JP3975775B2 - Data transmission method and apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The invention described in the claims of the present application is, MovieThe present invention relates to a data transmission method for serially transmitting digital data in which the number of quantization bits representing image signal information is 10 bits, 12 bits, 14 bits, or 16 bits, and a data transmission apparatus used for the transmission.
[0002]
[Prior art]
  In the field of video signals, digitization from the viewpoint of realizing diversification of transmission information and high quality of reproduced images has been attempted. For example, a digital video signal formed by digital data representing video signal information A high definition television (HDTV) system and the like that handle TVs have been proposed. A digital video signal (hereinafter referred to as an HD digital video signal) under the HDTV system is formed according to a standard established by BTA (Broadcasting Technology Association), for example, Y, P_B/ P_RThere is a type and a G, B, R type. Y, P_B/ P_RIn the case of format, Y means luminance signal and P_BAnd P_RMeans a color difference signal. In the case of G, B, and R formats, G, B, and R mean a green primary color signal, a blue primary color signal, and a red primary color signal, respectively.
[0003]
  Y, P_B/ P_RThe format HD digital video signal has a frame rate of 30 Hz or 30 / 1.001 Hz (both of which are referred to as 30 Hz in this application), and each frame image is a first field image, a second field image, For example, the interlaced scanning signal is formed in accordance with a data format as shown in FIG. The data format shown in FIG. 39 includes a luminance signal data series (Y data series) representing luminance signal information in a video signal as shown in A of FIG. 39 and a video signal as shown in B of FIG. Color difference signal data series (P_B/ P_RData series), Y data series and P_B/ P_REach of the data series has a quantization bit number of 10 bits. Therefore, each of the word data forming the quantization data has a 10-bit configuration, and the word transmission rate is, for example, 74.25 MBps. 39A shows a line blanking portion in each line portion in the Y data series and a part of the video data portion before and after the line blanking portion, and FIG._B/ P_RA line blanking part in each line part in the data series and a part of the video data part before and after the line blanking part are shown.
[0004]
  In the Y data series, 4 words (3FF (Y), 000 (Y), 000 (Y), XYZ (Y); 3FF, 000) each having a 10-bit configuration immediately before each video data portion. And XYZ are hexadecimal representations, and (Y) represents a word in the Y data series.) Timing reference code data (SAV: Start of Active Video) is arranged, and each video data section Immediately after, timing reference code data (EAV: End of Active Video) consisting of 4 words (3FF (Y), 000 (Y), 000 (Y), XYZ (Y)) each having 10 bits is obtained. Arranged. Similarly, P_B/ P_REven in the data series, 4 words (3FF (C), 000 (C), 000 (C), XYZ (C); 3FF, 000, and XYZ is a hexadecimal representation, and (C) is P_B/ P_RRepresents a word in the data series. Timing reference code data: SAV is arranged, and immediately after each video data portion, each word is composed of 4 words (3FF (C), 000 (C), 000 (C), XYZ) each having 10 bits. (C)) is composed of timing reference code data: EAV. Of course, each of the timing reference code data: EAV and SAV in the Y data series is arranged in each line blanking section in the Y data series, and P_B/ P_RTiming reference code data in the data series: Each of EAV and SAV is P_B/ P_RIt is arranged in each line blanking part in the data series.
[0005]
  Here, in the four words (3FF, 000,000, XYZ) indicated by (Y) or (C), the first three words (3FF, 000,000) perform word synchronization or line synchronization. The last one word (XYZ) is used for identification of the first field and the second field in the same frame, or timing reference code data: SAV and timing reference code data: EAV (The same applies hereinafter).
[0006]
  Also, the HD digital video signal in the G, B, R format is also a signal for interlaced scanning with a frame rate of 30 Hz, for example, according to a data format as shown in FIG. The data format shown in FIG. 40 includes a green primary color signal data series (G data series) representing green primary color signal information in a video signal, as shown in A of FIG. 40, and B as shown in FIG. A blue primary color signal data series (B data series) representing the blue primary color signal information in the video signal, and a red primary color signal data series (R data series) representing the red primary color signal information in the video signal as shown in FIG. Each of the G data series, the B data series, and the R data series has a quantization bit number of 10 bits. Therefore, each of the word data 4 forming the quantization data has a 10-bit configuration, and The word transmission rate is, for example, 74.25 MBps. 40, A, B, and C respectively show a line blanking portion in each line portion in the G data series, B data series, and R data series, and a part of the video data portion before and after that. .
[0007]
  In each of the G data series, the B data series, and the R data series, four words (3FF (G), 000 (G), 000 (G ) And XYZ (G) ((G) represents a word in the G data series.), 3FF (B), 000 (B), 000 (B) and XYZ (B) ((B) is B 3FF (R), 000 (R), 000 (R) and XYZ (R) ((R) represents a word in the R data series.) 4) (3FF (G), 000 (G), 000 (G)) each composed of 10 bits each immediately after each video data portion. And XYZ (G), 3FF (B , 000 (B), 000 (B) and XYZ (B) or 3FF (R), 000 (R), 000 (R) and XYZ (R)) timing reference code data: EAV is arranged . Of course, timing reference code data in each of the G data series, B data series, and R data series: EAV and SAV are arranged in the respective line blanking sections in the G data series, B data series, and R data series, respectively. The
[0008]
  In the current HDTV system, Y, P used for interlaced scanning when the frame rate is set to 30 Hz as described above._B/ P_RFormat, or G, B, R format HD digital video signals are used. On the other hand, as a next-generation HDTV system, the frame rate is 60 Hz or 60 / 1.001 Hz. Y, P used for progressive scanning in which each frame image is formed without being divided into first and second fields._B/ P_RSystems that use HD digital video signals in the format or G, B, R format have been proposed. Y, P for sequential scanning_B/ P_RThe HD digital video signal in the format or G, B, R format is referred to as a progressive HD video signal.
[0009]
  Digital data that forms progressive HD digital video signals with a frame rate of 60 Hz is a format established by SMPTE (Society of Motion Picture and Television Engineers) in the United States: SMPTE 274M format Is being standardized. In the format standardized by SMPTE 274M, in addition to the frame rate: 60 Hz, the number of effective lines per frame: 1080 lines, the number of effective data samples per line: 1920 samples, and the sampling frequency: 148.5 MHz or 148 .5 / 1.001 MHz (in the present application, all of these are referred to as 148.5 MHz), the number of quantization bits: 8 bits, 10 bits, or the like. And the parallel data interface is Y, P_B/ P_RIn the case of the format, 8 bits × 2 = 16 bits or 10 bits × 2 = 20 bits, and in the case of the G, B, R format, 8 bits × 3 = 24 bits or 10 bits × 3 = 30 bits.
[0010]
  In digital data constituting a digital video signal having such a quantization bit number of 8 bits or 10 bits, a code that is not used to represent video signal information is determined as a prohibited code. For example, when the number of quantization bits is 8 bits, the prohibition code is 00h and FFh in hexadecimal representation (subscript h indicates that it is a hexadecimal number), that is, 0000 0000 and 1111 1111. When the number of bits is 10 bits, the prohibition code is expressed in hexadecimal notation as 000h to 003h and 3FCh to 3FFh, that is, 00 0000 0000 to 00 0000 0011 and 11 1111 1100 to 11 1111 1111.
[0011]
  Y, P_B/ P_RP for format_BData series and P_REach sampling frequency of the data series is set to ½ of the sampling frequency of the Y data series. In the following, Y, P as required_B/ P_RThe format is expressed as 4: 2: 2 format. In the case of the G, B, and R formats, the sampling frequencies of the G data series, B data series, and R data series are the same. In the following, the G, B, and R formats are expressed as 4: 4: 4 formats as necessary.
[0012]
  In addition to such HD digital video signals, for example, a progressive method for realizing a moving image of a movie projected through a film of 24 frames per second (24 frames / second) with an image quality equivalent to that of an HDTV system image. Digital video signals have been proposed. Hereinafter, such a digital video signal is referred to as a D-Cinema signal.
[0013]
  The D-Cinema signal can be referred to as a progressive digital video signal having a frame rate of 24 Hz or 24 / 1.001 Hz (both of which are referred to as 24 Hz in the present application). The frame rate is not limited to 24 Hz, and 25 Hz, 30 Hz, and the like are also conceivable. The format of digital data constituting digital video signals with a frame rate of 24 Hz, 25 Hz, and 30 Hz is standardized by SMPTE 274M. In addition to the frame rate: 24 Hz, 25 Hz, and 30 Hz, the number of effective lines per frame: 1080 lines, number of effective data samples per line: 1920 samples, sampling frequency: 74.25 MHz or 74.25 / 1.001 MHz (all of which are referred to as 74.25 MHz in this application), number of quantization bits: 8 Bits or 10 bits are determined. The parallel data interface is 8 bits × 2 = 16 bits or 10 bits × 2 = 20 bits in the 4: 2: 2 format, and 8 bits × 3 = 24 bits in the 4: 4: 4 format. Alternatively, 10 bits × 3 = 30 bits.
[0014]
  Under such circumstances, for digital data forming the D-Cinema signal, for example, in order to further improve the resolution of an image reproduced based on the digital data, the number of quantization bits is set to 8 bits or 10 bits. It has been desired to increase the number of bits to exceed, for example, 12 bits, 14 bits, 16 bits, and the like. Further, for the same purpose, the number of effective lines per frame and the number of effective data samples per line are not limited to 1080 lines and 1920 samples, as described above, but more than that, for example, 1080 lines. 2 times and 2 times 1920 samples.
[0015]
  A D-Cinema signal with the number of effective lines per frame being, for example, twice that of 1080 lines, ie, 2160 lines, and the number of effective data samples per line being, for example, twice of 1920 samples, ie, 3840 samples, is Commonly called a 2k × 4k signal. Such a 2k × 4k signal has a quantization bit number of, for example, 10 bits, 12 bits, 14 bits, or 16 bits, and the number of effective lines per frame and the number of effective data samples per line. For example, not only a combination of 2160 lines and 3840 samples is considered, but a combination of 2048 lines and 4096 samples, a combination of 2160 lines and 3586 samples, a combination of 2048 lines and 3400 samples, 2160 line and 3840 sample combination, 2048 line and 3640 sample combination, 2075 line and 3840 sample combination, 2048 line and 3789 sample combination, 1600 line and 3840 sample combination, 1706 line and 4096 So the combination of the sample are considered.
[0016]
  Thus, for a 2k × 4k signal, for example, the number of effective lines per frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples per line is set to a value of 3400 or more and 4400 or less. Will be.
[0018]
[Problems to be solved by the invention]
  HoweverFor digital data that constitutes a digital video signal such as a 2k × 4k signal, problems associated with the transmissionButis there. That is, in the transmission of digital data constituting a digital video signal, serial transmission that is converted into serial data and transmitted is desired, but the 4: 2: 2 format in which the number of quantization bits is 8 bits or 10 bits. It is only standardized to transmit digital data that constitutes digital video signals using HD SDI (High Definition Serial Digital Interface) according to BTA S-004, a standard established by the BTA mentioned above. Other types of digital data, such as digital data forming a 2k × 4k signal, are not standardized. At present, the existing circuit used for serial transmission of digital data forming a 2k × 4k signal, for serial transmission of digital data forming a digital video signal, for example, according to HD SDI according to the standard BTA S-004 There is no specific example of a transmission system that can be appropriately realized using the components. In addition, there is no literature describing the technology related to such a serial transmission system.
[0019]
  In view of such points, the invention described in the claims of the present application is,amountThe number of child bits is 10 bits, 12 bits, 14 bits, or 16 bits, the number of effective lines per frame is set to a value of 1600 or more and 2250 or less, and the number of valid data samples per line is 3400 or more. Appropriate serial transmission of digital data comprising a digital video signal such as a 2k × 4k signal set to a numerical value of 4400 or less using, for example, existing circuit components used for serial transmission according to HD SDI The present invention provides a data transmission method that can be realized and a data transmission apparatus that is used for the method.
[0021]
[Means for Solving the Problems]
  BookClaims in the claims of the application1Claims from6In the data transmission method according to the invention described in any of the above, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and effective in each line The number of data samples is set to a value not less than 3400 and not more than 4400, the number of quantization bits is set to 10 bits, and the prohibition code that is not used to represent the video signal information for each effective line part is set to 16 upper 8 bits. Digital video signals with all 10-bit codes of 00h or FFh in hexadecimal notation are formed and formed by parallel arrangement of G data series, B data series, and R data series, each of which is 10-bit word string data The effective data sample in each line section is added to the 30-bit parallel data By sequentially assigning the samples one by one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value between 1600 and 2250, and the number of valid data samples in each line 1st and 2nd division | segmentation digital data which comprise the digital video signal set to the numerical value of 1700 or more and 2200 or less are formed, and 1st every other 1st and 2nd division | segmentation digital data The line portion and the second alternate line portion are stored in the first and second memories, respectively, and the line portion stored in the first memory and the line portion stored in the second memory are respectively G that forms a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz Data, B data series, and R data series are read as forming 30-bit parallel data, and processing is performed to obtain 30-bit word string data with a word transmission rate of 74.25 MBps. First to fourth 30-bit word string data having a transmission rate of 74.25 MBps is obtained, and for each of the first to fourth 30-bit word string data, a G data series, a B data series, and an R data series A first word group including a 10-bit word forming each of the 10-bit word forming a G data series and a part of the 10-bit word forming each of a B data series and an R data series, and auxiliary data A 10-bit word forming a series and a 10-bit word forming each of a B data series and an R data series And processing to obtain 20-bit word string data with a word transmission rate of 74.25 MBps based on each of the first and second word groups. , Each of which performs data processing for forming first to eighth 20-bit word string data with a word transmission rate of 74.25 MBps, and is based on the first to eighth 20-bit word string data. It is assumed that up to eighth serial data is obtained and sent out for transmission.
[0022]
  Claims in the claims of this application7Claims from12In the data transmission method according to the invention described in any of the above, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and effective in each line When the number of data samples is 3400 or more and 4400 or less, the quantization bit number is 12 bits, 14 bits, or 16 bits, and the quantization bit number is 12 bits, the video signal information for each effective line portion Forbidden codes that are not used to represent all the 12-bit codes in which the upper 8 bits are 00h or FFh in hexadecimal notation and the number of quantization bits is 14 bits. Prohibited codes that are not used to represent video signal information When all the 14-bit codes are 00h or FFh in hexadecimal notation and the quantization bit number is 16 bits, there are prohibited codes that are not used to represent video signal information for each effective line portion. A digital video signal in which the upper 8 bits are all 16-bit codes having a hexadecimal representation of 00h or FFh, each of which is a 12-bit, 14-bit, or 16-bit word string data and P data_B/ P_RBy sequentially allocating effective data samples in each line portion by one sample or two samples to 24-bit, 28-bit, or 32-bit parallel data formed in parallel arrangement with the data series, each has a frame rate of 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 1700 or more and 2200 or less. And the second divided digital data, and the first alternate line portion and the second alternate line portion for the first and second divided digital data, respectively. Line stored in the first memory and stored in the first memory Each of the line portions stored in the second memory is read as forming 24-bit, 28-bit, or 32-bit parallel data constituting a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz. 24 bit from the first to the fourth each having a word transmission rate of 74.25 MBps by performing a process of obtaining word sequence data of 24 bits, 28 bits or 32 bits with a word transmission rate of 74.25 MBps, 28-bit or 32-bit word string data is obtained, and the Y data series and P for each of the first to fourth 24-bit, 28-bit or 32-bit word string data_B/ P_REach 12-bit, 14-bit or 16-bit word forming each data series is divided into upper 10 bits, lower 2 bits, 4 bits or 6 bits, and word transmission based on the divided upper 10 bits 20-bit word string having a rate of 74.25 MBps and 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of divided lower 2 bits, 4 bits or 6 bits and auxiliary bits. The first to eighth 20-bit word string data are formed by performing the processing to obtain the first to eighth 20-bit word string data, each of which has a word transmission rate of 74.25 MBps, and the first to eighth 20-bit word string data. 1st to 8th serial data based on the above, and sending them for transmission It is.
