission method according to the described invention. Receive optical signal SZ based on DZSAccording to the invention described in claim 15 of the present application in which another example of the data receiving method according to the invention described in claim 14 of the present application is implemented.Of data receiverotherAn example is shown.
[0100]
In the example of the data receiving apparatus shown in FIG. 14, for example, a receiving unit 51 that receives an optical signal SZ transmitted through a data transmission path formed using an optical fiber is provided. When receiving the optical signal SZ, the receiving unit 51 reproduces the serial data DZS based on the received optical signal SZ and supplies the reproduced serial data DZS to the synchronous data detection / S / P conversion unit 52.
[0101]
In the synchronous data detection / S / P converter 52, the 20-bit word data K28.5: DXX. A portion where + K28.5 (or -K28.5) forming X is converted into serial data is detected as synchronization data, word synchronization based on the detected synchronization data is performed, and serial data DZS is converted to S / P. Conversion is performed to form composite 20-bit word string data DZ (20), which is parallel data with a word transmission rate of 54.0315 MBps, for example, as shown in FIG. The composite 20-bit word string data DZ (20) obtained from the synchronous data detection / S / P converter 52 is supplied to the word data separation / speed converter 54.
[0102]
Further, in the synchronous data detection / S / P converter 52, 20-bit word data including + K28.5 (or -K28.5) in the additional word data group DWS in the composite 20-bit word string data DZ (20). K28.5: DXX. X is detected and a K28.5 detection output signal SWS is sent out. The K28.5 detection output signal SWS is obtained, for example, as shown in FIG. 15B according to the contents of the additional word data group DWS in the composite 20-bit word string data DZ (20). In this way, the K28.5 detection output signal SWS obtained from the synchronous data detection / S / P conversion unit 52 is supplied to the control signal forming unit 53. In the control signal forming unit 53, a synchronization control signal CW based on the K28.5 detection output signal SWS is formed.
[0103]
The synchronization control signal CW from the control signal formation unit 53 is also supplied to the word data separation / speed conversion unit 54 to which the composite 20-bit word string data DZ (20) is supplied from the synchronization data detection / S / P conversion unit 52. Is done. Then, in the word data separation / speed conversion unit 54, an additional word data group DWS having a word transmission rate of 54.0315 MBps from the composite 20-bit word string data DZ (20) in accordance with the synchronization control signal CW, The 20-bit word string data DM (20) having a transmission rate of 54.0315 MBps is separated and extracted.
[0104]
Further, the word data separation / speed conversion unit 54 performs speed conversion for converting the word transmission rate from 54.0315 MBps to 54 MBps on the extracted 20-bit word string data DM (20), and transmits the word data. 20-bit word string data DM (20) with a rate of 54 MBps is formed. As a result, the word data separation / speed converter 54 sends out an additional word data group DWS with a word transmission rate of 54.0315 MBps and 20-bit word string data DM (20) with a word transmission rate of 54 MBps. The 20-bit word string data DM (20) is supplied to the 10B / 8B conversion / 16-bit word string data forming unit 55.
[0105]
The 10B / 8B conversion / 16-bit word string data forming unit 55 is also supplied with the synchronization control signal CW from the control signal forming unit 53. The 10B / 8B conversion / 16-bit word string data forming unit 55 first performs 10B / 8B conversion processing on the 20-bit word string data DM (20) under the synchronization control by the synchronization control signal CW. Is given. Such 10B / 8B conversion processing is performed by dividing 20 bits forming each word into two 10-bit bit groups for 20-bit word string data DM (20). This is performed by sequentially converting each of the divided 10 bits into 8-bit data in accordance with a conversion table prepared in advance. Subsequently, in the 10B / 8B conversion / 16-bit word string data forming unit 55, two pieces of 8-bit data sequentially obtained by the 10B / 8B conversion process are superposed and derived, and the word transmission rate is set to 54 MBps. 16-bit word string data DU (16) is formed.
[0106]
The 16-bit word string data DU (16) obtained from the 10B / 8B conversion / 16-bit word string data forming unit 55 is supplied to the data separating unit 56.
[0107]
In the data separator 56, the 32 bits forming two consecutive words of the 16-bit word string data DU (16) with a word transmission rate of 54 MBps are divided into three groups of 10 bits and 2 bits. In addition, the state where each of the three groups of 10 bits and 2 bits is derived individually is continued. As a result, based on the 16-bit word string data DU (16), three channels of parallel data forming 10-bit word string data each having a word transmission rate of 54 MBps / 2 = 27 MBps, and a word transmission rate of 54 MBps / 2 The 3-channel D1 signals DVP1, DVP2, and DVP3, and the 2-bit additional data DAB (2), which are bit additional signals of = 27 MBps, are formed separately from each other. As a result, the reproduced three-channel D1 signals DVP1, DVP2, and DVP3 and the 2-bit additional data DAB (2) are derived from the data separation unit 56.
[0108]
In this way, each of the 3-channel D1 signals DVP1 to DVP3 and the 2-bit additional data DAB (2) each having a word transmission rate of 27 MBps is reproduced.
[0109]
An example of the data transmission method according to the invention described in any one of claims 1 to 10 in the claims of the present application described above, or claims 1 to 6 in the claims of the present application In the example of the data transmission method according to the invention described in any one of claims 8 to 10, claims 11 to 13 in the claims of the present application shown in FIG. The data multiplexing unit 11 in the example of the data transmission device described in any one of the above, or the data transmission device according to any one of claims 11 and 12 in the claims of the present application shown in FIG. In the example, the digital video signal supplied to the data multiplexing unit 31, that is, the digital video signal to be transmitted is bit-synchronized, but the horizontal synchronization Fine vertical sync is the D1 signal of 3 channels not taken, moreover, have been assumed to be combined with the 2-bit additional data DAB (2). However, the data transmission method according to any one of claims 1 to 10 in the claims of the present application and any one of claims 11 to 13 in the claims of the present application. In the data transmission apparatus according to the described invention, the digital video signal to be transmitted need not be limited to the D1 signal, for example, a digital video signal other than the D1 signal such as a D2 signal or an SDTI signal. Further, a combination with a bit additional signal such as the 2-bit additional data DAB (2) is not necessarily required. Furthermore, the number of channels of the digital video signal to be transmitted need not be limited to three, and can be any number of channels.
[0110]
【The invention's effect】
  As is apparent from the above description, a data transmission method according to any one of claims 1 to 10 in the claims of the present application.And a data receiving method according to the invention described in claim 14 in the claims of the present applicationAccording toOn the sending side,Bit synchronization is performed but horizontal synchronization and vertical synchronization are not performed, each of which is, for example, a plurality of digital video signals such as D1 signal, D2 signal, SDTI signal, or the like. The composite word string data formed through the 8B / 10B conversion process and the additional word data group insertion process based on the combination of the signal and the bit additional signal, converted into serial data, and transmitted, includes a plurality of digital images An additional word data group including word synchronization data is inserted into a portion corresponding to a specific position of one of the signals.
[0111]
  On the receiving side that receives the serial data obtained by converting the composite word string data, the word synchronization data in the composite word string data that is converted into serial data and transmitted is a plurality of digital video signals or a plurality of digital video signals. It is assumed that the word synchronization data required for processing for reproducing the bit additional signal is properly detected. In addition, the word string data included in the composite word string data is obtained through 8B / 10B conversion processing, so that it is formed using 10-bit words having the selected content, and good transmission quality. Will bring. therefore,A data receiving method according to the invention described in claim 14 in the claims of the present applicationTherefore, it is necessary for processing for reproduction of a plurality of digital video signals or a plurality of digital video signals and a bit additional signal based on composite word string data received with good transmission quality being obtained. This ensures a state where the data synchronization state to be obtained can be reliably obtained.
[0112]
  In particular,According to the data transmission method according to any one of claims 1 to 10 in the claims of the present application, composite word string data in which an additional word data group including word synchronization data is inserted Conversion to serial data, transmission of converted serial data, reception of serial data on the receiving side, conversion of received serial data to composite word string data, etc. The transmission circuit device used for transmission and reception of the original digital video signal can be used. Therefore, based on the data to be transmitted, 8B / 10B conversion processing is performed and word string data including the word synchronization data is formed, and the word string data is converted into serial data and transmitted. A plurality of digital video signals, each of which is, for example, a plurality of D1 signals, D2 signals, SDTI signals, etc., in which bit synchronization is taken but horizontal synchronization and vertical synchronization are not taken. Therefore, it can be transmitted by means that can be arranged relatively easily.