[0023]
  Claims in the claims of this application13Claims from18In the data transmission method according to the invention described in any of the above, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and effective in each line The number of data samples is set to a value not less than 3400 and not more than 4400, the number of quantization bits is set to 12 bits, and the prohibition code that is not used for representing the video signal information for each effective line portion is 16 in the upper 8 bits. Digital video signals that are all 12-bit codes that are 00h or FFh in hexadecimal notation are formed, and are formed by parallel arrangement of G data series, B data series, and R data series, each of which is 12-bit word string data. The obtained 36-bit parallel data is converted into an effective data sample in each line section. By sequentially assigning the samples one by one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value between 1600 and 2250, and the number of valid data samples in each line 1st and 2nd division | segmentation digital data which comprise the digital video signal set to the numerical value of 1700 or more and 2200 or less are formed, and 1st every other 1st and 2nd division | segmentation digital data The line portion and the second alternate line portion are stored in the first and second memories, respectively, and the line portion stored in the first memory and the line portion stored in the second memory are respectively G that forms a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz By reading the data sequence, the B data sequence and the R data sequence as 36-bit parallel data, and obtaining 36-bit word string data with a word transmission rate of 74.25 MBps, First to fourth 36-bit word string data having a transmission rate of 74.25 MBps is obtained, and for each of the first to fourth 36-bit word string data, a G data series, a B data series, and an R data series Are divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data series and a plurality of parts divided from the B data series and the R data series, respectively. A 20-bit word string with a word transmission rate of 74.25 MBps based on a part of the upper 10 bits of Another part of a plurality of upper 10 bits divided from each of the B data series and the R data series, and a plurality of lower 2 bits and auxiliary bits divided from the G data series, the B data series, and the R data series The first to eighth 20-bit word string data each having a word transmission rate of 74.25 MBps are formed by performing processing based on the 20-bit word string data having a word transmission rate of 74.25 MBps. The first to eighth serial data based on the first to eighth 20-bit word string data are obtained and transmitted for transmission.
[0024]
  Claims in the claims of this application19In the data transmission device according to the invention described in the above, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value of 1600 or more and 2250 or less, and the number of effective data samples in each line is It is set to a numerical value of 3400 or more and 4400 or less, the quantization bit number is 10 bits, and the prohibition code that is not used to represent the video signal information for each effective line part is 00h in hexadecimal representation of the upper 8 bits. Alternatively, all 10-bit code digital video signals of FFh are formed, and 30 bits formed by parallel arrangement of G data series, B data series, and R data series, each of which is 10-bit word string data. One sample of valid data sample in each line section for parallel data By sequentially allocating each one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples in each line is 1700 or more and 2200. First and second divided digital data forming a digital video signal set to the following numerical values are formed. For each of the first and second divided digital data, first alternate line portions and 2 alternate line portions are stored in the first and second memories, respectively, and the line portion stored in the first memory and the line portion stored in the second memory are each set to a frame rate of 24 Hz. , G data series constituting segmented frame digital video signal of 25 Hz or 30 Hz, B By reading the data as 30-bit parallel data including the data sequence and the R data sequence, and obtaining 30-bit word string data with a word transmission rate of 74.25 MBps, each of the data transmission rate is set to 74. The first to fourth 30-bit word string data of 25 MBps are obtained, and the G data series, B data series, and R data series are formed for each of the first to fourth 30-bit word string data. Forming an auxiliary data sequence with a first word group including a 10-bit word forming a G data sequence and a part of the 10-bit word forming each of a B data sequence and an R data sequence A 10-bit word and the other part of the 10-bit word forming the B data series and the R data series respectively. Each of the first word group and the second word group is processed, and the word transmission rate based on each of the first and second word groups is 74.25 MBps. A data processing unit for performing data processing for forming first to eighth 20-bit word string data at 74.25 MBps, and first to eighth based on first to eighth 20-bit word string data, respectively. The first to eighth parallel / serial converters for obtaining the serial data and the first to eighth serial data obtained from the first to eighth parallel / serial converters are transmitted for transmission. And first to eighth data transmission units.
[0025]
  Claims in the claims of this application20In the data transmission device according to the invention described in the above, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples in each line is In order to represent video signal information for each effective line section when the number of quantization bits is set to a value of 3400 or more and 4400 or less, the quantization bit number is 12 bits, 14 bits, or 16 bits, and the quantization bit number is 12 bits. When the prohibited codes that are not used are all 12-bit codes in which the upper 8 bits are 00h or FFh in hexadecimal representation and the number of quantization bits is 14 bits, the video signal information for each effective line part is Forbidden codes that are not used to represent the upper 8 bits in hexadecimal notation When all the 14-bit codes are 00h or FFh and the number of quantization bits is 16 bits, the prohibition code that is not used to represent the video signal information for each effective line portion is the upper 8 bits. A digital video signal that is all 16-bit codes that become 00h or FFh in hexadecimal representation, each of which is a 12-bit, 14-bit, or 16-bit word string data and a Y data series and P_B/ P_RBy sequentially allocating effective data samples in each line portion by one sample or two samples to 24-bit, 28-bit, or 32-bit parallel data formed in parallel arrangement with the data series, each has a frame rate of 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 1700 or more and 2200 or less. And the second divided digital data, and the first alternate line portion and the second alternate line portion for the first and second divided digital data, respectively. Stored in the first memory and the line section and the first memory stored in the first memory. Read each line portion stored in the second memory as forming a 24-bit, 28-bit, or 32-bit parallel data forming a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz. By performing processing for obtaining 24-bit, 28-bit, or 32-bit word string data with a transmission rate of 74.25 MBps, each of the first to fourth 24-bit, 28 bits with a word transmission rate of 74.25 MBps. Alternatively, 32-bit word string data is obtained, and the Y data series and P for each of the first to fourth 24-bit, 28-bit, or 32-bit word string data_B/ P_REach 12-bit, 14-bit or 16-bit word forming each data series is divided into upper 10 bits, lower 2 bits, 4 bits or 6 bits, and word transmission based on the divided upper 10 bits 20-bit word string having a rate of 74.25 MBps and 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of divided lower 2 bits, 4 bits or 6 bits and auxiliary bits. A data processing unit for performing data processing for forming first to eighth 20-bit word string data each having a word transmission rate of 74.25 MBps, and first to eighth 20 The first to eighth pass data for obtaining the first to eighth serial data based on the bit word string data, respectively. A first / eighth data sending unit for sending first to eighth serial data obtained from the first / eighth parallel / serial conversion unit, and a first / eighth data sending unit, respectively. It is configured with.
[0026]
  Further claims in the claims of this application21In the data transmission device according to the invention described in the above, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples in each line is It is set to a numerical value of 3400 or more and 4400 or less, the number of quantization bits is 12 bits, and the prohibition code that is not used to represent the video signal information for each effective line part is 00h in hexadecimal notation. Alternatively, all the 12-bit code digital video signals that become FFh are formed, and 36 bits formed by parallel arrangement of a G data series, a B data series, and an R data series, each of which is a 12-bit word string data. One sample of valid data sample in each line section for parallel data By sequentially allocating each one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less, and the number of effective data samples in each line is 1700 or more and 2200. First and second divided digital data forming a digital video signal set to the following numerical values are formed. For each of the first and second divided digital data, first alternate line portions and 2 alternate line portions are stored in the first and second memories, respectively, and the line portion stored in the first memory and the line portion stored in the second memory are each set to a frame rate of 24 Hz. , G data series constituting segmented frame digital video signal of 25 Hz or 30 Hz, B The data transmission rate is set to 74 by reading the data as 36-bit parallel data including the data sequence and the R data sequence, and obtaining 36-bit word string data with a word transmission rate of 74.25 MBps. The first to fourth 36-bit word string data of 25 MBps is obtained, and the G data series, B data series, and R data series are formed for each of the first to fourth 36-bit word string data. Each 12-bit word is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data series and a plurality of upper 10 bits divided from each of the B data series and the R data series A 20-bit word string with a word transmission rate of 74.25 MBps based on a part of And a word based on another part of the plurality of upper 10 bits divided from each of the R data series and the plurality of lower 2 bits and auxiliary bits divided from the G data series, B data series and R data series Data processing for forming first to eighth 20-bit word string data each having a word transmission rate of 74.25 MBps by performing processing for obtaining 20-bit word string data having a transmission rate of 74.25 MBps A first to eighth parallel / serial converters for obtaining first to eighth serial data based on the first to eighth 20-bit word string data, respectively, 1st to 8th data to be transmitted to transmit the 1st to 8th serial data respectively obtained from the 8th parallel / serial converter. Configured to include a detection section, a.
[0028]
  UpClaims in the claims of this application as stated1Claims from18A data transmission method according to the invention described in any of the above or claims19Claims from21In the data transmission apparatus according to any of the above-described inventions, the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits, and the number of effective lines per frame is 1600 or more and 2250 or less. Digital data that constitutes a digital video signal in which the number of valid data samples per line is set to a value of 3400 or more and 4400 or less, and the previous quantization bit number is 8 bits or 10 bits. Is divided into a plurality of word string data that is compatible with the digital data constituting the HD digital video signal, and each of the plurality of word string data is converted into serial data and transmitted. Will do. Accordingly, the claims in the claims of this application1Claims from18A data transmission method according to the invention described in any of the above or claims19Claims from21According to the data transmission device according to any of the inventions described above, the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits, and the number of effective lines per frame is 1600 or more and 2250 or less. The serial transmission of digital data forming a digital video signal such as a 2k × 4k signal that is set to a numerical value and the number of valid data samples per line is set to a numerical value of 3400 or more and 4400 or less, for example, according to HD SDI It is possible to appropriately carry out using existing circuit components used for serial transmission.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
  FIG. 1 shows claims 7 to claims in the scope of claims of the present application.12According to the invention described in any of the aboveAn example of a data transmission method is implemented, and is dealt with in an example of a data transmission apparatus according to the invention described in claim 20 in the scope of claims of the present application2 shows an example data format of digital data constituting a digital video signal.
[0030]
  Digital data having the data format shown in FIG.Is obtainedData formation methodLaw isA numerical value 2k = n where the number of effective lines in each frame is 1600 or more and 2250 or less₂-N₁For example, the number of valid data samples in each line portion is set to a numerical value 4k of 3400 or more and 4400 or less, for example, 3840, and the number of quantization bits is 10 bits, 12 bits, 14 bits or Digital data forming a 2k × 4k signal which is a 16: bit 4: 2: 2 format digital video signal is formed. Since such digital data constitutes a digital video signal in 4: 2: 2 format, the Y data series and the number of quantization bits are set to 10 bits, 12 bits, 14 bits, or 16 bits. P with 10 bits, 12 bits, 14 bits, or 16 bits_B/ P_RData series.
[0031]
  Then, digital data having the data format shown in FIG. 1 is obtained.DeData formationTo the lawIn that case, Y data series and P_B/ P_RWith respect to the data series, the frame part is set to be continuous every 1/24 second, 1/25 second or 1/30 second, and each frame part is changed from the line part L0001 to the line part Ln_ThreeUp to n_ThreeIt is formed with a series of line parts. In addition, the effective line portion in each frame portion is defined as the line portion Ln.₁+1 to line part Ln₂And the number of effective lines in each frame is 2k = n₂-N₁For example, it is set to 2160 (2k line portion). Further, the number of valid data samples in each line portion is set to 4k, for example, 3840 (4k samples). Then, the number of quantization bits is selected as 10 bits, 12 bits, 14 bits, or 16 bits.
[0032]
  Under such circumstances, the line portion L0001 to the line portion Ln in each frame portion._ThreeEach of the above is a line portion of a Y data series in which the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits, and a P portion in which the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits._B/ P_RIn particular, the line portion Ln forming the effective line portion is included.₁+1 to line part Ln₂For each of the above, the line part Ln which is one of them₁As illustrated in FIG. 1 for the state at +1, the line portion of the Y data series and the number of quantization bits of 10 bits, 12 bits, 14 bits, or 16 bits forming the quantization bits are 10 bits. P with bit, 12 bit, 14 bit or 16 bit_B/ P_REach line part of the data series is formed to include a line blanking part and a video data part.
[0033]
  Each line blanking section is configured such that the timing reference code: EAV is disposed at the start end portion thereof and the timing reference code: SAV is disposed at the end portion thereof. On the other hand, for the video data portion, the video data portion in the Y data series is configured by arranging data YD representing luminance signal information with 4k effective data samples, and P_B/ P_RThe video data portion in the data series is configured by arranging data PbD / PrD representing color difference signal information with an effective data sample number of 4k.
[0034]
  Further, a line portion Ln forming an effective line portion in each frame portion₁+1 to line part Ln₂The line part of the Y data series and P_B/ P_RWhen the video data part in each line part of the data series is configured by arranging data YD representing luminance signal information or data PbD / PrD representing chrominance signal information, the upper 8 bits are 00h or FFh in hexadecimal representation. All of the 10-bit code, 12-bit code, 14-bit code, or 16-bit code are the prohibited codes that are not used as the data YD representing the luminance signal information or the data PbD / PrD representing the color difference signal information.
[0035]
  As shown in FIG. 2, when the number of quantization bits is 10, the prohibition code determined in this way is 000h to 003h and 3FCh to 3FFh in hexadecimal representation, that is, 00 0000 0000 to 00 0000 0011 and 11 1111 1100 to 11 1111 1111, and when the number of quantization bits is 12 bits, 000h to 00Fh and FF0h to FFFh in hexadecimal representation, that is, 0000 0000 0000 to 0000 0000 1111 and 1111 1111 0000 to 1111 1111 1111 When the quantization bit number is 14 bits, 0000h to 003Fh and 3FC0h to FFFFh in hexadecimal representation, that is, 00 0000 0000 OOOO to 00 0000 0011 1111 and 11 1111 1100 0000 to 11 1111 1111 1111, When the number of quantization bits is 16 bits, 0000h to 00FFh and FF00h to FFFFh in hexadecimal representation, that is, 0000 0000 0000 OOOO to 0000 00 00 1111 1111 and 1111 1111 0000 0000 to 1111 1111 1111 1111.
[0036]
  As described above, digital data having the data format shown in FIG. 1 is obtained.DeData formationTo the lawTherefore, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, and the number of lines in each frame is n._Three, The number of effective lines in each frame is 2k = n₂-N₁When the number of valid data samples in each line is set to 4k, the number of quantization bits is 10, 12, 14 or 16 bits, and the number of quantization bits is 10 bits, the prohibition for each valid line portion is prohibited. When the upper 8 bits are all 10-bit codes with 00h or FFh in hexadecimal representation, and the number of quantization bits is 12 bits, the prohibition code for each effective line part represents the upper 8 bits in hexadecimal When all the 12-bit codes are 00h or FFh and the number of quantization bits is 14 bits, all the 14-bit codes for which the upper 8 bits are 00h or FFh in hexadecimal representation for the effective line part When the bit code is used or the number of quantization bits is 16 bits, Prohibition code is all of 16-bit code to 00h or FFh the upper 8 bits in hexadecimal, 4: 2: digital data constituting the 2 format digital video signal is formed.
[0037]
  FIG.Claims of the present application in which the examples of the data transmission method according to the invention described in any of claims 1 to 6 or claims 13 to 18 in the claims of the present application are implemented. In the example of the data transmission device according to the invention described in claim 19 or claim 212 shows an example data format of digital data constituting a digital video signal.
[0038]
  Digital data having the data format shown in FIG. 3 is obtained.DeData formationLaw isThen, digital data forming a 4: 4: 4 format digital video signal in which the number of quantization bits is 10 bits or 12 bits is formed. Since such digital data constitutes a digital video signal in 4: 4: 4 format, a G data series having a quantization bit number of 10 bits or 12 bits and a quantization bit number of 10 bits or 12 bits. And a R data sequence in which the number of quantization bits is 10 bits or 12 bits.
[0039]
  Then, digital data having the data format shown in FIG. 3 is obtained.DeData formationTo the lawThen, for the G data series, B data series, and R data series, the frame portion is set to be continuous every 1/24 seconds, 1/25 seconds, or 1/30 seconds, and each frame portion is set as a line portion. Line part Ln from L0001_ThreeUp to n_ThreeIt is formed with a series of line parts. In addition, the effective line portion in each frame portion is defined as the line portion Ln.₁+1 to line part Ln₂And the number of effective lines in each frame is 2k = n₂-N₁Set to. Furthermore, the number of valid data samples in each line portion is set to 4k. Then, the number of quantization bits is selected to be 10 bits or 12 bits.