[0113]
  A data transmission apparatus according to any one of claims 11 to 13 in the claims of the present application.According to the data receiving device according to the invention described in claim 15 in the claims of the present application,In the present invention, a plurality of digital video signals converted into serial data by a data transmission means and transmitted, for example, a plurality of digital video signals such as D1 signals, D2 signals, SDTI signals, or the like, or a plurality of such digital video signals and bits Based on the combination with the additional signal, the composite word string data formed through the 8B / 10B conversion process and the additional word data group insertion process includes word synchronization data in which RD is predetermined positive or negative. Will be.
[0114]
  On the receiving side that receives the serial data obtained by converting the composite word string data, the word synchronization data in the composite word string data that is converted into serial data and transmitted is a plurality of digital video signals or a plurality of digital video signals. It is assumed that the word synchronization data required for processing for reproducing the bit additional signal is properly detected. In addition, the word string data included in the composite word string data is obtained through 8B / 10B conversion processing, so that it is formed using 10-bit words having the selected content, and good transmission quality. Will bring. therefore,A data receiving device according to the invention described in claim 15 in the claims of the present applicationTherefore, it is necessary for processing for reproduction of a plurality of digital video signals or a plurality of digital video signals and a bit additional signal based on composite word string data received with good transmission quality being obtained. This ensures a state where the data synchronization state to be obtained can be reliably obtained.
[0115]
  In particular,According to the data transmission device according to any one of claims 11 to 13 in the claims of the present application, composite word string data into which an additional word data group including word synchronization data is inserted Conversion to serial data, transmission of converted serial data, reception of serial data on the receiving side, conversion of received serial data to composite word string data, etc. The transmission circuit device used for transmission and reception of the original digital video signal can be used. Therefore, based on the data to be transmitted, 8B / 10B conversion processing is performed and word string data including the word synchronization data is formed, and the word string data is converted into serial data and transmitted. In this transmission method, bit synchronization is performed but horizontal synchronization and vertical synchronization are not performed. For example, a plurality of digital video signals each of which is a D1 signal, a D2 signal, an SDTI signal, etc. It can be transmitted by means that can be easily arranged.
[Brief description of the drawings]
FIG. 1 shows an embodiment of the data transmission method according to any one of claims 1 to 10 according to claims 1 to 10 of the present application. It is a block block diagram which shows an example of the data transmission apparatus based on the invention as described in any one of Claim 13.
FIG. 2 is a time chart for explaining an example of a data transmission method according to the invention described in any one of claims 1 to 10 in the claims of the present application;
FIG. 3 is a time chart used for explaining an example of the data transmission method according to the invention described in any one of claims 1 to 10 in the claims of the present application.
4 is a block configuration diagram illustrating a specific configuration example of a speed conversion / data insertion unit in the data transmission apparatus illustrated in FIG. 1;
FIG. 5 is a conceptual diagram used for explaining 10-bit auxiliary word data used in an example of a data transmission method according to any one of claims 1 to 10 in claims of the present application; It is.
FIG. 6 is a time chart for explaining an example of the data transmission method according to the invention described in any one of claims 1 to 10 in the claims of the present application.
FIG. 7 is a time chart used for explaining an example of the data transmission method according to the invention described in any one of claims 1 to 10 in the claims of the present application.
FIG. 8 shows an example of the data transmission method according to the invention described in any one of claims 1 to 6 and claims 8 to 10 in the claims of the present application. It is a block block diagram which shows an example of the data transmission apparatus which concerns on the invention described in Claim 11 or Claim 12 in a Claim.
9 is a block configuration diagram showing a specific configuration example of a speed conversion / data insertion unit in the data transmission apparatus shown in FIG. 8;
FIG. 10 is a time for explaining an example of a data transmission method according to the invention described in any one of claims 1 to 6 and claims 8 to 10 in the claims of the present application; It is a chart.
FIG. 11 shows an optical signal transmitted in accordance with an example of the data transmission method according to any one of claims 1 to 10 in claims of the present application.According to an example of the data receiving method according to the invention described in claim 14 in the claims of the present applicationReceiveAccording to the invention described in claim 15 in the claims of the present applicationIt is a block block diagram which shows an example of a data receiver.
12 is a time chart for explaining the operation of the data receiving apparatus shown in FIG.
FIG. 13 is a time chart for explaining the operation of the data receiving apparatus shown in FIG. 11;
FIG. 14 shows an optical signal transmitted according to an example of a data transmission method according to the invention described in any one of claims 1 to 6 and claims 8 to 10 in claims of the present application.According to another example of the data receiving method according to the invention described in claim 14 in the claims of the present applicationReceiveAccording to the invention described in claim 15 in the claims of the present applicationOf data receiverotherIt is a block block diagram which shows an example.
FIG. 15 is a time chart used for explaining the operation of the data receiving apparatus shown in FIG. 14;
FIG. 16 is a conceptual diagram used for explaining a “frame” used for transmission of digital data.
FIG. 17 is a conceptual diagram used for explaining word synchronization data used in transmission of digital data.
FIG. 18 is a conceptual diagram for explaining an example of a data format of a digital video signal.
[Explanation of symbols]
11, 31... Data multiplexing unit, 12, 32... 8B / 10B conversion / word string data forming unit, 13, 33... Speed conversion / data insertion unit, 14, 15, 34. Sending unit 16, 21, 22, 35, 40 ... switch, 17, 36 ... switch control signal forming unit, 18, 19, 37, 38 ... memory unit, 20, 39 ... memory control Signal forming unit, 23, 42... P / S conversion unit, 24, 43.

Claims (15)

A first word string is obtained by performing multiplexing processing on a plurality of digital video signals that are bit-synchronized but not horizontally or vertically synchronized, or a combination of the plurality of digital video signals and a bit additional signal. Data is obtained, and the first word string data is subjected to 8-bit / 10-bit conversion processing, and second word string data is formed based on the 10-bit word data sequentially obtained by the 8-bit / 10-bit conversion processing. An additional word data group including word synchronization data having a preset code is inserted into a portion corresponding to a specific position of one of the plurality of digital video signals in the second word string data. To form composite word string data including word synchronization data, and convert the composite word string data into serial data. And conversion, data transmission method for sending in order to transmit the serial data. A portion corresponding to a specific position of one of the plurality of digital video signals in the second word string data into which the additional word data group is to be inserted is the portion of the plurality of digital video signals in the second word string data. 2. The data transmission method according to claim 1, wherein the data transmission method is set to a portion corresponding to a predetermined position in one of the line blanking periods. A portion corresponding to a specific position of one of the plurality of digital video signals in the second word string data into which the additional word data group is to be inserted is the portion of the plurality of digital video signals in the second word string data. 3. The data transmission method according to claim 2, wherein the data transmission method is set to a portion corresponding to immediately before the timing reference code data in one of the line blanking periods. 4. The data transmission method according to claim 1, wherein each of the plurality of digital video signals is a signal having a data format of 10-bit word string data. 5. The data according to claim 4, wherein a combination of a plurality of digital video signals and a bit additional signal is formed by a digital video signal having a data format of 3-bit 10-bit word string data and 2-bit additional data. Transmission method. Assuming that the first word string data is 16-bit word string data, the second word string data is 20-bit word string data, the additional word data group is a word synchronization data that forms a 20-bit word, 6. The data transmission method according to claim 5, wherein the word string data is composite 20-bit word string data. The additional word data group has different codes depending on whether the running disparity of the word data immediately before the additional word data group in the second word string data is positive or negative. 7. The data transmission method according to claim 1, wherein the data transmission method is a data transmission method. 8. The additional word data group is selected so that the compound word string data includes word synchronization data having a positive running disparity. The data transmission method described. 8. The additional word data group is selected so that the word synchronization data having a negative running disparity is included in the composite word string data. The data transmission method described. The data transmission method according to any one of claims 1 to 9, wherein the additional word data group includes auxiliary word data having a running disparity as neutral. A first word string is obtained by performing multiplexing processing on a plurality of digital video signals that are bit-synchronized but not horizontally or vertically synchronized, or a combination of the plurality of digital video signals and a bit additional signal. Data multiplexing means for obtaining data;
The first word string data obtained from the data multiplexing means is subjected to an 8-bit / 10-bit conversion process, and a second word string data based on the 10-bit word data sequentially obtained by the 8-bit / 10-bit conversion process is obtained. 8-bit / 10-bit conversion / word string data forming means to be formed;