[0040]
  Under such circumstances, the line portion L0001 to the line portion Ln in each frame portion._ThreeRespectively, the line part of the G data series in which the number of quantization bits is 10 bits or 12 bits, the line part of the B data series in which the number of quantization bits is 10 bits or 12 bits, and the number of quantization bits In particular, a line portion Ln forming an effective line portion is included.₁₊1 to line part Ln₂For each of the above, the line part Ln which is one of them₁₊As shown in FIG. 3, the state in 1 is a line portion of a G data series in which the number of quantization bits forming it is 10 bits or 12 bits, and B in which the number of quantization bits is 10 bits or 12 bits. Each of the line part of the data series and the line part of the R data series having the quantization bit number of 10 bits or 12 bits is formed as including the line blanking part and the video data part.
[0041]
  Each line blanking section is configured such that the timing reference code: EAV is disposed at the start end portion thereof and the timing reference code: SAV is disposed at the end portion thereof. On the other hand, for the video data part, the video data part in the G data series is configured by arranging data GD representing the green primary color signal information with 4k effective data samples, and the video data part in the B data series is composed of the effective data samples. The data BD representing the blue primary color signal information having a number of 4k is arranged, and the video data portion in the R data series is arranged by arranging the data RD representing the red primary color signal information having an effective data sample number of 4k. .
[0042]
  Further, a line portion Ln forming an effective line portion in each frame portion₁₊1 to line part Ln₂The data GD that represents the green primary color signal information and the data that represents the blue primary color signal information in the video data portion in each of the line portion of the G data series, the line portion of the B data series, and the line portion of the R data series. When the data RD representing the BD or the red primary color signal information is arranged, the data GD representing all the 10-bit codes or 12-bit codes in which the upper 8 bits are 00h or FFh in hexadecimal notation, and the green primary color signal information. , Forbidden codes that are not used as data BD representing blue primary color signal information and data RD representing red primary color signal information. The prohibition code determined in this way is also used when the number of quantization bits shown in FIG. 2 is 10 bits or 12 bits.
[0043]
  As described above, digital data having the data format shown in FIG. 3 is obtained.DeData formationTo the lawTherefore, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, and the number of lines in each frame is n._Three, The number of effective lines in each frame is 2k = n₂-N₁, The number of valid data samples in each line is set to 4k, the number of quantization bits is 10 bits or 12 bits, and the prohibition code for each valid line part is the upper 8 bits in hexadecimal representation 00h or FFh Digital data forming a digital video signal of 4: 4: 4 format in 10-bit or 12-bit code is formed.
[0044]
  AboveDeData formationTo the lawWhen the digital data thus obtained is organized, as shown in FIG. 4, data DA10 to DF10 which are digital data forming a digital video signal having a quantization bit number of 10 bits, and a quantization bit number of 12 bits. The data DA12 to DF12 which are digital data constituting the digital video signal and the data DA14 to DC14 which are digital data constituting the digital video signal having the quantization bit number of 14 bits and the quantization bit number of 16 bits. Data DA16 to DC16, which are digital data constituting a digital video signal, are obtained.
[0045]
  5 and 6 are claims in the claims of the present application.1, claim 2, claim 7, claim 8, claim 13 and claim 14Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21The data transmission / reception apparatus containing the 1st example of the data transmission apparatus which concerns on either of the invention described in the above is shown.
[0046]
  In the data transmission / reception apparatus shown in FIG. 5 and FIG. 6, the claims in the claims of this application19 to 21On the transmission side constituting the first example of the data transmission apparatus according to any of the inventions described above, digital data DVX constituting a digital video signal is supplied to the data processing unit 291.
[0047]
  The digital data DVX is any of the data shown as DA12, DB12, DC12, DD10, DE10, DF10, DD12, DE12, DF12, DA14, DB14, DC14, DA16, DB16, and DC16 in FIG. The frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame portion is set to a numerical value 2k of 1600 or more and 2250 or less, for example, 2160, and the number of effective data samples in each line portion is 3400 or more. A numerical value 4k of 4400 or less, for example, 3840 is set, the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits, and the prohibition code for each effective line part is 00h in hexadecimal notation for the upper 8 bits. FF All 10-bit code, 12-bit code that was set to 14-bit code or the 16-bit code, 4: 2: 2 format or 4: 4: is a digital data constituting the digital video signal of 4 format.
[0048]
  When the digital data DVX is the data DA12 shown in FIG. 4, the data DA12 has a frame rate of 24 Hz and the number of effective lines in each frame part is set to 2k as shown in FIG. A Y data sequence, which is a 12-bit word string data, forming a digital video signal having a series of frame portions Frame 1, 2, 3,. P as 12-bit word string data_B/ P_RThe data series is supplied to the data processing unit 291 as 24-bit word string data obtained by parallel multiplexing under frame synchronization and line synchronization.
[0049]
  In the effective data samples of 4k samples in each line portion of the data DA12, each of them includes data YD representing luminance signal information constituting the Y data series, and every other one of them is included. Things are P_B/ P_RData PbD / PrD representing color difference signal information constituting the data series is included. Therefore, each set of two consecutive valid data samples is composed of a sample including data YD and data PbD / PrD and a sample including only data YD.
[0050]
  Under such circumstances, the data processing unit 291 performs the following data processing on the data DA12 supplied as shown in FIG. 7A.
[0051]
  First, the effective data samples in each line portion of the data DA12 are subjected to a process of alternately distributing a set of two consecutive samples in order to form two divided digital data DA12A and DA12B. Each of the divided digital data DA12A and DA12B has a frame rate of 24 Hz, the number of effective lines in each frame is set to 2k, as shown in FIGS. 7B and 7C. A series of frame portions Frame 1A or 1B, 2A or 2B, 3A or 3B, in which the number of data samples is set to 4k / 2, which is 3400/2 or more and 4400/2 or less, for example, 3840/2 = 1920 .. Are 24-bit word string data forming a digital video signal having.
[0052]
  Next, with respect to the divided digital data DA12A, two first alternate line portions (for example, odd-numbered line portions) and second alternate line portions (for example, even-numbered line portions) are provided. Are stored in the memories AO and AE, respectively. The line portions stored in the memories AO and AE have a frame rate of 24 Hz as shown in FIGS. 8A and 8B, respectively, and the number of effective lines in each frame is 1600/2 or more and 2250/2. A series of frame parts Frame1AO or 1AE, 2AO or 2AE, 3A0 or 3AE, which are set to the following numerical values 2k / 2, for example, 1080 and the number of valid data samples in each line is set to 4k / 2 A 24-bit word string data forming a digital video signal having.
[0053]
  At the same time, for the divided digital data DA12B, two first alternate line portions (for example, odd-numbered line portions) and second alternate line portions (for example, even-numbered line portions) are provided. Are stored in the memories BO and BE, respectively. The line portions stored in the memories BO and BE have a frame rate of 24 Hz as shown in FIGS. 9A and 9B, and the number of effective lines in each frame is 1600/2 or more and 2250/2. A series of frame portions Frame 1BO or 1BE, 2BO or 2BE, 3B0 or 3BE, in which the following numerical values are set to 2k / 2, for example, 1080, and the number of valid data samples in each line is set to 4k / 2 A 24-bit word string data forming a digital video signal having.
[0054]
  Subsequently, each of the line portion stored in the memory AO and the line portion stored in the memory AE is read as forming 24-bit parallel data forming a segmented frame digital video signal with a frame rate of 24 Hz. A process of obtaining 24-bit word string data with a word transmission rate of 74.25 MBps is performed, whereby each of the frame rates is 24 Hz and a series of segmented frames as shown in C and D of FIG. A digital video signal having the parts SF1A1 or 1A2, 2A1, 2A2, 3A1, 3A2,..., And a 24-bit word string data DA12A1 and DA12A2 with a word transmission rate of 74.25 MBps are linked to the link A-1. And link A-2.
[0055]
  At the same time, the line portion stored in the memory BO and the line portion stored in the memory BE are read as forming 24-bit parallel data forming a segmented frame digital video signal with a frame rate of 24 Hz. Thus, a process of obtaining 24-bit word string data with a word transmission rate of 74.25 MBps is performed, whereby each of the frame rate is 24 Hz and a series of segment segments as shown in C and D of FIG. 24 bit word string data DA12B1 and DA12B2 with a word transmission rate of 74.25 MBps, which form a digital video signal having a Ted frame portion SF1B1 or 1B2, 2B1 or 2B2, 3B1 or 3B2,. -1 and link B-2.
[0056]
  Each of the 24-bit word string data DA12A1, DA12A2, DA12B1 and DA12B2 is composed of 12-bit words YD0, YD1, YD2, YD3,._B/ P_RThe 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series are parallel-multiplexed.
[0057]
  Further, as shown in FIG. 10, for each of the 24-bit word string data DA12A1, DA12A2, DA12B1 and DA12B2, 12-bit words YD0, YD1, YD2, YD3,. P_B/ P_REach of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series is represented by upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11, ... and Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11, ... ..., lower 2 bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1, ... and Pb0; 0-1, Pr0; 0-1, Pb1 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; 0-1,.
[0058]
  Then, the divided upper 10-bit columns: Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11,. : Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11,. Each of the 20-bit word string data DA12A1A, DA12A2A, DA12B1A, and DA12B2A having a word transmission rate of 74.25 MBps is shown as link A-1A, link A-2A, link B-1A, or link B-2A in FIG. Form as shown.
[0059]
  In addition, the divided lower 2 bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,..., And 8 auxiliary bits c0, c1, c2, 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 .. And the divided lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; 0-1 ,... Are added with 8 auxiliary bits d0, d1, d2, d3,..., 10 bits [Pb0; 0-1] + d0, [Pr0; 0-1] + d1 , [Pb1; 0-1] + d2, [Pr1; 0-1] + d3, [Pb2; 0-1] + d4, [Pr2; 0-1] + d5, ... . And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. 10-bit sequence: [Pb0; 0-1] + d0, [Pr0; 0-1] + d1, [Pb1; 0-1] + d2, [Pr1; 0-1] + d3, [Pb2; 0-1] + d4 [Pr2; 0-1] + d5,... Are multiplexed in parallel, and each of the 20-bit word string data DA12A1B, DA12A2B, DA12B1B, and DA12B2B having a word transmission rate of 74.25 MBps is connected to the link A−. 1B, link A-2B, link B-1B, or link B-2B are formed as shown in FIG.
[0060]
  Alternatively, the divided lower 2 bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... And the divided lower 2 bits Pb0; 1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; 0-1,.
[0061]
  10 bits [Y0BR0; 0-1] + d0, obtained by multiplexing the divided lower 2 bits Y0; 0-1 and Pb0; 0-1 and Pr0; 0-1 and adding 4 auxiliary bits d0 Divided lower 2 bits Y1; 10 bits obtained by adding 8 auxiliary bits e0 to 0-1 [Y1; 0-1] + e0, divided lower 2 bits Y2; 0-1 and Pb1; 0- 10 bits obtained by multiplexing 1 and Pr1; 0-1 and adding 4 auxiliary bits d1 [Y2BR1; 0-1] + d1, divided lower 2 bits Y3; 8-bit auxiliary to 0-1 10 bits obtained by adding bit e1 [Y3; 0-1] + e1, divided lower 2 bits Y4; 0-1 and Pb2; 0-1 and Pr2; 0-1 and 4 bit auxiliary Obtained by adding bit d2 10 bits [Y4BR2; 0-1] + d2, divided lower 2 bits Y5; 10 bits obtained by adding 8 auxiliary bits e2 to 0-1 [Y5; 0-1] + e2,... -Forming. Then, the 10-bit string thus obtained and the auxiliary 10-bit words αD0, αD1, αD2, αD3,... Are parallel-multiplexed to form a 20-bit word with a word transmission rate of 74.25 MBps. Each of the column data DA12A1B, DA12A2B, DA12B1B, and DA12B2B is formed as a link A-1B, a link A-2B, a link B-1B, or a link B-2B as shown in FIG.
[0062]
  That is, in this case, the data processing unit 291 is a digital video in which the frame rate is 24 Hz, the number of effective lines in each frame unit is set to 2k, and the number of effective data samples in each line unit is set to 4k. The Y data series made into 12-bit word string data and the P made into 12-bit word string data, which form a signal_B/ P_RData DA12, which is a 24-bit word string data obtained by parallel multiplexing under a frame synchronization and line synchronization with a data sequence, is a 20-bit word string data each having a word transmission rate of 74.25 MBps. DA12A1A, DA12A2A, DA12A1B, DA12A2B, DA12B1A, DA12B2A, DA12B1B, and DA12B2B are converted into eight word string data. Then, the data processing unit 291 converts the eight word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 ( 20), DPB3 (20) and DPB4 (20).
[0063]
  The data processing unit 291 includes the case where the digital data DVX is the data DA12 even when the digital data DVX is the data DB12 having a frame rate of 25 Hz shown in FIG. 4 or the data DC12 having a frame rate of 30 Hz. Similarly, the Y data series as 12-bit word string data forming a digital video signal in which the number of effective lines in each frame portion is set to 2k and the number of effective data samples in each line portion is set to 4k; P as 12-bit word string data_B/ P_RData DB12 or DC12, which is a 24-bit word string data, obtained by parallel multiplexing under a data synchronization and frame synchronization and line synchronization, is a 20-bit word with a word transmission rate of 74.25 MBps. It is converted into word system data of 8 lines which are column data. Then, the data processing unit 291 also converts such 8-system word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 ( 20), DPB3 (20) and DPB4 (20).
[0064]
  Further, the digital data DVX is data DA14, DB14, DC14, DA16, DB16 which are digital data forming a 4: 2: 2 format digital video signal in which the quantization bit number shown in FIG. 4 is 14 bits or 16 bits. Or when it is set as DC16, the data processing part 291 performs the process similar to the case with respect to data DA12, DB12, or DC12 with respect to data DA14, DB14, DC14, DA16, DB16, or DC16. However, Y data series and P_B/ P_RInstead of the process of dividing each of the 12-bit words constituting the data series into upper 10 bits and lower 2 bits, the Y data series and P_B/ P_RProcessing to divide each 14-bit word constituting the data series into upper 10 bits and lower 4 bits, or Y data series and P_B/ P_RA process of dividing each 16-bit word constituting the data series into upper 10 bits and lower 6 bits is performed.
[0065]
  The data DA14, DB14, DC14, DA16, DB16, or DC16 having a quantization bit number of 14 bits or 16 bits is converted into 20-bit word string data each having a word transmission rate of 74.25 MBps. Convert to word string data. The data processing unit 291 also converts such 8-system word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 (20). , DPB3 (20) and DPB4 (20).
[0066]
  When the digital data DVX is the data DD10 shown in FIG. 4, the data DD10 has a frame rate of 24 Hz, the number of effective lines in each frame part is set to 2k, as shown in FIG. A G data sequence that is a 10-bit word string data and that forms a digital video signal having a series of frame portions Frame 1, 2, 3,. As 30-bit word string data obtained by parallel-multiplexing the B data series made into 10-bit word string data and the R data series made into 10-bit word string data under frame synchronization and line synchronization, The data is supplied to the data processing unit 291.
[0067]
  In the effective data samples of 4k samples in each line portion of the data DD10, the data GD and the blue primary color signal information constituting the B data series each representing the green primary color signal information constituting the G data series are represented. Data BD representing, and data RD representing red primary color signal information constituting the R data series are included.
[0068]
  Under such circumstances, the data processing unit 291 performs the following data processing on the data DD10 supplied as shown in FIG.
[0069]
  First, valid data samples S0, S1, S2, S3, S4, S5,... (S0, S1, S2, S3, S4, S5,. Sampled green primary color signal information SG0, SG1, SG2,... And sampled blue primary color signal information SB0, SB1, SB2,. 15), the data SR0, SR1, SR2,... Representing the red primary color signal information (see FIG. 15) are sequentially distributed one sample at a time, as shown in A and B of FIG. Two divided digital data DD10A and DD10B are formed.
[0070]
  Each of the divided digital data DD10A and DD10B has a frame rate of 24 Hz, the number of effective lines in each frame is set to 2k, as shown in FIGS. 14B and 14C. A series of frame portions Frame 1A or 1B, 2A or 2B, 3A or 3B, in which the number of data samples is set to a numerical value 4k / 2 of 3400/2 or more and 4400/2 or less, for example, 3840/2 = 1920 .. Are 30-bit word string data forming a digital video signal.
[0071]
  Next, with respect to the divided digital data DD10A, as shown in FIGS. 16A and 16B, first alternate line portions (for example, odd-numbered line portions) Line AD1, Line AD3, Line AD5,. .. And second alternate line portions (for example, even-numbered line portions) Line AD2, Line AD4, Line AD6,... Are stored in two memories AO and AE, respectively. The line portions stored in the memories AO and AE have a frame rate of 24 Hz as shown in FIGS. 17A and 17B, and the number of effective lines in each frame is 1600/2 or more and 2250/2. The following numerical value is set to 2k / 2, for example, 1080, and the number of valid data samples in each line is set to 4k / 2, and the frame portion Frame 1A0 or 1AE, 2A0 or 2AE, 3A0 or 3AE,. .. 30-bit word string data forming a digital video signal having.
[0072]
  At the same time, as shown in FIGS. 18A and B, for the divided digital data DD10B, first alternate line portions (for example, odd-numbered line portions) Line BD1, Line BD3, Line BD5,. .. And second alternate line portions (for example, even-numbered line portions) Line BD2, Line BD4, Line BD6,... Are stored in two memories BO and BE, respectively. The line portions stored in each of the memories BO and BE have a frame rate of 24 Hz as shown in A and B of FIG. 19, and the number of effective lines in each frame is 1600/2 or more and 2250/2. The following numerical value is set to 2k / 2, for example, 1080, and the number of valid data samples in each line is set to 4k / 2, and the frame portion Frame 1B0 or 1BE, 2B0 or 2BE, 3B0 or 3BE,. .. 30-bit word string data forming a digital video signal having.
[0073]
  Subsequently, each of the line unit stored in the memory AO and the line unit stored in the memory AE is read as forming 30-bit parallel data forming a segmented frame digital video signal with a frame rate of 24 Hz, A process of obtaining 30-bit word string data with a word transmission rate of 74.25 MBps is performed, whereby each of the frame rate is 24 Hz and a series of segmented frames as shown in C and D of FIG. A digital video signal having SF1A1, 1A2, 2A1, 2A2, 3A1, 3A2,..., 30-bit word string data DD10A1 and DD10A2 having a word transmission rate of 74.25 MBps, link A-1 And link A-2.
[0074]
  At the same time, the line portion stored in the memory BO and the line portion stored in the memory BE are read as forming 30-bit parallel data constituting a segmented frame digital video signal with a frame rate of 24 Hz. Thus, a process for obtaining 30-bit word string data with a word transmission rate of 74.25 MBps is performed, whereby each of the frame rate is 24 Hz and a series of segment segments as shown in C and D of FIG. A digital video signal having a Ted frame SF1B1, 1B2, 2B1, 2B2, 3B1, or 3B2,..., Link B with 30-bit word string data DD10B1 and DD10B2 with a word transmission rate of 74.25 MBps. -1 and link B-2.
[0075]
  Each of the 30-bit word string data DD10A1, DD10A2, DD10B1, and DD10B2 is composed of 10-bit words GD0, GD1, GD2, GD3,. The 10-bit words BD0, BD1, BD2, BD3,... Constituting the sequence and the 10-bit words RD0, RD1, RD2, RD3,. It is supposed to consist of
[0076]
  Further, as shown in FIG. 20, for each of 30-bit word string data DD10A1, DD10A2, DD10B1 and DD10B2, 10-bit words GD0, GD1, GD2, GD3,. 10-bit words BD0, BD1, BD2, BD3,... Constituting the data series and 10-bit words RD0, RD1, RD2, RD3,. The auxiliary 10-bit words AD0, AD1, AD2, AD3,... Constituting the auxiliary data series are divided as shown by the bold solid line in FIG. Bit word GD0, GD1, GD2, GD3, ..., 10-bit word forming a B data series 10-bit word group 1 including D0, BD2,... And 10-bit words RD0, RD2,... Forming an R data series, and auxiliary 10-bit words AD0, AD1 forming an auxiliary data series. , AD2, AD3,..., 10-bit words BD1, BD3,... Forming a B data series and 10-bit words RD1, RD3,. Sort to 10-bit word group 2.
[0077]
  Then, the 20-bit word string data DD10A1A, DD10A2A, DD10B1A, and DD10B2A having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 21 are respectively connected to the link A-1A, the link A-2A, The link B-1A or the link B-2A is formed as shown in FIG. Further, based on the 10-bit word group 2 shown in FIG. 21, the 20-bit word string data DD10A1B, DD10A2B, DD10B1B and DD10B2B having a word transmission rate of 74.25 MBps are respectively connected to the link A-1B, the link A-2B, The link B-1B or the link B-2B is formed as shown in FIG.
[0078]
  That is, in this case, the data processing unit 291 is a digital video in which the frame rate is 24 Hz, the number of effective lines in each frame unit is set to 2k, and the number of effective data samples in each line unit is set to 4k. The G data series, which is a 10-bit word string data, the B data series, which is a 10-bit word string data, and the R data series, which is a 10-bit word string data, form a signal and perform frame synchronization and line synchronization. The data DD10, which is obtained as a 30-bit word string data, obtained by parallel multiplexing under the same conditions, is converted into 20-bit word string data DD10A1A, DD10A2A, DD10A1B, DD10A2B, DD10B1A, DD10B2A each having a word transmission rate of 74.25 MBps. , DD10B1B Fine DD10B2B, is to convert the 8 strains word sequence data. Then, the data processing unit 291 converts the eight word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 ( 20), DPB3 (20) and DPB4 (20).
[0079]
  In the case where the digital data DVX is DE10 with a frame rate of 25 Hz shown in FIG. 4 or DF10 with a frame rate of 30 Hz, the data processing unit 291 performs the same process as when the digital data DVX is DD10. The G data series and 10-bit word, which are 10-bit word string data, form a digital video signal in which the number of effective lines in each frame portion is set to 2k and the number of effective data samples in each line portion is set to 4k. Data DE10 to be 30-bit word string data obtained by parallel-multiplexing the B data series as column data and the R data series as 10-bit word string data under frame synchronization and line synchronization. Or DF10, each with a word transmission rate of 7 Converted into 8 lines of word sequence data which is 20-bit word sequence data to .25MBps. Then, the data processing unit 291 also converts such 8-system word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 ( 20), DPB3 (20) and DPB4 (20).
[0080]
  When the digital data DVX is the data DD12 shown in FIG. 4, the data DD12 has a frame rate of 24 Hz and the number of effective lines in each frame portion is set to 2k as shown in FIG. A G data sequence, which is a 12-bit word string data, forming a digital video signal having a series of frame portions Frame 1, 2, 3,. 36-bit word string data obtained by parallel-multiplexing the B data series converted into 12-bit word string data and the R data series converted into 12-bit word string data under frame synchronization and line synchronization. Is supplied to the data processing unit 291.
[0081]
  In the effective data samples of 4k samples in each line portion of the data DD12, the data GD and the blue primary color signal information constituting the B data series each representing the green primary color signal information constituting the G data series are represented. Data BD representing, and data RD representing red primary color signal information constituting the R data series are included.
[0082]
  Under such circumstances, the data processing unit 291 performs the following data processing on the data DD12 supplied as shown in FIG.
[0083]
  First, with respect to the effective data samples in each line portion of the data DD12, the processing for sequentially distributing the samples one by one in the same manner as the processing for the effective data samples in each line portion of the data DD10 shown in FIGS. The two divided digital data DD12A and DD12B are formed.
[0084]
  Each of the divided digital data DD12A and DD12B has a frame rate of 24 Hz, the number of effective lines in each frame is set to 2k, as shown in FIGS. A series of frame portions Frame 1A or 1B, 2A or 2B, 3A or 3B, in which the number of data samples is set to a numerical value 4k / 2 of 3400/2 or more and 4400/2 or less, for example, 3840/2 = 1920 Are 36-bit word string data forming a digital video signal having.
[0085]
  Next, with respect to the divided digital data DD12A, in the same manner as the divided digital data DD10A shown in A and B of FIG. 16, first alternate line portions (for example, odd-numbered line portions) and second Every other line portion (for example, even-numbered line portion) is stored in two memories AO and AE, respectively. The line portions stored in the memories AO and AE have a frame rate of 24 Hz as shown in FIGS. 25A and 25B, respectively, and the number of effective lines in each frame is 1600/2 or more and 2250/2. A series of frame portions Frame 1AO or 1AE, 2AO or 2AE, 3A0 or 3AE, etc., which are set to the following numerical values 2k / 2, for example, 1080 and the number of valid data samples in each line is set to 4k / 2 ... 36 bit word string data forming a digital video signal having.
[0086]
  At the same time, with respect to the divided digital data DD12B, as in the case of the divided digital data DD10B shown in FIGS. 18A and 18B, first alternate line portions (for example, odd-numbered line portions) and second Every other line portion (for example, even-numbered line portion) is stored in two memories BO and BE, respectively. The line portions stored in the memories BO and BE have a frame rate of 24 Hz as shown in FIGS. 26A and 26B, and the number of effective lines in each frame is 1600/2 or more and 2250/2. A series of frame portions Frame 1BO or 1BE, 2BO or 2BE, 3B0 or 3BE, in which the following numerical values are set to 2k / 2, for example, 1080, and the number of valid data samples in each line is set to 4k / 2 ... 36 bit word string data forming a digital video signal having.
[0087]
  Subsequently, each of the line unit stored in the memory AO and the line unit stored in the memory AE is read as forming 36-bit parallel data forming a segmented frame digital video signal with a frame rate of 24 Hz, A process of obtaining 36-bit word string data with a word transmission rate of 74.25 MBps is performed, whereby each of the frame rate is 24 Hz and a series of segmented frames as shown in C and D of FIG. A digital video signal having SF1A1, 1A2, 2A1, 2A2, 3A1, 3A2,..., 36-bit word string data DD12A1 and DD12A2 having a word transmission rate of 74.25 MBps, link A-1 And link A-2.
[0088]
  At the same time, the line portion stored in the memory BO and the line portion stored in the memory BE are read as forming 36-bit parallel data forming a segmented frame digital video signal with a frame rate of 24 Hz. Thus, a process of obtaining 36-bit word string data with a word transmission rate of 74.25 MBps is performed, whereby each of the frame rate is set to 24 Hz, as shown in C and D of FIG. A digital video signal having a Ted frame SF1B1, 1B2, 2B1, 2B2, 3B1, or 3B2,..., Link B to 36-bit word string data DD12B1 and DD12B2 with a word transmission rate of 74.25 MBps. -1 and link B-2.
[0089]
  Each of the 36-bit word string data DD12A1, DD12A2, DD12B1 and DD12B2 is, as shown in FIG. 27, 12-bit words GD0, GD1, GD2, GD3,. The 12-bit words BD0, BD1, BD2, BD3,... Constituting the sequence and the 12-bit words RD0, RD1, RD2, RD3,. It is supposed to consist of
[0090]
  Further, as shown in FIG. 27, for each of 36-bit word string data DD12A1, DD12A2, DD12B1 and DD12B2, 12-bit words GD0, GD1, GD2, GD3,. 12-bit words BD0, BD1, BD2, BD3,... Constituting the data series and 12-bit words RD0, RD1, RD2, RD3,. Upper 10 bits G0; 2-11, G1; 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; , B3; 2-11,... And R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. ; 0-1, G 0-1, G2; 0-1, G3; 0-1, ..., B0; 0-1, B1; 0-1, B2; 0-1, B3; 0-1,. .. And R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,.
[0091]
  Next, the divided lower 2 bits G0; 0-1, G1; 0-1, G2; 0-1, G3; 0-1, ..., B0; 0-1, B1; , B2; 0-1, B3; 0-1,... And R0; 0-1, R1; 0-1, R2; 0-1, R3; 10 bits [GBR0: 0-1] + f0, G1 obtained by bit-multiplexing G0; 0-1 and B0; 0-1 and R0; 0-1 and adding 4 auxiliary bits f0 0-1 and B1; 0-1 and R1; 0-1 and 10 bits obtained by adding 4 auxiliary bits f1 [GBR1: 0-1] + f1, G2; 0-1 10 bits obtained by bit-multiplexing B2; 0-1 and R2; 0-1 and adding 4 auxiliary bits f2 [GBR2: 0-1 ] + F2, G3; 10 bits obtained by bit-multiplexing 0-1 and B3; 0-1 and R3; 0-1 and adding 4 auxiliary bits f3 [GBR3: 0-1] + f3,. Is formed.
[0092]
  Subsequently, as shown in FIG. 28, the divided upper 10-bit columns: G0; 2-11, G1; 2-11, G2; 2-11, G3; 2-11,. B0; 2-11, B1; 2-11, B2; 2-11, B3; 2-11, ..., and R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,... And formed 10-bit string: [GBR0: 0-1] + f0, [GBR1: 0-1] + f1, [GBR2: 0-1] + f2, [GBR3 : 0-1] + f3,... Are divided as shown by the bold solid line in FIG. 28, and the divided upper 10-bit columns: G0; 2-11, G1; 2-11 , G2; 2-11, G3; 2-11,... And upper 10 bits divided: B0; 2-11, B2; 2-11, B4; 2-11,... And R0; 2-11, R2; 2-11, R4; 2-11,. Upper 10 bits: B1; 2-11, B3; 2-11, B5; 2-11, ... and R1; 2-11, R3; 2-11, R5; 2-11, ... And a formed 10-bit string: [GBR0: 0-1] + f0, [GBR1: 0-1] + f1, [GBR2: 0-1] + f2, [GBR3: 0-1] + f3,. .. and 10-bit word group 2 including
[0093]
  Then, based on the 10-bit word group 1 shown in FIG. 28, the 20-bit word string data DD12A1A, DD12A2A, DD12B1A and DD12B2A having a word transmission rate of 74.25 MBps are respectively connected to the link A-1A, the link A-2A, The link B-1A or the link B-2A is formed as shown in FIG. Further, based on the 10-bit word group 2 shown in FIG. 28, the 20-bit word string data DD12A1B, DD12A2B, DD12B1B, and DD12B2B having a word transmission rate of 74.25 MBps are respectively connected to the link A-1B, the link A-2B, The link B-1B or the link B-2B is formed as shown in FIG.
[0094]
  That is, in this case, the data processing unit 291 is a digital video in which the frame rate is 24 Hz, the number of effective lines in each frame unit is set to 2k, and the number of effective data samples in each line unit is set to 4k. The G data series, which is a 12-bit word string data, the B data series, which is a 12-bit word string data, and the R data series, which is a 12-bit word string data, form a signal and perform frame synchronization and line synchronization. The data DD12, which is 36-bit word string data obtained by being multiplexed in parallel under the condition, is converted into 20-bit word string data DD12A1A, DD12A2A, DD12A1B, DD12A2B, DD12B1A, DD12B2A each having a word transmission rate of 74.25 MBps. , DD12B1B Fine DD12B2B, is to convert the 8 strains word sequence data. Then, the data processing unit 291 converts the eight word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 ( 20), DPB3 (20) and DPB4 (20).
[0095]
  In the case where the digital data DVX is DE12 with a frame rate of 25 Hz shown in FIG. 4 or DF12 with a frame rate of 30 Hz, the data processing unit 291 performs the same process as when the digital data DVX is DD12. A G data sequence as 12-bit word string data, which forms a digital video signal in which the number of effective lines in each frame portion is set to 2k and the number of effective data samples in each line portion is set to 4k, and 12 bits The B data series converted to word string data and the R data series converted to 12-bit word string data are 36-bit word string data obtained by parallel multiplexing under frame synchronization and line synchronization. Data DE12 or DF12, each with a word transmission rate Converted into 8 lines of word sequence data which is 20-bit word sequence data to 74.25 MBps. Then, the data processing unit 291 also converts such 8-system word string data into 20-bit word string data DPA1 (20), DPA2 (20), DPA3 (20), DPA4 (20), DPB1 (20), DPB2 ( 20), DPB3 (20) and DPB4 (20).