A code set in advance in a portion corresponding to a specific position of one of the plurality of digital video signals in the second word string data obtained from the 8-bit / 10-bit conversion / word string data forming means. Data insertion means for forming composite word string data including word synchronization data by inserting an additional word data group including word synchronization data having
Data sending means for converting the composite word string data obtained from the data insertion means to serial data and sending the serial data for transmission;
A data transmission device configured to include: The data insertion means inserts the additional word data group into a portion corresponding to immediately before the timing reference code data in one line blanking period of the plurality of digital video signals in the second word string data. The data transmission apparatus according to claim 11. The data insertion means includes first and second word data sending sections for sending first and second additional word data groups having different codes, respectively, and immediately before the additional word data group in the second word string data. If the running disparity of the word data that is the positive one is positive, the first additional word data group is inserted into the second word string data, and the 13. The data transmission apparatus according to claim 11, wherein when the disparity is negative, the second additional word data group is inserted into the second word string data. A first word string is obtained by performing multiplexing processing on a plurality of digital video signals that are bit-synchronized but not horizontally or vertically synchronized, or a combination of the plurality of digital video signals and a bit additional signal. Data is obtained, and the first word string data is subjected to an 8-bit / 10-bit conversion process, and second word-string data based on the 10-bit word data sequentially obtained by the 8-bit / 10-bit conversion process is formed. An additional word data group including word synchronization data having a preset code is inserted into a portion corresponding to a specific position for one of the plurality of digital video signals in the second word string data. To form composite word string data including word synchronization data, and convert the composite word string data into serial data. And conversion, and receives the serial data sent in accordance with the data transmission method for sending in order to transmit the serial data, it detects the word sync data in said serial data is converted into serial data portion as the synchronization data, After taking word synchronization based on the detected synchronization data and converting the serial data into the composite word string data, taking word synchronization based on the word synchronization data included in the composite word string data, The additional word data group is separated from the data to obtain the second word string data, and further, word synchronization based on the word synchronization data included in the composite word string data is taken to obtain the second word string data. Apply 10-bit / 8-bit conversion processing, and perform 10-bit / 8-bit conversion processing The first word string data based on the obtained 8-bit word data is obtained, and the plurality of digital video signals or the plurality of digital video signals separated from the first word string data and the bit additional signal are obtained. Data reception method to be played back. A first word string is obtained by performing multiplexing processing on a plurality of digital video signals that are bit-synchronized but not horizontally or vertically synchronized, or a combination of the plurality of digital video signals and a bit additional signal. Data is obtained, and the first word string data is subjected to an 8-bit / 10-bit conversion process, and second word-string data based on the 10-bit word data sequentially obtained by the 8-bit / 10-bit conversion process is formed. An additional word data group including word synchronization data having a preset code is inserted into a portion corresponding to a specific position for one of the plurality of digital video signals in the second word string data. To form composite word string data including word synchronization data, and convert the composite word string data into serial data. And conversion, and receiving means for receiving the serial data sent in accordance with the data transmission method for sending in order to transmit the serial data,
A portion of the serial data obtained from the receiving means in which the word synchronization data is converted to serial data is detected as synchronization data, and word synchronization is performed based on the detected synchronization data, and the serial data is converted to the composite word string. Data conversion means for converting to data;
Taking word synchronization based on word synchronization data included in the composite word string data obtained in the data conversion means, separating the additional word data group from the composite word string data obtained from the data conversion means, Word data separation means for obtaining second word string data;
A 10-bit / 8-bit conversion process is performed on the second word string data obtained from the word data separation means by taking word synchronization based on the word synchronization data included in the composite word string data obtained in the data conversion means. 10-bit / 8-bit conversion / word-string data forming means for obtaining the first word-string data based on 8-bit word data sequentially obtained by the 10-bit / 8-bit conversion process,
The plurality of digital video signals or the plurality of digital video signals separated from each other and the bit addition signal are reproduced from the first word string data obtained from the 10-bit / 8-bit conversion / word string data forming means. Data separation means to
A data receiving device configured to include:

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