[0096]
  The 20-bit word string data DPA1 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 291 is supplied to the data insertion unit 292. The data insertion unit 292 inserts auxiliary data DAA1 including channel identification data as necessary into the 20-bit word string data DPA1 (20), and 20-bit word string data DPA1 ′ into which the auxiliary data DAA1 is inserted. (20) is formed. The 20-bit word string data DPA1 ′ (20) obtained from the data insertion unit 292 is supplied to the P / S conversion unit 293.
[0097]
  In the P / S conversion unit 293, the 20-bit word string data DPA1 ′ (20) is subjected to P / S conversion, and the bit transmission rate based on the 20-bit word string data DPA1 ′ (20) is set to 74.25 MBps × Serial data DSA1 with 20 = 1.485 Gbps is formed, and the serial data DSA1 is supplied to the E / O converter 294.
[0098]
  The E / O converter 294 performs electro-optical conversion processing on the serial data DSA1, and based on the serial data DSA1, an optical signal OSA1 having a center wavelength of, for example, approximately 1.3 μm, and a bit transmission rate of 1.485 Gbps. And send it as a transmission signal.
[0099]
  Also, 20-bit word string data DPA2 (20) to DPA4 (20) and DPB1 (20) to DPB4 (20) with a word transmission rate sent from the data processing unit 291 of 74.25 MBps are respectively data insertion units. 295-301. In the data insertion units 295 to 301, auxiliary data DAA2 including channel identification data as required is added to the 20-bit word string data DPA2 (20) to DPA4 (20) and DPB1 (20) to DPB4 (20). DAA3, DAA4, DAB1, DAB2, DAB3 and DAB4 are inserted, and 20-bit word string data DPA2 ′ (20) to DPA4 ′ (20) and DPB1 ′ (20) to DPB4 ′ (20) into which auxiliary data is inserted are inserted. Form.
[0100]
  The 20-bit word string data DPA2 ′ (20) to DPA4 ′ (20) and DPB1 ′ (20) to DPB4 ′ (20) obtained from the data insertion units 295 to 301 are supplied to the P / S conversion units 302 to 308. The
[0101]
  The P / S converters 302 to 308 perform P / S conversion on the 20-bit word string data DPA2 ′ (20) to DPA4 ′ (20) and DPB1 ′ (20) to DPB4 ′ (20), Serial data DSA2 to DSA4 and DSB1 to DSB4 with a bit transmission rate based on them of 74.25 MBps × 20 = 1.485 Gbps are formed and supplied to the E / O converters 310 to 316.
[0102]
  In the E / O converters 310 to 316, the optical data OSA2 to OSA4 and OSB1 are set based on the optical data OSA2 to OSA4 and OSB1 based on the serial data DSA2 to DSA4 and DSB1 to DSB4, respectively. -OSB4 is formed with each having a bit transmission rate of 1.485 Gbps, and is transmitted as a transmission signal.
[0103]
  The optical signal OSA1 that is a transmission signal sent from the E / O conversion unit 294 is guided to the optical fiber transmission path 321 through the optical connector 320 and transmitted to the receiving side through the optical fiber transmission path 321. The optical signals OSA2 to OSA4 and OSB1 to OSB4, which are transmission signals sent from the E / O conversion units 310 to 316, are led to the optical fiber transmission paths 329 to 335 through the optical connectors 322 to 328, respectively. It is transmitted to the receiving side through 329-335. Each of the optical fiber transmission lines 321 and 329 to 335 is formed using, for example, quartz-based SMF.
[0104]
  On the receiving side, the optical signal OSA 1 transmitted through the optical fiber transmission path 321 is guided to the O / E converter 337 through the optical connector 336. In addition, the optical signals OSA2 to OSA4 and OSB1 to OSB4 transmitted through the optical fiber transmission paths 329 to 335 are guided to the O / E converters 350 to 356 through the optical connectors 339 to 345, respectively.
[0105]
  The O / E conversion unit 337 performs a photoelectric conversion process on the optical signal OSA1 having a bit transmission rate of 1.485 Gbps and a center wavelength of approximately 1.3 μm, and sets the bit transmission rate based on the optical signal OSA1. The serial data DSA1 of 1.485 Gbps is reproduced. The reproduced serial data DSA1 is supplied to the S / P converter 360. The S / P converter 360 performs S / P conversion on the serial data DSA1 to reproduce 20-bit word string data DPA1 ′ (20) based on the serial data DSA1 with a word transmission rate of 74.25 MBps. Then, it is supplied to the data time difference absorption unit 361.
[0106]
  Further, in the O / E converters 350 to 356, photoelectric conversion processing is performed on the optical signals OSA2 to OSA4 and OSB1 to OSB4 having a bit transmission rate of 1.485 Gbps and a center wavelength of approximately 1.3 μm, Based on them, serial data DSA2 to DSA4 and DSB1 to DSB4 with a bit transmission rate of 1.485 Gbps are reproduced. The reproduced serial data DSA2 to DSA4 and DSB1 to DSB4 are supplied to S / P converters 362 to 368, respectively. In the S / P converters 362 to 368, serial data DSA2 to DSA4 and DSB1 to DSB4 are subjected to S / P conversion, and based on these, 20-bit word string data DPA2 having a word transmission rate of 74.25 MBps. '(20) to DPA4' (20) and DPB1 '(20) to DPB4' (20) are reproduced and supplied to the data time difference absorption unit 361.
[0107]
  In the data time difference absorbing unit 361, 20-bit word string data DPA1 ′ (20) from the S / P converter 360 and 20-bit word string data DPA2 ′ (20) from the S / P converters 362 to 368 are used. The mutual time difference generated between DPA4 ′ (20) and DPB1 ′ (20) to DPB4 ′ (20) is absorbed, and the word transmission rate based on the 20-bit word string data DPA1 ′ (20) is set to 74.25 MBps. The word transmission rate is 74. based on the bit word string data DPA1Q ′ (20) and the 20 bit word string data DPA2 ′ (20) to DPA4 ′ (20) and DPB1 ′ (20) to DPB4 ′ (20), respectively. 20-bit word string data DPA2Q ′ (20) to DPA4Q ′ (20) and DPB1Q ′ (20 The ~DPB4Q '(20), and sends as the mutual time difference is aimed to be kept in the absence substantially.
[0108]
  The 20-bit word string data DPA1Q ′ (20) obtained from the data time difference absorbing unit 361 is supplied to the data separating unit 370. In the data separator 370, the auxiliary data DAA1 is separated from the 20-bit word string data DPA1Q ′ (20), and the 20-bit word string data DPA1Q (20) and the auxiliary data DAA1 are individually transmitted. The bit word string data DPA1Q (20) is supplied to the data reproduction processing unit 371.
[0109]
  The 20-bit word string data DPA2Q ′ (20) to DPA4Q ′ (20) and DPB1Q ′ (20) to DPB4Q ′ (20) obtained from the data time difference absorption unit 361 are supplied to the data separation units 372 to 378, respectively. Is done. In the data separators 372 to 378, the auxiliary data DAA2, DAA3, DAA4, DAB1 are obtained from the 20-bit word string data DPA2Q ′ (20) to DPA4Q ′ (20) and DPB1Q ′ (20) to DPB4Q ′ (20). , DAB2, DAB3 and DAB4 are separated, and 20-bit word string data DPA2Q (20) to DPA4Q (20) and DPB1Q (20) to DPB4Q (20) and auxiliary data DAA2, DAA3, DAA4, DAB1, DAB2, DAB3 And DAB4 are sent separately, and the 20-bit word string data DPA2Q (20) to DPA4Q (20) and DPB1Q (20) to DPB4Q (20) are supplied to the data reproduction processing unit 371.
[0110]
  In the data reproduction processing unit 371, the 20-bit word string data DPA1Q (20) to DPA4Q (20) and DPB1Q (20) to DPB4Q (20) are converted into digital data DVX by the data processing unit 291 on the transmission side. A data reproduction process opposite to the data conversion process is performed to reproduce the digital data DVX based on the 20-bit word string data DPA1Q (20) to DPA4Q (20) and DPB1Q (20) to DPB4Q (20). Such digital data DVX is data shown as DA12, DB12, DC12, DD10, DE10, DF10, DD12, DE12, DF12, DA14, DB14, DC14, DA16, DB16 and DC16 in FIG.
[0111]
  In the above description, the Y signal data series and P in the data forming the digital video signal having the quantization bit number of 12 bits or more are used._B/ P_RThe 20-bit word string data formed based on the upper 10-bit string divided from each of the 12-bit words constituting each of the data series or the G data series, the B data series, and the R data series, Each can be recorded and reproduced by, for example, a current HD digital video signal magnetic recording / reproducing device (referred to as HD VTR). Therefore, using the current HD VTR, it is possible to check and edit the content of such 20-bit word string data, and further, using the current HD VTR and video monitor, A reproduced image based on such 20-bit word string data can be obtained, and thus, when handling data constituting a digital video signal with a quantization bit number of 12 bits or more, confirmation work etc. is performed using current equipment. This is very convenient.
[0112]
  31 and 32 are the claims in the claims of the present application.1, claim 4, claim 7, claim 10, claim 13 and claim 16Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21The part of the data transmission / reception apparatus containing the 2nd example of the data transmission apparatus which concerns on either of the invention described in the above is shown.
[0113]
  The data transmitting / receiving apparatus whose parts are shown in FIG. 31 and FIG. 32 has many parts configured in the same manner as the data transmitting / receiving apparatus shown in FIG. 5 and FIG. Only the parts different from the data transmission / reception apparatus shown in FIG. 6 and the parts related thereto are shown.
[0114]
  In the data transmission / reception apparatus shown in FIG. 31 and FIG. 32, the E / O conversion units 294 and 310 to 316 and the O / E conversion unit provided in the data transmission / reception apparatus shown in FIG. 5 and FIG. Instead of 337 and 350 to 356, E / O conversion units 385 to 388 and O / E conversion units 404 to 407 are provided. Furthermore, instead of the optical connectors 320 and 322 to 328, the optical fiber transmission paths 321 and 329 to 335, and the optical connectors 336 and 339 to 345 provided in the data transmission / reception apparatus shown in FIGS. 389 to 392, optical fiber transmission lines 395 to 398, and optical connectors 400 to 403 are provided. Each of the optical fiber transmission lines 395 to 398 is formed using, for example, quartz-based SMF.
[0115]
  31 and 32, the serial data DSA1 with the bit transmission rate from the P / S conversion unit 293 of 1.485 Gbps and the bit transmission rate from the P / S conversion unit 302 in the data transmission / reception apparatus shown in FIG. 31 and FIG. The serial data DSA2 having 1.485 Gbps is supplied to the bit multiplexing unit 381. The bit multiplexing unit 381 performs an operation of alternately taking out one bit address from each of the serial data DSA1 and DSA2 and sequentially arranging them, performing bit multiplexing processing on the serial data DSA1 and DSA2, and setting the bit transmission rate. Composite serial data DZA1 of 1.485 Gbps × 2 = 2.97 Gbps is formed.
[0116]
  The composite serial data DZA1 obtained from the bit multiplexing unit 381 is supplied to the E / O conversion unit 385. In the E / O conversion unit 385, an optical signal OZA1 having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZA1 is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
[0117]
  Serial data DSA3 with a bit transmission rate of 1.485 Gbps from the P / S conversion unit 303 and serial data DSA4 with a bit transmission rate of 1.485 Gbps from the P / S conversion unit 304 are supplied to the bit multiplexing unit 382. Is done. The bit multiplexing unit 382 performs an operation of alternately taking out one bit address from each of the serial data DSA3 and DSA4 and sequentially arranging them, performing bit multiplexing processing on the serial data DSA3 and DSA4, and setting the bit transmission rate. Composite serial data DZA2 with 1.485 Gbps × 2 = 2.97 Gbps is formed.
[0118]
  The composite serial data DZA2 obtained from the bit multiplexing unit 382 is supplied to the E / O conversion unit 386. In the E / O conversion unit 386, an optical signal OZA2 having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZA2 is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
[0119]
  Serial data DSB1 with a bit transmission rate of 1.485 Gbps from the P / S conversion unit 305 and serial data DSB2 with a bit transmission rate of 1.485 Gbps from the P / S conversion unit 306 are supplied to the bit multiplexing unit 383. Is done. The bit multiplexing unit 383 performs an operation of alternately taking out one bit address from each of the serial data DSB1 and DSB2 and sequentially arranging them, performing bit multiplexing processing on the serial data DSB1 and DSB2, and setting the bit transmission rate. Composite serial data DZB1 with 1.485 Gbps × 2 = 2.97 Gbps is formed.
[0120]
  The composite serial data DZB1 obtained from the bit multiplexing unit 383 is supplied to the E / O conversion unit 387. In the E / O conversion unit 387, an optical signal OZB1 having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZB1 is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
[0121]
  Further, the serial data DSB3 with the bit transmission rate from the P / S conversion unit 307 of 1.485 Gbps and the serial data DSB4 with the bit transmission rate of 1.485 Gbps from the P / S conversion unit 308 are the bit multiplexing unit 384. To be supplied. The bit multiplexing unit 384 performs an operation of alternately taking out one bit address from each of the serial data DSB3 and DSB4 and sequentially arranging them, performing a bit multiplexing process on the serial data DSB3 and DSB4, and setting a bit transmission rate. Composite serial data DZB2 with 1.485 Gbps × 2 = 2.97 Gbps is formed.
[0122]
  The composite serial data DZB2 obtained from the bit multiplexing unit 384 is supplied to the E / O conversion unit 388. In the E / O converter 388, an optical signal OZB2 having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZB2 is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
[0123]
  The optical signal OZA1 that is a transmission signal sent from the E / O conversion unit 385 is guided to the optical fiber transmission path 395 through the optical connector 389, and is transmitted to the receiving side through the optical fiber transmission path 395. The optical signal OZA2, which is a transmission signal sent from the E / O conversion unit 386, is guided to the optical fiber transmission path 396 through the optical connector 390, and is transmitted to the receiving side through the optical fiber transmission path 396. The optical signal OZB1 which is a transmission signal sent from the E / O conversion unit 387 is guided to the optical fiber transmission path 397 through the optical connector 391 and transmitted to the receiving side through the optical fiber transmission path 397. Further, the optical signal OZB2 that is a transmission signal transmitted from the E / O conversion unit 388 is guided to the optical fiber transmission path 398 through the optical connector 392 and transmitted to the receiving side through the optical fiber transmission path 398.
[0124]
  On the receiving side, the optical signal OZA1 transmitted through the optical fiber transmission path 395 is guided to the O / E converter 404 through the optical connector 400. The optical signal OZA2 transmitted through the optical fiber transmission path 396 is guided to the O / E converter 405 through the optical connector 401. The optical signal OZB1 transmitted through the optical fiber transmission line 397 is guided to the O / E converter 406 through the optical connector 402. Further, the optical signal OZB 2 transmitted through the optical fiber transmission path 398 is guided to the O / E conversion unit 407 through the optical connector 403.
[0125]
  In the O / E converter 404, the optical signal OZA1 having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps is subjected to photoelectric conversion processing, and the bit transmission rate based on the optical signal OZA1 is set. The composite serial data DZA1 of 2.97 Gbps is reproduced. The reproduced composite serial data DZA1 is supplied to the bit separation unit 408.
[0126]
  The bit separation unit 408 extracts one bit at a time from the composite serial data DZA1 and performs an operation of forming every other bit group to perform bit separation processing on the composite serial data DZA1. Then, the channel identification data included in the composite serial data DZA1 is used to specify a channel, and each of the serial data of 2 channels based on the composite serial data DZA1 has a bit transmission rate of 2.97 Gbps / 2 = 1.485 Gbps. Data DSA1 and DSA2 are formed. The serial data DSA1 is supplied to the S / P converter 360, and the serial data DSA2 is supplied to the S / P converter 362.
[0127]
  In the O / E converter 405, the optical signal OZA2 having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps is subjected to photoelectric conversion processing, and the bit transmission rate based on the optical signal OZA2 is set. The composite serial data DZA2 of 2.97 Gbps is reproduced. The reproduced composite serial data DZA2 is supplied to the bit separation unit 409.
[0128]
  The bit separation unit 409 takes out one bit at a time from the composite serial data DZA2 to form every other two bit groups, and performs a bit separation process on the composite serial data DZA2. Then, the channel identification data included in the composite serial data DZA2 is used to identify the channel, and each of the serial data of 2 channels based on the composite serial data DZA2 has a bit transmission rate of 2.97 Gbps / 2 = 1.485 Gbps. Data DSA3 and DSA4 are formed. The serial data DSA3 is supplied to the S / P converter 363, and the serial data DSA4 is supplied to the S / P converter 364.
[0129]
  In the O / E converter 406, the optical signal OZB1 having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps is subjected to photoelectric conversion processing, and the bit transmission rate based on the optical signal OZB1 is set. The composite serial data DZB1 of 2.97 Gbps is reproduced. The reproduced composite serial data DZB1 is supplied to the bit separation unit 410.
[0130]
  The bit separation unit 410 extracts one bit at a time from the composite serial data DZB1 and performs an operation of forming every other bit group to perform bit separation processing on the composite serial data DZB1. Then, the channel identification data included in the composite serial data DZB1 is used to specify a channel, and each of the two-channel serials based on the composite serial data DZB1 has a bit transmission rate of 2.97 Gbps / 2 = 1.485 Gbps. Data DSB1 and DSB2 are formed. The serial data DSB1 is supplied to the S / P conversion unit 365, and the serial data DSB2 is supplied to the S / P conversion unit 366.
[0131]
  Further, the O / E conversion unit 407 performs bit conversion based on the optical signal OZB2 by performing photoelectric conversion processing on the optical signal OZB2 having a center wavelength of approximately 1.3 μm and a bit transmission rate of 2.97 Gbps. The composite serial data DZB2 having a rate of 2.97 Gbps is reproduced. The reproduced composite serial data DZB2 is supplied to the bit separation unit 411.
[0132]
  The bit separation unit 411 extracts one bit at a time from the composite serial data DZB2 and performs an operation of forming every other bit group, and performs bit separation processing on the composite serial data DZB2. Then, the channel identification data included in the composite serial data DZB2 is used to specify a channel, and each of the two serial channels based on the composite serial data DZB2 has a bit transmission rate of 2.97 Gbps / 2 = 1.485 Gbps. Data DSB3 and DSB4 are formed. The serial data DSB3 is supplied to the S / P conversion unit 367, and the serial data DSB4 is supplied to the S / P conversion unit 368.
[0133]
  Other operations are the same as those of the data transmission / reception apparatus shown in FIG. 5 and FIG.
[0134]
  33 and 34 show the claims in the scope of claims of the present application.1, claim 4, claim 6, claim 7, claim 10, claim 12, claim 13, claim 16, and claim 18.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21The part of the data transmission / reception apparatus containing the 3rd example of the data transmission apparatus which concerns on either of the invention described in the above is shown.
[0135]
  The data transmission / reception apparatus shown in FIG. 33 and FIG. 34 has many parts configured similarly to the data transmission / reception apparatus shown in FIG. 31 and FIG. Blocks corresponding to the respective blocks in the data transmission / reception apparatus shown in FIGS. 31 and 32 are denoted by the same reference numerals as those in FIGS. 31 and 32, and redundant description thereof is omitted.
[0136]
  In the data transmission / reception apparatus whose parts are shown in FIGS. 33 and 34, the composite serial data DZA2 having a bit transmission rate of 2.97 Gbps from the bit multiplexing unit 382 is supplied to the E / O conversion unit 420. In the E / O converter 420, an optical signal OZA2 having a center wavelength of, for example, about 1.55 μm based on the composite serial data DZA2 is formed with a bit transmission rate of 2.97 Gbps.
[0137]
  In addition, composite serial data DZB2 having a bit transmission rate of 2.97 Gbps from the bit multiplexing unit 384 is supplied to the E / O conversion unit 422. In the E / O converter 422, an optical signal OZB2 having a center wavelength of, for example, approximately 1.55 μm based on the composite serial data DZB2 is formed with a bit transmission rate of 2.97 Gbps.
[0138]
  Then, the optical signal OZA1 from the E / O converter 385 having a center wavelength of approximately 1.3 μm and a bit transmission rate of 2.97 Gbps, and the center wavelength from the E / O converter 420 is approximately 1.55 μm. And the optical signal OZA2 having a bit transmission rate of 2.97 Gbps is guided to the multiplexing unit 421. The multiplexing unit 421 is formed by, for example, a dielectric multilayer film type WDM coupler. In the multiplexing unit 421, an optical signal OZA1 having a center wavelength of approximately 1.3 μm and an optical signal OZA2 having a center wavelength of approximately 1.55 μm are multiplexed and multiplexed to multiplex the optical signal OZA. And send it as a transmission signal.
[0139]
  Further, the optical signal OZB1 from the E / O conversion unit 387 having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and the center wavelength from the E / O conversion unit 422 are about 1.55 μm. And the optical signal OZB2 having a bit transmission rate of 2.97 Gbps is guided to the multiplexing unit 423. The multiplexing unit 423 is formed by, for example, a dielectric multilayer film type WDM coupler. In the multiplexing unit 423, the optical signal OZB1 having a center wavelength of approximately 1.3 μm and the optical signal OZB2 having a center wavelength of approximately 1.55 μm are multiplexed and multiplexed to multiplex the multiplexed optical signal OZB. And send it as a transmission signal.
[0140]
  A multiplexed optical signal OZA that is a transmission signal transmitted from the multiplexing unit 421 is guided to the optical fiber transmission line 425 through the optical connector 424 and transmitted to the receiving side through the optical fiber transmission line 425. A multiplexed optical signal OZB that is a transmission signal transmitted from the multiplexing unit 423 is guided to the optical fiber transmission path 427 through the optical connector 426 and transmitted to the receiving side through the optical fiber transmission path 427. The optical fiber transmission lines 425 and 427 are formed using, for example, quartz-based SMF.
[0141]
  On the receiving side, the multiplexed optical signal OZA transmitted through the optical fiber transmission line 425 is guided to the demultiplexing unit 429 through the optical connector 428. Further, the multiplexed optical signal OZB transmitted through the optical fiber transmission line 427 is guided to the demultiplexing unit 432 through the optical connector 431.
[0142]
  The demultiplexing unit 429 is formed using, for example, a dielectric multilayer WDM coupler as demultiplexing means. In the demultiplexing unit 429, the multiplexed optical signal OZA is demultiplexed into a component having a center wavelength of approximately 1.3 μm and a component having a center wavelength of approximately 1.55 μm, so that the bit transmission rate is 2 An optical signal OZA1 with a center wavelength of approximately 1.3 μm and an optical signal OZA2 with a bit transmission rate of 2.97 Gbps and a center wavelength of approximately 1.55 μm are reproduced.
[0143]
  The optical signals OZA1 and OZA2 reproduced by the demultiplexing unit 429 are guided to the O / E conversion units 404 and 430, respectively. In the O / E converter 430, the optical signal OZA2 having a center wavelength of about 1.55 μm and a bit transmission rate of 2.97 Gbps is subjected to photoelectric conversion processing, and the bit transmission rate based on the optical signal OZA2 is set. The composite serial data DZA2 of 2.97 Gbps is reproduced. The reproduced composite serial data DZA2 is supplied to the bit separation unit 409.
[0144]
  The demultiplexing unit 432 is also formed using, for example, a dielectric multilayer WDM coupler as demultiplexing means. In the demultiplexing unit 432, the multiplexed optical signal OZB is demultiplexed into a component having a center wavelength of approximately 1.3 μm and a component having a center wavelength of approximately 1.55 μm, so that the bit transmission rate is 2 An optical signal OZB1 with a center wavelength of approximately 1.3 μm and an optical signal OZB2 with a bit transmission rate of 2.97 Gbps and a center wavelength of approximately 1.55 μm are reproduced.
[0145]
  The optical signals OZB1 and OZB2 reproduced by the demultiplexing unit 432 are guided to the O / E conversion units 406 and 433, respectively. In the O / E converter 433, the optical signal OZB2 having a center wavelength of approximately 1.55 μm and a bit transmission rate of 2.97 Gbps is subjected to photoelectric conversion processing, and the bit transmission rate based on the optical signal OZB2 is set. The composite serial data DZB2 with 2.97 Gbps is reproduced. The reproduced composite serial data DZB2 is supplied to the bit separation unit 411.
[0146]
  Other operations are the same as those of the data transmission / reception apparatus shown in FIG. 31 and FIG.
[0147]
  35 and 36 show the claims in the claims of the present application.1, claim 5, claim 7, claim 11, claim 13 and claim 17.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21The part of the data transmission / reception apparatus containing the 4th example of the data transmission apparatus which concerns on either of the invention described in the above is shown.
[0148]
  The data transmission / reception apparatus shown in FIG. 35 and FIG. 36 has many parts configured in the same manner as the data transmission / reception apparatus shown in FIG. 33 and FIG. Only the parts different from the data transmission / reception apparatus shown in FIG. 34 and the parts related thereto are shown.
[0149]
  The data transmission / reception apparatus shown in FIG. 35 and FIG. 36 includes E / O conversion units 385, 420, 387 and 422 and an O / E conversion unit 404 provided in the data transmission / reception apparatus shown in FIG. 33 and FIG. , 430, 406, and 433, E / O converters 385C, 420C, 387C, and 422C and O / E converters 404C, 430C, 406C, and 433C are provided. Further, the multiplexing units 421 and 423, the optical connectors 424 and 426, the optical fiber transmission lines 425 and 427, the optical connectors 428 and 431, and the demultiplexing unit 429 provided in the data transmission / reception apparatus shown in FIGS. And 432 are provided with a multiplexing unit 440, an optical connector 441, an optical fiber transmission path 442, an optical connector 443 and a demultiplexing unit 444. The optical fiber transmission line 442 is formed using, for example, quartz-based SMF.
[0150]
  In the data transmission / reception apparatus shown in FIG. 35 and FIG. 36, the bit transmission rate from the bit multiplexing unit 381 is 2.97 Gbps, and the bit transmission rate from the bit multiplexing unit 382 is 2.97 Gbps. Composite serial data DZA2 with 97 Gbps, composite serial data DZB1 with a bit transmission rate from the bit multiplexing unit 383 of 2.97 Gbps, and composite serial data DZB2 with a bit transmission rate from the bit multiplexing unit 384 of 2.97 Gbps , E / O converters 385C, 420C, 387C and 422C, respectively.
[0151]
  The E / O conversion unit 385C forms an optical signal OZCA1 based on the composite serial data DZA1 with a center wavelength of, for example, approximately 1.511 μm, with a bit transmission rate of 2.97 Gbps, and combines them. Guide to section 440. The E / O conversion unit 420C forms an optical signal OZCA2 based on the composite serial data DZA2 with a center wavelength of, for example, approximately 1.531 μm, with a bit transmission rate of 2.97 Gbps, and combines them. Guide to section 440. The E / O conversion unit 387C forms an optical signal OZCB1 having a center wavelength of, for example, approximately 1.551 μm based on the composite serial data DZB1, with a bit transmission rate of 2.97 Gbps, and multiplexes them Guide to section 440. Further, the E / O conversion unit 422C forms an optical signal OZCB2 having a center wavelength of, for example, approximately 1.571 μm based on the composite serial data DZB2, with a bit transmission rate of 2.97 Gbps, Guide to the multiplexing unit 440.
[0152]
  The multiplexing unit 440 has an optical signal OZCA1 having a center wavelength of approximately 1.511 μm, an optical signal OZCA2 having a center wavelength of approximately 1.531 μm, an optical signal OZCB1 having a center wavelength of approximately 1.551 μm, and a center wavelength of approximately 1. The optical signal OZCB2 to be .571 μm is multiplexed and multiplexed to form a multiplexed optical signal OZCY, which is transmitted as a transmission signal.
[0153]
  In this way, the optical signals OZCA1, OZCA2, OZCB1 and OZCB2 multiplexed in the multiplexing unit 440 have center wavelengths that are sequentially close to each other at a wavelength interval of approximately 0.020 μm. Multiplexing is performed with wavelengths that are very close to each other, the center wavelengths of which are separated by approximately 0.020 μm (20 nm), thereby forming a multiplexed optical signal OZCY. A wavelength multiplexing technique called “Coase Wavelength Division Multiplexing (CWDM)” is used in a portion including the E / O conversion units 385C, 420C, 387, and 422C and the multiplexing unit 440.
[0154]
  A multiplexed optical signal OZCY that is a transmission signal transmitted from the multiplexing unit 440 is guided to the optical fiber transmission path 442 through the optical connector 441 and transmitted to the receiving side through the optical fiber transmission path 442.
[0155]
  On the receiving side, the multiplexed optical signal OZCY transmitted through the optical fiber transmission path 442 is guided to the demultiplexing unit 444 through the optical connector 443. The demultiplexing unit 444 converts the multiplexed optical signal OZCY into a component having a center wavelength of approximately 1.511 μm, a component having a center wavelength of approximately 1.531 μm, a component having a center wavelength of approximately 1.551 μm, and a center wavelength of approximately 1. The optical signal OZCA1 having a bit transmission rate of 2.97 Gbps and a center wavelength of approximately 1.511 μm, a bit transmission rate of 2.97 Gbps, and a center wavelength of approximately 1.97 Gbps. An optical signal OZCA2 with 531 μm, an optical signal OZCB1 with a bit transmission rate of 2.97 Gbps and a central wavelength of approximately 1.551 μm, and an optical signal with a bit transmission rate of 2.97 Gbps and a central wavelength of approximately 1.571 μm The signal OZCB2 is reproduced.
[0156]
  The optical signals OZCA1, OZCA2, OZCB1, and OZCB2 reproduced by the demultiplexing unit 444 are guided to the O / E conversion units 404C, 430C, 406C, and 433C, respectively. The O / E converter 404C performs photoelectric conversion processing on the optical signal OZCA1 having a center wavelength of approximately 1.511 μm and a bit transmission rate of 2.97 Gbps, and sets the bit transmission rate based on the optical signal OZCA1 to 2.97 Gbps. The composite serial data DZA1 is reproduced. The O / E conversion unit 430C performs photoelectric conversion processing on the optical signal OZCA2 having a center wavelength of approximately 1.531 μm and a bit transmission rate of 2.97 Gbps, and sets the bit transmission rate based on the optical signal OZCA2 to 2.97 Gbps. The composite serial data DZA2 is reproduced. The O / E conversion unit 406C performs photoelectric conversion processing on the optical signal OZCB1 having a center wavelength of approximately 1.551 μm and a bit transmission rate of 2.97 Gbps, and sets the bit transmission rate based on the optical signal OZCB1 to 2.97 Gbps. The composite serial data DZB1 is reproduced. Further, the O / E conversion unit 433C performs photoelectric conversion processing on the optical signal OZCB2 having a center wavelength of approximately 1.571 μm and a bit transmission rate of 2.97 Gbps, so that the bit transmission rate based on the optical signal OZCB2 is 2 Reproduces composite serial data DZB2 of .97 Gbps.
[0157]
  The composite serial data DZA1, DZA2, DZB1, and DZB2 reproduced by the O / E conversion units 404C, 430C, 406C, and 433C are supplied to the bit separation units 408, 409, 410, and 411, respectively. Other operations are the same as those of the data transmission / reception apparatus shown in FIGS.
[0158]
  37 and 38 are claims in the claims of the present application.1 to 3, 7 to 9, and 13 to 15.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19-claim 21The part of the data transmission / reception apparatus containing the 5th example of the data transmission apparatus based on invention described in any of these is shown.
[0159]
  The data transmitting / receiving apparatus whose parts are shown in FIG. 37 and FIG. 38 have many parts configured in the same manner as the data transmitting / receiving apparatus shown in FIG. 5 and FIG. Only the parts different from the data transmission / reception apparatus shown in FIG. 6 and the parts related thereto are shown.
[0160]
  In the data transmission / reception apparatus whose parts are shown in FIGS. 37 and 38, the E / O conversion units 294 and 310 to 316 provided in the data transmission / reception apparatus shown in FIGS. Instead of the units 337 and 350 to 356, E / O converters 294C and 310C to 316C, and O / E converters 337C and 350C to 356C are provided. Further, in place of the optical connectors 320 and 322 to 328, the optical fiber transmission paths 321 and 329 to 335, and the optical connectors 336 and 339 to 345 provided in the data transmission / reception apparatus shown in FIGS. 445, an optical connector 446, an optical fiber transmission line 447, an optical connector 448, and a demultiplexing unit 449. The optical fiber transmission line 447 is formed using, for example, quartz-based SMF.
[0161]
  In the data transmission / reception apparatus shown in FIG. 37 and FIG. 38, the bit transmission rate from the serial data DSA1 and P / S conversion unit 302 is 1.485 Gbps as the bit transmission rate from the P / S conversion unit 293. The serial data DSA2, the bit transmission rate from the P / S conversion unit 303 is 1.485 Gbps The serial data the bit transmission rate from the serial data DSA3, the P / S conversion unit 304 is 1.485 Gbps Serial data DSB2, serial data DSB2, P / S converter 307 which sets the bit transmission rate from DSA4, P / S converter 305 to 1.485 Gbps The bit transmission rate from 1.485 Gbps That serial data DSB3, and serial data DSB4 to 1.485Gbps bit transmission rate of the P / S conversion unit 308 are respectively supplied to the E / O conversion unit 294C and 310C～316C.
[0162]
  The E / O conversion unit 294C forms an optical signal OSCA1 based on the serial data DSA1 with a center wavelength of, for example, approximately 1.471 μm, with a bit transmission rate of 1.485 Gbps, and combines it. Lead to 445. The E / O conversion unit 310C forms an optical signal OSCA2 based on the serial data DSA2 with a center wavelength of, for example, approximately 1.491 μm, with a bit transmission rate of 1.485 Gbps, and combines it. Lead to 445. The E / O converter 311C forms an optical signal OSCA3 based on the serial data DSA3 with a center wavelength of, for example, approximately 1.511 μm, with a bit transmission rate of 1.485 Gbps, and combines it with the multiplexer Lead to 445. The E / O conversion unit 312C forms an optical signal OSCA4 based on the serial data DSA4 with a center wavelength of, for example, approximately 1.531 μm, with a bit transmission rate of 1.485 Gbps, and combines it. Lead to 445. The E / O conversion unit 313C forms an optical signal OSCB1 based on the serial data DSB1 with a center wavelength of, for example, approximately 1.551 μm, with a bit transmission rate of 1.485 Gbps, and combines it. Lead to 445. The E / O conversion unit 314C forms an optical signal OSCB2 based on the serial data DSB2 with a center wavelength of, for example, approximately 1.571 μm, with a bit transmission rate of 1.485 Gbps, and combines it. Lead to 445. The E / O conversion unit 315C forms an optical signal OSCB3 based on the serial data DSB3 with a center wavelength of, for example, approximately 1.591 μm, with a bit transmission rate of 1.485 Gbps, and combines it. Lead to 445. Further, the E / O converter 316C forms an optical signal OSCB4 based on the serial data DSB4 with a center wavelength of, for example, approximately 1.611 μm, with a bit transmission rate of 1.485 Gbps, and combines them. Guide to the wave section 445.
[0163]
  The multiplexing unit 445 includes an optical signal OSCA1 having a center wavelength of about 1.471 μm, an optical signal OSCA2 having a center wavelength of about 1.491 μm, an optical signal OSCA3 having a center wavelength of about 1.511 μm, and a center wavelength of about 1. An optical signal OSCB4 having a center wavelength of approximately 1.551 μm, an optical signal OSCB having a center wavelength of approximately 1.571 μm, an optical signal OSCB3 having a center wavelength of approximately 1.591 μm, and a center An optical signal OSCB4 having a wavelength of approximately 1.611 μm is multiplexed and multiplexed to form a multiplexed optical signal OZCZ, which is transmitted as a transmission signal.
[0164]
  In this way, the optical signals OSCA1, OSCA2, OSCA3, OSCA4, OSCB1, OSCB2, OSCB3, and OSCB4 multiplexed in the multiplexing unit 445 have central wavelengths that are sequentially close to each other with a wavelength interval of approximately 0.020 μm. Therefore, they are multiplexed with wavelengths that are very close to each other, with their center wavelengths only separated by approximately 0.020 μm (20 nm) to form a multiplexed optical signal OZCZ. Has been. A wavelength multiplexing technique called “Coase Wavelength Division Multiplexing (CWDM)” is used in a portion including the E / O conversion units 294C and 310C to 316C and the multiplexing unit 445.
[0165]
  The multiplexed optical signal OZCZ that is a transmission signal transmitted from the multiplexing unit 445 is guided to the optical fiber transmission path 447 through the optical connector 446 and transmitted to the receiving side through the optical fiber transmission path 447.
[0166]
  On the receiving side, the multiplexed optical signal OZCZ transmitted through the optical fiber transmission line 447 is guided to the demultiplexing unit 449 through the optical connector 448. The demultiplexing unit 449 converts the multiplexed optical signal OZCZ from a component having a center wavelength of approximately 1.471 μm, a component having a center wavelength of approximately 1.491 μm, a component having a center wavelength of approximately 1.511 μm, and a center wavelength of approximately 1. .531 μm, center wavelength about 1.551 μm, center wavelength about 1.571 μm, center wavelength about 1.591 μm and center wavelength about 1.611 μm Optical signal OSCA1 with a bit transmission rate of 1.485 Gbps and a center wavelength of approximately 1.471 μm, a bit transmission rate of 1.485 Gbps and a center wavelength of approximately 1.491 μm Optical signal OSCA3 with a transmission rate of 1.485 Gbps and a center wavelength of approximately 1.511 μm, a bit transmission rate of 1.485 Gbps, An optical signal OSCA4 with a core wavelength of about 1.531 μm, a bit transmission rate of 1.485 Gbps, an optical signal OSCB1 with a center wavelength of about 1.551 μm, a bit transmission rate of 1.485 Gbps, and a center wavelength of about 1. An optical signal OSCB2 having a bit wavelength of 1.485 Gbps, an optical signal OSCB3 having a central wavelength of approximately 1.591 μm, an optical signal OSCB4 having a bit transmission rate of 1.485 Gbps, and a central wavelength of approximately 1.611 μm. And play.
[0167]
  The optical signals OSCA1, OSCA2, OSCA3, OSCA4, OSCB1, OSCB2, OSCB3, and OSCB4 reproduced by the demultiplexing unit 449 are guided to the O / E conversion units 337C and 350C to 356C, respectively.
[0168]
  The O / E conversion unit 337C performs photoelectric conversion processing on the optical signal OSCA1 having a center wavelength of about 1.471 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCA1 to 1.485 Gbps. The serial data DSA1 is reproduced. The O / E converter 350C performs a photoelectric conversion process on the optical signal OSCA2 having a center wavelength of about 1.491 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCA2 to 1.485 Gbps. The serial data DSA2 is reproduced. The O / E conversion unit 351C performs photoelectric conversion processing on the optical signal OSCA3 having a center wavelength of approximately 1.511 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCA3 to 1.485 Gbps. The serial data DSA3 is reproduced. The O / E conversion unit 352C performs photoelectric conversion processing on the optical signal OSCA4 having a center wavelength of about 1.531 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCA4 to 1.485 Gbps. The serial data DSA4 is reproduced.
[0169]
  The O / E converter 353C performs photoelectric conversion processing on the optical signal OSCB1 having a center wavelength of approximately 1.551 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCB1 to 1 Reproduce the serial data DSB1 with .485 Gbps. The O / E conversion unit 354C performs photoelectric conversion processing on the optical signal OSCB2 having a center wavelength of approximately 1.571 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCB2 to 1.485 Gbps. The serial data DSB2 is reproduced. The O / E conversion unit 355C performs photoelectric conversion processing on the optical signal OSCB3 having a center wavelength of about 1.591 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCB3 to 1.485 Gbps. The serial data DSB3 is reproduced. The O / E conversion unit 356C performs photoelectric conversion processing on the optical signal OSCB4 having a center wavelength of approximately 1.611 μm and a bit transmission rate of 1.485 Gbps, and sets the bit transmission rate based on the optical signal OSCB4 to 1.485 Gbps. The serial data DSB4 is reproduced.
[0170]
  Serial data DSA1, DSA2, DSA3, DSA4, DSB1, DSB2, DSB3, and DSB4 reproduced by the O / E converters 337C and 350C to 356C are supplied to S / P converters 360 and 362-368, respectively. Other operations are the same as those of the data transmission / reception apparatus shown in FIGS.
[0173]
【The invention's effect】
  As is clear from the above explanationClaims in the claims of this application1 to 18A data transmission method according to the invention described in any of the above or claims19 to 21In the data transmission apparatus according to any of the above-described inventions, the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits, and the number of effective lines per frame is 1600 or more and 2250 or less. And the digital data constituting the digital video signal in which the number of valid data samples per line is set to a value of 3400 or more and 4400 or less, each of which has a conventional quantization bit number of 8 bits or 10 bits Is divided into a plurality of word string data that is compatible with the digital data constituting the HD digital video signal, and each of the plurality of word string data is converted into serial data and transmitted. Will do.
[0174]
  Accordingly, the claims in the claims of this application1 to 18A data transmission method according to the invention described in any of the above or claims19 to 21According to the data transmission device according to any of the inventions described above, the number of quantization bits is 10 bits, 12 bits, 14 bits, or 16 bits, and the number of effective lines per frame is 1600 or more and 2250 or less. The serial transmission of digital data forming a digital video signal such as a 2k × 4k signal that is set to a numerical value and the number of valid data samples per line is set to a numerical value of 3400 or more and 4400 or less, for example, according to HD SDI It is possible to carry out appropriately using existing circuit components used for serial transmission.
[Brief description of the drawings]
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 to claim 7 in claims of the present application;12Data related to the invention described in any of the abovetransmissionWayExamples are implemented in the example of a data transmission device according to the invention as claimed in claim 20 in the claims of this applicationDigital data making up digital video signalOfIt is a conceptual diagram which shows a data format.
[Fig. 2] Claims 1 to claims in the claims of the present application.A data transmission apparatus according to any one of claims 19 to 21 in the claims of the present application, in which an example of the data transmission method according to the invention described in any one of claims 18 to 18 is implemented. Treated in the exampleIt is a table | surface provided for description of the prohibition code in the digital data which comprises a digital video signal.
FIG. 3: Claims 1 to in claims of the present application6UntilOr claims 13-18.Data related to the invention described in any of the abovetransmissionWayAn example is implemented, which is dealt with in the example of the data transmission device according to claim 19 or claim 21 in the scope of claims of the present applicationDigital data making up digital video signalOfIt is a conceptual diagram which shows a data format.
FIG. 4: Claims 1 to in claims of the present application18Data related to the invention described in any of the abovetransmissionMethodIn the example of the data transmission device according to the invention described in any one of claims 19 to 21 in the claims of the present application,It is a table | surface figure with which it uses for description of the digital data which comprises a digital video signal.
FIG. 5: Claims in the claims of the present application1, claim 2, claim 7, claim 8, claim 13 and claim 14Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection diagram showing a portion of a data transmission / reception device including a first example of a data transmission device according to the invention described in any of the above.
FIG. 6: Claims in the claims of this application1, claim 2, claim 7, claim 8, claim 13 and claim 14Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection diagram showing a portion of a data transmission / reception device including a first example of a data transmission device according to the invention described in any of the above.
7 is a conceptual diagram showing data used for explanation of the operation of a data processing unit in the data transmission / reception apparatus shown in FIG. 5 and FIG. 6;
FIG. 8 is a conceptual diagram showing data used to explain the operation of a data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 9 is a conceptual diagram showing data used to explain the operation of a data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
10 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6. FIG.
11 is a conceptual diagram showing data used to explain the operation of a data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6. FIG.
12 is a conceptual diagram showing data used for explaining the operation of a data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6. FIG.
FIG. 13 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
14 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIG. 5 and FIG. 6;
FIG. 15 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 16 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 17 is a conceptual diagram showing data used to explain the operation of a data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 18 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 19 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
20 is a conceptual diagram showing data used for explanation of the operation of the data processing unit in the data transmission / reception apparatus shown in FIG. 5 and FIG. 6;
FIG. 21 is a conceptual diagram showing data used for explanation of the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 22 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 23 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
24 is a conceptual diagram showing data used for explaining the operation of a data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6. FIG.
FIG. 25 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 26 is a conceptual diagram showing data for explaining the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 27 is a conceptual diagram showing data used to explain the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 28 is a conceptual diagram showing data used for explaining the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
FIG. 29 is a conceptual diagram showing data for explaining the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6;
30 is a conceptual diagram showing data used for explaining the operation of the data processing unit in the data transmission / reception apparatus shown in FIGS. 5 and 6. FIG.
FIG. 31: Claims in the claims of this application1, claim 4, claim 7, claim 10, claim 13 and claim 16Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection figure which shows the part of the data transmission / reception apparatus containing the 2nd example of the data transmission apparatus which concerns on either of the invention described in the above.
FIG. 32: Claims in the claims of this application1, claim 4, claim 7, claim 10, claim 13 and claim 16Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection figure which shows the part of the data transmission / reception apparatus containing the 2nd example of the data transmission apparatus which concerns on either of the invention described in the above.
FIG. 33: Claims in the claims of this application1, claim 4, claim 6, claim 7, claim 10, claim 12, claim 13, claim 16, and claim 18.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection figure which shows the part of the data transmission / reception apparatus containing the 3rd example of the data transmission apparatus which concerns on either of the invention described in the above.
FIG. 34. Claims in the claims of this application1, claim 4, claim 6, claim 7, claim 10, claim 12, claim 13, claim 16, and claim 18.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection figure which shows the part of the data transmission / reception apparatus containing the 3rd example of the data transmission apparatus which concerns on either of the invention described in the above.
FIG. 35: Claims in the claims of this application1, claim 5, claim 7, claim 11, claim 13 and claim 17.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection diagram which shows the part of the data transmission / reception apparatus containing the 4th example of the data transmission apparatus based on either of the invention described in the above.
FIG. 36. Claims in the claims of this application1, claim 5, claim 7, claim 11, claim 13 and claim 17.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection diagram which shows the part of the data transmission / reception apparatus containing the 4th example of the data transmission apparatus based on either of the invention described in the above.
FIG. 37. Claims in the claims of this application1 to 3, 7 to 9, and 13 to 15.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection figure which shows the part of the data transmission / reception apparatus containing the 5th example of the data transmission apparatus based on either of the invention described in the above.
FIG. 38: Claims in the claims of this application1 to 3, 7 to 9, and 13 to 15.Claims in the claims of this application in which an example of a data transmission method according to any of the inventions described in any of the above is implemented19 to 21It is a block connection figure which shows the part of the data transmission / reception apparatus containing the 5th example of the data transmission apparatus based on either of the invention described in the above.
FIG. 39 is a conceptual diagram for explaining an example of a data format of an HD digital video signal.
FIG. 40 is a conceptual diagram for explaining an example of a data format of an HD digital video signal.
[Explanation of symbols]
  291: Data processing unit, 292, 295-301 ... Data insertion unit, 293, 302-308 ... P / S conversion unit, 294, 310-316, 385-388, 420, 422, 124C, 127C, 130C, 133C, 294C, 310C to 316C, 385C, 387C, 420C, 422C ... E / O converter, 320, 322 to 328, 336, 339 to 345, 389 to 392, 400 to 403, 424 426, 428, 431, 441, 443, 446, 448 ... optical connector, 321, 329-335, 395-398, 425, 427, 442, 447 ... optical fiber transmission line, 337, 350-356, 404 ~ 407, 430, 433, 337C, 350C ~ 356C, 404C, 406C, 4 0C, 433C,... O / E conversion unit, 360, 362-368 ... S / P conversion unit, 361 ... data time difference absorption unit, 370, 372-378 ... data separation unit, 371 ··· Data reproduction processing unit, 381 to 384 ··· bit multiplexing unit, 408 to 411 ··· bit separation unit, 421, 423, 440, 445 ··· multiplexing unit, 429, 432, 444, 449 ···・ Demultiplexer

Claims (21)

Frame rate 24 Hz, and 25Hz or 30 Hz, with the number of effective lines which definitive each frame is set to 2250 or less of the number in 1600 or more, 4400 to the following numbers in the number of effective data samples definitive each line is 3400 or more is set, the number of quantization bits is 10 bits, forbidden codes which are not used to represent the video signal information for each active line portion, 00h or FFh (subscript h the upper 8 bits in hexadecimal representation all forms a digital video signal with 10-bit code, each is a 10-bit word sequence data are green primary color signal data series and the blue primary color signal data series and the red primary color signal to the indicating) that hexadecimal To 30-bit parallel data formed with parallel arrangement with data series,
By sequentially assigning the effective data samples in each line portion one by one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, and the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less. Forming first and second divided digital data forming a digital video signal in which the number of valid data samples at 1700 is set to a numerical value of 1700 or more and 2200 or less;
For each of the first and second divided digital data, a first alternate line portion and a second alternate line portion are stored in first and second memories, respectively. A green primary color signal data series and a blue primary color signal that form a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz for each of the line portion stored in the memory and the line portion stored in the second memory. By reading out the data sequence and the 30-bit parallel data including the red primary color signal data sequence to obtain 30-bit word string data with a word transmission rate of 74.25 MBps, Obtain 1st to 4th 30-bit word string data of 74.25 MBps,
For each of the first to fourth 30-bit word string data, a 10-bit word forming a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series is converted into the green primary color signal data series. A first word group including a 10-bit word forming a blue primary color signal data series and a part of the 10-bit word forming each of the blue primary color signal data series and a 10-bit word forming an auxiliary data series; Distribution to a second word group including the other part of the 10-bit word forming each of the blue primary color signal data series and the red primary color signal data series, and based on each of the first and second word groups By performing processing to obtain 20-bit word string data with a word transmission rate of 74.25 MBps, each Performing data processing for forming a 20-bit word sequence data of the de transmission rate from the first to 74.25MBps to the eighth,
A data transmission method for obtaining first to eighth serial data based on the first to eighth 20-bit word string data and transmitting the first to eighth serial data for transmission . 2. The data transmission method according to claim 1 , wherein the first to eighth serial data are converted into first to eighth optical signals and transmitted . The first to eighth serial data are converted into first to eighth optical signals having central wavelengths that are sequentially close to each other at a predetermined wavelength interval, and the first to eighth optical signals are converted. 2. The data transmission method according to claim 1 , wherein the data are transmitted after being combined . Bit multiplexing is performed on each of the first to fourth sets of two of the first to eighth serial data to obtain first to fourth composite serial data, and the second data transmission method according to claim 1, wherein the transmitting composite serial data from 1 to 4. The first to fourth composite serial data is converted into first to fourth optical signals having central wavelengths that are sequentially close to each other at a predetermined wavelength interval, and the first to fourth optical signals are converted. 5. The data transmission method according to claim 4, wherein the signals are multiplexed and transmitted. Two of the first to fourth composite serial data are converted into first and second optical signals having different center wavelengths, and the first and second optical signals are combined. And the remaining two of the first to fourth composite serial data are converted into third and fourth optical signals having different center wavelengths, respectively, and the third and fourth optical signals are converted. 5. The data transmission method according to claim 4, wherein the optical signals are multiplexed and transmitted. The frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 3400 or more and 4400 or less. When the number of quantization bits is 12 bits, 14 bits, or 16 bits and the number of quantization bits is 12 bits, the prohibition code that is not used to represent the video signal information for each effective line portion is the upper 8 bits. When all the 12-bit codes are 00h or FFh in hexadecimal notation (subscript h indicates that they are hexadecimal numbers) and the number of quantization bits is 14 bits, the video signal information for each effective line portion is The prohibition code that is not used to represent the upper 8 bits is a hexadecimal table. When all the 14-bit codes are 00h or FFh and the number of quantization bits is 16 bits, the prohibition code that is not used to represent the video signal information for each effective line portion is the upper 8 bits. A luminance video data sequence and a chrominance signal data sequence, each of which is a 16-bit code that is 00h or FFh in hexadecimal representation, each of which is 12-bit, 14-bit, or 16-bit word string data, 24 bit, 28 bit or 32 bit parallel data formed with the parallel arrangement of
By sequentially assigning effective data samples in each line portion by one sample or two samples, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, and the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less. Forming the first and second divided digital data forming a digital video signal in which the number of valid data samples in each line is set to a numerical value of 1700 or more and 2200 or less,
For each of the first and second divided digital data, a first alternate line portion and a second alternate line portion are stored in first and second memories, respectively. Each of the line portion stored in the memory and the line portion stored in the second memory has a 24-bit, 28-bit, or 32-bit parallel forming a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz. By reading the data as forming data and obtaining a 24-bit, 28-bit, or 32-bit word string data with a word transmission rate of 74.25 MBps, each of the word transmission rates is set to 74.25 MBps. Get 24 bit, 28 bit or 32 bit word string data up to 4th,
For each of the 24-bit, 28-bit, or 32-bit word string data from the first to the fourth, each 12-bit, 14-bit, or 16-bit word that forms the luminance signal data series and the chrominance signal data series, A 20-bit word string with a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of divided lower 2 By performing processing for obtaining 20-bit word string data having a word transmission rate of 74.25 MBps based on 4 bits, 4 bits or 6 bits, and auxiliary bits, each of which has a word transmission rate of 74.25 MBps. To data processing for forming 20-bit word string data from No. 8 to No. 8,
A data transmission method for obtaining first to eighth serial data based on the first to eighth 20-bit word string data and transmitting the first to eighth serial data for transmission . 8. The data transmission method according to claim 7 , wherein the first to eighth serial data are respectively converted into first to eighth optical signals and transmitted. The serial data from the first to eighth respectively converted into optical signals from the first having a center wavelength sequentially close at predetermined wavelength intervals until eighth optical signal from the first to the eighth 8. The data transmission method according to claim 7 , wherein the signals are multiplexed and transmitted. By two of the serial data from the first to the eighth obtain a composite serial data from the first subjected to a set of respective bit multiplexing process from the first constituting up to 4 to 4, wherein 8. The data transmission method according to claim 7, wherein the first to fourth composite serial data is transmitted. The first to fourth composite serial data are converted into first to fourth optical signals having center wavelengths that are sequentially close to each other at a predetermined wavelength interval, and the first to fourth optical signals are converted. The data transmission method according to claim 10, wherein the signals are multiplexed and transmitted. Two of the first to fourth composite serial data are converted into first and second optical signals having different center wavelengths, and the first and second optical signals are combined. And the remaining two of the first to fourth composite serial data are converted into third and fourth optical signals having different center wavelengths, respectively, and the third and fourth optical signals are converted. 11. The data transmission method according to claim 10, wherein optical signals are multiplexed and transmitted. The frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 3400 or more and 4400 or less. The prohibition code that is not used to represent the video signal information for each effective line part is 00h or FFh in hexadecimal notation and the FFh (subscript h is a hexadecimal number). A parallel arrangement of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series, each of which is a 12-bit word string data. In the 36-bit parallel data formed with
By sequentially assigning the effective data samples in each line portion one by one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, and the number of effective lines in each frame is set to a numerical value of 1600 or more and 2250 or less. Forming first and second divided digital data forming a digital video signal in which the number of valid data samples at 1700 is set to a numerical value of 1700 or more and 2200 or less;
For each of the first and second divided digital data, a first alternate line portion and a second alternate line portion are stored in first and second memories, respectively. A green primary color signal data series and a blue primary color signal that form a segmented frame digital video signal with a frame rate of 24 Hz, 25 Hz, or 30 Hz for each of the line portion stored in the memory and the line portion stored in the second memory. By reading out the data sequence and the 36-bit parallel data including the red primary color signal data sequence to obtain 36-bit word string data having a word transmission rate of 74.25 MBps, Obtain first to fourth 36-bit word string data of 74.25 MBps,
For each of the first to fourth 36-bit word string data, each of the 12-bit words forming the green primary color signal data series, the blue primary color signal data series, and the red primary color signal data series is divided into upper 10 bits and lower order Divided into two bits, a plurality of upper 10 bits divided from the green primary color signal data series, and a part of a plurality of upper 10 bits divided from the blue primary color signal data series and the red primary color signal data series, respectively. , A 20-bit word string having a word transmission rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from the blue primary color signal data series and the red primary color signal data series, and the green color A plurality of lower two bits divided from the primary color signal data series, blue primary color signal data series, and red primary color signal data series and auxiliary The first to eighth 20-bit words each having a word transmission rate of 74.25 MBps are obtained by performing processing for obtaining 20-bit word string data having a word transmission rate of 74.25 MBps based on Perform data processing to form column data,
A data transmission method for obtaining first to eighth serial data based on the first to eighth 20-bit word string data and transmitting the first to eighth serial data for transmission . 14. The data transmission method according to claim 13 , wherein the first to eighth serial data are converted into first to eighth optical signals and transmitted. The serial data from the first to eighth respectively converted into optical signals from the first having a center wavelength sequentially close at predetermined wavelength intervals until eighth optical signal from the first to the eighth 14. The data transmission method according to claim 13 , wherein the data are multiplexed and transmitted. By two of the serial data from the first to the eighth obtain a composite serial data from the first subjected to a set of respective bit multiplexing process from the first constituting up to 4 to 4, wherein 14. The data transmission method according to claim 13, wherein the first to fourth composite serial data is transmitted. The first to fourth composite serial data is converted into first to fourth optical signals having central wavelengths that are sequentially close to each other at a predetermined wavelength interval, and the first to fourth optical signals are converted. The data transmission method according to claim 16, wherein the signals are multiplexed and transmitted. Two of the first to fourth composite serial data are converted into first and second optical signals having different center wavelengths, and the first and second optical signals are combined. And the remaining two of the first to fourth composite serial data are converted into third and fourth optical signals having different center wavelengths, respectively, and the third and fourth optical signals are converted. 17. The data transmission method according to claim 16, wherein the optical signals are multiplexed and transmitted. The frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 3400 or more and 4400 or less. The prohibited code that is not used to represent video signal information for each effective line part is 10h in the hexadecimal representation of 00h or FFh (subscript h is a hexadecimal number). A parallel arrangement of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series, all of which are 10-bit code digital video signals, each of which is 10-bit word string data. 30-bit parallel data formed with By sequentially assigning valid data samples one by one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of valid lines in each frame is set to a value between 1600 and 2250, and valid data samples in each line First and second divided digital data forming a digital video signal whose number is set to a value of 1700 or more and 2200 or less is formed, and each of the first and second divided digital data is a first one. The alternate line portion and the second alternate line portion are stored in the first and second memories, respectively, and the line portion stored in the first memory and the line stored in the second memory are respectively stored. Segmented frames with a frame rate of 24, 25, or 30 Hz for each part 30-bit word string data that is read out to form 30-bit parallel data including a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series forming a digital video signal, and a word transmission rate is 74.25 MBps. To obtain first to fourth 30-bit word string data each having a word transmission rate of 74.25 MBps, and for each of the first to fourth 30-bit word string data 10-bit words forming the green primary color signal data series, the blue primary color signal data series, and the red primary color signal data series, the 10-bit words forming the green primary color signal data series, the blue primary color signal data series, and the red primary color A first part including a part of a 10-bit word forming each of the signal data series And a second word group including a 10-bit word forming the auxiliary data series and another part of the 10-bit word forming each of the blue primary color signal data series and the red primary color signal data series. First, each of the first and second word groups has a word transmission rate of 74.25 MBps by performing processing for obtaining 20-bit word string data having a word transmission rate of 74.25 MBps based on each of the first and second word groups. To a data processing unit for performing data processing for forming 20-bit word string data from 8 to 8,
And a parallel / serial converter from the first to obtain the serial data from the first based respectively to the eighth to the 20-bit word sequence data from the first to the eighth to the eighth, from the first to the eighth First to eighth data sending units for sending first to eighth serial data respectively obtained from the parallel / serial conversion unit;
A data transmission device configured to include: The frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 3400 or more and 4400 or less. When the number of quantization bits is 12 bits, 14 bits, or 16 bits and the number of quantization bits is 12 bits, the prohibition code that is not used to represent the video signal information for each effective line portion is the upper 8 bits. When all the 12-bit codes are 00h or FFh in hexadecimal notation (subscript h indicates that they are hexadecimal numbers) and the number of quantization bits is 14 bits, the video signal information for each effective line portion is The prohibition code that is not used to represent the upper 8 bits is a hexadecimal table. When all the 14-bit codes are 00h or FFh and the number of quantization bits is 16 bits, the prohibition code that is not used to represent the video signal information for each effective line portion is the upper 8 bits. A luminance video data sequence and a chrominance signal data sequence, each of which is a 16-bit code that is 00h or FFh in hexadecimal representation, each of which is 12-bit, 14-bit, or 16-bit word string data, By sequentially allocating effective data samples in each line portion by one sample or two samples to 24-bit, 28-bit, or 32-bit parallel data formed with the parallel arrangement of each, the frame rate is set to 24 Hz, 25 Hz, or 30 Hz, Effective line in each frame Is set to a numerical value of 1600 or more and 2250 or less, and the first and second divided digital data forming a digital video signal in which the number of valid data samples in each line is set to a numerical value of 1700 or more and 2200 or less is formed. Then, for each of the first and second divided digital data, the first alternate line portion and the second alternate line portion are stored in the first and second memories, respectively. Each of the line portion stored in the memory 1 and the line portion stored in the second memory is a 24-bit, 28-bit, or 32-bit forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read as forming bit-parallel data, and the word transmission rate is 74.25 MBps 24 By performing processing to obtain bit, 28-bit or 32-bit word string data, first to fourth 24-bit, 28-bit or 32-bit word string data each having a word transmission rate of 74.25 MBps is obtained, For each of the 24-bit, 28-bit, or 32-bit word string data from the first to the fourth, each 12-bit, 14-bit, or 16-bit word that forms the luminance signal data series and the chrominance signal data series, A 20-bit word string with a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of divided lower 2 Word transmission rate based on bits, 4 bits or 6 bits and auxiliary bits Data for performing data processing for forming first to eighth 20-bit word string data each having a word transmission rate of 74.25 MBps by performing processing to obtain 20-bit word string data of 74.25 MBps. A processing unit;
First to eighth parallel / serial converters for obtaining first to eighth serial data based on the first to eighth 20-bit word string data, respectively, and the first to eighth parallel data / First to eighth data sending units for sending first to eighth serial data respectively obtained from the serial conversion unit;
A data transmission device configured to include: The frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of effective lines in each frame is set to a value of 1600 or more and 2250 or less, and the number of effective data samples in each line is set to a value of 3400 or more and 4400 or less. The prohibition code that is not used to represent the video signal information for each effective line part is 00h or FFh in hexadecimal notation and the FFh (subscript h is a hexadecimal number). A parallel arrangement of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series, each of which is a 12-bit word string data. The 36-bit parallel data formed with By sequentially assigning valid data samples one by one, each frame rate is set to 24 Hz, 25 Hz, or 30 Hz, the number of valid lines in each frame is set to a value between 1600 and 2250, and valid data samples in each line First and second divided digital data forming a digital video signal whose number is set to a value of 1700 or more and 2200 or less is formed, and each of the first and second divided digital data is a first one. The alternate line portion and the second alternate line portion are stored in the first and second memories, respectively, and the line portion stored in the first memory and the line stored in the second memory are respectively stored. Segmented frames with a frame rate of 24, 25, or 30 Hz for each part 36-bit word string data that is read out to form 36-bit parallel data including a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series forming a digital video signal, and a word transmission rate is set to 74.25 MBps. To obtain first to fourth 36-bit word string data each having a word transmission rate of 74.25 MBps, and for each of the first to fourth 36-bit word string data Each of the 12-bit words forming the green primary color signal data series, the blue primary color signal data series, and the red primary color signal data series is divided into upper 10 bits and lower 2 bits, and is divided from the green primary color signal data series. A plurality of upper 10 bits, the blue primary color signal data series and the red primary color signal data A 20-bit word string with a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the series, and a blue primary color signal data series and a red primary color signal data series. Word transmission based on the other part of the plurality of upper 10 bits and a plurality of lower 2 bits and auxiliary bits divided from the green primary color signal data series, blue primary color signal data series, and red primary color signal data series By performing processing for obtaining 20-bit word string data having a rate of 74.25 MBps, data processing for forming first to eighth 20-bit word string data each having a word transmission rate of 74.25 MBps is performed. A data processing unit to be applied;
First to eighth parallel / serial converters for obtaining first to eighth serial data based on the first to eighth 20-bit word string data, respectively, and the first to eighth parallel data / First to eighth data sending units for sending first to eighth serial data respectively obtained from the serial conversion unit;
A data transmission device configured to include: