JPWO2002067592A1 - Data transmission method and apparatus - Google Patents

Abstract

A digital video signal having a frame rate of 50, 60 or 120 Hz, a 20-bit parallel signal including a luminance signal data sequence and a color difference signal data sequence each having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps. In the data, the first and second alternate frame portions are stored in the first and second memories, respectively, and each of the stored frame portions is read out as forming 20-bit parallel data, and each is read out. A process for obtaining first and second 20-bit word string data having a word transmission rate of 74.25 MBps is performed, and first and second serial data based on the first and second 20-bit word string data are transmitted. I do.

Description

Technical field
In the present invention, the frame rate is set to 50 Hz, 60 Hz or 60 / 1.001 Hz (all of them are referred to as 60 Hz in the present application), 72 Hz or 72 / 1.001 Hz (all of these are referred to as 72 Hz in the present application). , 75 Hz, 90 Hz or 90 / 1.001 Hz (all of them are referred to as 90 Hz in the present application), or 120 Hz or 120 / 1.001 Hz (all of them are referred to as 120 Hz in the present application). A data transmission method for serially transmitting digital data representing information and having a quantization bit number of 10, 12, 14, or 16 bits, or a combination of such digital data and additional information data related thereto; And in its implementation It relates to a data transmission device being.
Background art
2. Description of the Related Art In the field of video signals, digitization has been attempted from the viewpoint of diversifying transmitted information and improving the quality of reproduced images. For example, digital video signals formed by digital data representing video signal information have been developed. There has been proposed a high definition television (HDTV) system or the like that handles the TV. A digital video signal (hereinafter, referred to as an HD digital video signal) under the HDTV system is formed, for example, according to a standard established by BTA (Broadcasting Technology Association), and Y, P _B / P _R Format and G, B, R format. Y, P _B / P _R In the case of the format, Y means a luminance signal, and P _B And P _R Means a color difference signal. In the case of the 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.
Y, P _B / P _R The HD digital video signal of the format has a frame rate of 30 Hz or 30 / 1.001 Hz (in the present application, each of these is referred to as 30 Hz), and each frame image is composed of a first field image and a second field image. The signal for interlaced scanning is formed by dividing the data into a data format as shown in FIG. 1, for example. The data format shown in FIG. 1 includes a luminance signal data sequence (Y data sequence) representing luminance signal information in a video signal as shown in FIG. 1A, and a video signal sequence as shown in FIG. Color difference signal data sequence (P _B / P _R Data series), Y data series and P _B / P _R Each of the data sequences has a quantization bit number of 10 bits. Therefore, each of the word data forming the data sequence has a 10-bit configuration, and the word transmission rate is, for example, 74.25 MBps. FIG. 1A shows a line blanking portion in each line portion of the Y data sequence and a part of the video data portion before and after the line blanking portion. FIG. _B / P _R A line blanking part in each line part in the data sequence and a part of the video data part before and after the line blanking part are shown.
In the Y data series, four words (3FF (Y), 000 (Y), 000 (Y), XYZ (Y) (3FF, 000) each having a 10-bit configuration are provided immediately before each video data portion. And XYZ are represented in hexadecimal, and (Y) represents a word in the Y data series.)) And timing reference code data (SAV: Start of Active Video), and each video data Immediately after the section, timing reference code data (EAV: End of Active Video) composed of four words (3FF (Y), 000 (Y), 000 (Y), XYZ (Y)) each having a 10-bit configuration. Is arranged. Similarly, P _B / P _R Even in the data sequence, immediately before each video data portion, four words (3FF (C), 000 (C), 000 (C), XYZ (C) (3FF, 000 and XYZ is a hexadecimal expression, and (C) is P _B / P _R Represents a word in the data series. )), Four bits (3FF (C), 000 (C), 000 (C), 3FF (C), 000 (C), 000 (C), each of which has a 10-bit configuration immediately after each video data portion. XYZ (C)) is provided. Of course, each of the timing reference code data: EAV and SAV in the Y data sequence is allocated to each line blanking section in the Y data sequence. _B / P _R Timing reference code data in the data series: EAV and SAV are each P _B / P _R It is allocated to each line blanking section in the data sequence.
In the four words (3FF, 000,000, XYZ) indicated with (Y) or (C), the first three words (3FF, 000,000) establish word synchronization or line synchronization. The last one word (XYZ) is used for identifying the first field and the second field in the same frame, or between the timing reference code data: SAV and the timing reference code data: EAV. This is for identification (the same applies hereinafter).
Also, the HD digital video signals of the G, B, and R formats are signals for interlaced scanning at a frame rate of 30 Hz, and follow, for example, a data format as shown in FIG. The data format shown in FIG. 2 includes a green primary color signal data sequence (G data sequence) representing green primary color signal information in a video signal, as shown in FIG. 2A, and a data format shown in FIG. A blue primary color signal data sequence (B data sequence) representing blue primary color signal information in a video signal, and a red primary color signal data sequence (R data sequence) representing red primary color signal information in a video signal as shown in FIG. 2C. Each of the G data sequence, the B data sequence, and the R data sequence has a quantization bit number of 10 bits, and therefore, each of the word data forming the data has a 10-bit configuration. The transmission rate is, for example, 74.25 MBps. A, B, and C in FIG. 2 show a line blanking portion in each line portion in the G data sequence, the B data sequence, and the R data sequence, respectively, and a part of the video data portion before and after the line blanking portion. .
In each of the G data sequence, the B data sequence, and the R data sequence, immediately before each video data portion, 4 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) represent words in the R data series.) .)), And four words (3FF (G), 000 (G), 000 (G)) each having a 10-bit configuration immediately after each video data part are provided with the SAV. And XYZ (G), 3FF (B , 000 (B), 000 (B) and XYZ (B) or 3FF (R), 000 (R), 000 (R) and XYZ (R)). . Of course, each of the timing reference code data: EAV and SAV in each of the G data sequence, B data sequence, and R data sequence is allocated to each line blanking section in each of the G data sequence, B data sequence, and R data sequence. You.
In the current HDTV system, Y, P for interlaced scanning at a frame rate of 30 Hz as described above is used. _B / P _R Format or G, B, R format HD digital video signals are used. On the other hand, as a next-generation HDTV system, each frame image is divided into first and second frames under a frame rate of 60 Hz. Y, P for progressive scanning formed without being divided into fields _B / P _R A system using an HD digital video signal of a format or a G, B, or R format has been proposed. Y, P for interlaced scanning _B / P _R Format or G, B, and R format HD digital video signals are referred to as HD digital video signals of a field interlace system, and Y, P _B / P _R The HD digital video signal of the format or the G, B, and R formats is referred to as an HD digital video signal of a progressive (Progressive) system.
Digital data forming a progressive HD digital video signal having a frame rate of 60 Hz is a format defined by SMPTE 247M, a standard established by the United States SMPTE (Society of Motion Picture and Television Engineers: Movie and Television Engineers Association). Has been standardized. In the format standardized by the SMPTE 247M, the frame rate is 60 Hz, the number of valid data samples per line is 1920 samples, the number of valid lines per frame is 1080 lines, and the sampling frequency is 148.5 MHz or 148.5 / 1.001 MHz (all of them are referred to as 148.5 MHz in the present application), the number of quantization bits: 8 bits or 10 bits, and the like. And the parallel data interface is Y, P _B / P _R In 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.
In such digital data forming a digital video signal having 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 prohibition code. For example, when the quantization bit number is 8 bits, the prohibition codes are 00h and FFh in hexadecimal notation (the subscript h represents a hexadecimal number), that is, 0000 0000 and 1111 1111. When the number of coded bits is 10 bits, the prohibition codes are represented 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.
Note that Y, P _B / P _R For format, P _B Data series and P _R Each sampling frequency of the data series is set to の of the sampling frequency of the Y data series. In the following, Y, P _B / P _R The format is represented as 4: 2: 2 format. In the case of the G, B, and R formats, the sampling frequencies of the G data sequence, the B data sequence, and the R data sequence are the same. Hereinafter, the G, B, and R formats will be referred to as 4: 4: 4 formats as necessary.
In addition to such an HD digital video signal, for example, 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 an image by an HDTV system, A progressive digital video signal has been proposed. Hereinafter, such a digital video signal is referred to as a D-Cinema signal.
The D-Cinema signal can be called, for example, a progressive digital video signal having a frame rate of 24 Hz or 24 / 1.001 Hz (in the present application, both of them are referred to as 24 Hz). The frame rate of the Cinema signal is not limited to 24 Hz, but may be 25 Hz, 30 Hz, 50 Hz, 60 Hz, or the like. The format of digital data forming a digital video signal having a frame rate of 24 Hz, 25 Hz, 30 Hz, 50 Hz, and 60 Hz is standardized by SMPTE 247M, and the frame rate is 24 Hz, 25 Hz, 30 Hz, 50 Hz or 60 Hz. The number of valid data samples per line: 1920 samples, the number of valid lines per frame: 1080 lines, the sampling frequency: 74.25 MHz or 74.25 / 1.001 MHz (in the present application, any of these is referred to as 74.25 MHz. ) Or 148.5 MHz, the number of quantization bits: 8 bits or 10 bits, and the like. In the case of the 4: 2: 2 format, the parallel data interface has 8 bits × 2 = 16 bits or 10 bits × 2 = 20 bits, and in the case of the 4: 4: 4 format, 8 bits × 3 = 24 bits. Alternatively, 10 bits × 3 = 30 bits.
Further, separately from the HD digital video signal or the D-Cinema signal, the frame rate is set to 24 Hz, 25 Hz, 30 Hz, 50 Hz or 60 Hz, the number of effective lines in each frame is set to 720 lines, and the number of effective lines in each line is set. There has also been proposed a progressive digital video signal in which the number of data samples is set to 1280 (this digital video signal is referred to as a 720P signal in the present application). The digital data forming such a 720P signal has been standardized in format according to a standard established by SMPTE: SMPTE 296M. In the format standardized by such SMPTE 296M, if the frame rate is 24 Hz, 25 Hz, 30 Hz, 50 Hz or 60 HZ, the number of effective lines per frame: 720, the number of effective data samples per line: only 1280 samples However, the number of lines in each frame: 750 lines, the sampling frequency: 74.25 MHz, the number of quantization bits: 8 bits or 10 bits, and the like. And the parallel data interface is Y, P _B / P _R In 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.
The 720P signal was originally proposed in the transition period to the HD digital video signal in the field of the digital video signal, and the number of effective lines per frame and the number of effective data samples per line are different from those of the HD digital video signal. Is 1080 lines and 1920 samples, but is 720 lines and 1280 samples, which is ／ of the case of the HD digital video signal. Although it is inferior to a signal, when the frame rate is 60 Hz, it is suitable for use as a signal representing a fast-moving image.
Under these circumstances, with respect to digital data forming an HD digital video signal, a D-Cinema signal in a broad sense, or a 720P signal, for example, in order to further improve the resolution of an image reproduced based on the digital signal, the number of quantization bits is determined. Has been desired to be a bit number exceeding the conventional 8 bits or 10 bits, for example, 12 bits, 14 bits, 16 bits, or the like. However, in the current standards relating to digital data forming digital video signals including the above-mentioned SMPTE 247M, SMPTE 296M, etc., standardization is carried out in which the number of quantization bits is set to 8 bits or 10 bits. However, it is not standardized that the number of quantization bits be 8 bits or more than 10 bits, for example, 12 bits, 14 bits, 16 bits, or the like.
In transmitting digital data forming a digital video signal, serial transmission in which the data is converted into serial data and transmitted is desired. However, at present, digital data having a quantization rate of 8 bits or 10 bits forming a digital video signal of 4: 2: 2 format having a frame rate of 30 Hz is a standard established by the above-mentioned BTA. It is only standardized to transmit using HD SDI (High Definition Serial Digital Interface) according to BTA S-004, and digital data in other modes, for example, a frame rate of 50 Hz or 60 Hz 4: 2: Digital data forming a digital video signal of a 2 format or 4: 4: 4 format, digital data having a quantization bit number of 10 bits forming a digital video signal of a 4: 4: 4 format, 4: 2: 2 format or 4 : 4: 4 format format Forming a barrel video signal, for serial transmission, such as digital data shall the number of quantization bits exceeding 10 bits, not normalized.
With the digitalization of the video signal as described above, for example, in obtaining a digital video signal using a digital video camera device, the digital video camera device is required to increase the frame processing speed by three times or four times the standard. It has been proposed to operate at a speed of 3 ×, 4 ×, 5 ×, etc., which is assumed to be 5 ×, to obtain a double speed digital video signal. When such a double-speed digital video signal is supplied to a reproduced image at a standard frame processing speed, a high-definition slow image can be obtained.
The digital data forming the double-speed digital video signal has a basic data structure similar to that of a progressive digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz, and has a frame rate three times, four times, or five times those. Double, that is, 72 Hz, 75 Hz, 90 Hz, 120 Hz, or the like.
A D-Cinema signal or a D-Cinema signal in a broad sense in which the number of effective lines per frame is 1080 lines, the number of effective data samples per line is 1920 samples, and the frame rate is 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz or 120 Hz. The digital data forming the digital video signal including the double-speed digital video signal of the Cinema signal system is, for example, as shown in FIG. 3 as those from DVC10 to DVV12. Similarly, the number of effective lines per frame is set to 720 lines, the number of effective data samples per line is set to 1280 samples, and the frame rate is 72 Hz, 75 Hz, 90 Hz or 120 Hz. The digital data is, for example, as shown in FIG. 4 as DTU10 to DTS12.
Also, in connection with various digital video signals as described above, it is known to use a specific key signal (Key Signal) in synthesizing a certain digital video signal with another digital video signal. Such a Key signal is a signal representing opacity or transparency of a related video signal, and is recommended as “SMPTE RECOMMENDED PRACTICE” RP 157 to 1995.
The Key signal related to the 4: 2: 2 format digital video signal has a Key signal data sequence, which is digital data forming the same, having a data format equivalent to the Y data sequence included in the digital data forming the digital video signal. And are treated in the same manner as the Y data series. The Key signal related to the 4: 4: 4 format digital video signal has a Key signal data sequence, which is digital data constituting the Key signal data, equivalent to a G data sequence included in the digital data constituting the digital video signal. It has a format and is handled in the same way as a G data series.
Under these circumstances, the frame rates including the aforementioned D-Cinema signal in a broad sense, a double-speed digital video signal of the D-Cinema signal system, a double-speed digital video signal of the 720P signal system, and the like are set to 50 Hz, 60 Hz, 72 Hz, 75 Hz, In transmitting digital data forming a digital video signal of 4: 2: 2 format or 4: 4: 4 format, such as 90 Hz, 120 Hz, etc., the digital data is transmitted, for example, according to a standard BTAS for digital data forming a digital video signal. It is desired from the viewpoints of ease of implementation, reduction of cost, and the like, that existing circuit components used for serial transmission conforming to HD SDI according to -004 be used.
Also, when transmitting digital data forming a 4: 2: 2 format or a 4: 4: 4 format digital video signal having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz, or the like, the digital video signal is also transmitted. In many cases, it is required to transmit the digital data and the related Key signal data sequence. In such a case, in addition to digital data forming a digital video signal in 4: 2: 2 format or 4: 4: 4 format, a key signal data sequence related thereto forms a digital video signal to be transmitted. The digital data is transmitted as an additional information data sequence, and the transmission of both is performed, for example, by serial transmission according to HD SDI according to the standard BTAS-004 for digital data forming a digital video signal. It is desired from the viewpoints of easiness in implementation, reduction of cost, and the like, that the existing circuit components used in the above are used.
However, as described above, regarding serial transmission of digital data forming a digital video signal, the number of quantization bits is set to 8 bits or 10 bits to form a digital video signal of 4: 2: 2 format with a frame rate of 30 Hz. Under the present circumstances in which transmission of digital data using HD SDI is only standardized, a D-Cinema signal in a broad sense, a double-speed digital video signal of a D-Cinema signal system, or , Including a double speed digital video signal of a 720P signal system, and a digital video signal of a 4: 2: 2 format or a 4: 4: 4 format having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like. For example, serial data transmission according to HD SDI is performed. A specific example of a transmission system that can be appropriately realized by using existing circuit components used in the present invention, furthermore, a D-Cinema signal in a broad sense, a double-speed digital video signal of a D-Cinema signal system, or a 720P Digital data including a 4: 2: 2 format or 4: 4: 4 format digital video signal having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz, etc., including a double speed digital video signal of a signal system; The transmission of the combination with the associated Key signal data sequence is an additional information data sequence associated with the digital data forming the digital video signal to be transmitted, and is used, for example, in serial transmission according to HD SDI. It can be implemented properly using existing circuit components. That examples of the transmission system is not missing any. Further, a document or the like which describes a technology related to such a serial transmission system cannot be found.
In view of the above, one of the objects of the present invention is to provide a 4: 2: 2 format or a 4: 4: 4 digital video signal with a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz, or the like. A data transmission method and a data transmission apparatus for appropriately implementing digital data transmission using the existing circuit components used for serial transmission conforming to HD SDI, for example. Is to provide.
Another object of the present invention is to provide a digital video signal having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz, or the like, which forms a digital video signal of 4: 2: 2 format or 4: 4: 4 format. The transmission of the combination with the related Key signal data sequence can be performed in a state where the Key signal data sequence is formed as an additional information data sequence attached to digital data forming a digital video signal to be transmitted. It is an object of the present invention to provide a data transmission method that can be appropriately realized by using existing circuit components used for serial transmission in accordance with SDI, and a data transmission device that is used to execute the method.
Disclosure of the invention
A first aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each of which has a quantization bit number of 10 bits. Y data sequence with word transmission rate of 148.5 MBps and P _B / P _R In the 20-bit parallel data including the data series, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. , And a frame part stored in the second memory are respectively converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. _B / P _R The data is read as forming 20-bit parallel data including a data sequence, and data processing is performed to obtain first and second 20-bit word string data, each of which has a word transmission rate of 74.25 MBps. To obtain the first and second serial data based on the 20-bit word string data, respectively, and transmit them for transmission.
A second aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R In the 20-bit parallel data including the data sequence, the first alternate frame portion is stored in the first memory, the second alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the second memory. Are stored in a third memory, and the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory are each stored at a frame rate. Frame and a Y data sequence forming a segmented frame digital video signal having a frequency of 24 Hz, 25 Hz or 30 Hz. _B / P _R The data is read as forming 20-bit parallel data including a data sequence, and data processing is performed to obtain first, second, and third 20-bit word string data, each of which has a word transmission rate of 74.25 MBps. , Second, and third serial data based on the 20-bit word string data, respectively, and transmit them for transmission.
In a third aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame is formed, each having a quantization bit number of 12 bits, A Y data sequence having a word transmission rate of 148.5 MBps as 14 bits or 16 bits and P _B / P _R In the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. Then, each of the frame portion stored in the first memory and the frame portion stored in the second memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. _B / P _R First and second 24-bit, 28-bit or 32-bit word string data read out as forming 24-bit, 28-bit or 32-bit parallel data including a data sequence, each having a word transmission rate of 74.25 MBps And the Y data sequence and P included in each of the first 24-bit, 28-bit or 32-bit word string data _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. Performing data processing for obtaining 20-bit word string data, obtaining first to fourth serial data based on the first to fourth 20-bit word string data, and transmitting them for transmission; Is done.
A fourth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective number of 1080 lines in each frame, each of which has a quantization bit number of 10 bits. In the 30-bit parallel data including the G data sequence, the B data sequence, and the R data sequence having a word transmission rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. A second frame part is stored in the second memory, and the frame part stored in the first memory and the frame part stored in the second memory are each a segmented frame having a frame rate of 25 Hz or 30 Hz. A 30-bit parameter including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal The first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are read out to form a G data series, B, which are included in the first 30-bit word string data. A 10-bit word forming each of the data sequence and the R data sequence is a first bit including a 10-bit word forming the G data sequence and a part of the 10-bit word forming each of the B data sequence and the R data sequence. A first word group and a second word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence; First and second 20-bit word string data having a word transmission rate of 74.25 MBps based on each of the 2 word groups The 10-bit words forming the G data sequence, the B data sequence, and the R data sequence included in the second 30-bit word sequence data are replaced with the 10-bit words forming the G data sequence, the B data sequence, and the R data sequence. A third word group including a part of the 10-bit word forming each of the data sequences, a 10-bit word forming the auxiliary data sequence, and a 10-bit word forming each of the B data sequence and the R data sequence. To obtain third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. Processing is performed to obtain first to fourth serial data based on the first to fourth 20-bit word string data, respectively. These are sent out for transmission.
A fifth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits. In the 36-bit parallel data including the G data sequence, the B data sequence, and the R data sequence having a word transmission rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. A second frame part is stored in the second memory, and the frame part stored in the first memory and the frame part stored in the second memory are each a segmented frame having a frame rate of 25 Hz or 30 Hz. A 36-bit parameter including a G data sequence, a B data sequence, and an R data sequence forming a digital video signal The first and second 36-bit word string data, each of which has a word transmission rate of 74.25 MBps, are read out as forming data, and the G data sequence B included in the first 36-bit word string data is obtained. The 12-bit word forming each of the data sequence and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and each of the B data sequence and the R data sequence. , A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits divided from a plurality of upper 10 bits, and a plurality of divided B data sequences and R data sequences. Based on another part of the upper 10 bits and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. And the second 20-bit word string data having a word transmission rate of 74.25 MBps, and forming each of the G data sequence, B data sequence, and R data sequence included in the second 36-bit word string data. The 12-bit word is divided into upper 10 bits and lower 2 bits, and one of a plurality of upper 10 bits divided from the G data sequence and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. , A third 20-bit word string data having a word transmission rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and G A word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence, the B data sequence, and the R data sequence To obtain the first to fourth serial data based on the first to fourth 20-bit word string data, and to transmit them. It shall be sent.
In a sixth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective number of lines of 1080 in each frame is formed, and word transmission is performed with each having a quantization bit number of 10 bits. Y data sequence with rate 297 MBps and P _B / P _R In the 20-bit parallel data including the data sequence, the first every third frame part in the first memory, the second every third frame part in the second memory, and the third every third frame The fourth part in a third memory and the fourth every third frame part in a fourth memory, the frame part stored in the first memory, the frame part stored in the second memory, Each of the frame part stored in the third memory and the frame part stored in the fourth memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 30 Hz. _B / P _R Data processing is performed to read out as forming 20-bit parallel data including a data sequence and obtain first, second, third, and fourth 20-bit word string data each having a word transmission rate of 74.25 MBps. , First to fourth serial data based on the first to fourth 20-bit word string data, respectively, and transmit them for transmission.
According to a seventh aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, each of which has a quantization bit number of 12 lines. Y data sequence with word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R For the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion to the first memory, the second alternate frame portion to the second memory, A third alternate frame portion is stored in a third memory, a frame portion stored in a first memory, a frame portion stored in a second memory, and a frame portion stored in a third memory. Are defined as Y data series and P data forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. _B / P _R Read as forming 24-bit, 28-bit, or 32-bit parallel data including a data sequence, and first, second, and third 24-bit, 28-bit, or 32-bit each having a word transmission rate of 74.25 MBps. Word string data is obtained, and the Y data series and P included in each of the first 24-bit, 28-bit or 32-bit word string data are _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. 20-bit word string data, and the Y data series and P included in the third 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A sixth 20-bit word rate of 74.25 MBps based on fifth 20-bit word string data having a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. Performing data processing to obtain 20-bit word string data, obtaining first to sixth serial data based on the first to sixth 20-bit word string data, and transmitting them for transmission; Is done.
In an eighth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, and each has a quantization bit number of 10 lines. For every 30 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory and second The alternate frame portion is stored in the second memory, the third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory and the second frame portion are stored in the second memory. Each of the frame portion stored in the third memory and the frame portion stored in the third memory is set to a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence forming a frame digital video signal, each of which has a word transmission rate of 74.25 MBps, first, second, and third. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the first 30-bit word sequence data, and a 10-bit word forming a G data sequence. And a first word group including a part of the 10-bit word forming each of the B data sequence and the R data sequence, and forming a 10-bit word forming the auxiliary data sequence and each of the B data sequence and the R data sequence And a second word group including the other part of the 10-bit word, First and second 20-bit word sequence data having a word transmission rate of 74.25 MBps based on each group are obtained, and the G data sequence, B data sequence, and R data included in the second 30-bit word sequence data A 10-bit word forming each of the series, a third word group including a 10-bit word forming the G data series and a part of the 10-bit word forming each of the B data series and the R data series; A fourth word group including a 10-bit word forming a data sequence and another part of the 10-bit word forming each of a B data sequence and an R data sequence is divided into third and fourth word groups. Third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on each of them are obtained. A 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the bit word sequence data is formed, and a 10-bit word forming the G data sequence and each of the B data sequence and the R data sequence are formed. A fifth word group including a part of the 10-bit word, and a fifth word group including the 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. And performing data processing to obtain fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively. Obtain first to sixth serial data based on the sixth 20-bit word string data, respectively, and transmit them for transmission. It is as.
A ninth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective number of lines of 1080 lines in each frame, each of which has a quantization bit number of 12 lines. For every 36 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory, and second and third frames are stored in a first memory. The alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the third memory. The frame portion stored in the first memory and the second frame portion are stored in the second memory. Of each of the frame part stored in the third memory and the frame part stored in the third memory are segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. It is read as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a frame digital video signal, and each of the first, second, and third data has a word transmission rate of 74.25 MBps. And the 12-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the first 36-bit word sequence data is converted into upper 10 bits and lower 2 bits. The word transmission rate is set to 74.25 MBps based on the plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The first 20-bit word string data and a plurality of upper 10 data divided from each of the B data sequence and the R data sequence 20-bit word string data having a word transmission rate of 74.25 MBps based on another part of the data and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits, A third 20-bit having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The word string data, another part of a plurality of upper 10 bits divided from each of the B data series and the R data series, the G data series, the B data series, and the R data series. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence is obtained, and G included in the third 36-bit word string data is obtained. The 12-bit word forming each of the data sequence, the B data sequence, and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, the B data sequence, and the R data sequence. A fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the data sequences, and a B data sequence and an R data sequence respectively. The other part of the plurality of upper 10 bits and the lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence And a data processing for obtaining sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the first to sixth 20-bit word string data based on the first to sixth 20-bit word string data, respectively. It is assumed that serial data is obtained and transmitted for transmission.
A tenth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each of which has a quantization bit number of 10 bits and word transmission. A 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. Each of the frame portion, the frame portion stored in the second memory, the frame portion stored in the third memory, and the frame portion stored in the fourth memory has a frame rate of 3 Hz, and is read out as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal, and each of the first and second data transmission rates is 74.25 MBps. The second, third, and fourth 30-bit word string data are obtained, and the 10-bit words forming the G data series, B data series, and R data series included in the first 30-bit word string data are represented by G A first word group including a 10-bit word forming a data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word and a B data sequence forming an auxiliary data sequence And a second group of words including the other part of the 10-bit word forming each of the R data sequences. Then, first and second 20-bit word string data having a word transmission rate of 74.25 MBps are obtained based on the first and second word groups, respectively, and G included in the second 30-bit word string data is obtained. A 10-bit word forming each of the data sequence, the B data sequence, and the R data sequence is defined as a 10-bit word forming the G data sequence and a part of the 10-bit word forming each of the B data sequence and the R data sequence. And a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence, Third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the third 30-bit word sequence data, and a 10-bit word and a B data sequence forming a G data sequence. A fifth word group including a part of the 10-bit word forming each of the R data sequences, and a 10-bit word forming the auxiliary data sequence and a 10-bit word forming each of the B data sequence and the R data sequence. Fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, are assigned to a sixth word group including another part. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the fourth 30-bit word string data. A seventh word group including a 10-bit word forming a G data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word forming an auxiliary data sequence. A word transmission rate based on the seventh and eighth word groups is allocated to an eighth word group including the other part of the 10-bit word that forms each of the B data sequence and the R data sequence. Data processing for obtaining seventh and eighth 20-bit word string data of 25 MBps is performed to obtain first to eighth serial data based on the first to eighth 20-bit word string data, respectively. To be transmitted.
According to an eleventh aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame is formed, and each of the digital image signals has a quantization bit number of 12 bits. A 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and further, the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. The frame rate of each of the frame part, the frame part stored in the second memory, the frame part stored in the third memory, and the frame part stored in the fourth memory is defined as It is read out as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence forming a segmented frame digital video signal having a frequency of 0 Hz. The second, third, and fourth 36-bit word string data are obtained, and the 12-bit words forming the G data series, B data series, and R data series included in the first 36-bit word string data are placed in the upper order. A word that is divided into 10 bits and lower 2 bits, and is based on a plurality of upper 10 bits divided from the G data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. First 20-bit word string data having a transmission rate of 74.25 MBps, and B data series and R data series A word transmission rate is set to 74.25 MBps based on another part of the plurality of upper 10 bits divided from each other and the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. The second 20-bit word string data is obtained, and the 12-bit words forming each of the G data sequence, the B data sequence, and the R data sequence included in the second 36-bit word sequence data are divided into upper 10 bits and lower 2 bits. And a word transmission rate based on a plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A third 20-bit word string data of 25 MBps, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the G data series, the B data series, and the R data series, and a third 36 bits The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the word string data is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on bits and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence; Another part of the plurality of upper 10 bits divided from each of the R data sequences and the G data sequence, the B data sequence, and the R data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of lower 2 bits obtained, and a G data sequence B included in the fourth 36-bit word string data. The 12-bit word forming each of the data sequence and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and each of the B data sequence and the R data sequence. , A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from a plurality of upper 10 bits, and a plurality of divided B data sequences and R data sequences. A word based on another part of the upper 10 bits and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. Data processing is performed to obtain eighth 20-bit word string data at a transmission rate of 74.25 MBps, and first to eighth serial data based on the first to eighth 20-bit word string data are obtained. And transmit them for transmission.
A twelfth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 10 bits and word transmission. Y data sequence with a rate of 148.5 MBps and P _B / P _R In the 20-bit parallel data including the data series, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. And a frame portion stored in the second memory are respectively converted into a Y data sequence and a P data which form a segmented frame digital video signal having a frame rate of 60 Hz. _B / P _R The data is read as forming 20-bit parallel data including a data sequence, and data processing is performed to obtain first and second 20-bit word string data, each of which has a word transmission rate of 74.25 MBps. To obtain the first and second serial data based on the 20-bit word string data, respectively, and transmit them for transmission.
In a thirteenth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame is formed, and each has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R In the 20-bit parallel data including the data sequence, the first alternate frame portion is stored in the first memory, the second alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the second memory. Are stored in a third memory, and the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory are each stored at a frame rate. Frame and a Y data sequence forming a segmented frame digital video signal having a frequency of 24 Hz, 25 Hz or 30 Hz. _B / P _R The data is read as forming 20-bit parallel data including a data sequence, and data processing is performed to obtain first, second, and third 20-bit word string data, each of which has a word transmission rate of 74.25 MBps. , Second, and third serial data based on the 20-bit word string data, respectively, and transmit them for transmission.
A fourteenth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 10 bits and word transmission. Y data sequence with rate 297 MBps and P _B / P _R In the 20-bit parallel data including the data sequence, the first every third frame part in the first memory, the second every third frame part in the second memory, and the third every third frame The fourth part in a third memory and the fourth every third frame part in a fourth memory, the frame part stored in the first memory, the frame part stored in the second memory, Each of the frame part stored in the third memory and the frame part stored in the fourth memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 30 Hz. _B / P _R Data processing is performed to read out as forming 20-bit parallel data including a data sequence and obtain first, second, third, and fourth 20-bit word string data each having a word transmission rate of 74.25 MBps. , First to fourth serial data based on the first to fourth 20-bit word string data, respectively, and transmit them for transmission.
A fifteenth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 120 Hz and an effective number of lines of 720 lines in each frame, each of which has a quantization bit number of 10 bits and word transmission. In the 30-bit parallel data including the G data sequence, the B data sequence, and the R data sequence at a rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. Is stored in the second memory, and each of the frame part stored in the first memory and the frame part stored in the second memory is converted into a segmented frame digital video signal having a frame rate of 60 Hz. Forming 30-bit parallel data including G data sequence, B data sequence and R data sequence And obtains first and second 30-bit word string data each having a word transmission rate of 74.25 MBps. The G data series, B data series, and R data included in the first 30-bit word string data are obtained. A first word group including a 10-bit word forming a G data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence; A second word group including a 10-bit word forming the data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence is divided into first and second word groups. First and second 20-bit word string data having a word transmission rate of 74.25 MBps based on each of them are obtained, and a second 30-bit word string data is obtained. A 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the word string data is converted into a 10-bit word forming the G data sequence and a 10-bit word forming each of the B data sequence and the R data sequence. A third word group including a part of the bit word; and a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. And performing data processing to obtain third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively, from the first to fourth word groups. Obtaining first to fourth serial data based on 20-bit word string data of up to 4, respectively, and transmitting them for transmission; Is done.
A sixteenth aspect of the data transmission method according to the present invention is to form a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 720 lines, and the number of quantization bits is 12 bits. In the 36-bit parallel data including the G data sequence, the B data sequence, and the R data sequence at a rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. Is stored in the second memory, and each of the frame part stored in the first memory and the frame part stored in the second memory is converted into a segmented frame digital video signal having a frame rate of 60 Hz. Forming 36-bit parallel data including G data sequence, B data sequence and R data sequence And obtains first and second 36-bit word string data each having a word transmission rate of 74.25 MBps, and obtains a G data sequence, a B data sequence, and an R data sequence included in the first 36-bit word sequence data. The 12-bit word forming each of the series 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 divided B data series and R data series. A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the upper 10 bits of the data, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. , And a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the word transmission rate is 74.2. The second 20-bit word string data of MBps is obtained, and the 12-bit words forming each of the G data series, B data series, and R data series included in the second 36-bit word string data are placed in the upper 10 bits. Word transmission based on a plurality of upper 10 bits divided from a G data sequence and a plurality of upper 10 bits divided from a B data sequence and an R data sequence, respectively. Third 20-bit word string data at a rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, a G data sequence, a B data sequence, A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the R data sequence. Data processing is performed to obtain the first to fourth serial data based on the first to fourth 20-bit word string data, respectively, and to transmit them for transmission.
A seventeenth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each having a quantization bit number of 12 bits or 14 bits. Alternatively, a Y data sequence having a word transmission rate of 148.5 MBps as 16 bits and P _B / P _R In the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. Then, each of the frame part stored in the first memory and the frame part stored in the second memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 60 Hz. _B / P _R First and second 24-bit, 28-bit or 32-bit word strings read out as forming 24-bit, 28-bit or 32-bit parallel data including a data sequence, each of which has a word transmission rate of 74.25 MBps Data, and the Y data sequence and P data included in each of the first 24-bit, 28-bit or 32-bit word string data are obtained. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. Performing data processing for obtaining 20-bit word string data, obtaining first to fourth serial data based on the first to fourth 20-bit word string data, and transmitting them for transmission; Is done.
An eighteenth aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 12 Y data sequence with word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R For the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion to the first memory, the second alternate frame portion to the second memory, A third alternate frame portion is stored in a third memory, a frame portion stored in a first memory, a frame portion stored in a second memory, and a frame portion stored in a third memory. Are defined as Y data series and P data forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. _B / P _R Read as forming 24-bit, 28-bit, or 32-bit parallel data including a data sequence, and first, second, and third 24-bit, 28-bit, or 32-bit each having a word transmission rate of 74.25 MBps. Word string data is obtained, and the Y data series and P included in each of the first 24-bit, 28-bit or 32-bit word string data are _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. 20-bit word string data, and the Y data series and P included in the third 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A sixth 20-bit word rate of 74.25 MBps based on fifth 20-bit word string data having a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. Performing data processing to obtain 20-bit word string data, obtaining first to sixth serial data based on the first to sixth 20-bit word string data, and transmitting them for transmission; Is done.
A nineteenth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 10 For every 30 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory and second The alternate frame portion is stored in the second memory, the third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory and the second frame portion are stored in the second memory. Each of the frame portion stored in the third memory and the frame portion stored in the third memory is set to a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence forming a frame digital video signal, each of which has a word transmission rate of 74.25 MBps, first, second, and third. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the first 30-bit word sequence data, and a 10-bit word forming a G data sequence. And a first word group including a part of the 10-bit word forming each of the B data sequence and the R data sequence, and forming a 10-bit word forming the auxiliary data sequence and each of the B data sequence and the R data sequence And a second word group including the other part of the 10-bit word, First and second 20-bit word sequence data having a word transmission rate of 74.25 MBps based on each group are obtained, and the G data sequence, B data sequence, and R data included in the second 30-bit word sequence data A 10-bit word forming each of the series, a third word group including a 10-bit word forming the G data series and a part of the 10-bit word forming each of the B data series and the R data series; A fourth word group including a 10-bit word forming a data sequence and another part of the 10-bit word forming each of a B data sequence and an R data sequence is divided into third and fourth word groups. Third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on each of them are obtained. A 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the bit word sequence data is formed, and a 10-bit word forming the G data sequence and each of the B data sequence and the R data sequence are formed. A fifth word group including a part of the 10-bit word, and a fifth word group including the 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. And performing data processing to obtain fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively. Obtain first to sixth serial data based on the sixth 20-bit word string data, respectively, and transmit them for transmission. It is as.
A twentieth aspect of the data transmission method according to the present invention is to form a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 12 lines. For every 36 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory, and second and third frames are stored in a first memory. The alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the third memory. The frame portion stored in the first memory and the second frame portion are stored in the second memory. Of each of the frame part stored in the third memory and the frame part stored in the third memory are segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. It is read as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a frame digital video signal, and each of the first, second, and third data has a word transmission rate of 74.25 MBps. And the 12-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the first 36-bit word sequence data is converted into upper 10 bits and lower 2 bits. The word transmission rate is set to 74.25 MBps based on the plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The first 20-bit word string data and a plurality of upper 10 data divided from each of the B data sequence and the R data sequence 20-bit word string data having a word transmission rate of 74.25 MBps based on another part of the data and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits, A third 20-bit having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The word string data, another part of a plurality of upper 10 bits divided from each of the B data series and the R data series, the G data series, the B data series, and the R data series. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence is obtained, and G included in the third 36-bit word string data is obtained. The 12-bit word forming each of the data sequence, the B data sequence, and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, the B data sequence, and the R data sequence. A fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the data sequences, and a B data sequence and an R data sequence respectively. The other part of the plurality of upper 10 bits and the lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence And a data processing for obtaining sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the first to sixth 20-bit word string data based on the first to sixth 20-bit word string data, respectively. It is assumed that serial data is obtained and transmitted for transmission.
According to a twenty-first aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed, and each of the digital image signals has a quantization bit number of 10 bits. A 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. Each of the frame portion, the frame portion stored in the second memory, the frame portion stored in the third memory, and the frame portion stored in the fourth memory has a frame rate of 30. z, a segmented frame is read out as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal, and each of the first and second data transmission rates is 74.25 MBps. The second, third, and fourth 30-bit word string data are obtained, and the 10-bit words forming the G data series, B data series, and R data series included in the first 30-bit word string data are represented by G A first word group including a 10-bit word forming a data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word and a B data sequence forming an auxiliary data sequence And a second word group including the other part of the 10-bit word forming each of the R data sequences. Dividing, obtaining first and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the first and second word groups, respectively, and G data included in the second 30-bit word string data The 10-bit word forming each of the sequence, the B data sequence, and the R data sequence includes the 10-bit word forming the G data sequence and a part of the 10-bit word forming each of the B data sequence and the R data sequence. The third word group is divided into a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. Third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. And a 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the third 30-bit word sequence data is replaced with a 10-bit word forming the G data sequence, the B data sequence, and the R data sequence. A fifth word group including a part of the 10-bit word forming each of the data sequences, a 10-bit word forming the auxiliary data sequence, and a 10-bit word forming each of the B data sequence and the R data sequence. And fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, are obtained. Further, a 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the fourth 30-bit word sequence data , A seventh word group including a 10-bit word forming a G data sequence, a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word and a B forming an auxiliary data sequence. And a word transmission rate of 74.25 MBps based on the seventh and eighth word groups, respectively, to an eighth word group including the other part of the 10-bit word forming each of the data sequence and the R data sequence. Data processing is performed to obtain seventh and eighth 20-bit word string data, and first to eighth serial data based on the first to eighth 20-bit word string data are obtained. It is sent out for transmission.
In a twenty-second aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective number of lines of 720 lines in each frame is formed, and each of the digital image signals has a quantization bit number of 12 bits. A 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in a first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and further, the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. Each of the frame portion, the frame portion stored in the second memory, the frame portion stored in the third memory, and the frame portion stored in the fourth memory has a frame rate of 3 Hz, and is read out as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal having a frequency of 74.25 MBps. The second, third, and fourth 36-bit word string data are obtained, and the 12-bit words forming the G data series, B data series, and R data series included in the first 36-bit word string data are placed in the upper order. A word that is divided into 10 bits and lower 2 bits, and is based on a plurality of upper 10 bits divided from the G data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The first 20-bit word string data having a transmission rate of 74.25 MBps and the B data sequence and the R data sequence A word transmission rate of 74.25 MBps based on another part of the plurality of upper 10 bits divided from the G bit sequence and the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. 2 20-bit word string data, and a 12-bit word forming each of the G data series, B data series, and R data series included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. And a word transmission rate of 74.25 Mbps based on a plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A third 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and G A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the data sequence, the plurality of lower 2 bits divided from the B data sequence and the R data sequence, and a third 36-bit word The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the column data is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the B data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence; The other part of the plurality of upper 10 bits divided from each of the data sequences and the G data sequence, the B data sequence, and the R data sequence. Sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of lower 2 bits obtained, and further, a G data sequence and B data included in the fourth 36-bit word string data The 12-bit word forming each of the sequence and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and each of the B data sequence and the R data sequence. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the divided plurality of upper 10 bits, and a plurality of upper bits divided from each of the B data sequence and the R data sequence A word transmission based on another part of the 10 bits and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. Data processing is performed to obtain eighth 20-bit word string data at a rate of 74.25 MBps, and first to eighth serial data based on the first to eighth 20-bit word string data are obtained. Are transmitted for transmission.
A twenty-third aspect of the data transmission method according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits. Y data sequence with word transmission rate of 148.5 MBps and P _B / P _R The first one of 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. Storing alternate frame portions in the first memory and storing second alternate frame portions in the second memory; storing the alternate frame portions in the first memory and the second memory; The Y data sequence and the P data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz _B / P _R The data is read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Y data series and P included in 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R Word transmission based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence Data processing for forming fourth 20-bit word string data having a rate of 74.25 MBps is performed to obtain first to fourth serial data based on the first to fourth 20-bit word string data, respectively. And transmit them for transmission.
A twenty-fourth aspect of the data transmission method according to the present invention provides a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each of which has a quantization bit number of 10 bits. It has a G data sequence, a B data sequence, and an R data sequence with a word transmission rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps. Storing the first alternate frame portion in the first memory and the second alternate frame portion in the second memory in the 40-bit parallel data including the additional information data sequence Each of the frame part stored in the first memory and the frame part stored in the second memory is referred to as a frame. The data is read as forming 40-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence which form a segmented frame digital video signal having a rate of 25 Hz or 30 Hz. First and second 40-bit word string data having a transmission rate of 74.25 MBps are obtained, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the first 40-bit word sequence data are obtained. A 10-bit word to be formed forms a first word group including a 10-bit word forming a G data sequence, a part of a 10-bit word forming a B data sequence and an R data sequence, and an additional information data sequence. A 10-bit word and a 10-bit word forming a B data sequence and an R data sequence A first 20-bit word string data having a word transmission rate of 74.25 MBps based on the first word group, and a second word group based on the second word group. A second 20-bit word sequence data having a word transmission rate of 74.25 MBps is formed, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the second 40-bit word sequence data And a third word group including a 10-bit word forming a G data sequence, a part of the 10-bit word forming a B data sequence and an R data sequence, and an additional information data sequence. A fourth bit including a 10-bit word to form the B data sequence and another part of the 10-bit word forming the R data sequence. The third 20-bit word string data having a word transmission rate of 74.25 MBps based on the third word group and the fourth word group having a word transmission rate of 74.25 MBps based on the fourth word group. 4 to form first and fourth serial data based on the first to fourth 20-bit word string data, respectively, and transmit them for transmission. It is assumed that.
According to a twenty-fifth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R A 30-bit parallel data having a data format and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps is added to the first two bits. Storing the alternate frame portions in a first memory, the second alternate frame portions in a second memory, and the third alternate frame portion in a third memory; , A frame part stored in the second memory, and a frame part stored in the third memory, each of which has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Y data series and P _B / P _R Read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and obtain first, second and third 30-bit word string data each having a word transmission rate of 74.25 MBps; Y data series and P included in first 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R A word based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A fourth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the third 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a fifth 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a third 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing for forming a sixth 20-bit word string data having a transmission rate of 74.25 MBps is performed, and the first to sixth serial data based on the first to sixth 20-bit word string data are respectively processed. Then, they are sent out for transmission.
A twenty-sixth aspect of the data transmission method according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits. A Y data sequence having a word transmission rate of 148.5 MBps as 14 bits or 16 bits and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. In a bit or 48-bit parallel data, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory, and is stored in the first memory. And the Y data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz, respectively. _B / P _R It is read as forming 36-bit, 42-bit or 48-bit parallel data including a data sequence and an additional information data sequence, and the first and second 36-bit and 42-bit, respectively, having a word transmission rate of 74.25 MBps. Alternatively, a 48-bit word string data is obtained, and the Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Third 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Along with the Y data series, P, contained in the second 36-bit, 42-bit or 48-bit word string data. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Data processing is performed to obtain first to sixth serial data based on the first to sixth 20-bit word string data, respectively, and to transmit them.
According to a twenty-seventh aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame is formed, each of which has a quantization bit number of 12 bits. It has a G data sequence, a B data sequence, and an R data sequence with a word transmission rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps. Storing the first alternate frame portion in the first memory and storing the second alternate frame portion in the second memory in the 48-bit parallel data including the additional information data sequence Each of the frame part stored in the first memory and the frame part stored in the second memory is referred to as a frame. Read out as forming 48-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence, which form a segmented frame digital video signal having a rate of 25 Hz or 30 Hz. First and second 48-bit word string data having a transmission rate of 74.25 MBps are obtained, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the first 48-bit word string data are obtained. Each 12-bit word to be formed is divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper bits divided from each of the B data sequence and the R data sequence. The first 20 bits having a word transmission rate of 74.25 MBps based on a part of 10 bits And another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. And G data series, B data series, and R data included in the second 48-bit word string data, which form the third 20-bit word string data having a word transmission rate of 74.25 MBps based on the auxiliary bits of Each 12-bit word forming the sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and divided from the G data sequence. A fourth 20-bit word sequence having a word transmission rate of 74.25 MBps based on the extracted plurality of upper 10 bits and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence Data, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and a plurality of lower 2 bits divided from the G data sequence, the B data sequence and the R data sequence; Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from an additional information data sequence, and a plurality of auxiliary bits And performing data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits. The first based respectively on 20-bit word sequence data al to the sixth to obtain serial data up to the 6, it is assumed to be sent in order to transmit them.
According to a twenty-eighth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, each of which has a quantization bit number of 10 lines. A G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, and a data format equivalent to the G data sequence. The number of quantization bits is 10 bits and the word transmission rate is 222.75 MBps. 40-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in a third memory, and the frame portion stored in the first memory, the second Each of the frame part stored in the memory and the frame part stored in the third memory is converted into a G data sequence, a B data sequence, and an R data which form a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. Read out as forming 40-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 40-bit word string data, each of which has a word transmission rate of 74.25 Mbps, The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word string data of No. 1 is replaced with the 10-bit word forming the G data sequence, the B data sequence and the R data A first word group comprising a portion of the 10-bit words forming the sequence; The word is divided into a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the B data sequence and the R data sequence, and is based on the first word group. Forming first 20-bit word string data having a transmission rate of 74.25 MBps and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group; The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word sequence data is referred to as the 10-bit word forming the G data sequence, the B data sequence and the R data sequence. A third word group including a part of the 10-bit word to be formed; A bit word is divided into a fourth word group including a bit word and another part of the 10-bit word forming the B data sequence and the R data sequence, and a word transmission rate based on the third word group is determined to be 74.25 MBps. No. 3 20-bit word string data and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fourth word group are included in the third 40-bit word string data. A 10-bit word forming a G data sequence, a B data sequence, an R data sequence, and a part of a 10-bit word forming a G data sequence and a 10-bit word forming a B data sequence and an R data sequence And a 10-bit word forming the additional information data sequence, the B data sequence and R Fifth 20-bit word string data at a word transmission rate of 74.25 MBps based on the fifth word group, which is divided into a sixth word group including another part of the 10-bit word forming the data sequence. And data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the sixth word group, and applying the first to sixth 20-bit word string data respectively. The first to sixth serial data are obtained and transmitted for transmission.
A twenty-ninth aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 1080, and the number of quantization bits is 10 bits. Y data sequence with rate 297 MBps and P _B / P _R The first three sets of 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. Frame portion in the first memory, second every third frame portion in the second memory, third every third frame portion in the third memory, and fourth every third frame portion. Is stored in the fourth memory, and stored in the frame part stored in the first memory, the frame part stored in the second memory, the frame part stored in the third memory, and the fourth memory. Each of the stored frame parts is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 30 Hz. _B / P _R The data is read out as forming 30-bit parallel data including a data sequence and an additional information data sequence, and first to fourth 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Data series and P data included in the 30-bit word string data of _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R A word based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A fourth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the third 30-bit word string data are formed. _B / P _R Word transmission based on a data sequence and an additional information data sequence and an auxiliary 10-bit word sequence included in the fifth 20-bit word sequence data and the third 30-bit word sequence data having a word transmission rate of 74.25 MBps. A sixth 20-bit word string data having a rate of 74.25 MBps is formed, and the Y data series and P included in the fourth 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a seventh 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a fourth 30-bit word sequence data, and an auxiliary 10-bit word sequence Data processing for forming an eighth 20-bit word string data having a transmission rate of 74.25 MBps is performed, and the first to eighth serial data based on the first to eighth 20-bit word string data are respectively processed. Then, they are sent out for transmission.
According to a thirtieth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame is formed, and each of the digital image signals has a quantization bit number of 10 bits. A G data sequence, a B data sequence, and an R data sequence having a rate of 297 MBps; and an additional information data sequence having a data format equivalent to the G data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. In the 40-bit parallel data, the first every third frame portion in the first memory, the second every third frame portion in the second memory, and the third every third frame portion. A third memory and a fourth every third frame portion stored in the fourth memory, the frame stored in the first memory , A frame part stored in the second memory, a frame part stored in the third memory, and a frame part stored in the fourth memory are each converted into a segmented frame digital video signal having a frame rate of 30 Hz. The data is read out as forming 40-bit parallel data including the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence, each of which has a word transmission rate of 74.25 MBps. The 40-bit word string data is obtained, and the 10-bit words forming the G data series, the B data series, the R data series, and the additional information data series included in the first 40-bit word string data are converted into the G data series. A first word comprising a bit word and a portion of a 10-bit word forming a B data sequence and an R data sequence. And a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the B data sequence and the R data sequence. Forming first 20-bit word string data having a word transmission rate of 74.25 MBps based on a second word group, and second 20-bit word string data having a word transmission rate of 74.25 MBps based on a second word group; The 10-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the second 40-bit word sequence data are replaced with the 10-bit words forming the G data sequence, the B data sequence, and the R data sequence. A third word group including a part of a 10-bit word forming a data sequence; The word transmission rate based on the third word group is divided into a fourth word group including a 10-bit word forming a column and another part of the 10-bit word forming a B data sequence and an R data sequence. Forming a third 20-bit word string data at 74.25 MBps and a fourth 20-bit word string data at a word transmission rate of 74.25 MBps based on the fourth word group; The 10-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the column data are replaced with the 10-bit words forming the G data sequence and the 10-bit words forming the B data sequence and the R data sequence. A fifth word group including a part of a bit word, a 10-bit word forming a side information data sequence, and B And a sixth word group including the other part of the 10-bit word forming the data sequence and the R data sequence, based on the fifth word group and having a word transmission rate of 74.25 MBps based on the fifth word group. A G data sequence which forms bit word string data and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the sixth word group and is included in the fourth 40-bit word string data , B data sequence, R data sequence, and additional information data sequence, include a 10-bit word forming a G data sequence and a part of a 10-bit word forming a B data sequence and an R data sequence. A seventh word group, a 10-bit word forming an additional information data sequence, and a B data sequence and an R data sequence are formed. A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on the seventh word group and an eighth word group including another part of the 10-bit word. Data processing for forming eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on the word group is performed, and the first to eighth data are respectively formed based on the first to eighth 20-bit word string data. It is assumed that up to 8 serial data are obtained and transmitted for transmission.
According to a thirty-first aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, and each has a quantization bit number of 12 lines. Y data sequence with word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 222.75 MBps. Bit or 48-bit parallel data, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion. Are stored in a third memory, and each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz. , 25 Hz or 30 Hz segmented frame digital video signal and Y data sequence _B / P _R A 36-bit, 42-bit, or 48-bit parallel data including a data sequence and an additional information data sequence is read out to form parallel data, and each of the first, second, and third 36 bits has a word transmission rate of 74.25 MBps. , 42-bit or 48-bit word string data, and Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits; , Y data series included in the second 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. , Y data series included in the third 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A ninth 20-bit word string data with a word transmission rate of 74.25 MBps is formed based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Data processing is performed to obtain first to ninth serial data based on the first to ninth 20-bit word string data, respectively, and to transmit them.
A thirty-second aspect of the data transmission method according to the present invention provides a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective number of lines of 1080 in each frame, each of which has a quantization bit number of 12 lines. It has the same data format as the G data sequence, the G data sequence, the B data sequence, and the R data sequence with a word transmission rate of 222.75 MBps as bits, and the word transmission rate with the number of quantization bits being 12 bits. 48-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in a third memory, and the frame portion stored in the first memory, the second Each of the frame part stored in the memory and the frame part stored in the third memory is converted into a G data sequence, a B data sequence and an R data which form a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. Read as forming 48-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 48-bit word string data, each of which has a word transmission rate of 74.25 MBps, Each of the 12-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the 48-bit word sequence data of No. 1 is divided into upper 10 bits and lower 2 bits, and the G data sequence From a plurality of upper 10 bits divided from the B data sequence and the R data sequence First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the divided plurality of upper 10 bits, and a plurality of upper bits divided from each of the B data sequence and the R data sequence A second word rate of 74.25 MBps based on another part of 10 bits, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. And the third 20 bits having a word transmission rate of 74.25 MBps based on the 20-bit word string data and the plurality of upper 10 bits, the plurality of lower 2 bits, and the plurality of auxiliary bits divided from the additional information data sequence G data series, B data series, R data series and additional information included in the second 48-bit word string data. Each 12-bit word forming the data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence and each of the B data sequence and the R data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. Fifth 20-bit having a word transmission rate of 74.25 MBps based on another part, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits Word data based on word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A sixth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the third 48-bit word string data are formed. Each of the 12-bit words to be divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper 10 bits divided from the B data sequence and the R data sequence, respectively. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the bits and another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence And a plurality of lower bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. The word transmission rate is set to 74 based on the eighth 20-bit word string data having a data rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. .25 MBps to obtain ninth 20-bit word string data, and obtain first to ninth serial data based on the first to ninth 20-bit word string data, respectively. To be transmitted.
A thirty-third aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 1080, and the number of quantization bits is 12 bits. A G data sequence, a B data sequence, and an R data sequence having a rate of 297 MBps; and an additional information data sequence having a data format equivalent to the G data sequence, a quantization bit number of 12 bits, and a word transmission rate of 297 MBps. In the 48-bit parallel data, the first every third frame portion in the first memory, the second every third frame portion in the second memory, and the third every third frame portion. A third memory and a fourth every third frame portion stored in the fourth memory, the frame stored in the first memory , A frame part stored in the second memory, a frame part stored in the third memory, and a frame part stored in the fourth memory are each converted into a segmented frame digital video signal having a frame rate of 30 Hz. The data is read out as forming 48-bit parallel data including the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence, each of which has a word transmission rate of 74.25 MBps. The third and fourth 48-bit word string data are obtained, and each of the 12-bit words forming the G data sequence, B data sequence, R data sequence and additional information data sequence included in the first 48-bit word sequence data is placed in the higher order. It is divided into 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a B data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the R data sequences, and each of the B data sequence and the R data sequence The word transmission rate is set to 74 based on another part of the plurality of divided upper 10 bits, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word transmission rate of 74.25 MBps based on second 20-bit word string data of .25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence; G data series, B data series, and G data series included in the second 48-bit word string data. Each 12-bit word forming the R data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and the B data sequence and the R data sequence. And a fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the B data series and the R data series. A word transmission rate of 74.25 MBps based on another part of the plurality of upper 10 bits, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. And a plurality of lower 10 bits and a plurality of lower 10 bits divided from the additional information data sequence. And a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits, and a G data sequence, a B data sequence, an R data sequence, and a third 48-bit word sequence data included in the third 48-bit word sequence data. Each 12-bit word forming the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence and each of the B data sequence and the R data sequence. 7th 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the extracted plurality of upper 10 bits, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. Other bits, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. Based on the 8th 20-bit word string data having a word transmission rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A ninth 20-bit word string data having a word transmission rate of 74.25 MBps is formed, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the fourth 48-bit word sequence data are formed. Each 12-bit word to be formed is divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper bits divided from each of the B data sequence and the R data sequence. A tenth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of 10 bits, and a B data A plurality of upper 10 bits divided from each of the data sequence and the R data sequence, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence; The 11th 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence Data processing for forming a twelfth 20-bit word string data having a word transmission rate of 74.25 MBps based on the first to twelfth 20-bit word string data, respectively. It is assumed that serial data is obtained and transmitted for transmission.
A thirty-fourth aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 10 bits. Y data sequence with a rate of 148.5 MBps and P _B / P _R The first one of 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. Storing alternate frame portions in the first memory and storing second alternate frame portions in the second memory; storing the alternate frame portions in the first memory and the second memory; The Y data sequence and the P data forming a segmented frame digital video signal having a frame rate of 60 Hz _B / P _R The data is read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Y data series and P included in 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R Word transmission based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence Data processing for forming fourth 20-bit word string data having a rate of 74.25 MBps is performed to obtain first to fourth serial data based on the first to fourth 20-bit word string data, respectively. And transmit them for transmission.
A thirty-fifth aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 120 Hz and the number of effective lines in each frame is 720 lines, each of which is a word transmission with a quantization bit number of 10 bits. G data sequence, B data sequence, and R data sequence with a rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps added In the 40-bit parallel data including the information data sequence, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. Each of the frame part stored in the memory and the frame part stored in the second memory has a frame rate of 60 Hz. And read out as forming 40-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence, which form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. The first and second 40-bit word string data are obtained, and the 10-bit words forming the G data sequence, B data sequence, R data sequence, and additional information data sequence included in the first 40-bit word string data are A first word group including a 10-bit word forming a G data sequence, a part of a 10-bit word forming a B data sequence and an R data sequence, and a 10-bit word and a B data sequence forming an additional information data sequence And another portion of the 10-bit word forming the R data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on the first word group and a second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group. 2 20-bit word string data and a 10-bit word forming a G data series, a B data series, an R data series, and an additional information data series included in the second 40-bit word string data. A third word group including a 10-bit word forming a sequence and a part of a 10-bit word forming a B data sequence and an R data sequence; a 10-bit word forming a side information data sequence, a B data sequence and an R data sequence; A fourth word group including the other part of the 10-bit word forming the data sequence; A third 20-bit word string data having a word transmission rate of 74.25 MBps based on a fourth word group, and a fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a fourth word group. Is performed to obtain first to fourth serial data based on the first to fourth 20-bit word string data, respectively, and to transmit them.
A thirty-sixth aspect of the data transmission method according to the present invention provides a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R A 30-bit parallel data having a data format and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps is added to the first two bits. Storing the alternate frame portions in a first memory, the second alternate frame portions in a second memory, and the third alternate frame portion in a third memory; , A frame part stored in the second memory, and a frame part stored in the third memory, each of which has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Y data series and P _B / P _R Read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and obtain first, second and third 30-bit word string data each having a word transmission rate of 74.25 MBps; Y data series and P included in first 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R A word based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A fourth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the third 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a fifth 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a third 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing for forming a sixth 20-bit word string data having a transmission rate of 74.25 MBps is performed, and the first to sixth serial data based on the first to sixth 20-bit word string data are respectively processed. Then, they are sent out for transmission.
A thirty-seventh aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 120 Hz and the number of effective lines in each frame is 720 lines, and the number of quantization bits is 12 bits and 14 bits, respectively. Alternatively, a Y data sequence having a word transmission rate of 148.5 MBps as 16 bits and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. In a bit or 48-bit parallel data, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory, and is stored in the first memory. The frame data stored in the second memory and the frame data stored in the second memory are respectively converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 60 Hz. _B / P _R It is read as forming 36-bit, 42-bit or 48-bit parallel data including a data sequence and an additional information data sequence, and the first and second 36-bit and 42-bit, respectively, having a word transmission rate of 74.25 MBps. Alternatively, a 48-bit word string data is obtained, and the Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Third 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Along with the Y data series, P, contained in the second 36-bit, 42-bit or 48-bit word string data. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Data processing is performed to obtain first to sixth serial data based on the first to sixth 20-bit word string data, respectively, and to transmit them.
A thirty-eighth aspect of the data transmission method according to the present invention provides a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 12 in each case. A G data sequence, a B data sequence, and an R data sequence with a rate of 148.5 MBps and a data format equivalent to the G data sequence, with a 12-bit quantization bit rate and a word transmission rate of 148.5 MBps added In the 48-bit parallel data including the information data sequence, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. Each of the frame part stored in the memory and the frame part stored in the second memory has a frame rate of 60 Hz. And read out as forming 48-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence, which form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. First and second 48-bit word string data are obtained, and each of the 12-bit words forming the G data series, B data series, R data series and additional information data series included in the first 48-bit word string data is obtained. , Divided into upper 10 bits and lower 2 bits, and divided into a plurality of upper 10 bits divided from the G data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. 20-bit word string data having a word transmission rate of 74.25 MBps based on And another part of the plurality of upper 10 bits divided from each of the R data sequence, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word based on second 20-bit word string data having a word transmission rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence A third 20-bit word string data having a transmission rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the second 48-bit word string data are formed. Each of the 12-bit words to be divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence; A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the data sequence and the R data sequence, and a B data sequence and an R data sequence Word transmission based on another part of the plurality of upper 10 bits divided from each of the above, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word transmission rate of 74 based on fifth 20-bit word string data having a rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. Data processing to form a sixth 20-bit word string data of .25 MBps, and a first to sixth 20-bit word string data To obtain serial data from the first based respectively to the sixth to over data, is assumed to be transmitted in order to transmit them.
A thirty-ninth aspect of the data transmission method according to the present invention provides a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective number of lines of 720 lines in each frame, each of which has a quantization bit number of 10 lines. A G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, and a data format equivalent to the G data sequence. The number of quantization bits is 10 bits and the word transmission rate is 222.75 MBps. 40-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the second A G data sequence, a B data sequence and an R data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz, respectively, for each of the frame part stored in the memory and the frame part stored in the third memory. Read out as forming 40-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 40-bit word string data, each of which has a word transmission rate of 74.25 Mbps, The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word string data of No. 1 is replaced with the 10-bit word forming the G data sequence, the B data sequence and the R data A first group of words comprising a portion of the 10-bit words forming the sequence; The word is divided into a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the B data sequence and the R data sequence, and based on the first word group, Forming first 20-bit word string data having a transmission rate of 74.25 MBps and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group; The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word sequence data is referred to as the 10-bit word forming the G data sequence, the B data sequence and the R data sequence. A third word group including a part of the 10-bit word to be formed; And a fourth word group including the other word and the other part of the 10-bit word forming the B data sequence and the R data sequence. The third word group is based on the third word group and has a word transmission rate of 74.25 MBps. And the fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fourth word group, and G included in the third 40-bit word string data. A 10-bit word forming a data sequence, a B data sequence, an R data sequence, and an additional information data sequence is defined as a 10-bit word forming a G data sequence and a part of a 10-bit word forming a B data sequence and an R data sequence. , A 10-bit word forming an additional information data sequence, a B data sequence and an R data sequence. A fifth 20-bit word string data which is divided into a sixth word group including another part of the 10-bit word forming the data sequence, and which has a word transmission rate of 74.25 MBps based on the fifth word group; , And a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the sixth word group, based on the first to sixth 20-bit word string data. It is assumed that the first to sixth serial data are obtained and transmitted for transmission.
According to a fortieth aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame is formed, and each of them has a quantization bit number of 12 Data sequence with a word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 222.75 MBps. Bit or 48-bit parallel data, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion. Are stored in a third memory, and each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz. , 25 Hz or 30 Hz segmented frame digital video signal and Y data sequence _B / P _R A 36-bit, 42-bit, or 48-bit parallel data including a data sequence and an additional information data sequence is read out to form parallel data, and each of the first, second, and third 36 bits has a word transmission rate of 74.25 MBps. , 42-bit or 48-bit word string data, and Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits; , Y data series included in the second 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. , Y data series included in the third 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A ninth 20-bit word string data with a word transmission rate of 74.25 MBps is formed based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Data processing is performed to obtain first to ninth serial data based on the first to ninth 20-bit word string data, respectively, and to transmit them.
In a forty-first aspect of the data transmission method according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame is formed, and each has a quantization bit number of 12 lines. It has the same data format as the G data sequence, the G data sequence, the B data sequence, and the R data sequence with a word transmission rate of 222.75 MBps as bits, and the word transmission rate with the number of quantization bits being 12 bits. 48-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the second A G data sequence, a B data sequence and an R data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz, respectively, for each of the frame part stored in the memory and the frame part stored in the third memory. Read as forming 48-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 48-bit word string data, each of which has a word transmission rate of 74.25 MBps, Each of the 12-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the 48-bit word sequence data of No. 1 is divided into upper 10 bits and lower 2 bits, and the G data sequence From the plurality of upper 10 bits divided from the B data sequence and the R data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits thus obtained, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A second transmission rate of 74.25 MBps based on another part of the bits, a plurality of lower two bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits; A third 20-bit word having a word transmission rate of 74.25 MBps based on 20-bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence And G data series, B data series, R data series and additional information data included in the second 48-bit word string data. Each 12-bit word forming the data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence and each of the B data sequence and the R data sequence. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence A fifth transmission rate of 74.25 MBps based on the other part, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word based on bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence A sixth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the third 48-bit word string data are formed. Each of the 12-bit words to be divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper 10 bits divided from the B data sequence and the R data sequence, respectively. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the bits and another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence And a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. The word transmission rate is set to 74.25 MBps based on the eighth 20-bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. Data processing for forming ninth 20-bit word string data of 25 MBps is performed to obtain first to ninth serial data based on the first to ninth 20-bit word string data, respectively. It is sent out for transmission.
Further, the first aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective number of lines of 1080 lines in each frame, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 148.5 MBps as bits and P _B / P _R In the 20-bit parallel data including the data series, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. , And a frame part stored in the second memory are respectively converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. _B / P _R A data processing unit that reads data as forming 20-bit parallel data including a data sequence and performs data processing to obtain first and second 20-bit word string data each having a word transmission rate of 74.25 MBps; First and second parallel / serial (P / S) converters for obtaining first and second serial data based on the first and second 20-bit word string data, respectively, and the first and second serial data And a data transmission unit for transmitting the data for transmission.
In a second aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective number of lines of 1080 lines in each frame is formed, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R In the 20-bit parallel data including the data sequence, the first alternate frame portion is stored in the first memory, the second alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the second memory. Are stored in a third memory, and the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory are each stored at a frame rate. Frame and a Y data sequence forming a segmented frame digital video signal having a frequency of 24 Hz, 25 Hz or 30 Hz. _B / P _R A data processing unit that reads as forming 20-bit parallel data including a data sequence and performs data processing to obtain first, second, and third 20-bit word string data each having a word transmission rate of 74.25 MBps. A first, second, and third P / S converter that obtains first, second, and third serial data based on first, second, and third 20-bit word string data, respectively; , Second and third serial data to be transmitted.
A third aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits, A Y data sequence having a word transmission rate of 148.5 MBps as 14 bits or 16 bits and P _B / P _R In the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. Then, each of the frame portion stored in the first memory and the frame portion stored in the second memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. _B / P _R First and second 24-bit, 28-bit or 32-bit word string data read out as forming 24-bit, 28-bit or 32-bit parallel data including a data sequence, each having a word transmission rate of 74.25 MBps And the Y data sequence and P included in each of the first 24-bit, 28-bit or 32-bit word string data _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. A data processing unit for performing data processing for obtaining 20-bit word string data; and a first to fourth data for obtaining first to fourth serial data based on the first to second 20-bit word string data, respectively. It comprises a P / S converter and a data transmitter for transmitting the first to fourth serial data for transmission.
A fourth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits. In the 30-bit parallel data including the G data sequence, the B data sequence, and the R data sequence having a word transmission rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. A second frame part is stored in the second memory, and the frame part stored in the first memory and the frame part stored in the second memory are each a segmented frame having a frame rate of 25 Hz or 30 Hz. A 30-bit parameter including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal The first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are read out to form a G data series, B, which are included in the first 30-bit word string data. A 10-bit word forming each of the data sequence and the R data sequence is a first bit including a 10-bit word forming the G data sequence and a part of the 10-bit word forming each of the B data sequence and the R data sequence. A first word group and a second word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence; First and second 20-bit word string data having a word transmission rate of 74.25 MBps based on each of the 2 word groups The 10-bit words forming the G data sequence, the B data sequence, and the R data sequence included in the second 30-bit word sequence data are replaced with the 10-bit words forming the G data sequence, the B data sequence, and the R data sequence. A third word group including a part of the 10-bit word forming each of the data sequences, a 10-bit word forming the auxiliary data sequence, and a 10-bit word forming each of the B data sequence and the R data sequence. To obtain third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. A data processing unit for performing processing, and first to fourth serial data based on the first to fourth 20-bit word string data, respectively. The first to fourth P / S converters for obtaining data, and the data transmitter for transmitting the first to fourth serial data for transmission.
A fifth aspect of the data transmission apparatus according to the present invention is a digital video signal in which the frame rate is 50 Hz or 60 Hz, the number of effective lines in each frame is 1080, and the number of quantization bits is 12 bits. In the 36-bit parallel data including the G data sequence, the B data sequence, and the R data sequence having a word transmission rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. A second frame part is stored in the second memory, and the frame part stored in the first memory and the frame part stored in the second memory are each a segmented frame having a frame rate of 25 Hz or 30 Hz. A 36-bit parameter including a G data sequence, a B data sequence, and an R data sequence forming a digital video signal The first and second 36-bit word string data, each of which has a word transmission rate of 74.25 MBps, are read out as forming data, and the G data sequence B included in the first 36-bit word string data is obtained. The 12-bit word forming each of the data sequence and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and each of the B data sequence and the R data sequence. , A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits divided from a plurality of upper 10 bits, and a plurality of divided B data sequences and R data sequences. Based on another part of the upper 10 bits and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. And the second 20-bit word string data having a word transmission rate of 74.25 MBps, and forming each of the G data sequence, B data sequence, and R data sequence included in the second 36-bit word string data. The 12-bit word is divided into upper 10 bits and lower 2 bits, and one of a plurality of upper 10 bits divided from the G data sequence and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. , A third 20-bit word string data having a word transmission rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and G A word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence, the B data sequence, and the R data sequence A data processing unit for performing data processing for obtaining fourth 20-bit word string data to be processed, and first to fourth data for obtaining first to fourth serial data based on the first to fourth 20-bit word string data, respectively. 4 P / S converter and a data transmitter for transmitting the first to fourth serial data.
A sixth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective number of lines of 1080 lines in each frame, each of which has a quantized bit number of 10 bits, and performs word transmission. Y data sequence with rate 297 MBps and P _B / P _R In the 20-bit parallel data including the data sequence, the first every third frame part in the first memory, the second every third frame part in the second memory, and the third every third frame The fourth part in a third memory and the fourth every third frame part in a fourth memory, the frame part stored in the first memory, the frame part stored in the second memory, Each of the frame part stored in the third memory and the frame part stored in the fourth memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 30 Hz. _B / P _R Data processing is performed to read out as forming 20-bit parallel data including a data sequence and obtain first, second, third and fourth 20-bit word string data each having a word transmission rate of 74.25 MBps. A data processing unit, first to fourth P / S converters for obtaining first to fourth serial data based on the first to fourth 20-bit word string data, and first to fourth P / S converters And a data transmission unit for transmitting the serial data up to the above.
According to a seventh aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, and each of them has a quantization bit number of 12 lines. Y data sequence with word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R For the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion to the first memory, the second alternate frame portion to the second memory, A third alternate frame portion is stored in a third memory, a frame portion stored in a first memory, a frame portion stored in a second memory, and a frame portion stored in a third memory. Are defined as Y data series and P data forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. _B / P _R Read as forming 24-bit, 28-bit, or 32-bit parallel data including a data sequence, and first, second, and third 24-bit, 28-bit, or 32-bit each having a word transmission rate of 74.25 MBps. Word string data is obtained, and the Y data series and P included in each of the first 24-bit, 28-bit or 32-bit word string data are _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. 20-bit word string data, and the Y data series and P included in the third 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A sixth 20-bit word rate of 74.25 MBps based on fifth 20-bit word string data having a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. A data processing unit for performing data processing for obtaining 20-bit word string data; and a first to sixth data for obtaining first to sixth serial data based on the first to sixth 20-bit word string data, respectively. It comprises a P / S converter and a data transmitter for transmitting the first to sixth serial data for transmission.
In an eighth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz, or 90 Hz and an effective number of lines of 1080 in each frame is formed. For every 30 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory, and second and third frames are stored in a first memory. The alternate frame portion is stored in the second memory, the third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory and the second frame portion are stored in the second memory. Each of the frame portion stored in the third memory and the frame portion stored in the third memory is set to a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence forming a frame digital video signal, each of which has a word transmission rate of 74.25 MBps, first, second, and third. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the first 30-bit word sequence data, and a 10-bit word forming a G data sequence. And a first word group including a part of the 10-bit word forming each of the B data sequence and the R data sequence, and forming a 10-bit word forming the auxiliary data sequence and each of the B data sequence and the R data sequence And a second word group including the other part of the 10-bit word, and the first and second word groups. And first and second 20-bit word sequence data having a word transmission rate of 74.25 MBps based on the G data sequence, the B data sequence, and the R data sequence included in the second 30-bit word sequence data. A third word group including a 10-bit word forming each of the data sequences, a 10-bit word forming the G data sequence, and a part of the 10-bit words forming each of the B data sequence and the R data sequence; A third word group including a 10-bit word forming the auxiliary data sequence and a fourth word group including another part of the 10-bit word forming each of the B data sequence and the R data sequence; And third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps, respectively, based on The 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the word sequence data is replaced with the 10-bit word forming the G data sequence and the 10-bit word forming each of the B data sequence and the R data sequence. A fifth word group including a part of the bit word, and a sixth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. A data processing unit for performing data processing for obtaining fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, The first to sixth serial data for obtaining the first to sixth serial data based on the first to sixth 20-bit word string data, respectively. / A S conversion unit, and a data transmitting portion for transmitting the serial data from the first to the sixth.
In a ninth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz, or 90 Hz and an effective line number of 1080 lines in each frame is formed, and each of them has a quantization bit number of 12 lines. For every 36 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory, and second and third frames are stored in a first memory. The alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the third memory. The frame portion stored in the first memory and the second frame portion are stored in the second memory. Of each of the frame part stored in the third memory and the frame part stored in the third memory are segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. It is read as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a frame digital video signal, and each of the first, second, and third data has a word transmission rate of 74.25 MBps. And the 12-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the first 36-bit word sequence data is converted into upper 10 bits and lower 2 bits. The word transmission rate is set to 74.25 MBps based on the plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The first 20-bit word string data and a plurality of upper 10 data divided from each of the B data sequence and the R data sequence 20-bit word string data having a word transmission rate of 74.25 MBps based on another part of the data and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits, A third 20-bit having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The word string data, another part of a plurality of upper 10 bits divided from each of the B data series and the R data series, the G data series, the B data series, and the R data series. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence is obtained, and G included in the third 36-bit word string data is obtained. The 12-bit word forming each of the data sequence, the B data sequence, and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, the B data sequence, and the R data sequence. A fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the data sequences, and a B data sequence and an R data sequence respectively. The other part of the plurality of upper 10 bits and the lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence And a data processing unit for performing data processing for obtaining sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the first to sixth 20-bit word string data. A first P / S converter for obtaining the sixth serial data and a data transmitter for transmitting the first to sixth serial data are provided.
In a tenth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective number of lines of 1080 in each frame is formed, and word transmission is performed with each of the quantization bits being 10 bits. A 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. Each of the frame portion, the frame portion stored in the second memory, the frame portion stored in the third memory, and the frame portion stored in the fourth memory has a frame rate of 3 Hz, and is read out as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal, and each of the first and second data transmission rates is 74.25 MBps. The second, third, and fourth 30-bit word string data are obtained, and the 10-bit words forming the G data series, B data series, and R data series included in the first 30-bit word string data are represented by G A first word group including a 10-bit word forming a data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word and a B data sequence forming an auxiliary data sequence And a second group of words including the other part of the 10-bit word forming each of the R data sequences. Then, first and second 20-bit word string data having a word transmission rate of 74.25 MBps are obtained based on the first and second word groups, respectively, and G included in the second 30-bit word string data is obtained. A 10-bit word forming each of the data sequence, the B data sequence, and the R data sequence is defined as a 10-bit word forming the G data sequence and a part of the 10-bit word forming each of the B data sequence and the R data sequence. And a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence, Third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the third 30-bit word sequence data, and a 10-bit word and a B data sequence forming a G data sequence. A fifth word group including a part of the 10-bit word forming each of the R data sequences, and a 10-bit word forming the auxiliary data sequence and a 10-bit word forming each of the B data sequence and the R data sequence. Fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, are assigned to a sixth word group including another part. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the fourth 30-bit word string data. A seventh word group including a 10-bit word forming a G data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word forming an auxiliary data sequence. A word transmission rate based on the seventh and eighth word groups is allocated to an eighth word group including the other part of the 10-bit word that forms each of the B data sequence and the R data sequence. Data processing for obtaining seventh and eighth 20-bit word string data of 25 MBps is performed to obtain first to eighth serial data based on the first to eighth 20-bit word string data, respectively. The P / S converter includes up to an eighth P / S converter and a data transmitter that transmits the first to eighth serial data for transmission.
An eleventh aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each of which has a quantization bit number of 12 bits and word transmission. A 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and further, the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. The frame rate of each of the frame part, the frame part stored in the second memory, the frame part stored in the third memory, and the frame part stored in the fourth memory is defined as It is read out as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence forming a segmented frame digital video signal having a frequency of 0 Hz. The second, third, and fourth 36-bit word string data are obtained, and the 12-bit words forming the G data series, B data series, and R data series included in the first 36-bit word string data are placed in the upper order. A word that is divided into 10 bits and lower 2 bits, and is based on a plurality of upper 10 bits divided from the G data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. First 20-bit word string data having a transmission rate of 74.25 MBps, and B data series and R data series A word transmission rate is set to 74.25 MBps based on another part of the plurality of upper 10 bits divided from each other and the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. The second 20-bit word string data is obtained, and the 12-bit words forming each of the G data sequence, the B data sequence, and the R data sequence included in the second 36-bit word sequence data are divided into upper 10 bits and lower 2 bits. And a word transmission rate based on a plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A third 20-bit word string data of 25 MBps, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the G data series, the B data series, and the R data series, and a third 36 bits The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the word string data is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on bits and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence; Another part of the plurality of upper 10 bits divided from each of the R data sequences and the G data sequence, the B data sequence, and the R data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of lower 2 bits obtained, and a G data sequence B included in the fourth 36-bit word string data. The 12-bit word forming each of the data sequence and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and each of the B data sequence and the R data sequence. , A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from a plurality of upper 10 bits, and a plurality of divided B data sequences and R data sequences. A word based on another part of the upper 10 bits and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. A data processing unit for performing data processing to obtain eighth 20-bit word string data having a transmission rate of 74.25 MBps; and a first to eighth data processing section based on the first to eighth 20-bit word string data, respectively. It comprises first to eighth P / S converters for obtaining serial data and a data transmitter for transmitting the first to eighth serial data for transmission.
A twelfth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each having a quantization bit number of 10 bits. Y data sequence with word transmission rate of 148.5 MBps and P _B / P _R In the 20-bit parallel data including the data series, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. And a frame portion stored in the second memory are respectively converted into a Y data sequence and a P data which form a segmented frame digital video signal having a frame rate of 60 Hz. _B / P _R A data processing unit that reads out as forming 20-bit parallel data including a data sequence and obtains first and second 20-bit word string data each having a word transmission rate of 74.25 MBps; A first and second P / S converter for obtaining first and second serial data based on the 20-bit word string data, and a data transmitter for transmitting the first and second serial data. It is comprised including.
A thirteenth aspect of the data transmission apparatus according to the present invention is a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R In the 20-bit parallel data including the data sequence, the first alternate frame portion is stored in the first memory, the second alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the second memory. Are stored in a third memory, and the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory are each stored at a frame rate. Frame and a Y data sequence forming a segmented frame digital video signal having a frequency of 24 Hz, 25 Hz or 30 Hz. _B / P _R A data processing unit that reads as forming 20-bit parallel data including a data sequence and performs data processing to obtain first, second, and third 20-bit word string data each having a word transmission rate of 74.25 MBps. A first, second, and third P / S converter that obtains first, second, and third serial data based on first, second, and third 20-bit word string data, respectively; , Second and third serial data to be transmitted.
A fourteenth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective number of lines of 720 lines in each frame, each of which has a quantization bit number of 10 bits and word transmission. Y data sequence with rate 297 MBps and P _B / P _R In the 20-bit parallel data including the data sequence, the first every third frame part in the first memory, the second every third frame part in the second memory, and the third every third frame The fourth part in a third memory and the fourth every third frame part in a fourth memory, the frame part stored in the first memory, the frame part stored in the second memory, Each of the frame part stored in the third memory and the frame part stored in the fourth memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 30 Hz. _B / P _R Data processing is performed to read out as forming 20-bit parallel data including a data sequence and obtain first, second, third and fourth 20-bit word string data each having a word transmission rate of 74.25 MBps. A data processing unit, first to fourth P / S converters for obtaining first to fourth serial data based on the first to fourth 20-bit word string data, and first to fourth P / S converters And a data transmission unit for transmitting the serial data up to the above.
According to a fifteenth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed. In the 30-bit parallel data including the G data sequence, the B data sequence, and the R data sequence at a rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. Is stored in the second memory, and each of the frame part stored in the first memory and the frame part stored in the second memory is converted into a segmented frame digital video signal having a frame rate of 60 Hz. Forming 30-bit parallel data including G data sequence, B data sequence and R data sequence And obtains first and second 30-bit word string data each having a word transmission rate of 74.25 MBps. The G data series, B data series, and R data included in the first 30-bit word string data are obtained. A first word group including a 10-bit word forming a G data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence; A second word group including a 10-bit word forming the data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence is divided into first and second word groups. First and second 20-bit word string data having a word transmission rate of 74.25 MBps based on each of them are obtained, and a second 30-bit word string data is obtained. A 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the word string data is converted into a 10-bit word forming the G data sequence and a 10-bit word forming each of the B data sequence and the R data sequence. A third word group including a part of the bit word; and a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. A data processing unit for performing data processing for obtaining third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively, The first to fourth Ps for obtaining the first to fourth serial data based on the first to fourth 20-bit word string data, respectively. / S conversion unit; and a data transmission unit for transmitting the first to fourth serial data for transmission.
A sixteenth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 12 bits and word transmission. In the 36-bit parallel data including the G data sequence, the B data sequence, and the R data sequence at a rate of 148.5 MBps, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored. Is stored in the second memory, and each of the frame part stored in the first memory and the frame part stored in the second memory is converted into a segmented frame digital video signal having a frame rate of 60 Hz. Forming 36-bit parallel data including G data sequence, B data sequence and R data sequence And obtains first and second 36-bit word string data each having a word transmission rate of 74.25 MBps, and obtains a G data sequence, a B data sequence, and an R data sequence included in the first 36-bit word sequence data. The 12-bit word forming each of the series 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 divided B data series and R data series. A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the upper 10 bits of the data, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. , And a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the word transmission rate is 74.2. The second 20-bit word string data of MBps is obtained, and the 12-bit words forming each of the G data series, B data series, and R data series included in the second 36-bit word string data are placed in the upper 10 bits. Word transmission based on a plurality of upper 10 bits divided from a G data sequence and a plurality of upper 10 bits divided from a B data sequence and an R data sequence, respectively. Third 20-bit word string data at a rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, a G data sequence, a B data sequence, A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the R data sequence. A data processing unit for performing data processing for obtaining serial data, and first to fourth P / Ss for obtaining first to fourth serial data based on first to fourth 20-bit word string data, respectively. It comprises a converter and a data transmitter for transmitting the first to fourth serial data for transmission.
A seventeenth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each having a quantization bit number of 12 bits or 14 bits. Alternatively, a Y data sequence having a word transmission rate of 148.5 MBps as 16 bits and P _B / P _R In the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. Then, each of the frame part stored in the first memory and the frame part stored in the second memory is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 60 Hz. _B / P _R First and second 24-bit, 28-bit or 32-bit word strings read out as forming 24-bit, 28-bit or 32-bit parallel data including a data sequence, each of which has a word transmission rate of 74.25 MBps Data, and the Y data sequence and P data included in each of the first 24-bit, 28-bit or 32-bit word string data are obtained. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data having a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. A data processing unit for performing data processing for obtaining 20-bit word string data; and a first to fourth data for obtaining first to fourth serial data based on the first to fourth 20-bit word string data, respectively. It comprises a P / S converter and a data transmitter for transmitting the first to fourth serial data for transmission.
In an eighteenth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame is formed, each of which has a quantization bit number of 12 lines. Y data sequence with word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R For the 24-bit, 28-bit or 32-bit parallel data including the data series, the first alternate frame portion to the first memory, the second alternate frame portion to the second memory, A third alternate frame portion is stored in a third memory, a frame portion stored in a first memory, a frame portion stored in a second memory, and a frame portion stored in a third memory. Are defined as Y data series and P data forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. _B / P _R Read as forming 24-bit, 28-bit, or 32-bit parallel data including a data sequence, and first, second, and third 24-bit, 28-bit, or 32-bit each having a word transmission rate of 74.25 MBps. Word string data is obtained, and the Y data series and P included in each of the first 24-bit, 28-bit or 32-bit word string data are _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A second 20-bit word transmission rate of 74.25 MBps based on first 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits, or 6 bits and auxiliary data; 20-bit word string data, and the Y data series and P included in the second 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A fourth 20.degree. MBps word transmission rate based on third 20-bit word string data at a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. 20-bit word string data, and the Y data series and P included in the third 24-bit, 28-bit or 32-bit word string data, respectively. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and word transmission is performed based on the plurality of divided upper 10 bits. A sixth 20-bit word rate of 74.25 MBps based on fifth 20-bit word string data having a rate of 74.25 MBps, a plurality of divided lower 2 bits, 4 bits or 6 bits, and auxiliary data. A data processing unit for performing data processing for obtaining 20-bit word string data; and a first to sixth data for obtaining first to sixth serial data based on the first to sixth 20-bit word string data, respectively. It comprises a P / S converter and a data transmitter for transmitting the first to sixth serial data for transmission.
In a nineteenth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame is formed, and each has a quantization bit number of 10 lines. For every 30 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory and second The alternate frame portion is stored in the second memory, the third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory and the second frame portion are stored in the second memory. Each of the frame portion stored in the third memory and the frame portion stored in the third memory is set to a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence forming a frame digital video signal, each of which has a word transmission rate of 74.25 MBps, first, second, and third. And a 10-bit word forming each of a G data sequence, a B data sequence, and an R data sequence included in the first 30-bit word sequence data, and a 10-bit word forming a G data sequence. And a first word group including a part of the 10-bit word forming each of the B data sequence and the R data sequence, and forming a 10-bit word forming the auxiliary data sequence and each of the B data sequence and the R data sequence And a second word group including the other part of the 10-bit word, and the first and second word groups. And first and second 20-bit word sequence data having a word transmission rate of 74.25 MBps based on the G data sequence, the B data sequence, and the R data sequence included in the second 30-bit word sequence data. A third word group including a 10-bit word forming each of the data sequences, a 10-bit word forming the G data sequence, and a part of the 10-bit words forming each of the B data sequence and the R data sequence; A third word group including a 10-bit word forming the auxiliary data sequence and a fourth word group including another part of the 10-bit word forming each of the B data sequence and the R data sequence; And third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps, respectively, based on The 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the word sequence data is replaced with the 10-bit word forming the G data sequence and the 10-bit word forming each of the B data sequence and the R data sequence. A fifth word group including a part of the bit word, and a sixth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. A data processing unit for performing data processing for obtaining fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, The first to sixth serial data for obtaining the first to sixth serial data based on the first to sixth 20-bit word string data, respectively. / A S conversion unit, and a data transmitting portion for transmitting the serial data from the first to the sixth.
A twentieth aspect of the data transmission apparatus according to the present invention is a digital video signal in which the frame rate is 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 12 For every 36 bits parallel data including a G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, first and second frame portions are stored in a first memory and second The alternate frame portion is stored in the second memory, and the third alternate frame portion is stored in the third memory. The frame portion stored in the first memory and the second frame portion are stored in the second memory. Of each of the frame part stored in the third memory and the frame part stored in the third memory are segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. It is read as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a frame digital video signal, and each of the first, second, and third data has a word transmission rate of 74.25 MBps. And the 12-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the first 36-bit word sequence data is converted into upper 10 bits and lower 2 bits. The word transmission rate is set to 74.25 MBps based on the plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The first 20-bit word string data and a plurality of upper 10 data divided from each of the B data sequence and the R data sequence 20-bit word string data having a word transmission rate of 74.25 MBps based on another part of the data and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits, A third 20-bit having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The word string data, another part of a plurality of upper 10 bits divided from each of the B data series and the R data series, the G data series, the B data series, and the R data series. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence is obtained, and G included in the third 36-bit word string data is obtained. The 12-bit word forming each of the data sequence, the B data sequence, and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, the B data sequence, and the R data sequence. A fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the data sequences, and a B data sequence and an R data sequence respectively. The other part of the plurality of upper 10 bits and the lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence And a data processing unit for performing data processing for obtaining sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the first to sixth 20-bit word string data. A first P / S converter for obtaining the sixth serial data and a data transmitter for transmitting the first to sixth serial data are provided.
According to a twenty-first aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed, and each of the digital image signals has a quantization bit number of 10 bits. A 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. Each of the frame portion, the frame portion stored in the second memory, the frame portion stored in the third memory, and the frame portion stored in the fourth memory has a frame rate of 30. z, a segmented frame is read out as forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal, and each of the first and second data transmission rates is 74.25 MBps. The second, third, and fourth 30-bit word string data are obtained, and the 10-bit words forming the G data series, B data series, and R data series included in the first 30-bit word string data are represented by G A first word group including a 10-bit word forming a data sequence and a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word and a B data sequence forming an auxiliary data sequence And a second word group including the other part of the 10-bit word forming each of the R data sequences. Dividing, obtaining first and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the first and second word groups, respectively, and G data included in the second 30-bit word string data The 10-bit word forming each of the sequence, the B data sequence, and the R data sequence includes the 10-bit word forming the G data sequence and a part of the 10-bit word forming each of the B data sequence and the R data sequence. The third word group is divided into a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the B data sequence and the R data sequence. Third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. And a 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the third 30-bit word sequence data is replaced with a 10-bit word forming the G data sequence, the B data sequence, and the R data sequence. A fifth word group including a part of the 10-bit word forming each of the data sequences, a 10-bit word forming the auxiliary data sequence, and a 10-bit word forming each of the B data sequence and the R data sequence. And fifth and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, are obtained. Further, a 10-bit word forming each of the G data sequence, the B data sequence, and the R data sequence included in the fourth 30-bit word sequence data , A seventh word group including a 10-bit word forming a G data sequence, a part of a 10-bit word forming each of a B data sequence and an R data sequence, and a 10-bit word and a B forming an auxiliary data sequence. And a word transmission rate of 74.25 Mbps based on the seventh and eighth word groups, respectively. Data processing is performed to obtain seventh and eighth 20-bit word string data, and first to eighth serial data are obtained to obtain first to eighth serial data based on the first to eighth 20-bit word string data, respectively. 8 P / S converters, and a data transmitter for transmitting the first to eighth serial data for transmission.
A twenty-second aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz, an effective number of lines in each frame of 720 lines, and word transmission with each having a quantization bit number of 12 bits. A 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence at a rate of 297 MBps, a first every third frame portion in the first memory, and a second every third frame portion. In the second memory, the third every third frame portion is stored in the third memory, and further, the fourth every third frame portion is stored in the fourth memory, and is stored in the first memory. Each of the frame portion, the frame portion stored in the second memory, the frame portion stored in the third memory, and the frame portion stored in the fourth memory has a frame rate of 3 Hz, and is read out as forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a digital video signal having a frequency of 74.25 MBps. The second, third, and fourth 36-bit word string data are obtained, and the 12-bit words forming the G data series, B data series, and R data series included in the first 36-bit word string data are placed in the upper order. A word that is divided into 10 bits and lower 2 bits, and is based on a plurality of upper 10 bits divided from the G data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. The first 20-bit word string data having a transmission rate of 74.25 MBps and the B data sequence and the R data sequence A word transmission rate of 74.25 MBps based on another part of the plurality of upper 10 bits divided from the G bit sequence and the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. 2 20-bit word string data, and a 12-bit word forming each of the G data series, B data series, and R data series included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. And a word transmission rate of 74.25 Mbps based on a plurality of upper 10 bits divided from the G data sequence and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A third 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and G A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the data sequence, the plurality of lower 2 bits divided from the B data sequence and the R data sequence, and a third 36-bit word The 12-bit word forming each of the G data sequence, B data sequence, and R data sequence included in the column data is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the B data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence; The other part of the plurality of upper 10 bits divided from each of the data sequences and the G data sequence, the B data sequence, and the R data sequence. Sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of lower 2 bits obtained, and further, a G data sequence and B data included in the fourth 36-bit word string data The 12-bit word forming each of the sequence and the R data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and each of the B data sequence and the R data sequence. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the divided plurality of upper 10 bits, and a plurality of upper bits divided from each of the B data sequence and the R data sequence A word transmission based on another part of the 10 bits and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. A data processing unit for performing data processing to obtain eighth 20-bit word string data at a rate of 74.25 MBps; and first to eighth serial data based on the first to eighth 20-bit word string data, respectively. It is provided with first to eighth P / S converters for obtaining data and a data transmitter for transmitting the first to eighth serial data for transmission.
A twenty-third aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits. Y data sequence with word transmission rate of 148.5 MBps and P _B / P _R 30-bit parallel data including a color difference signal data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, The second alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory, and the second alternate frame portion is stored in the first memory and the second memory portion. Each of the stored frame portions is converted into a Y data sequence and a P data which form a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. _B / P _R The data is read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Y data series and P included in 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R Word transmission based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing unit for performing data processing for forming fourth 20-bit word string data having a rate of 74.25 MBps; and first to fourth data processing sections based on the first to fourth 20-bit word string data, respectively. First to fourth P / S converters for obtaining serial data, and data to be transmitted to transmit first to fourth serial data respectively obtained from the first to fourth P / S converters And a sending unit.
A twenty-fourth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits. It has a G data sequence, a B data sequence, and an R data sequence with a word transmission rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps. Storing the first alternate frame portion in the first memory and the second alternate frame portion in the second memory in the 40-bit parallel data including the additional information data sequence Each of the frame portion stored in the first memory and the frame portion stored in the second memory is The data is read as forming 40-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence which form a segmented frame digital video signal having a rate of 25 Hz or 30 Hz. First and second 40-bit word string data having a transmission rate of 74.25 MBps are obtained, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the first 40-bit word sequence data are obtained. A 10-bit word to be formed forms a first word group including a 10-bit word forming a G data sequence, a part of a 10-bit word forming a B data sequence and an R data sequence, and an additional information data sequence. A 10-bit word and a 10-bit word forming a B data sequence and an R data sequence A first 20-bit word string data having a word transmission rate of 74.25 MBps based on the first word group, and a second word group based on the second word group. A second 20-bit word sequence data having a word transmission rate of 74.25 MBps is formed, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the second 40-bit word sequence data And a third word group including a 10-bit word forming a G data sequence, a part of the 10-bit word forming a B data sequence and an R data sequence, and an additional information data sequence. A fourth bit including a 10-bit word to form the B data sequence and another part of the 10-bit word forming the R data sequence. The third 20-bit word string data having a word transmission rate of 74.25 MBps based on the third word group and the fourth word group having a word transmission rate of 74.25 MBps based on the fourth word group. 4, a data processing unit for performing data processing for forming 20-bit word string data, and first to fourth data for obtaining first to fourth serial data based on the first to fourth 20-bit word string data, respectively. 4 P / S converters and a data transmitter for transmitting the first to fourth serial data obtained from the first to fourth P / S converters, respectively. Is done.
According to a twenty-fifth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R A 30-bit parallel data having a data format and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps is added to the first two bits. Storing the alternate frame portions in a first memory, the second alternate frame portions in a second memory, and the third alternate frame portion in a third memory; , A frame part stored in the second memory, and a frame part stored in the third memory, each of which has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Y data series and P _B / P _R Read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and obtain first, second and third 30-bit word string data each having a word transmission rate of 74.25 MBps; Y data series and P included in first 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R A word based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A fourth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the third 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a fifth 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a third 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing section for performing data processing for forming sixth 20-bit word string data having a transmission rate of 74.25 MBps; and first to sixth data processing sections based on the first to sixth 20-bit word string data, respectively. The first to sixth P / S converters for obtaining the first serial data and the first to sixth serial data obtained from the first to sixth P / S converters are transmitted for transmission. And a data transmission unit.
A twenty-sixth aspect of the data transmission apparatus according to the present invention is a digital video signal in which the frame rate is 50 Hz or 60 Hz, the number of effective lines in each frame 6 is 1080, and each has a quantization bit number of 12 bits. , 14 bits or 16 bits, and a Y data sequence with a word transmission rate of 148.5 MBps _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. In a bit or 48-bit parallel data, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory, and is stored in the first memory. And the Y data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz, respectively. _B / P _R It is read as forming 36-bit, 42-bit or 48-bit parallel data including a data sequence and an additional information data sequence, and the first and second 36-bit and 42-bit, respectively, having a word transmission rate of 74.25 MBps. Alternatively, a 48-bit word string data is obtained, and the Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _{R de} First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P data _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Third 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Along with the Y data series, P, contained in the second 36-bit, 42-bit or 48-bit word string data. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. A data processing unit for performing data processing, first to sixth P / S conversion units for obtaining first to sixth serial data based on the first to sixth 20-bit word string data, And a data transmission unit for transmitting the first to sixth serial data obtained from the first to sixth P / S conversion units, respectively. Constructed.
A twenty-seventh aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits. It has a G data sequence, a B data sequence, and an R data sequence with a word transmission rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps. Storing the first alternate frame portion in the first memory and storing the second alternate frame portion in the second memory in the 48-bit parallel data including the additional information data sequence Each of the frame portion stored in the first memory and the frame portion stored in the second memory is Read out as forming 48-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence, which form a segmented frame digital video signal having a rate of 25 Hz or 30 Hz. First and second 48-bit word string data having a transmission rate of 74.25 MBps are obtained, and a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence included in the first 48-bit word string data are obtained. Each 12-bit word to be formed is divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper bits divided from each of the B data sequence and the R data sequence. The first 20 bits having a word transmission rate of 74.25 MBps based on a part of 10 bits And another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence. A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. And G data series, B data series, and R data included in the second 48-bit word string data, which form the third 20-bit word string data having a word transmission rate of 74.25 MBps based on the auxiliary bits of Each 12-bit word forming the sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and divided from the G data sequence. A fourth 20-bit word sequence having a word transmission rate of 74.25 MBps based on the extracted plurality of upper 10 bits and a part of the plurality of upper 10 bits divided from each of the B data sequence and the R data sequence Data, another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence, and a plurality of lower 2 bits divided from the G data sequence, the B data sequence and the R data sequence; Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from an additional information data sequence, and a plurality of auxiliary bits Data to be subjected to data processing for forming a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on bits First to sixth P / S converters for obtaining first to sixth serial data based on the first to sixth 20-bit word string data, respectively, and first to sixth P / S converters. And a data transmission unit for transmitting the first to sixth serial data obtained from the P / S conversion unit.
According to a twenty-eighth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective number of lines of 1080 in each frame is formed, and each of them has a quantization bit number of 10 A G data sequence, a B data sequence, and an R data sequence having a word transmission rate of 222.75 MBps as bits, and a data format equivalent to the G data sequence. The number of quantization bits is 10 bits and the word transmission rate is 222.75 MBps. 40-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the second Each of the frame part stored in the memory and the frame part stored in the third memory is converted into a G data sequence, a B data sequence, and an R data which form a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. Read out as forming 40-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 40-bit word string data, each of which has a word transmission rate of 74.25 Mbps, The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word string data of No. 1 is replaced with the 10-bit word forming the G data sequence, the B data sequence and the R data A first word group comprising a portion of the 10-bit words forming the sequence; The word is divided into a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the B data sequence and the R data sequence, and is based on the first word group. Forming first 20-bit word string data having a transmission rate of 74.25 MBps and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group; The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word sequence data is referred to as the 10-bit word forming the G data sequence, the B data sequence and the R data sequence. A third word group including a part of the 10-bit word to be formed; A bit word is divided into a fourth word group including a bit word and another part of the 10-bit word forming the B data sequence and the R data sequence, and a word transmission rate based on the third word group is determined to be 74.25 MBps. No. 3 20-bit word string data and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fourth word group are included in the third 40-bit word string data. A 10-bit word forming a G data sequence, a B data sequence, an R data sequence, and a part of a 10-bit word forming a G data sequence and a 10-bit word forming a B data sequence and an R data sequence And a 10-bit word forming the additional information data sequence, the B data sequence and R Fifth 20-bit word string data at a word transmission rate of 74.25 MBps based on the fifth word group, which is divided into a sixth word group including another part of the 10-bit word forming the data sequence. And a data processing unit for performing data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the sixth word group, and first to sixth 20-bit words First to sixth P / S converters for obtaining first to sixth serial data based on the respective column data, and first to sixth P / S converters respectively obtained from the first to sixth P / S converters And a data transmission unit for transmitting up to 6 serial data.
A twenty-ninth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective number of lines of 1080 lines in each frame, each of which has a quantization bit number of 10 bits and word transmission. Y data sequence with rate 297 MBps and P _B / P _R The first three sets of 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. Frame portion in the first memory, second every third frame portion in the second memory, third every third frame portion in the third memory, and fourth every third frame portion. Is stored in the fourth memory, and stored in the frame part stored in the first memory, the frame part stored in the second memory, the frame part stored in the third memory, and the fourth memory. Each of the stored frame parts is converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 30 Hz. _B / P _R The data is read out as forming 30-bit parallel data including a data sequence and an additional information data sequence, and first to fourth 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Data series and P data included in the 30-bit word string data of _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R A word based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A fourth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the third 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a fifth 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a third 30-bit word sequence data, and an auxiliary 10-bit word sequence A sixth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the fourth 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a seventh 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a fourth 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing unit for performing data processing for forming eighth 20-bit word string data having a transmission rate of 74.25 MBps; and first to eighth data processing sections based on the first to eighth 20-bit word string data, respectively. The first to eighth P / S converters for obtaining the first serial data and the first to eighth serial data obtained from the first to eighth P / S converters are transmitted for transmission. And a data transmission unit.
According to a thirtieth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 120 Hz and an effective number of lines of 1080 lines in each frame is formed, and each of the digital transmission signals has a quantization bit number of 10 bits. A G data sequence, a B data sequence, and an R data sequence having a rate of 297 MBps; and an additional information data sequence having a data format equivalent to the G data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. In the 40-bit parallel data, the first every third frame portion in the first memory, the second every third frame portion in the second memory, and the third every third frame portion. A third memory, and a fourth every third frame portion stored in the fourth memory, the frame stored in the first memory , A frame part stored in the second memory, a frame part stored in the third memory, and a frame part stored in the fourth memory are each converted into a segmented frame digital video signal having a frame rate of 30 Hz. The data is read out as forming 40-bit parallel data including the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence, each of which has a word transmission rate of 74.25 MBps. The 40-bit word string data is obtained, and the 10-bit words forming the G data series, the B data series, the R data series, and the additional information data series included in the first 40-bit word string data are converted into the G data series. A first word comprising a bit word and a portion of a 10-bit word forming a B data sequence and an R data sequence. And a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the B data sequence and the R data sequence. Forming first 20-bit word string data having a word transmission rate of 74.25 MBps based on a second word group, and second 20-bit word string data having a word transmission rate of 74.25 MBps based on a second word group; The 10-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the second 40-bit word sequence data are replaced with the 10-bit words forming the G data sequence, the B data sequence, and the R data sequence. A third word group including a part of a 10-bit word forming a data sequence; The word transmission rate based on the third word group is divided into a fourth word group including a 10-bit word forming a column and another part of the 10-bit word forming a B data sequence and an R data sequence. Forming a third 20-bit word string data at 74.25 MBps and a fourth 20-bit word string data at a word transmission rate of 74.25 MBps based on the fourth word group; The 10-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the column data are replaced with the 10-bit words forming the G data sequence and the 10-bit words forming the B data sequence and the R data sequence. A fifth word group including a part of a bit word, a 10-bit word forming a side information data sequence, and B And a sixth word group including the other part of the 10-bit word forming the data sequence and the R data sequence, based on the fifth word group and having a word transmission rate of 74.25 MBps based on the fifth word group. A G data sequence which forms bit word string data and sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the sixth word group and is included in the fourth 40-bit word string data , B data sequence, R data sequence, and additional information data sequence, include a 10-bit word forming a G data sequence and a part of a 10-bit word forming a B data sequence and an R data sequence. A seventh word group, a 10-bit word forming an additional information data sequence, and a B data sequence and an R data sequence are formed. A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on the seventh word group and an eighth word group including another part of the 10-bit word. A data processing unit for performing data processing for forming an eighth 20-bit word string data having a word transmission rate of 74.25 and MBps based on the word group; and a first to eighth 20-bit word string data, respectively. First to eighth P / S converters for obtaining first to eighth serial data based on the first and eighth serial data obtained from the first to eighth P / S converters, respectively. And a data transmission unit for transmitting data.
According to a thirty-first aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, and each has a quantization bit number of 12 lines. Data sequence with a word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 222.75 MBps. Bit or 48-bit parallel data, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion. Are stored in a third memory, and each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz. , 25 Hz or 30 Hz segmented frame digital video signal and Y data sequence _B / P _R A 36-bit, 42-bit, or 48-bit parallel data including a data sequence and an additional information data sequence is read out to form parallel data, and each of the first, second, and third 36 bits has a word transmission rate of 74.25 MBps. , 42-bit or 48-bit word string data, and Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits; , Y data series included in the second 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. , Y data series included in the third 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A ninth 20-bit word string data with a word transmission rate of 74.25 MBps is formed based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. A data processing unit for performing data processing, first to ninth P / S conversion units for obtaining first to ninth serial data based on the first to ninth 20-bit word string data, respectively, A data transmission unit for transmitting the first to ninth serial data obtained from the first to ninth P / S conversion units, respectively. Constructed.
According to a thirty-second aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 1080 lines in each frame is formed, and each has a quantization bit number of 12 lines. It has the same data format as the G data sequence, the G data sequence, the B data sequence, and the R data sequence with a word transmission rate of 222.75 MBps as bits, and the word transmission rate with the number of quantization bits being 12 bits. 48-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in a third memory, and the frame portion stored in the first memory, the second Each of the frame part stored in the memory and the frame part stored in the third memory is converted into a G data sequence, a B data sequence and an R data which form a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. Read as forming 48-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 48-bit word string data, each of which has a word transmission rate of 74.25 MBps, Each of the 12-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the 48-bit word sequence data of No. 1 is divided into upper 10 bits and lower 2 bits, and the G data sequence From a plurality of upper 10 bits divided from the B data sequence and the R data sequence First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the divided plurality of upper 10 bits, and a plurality of upper bits divided from each of the B data sequence and the R data sequence A second word rate of 74.25 MBps based on another part of 10 bits, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. And the third 20 bits having a word transmission rate of 74.25 MBps based on the 20-bit word string data and the plurality of upper 10 bits, the plurality of lower 2 bits, and the plurality of auxiliary bits divided from the additional information data sequence G data series, B data series, R data series and additional information included in the second 48-bit word string data. Each 12-bit word forming the data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence and each of the B data sequence and the R data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. Fifth 20-bit having a word transmission rate of 74.25 MBps based on another part, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits Word data based on word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A sixth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the third 48-bit word string data are formed. Each of the 12-bit words to be divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper 10 bits divided from the B data sequence and the R data sequence, respectively. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the bits and another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence And a plurality of lower bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. The word transmission rate is set to 74 based on the eighth 20-bit word string data having a data rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. .25 MBps, a data processing unit for performing data processing for forming ninth 20-bit word string data, and first to ninth serial data based on the first to ninth 20-bit word string data, respectively. A first to ninth P / S converter to be obtained, and a data transmitter for transmitting the first to ninth serial data obtained from the first to ninth P / S converters, respectively. , Is configured.
A thirty-third aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each of which has a quantization bit number of 12 bits and word transmission. A G data sequence, a B data sequence, and an R data sequence having a rate of 297 MBps, and an additional information data sequence having a data format equivalent to the G data sequence, a quantization bit number of 12 bits, and a word transmission rate of 297 MBps. In the 48-bit parallel data, the first every third frame portion in the first memory, the second every third frame portion in the second memory, and the third every third frame portion. A third memory and a fourth every third frame portion stored in the fourth memory, the frame stored in the first memory , A frame part stored in the second memory, a frame part stored in the third memory, and a frame part stored in the fourth memory are respectively converted into segmented frame digital video signals having a frame rate of 30 Hz. The data is read out as forming 48-bit parallel data including the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence, and each of the first to fourth data sets has a word transmission rate of 74.25 MBps. The 48-bit word string data is obtained, and the 12-bit words forming the G data series, B data series, R data series and additional information data series included in the first 48-bit word string data are divided into upper 10 bits and lower 2 bits. And a plurality of upper 10 bits divided from the G data sequence, a B data sequence and an R data First 20-bit word string data having 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 each of the B data series and the R data series are divided. A word transmission rate of 74.25 Mbps based on another part of the plurality of upper 10 bits, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. And a second 20-bit word string data, and a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. 3 G data series, B data series, and R data included in the second 48-bit word string data. Each 12-bit word forming the sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence, and a B data sequence and an R data sequence, respectively. , A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from a plurality of upper 10 bits, and a plurality of B data sequences and R data sequences respectively divided. A word transmission rate of 74.25 MBps based on another part of the upper 10 bits, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. 5, 20-bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence G data sequence, B data sequence, R data sequence and additional information included in the third 48-bit word sequence data, which form the sixth 20-bit word sequence data having a word transmission rate of 74.25 MBps based on Each 12-bit word forming the data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence and each of the B data sequence and the R data sequence. A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence Based on another part, a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. Word transmission based on eighth 20-bit word string data having a word transmission rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A ninth 20-bit word string data having a rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the fourth 48-bit word string data are formed. 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 sequence and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of And another part of the plurality of upper 10 bits divided from each of the R data sequence, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word based on eleventh 20-bit word string data having a word transmission rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence A data processing unit for performing data processing for forming twelfth 20-bit word string data having a transmission rate of 74.25 MBps; and first to twelfth based on the first to twelfth 20-bit word string data, respectively. First to twelfth P / S converters for obtaining serial data of the first and twelfth P / S converters respectively obtained from the first to twelfth P / S converters. A data transmitting portion for transmitting the serial data to 2, and includes a.
A thirty-fourth aspect of the data transmission apparatus according to the present invention provides a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 10 bits. Y data sequence with a rate of 148.5 MBps and P _B / P _R The first one of 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. Storing alternate frame portions in the first memory and storing second alternate frame portions in the second memory; storing the alternate frame portions in the first memory and the second memory; The Y data sequence and the P data forming a segmented frame digital video signal having a frame rate of 60 Hz _B / P _R The data is read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Y data series and P included in 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R Word transmission based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing unit for performing data processing for forming fourth 20-bit word string data having a rate of 74.25 MBps; and first to fourth data processing sections based on the first to fourth 20-bit word string data, respectively. It comprises first to fourth P / S converters for obtaining serial data, and a data transmitter for transmitting the first to fourth serial data for transmission.
A thirty-fifth aspect of the data transmission apparatus according to the present invention forms a digital video signal in which the frame rate is 120 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 10 bits. G data sequence, B data sequence, and R data sequence having a rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps added In the 40-bit parallel data including the information data sequence, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. Each of the frame part stored in the memory and the frame part stored in the second memory has a frame rate of 60 Hz. And read out as forming 40-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence, which form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. The first and second 40-bit word string data are obtained, and the 10-bit words forming the G data sequence, B data sequence, R data sequence, and additional information data sequence included in the first 40-bit word string data are A first word group including a 10-bit word forming a G data sequence, a part of a 10-bit word forming a B data sequence and an R data sequence, and a 10-bit word and a B data sequence forming an additional information data sequence And another portion of the 10-bit word forming the R data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on the first word group and a second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group. 2 20-bit word string data and a 10-bit word forming a G data series, a B data series, an R data series, and an additional information data series included in the second 40-bit word string data. A third word group including a 10-bit word forming a sequence and a part of a 10-bit word forming a B data sequence and an R data sequence; a 10-bit word forming a side information data sequence, a B data sequence and an R data sequence; A fourth word group including the other part of the 10-bit word forming the data sequence; A third 20-bit word string data having a word transmission rate of 74.25 MBps based on a fourth word group, and a fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a fourth word group. And a first to fourth P / S converter for obtaining first to fourth serial data based on the first to fourth 20-bit word string data, respectively. And a data transmission unit for transmitting the first to fourth serial data for transmission.
A thirty-sixth aspect of the data transmission apparatus according to the present invention provides a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame, each of which has a quantization bit number of 10 lines. Y data sequence with word transmission rate of 222.75 MBps as bits and P _B / P _R A 30-bit parallel data having a data format and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps is added to the first two bits. Storing the alternate frame portions in a first memory, the second alternate frame portions in a second memory, and the third alternate frame portion in a third memory; , A frame part stored in the second memory, and a frame part stored in the third memory, each of which has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Y data series and P _B / P _R Read as forming 30-bit parallel data including a data sequence and an additional information data sequence, and obtain first, second and third 30-bit word string data each having a word transmission rate of 74.25 MBps; Y data series and P included in first 30-bit word string data _B / P _R A word based on a first 20-bit word string data having a word transmission rate of 74.25 MBps based on a data series, an additional information data series included in the first 30-bit word string data, and an auxiliary 10-bit word string A second 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the second 30-bit word string data are formed. _B / P _R A word based on a data sequence based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word sequence data, and an auxiliary 10-bit word sequence A fourth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and the Y data series and P included in the third 30-bit word string data are formed. _B / P _R A word based on a data sequence based on a fifth 20-bit word sequence data having a word transmission rate of 74.25 MBps, an additional information data sequence included in a third 30-bit word sequence data, and an auxiliary 10-bit word sequence A data processing section for performing data processing for forming sixth 20-bit word string data having a transmission rate of 74.25 MBps; and first to sixth data processing sections based on the first to sixth 20-bit word string data, respectively. The first to sixth P / S converters for obtaining the first to sixth serial data, and the data transmitter for transmitting the first to sixth serial data for transmission.
A thirty-seventh aspect of the data transmission apparatus according to the present invention provides a digital video signal in which the frame rate is 120 Hz and the number of effective lines in each frame is 720, and the number of quantization bits is 12 bits and 14 bits, respectively. Alternatively, a Y data sequence having a word transmission rate of 148.5 MBps as 16 bits and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. In a bit or 48-bit parallel data, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory, and is stored in the first memory. The frame data stored in the second memory and the frame data stored in the second memory are respectively converted into a Y data sequence and a P data forming a segmented frame digital video signal having a frame rate of 60 Hz. _B / P _R It is read as forming 36-bit, 42-bit or 48-bit parallel data including a data sequence and an additional information data sequence, and the first and second 36-bit and 42-bit, respectively, having a word transmission rate of 74.25 MBps. Alternatively, a 48-bit word string data is obtained, and the Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Third 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. Along with the Y data series, P, contained in the second 36-bit, 42-bit or 48-bit word string data. _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on the divided plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. A data processing unit for performing data processing, first to sixth P / S conversion units for obtaining first to sixth serial data based on the first to sixth 20-bit word string data, And a data transmission unit for transmitting the first to sixth serial data for transmission.
A thirty-eighth aspect of the data transmission apparatus according to the present invention forms a digital video signal having a frame rate of 120 Hz, an effective line number of 720 lines in each frame, and a word transmission with each having a quantization bit number of 12 bits. A G data sequence, a B data sequence, and an R data sequence with a rate of 148.5 MBps, and a data format equivalent to the G data sequence, with a 12-bit quantization bit rate and a word transmission rate of 148.5 MBps In the 48-bit parallel data including the information data sequence, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. Each of the frame part stored in the memory and the frame part stored in the second memory has a frame rate of 60 Hz. And read out as forming 48-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and an additional information data sequence, which form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. First and second 48-bit word string data are obtained, and each of the 12-bit words forming the G data series, B data series, R data series and additional information data series included in the first 48-bit word string data is obtained. , Divided into upper 10 bits and lower 2 bits, and divided into a plurality of upper 10 bits divided from the G data sequence and a part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. 20-bit word string data having a word transmission rate of 74.25 MBps based on And another part of the plurality of upper 10 bits divided from each of the R data sequence, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word based on second 20-bit word string data having a word transmission rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence A third 20-bit word string data having a transmission rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the second 48-bit word string data are formed. Each of the 12-bit words to be divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence; A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the data sequence and the R data sequence, and a B data sequence and an R data sequence Word transmission based on another part of the plurality of upper 10 bits divided from each of the above, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word transmission rate of 74 based on fifth 20-bit word string data having a rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A data processing unit for performing data processing for forming a sixth 20-bit word string data of .25 MBps; A first to sixth P / S converter for obtaining first to sixth serial data based on the respective word string data, and a data transmitter for transmitting the first to sixth serial data. It is comprised including.
A thirty-ninth aspect of the data transmission apparatus according to the present invention provides a digital video signal in which the frame rate is 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the number of quantization bits is 10 A G data sequence, a B data sequence, and an R data sequence with a word transmission rate of 222.75 MBps as bits, and a data format equivalent to the G data sequence, with a quantization bit number of 10 bits and a word transmission rate of 222.75 MBps. 40-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the second A G data sequence, a B data sequence and an R data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz, respectively, for each of the frame part stored in the memory and the frame part stored in the third memory. Read out as forming 40-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 40-bit word string data, each of which has a word transmission rate of 74.25 Mbps, The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word string data of No. 1 is replaced with the 10-bit word forming the G data sequence, the B data sequence and the R data A first group of words comprising a portion of the 10-bit words forming the sequence; The word is divided into a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the B data sequence and the R data sequence, and based on the first word group, Forming first 20-bit word string data having a transmission rate of 74.25 MBps and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group; The 10-bit word forming the G data sequence, the B data sequence, the R data sequence and the additional information data sequence included in the 40-bit word sequence data is referred to as the 10-bit word forming the G data sequence, the B data sequence and the R data sequence. A third word group including a part of the 10-bit word to be formed; And a fourth word group including the other word and the other part of the 10-bit word forming the B data sequence and the R data sequence. The third word group is based on the third word group and has a word transmission rate of 74.25 MBps. And the fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fourth word group, and G included in the third 40-bit word string data. A 10-bit word forming a data sequence, a B data sequence, an R data sequence, and an additional information data sequence is defined as a 10-bit word forming a G data sequence and a part of a 10-bit word forming a B data sequence and an R data sequence. , A 10-bit word forming an additional information data sequence, a B data sequence and an R data sequence. And a fifth 20-bit word string data that is distributed to a sixth word group including another part of the 10-bit word forming the data sequence and that has a word transmission rate of 74.25 MBps based on the fifth word group. A data processing unit for performing data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the sixth word group, and first to sixth 20-bit word strings A first to sixth P / S converter for obtaining first to sixth serial data based on the respective data, and a data transmitter for transmitting the first to sixth serial data for transmission are provided. It is composed.
According to a fortieth aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz, or 90 Hz and an effective line number of 720 lines in each frame is formed, and each of them has a quantization bit number of 12 lines. Y data sequence with word transmission rate of 222.75 MBps as bits, 14 bits or 16 bits, and P _B / P _R 36 bits, 42 bits including a data sequence and an additional information data sequence having a data format equivalent to that of the Y data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 222.75 MBps. Bit or 48-bit parallel data, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion. Are stored in a third memory, and each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz. , 25 Hz or 30 Hz segmented frame digital video signal and Y data sequence _B / P _R A 36-bit, 42-bit, or 48-bit parallel data including a data sequence and an additional information data sequence is read out to form parallel data, and each of the first, second, and third 36 bits has a word transmission rate of 74.25 MBps. , 42-bit or 48-bit word string data, and Y data series, P included in the first 36-bit, 42-bit or 48-bit word string data, _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, Y data sequence and P _B / P _R A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits; , Y data series included in the second 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence Forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. , Y data series included in the third 36-bit, 42-bit or 48-bit word string data, P _B / P _R Each 12-bit, 14-bit, or 16-bit word forming each of the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits to form a Y data sequence and a P data. _B / P _R A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the data sequence, a Y data sequence and P _B / P _R Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the data sequence, and an additional information data sequence A ninth 20-bit word string data with a word transmission rate of 74.25 MBps is formed based on the plurality of divided upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits. A data processing unit for performing data processing, first to ninth P / S conversion units for obtaining first to ninth serial data based on the first to ninth 20-bit word string data, respectively, And a data transmission unit for transmitting the first to ninth serial data for transmission.
According to a forty-first aspect of the data transmission apparatus according to the present invention, a digital video signal having a frame rate of 72 Hz, 75 Hz or 90 Hz and an effective line number of 720 lines in each frame is formed. It has the same data format as the G data sequence, the G data sequence, the B data sequence, and the R data sequence with a word transmission rate of 222.75 MBps as bits, and the word transmission rate with the number of quantization bits being 12 bits. 48-bit parallel data including an additional information data sequence of 75 MBps, a first alternate frame portion in a first memory, a second alternate frame portion in a second memory, and The third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the second A G data sequence, a B data sequence and an R data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz, respectively, for each of the frame part stored in the memory and the frame part stored in the third memory. Read as forming 48-bit parallel data including a stream and an additional information data stream, and obtain first, second and third 48-bit word string data, each of which has a word transmission rate of 74.25 MBps, Each of the 12-bit words forming the G data sequence, the B data sequence, the R data sequence, and the additional information data sequence included in the 48-bit word sequence data of No. 1 is divided into upper 10 bits and lower 2 bits, and the G data sequence From the plurality of upper 10 bits divided from the B data sequence and the R data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits thus obtained, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence. A second transmission rate of 74.25 MBps based on another part of the bits, a plurality of lower two bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits; A third 20-bit word having a word transmission rate of 74.25 MBps based on 20-bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence And G data series, B data series, R data series and additional information data included in the second 48-bit word string data. Each 12-bit word forming the data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the G data sequence and each of the B data sequence and the R data sequence. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits, and a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence A fifth transmission rate of 74.25 MBps based on the other part, the plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and the plurality of auxiliary bits. A word based on bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence A sixth 20-bit word string data having a transmission rate of 74.25 MBps is formed, and a G data series, a B data series, an R data series, and an additional information data series included in the third 48-bit word string data are formed. Each of the 12-bit words to be divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the G data sequence, and a plurality of upper 10 bits divided from the B data sequence and the R data sequence, respectively. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the bits and another part of a plurality of upper 10 bits divided from each of the B data sequence and the R data sequence And a plurality of lower 2 bits divided from the G data sequence, the B data sequence, and the R data sequence, and a plurality of auxiliary bits. The word transmission rate is set to 74.25 MBps based on the eighth 20-bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A data processing unit for performing data processing for forming ninth 20-bit word string data of 25 MBps, and obtaining first to ninth serial data based on the first to ninth 20-bit word string data, respectively; It comprises a first to ninth P / S converter and a data transmitter for transmitting the first to ninth serial data for transmission. −
In any of the first to eleventh aspects of the data transmission method according to the present invention as described above, or in any of the first to eleventh aspects of the data transmission apparatus according to the present invention, first, A digital video signal of 4: 2: 2 format or 4: 4: 4 format having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz or 120 Hz is formed, each having a word transmission rate of 148.5 MBps, 222.75 MBps or 297 MBps, and a Y data sequence and a P bit with a quantization bit number of 10, 12, 14, or 16 bits. _B / P _R Processing for storing first and second alternate frame parts in the first and second memories for the data series or the G data series, the B data series, and the R data series, respectively, And storing the third and third alternate frame portions in the first, second and third memories, respectively, or the first, second, third and fourth alternate frame portions in the first, second and third memory portions, respectively. The processing for storing in the first, second, third and fourth memories is performed.
Next, the frame units stored in the first and second memories, the first, second, and third memories, or the first, second, third, and fourth memories, respectively, are read, and each of them is read out. A plurality of 20-bit word string data, a 24-bit word string data, a 28-bit word string data, a 30-bit word string data, a 32-bit word string data, or a 36-bit word string data having a word transmission rate of 74.25 MBps are formed.
Subsequently, when a plurality of 20-bit word string data are formed, each of them is converted into serial data and transmitted. On the other hand, when a plurality of 24-bit word string data, 28-bit word string data, 30-bit word string data, 32-bit word string data, or 36-bit word string data are formed, each of them sets the word transmission rate. The data is converted into two 20-bit word string data of 74.25 MBps, and a plurality of the obtained 20-bit word string data are converted into serial data and transmitted.
The processing for a plurality of 20-bit word string data, each of which has a word transmission rate of 74.25 MBps, and the processing for converting each of them into serial data and transmitting the serial data are performed on digital data forming a conventional digital video signal. This is a process that can be performed using existing circuit components used for serial transmission according to HD SDI.
Therefore, according to any one of the first to eleventh aspects of the data transmission method according to the present invention, or according to any one of the first to eleventh aspects of the data transmission apparatus according to the present invention, D-Cinema in a broad sense A digital video signal of a 4: 2: 2 format or a 4: 4: 4 format having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like, including a signal or a D-Cinema signal system double-speed digital video signal or the like. The transmission of digital data can be appropriately realized, for example, by utilizing existing circuit components used for serial transmission according to HD SDI.
In any one of the twelfth to twenty-second aspects of the data transmission method according to the present invention, or any one of the twelfth to twenty-second aspects of the data transmission apparatus according to the present invention, first, the frame rate Are 72 Hz, 75 Hz, 90 Hz or 120 Hz, and digital video signals of 4: 2: 2 format or 4: 4: 4 format are formed, each having a word transmission rate of 148.5 MBps, 222.75 MBps or 297 MBps, and a quantization bit rate of A Y data sequence whose number is 10, 12, 14, or 16 bits and P _B / P _R Processing for storing first and second alternate frame parts in the first and second memories for the data series or the G data series, the B data series, and the R data series, respectively, And storing the third and third alternate frame portions in the first, second and third memories, respectively, or the first, second, third and fourth alternate frame portions in the first, second and third memory portions, respectively. The processing for storing in the first, second, third and fourth memories is performed.
Next, the frame units stored in the first and second memories, the first, second, and third memories, or the first, second, third, and fourth memories, respectively, are read, and each of them is read out. A plurality of 20-bit word string data, a 24-bit word string data, a 28-bit word string data, a 30-bit word string data, a 32-bit word string data, or a 36-bit word string data having a word transmission rate of 74.25 MBps are formed.
Subsequently, when a plurality of 20-bit word string data are formed, each of them is converted into serial data and transmitted. On the other hand, when a plurality of 24-bit word string data, 28-bit word string data, 30-bit word string data, 32-bit word string data, or 36-bit word string data are formed, each of them sets the word transmission rate. The data is converted into two 20-bit word string data of 74.25 MBps, and a plurality of the obtained 20-bit word string data are converted into serial data and transmitted.
The processing for a plurality of 20-bit word string data, each of which has a word transmission rate of 74.25 MBps, and the processing for converting each of them into serial data and transmitting the serial data are performed on digital data forming a conventional digital video signal. This is a process that can be performed using existing circuit components used for serial transmission according to HD SDI.
Therefore, according to any one of the twelfth to twenty-second aspects of the data transmission method according to the present invention or any one of the twelfth to twenty-second aspects of the data transmission apparatus according to the present invention, the 720P signal system double speed digital Transmission of digital data forming a digital video signal of 4: 2: 2 format or 4: 4: 4 format having a frame rate of 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like, including a video signal, is performed by, for example, HD SDI. Appropriate realization can be achieved by utilizing existing circuit components used for the serial transmission according to the present invention.
In any one of the twenty-third to thirty-third aspects of the data transmission method according to the present invention, or any one of the twenty-third to thirty-third aspects of the data transmission apparatus according to the present invention, first, the frame rate is set to 50 Hz. , 60 Hz, 72 Hz, 75 Hz, 90 Hz or 120 Hz to form a digital video signal of 4: 2: 2 format or 4: 4: 4 format, each having a word transmission rate of 148.5 MBps, 222.75 MBps or 297 MBps, and Data sequence with 10 bits, 12 bits, 14 bits or 16 bits _B / P _R A data sequence, or a G data sequence, a B data sequence, and an R data sequence, and a Y data sequence or an additional information data sequence having a data format equivalent to the G data sequence, And P _B / P _R The first and second alternate frame portions are stored in the first and second memories, respectively, based on the data sequence, or the G data sequence, the B data sequence, and the R data sequence. Processing, storing the first, second and third alternate frame portions in the first, second and third memories, respectively, or processing the first, second, third and fourth three A process of storing the other frame units in the first, second, third, and fourth memories, respectively, is performed.
Next, the frame units stored in the first and second memories, the first, second, and third memories, or the first, second, third, and fourth memories, respectively, are read, and each of them is read out. A plurality of 30-bit word string data, 36-bit word string data, 40-bit word string data, 42-bit word string data, or 48-bit word string data having a word transmission rate of 74.25 MBps are formed.
Subsequently, when a plurality of 30-bit word string data, 36-bit word string data, 40-bit word string data, 42-bit word string data, or 48-bit word string data are formed, each of them is converted into a word transmission rate. Is converted to two or three 20-bit word string data of 74.25 MBps, and a plurality of 20-bit word string data obtained thereby are converted into serial data and transmitted.
The processing for a plurality of 20-bit word string data, each of which has a word transmission rate of 74.25 MBps, and the processing for converting each of them into serial data and transmitting the serial data are performed on digital data forming a conventional digital video signal. This is a process that can be performed using existing circuit components used for serial transmission according to HD SDI.
Therefore, according to any one of the twenty-third to thirty-third aspects of the data transmission method according to the present invention, or any one of the twenty-third to thirty-third aspects of the data transmission apparatus according to the present invention, D-Cinema in a broad sense A digital video signal of a 4: 2: 2 format or a 4: 4: 4 format having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like, including a signal or a D-Cinema signal system double-speed digital video signal or the like. According to HD SDI, for example, the transmission of the digital data and the related Key signal data sequence is performed with the Key signal data sequence being an additional information data sequence attached to the digital data forming the digital video signal to be transmitted. It can be implemented properly using existing circuit components used for serial transmission. Wear.
Further, in any one of the thirty-fourth to forty-first aspects of the data transmission method according to the present invention, or any one of the thirty-fourth to forty-first aspects of the data transmission apparatus according to the present invention, first, the frame rate Are 72 Hz, 75 Hz, 90 Hz or 120 Hz to form a digital video signal of 4: 2: 2 format or 4: 4: 4 format, each of which has a word transmission rate of 148.5 MBps or 222.75 MBps and a quantization bit number of Y data sequence of 10 bits, 12 bits, 14 bits or 16 bits and P _B / P _R A data sequence, or a G data sequence, a B data sequence, and an R data sequence, and a Y data sequence or an additional information data sequence having a data format equivalent to the G data sequence, And P _B / P _R The first and second alternate frame portions are stored in the first and second memories, respectively, based on the data sequence, or the G data sequence, the B data sequence, and the R data sequence. Processing or processing for storing every second, third, and third frame portions in the first, second, and third memories, respectively.
Next, the frame portions stored in the first and second memories or the first, second, and third memories are read, and a plurality of 30-bit word string data each having a word transmission rate of 74.25 MBps are read. , 36-bit word string data, 40-bit word string data, 42-bit word string data, or 48-bit word string data.
Subsequently, when a plurality of 30-bit word string data, 36-bit word string data, 40-bit word string data, 42-bit word string data, or 48-bit word string data are formed, each of them is converted into a word transmission rate. Is converted to two or three 20-bit word string data of 74.25 MBps, and a plurality of 20-bit word string data obtained thereby are converted into serial data and transmitted.
The processing for a plurality of 20-bit word string data, each of which has a word transmission rate of 74.25 MBps, and the processing for converting each of them into serial data and transmitting the serial data are performed on digital data forming a conventional digital video signal. This is a process that can be performed using existing circuit components used for serial transmission according to HD SDI.
Therefore, according to any one of the thirty-fourth to forty-first aspects of the data transmission method according to the present invention or any one of the thirty-fourth to forty-first aspects of the data transmission apparatus according to the present invention, the 720P signal system double-speed digital A digital data comprising a 4: 2: 2 format or 4: 4: 4 format digital video signal having a frame rate of 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like, including a video signal, and a key signal data sequence related thereto. Using existing circuit components used for serial transmission in accordance with HD SDI, for example, in a state in which a Key signal data sequence is converted into an additional information data sequence attached to digital data forming a digital video signal to be transmitted. Then, it can be realized appropriately.
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 5 includes the first example of the first or twelfth aspect of the data transmission apparatus according to the present invention, in which the example of the first or twelfth aspect of the data transmission method according to the present invention is implemented. 1 shows a data transmission / reception device.
In the data transmission / reception device shown in FIG. 5, digital data DVX forming a digital video signal is supplied to the data processing unit 11 on the transmission side constituting an example of the data transmission device according to the present invention.
The digital data DVX is data shown as DVC10 in FIG. 3 or data shown as DTU10 in FIG.
When the digital data DVX is data shown as DVC 10 in FIG. 3, the data processing unit 11 sets the frame rate to 50 Hz or 60 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is A Y data sequence and a Y data sequence each forming a 4: 2: 2 format digital video signal set to 1920 samples, each having a word transmission rate of 148.5 MBps and a quantization bit number of 10 bits. _B / P _R A data series is input.
When the digital data DVX is data indicated as DTU 10 in FIG. 4, the data processing unit 11 sets the frame rate to 120 Hz, the number of valid lines in each frame is 720, and the number of valid data samples in each line is A Y data sequence having a digital transmission signal of 4: 2: 2 format set to 1280 samples, each having a word transmission rate of 148.5 MBps and a quantization bit number of 10 bits, and P _B / P _R A data series is input.
These data DVC10 or DTU10 form a Y data series and P _B / P _R As shown in FIG. 6, the data sequence is supplied to the data processing unit 11 as 20-bit parallel data having a word transmission rate of 148.5 MBps, which is obtained by performing parallel multiplexing under the condition of frame synchronization and line synchronization. Is done.
The data processing unit 11 performs the following processing on the data DVC10 or DTU10 supplied as shown in FIG.
First, as shown in FIG. 6, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVC 10 is Frame 1, Frame 3, Frame 5. ,... And the second alternate frame portions Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a Y data sequence and P having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 3, Segmented Frame 5,..., Of 120 Hz / 2 = 60 Hz, forming a segmented frame digital video signal _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVC10A or DTU10A having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. Y data sequence and segmented frame digital video signal having segmented frame 2, Segmented Frame 4, Segmented Frame 6,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVC10B or DTU10B having a word transmission rate of 74.25 MBps.
As shown in FIG. 7A, the 20-bit word string data DVC10A or DTU10A is composed of 10-bit words YD0, YD1, YD2, YD3,. _B / P _R A 10-bit word PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting a data sequence is parallel-multiplexed and formed as a link A. As shown in FIG. 7B, the 20-bit word string data DVC10B or DTU10B also includes 10-bit words YD0, YD1, YD2, YD3,... _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are parallel-multiplexed and formed as a link B.
That is, in the data processing unit 11, the data DVC10 or DTU10 forming the 20-bit word string data having the word transmission rate of 148.5 MBps is converted to the 20-bit word string data having the word transmission rate of 74.25 MBps. The data is converted into two-system word string data of DVC10A and DVC10B or DTU10A and DTU10B. Then, the data processing unit 11 derives a set of 20-bit word string data DVC10A and DVC10B or a set of 20-bit word string data DTU10A and DTU10B as a set of 20-bit word string data DPA (20) and DPB (20). .
The 20-bit word string data DPA (20) with a word transmission rate of 74.25 MBps sent from the data processing unit 11 is supplied to the data insertion unit 12. The data insertion unit 12 inserts auxiliary data DAA including channel identification data as needed into the 20-bit word string data DPA (20), and the 20-bit word string data DPA 'into which the auxiliary data DAA has been inserted. (20) is formed. The 20-bit word string data DPA ′ (20) obtained from the data insertion unit 12 is supplied to the P / S conversion unit 13.
The P / S conversion unit 13 performs P / S conversion on the 20-bit word string data DPA '(20) to increase the bit transmission rate based on the 20-bit word string data DPA' (20) to 74.25 MBps × The serial data DSA with 20 = 1.485 Gbps is formed, and the serial data DSA is supplied to the electro-optical converter (E / O converter) 14.
The E / O converter 14 performs an electro-optical conversion process on the serial data DSA, and converts the optical signal OSA having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSA to a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
On the other hand, the 20-bit word string data DPB (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 11 is supplied to the data insertion unit 15. The data insertion unit 15 inserts the auxiliary data DAB including the necessary channel identification data into the 20-bit word string data DPB (20), and the 20-bit word string data DPB ′ into which the auxiliary data DAB has been inserted. (20) is formed. The 20-bit word string data DPB ′ (20) obtained from the data insertion unit 15 is supplied to the P / S conversion unit 16.
The P / S conversion section 16 performs P / S conversion on the 20-bit word string data DPB '(20) to increase the bit transmission rate based on the 20-bit word string data DPB' (20) to 74.25 Mbps. The serial data DSB having 20 = 1.485 Gbps is formed, and the serial data DSB is supplied to the E / O converter 17.
The E / O conversion unit 17 performs an electro-optical conversion process on the serial data DSB to convert an optical signal OSB having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSB into a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
Under these circumstances, the E / O conversion units 14 and 17 form a data transmission unit that transmits the serial data DSA and DSB obtained from the P / S conversion units 13 and 16, respectively, for transmission.
The optical signal OSA, which is a transmission signal transmitted from the E / O converter 14, is guided to the optical fiber transmission line 19 through the optical connector 18 and transmitted to the receiving side through the optical fiber transmission line 19. The optical signal OSB, which is a transmission signal transmitted from the E / O conversion unit 17, is guided to the optical fiber transmission line 21 through the optical connector 20, and is transmitted to the receiving side through the optical fiber transmission line 21. Each of the optical fiber transmission paths 19 and 21 is formed using, for example, a quartz single mode fiber (silica SMF).
On the receiving side, the optical signal OSA transmitted through the optical fiber transmission line 19 is guided to the photoelectric conversion unit (O / E conversion unit) 23 through the optical connector 22. The optical signal OSB transmitted through the optical fiber transmission line 21 is guided to the O / E converter 25 through the optical connector 24.
The O / E converter 23 performs a photoelectric conversion process on the optical signal OSA having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OSA. 1. Reproduce serial data DSA at 485 Gbps. Then, the reproduced serial data DSA is supplied to the serial / parallel (S / P) converter 26.
The S / P conversion unit 26 performs S / P conversion on the serial data DSA to reproduce 20-bit word string data DPA ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSA. Then, it is supplied to the data separation unit 28. In the data separation unit 28, the auxiliary data DAA is separated from the 20-bit word string data DPA '(20), and the 20-bit word string data DPA (20) and the auxiliary data DAA are separately transmitted. The bit word string data DPA (20) is supplied to the data time difference absorbing unit 29.
In the O / E converter 25, the optical signal OSB having a center wavelength of about 1.3 μm and a bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing to perform bit transmission based on the optical signal OSB. The serial data DSB whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSB is supplied to the S / P converter 30.
The S / P conversion unit 30 performs S / P conversion on the serial data DSB to reproduce 20-bit word string data DPB ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSB. Then, it is supplied to the data separation unit 31. In the data separation unit 31, the auxiliary data DAB is separated from the 20-bit word string data DPB '(20), and the 20-bit word string data DPB (20) and the auxiliary data DAB are separately transmitted. The bit word string data DPB (20) is supplied to the data time difference absorbing unit 29.
In the data time difference absorbing section 29, the mutual time difference generated between the 20-bit word string data DPA (20) from the data separating section 28 and the 20-bit word string data DPB (20) from the data separating section 31 is calculated. The 20-bit word string data DPAQ (20) that absorbs and sets the word transmission rate based on the 20-bit word string data DPA (20) to 74.25 MBps, and the word transmission rate based on the 20-bit word string data DPB (20) is 74 The data and the 20-bit word string data DPBQ (20) of .25 MBps are transmitted as being intended to be maintained in a state where there is substantially no mutual time difference.
The 20-bit word string data DPAQ (20) and DPBQ (20) obtained from the data time difference absorption unit 29 are supplied to the data reproduction processing unit 32. In the data reproduction processing section 32, the data conversion processing applied to the digital data DVX by the data processing section 11 on the transmission side is performed on the 20-bit word string data DPAQ (20) and DPBQ (20). A data reproduction process is performed to reproduce digital data DVX based on the 20-bit word string data DPAQ (20) and DPBQ (20). Such digital data DVX is data shown as DVC10 in FIG. 3 or data shown as DTU10 in FIG.
FIG. 8 includes a second example that forms the first or twelfth aspect of the data transmission apparatus according to the present invention, in which the example that forms the first or twelfth aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the data transmission / reception device.
The data transmission / reception device whose part is shown in FIG. 8 has many parts configured in the same way as the data transmission / reception device shown in FIG. 5, and FIG. 8 shows parts different from the data transmission / reception device shown in FIG. And only relevant parts are shown.
In the data transmission / reception device whose part is shown in FIG. 8, instead of the E / O conversion units 14 and 17 and the O / E conversion units 23 and 25 provided in the data transmission / reception device shown in FIG. An E / O converter 43 and an O / E converter 48 are provided. Further, instead of the optical connectors 18 and 20, the optical fiber transmission lines 19 and 21, and the optical connectors 22 and 24 provided in the data transmitting / receiving apparatus shown in FIG. 5, an optical connector 45, an optical fiber transmission line 46, and an optical connector are used. 47 are provided. The optical fiber transmission path 46 is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 8, the serial data DSA whose bit transmission rate from the P / S conversion unit 13 is 1.485 Gbps and the bit transmission rate from the P / S conversion unit 16 is 1. The serial data DSB of 485 Gbps is supplied to the bit multiplexing unit 42. The bit multiplexing unit 42 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSA and DSB, performing a bit multiplexing / combining process on the serial data DSA and DSB, and reducing the bit transmission rate. The composite serial data DZV with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZV obtained from the bit multiplexing unit 42 is supplied to the E / O conversion unit 43. In the E / O converter 43, an optical signal OZV having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZV is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal. Under such circumstances, the bit multiplexing unit 42 and the E / O conversion unit 43 form a data transmission unit that transmits the serial data DSA and DSB obtained from the P / S conversion units 13 and 16, respectively, for transmission. .
The optical signal OZV, which is a transmission signal transmitted from the E / O converter 43, is guided to the optical fiber transmission line 46 through the optical connector 45, and is transmitted to the receiving side through the optical fiber transmission line 46.
On the receiving side, the optical signal OZV transmitted through the optical fiber transmission line 46 is guided to the O / E converter 48 through the optical connector 47. The O / E converter 48 performs a photoelectric conversion process on the optical signal OZV having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and adjusts the bit transmission rate based on the optical signal OZV. 2. Reproduce composite serial data DZV at 2.97 Gbps. Then, the reproduced composite serial data DZV is supplied to the bit separation unit 49.
The bit separation unit 49 performs an operation of taking out one bit at a time from the composite serial data DZV to form every other two bit groups, and performs bit separation processing on the composite serial data DZV. Then, a channel is specified by using the channel identification data included in the composite serial data DZV, and based on the composite serial data DZV, a 2-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. Form data DSA and DSB. The serial data DSA is supplied to the S / P converter 26, and the serial data DSB is supplied to the S / P converter 30. Other operations are the same as those of the data transmitting / receiving apparatus shown in FIG.
FIG. 9 includes a third example that implements the first or twelfth aspect of the data transmission apparatus according to the present invention, in which the example that implements the first or twelfth aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the data transmission / reception device.
The data transmission / reception device whose part is shown in FIG. 9 also has many parts configured similarly to the data transmission / reception device shown in FIG. 5, and FIG. 9 shows parts different from the data transmission / reception device shown in FIG. And only relevant parts are shown.
In the data transmission / reception device whose part is shown in FIG. 9, the E / O conversion unit 17 and the O / E conversion unit 25 provided in the data transmission / reception device shown in FIG. It has a unit 35 and an O / E conversion unit 41. Further, instead of the optical connectors 18 and 20, the optical fiber transmission lines 19 and 21, and the optical connectors 22 and 24 provided in the data transmitting / receiving apparatus shown in FIG. 5, an optical connector 37, an optical fiber transmission line 38 and an optical connector are used. 39 are provided. The optical fiber transmission line 38 is formed using, for example, a quartz SMF.
In the data transmission / reception device whose part is shown in FIG. 9, the serial data DSA whose bit transmission rate is 1.485 Gbps from the P / S converter 13 is supplied to the E / O converter 14 and the P / S converter Serial data DSB with a bit transmission rate of 1.485 Gbps from the S converter 16 is supplied to the E / O converter 35. The E / O converter 14 forms an optical signal OSA having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSA as a signal having a bit transmission rate of 1.485 Gbps, and multiplexes it. It leads to the unit 36. Further, the E / O conversion unit 35 performs an electro-optical conversion process on the serial data DSB whose bit transmission rate from the P / S conversion unit 16 is 1.485 Gbps, and sets the center wavelength based on the serial data DSB to, for example, The optical signal OSB of about 1.55 μm is formed with a bit transmission rate of 1.485 Gbps, which is guided to the multiplexing unit 36.
The multiplexing unit 36 is formed by, for example, a fiber-type WDM coupler (fiber-type WDM coupler). In the multiplexing section 36, an optical signal OSA having a center wavelength of about 1.3 μm and an optical signal OSB having a center wavelength of about 1.55 μm are multiplexed and multiplexed to form a multiplexed optical signal OSZ. And sends it out as a transmission signal. Under these circumstances, the E / O conversion units 14 and 35 and the multiplexing unit 36 form a data transmission unit that transmits serial data DSA and DSB obtained from the P / S conversion units 13 and 16, respectively, for transmission. ing.
The multiplexed optical signal OSZ, which is a transmission signal transmitted from the multiplexing unit 36, is guided to the optical fiber transmission line 38 through the optical connector 37, and is transmitted to the receiving side through the optical fiber transmission line 38.
On the receiving side, the multiplexed optical signal OSZ transmitted through the optical fiber transmission line 38 is guided to the demultiplexer 40 through the optical connector 39. The branching unit 40 is formed by using, for example, a fiber WDM coupler as a branching unit. In the demultiplexing unit 40, the multiplexed optical signal OSZ 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, and the bit transmission rate is set to 1 An optical signal OSA having a center wavelength of approximately 1.3 μm and an optical signal OSB having a bit transmission rate of 1.485 Gbps and a central wavelength of approximately 1.55 μm are reproduced.
The optical signals OSA and OSB reproduced by the demultiplexer 40 are guided to O / E converters 23 and 41, respectively. The O / E converter 23 performs a photoelectric conversion process on the optical signal OSA having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OSA. 1. Reproduce serial data DSA at 485 Gbps. Then, the reproduced serial data DSA is supplied to the S / P converter 26. The O / E converter 41 performs a photoelectric conversion process on an optical signal OSB having a center wavelength of about 1.55 μm and a bit transmission rate of 1.485 Gbps, and performs bit transmission based on the optical signal OSB. The serial data DSB whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSB is supplied to the S / P converter 30. Other operations are the same as those of the data transmitting / receiving apparatus shown in FIG.
FIG. 10 includes a first example that implements the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which the example that implements the second or thirteenth aspect of the data transmission method according to the present invention is implemented. 1 shows a data transmitting and receiving device.
In the data transmission / reception device shown in FIG. 10, digital data DVX forming a digital video signal is supplied to the data processing unit 51 on the transmission side forming an example of the data transmission device according to the present invention.
The digital data DVX is data shown as DVR10 in FIG. 3 or data shown as DTR10 in FIG.
When the digital data DVX is data indicated as DVR10 in FIG. 3, the data processing unit 51 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080, and the effective data sample in each line is A Y data sequence having a word transmission rate of 222.75 MBps, a quantization bit number of 10 bits, and a P data stream, each of which forms a 4: 2: 2 digital video signal whose number is set to 1920 samples. _B / P _R A data series is input.
When the digital data DVX is data indicated as DTR 10 in FIG. 4, the data processing unit 51 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of valid lines in each frame is 720, and the number of valid lines in each line is 720. A Y data sequence having a word transmission rate of 222.75 MBps, a quantization bit number of 10 bits, and a P data stream, each of which forms a digital video signal of 4: 2: 2 format in which the number of data samples is set to 1280 samples. _B / P _R A data series is input.
These data DVR10 or DTR10 constitute a Y data series and P _B / P _R As shown in FIG. 11, the data sequence is supplied to the data processing unit 51 as 20-bit parallel data having a word transmission rate of 222.75 MBps obtained by performing parallel multiplexing under the condition of frame synchronization and line synchronization. Is done.
The data processing unit 51 performs the following processing on the data DVR10 or DTR10 supplied as shown in FIG.
First, as shown in FIG. 11, the first two frame parts Frame 1, Frame 4,... Of the frame parts Frame 1, Frame 2, Frame 3,... Forming the data DVR10 or DTR10. Frame 7, Frame 5, Frame 8, Frame 5, Frame 8, Frame 9, Frame 9 Frame 3 Frame 6, Frame 6, Frame 9 ,... Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a Y data sequence and P having a series of segmented frame sections, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,..., At 90 Hz / 3 = 30 Hz, forming a segmented frame digital video signal. _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVR10A or DTR10A having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps. Also, each of the frame parts Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal having a segmented frame section 2, a segmented frame 5, a segmented frame 8,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVR10B or DTR10B having a word transmission rate of 74.25 MBps. Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal and have a segmented frame portion 3, a segmented frame 6, a segmented frame 9,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVR10C or DTR10C having a word transmission rate of 74.25 MBps.
As shown in FIG. 12A, the 20-bit word string data DVR10A or DTR10A is composed of 10-bit words YD0, YD1, YD2, YD3,. _B / P _R A 10-bit word PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting a data sequence is parallel-multiplexed and formed as a link A. Also, as shown in FIG. 12B and FIG. 12C, the 20-bit word string data DVR10B or DTR10B and the DVR10 or DTR10C are also 10-bit words YD0, YD1, YD2, YD3,. ... and P _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are multiplexed in parallel and formed as a link B and a link C.
That is, in the data processing unit 51, the data DVR10 or DTR10 forming the 20-bit word string data having the word transmission rate of 222.75 MBps is converted to the 20-bit word string data having the word transmission rate of 74.25 MBps. The data is converted into three-system word string data of DVR10A, DVR10B and DVR10C or DTR10A, DTR10B and DTR10C. Then, the data processing unit 51 converts the set of 20-bit word string data DVR10A, DVR10B and DVR10C or the set of 20-bit word string data DTR10A, DTR10B and DTR10C into 20-bit word string data DPA (20), DPB (20). ) And DPC (20).
The 20-bit word string data DPA (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 51 is supplied to the data insertion unit 52. The data insertion unit 52 inserts auxiliary data DAA including channel identification data as needed into the 20-bit word string data DPA (20), and the 20-bit word string data DPA ′ into which the auxiliary data DAA has been inserted. (20) is formed. The 20-bit word string data DPA ′ (20) obtained from the data insertion unit 52 is supplied to the P / S conversion unit 53.
The P / S conversion unit 53 performs P / S conversion on the 20-bit word string data DPA '(20) to increase the bit transmission rate based on the 20-bit word string data DPA' (20) to 74.25 Mbps. The serial data DSA of 20 = 1.485 Gbps is formed, and the serial data DSA is supplied to the E / O converter 54.
The E / O conversion unit 54 performs an electro-optical conversion process on the serial data DSA, and converts the optical signal OSA whose central wavelength is, for example, approximately 1.3 μm based on the serial data DSA to a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
The 20-bit word string data DPB (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 51 is supplied to the data insertion unit 55. The data insertion unit 55 inserts the auxiliary data DAB including the necessary channel identification data into the 20-bit word string data DPB (20), and the 20-bit word string data DPB ′ into which the auxiliary data DAB has been inserted. (20) is formed. The 20-bit word string data DPB ′ (20) obtained from the data insertion unit 55 is supplied to the P / S conversion unit 56.
The P / S conversion section 56 performs P / S conversion on the 20-bit word string data DPB '(20) to increase the bit transmission rate based on the 20-bit word string data DPB' (20) to 74.25 Mbps. The serial data DSB with 20 = 1.485 Gbps is formed, and the serial data DSB is supplied to the E / O converter 57.
The E / O conversion unit 57 performs an electro-optical conversion process on the serial data DSB, converts the optical signal OSB having a center wavelength of, for example, approximately 1.3 μm, based on the serial data DSB, to a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
Further, 20-bit word string data DPC (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 51 is supplied to the data insertion unit 58. The data insertion unit 58 inserts auxiliary data DAC including channel identification data as needed into the 20-bit word string data DPC (20), and inserts the 20-bit word string data DPC 'into which the auxiliary data DAC has been inserted. (20) is formed. The 20-bit word string data DPC ′ (20) obtained from the data insertion unit 58 is supplied to the P / S conversion unit 59.
The P / S conversion section 59 performs P / S conversion on the 20-bit word string data DPC ′ (20) to increase the bit transmission rate based on the 20-bit word string data DPC ′ (20) to 74.25 MBps × The serial data DSC in which 20 = 1.485 Gbps is formed, and the serial data DSC is supplied to the E / O converter 60.
The E / O conversion unit 60 performs an electro-optical conversion process on the serial data DSC to convert an optical signal OSC having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSC into a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
Under these circumstances, the E / O converters 54, 57 and 60 form a data transmitter for transmitting the serial data DSA, DSB and DSC obtained from the P / S converters 53, 56 and 59, respectively. are doing.
An optical signal OSA, which is a transmission signal transmitted from the E / O conversion unit 54, is guided to an optical fiber transmission line 62 through an optical connector 61, and is transmitted to a receiving side through the optical fiber transmission line 62. The optical signal OSB, which is a transmission signal transmitted from the E / O converter 57, is guided to the optical fiber transmission line 64 through the optical connector 63, and is transmitted to the receiving side through the optical fiber transmission line 64. Further, an optical signal OSC, which is a transmission signal transmitted from the E / O conversion unit 60, is guided to an optical fiber transmission line 66 through an optical connector 65, and is transmitted to the receiving side through the optical fiber transmission line 66. Each of the optical fiber transmission lines 62, 64 and 66 is formed using, for example, a quartz SMF.
On the receiving side, the optical signal OSA transmitted through the optical fiber transmission line 62 is guided to the O / E converter 68 through the optical connector 67. The optical signal OSB transmitted through the optical fiber transmission line 64 is guided to the O / E converter 70 through the optical connector 69. Further, the optical signal OSC transmitted through the optical fiber transmission line 66 is guided to the O / E converter 72 through the optical connector 71.
The O / E conversion unit 68 performs a photoelectric conversion process on the optical signal OSA having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps to obtain a bit transmission rate based on the optical signal OSA. 1. Reproduce serial data DSA at 485 Gbps. Then, the reproduced serial data DSA is supplied to the S / P converter 73. The S / P converter 73 performs S / P conversion on the serial data DSA to reproduce 20-bit word string data DPA ′ (20) based on the serial data DSA and having a word transmission rate of 74.25 MBps. Then, it is supplied to the data time difference absorbing section 74.
In the O / E conversion unit 70, the optical signal OSB having the center wavelength of about 1.3 μm and the bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing, and bit transmission based on the optical signal OSB is performed. The serial data DSB whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSB is supplied to the S / P converter 75. The S / P converter 75 performs S / P conversion on the serial data DSB to reproduce 20-bit word string data DPB ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSB. Then, it is supplied to the data time difference absorbing section 74.
Further, the O / E converter 72 performs a photoelectric conversion process on the optical signal OSC having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps, and performs bit transmission based on the optical signal OSC. The serial data DSC whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSC is supplied to the S / P converter 76. The S / P converter 76 performs S / P conversion on the serial data DSC to reproduce 20-bit word string data DPC ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSC. Then, it is supplied to the data time difference absorbing section 74.
In the data time difference absorption section 74, the 20-bit word string data DPA '(20) from the S / P conversion section 73, the 20-bit word string data DPB' (20) from the S / P conversion section 75, and the S / P The mutual time difference generated between the 20-bit word string data DPC '(20) from the P conversion unit 76 is absorbed, and the word transmission rate based on the 20-bit word string data DPA' (20) is set to 74.25 MBps. Bit word sequence data DPAQ '(20), 20-bit word sequence data DPBQ' (20) having a word transmission rate based on 20-bit word sequence data DPB '(20) of 74.25 MBps, and 20-bit word sequence data DPC And a 20-bit word string data DPCQ with a word transmission rate of 74.25 MBps based on (20) Sent as it is maintained in absence substantially is aimed.
The 20-bit word string data DPAQ '(20), DPBQ' (20) and DPCQ '(20) obtained from the data time difference absorbing unit 74 are supplied to data separating units 77, 78 and 79, respectively. In the data separation unit 77, the auxiliary data DAA is separated from the 20-bit word string data DPAQ '(20), and the 20-bit word string data DPAQ (20) and the auxiliary data DAA are separately transmitted. The bit word string data DPAQ (20) is supplied to the data reproduction processing unit 80. In the data separation section 78, the auxiliary data DAB is separated from the 20-bit word string data DPBQ '(20), and the 20-bit word string data DPBQ (20) and the auxiliary data DAB are separately transmitted. , 20-bit word string data DPBQ (20) are supplied to the data reproduction processing unit 80. Further, in the data separating section 79, the auxiliary data DAC is separated from the 20-bit word string data DPCQ '(20), and the 20-bit word string data DPCQ (20) and the auxiliary data DAC are separately transmitted. , 20-bit word string data DPCQ (20) are supplied to the data reproduction processing unit 80.
In the data reproduction processing unit 80, data conversion performed on the digital data DVX by the data processing unit 51 on the transmission side is performed on the 20-bit word string data DPAQ (20), DPBQ (20) and DPCQ (20). Data reproduction processing reverse to the processing is performed to reproduce digital data DVX based on the 20-bit word string data DPAQ (20), DPBQ (20) and DPCQ (20). Such digital data DVX is data shown as DVR10 in FIG. 3 or data shown as DTR10 in FIG.
FIG. 13 includes a second example of the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which the example of the second or thirteenth aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the data transmission / reception device.
The data transmission / reception device whose part is shown in FIG. 13 has many parts configured in the same manner as the data transmission / reception device shown in FIG. 10, and FIG. 13 shows parts different from the data transmission / reception device shown in FIG. And only relevant parts are shown.
In the data transmission / reception device whose part is shown in FIG. 13, the E / O conversion units 54, 57 and 60 and the O / E conversion units 68, 70 and 72 provided in the data transmission / reception device shown in FIG. , E / O converters 91 and 94 and O / E converters 98 and 101 are provided. Further, instead of the optical connectors 61, 63 and 65, the optical fiber transmission lines 62, 64 and 66, and the optical connectors 67, 69 and 71 provided in the data transmitting and receiving apparatus shown in FIG. , Optical fiber transmission lines 93 and 96, and optical connectors 97 and 100. Each of the optical fiber transmission lines 93 and 96 is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 13, the serial data DSA whose bit transmission rate from the P / S converter 53 is 1.485 Gbps and the bit transmission rate from the P / S converter 56 are 1. The serial data DSB of 485 Gbps is supplied to the bit multiplexing unit 90. The bit multiplexing unit 90 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSA and DSB, performing a bit multiplexing / combining process on the serial data DSA and DSB, and reducing the bit transmission rate. The composite serial data DZV with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZV obtained from the bit multiplexing unit 90 is supplied to an E / O conversion unit 91. In the E / O converter 91, an optical signal OZV having a center wavelength of, for example, about 1.3 μm based on the composite serial data DZV is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Further, the serial data DSC whose bit transmission rate is 1.485 Gbps from the P / S converter 59 is supplied to the E / O converter 94. In the E / O converter 94, an optical signal OSC having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSC is formed with a bit transmission rate of 1.485 Gbps, and is formed. It is transmitted as a transmission signal.
Under the circumstances, the bit multiplexing section 90 and the E / O conversion sections 91 and 94 transmit the serial data DSA, DSB and DSC obtained from the P / S conversion sections 53, 56 and 59, respectively, for transmission. A sending section is formed.
An optical signal OZV, which is a transmission signal transmitted from the E / O converter 91, is guided to an optical fiber transmission line 93 through an optical connector 92, and is transmitted to a receiving side through the optical fiber transmission line 93. The optical signal OSC, which is a transmission signal transmitted from the E / O converter 94, is guided to the optical fiber transmission line 96 through the optical connector 95, and is transmitted to the receiving side through the optical fiber transmission line 96.
On the receiving side, the optical signal OZV transmitted through the optical fiber transmission line 93 is guided to the O / E converter 98 through the optical connector 97. The optical signal OSC transmitted through the optical fiber transmission line 96 is guided to the O / E conversion unit 101 through the optical connector 100.
The O / E converter 98 performs a photoelectric conversion process on the optical signal OZV having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and obtains a bit transmission rate based on the optical signal OZV. 2. Reproduce composite serial data DZV at 2.97 Gbps. Then, the reproduced composite serial data DZV is supplied to the bit separation unit 99.
The bit separation unit 99 extracts one bit at a time from the composite serial data DZV, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZV. Then, a channel is specified by using the channel identification data included in the composite serial data DZV, and based on the composite serial data DZV, a 2-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. Form data DSA and DSB. The serial data DSA is supplied to the S / P converter 73, and the serial data DSB is supplied to the S / P converter 75.
Also, in the O / E conversion unit 101, the optical signal OSC having the center wavelength of approximately 1.3 μm and the bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing to perform bit transmission based on the optical signal OSC. The serial data DSC whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSC is supplied to the S / P converter 76. Other operations are the same as those of the data transmitting / receiving apparatus shown in FIG.
FIG. 14 includes a third example according to the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which an example according to the second or thirteenth aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the data transmission / reception device.
The data transmission / reception device whose part is shown in FIG. 14 has many parts configured similarly to the data transmission / reception device whose part is shown in FIG. 13, and FIG. 14 shows the data transmission / reception device shown in FIG. Blocks corresponding to the respective blocks in the portion are denoted by the same reference numerals as in FIG. 13, and overlapping description thereof will be omitted.
In the data transmission / reception device whose part is shown in FIG. 14, serial data DSC whose bit transmission rate is 1.485 Gbps from the P / S converter 59 is supplied to the E / O converter 105. In the E / O conversion unit 105, an optical signal OSC having a center wavelength of, for example, about 1.55 μm based on the serial data DSC is formed with a bit transmission rate of 1.485 Gbps.
The optical signal OZV from the E / O conversion unit 91 having a center wavelength of approximately 1.3 μm and the bit transmission rate of 2.97 Gbps, and the center wavelength from the E / O conversion unit 105 of approximately 1.55 μm The optical signal OSC having a bit transmission rate of 1.485 Gbps is guided to the multiplexing unit 106. The multiplexing unit 106 is formed by, for example, a dielectric multilayer type wavelength division multiplexing (dielectric multilayer type WDM) coupler. In the multiplexing unit 106, an optical signal OZV having a center wavelength of about 1.3 μm and an optical signal OSC having a center wavelength of about 1.55 μm are multiplexed and multiplexed to form a multiplexed optical signal OZZ. And sends it out as a transmission signal. Under these circumstances, the E / O converters 91 and 105 and the multiplexing unit 106 transmit the serial data DSA, DSB and DSC obtained from the P / S converters 53, 56 and 59, respectively, for transmission. A sending section is formed.
The multiplexed optical signal OZZ, which is a transmission signal transmitted from the multiplexing unit 106, is guided to the optical fiber transmission line 108 through the optical connector 107, and is transmitted to the receiving side through the optical fiber transmission line 108 formed using, for example, a quartz SMF. Is transmitted.
On the receiving side, the multiplexed optical signal OZZ transmitted through the optical fiber transmission line 108 is guided to the demultiplexer 110 through the optical connector 109. The branching unit 110 is formed by using, for example, a dielectric multilayer WDM coupler as a branching unit. Then, in the demultiplexing unit 110, the multiplexed optical signal OZZ 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, and a bit transmission rate of 2 An optical signal OZV having a center wavelength of approximately 1.3 μm and an optical signal OSC having a bit transmission rate of 1.485 Gbps and a central wavelength of approximately 1.55 μm are reproduced.
The optical signals OZV and OSC reproduced by the demultiplexer 110 are guided to O / E converters 111 and 112, respectively. The O / E converter 111 performs a photoelectric conversion process on the optical signal OZV having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and adjusts the bit transmission rate based on the optical signal OZV. 2. Reproduce composite serial data DZV at 2.97 Gbps. Then, the reproduced composite serial data DZV is supplied to the bit separation unit 99. The O / E converter 112 performs a photoelectric conversion process on an optical signal OSC having a center wavelength of about 1.55 μm and a bit transmission rate of 1.485 Gbps, and performs bit transmission based on the optical signal OSC. The serial data DSC whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSC is supplied to the S / P converter 76. Other operations are the same as those of the data transmitting / receiving device whose part is shown in FIG.
FIG. 15 includes a fourth example which forms the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which the example which forms the second or thirteenth aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the data transmission / reception device.
The data transmission / reception device whose part is shown in FIG. 15 also has many parts configured in the same manner as the data transmission / reception device shown in FIG. 10, and FIG. 15 shows parts different from the data transmission / reception device shown in FIG. And only relevant parts are shown.
In the data transmission / reception device whose part is shown in FIG. 15, instead of the E / O conversion units 57 and 60 and the O / E conversion units 70 and 72 provided in the data transmission / reception device shown in FIG. E / O converters 81 and 82 and O / E converters 88 and 89 are provided. Further, instead of the optical connectors 61, 63 and 65, the optical fiber transmission lines 62, 64 and 66, and the optical connectors 67, 69 and 71 provided in the data transmission / reception device shown in FIG. A transmission path 85 and an optical connector 86 are provided. The optical fiber transmission line 85 is formed using, for example, a quartz SMF.
In the data transmission / reception device whose part is shown in FIG. 15, the serial data DSA whose bit transmission rate is 1.485 Gbps from the P / S converter 53 is supplied to the E / O converter 54 and the P / S converter Serial data DSB having a bit transmission rate of 1.485 Gbps from the S conversion section 56 is supplied to the E / O conversion section 81, and further, serial data having a bit transmission rate of 1.485 Gbps from the P / S conversion section 59. The DSC is supplied to the E / O converter 82.
The E / O converter 54 forms an optical signal OSA having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSA as a signal having a bit transmission rate of 1.485 Gbps, and multiplexes the signals. Guide to section 83. Further, the E / O converter 81 performs an electro-optical conversion process on the serial data DSB whose bit transmission rate from the P / S converter 56 is 1.485 Gbps, and sets a center wavelength based on the serial data DSB, for example, The optical signal OSB of approximately 1.48 μm is formed with a bit transmission rate of 1.485 Gbps, and is guided to the multiplexing unit 83. Further, the E / O converter 82 performs an electro-optical conversion process on the serial data DSC whose bit transmission rate from the P / S converter 59 is 1.485 Gbps, and sets a center wavelength based on the serial data DSC, for example, The optical signal OSC of approximately 1.55 μm is formed with a bit transmission rate of 1.485 Gbps, and is guided to the multiplexing unit 83.
The multiplexing unit 83 is formed by, for example, a fiber type WDM coupler and a dielectric multilayer film type WDM coupler. In the multiplexing unit 83, an optical signal OSA having a center wavelength of approximately 1.3 μm, an optical signal OSB having a center wavelength of approximately 1.48 μm, and an optical signal OSC having a center wavelength of approximately 1.55 μm are combined. Waves are multiplexed to form a multiplexed optical signal OSZ, which is transmitted as a transmission signal. Under these circumstances, the E / O converters 54, 81 and 82 and the multiplexer 83 transmit the serial data DSA, DSB and DSC obtained from the P / S converters 53, 56 and 59, respectively, for transmission. To form a data transmission unit.
The multiplexed optical signal OSZ, which is a transmission signal transmitted from the multiplexing unit 83, is guided to the optical fiber transmission line 85 through the optical connector 84, and is transmitted to the receiving side through the optical fiber transmission line 85.
On the receiving side, the multiplexed optical signal OSZ transmitted through the optical fiber transmission line 85 is guided to the demultiplexer 87 through the optical connector 86. The branching unit 87 is formed by using, for example, a fiber WDM coupler and a dielectric multilayer WDM coupler as a branching unit. In the demultiplexer 87, the multiplexed optical signal OSZ is divided into a component having a center wavelength of approximately 1.3 μm, a component having a center wavelength of approximately 1.48 μm, and a component having a center wavelength of approximately 1.55 μm. An optical signal OSA having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.3 μm, and an optical signal OSB having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.48 μm And an optical signal OSC having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.55 μm.
The optical signals OSA, OSB and OSC reproduced by the demultiplexer 87 are guided to O / E converters 68, 88 and 89, respectively. The O / E conversion unit 68 performs a photoelectric conversion process on the optical signal OSA having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps to obtain a bit transmission rate based on the optical signal OSA. 1. Reproduce serial data DSA at 485 Gbps. Then, the reproduced serial data DSA is supplied to the S / P converter 73. In the O / E conversion unit 88, the optical signal OSB having the center wavelength of about 1.48 μm and the bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing to perform bit transmission based on the optical signal OSB. The serial data DSB whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSB is supplied to the S / P converter 75. Further, the O / E converter 89 performs a photoelectric conversion process on the optical signal OSC having a center wavelength of about 1.55 μm and a bit transmission rate of 1.485 Gbps, and performs bit transmission based on the optical signal OSC. The serial data DSC whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSC is supplied to the S / P converter 76. Other operations are the same as those of the data transmitting / receiving apparatus shown in FIG.
FIG. 16 includes a fifth example according to the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which an example according to the second or thirteenth aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the data transmission / reception device.
The data transmission / reception device whose part is shown in FIG. 16 also has many parts configured similarly to the data transmission / reception device shown in FIG. 10, and FIG. 16 shows a portion different from the data transmission / reception device shown in FIG. And only relevant parts are shown.
In the data transmission / reception device whose part is shown in FIG. 16, the E / O conversion units 54, 57 and 60 and the O / E conversion units 68, 70 and 72 provided in the data transmission / reception device shown in FIG. In place of E / O converters 54C, 57C and 60C and O / E converters 68C, 70C and 72C. Further, instead of the optical connectors 61, 63 and 65, the optical fiber transmission lines 62, 64 and 66, and the optical connectors 67, 69 and 71 provided in the data transmission / reception device shown in FIG. An optical connector 84C, an optical fiber transmission line 85C, an optical connector 86C, and a demultiplexer 87C are provided.
In the data transmission / reception device whose part is shown in FIG. 16, serial data DSA whose bit transmission rate is 1.485 Gbps from P / S conversion section 53 is supplied to E / O conversion section 54C and P / S Serial data DSB having a bit transmission rate of 1.485 Gbps from the S conversion section 56 is supplied to the E / O conversion section 57C, and further, serial data having a bit transmission rate of 1.485 Gbps from the P / S conversion section 59. The DSC is supplied to the E / O conversion unit 60C.
In the E / O conversion unit 54C, an optical signal OSA having a center wavelength of, for example, approximately 1.511 μm based on the serial data DSA is formed with a bit transmission rate of 1.485 Gbps, and is combined. Guide to section 83C. Further, the E / O converter 57C performs an electro-optical conversion process on the serial data DSB whose bit transmission rate from the P / S converter 56 is 1.485 Gbps, and sets the center wavelength based on the serial data DSB to, for example, The optical signal OSB of approximately 1.531 μm is formed with a bit transmission rate of 1.485 Gbps, and is guided to the multiplexing unit 83C. Further, the E / O conversion unit 60C performs an electro-optical conversion process on the serial data DSC whose bit transmission rate from the P / S conversion unit 59 is 1.485 Gbps, and sets the center wavelength based on the serial data DSC to, for example, The optical signal OSC of about 1.551 μm is formed with a bit transmission rate of 1.485 Gbps, which is guided to the multiplexing unit 83C.
In the multiplexing section 83C, an optical signal OSA having a center wavelength of about 1.511 μm, an optical signal OSB having a center wavelength of about 1.531 μm, and an optical signal OSC having a center wavelength of about 1.551 μm are combined. Waves are multiplexed to form a multiplexed optical signal OSZC, which is transmitted as a transmission signal. Under the circumstances, the E / O conversion units 54C, 57C and 60C and the multiplexing unit 83C transmit the serial data DSA, DSB and DSC obtained from the P / S conversion units 53, 56 and 59, respectively, for transmission. To form a data transmission unit.
In this manner, the optical signals OSA, OSB and OSC multiplexed in the multiplexing unit 83C have wavelengths very close to each other, whose center wavelengths are only separated by approximately 0.020 μm (20 nm). The multiplexed signal is multiplexed to form a multiplexed optical signal OSZC. In a portion including the E / O converters 54C, 57C and 60C and the multiplexing unit 83C, the Coase Wavelength Division Multiplexing (CWDM) is used. ) Is used.
The multiplexed optical signal OSZC, which is a transmission signal transmitted from the multiplexing unit 83C, is guided through an optical connector 84C to an optical fiber transmission line 85C formed using, for example, a silica-based SMF, and is transmitted through the optical fiber transmission line 85C. Transmitted to.
On the receiving side, the multiplexed optical signal OSZC transmitted through the optical fiber transmission line 85C is guided to the demultiplexing unit 87C through the optical connector 86C. The splitter 87C separates the multiplexed optical signal OSZC into a component having a center wavelength of approximately 1.511 μm, a component having a center wavelength of approximately 1.531 μm, and a component having a center wavelength of approximately 1.551 μm. An optical signal OSA having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.511 μm, an optical signal OSB of a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.531 μm, An optical signal OSC having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.551 μm is reproduced.
The optical signals OSA, OSB, and OSC reproduced by the demultiplexer 87C are guided to O / E converters 68C, 70C, and 72C, respectively. The O / E conversion unit 68C performs a photoelectric conversion process on the optical signal OSA having a center wavelength of about 1.511 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OSA. 1. Reproduce serial data DSA at 485 Gbps. Then, the reproduced serial data DSA is supplied to the S / P converter 73. In the O / E conversion unit 70C, the optical signal OSB having the center wavelength of about 1.531 μm and the bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing to perform bit transmission based on the optical signal OSB. The serial data DSB whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSB is supplied to the S / P converter 75. Further, in the O / E conversion section 72C, the optical signal OSC having the center wavelength of about 1.551 μm and the bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing to perform bit transmission based on the optical signal OSC. The serial data DSC whose rate is 1.485 Gbps is reproduced. Then, the reproduced serial data DSC is supplied to the S / P converter 76. Other operations are the same as those of the data transmitting / receiving apparatus shown in FIG.
FIGS. 17 and 18 show examples in which any one of the third to sixth, fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission method according to the present invention is implemented. A data transmission / reception device including a first example of any one of the third to sixth, fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission device according to the present invention. Show.
In the data transmission / reception device shown in FIGS. 17 and 18, digital data DVX forming a digital video signal is supplied to the data processing unit 121 on the transmission side which is an example of the data transmission device according to the present invention.
The digital data DVX is any one of data shown as DVC12, DVC14, DVC16, DVD10, DVD12 and DVU10 in FIG. 3, and any one of data shown as DTU12, DTU14, DTU16, DTV10, DTV12 and DTU10 in FIG. Data data DVC10 + DKC10 in which a key signal data sequence DKC10 having a quantization bit number of 10 bits is added to DVC10, and data data DVD10 + DKD10, data data in which a Key signal data sequence DKD10 having a quantization bit number of 10 bits is added to data DVD10. Data data DTU10 + DYU10 in which a key signal data series DYU10 having a quantization bit number of 10 bits is added to DTU10, or data DTV10 It is data DTV10 + DYV10 the Key signal data series DYV10 that the number of quantization bits of 10 bits is added.
When the digital data DVX is the data DVC12 shown in FIG. 3, the data processing unit 121 sets the frame rate to 50 Hz or 60 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is 1920. A Y data series and a P data, each of which forms a digital video signal of 4: 2: 2 format set in a sample, each having a word transmission rate of 148.5 MBps and a quantization bit number of 12 bits. _B / P _R A data series is input.
When the digital data DVX is the data DTU 12 shown in FIG. 4, the data processing unit 121 sets the frame rate to 120 Hz, the number of valid lines in each frame is 720, and the number of valid data samples in each line is 1280. A Y data series and a P data, each of which forms a digital video signal of 4: 2: 2 format set in a sample, each having a word transmission rate of 148.5 MBps and a quantization bit number of 12 bits. _B / P _R A data series is input.
These data DVC12 or DTU12 and the Y data series and P _B / P _R As shown in FIG. 19, the data sequence is supplied to the data processing unit 121 as 24-bit parallel data having a word transmission rate of 148.5 MBps, which is obtained by performing parallel multiplexing under the condition of frame synchronization and line synchronization. Is done.
The data processing unit 121 performs the following processing on the data DVC12 or DTU12 supplied as shown in FIG.
First, as shown in FIG. 19, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVC 12 or DTU 12 is located at Frame 1, Frame 3,. .. And the second alternate frame portion Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a Y data sequence and P having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 3, Segmented Frame 5,..., Of 120 Hz / 2 = 60 Hz, forming a segmented frame digital video signal _B / P _R It is assumed that 24-bit parallel data including a data sequence is formed, thereby obtaining 24-bit word string data DVC12A or DTU12A having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. Y data sequence and segmented frame digital video signal having segmented frame 2, Segmented Frame 4, Segmented Frame 6,... _B / P _R It is assumed that 24-bit parallel data including a data sequence is formed, thereby obtaining 24-bit word string data DVC12B or DTU12B having a word transmission rate of 74.25 MBps.
As shown in FIG. 20A, the 24-bit word string data DVC12A or DTU12A is composed of 12-bit words YD0, YD1, YD2, YD3,... _B / P _R A 12-bit word PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting a data sequence is parallel-multiplexed and formed as a link A. As shown in FIG. 20B, the 24-bit word string data DVC12B or DTU12B also includes 12-bit words YD0, YD1, YD2, YD3,... _B / P _R A 12-bit word PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting a data sequence is parallel-multiplexed and formed as a link B.
Subsequently, as shown in FIG. 20A, 12-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in the 24-bit word string data DVC12A or DTU12A. _B / P _R Each of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence is represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; ... and Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11, ... ... and lower two 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,.
A sequence of the divided upper 10 bits: 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,. 20-bit word string data DVC12A1 or DTU12A1 having a transmission rate of 74.25 MBps is formed as a link A-1 as shown in FIG. 21A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. Bit sequence: [Pb0; 0-1] + d0, [Pr0; 0-1] + d1, [Pb1; 0-1] + d2, [Pr1; 0-1] + d3, [Pb2; 0-1] + d4, [ .., And the 20-bit word string data DVC12A2 or DTU12A2 having a word transmission rate of 74.25 MBps is set as a link A-2 in FIG. 21B. Form as shown.
Further, as shown in FIG. 20B, 12-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in the 24-bit word string data DVC12B or DTU12B. _B / P _R The upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11 of each of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,. , Y3; 2-11, ... and Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; ... and lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1, ... and Pb0; 0-1, Pr0; Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; 0-1,.
A sequence of the divided upper 10 bits: 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,. 20-bit word string data DVC12B1 or DTU12B1 having a transmission rate of 74.25 MBps is formed as link B-1 as shown in FIG. 21A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. 10-bit string: [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 parallel-multiplexed, and the 20-bit word string data DVC12B2 or DTU12B2 having a word transmission rate of 74.25 MBps is used as a link B-2 as a link B-2 in FIG. It is formed as shown in FIG.
That is, in the data processing unit 121, the data DVC12 or DTU12 forming the 24-bit word string data having the word transmission rate of 148.5 MBps is converted to the 20-bit word string data having the word transmission rate of 74.25 MBps. The data is converted into four-system word string data of DVC12A1, DVC12A2, DVC12B1, and DVC12B2, or DTU12A1, DTU12A2, DTU12B1, and DTU12B2.
When the digital data DVX is the data indicated as DVC14 or the data indicated as DVC16 in FIG. 3, the data processing unit 121 sets the frame rate to 50 Hz or 60 Hz, and sets the number of effective lines in each frame to 1080 lines and each line. Form a digital video signal of 4: 2: 2 format in which the number of valid data samples in is set to 1920 samples, each having a word transmission rate of 148.5 MBps and a quantization bit number of 14 bits or 16 bits. Y data series and P _B / P _R A data series is input.
When the digital data DVX is data indicated as DTU 14 or data indicated as DTU 16 in FIG. 4, the data processing unit 121 sets the frame rate to 120 Hz, sets the number of effective lines in each frame to 720 lines, , The number of effective data samples is set to 1280, and a digital video signal of 4: 2: 2 format is formed, each of which has a word transmission rate of 148.5 MBps and a quantization bit number of 14 bits or 16 bits. Y data series and P _B / P _R A data series is input.
These data DVC14 or DVC16 or data DTU14 or DTU16, _B / P _R The data sequence is supplied to the data processing unit 121 as 28-bit parallel data or 32-bit parallel data with a word transmission rate of 148.5 MBps, which is obtained by performing parallel multiplexing under frame synchronization and line synchronization.
In such a case, the data processing unit 121 performs the same processing on the data DVC14 or DVC16 or the data DTU14 or DTU16 as in the case of the data DVC12 or DTU12. Where Y data series and P _B / P _R Instead of dividing each of the 12-bit words constituting the data sequence into upper 10 bits and lower 2 bits, a Y data sequence and a P data _B / P _R The operation of dividing each of the 14-bit words constituting the data sequence into upper 10 bits and lower 4 bits, or the Y data sequence and P _B / P _R An operation of dividing each of the 16-bit words constituting the data sequence into upper 10 bits and lower 6 bits is performed.
The data DVC14 or DVC16 or the data DTU14 or DTU16 forming the 28-bit word string data or the 32-bit word string data having the word transmission rate of 148.5 MBps is a 20-bit word having the word transmission rate of 74.25 MBps. Column data DVC14A1 or DVC16A1, DVC14A2 or DVC16A2, DVC14B1 or DVC16B1, and DVC14B2 or DVC16B2, or 20-bit word column data DTU14A1 or DTU16A1, DTU14A2 or DTU16A2, DTU14B1 or BDU4B1 or BDU4B1 or 2 Convert to data.
When the digital data DVX is the data DVD 10 shown in FIG. 3, the data processing unit 121 sets the frame rate to 50 Hz or 60 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is 1920. A G data sequence, a B data sequence, and an R data sequence each forming a 4: 4: 4 format digital video signal set to a sample, each having a word transmission rate of 148.5 MBps and a quantization bit number of 10 bits. Is entered.
When the digital data DVX is the data DTV10 shown in FIG. 4, the data processing unit 121 sets the frame rate to 120 Hz, the number of valid lines in each frame is 720, and the number of valid data samples in each line is 1280. A G data sequence, a B data sequence, and an R data sequence each forming a 4: 4: 4 format digital video signal set to a sample, each having a word transmission rate of 148.5 MBps and a quantization bit number of 10 bits. Is entered.
As shown in FIG. 22, the G data sequence, B data sequence, and R data sequence forming the data DVD 10 or DTV 10 have a word transmission rate obtained by parallel multiplexing under frame synchronization and line synchronization. The data is supplied to the data processing unit 121 as 30-bit parallel data of 148.5 MBps.
The data processing unit 121 performs the following processing on the data DVD 10 or DTV 10 supplied as shown in FIG.
First, as shown in FIG. 22, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVD 10 or the DTV 10 is Frame 1, Frame 3,. .. And the second alternate frame portion Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a G data sequence and a B data which constitute a segmented frame digital video signal having a series of segmented frame portions 1, 2, 3, 4, 5,... Which are set to 120 Hz / 2 = 60 Hz. 30-bit parallel data including the data sequence and the R data sequence, thereby forming a 30-bit word string data DVD10A or DTV1 having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Get the A. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. 30 bit parallel data including a G data sequence, a B data sequence, and an R data sequence that constitute a segmented frame digital video signal having a segmented frame portion 2, a segmented frame 4, a segmented frame 6,... Thus, a 30-bit word string data DVD 10B or DTV 10B having a word transmission rate of 74.25 MBps is obtained.
As shown in FIG. 23A, the 30-bit word sequence data DVD 10A or DTV 10A forms a B data sequence with 10-bit words GD0, GD1, GD2, GD3,... .. And 10-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are parallel-multiplexed, and the link is formed by a 10-bit word BD0, BD1, BD2, BD3,. A is formed. Further, as shown in FIG. 23B, the 30-bit word string data DVD 10B or DTV 10B also includes the 10-bit words GD0, GD1, GD2, GD3,... , And 10-bit words RD0, RD1, RD2, RD3,..., Which constitute an R data sequence, are multiplexed in parallel to form 10-bit words BD0, BD1, BD2, BD3,. , Link B.
Subsequently, as shown in FIG. 23A, a 10-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 30-bit word string data DVD 10A or DTV 10A is constructed. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and auxiliary data added to the 10-bit words BD0, BD1, BD2, BD3,. The auxiliary 10-bit words ad0, ad1, ad2, ad3,... Constituting the sequence are divided as separated by a thick solid line in FIG. 24 to form a 10-bit word GD0 forming a G data sequence. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. The 10-bit word group 1 including the 10-bit words RD0, RD2,... Forming the R data sequence, and the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence. Then, 20-bit word string data DVD10A1 or DTV10A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link A-1 as shown in FIG. 25A. At the same time, a 20-bit word string data DVD 10A2 or DTV 10A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link A-2 as shown in FIG. Form.
Further, as shown in B of FIG. 23, a 10-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 30-bit word string data DVD 10B or DTV 10B is constructed. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and an auxiliary data sequence added thereto Are divided in such a manner as to be separated by a thick solid line in FIG. 24, and a 10-bit word GD0 that forms a G data sequence is also divided into the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. .. and a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming an R data sequence, and auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence Distribute. Then, 20-bit word string data DVD10B1 or DTV10B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link B-1 as shown in FIG. 25A. At the same time, a 20-bit word string data DVD 10B2 or DTV 10B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link B-2 as shown in FIG. Form.
That is, in the data processing unit 121, the data DVD10 or DTV10 forming 30-bit word string data having a word transmission rate of 148.5 MBps is converted to the 20-bit word string data DVD10A1 having a word transmission rate of 74.25 MBps. The data is converted into four-system word string data of DVD10A2, DVD10B1 and DVD10B2, or DTV10A1, DTV10A2, DTV10B1 and DTV10B2.
When the digital data DVX is the data DVD 12 shown in FIG. 3, the data processing unit 121 sets the frame rate to 50 Hz or 60 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is 1920. A G data sequence, a B data sequence, and an R data sequence each forming a 4: 4: 4 format digital video signal set to a sample, each having a word transmission rate of 148.5 MBps and a quantization bit number of 12 bits. Is entered.
Further, when the digital data DVX is the data DTV12 shown in FIG. 4, the data processing unit 121 sets the frame rate to 120 Hz, the number of effective lines in each bloom is 720 lines, and the number of effective data samples in each line is 1280. A G data sequence, a B data sequence, and an R data sequence each forming a 4: 4: 4 format digital video signal set to a sample, each having a word transmission rate of 148.5 MBps and a quantization bit number of 12 bits. Is entered.
As shown in FIG. 26, the G data sequence, B data sequence, and R data sequence forming the data DVD 12 or the DTV 12 have a word transmission rate obtained by parallel multiplexing under frame synchronization and line synchronization. The data is supplied to the data processing unit 121 as 36-bit parallel data of 148.5 MBps.
The data processing unit 121 performs the following processing on the data DVD 12 or DTV 12 supplied as shown in FIG.
26. First, as shown in FIG. 26, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVD 12 or the DTV 12 are Frame 1, Frame 3, Frame 3,. .. And the second alternate frame portion Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. A G data sequence forming a segmented frame digital video signal having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 3, Segmented Frame 5, ..., 120 Hz / 2 = 60 Hz; 36-bit parallel data including a B data sequence and an R data sequence is formed, whereby a 36-bit word sequence data DVD12A or DTV having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps Get a 2A. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that constitute a segmented frame digital video signal having a segmented frame portion 2, a segmented frame 4, a segmented frame 6,... Thus, 36-bit word string data DVD12B or DTV12B having a word transmission rate of 74.25 MBps is obtained.
As shown in FIG. 27A, the 36-bit word sequence data DVD 12A or DTV 12A forms a B data sequence with 12-bit words GD0, GD1, GD2, GD3,... .. And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are parallel-multiplexed, and are linked. A is formed. Also, as shown in FIG. 27B, the 36-bit word string data DVD 12B or DTV 12B also includes the B data series including 12-bit words GD0, GD1, GD2, GD3,. , And 12-bit words RD0, RD1, RD2, RD3,..., Which constitute an R data sequence, are parallel-multiplexed. , Link B.
Subsequently, as shown in FIG. 27A, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 36-bit word string data DVD 12A or DTV 12A is constructed. .., And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are represented by the upper 10 bits G0. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0-1, G3 0-1, B1; 0-1, B2; 0-1, B3; 0-1,..., And R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, G1 are obtained by adding a 4-bit auxiliary bit f0. 0-1 and B1; 10 bits [GBR1; 0-1] + f1, G2; 0-1 obtained by multiplexing bits 0-1 and R1; 0-1 and adding 4 auxiliary bits f1. B2; 0-1 and R2; 0-1 are bit-multiplexed, and 10 bits [GBR2; 0] obtained by adding 4-bit auxiliary bit f2. 1] + f2, G3; 10 bits [GBR3; 0-1] + f3, obtained by multiplexing bits 0-1 and B3; 0-1 and R3; 0-1 and adding a 4-bit auxiliary bit f3. ... are formed.
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; , 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.
Then, 20-bit word string data DVD12A1 or DTV12A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link A-1 as shown in FIG. 29A. At the same time, a 20-bit word string data DVD 12A2 or DTV 12A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is used as a link A-2 as shown in FIG. Form.
Further, as shown in FIG. 27B, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 36-bit word string data DVD 12B or DTV 12B is constituted. .., And 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence, the upper 10 bits G0 are also set for each of the 12-bit words BD0, BD1, BD2, BD3,. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0- , G3; 0-1, ..., B0; 0-1, B1; 0-1, B2; 0-1, B3; 0-1, ..., and R0; , R1; 0-1, R2; 0-1, R3; 0-1,.
Next, the lower two 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; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, G1 are obtained by adding a 4-bit auxiliary bit f0. 0-1 and B1; 10 bits [GBR1; 0-1] + f1, G2; 0-1 obtained by multiplexing bits 0-1 and R1; 0-1 and adding 4 auxiliary bits f1. B2; 0-1 and R2; 0-1 are bit-multiplexed, and 10 bits [GBR2; 0] obtained by adding 4-bit auxiliary bit f2. 1] + f2, G3; 10 bits [GBR3; 0-1] + f3, obtained by multiplexing bits 0-1 and B3; 0-1 and R3; 0-1 and adding a 4-bit auxiliary bit f3. ... are formed.
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVD12B1 or DTV12B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link B-1 as shown in FIG. 29A. In addition, 20-bit word string data DVD12B2 or DTV12B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is used as a link B-2 as shown in FIG. Form.
That is, in the data processing unit 121, the data DVD12 or DTV12 forming the 36-bit word string data having the word transmission rate of 148.5 MBps is converted into the 20-bit word string data having the word transmission rate of 74.25 MBps. The data is converted into four-system word string data of DVD12A1, DVD12A2, DVD12B1 and DVD12B2, or DTV12A1, DTV12A2, DTV12B1 and DTV12B2.
When the digital data DVX is the data DVU 10 shown in FIG. 3, the data processing unit 121 sets the frame rate to 120 Hz, the number of effective lines in each frame to 1080, and the number of effective data samples in each line to 1920. A Y data sequence and a P data which form a set digital video signal of 4: 2: 2 format, each having a word transmission rate of 297 MBps and a quantization bit number of 10 bits. _B / P _R A data series is input.
When the digital data DVX is the data DTU 10 shown in FIG. 4, the data processing unit 121 sets the frame rate to 120 Hz, the number of valid lines in each frame is 720, and the number of valid data samples in each line is 1280. A Y data sequence and a Y data sequence each having a word transmission rate of 297 MBps and a quantization bit number of 10 bits, each of which forms a digital video signal of 4: 2: 2 format set in the sample. _B / P _R A data series is input.
These data DVU10 or DTU10 constitute a Y data series and P _B / P _R As shown in FIG. 30, the data sequence is supplied to the data processing unit 121 as 20-bit parallel data with a word transmission rate of 297 MBps, which is obtained by performing parallel multiplexing under frame synchronization and line synchronization. .
The data processing unit 121 performs the following processing on the data DVU10 or DTU10 supplied as shown in FIG.
First, as shown in FIG. 30, the first every third frame part Frame 1, Frame 5, Frame 5, among the frame parts Frame 1, Frame 2, Frame 3,... Forming the data DVU10 or DTU10. Frame 9, Frame 6, Frame 10, Frame 10, Second third frame portion Frame 3, Frame 7, Frame 11, Third every third frame portion ,..., And the fourth every third frame part Frame 4, Frame 8, Frame 12,... Are stored in the memory A, the memory B, the memory C, and the memory D, respectively.
Next, each of the frame portions Frame 1, Frame 5, Frame 9,... Stored in the memory A is read out by the field interlace method, and a series of segments in which the frame rate is set to 120 Hz / 4 = 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal and have a segmented frame portion 1, a segmented frame 5, a segmented frame 9,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVU10A or DTU10A having a word transmission rate of 297 MBps / 4 = 74.25 MBps. Also, each of the frame portions Frame 2, Frame 6, Frame 10,... Stored in the memory B is read out by the field interlace method and a series of segmented frame portions Segmented at a frame rate of 30 Hz. .. Having a Frame 2, a Segmented Frame 6, a Segmented Frame 10,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVU10B or DTU10B having a word transmission rate of 74.25 MBps.
Similarly, each of the frame parts Frame 3, Frame 7, Frame 11,... Stored in the memory C is read out by the field interlace method, and a series of segmented frame parts in which the frame rate is set to 30 Hz. .. Having a Segmented Frame 3, a Segmented Frame 7, a Segmented Frame 11,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVU10C or DTU10C having a word transmission rate of 74.25 MBps. Further, each of the frame portions Frame 4, Frame 8, Frame 12,... Stored in the memory D is read out by the field interlace method, and a series of segmented frame portions Segmented in which the frame rate is set to 30 Hz. .. Having a Frame 4, Segmented Frame 8, Segmented Frame 12,... _B / P _R It is assumed that 20-bit parallel data including a data sequence is formed, thereby obtaining 20-bit word string data DVU10D or DTU10D having a word transmission rate of 74.25 MBps.
The 20-bit word string data DVU10A, DVU10B, DVU10C, and DVU10D, or DTU10A, DTU10B, DTU10C, and DTU10D, respectively, constitute a Y data sequence as shown in A, B, C, and D of FIG. , And the 10-bit words YD0, YD1, YD2, YD3,. _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are multiplexed in parallel and formed as links A, B, C and D.
That is, in the data processing unit 121, the data DVU10 or DTU10 forming the 20-bit word string data having the word transmission rate of 297 MBps is converted to the 20-bit word string data DVU10A, each of which has the word transmission rate of 74.25 MBps. The data is converted into word string data of four systems of DVU10B, DVU10C and DVU10D, or DTU10A, DTU10B, DTU10C and DTU10D.
When the digital data DVX is the data DVC10 + DKC10, the data processing unit 121 sets the frame rate to 50 Hz or 60 Hz, sets the number of effective lines in each frame to 1080 lines, and sets the number of effective data samples in each line to 1920 samples. , A Y data sequence and a Y data sequence each having a quantization bit number of 10 bits, a word transmission rate of 148.5 MBps, and a digital video signal of 4: 2: 2 format. _B / P _R A data sequence (DVC10) and a Key signal data sequence (DKC10) having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
When the digital data DVX is the data DTU10 + DYU10, the data processing unit 121 sets the frame rate to 120 Hz, sets the number of valid lines in each frame to 720, and sets the number of valid data samples in each line to 1280. , A Y data sequence and a Y data sequence each having a quantization bit number of 10 bits, a word transmission rate of 148.5 MBps, and a digital video signal of 4: 2: 2 format. _B / P _R A data sequence (DTU10) and a Key signal data sequence (DYU10) having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, the Y data series constituting these data DVC10 + DKC10 or DTU10 + DYU10, P _B / P _R As shown in FIG. 32, the data sequence and the Key signal data sequence (represented by 4: 2: 2: 4 format data) are word transmission obtained by parallel multiplexing under frame synchronization and line synchronization. The data is supplied to the data processing unit 121 as 30-bit parallel data having a rate of 148.5 MBps.
The data processing unit 121 performs the following processing on the data DVC10 + DKC10 or DTU10 + DYU10 supplied as shown in FIG.
First, as shown in FIG. 32, every other one of the frame parts Frame 1, Frame 2, Frame 3,... Forming the data DVC10 + DKC10 or DTU10 + DYU10. .. And the second alternate frame portion Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a Y data sequence and P having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 3, Segmented Frame 5,..., Of 120 Hz / 2 = 60 Hz, forming a segmented frame digital video signal _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVC10A + DKC10A or DTU10A + DYU10A having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. Y data sequence and segmented frame digital video signal having segmented frame 2, Segmented Frame 4, Segmented Frame 6,... _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVC10B + DKC10B or DTU10B + DYU10B having a word transmission rate of 74.25 MBps.
As shown in FIG. 33A, the 30-bit word string data DVC10A + DKC10A or DTU10A + DYU10A is composed of 10-bit words YD0, YD1, YD2, YD3,. _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series, and the 10-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel and formed as a link A. Further, as shown in FIG. 33B, the 30-bit word string data DVC10B + DKC10B or DTU10B + DYU10B also has 10-bit words YD0, YD1, YD2, YD3,. _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series, and the 10-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel and formed as a link B.
Then, as shown in FIG. 33A, the 10-bit words YD0, YD1, YD2, YD3,... Constituting the Y data series in the 30-bit word string data DVC10A + DKC10A or DTU10A + DYU10A, and P _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are multiplexed in parallel, and the word transmission rate is 74.25 MBps as shown in FIG. The 20-bit word string data DVCK10A1 or DTUY10A1 is formed as a link A-1. .., And auxiliary 10-bit words αD0, αD1, αD1, αD2, αD3, which constitute 10-bit words AD0, AD1, AD2, AD3,. ,... Are parallel-multiplexed to form 20-bit word string data DVCK10A2 or DTUY10A2 having a word transmission rate of 74.25 MBps as shown in FIG. 34B as a link A-2.
Also, as shown in B of FIG. 33, 10-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in 30-bit word string data DVC10B + DKC10B or DTU10B + DYU10B. _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are multiplexed in parallel, and the word transmission rate is 74.25 MBps as shown in FIG. The 20-bit word string data DVCK10B1 or DTUY10B1 is formed as a link B-1. Along with that, 10-bit words AD0, AD1, AD2, AD3,... Constituting a Key signal data sequence in 30-bit word string data DVC10B + DKC10B or DTU10B + DYU10B, and auxiliary 10-bit words αD0, αD1, αD2, αD3 ,... Are parallel-multiplexed to form 20-bit word string data DVCK10B2 or DTUY10B2 having a word transmission rate of 74.25 MBps as shown in FIG. 34B as link B-2.
That is, in the data processing unit 121, the data DVC10 + DKC10 or the data DTU10 + DYU10 forming the 30-bit word string data having the word transmission rate of 148.5 MBps, and the 20-bit word string having the word transmission rate of 74.25 MBps, respectively. The data DVCK10A1, DVCK10A2, DVCK10B1 and DVCK10B2 are converted into data or four-system word string data of DTUY10A1, DTUY10A2, DTUY10B1 and DTUY10B2.
When the digital data DVX is the data DVD10 + DKD10, the data processing unit 121 sets the frame rate to 50 Hz or 60 Hz, sets the number of valid lines in each frame to 1080 lines, and the number of valid data samples in each line to 1920 samples. A G data sequence, a B data sequence, and an R data sequence (DVD10), which form digital video signals of 4: 4: 4 format, each having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps, A Key signal data sequence (DKD10) having a data format equivalent to that of the G data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps is input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
When the digital data DVX is data DTV10 + DYV10, the data processing unit 121 sets the frame rate to 120 Hz, sets the number of effective lines in each frame to 720, and sets the number of effective data samples in each line to 1280. G data sequence, B data sequence, and R data sequence (DTV10), which form digital video signals of 4: 4: 4 format, each having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps, A Key signal data sequence (DYV10) having a data format equivalent to that of the G data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps is input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
A G data sequence, a B data sequence, an R data sequence, and a Key signal data sequence (expressed as 4: 4: 4: 4 format data) constituting these data DVD10 + DKD10 or DTV10 + DYV10 are as shown in FIG. Are supplied to the data processing unit 121 as 40-bit parallel data having a word transmission rate of 148.5 MBps, which is obtained by performing parallel multiplexing under frame synchronization and line synchronization.
The data processing section 121 performs the following processing on the data DVD10 + DKD10 or DTV10 + DYV10 supplied as shown in FIG.
First, as shown in FIG. 35, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVD 10 + DKD10 or DTV10 + DYV10, Frame 1, Frame 3, Frame 3, etc. .. And the second alternate frame portions Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a G data sequence and a B data which constitute a segmented frame digital video signal having a series of segmented frame portions 1, 2, 3, 4, 5,... Which are set to 120 Hz / 2 = 60 Hz. 40-bit parallel data including the sequence and the R data sequence and the Key signal data sequence, thereby forming 40-bit word string data D having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Get the D10A + DKD10A or DTV10A + DYV10A. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. A G data sequence, a B data sequence, an R data sequence, and a Key signal data sequence that constitute a segmented frame digital video signal having a Ted frame portion Segmented Frame 2, Segmented Frame 4, Segmented Frame 6,... 40-bit parallel data including a 10-bit word string data DVD10B + DKD10B or DTV10B + DYV10B having a word transmission rate of 74.25 MBps. .
The 40-bit word string data DVD10A + DKD10A or DTV10A + DYV10A is composed of 10-bit words GD0, GD1, GD2, GD3,..., And 10 constituting a G data series as shown in FIG. Bit data BD0, BD1, BD2, BD3,..., 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and 10 bits forming a Key signal data sequence The words AD0, AD1, AD2, AD3,... Are formed by parallel multiplexing and formed as a link A. Also, as shown in FIG. 36B, the 40-bit word string data DVD10B + DKD10B or DTV10B + DYV10B also forms 10-bit words GD0, GD1, GD2, GD3,... , And 10-bit words RD0, RD1, RD2, RD3,... Constituting a R data sequence and a Key signal data sequence The 10-bit words AD0, AD1, AD2, AD3,... Are parallel multiplexed and formed as a link B.
Subsequently, as shown in FIG. 36A, a 10-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 40-bit word string data DVD10A + DKD10A or DTV10A + DYV10A is constituted. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting a R data sequence and a Key signal data sequence Each of the 10-bit words AD0, AD1, AD2, AD3,... Is divided as indicated by a thick solid line in FIG. 37 to form 10-bit words GD0, GD1, GD2, GD3 forming a G data sequence. ,..., 10-bit words BD0, BD2,. And a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming a R data sequence, and 10-bit words AD0, AD1, AD2, AD3,. , A 10-bit word group 2 including 10-bit words BD1, BD3,... Forming a B data sequence and 10-bit words RD1, RD3,. Distribute to. Then, 20-bit word string data DVDK10A1 or DTVY10A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 37 is formed as a link A-1 as shown in FIG. 38A. At the same time, 20-bit word string data DVDK10A2 or DTVY10A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 37 is used as a link A-2 as shown in FIG. Form.
Also, as shown in FIG. 36B, a 10-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 40-bit word string data DVD10B + DKD10B or DTV10B + DYV10B. , Constituting 10-bit words BD0, BD1, BD2, BD3,..., R data series, and 10 constituting 10-bit words, Key signal data series Each of the bit words AD0, AD1, AD2, AD3,... Is divided as shown by a thick solid line in FIG. 37, and 10-bit words GD0, GD1, GD2, GD3 forming a G data sequence are formed. ....., 10-bit words BD0, BD2, ... forming a B data sequence .. and a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming a R data sequence, and 10-bit words AD0, AD1, AD2, AD3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence Distribute. Then, 20-bit word string data DVDK10B1 or DTVY10B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 37 is formed as a link B-1 as shown in FIG. 38A. At the same time, 20-bit word string data DVDK10B2 or DTVY10B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 37 is used as a link B-2 as shown in FIG. Form.
That is, in the data processing unit 121, the data DVD10 + DKD10 or DTV10 + DYV10 forming 40-bit word string data having a word transmission rate of 148.5 MBps is converted to the 20-bit word string data DVDK10A1 having a word transmission rate of 74.25 MBps. This is converted into word string data of four systems of DVDK10A2, DVDK10B1 and DVDK10B2, or DTVY10A1, DTVY10A2, DTVY10B1 and DTVY10B2.
Then, the data processing unit 121 includes a set of 20-bit word string data DVC12A1, DVC12A2, DVC12B1 and DVC12B2, a set of 20-bit word string data DVC14A1, DVC14A2, DVC14B1 and DVC14B2, and a 20-bit word string. A set of data DVC16A1, DVC16A2, DVC16B1 and DVC16B2, a set of 20-bit word string data DVD10A1, DVD10A2, DVD10B1 and DVD10B2, a set of 20-bit word string data DVD12A1, DVD12A2, DVD12B1 and DVD12B2, a 20-bit word string data DVU10A, DVU10B A set of DVU10C and DVU10D, 20-bit word string data DTU12A1, DTU12A , DTU12B1 and DTU12B2, 20-bit word string data DTU14A1, DTU14A2, DTU14B1 and DTU14B2, 20-bit word string data DTU16A1, DTU16A2, DTU16B1 and DTU16B2, 20-bit word string data DTV10A1, DTV10A2, DTV10B2 and DTV10B2. Set, set of 20-bit word string data DTV12A1, DTV12A2, DTV12B1 and DTV12B2, set of 20-bit word string data DTU10A, DTU10B, DTU10C and DTU10D, set of 20-bit word string data DVCK10A1, DVCK10A2, DVCK10B1 and DVCK10B2, 20 bits Column data DTUY10A1, DTUY10A2, One of the set of TUY10B1 and DTUY10B2, the set of 20-bit word string data DVDK10A1, DVDK10A2, DVDK10B1 and DVDK10B2, and the set of 20-bit word string data DTVY10A1, DTVY10A2, DTVY10B1 and DTVY10B2 is converted to 20-bit word string data DPA1 (20). ), DPA2 (20), DPB1 (20) and DPB2 (20).
The 20-bit word string data DPA1 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 121 is supplied to the data insertion unit 122. In the data insertion unit 122, the auxiliary data DAA1 including the necessary channel identification data is inserted into the 20-bit word string data DPA1 (20), and the 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 122 is supplied to the P / S conversion unit 123.
The P / S conversion unit 123 performs P / S conversion on the 20-bit word string data DPA1 ′ (20) to increase the bit transmission rate based on the 20-bit word string data DPA1 ′ (20) to 74.25 MBps × The serial data DSA1 with 20 = 1.485 Gbps is formed, and the serial data DSA1 is supplied to the E / O converter 124. The E / O conversion unit 124 performs an electro-optical conversion process on the serial data DSA1, and converts the optical signal OSA1 having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSA1 to a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
In addition, the data insertion units 125 and 128 and the 20-bit word string data DPA2 (20), DPB1 (20), and DPB2 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 121 are also used. 131, P / S converters 126, 129, and 132, and E / O converters 127, 130, and 133, respectively, to insert data 122, P for 20-bit word string data DPA1 (20). The same processing as the processing by the / S converter 123 and the E / O converter 124 is performed, and the center wavelength is set to, for example, approximately 1.3 μm from the E / O converters 127, 130, and 133, and bit transmission is performed. Optical signals OSA2, OSB1 and OSB2 having a rate of 1.485 Gbps are transmitted as transmission signals.
The optical signal OSA1, which is a transmission signal transmitted from the E / O converter 124, is guided to the optical fiber transmission line 136 through the optical connector 135, and is transmitted to the receiving side through the optical fiber transmission line 136. Further, optical signals OSA2, OSB1 and OSB2, which are transmission signals transmitted from the E / O converters 127, 130 and 133, are also guided to the optical fiber transmission lines 138, 140 and 142 through the optical connectors 137, 139 and 141, respectively. The light is transmitted to the receiving side through the optical fiber transmission lines 138, 140, and 142. Each of the optical fiber transmission lines 136, 138, 140 and 142 is formed using, for example, a quartz SMF.
On the receiving side, the optical signal OSA1 transmitted through the optical fiber transmission line 136 is guided to the O / E converter 144 via the optical connector 143. The optical signals OSA2, OSB1 and OSB2 transmitted through the optical fiber transmission lines 138, 140 and 142 are guided to the O / E converters 146, 148 and 150 through the optical connectors 145, 147 and 149, respectively.
The O / E converter 144 performs a photoelectric conversion process on the optical signal OSA1 having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OSA1. The serial data DSA1 having 1.485 Gbps is reproduced. Then, the reproduced serial data DSA1 is supplied to the S / P converter 151. The S / P converter 151 performs S / P conversion on the serial data DSA1, and reproduces 20-bit word string data DPA1 ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSA1. Then, it is supplied to the data time difference absorption unit 152.
In the O / E converters 146, 148, and 150, the optical signals OSA2, OSB1, and OSB2 each having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps are subjected to photoelectric conversion processing. Then, based on the optical signals OSA2, OSB1 and OSB2, the serial data DSA2, DSB1 and DSB2 each having a bit transmission rate of 1.485 Gbps are reproduced. Then, the reproduced serial data DSA2, DSB1 and DSB2 are supplied to S / P converters 153, 154 and 155, respectively. The S / P converters 153, 154 and 155 perform S / P conversion on the serial data DSA2, DSB1 and DSB2, and based on the serial data DSA2, DSB1 and DSB2, each have a word transmission rate of 74.25 Mbps. The 20-bit word string data DPA2 ′ (20), DPB1 ′ (20), and DPB2 ′ (20) to be reproduced are supplied to the data time difference absorption unit 152.
In the data time difference absorbing section 152, the 20-bit word string data DPA1 '(20), DPA2' (20), DPB1 '(20) and DPB2' (20) from the S / P converters 151, 153, 154 and 155 are output. 20) absorbs the mutual time difference generated during 20), and each of them is based on each of the 20-bit word string data DPA1 '(20), DPA2' (20), DPB1 '(20) and DPB2' (20), and has a word transmission rate. Of the 20-bit word string data DPA1Q ′ (20), DPA2Q ′ (20), DPB1Q ′ (20), and DPB2Q ′ (20), which is set to 74.25 MBps, can be maintained in a state where there is substantially no mutual time difference. Sent out as intended.
The 20-bit word string data DPA1Q '(20), DPA2Q' (20), DPB1Q '(20), and DPB2Q' (20) obtained from the data time difference absorbing unit 152 are data separating units 156, 157, 158, and 159, respectively. Supplied to In the data separation unit 156, 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 separately transmitted. The bit word string data DPA1Q (20) is supplied to the data reproduction processing unit 160. In the data separation units 157, 158 and 159, the auxiliary data DAA2, DAB1 and DAB2 are separated from the 20-bit word string data DPA2Q '(20), DPB1Q' (20) and DPB2Q '(20), respectively. Then, the 20-bit word string data DPA2Q (20), DPB1Q (20) and DPB2Q (20) and the auxiliary data DAA2, DAB1 and DAB2 are individually transmitted, and the 20-bit word string data DPA2Q (20) and DPB1Q (20) ) And DPB2Q (20) are supplied to the data reproduction processing unit 160.
In the data reproduction processing unit 160, the data processing unit 121 on the transmission side converts the 20-bit word string data DPA1Q (20), DPA2Q (20), DPB1Q (20), and DPB2Q (20) into digital data DVX. A data reproduction process reverse to the data conversion process to be performed is performed to reproduce digital data DVX based on the 20-bit word string data DPA1Q (20), DPA2Q (20), DPB1Q (20), and DPB2Q (20). The digital data DVX reproduced in this manner includes the data DVC12, DVC14, DVC16, DVD10, DVD12, and DVU10 shown in FIG. 3, and the data DTU12, DTU14, DTU16, DYV10, DTV12, and DTU10 shown in FIG. Further, it is any one of data DVC10 + DKC10, data DVD10 + DKD10, data DTU10 + DYU10, and data DTV10 + DYV10.
In the above description, in the data forming the digital video signal having a quantization bit number of 12 bits or more, the upper 10-bit column divided from each of the 12-bit, 14-bit, and 16-bit words constituting the Y data sequence , P _B / P _R 20-bit word string data DVC12A1, DVC14A1 and DVC16A1, or 20-bit word string data formed by parallel multiplexing a 12-bit, 14-bit or 16-bit word divided from each of the 12-bit, 14-bit or 16-bit word constituting the data sequence The word string data DTU12A1, DTU14A1 and DTU16A1 and the like are formed based on the upper 10-bit column divided from each of the 12-bit words constituting each of the G, B and R data sequences. Each of the bit word string data DVD12A1 and DVD12B1, or the 20-bit word string data DTV12A1 and DTV12B1 is, for example, a magnetic recording / reproducing device for HD digital video signals (referred to as a VTR for HD). Those capable of performing recording and reproduction. Therefore, using the current HD VTR, confirmation and editing of the contents of the 20-bit word string data DVC12A1, DVC14A1, DVC16A1, DTU12A1, DTU14A1, DTU16A1, DVD12A1, DVD12B1, DTV12A1, DTV12B1, etc. are performed. Further, using a current HD VTR and a video monitor, a reproduced image based on 20-bit word string data DVC12A1, DVC14A1, DVC16A1, DTU12A1, DTU14A1, DTU16A1, DVD12A1, DVD12B1, DTV12A1, DTV12B1, etc. It can be used to check data using a current device when handling data forming a digital video signal with a quantization bit number of 12 bits or more. Supposed to be able to be carried out, it is extremely convenient.
FIG. 39 is a diagram illustrating a data transmission method according to the present invention in which an example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission method according to the present invention is implemented. Of the data transmission / reception device including a second example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission device according to the present invention. .
The data transmission / reception device whose part is shown in FIG. 39 has many parts configured similarly to the data transmission / reception device shown in FIGS. 17 and 18, and FIG. 39 shows the data transmission / reception device shown in FIGS. Only the parts different from the data transmitting / receiving device and the parts related thereto are shown.
In the data transmission / reception device whose part is shown in FIG. 39, the E / O conversion units 124, 127, 130 and 133 provided in the data transmission / reception device shown in FIGS. E / O converters 162 and 164 and O / E converters 170 and 173 are provided in place of 144, 146, 148 and 150. Further, the optical connectors 135, 137, 139, and 141, the optical fiber transmission lines 136, 138, 140, and 142, and the optical connectors 143, 145, 147, and 149 provided in the data transmission / reception devices shown in FIGS. , Optical connectors 165 and 167, optical fiber transmission lines 166 and 168, and optical connectors 169 and 172. Each of the optical fiber transmission lines 166 and 168 is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 39, the serial data DSA1 whose bit transmission rate from the P / S converter 123 is 1.485 Gbps and the bit transmission rate from the P / S converter 126 are 1. The serial data DSA2 at 485 Gbps is supplied to the bit multiplexing unit 161. The bit multiplexing section 161 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSA1 and DSA2, and performing bit multiplexing and combining processing on the serial data DSA1 and DSA2 to reduce the bit transmission rate. The composite serial data DZA with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZA obtained from the bit multiplexing unit 161 is supplied to the E / O conversion unit 162. In the E / O converter 162, an optical signal OZA having a center wavelength of, for example, about 1.3 μm based on the composite serial data DZA is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Also, the serial data DSB1 from the P / S conversion unit 129 at a bit transmission rate of 1.485 Gbps and the serial data DSB2 from the P / S conversion unit 132 at a bit transmission rate of 1.485 Gbps are combined into a bit multiplexing unit 163. Supplied to The bit multiplexing unit 163 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSB1 and DSB2, and performing bit multiplexing and combining processing on the serial data DSB1 and DSB2 to reduce the bit transmission rate. The composite serial data DZB with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZB obtained from the bit multiplexing unit 163 is supplied to the E / O conversion unit 164. In the E / O converter 164, an optical signal OZB having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZB is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Under these circumstances, the bit multiplexing units 161 and 163 and the E / O conversion units 162 and 164 convert the serial data DSA1, DSA2, DSB1 and DSB2 obtained from the P / S conversion units 123, 126, 129 and 132, respectively. A data transmitting unit for transmitting the data is formed.
The optical signal OZA, which is a transmission signal transmitted from the E / O converter 162, is guided to the optical fiber transmission line 166 through the optical connector 165, and is transmitted to the receiving side through the optical fiber transmission line 166. The optical signal OZB, which is a transmission signal transmitted from the E / O converter 164, is guided to the optical fiber transmission line 168 through the optical connector 167, and is transmitted to the receiving side through the optical fiber transmission line 168.
On the receiving side, the optical signal OZA transmitted through the optical fiber transmission line 166 is guided to the O / E converter 170 through the optical connector 169, and the optical signal OZB transmitted through the optical fiber transmission line 168 is converted into the optical connector 172. To the O / E converter 173. The O / E conversion unit 170 performs a photoelectric conversion process on the optical signal OZA having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and obtains a bit transmission rate based on the optical signal OZA. The composite serial data DZA at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZA is supplied to the bit separation unit 171. The O / E conversion unit 173 performs a photoelectric conversion process on the optical signal OZB having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and adjusts the bit transmission rate based on the optical signal OZB. The composite serial data DZB at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZB is supplied to the bit separation unit 174.
The bit separation unit 171 takes out one bit at a time from the composite serial data DZA, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZA. Then, a channel is specified by using the channel identification data included in the composite serial data DZA, and based on the composite serial data DZA, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSA1 and DSA2 are formed. The serial data DSA1 is supplied to the S / P converter 151, and the serial data DSA2 is supplied to the S / P converter 153.
The bit separation unit 174 takes out one bit at a time from the composite serial data DZB, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZB. Then, a channel is specified by using the channel identification data included in the composite serial data DZB, and based on the composite serial data DZB, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSB1 and DSB2 are formed. The serial data DSB1 is supplied to the S / P converter 154, and the serial data DSB2 is supplied to the S / P converter 155.
Other operations are the same as those of the data transmission / reception device whose part is shown in FIGS.
FIG. 40 is a diagram illustrating an example in which any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission method according to the present invention is implemented. 11 shows a part of a data transmission / reception device including a third example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission device according to the present invention. .
The data transmission / reception device whose part is shown in FIG. 40 has many parts configured similarly to the data transmission / reception device whose part is shown in FIG. 39, and FIG. 40 shows the data transmission / reception device shown in FIG. Blocks corresponding to the respective blocks in the portion are denoted by the same reference numerals as in FIG. 39, and redundant description thereof will be omitted.
In the data transmitting / receiving apparatus whose part is shown in FIG. 40, composite serial data DZB having a bit transmission rate of 2.97 Gbps from bit multiplexing section 163 is supplied to E / O conversion section 175. In the E / O converter 175, an optical signal OZB having a center wavelength of, for example, about 1.55 μm based on the composite serial data DZB is formed with a bit transmission rate of 2.97 Gbps.
An optical signal OZA from the E / O converter 162 having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and a center wavelength from the E / O converter 175 of about 1.55 μm, The optical signal OZB having a bit transmission rate of 2.97 Gbps is guided to the multiplexing unit 176. The multiplexing unit 176 is formed by, for example, a dielectric multilayer WDM coupler. In the multiplexing unit 176, the optical signal OZA having a center wavelength of about 1.3 μm and the optical signal OZB having a center wavelength of about 1.55 μm are multiplexed and multiplexed, and the multiplexed optical signal OZAB is formed. And transmit it as a transmission signal. Under these circumstances, E / O conversion sections 162 and 175 and multiplexing section 176 transmit serial data DSA1, DSA2, DSB1 and DSB2 obtained from P / S conversion sections 123, 126, 129 and 132, respectively. A data transmission unit for transmitting the data is formed.
The multiplexed optical signal OZAB, which is a transmission signal transmitted from the multiplexing unit 176, is guided through the optical connector 177 to an optical fiber transmission line 178 formed using, for example, a silica-based SMF, and is received through the optical fiber transmission line 178. Transmitted to.
On the receiving side, the multiplexed optical signal OZAB transmitted through the optical fiber transmission line 178 is guided to the demultiplexing unit 180 through the optical connector 179. The branching unit 180 is formed by using, for example, a dielectric multilayer WDM coupler as a branching unit. In the demultiplexing unit 180, the multiplexed optical signal OZAB 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, and the bit transmission rate is set to 2 An optical signal OZA having a center wavelength of about 1.3 μm and an optical signal OZB having a bit transmission rate of 2.97 Gbps and a center wavelength of about 1.55 μm is reproduced.
The optical signals OZA and OZB reproduced by the demultiplexer 180 are guided to O / E converters 170 and 181 respectively. The O / E converter 181 performs a photoelectric conversion process on the optical signal OZB having a center wavelength of about 1.55 μm and a bit transmission rate of 2.97 Gbps, and adjusts the bit transmission rate based on the optical signal OZB. The composite serial data DZB at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZB is supplied to the bit separation unit 174. Other operations are the same as those of the data transmitting / receiving device whose part is shown in FIG.
FIG. 41 is a diagram illustrating a data transmission method according to the present invention, in which an example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission method according to the present invention is implemented. Of the data transmission / reception device including a fourth example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission device according to the present invention. .
The data transmission / reception device whose part is shown in FIG. 41 has many parts configured similarly to the data transmission / reception device shown in FIGS. 17 and 18, and FIG. 41 shows the data transmission / reception device shown in FIGS. Only the parts different from the data transmitting / receiving device and the parts related thereto are shown.
In the data transmission / reception device whose part is shown in FIG. 41, the E / O conversion units 124, 127, 130 and 133 provided in the data transmission / reception device shown in FIGS. E / O converters 124C, 127C, 130C, and 133C, and O / E converters 144C, 146C, 148C, and 150C are provided instead of 144, 146, 148, and 150. Further, the optical connectors 135, 137, 139, and 141, the optical fiber transmission lines 136, 138, 140, and 142, and the optical connectors 143, 145, 147, and 149 provided in the data transmission / reception devices shown in FIGS. Instead, a multiplexing unit 176C, an optical connector 177C, an optical fiber transmission line 178C, an optical connector 179C, and a demultiplexing unit 180C are provided. The optical fiber transmission line 178C is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 41, the bit transmission rate from serial data DSA1 and P / S conversion section 126 is 1.485 Gbps from P / S conversion section 123. Serial data DSA2 at 485 Gbps, serial data DSB1 at a bit transmission rate of 1.485 Gbps from the P / S converter 129, and serial data DSB2 at a bit transmission rate of 1.485 Gbps from the P / S converter 132, The signals are supplied to the E / O converters 124C, 127C, 130C, and 133C, respectively.
The E / O conversion unit 124C forms an optical signal OZA1 having a center wavelength of, for example, approximately 1.511 μm based on the serial data DSA1 as having a bit transmission rate of 1.485 Gbps, and combines the optical signal OZA1 with the multiplexed unit. 176C. The E / O conversion unit 127C forms an optical signal OZA2 having a center wavelength of, for example, approximately 1.531 μm based on the serial data DSA2 as a signal having a bit transmission rate of 1.485 Gbps, and combines it with a multiplexing unit. 176C. The E / O conversion unit 130C forms an optical signal OZB1 having a center wavelength of, for example, approximately 1.551 μm based on the serial data DSB1 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OZB1 with the multiplexed unit. 176C. Further, the E / O conversion unit 133C forms an optical signal OZB2 having a center wavelength of, for example, approximately 1.571 μm based on the serial data DSB2 as a signal having a bit transmission rate of 1.485 Gbps, and combines them. It supplies to wave part 176C.
In the multiplexing unit 176C, the optical signal OZA1 having a center wavelength of about 1.511 μm, the optical signal OZA having a center wavelength of about 1.531 μm, the optical signal OZB1 having a center wavelength of about 1.551 μm, and the center wavelength Are combined and multiplexed to form a multiplexed optical signal OZX, which is transmitted as a transmission signal. Under these circumstances, the E / O conversion units 124C, 127C, 130C, and 133C and the multiplexing unit 176C combine the serial data DSA1, DSA2, DSB1 and DSA1, DSA2, DSB1 obtained from the P / S conversion units 123, 126, 129, and 132, respectively. A data transmission section for transmitting DSB2 is formed.
In this way, the optical signals OZA1, OZA2, OZB1 and OZB2 multiplexed in the multiplexing unit 176C are very close to each other, with their center wavelengths only being separated by about 0.020 μm (20 nm). It is supposed that the multiplexed optical signal OZX is formed based on the multiplexed signal having the wavelength, and the portion including the E / O converters 124C, 127C, 130C and 133C and the multiplexing unit 176C has the CWMD. A so-called wavelength multiplexing technique is used.
The multiplexed optical signal OZX, which is a transmission signal transmitted from the multiplexing unit 176C, is guided to the optical fiber transmission line 178C through the optical connector 177C, and is transmitted to the receiving side through the optical fiber transmission line 178C.
On the receiving side, the multiplexed optical signal OZX transmitted through the optical fiber transmission line 178C is guided to the demultiplexer 180C through the optical connector 179C. In the demultiplexing unit 180C, the multiplexed optical signal OZX is converted 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. Is divided into a component of about 1.571 μm, the bit transmission rate is 1.485 Gbps, the optical signal OZA1 has a center wavelength of about 1.511 μm, the bit transmission rate is 1.485 Gbps, and the center wavelength is about An optical signal OZA2 having 1.531 μm, a bit transmission rate of 1.485 Gbps, an optical signal OZB1 having a center wavelength of about 1.551 μm, and a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.571 μm. The optical signal OZB2 to be reproduced is reproduced.
The optical signals OZA1, OZA2, OZB1 and OZB2 reproduced by the demultiplexer 180C are guided to O / E converters 144C, 146C, 148C and 150C, respectively. The O / E converter 144C performs a photoelectric conversion process on the optical signal OZA1 having a center wavelength of about 1.511 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OZA1. The serial data DSA1 having 1.485 Gbps is reproduced. In the O / E conversion unit 146C, the optical signal OZA2 having a center wavelength of about 1.531 μm and a bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing to obtain a bit transmission rate based on the optical signal OZA2. 1. Reproduce the serial data DSA2 at 485 Gbps. In the O / E converter 148C, the optical signal OZB1 having a center wavelength of about 1.551 μm and a bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing, and the bit transmission rate based on the optical signal OZB1 is calculated. 1. Reproduce the serial data DSB1 at 485 Gbps. Further, in the O / E converter 150C, the optical signal OZB2 having a center wavelength of about 1.571 μm and a bit transmission rate of 1.485 Gbps is subjected to photoelectric conversion processing, and bit transmission based on the optical signal OZB2 is performed. The serial data DSB2 having a rate of 1.485 Gbps is reproduced.
The serial data DSA1 from the O / E converter 144C, the serial data DSA2 from the O / E converter 146C, the serial data DSB1 from the O / E converter 148C, and the serial data DSB2 from the O / E converter 150C are represented by S / P converters 151, 153, 154 and 155, respectively.
Other operations are the same as those of the data transmission / reception device whose parts are shown in FIGS.
FIGS. 42 and 43 show examples in which any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. And a data transmission / reception device including a first example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. Show the part.
In the data transmission / reception device shown in FIGS. 42 and 43, digital data DVX forming a digital video signal is supplied to the data processing unit 191 on the transmission side forming an example of the data transmission device according to the present invention.
The digital data DVX includes data DVR12, DVR14, DVR16, DVS10 and DVS12 shown in FIG. 3, data DTR12, DTR14, DTR16, DTS10 and DTS12 shown in FIG. Data DTR10 + DYR10, DTU12 + DYU12, DTU14 + DYU14, DTU16 + DYU16, DTV12 + DYV12 and DTS10 + DYS10.
When the digital data DVX is the DVR 12 shown in FIG. 3, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of valid lines in each frame is 1080, and the number of valid data samples in each line is A Y data sequence and a Y data sequence each forming a digital video signal of 4: 2: 2 format set to 1920 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 12 bits. _B / P _R A data series is input.
When the digital data DVX is the DTR 12 shown in FIG. 4, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, 720 effective lines in each frame, and 720 effective data samples in each line. A Y data sequence and a Y data sequence, each having a word transmission rate of 222.75 MBps and a quantization bit number of 12 bits, form a digital video signal of 4: 2: 2 format in which the number is set to 1280 samples. _B / P _R A data series is input.
These data DVR12 or DTR12 constitute a Y data series and P _B / P _R As shown in FIG. 44, the data sequence is supplied to the data processing unit 191 as 24-bit parallel data having a word transmission rate of 222.75 MBps, which is obtained by performing parallel multiplexing under frame synchronization and line synchronization. Is done.
The data processing unit 191 performs the following processing on the data DVR12 or DTR12 supplied as shown in FIG.
44. First, as shown in FIG. 44, of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVR12, the first alternate frame portions Frame 1, Frame 4, Frame 7 are formed. ,..., The second alternate frame portion Frame 2, Frame 5, Frame 8,..., And the third alternate frame portion Frame 3, Frame 6, Frame 9 ,... Are stored in the memories A, B, and C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a Y data sequence and P having a series of segmented frame sections, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,..., At 90 Hz / 3 = 30 Hz, forming a segmented frame digital video signal. _B / P _R It is assumed that 24-bit parallel data including a data sequence is formed, thereby obtaining 24-bit word string data DVR12A or DTR12A having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps. Also, each of the frame portions Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by a field interlace method, and a series of segmented operations is performed by setting the frame rate to 24 Hz, 25 Hz, or 30 Hz. .. Having a frame part Segmented Frame 2, Segmented Frame 5, Segmented Frame 8,... _B / P _R It is assumed that 24-bit parallel data including a data sequence is formed, thereby obtaining 24-bit word string data DVR12B or DTR12B having a word transmission rate of 74.25 MBps. Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal and have a segmented frame portion 3, a segmented frame 6, a segmented frame 9,... _B / P _R It is assumed that 24-bit parallel data including a data sequence is formed, thereby obtaining 24-bit word string data DVR12C or DTR12C having a word transmission rate of 74.25 MBps.
The 24-bit word string data DVR12A, DVR12B and DVR12C or DTR12A, DTR12B and DTR12C are respectively 12-bit words YD0, YD1, YD2 and YD2 constituting a Y data sequence as shown in A, B and C of FIG. YD3, ... and P _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are parallel-multiplexed and formed as links A, B and C.
Subsequently, as shown in FIG. 45A, 12-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in the 24-bit word string data DVR12A or DTR12A. _B / P _R Each of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence is represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; ... and Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11, ... ... and lower two 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,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVR12A1 or DTR12A1 having a transmission rate of 74.25 MBps is formed as a link A-1 as shown in FIG. 46A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. 10-bit string: [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 parallel-multiplexed, and the 20-bit word string data DVR12A2 or DTR12A2 having a word transmission rate of 74.25 MBps is used as a link A-2 as a link A-2 in FIG. It is formed as shown in FIG.
Similarly, as shown in FIG. 45B, the 12-bit words YD0, YD1, YD2, YD3,... And P forming the Y data series in the 24-bit word string data DVR12B or DTR12B. _B / P _R Each of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence is represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; ... and Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11, ... ... and lower two 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,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVR12B1 or DTR12B1 having a rate of 74.25 MBps is formed as a link B-1 as shown in FIG. 46A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. 10-bit string: [Pb0; 0-1] + d0, [Pr0; 0-1] + d1, [Pb1; 0-1] + d2, [Pr1; 0-1] + d3, [Pb2; 0-1] + d4 46 are parallel-multiplexed with [Pr2; 0-1] + d5,. It is formed as shown in FIG.
Further, as shown in FIG. 45C, 12-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in the 24-bit word string data DVR12C or DTR12C. _B / P _R Each of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence is represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; ... and Pb0; 2-11, Pr0; 2-11, Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11, ... ... and lower two 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,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVR12C1 or DTR12C1 having a rate of 74.25 MBps is formed as a link C-1 as shown in FIG. 46A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. Bit sequence: [Pb0; 0-1] + d0, [Pr0; 0-1] + d1, [Pb1; 0-1] + d2, [Pr1; 0-1] + d3, [Pb2; 0-1] + d4, [ .., And 20-bit word string data DVR12C2 or DTR12C2 having a word transmission rate of 74.25 MBps as a link C-2 in FIG. 46B. Form as shown.
That is, in the data processing unit 191, data DVR12 or DTR12 forming 24-bit word string data having a word transmission rate of 222.75 MBps is converted to 20-bit word string data having a word transmission rate of 74.25 MBps. DVR12A1, DVR12A2, DVR12B1, DVR12B2, DVR12C1, and DVR12C2, or 20-bit word string data DTR12A1, DTR12A2, DTR12B1, DTR12B2, DTR12C1, and DTR12C2 are converted into six types of word string data.
When the digital data DVX is the data DVR14 or DVR16 shown in FIG. 3, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080, and the effective data in each line is 1080. A Y data sequence that forms a 4: 2: 2 digital video signal with the number of samples set to 1920, each having a word transmission rate of 222.75 MBps and a quantization bit number of 14 or 16 bits And P _B / P _R A data series is input.
When the digital data DVX is the data DTR14 or DTR16 shown in FIG. 4, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the number of lines in each line is 720. A digital video signal of 4: 2: 2 format in which the number of valid data samples is set to 1280 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 14 bits or 16 bits Y Data series and P _B / P _R A data series is input.
The data DVR14 or DVR16 or the Y data series and DTR14 _B / P _R The data sequence is supplied to the data processing unit 191 as 28-bit parallel data or 32-bit parallel data with a word transmission rate of 222.75 MBps, which is obtained by performing parallel multiplexing under frame synchronization and line synchronization.
In such a case, the data processing unit 191 performs the same processing on the data DVR14 or DVR16 or DTR14 or DTR16 as in the case of the data DVR12 or DTR12. Where Y data series and P _B / P _R Instead of dividing each of the 12-bit words constituting the data sequence into upper 10 bits and lower 2 bits, a Y data sequence and a P data _B / P _R The operation of dividing each of the 14-bit words constituting the data sequence into upper 10 bits and lower 4 bits, or the Y data sequence and P _B / P _R An operation of dividing each of the 16-bit words constituting the data sequence into upper 10 bits and lower 6 bits is performed.
Then, data DVR14 or DVR16 or DTR14 or DTR16 forming 28-bit word string data or 32-bit word string data having a word transmission rate of 222.75 MBps, and a 20-bit word string having a word transmission rate of 74.25 MBps, respectively. Data DVR14A1 or DVR16A1, DVR14A2 or DVR16A2, DVR14B1 or DVR16B1, DVR14B2 or DVR16B2, DVR14C1 or DVR16C1, DVR14C2 or DVR16C2, or 20-bit word string data DTR14A1 or DTR14A1 or DTR16D1 B2, converted DTR14C1 or DTR16C1, DTR14C2 or the 6 strains word sequence data DTR16C2.
When the digital data DVX is the data DVS10 shown in FIG. 3, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of valid lines in each frame is 1080, and the number of valid data samples in each line is Form a digital video signal of 4: 4: 4 format with 1920 samples set, each having a word transmission rate of 222.75 MBps and a quantization bit number of 10 bits, a G data sequence, a B data sequence and an R data sequence. A data series is input.
When the digital data DVX is the data DTS 10 shown in FIG. 4, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the effective data in each line is 720. A G data sequence and a B data sequence each forming a digital video signal of 4: 4: 4 format with the number of samples set to 1280, each having a word transmission rate of 222.75 MBps and a quantization bit number of 10 bits And the R data series are input.
As shown in FIG. 47, the G data sequence, the B data sequence, and the R data sequence constituting these data DVS10 or DTS10 are obtained by parallel multiplexing under frame synchronization and line synchronization. Is supplied to the data processing unit 191 as 30-bit parallel data having a value of 222.75 MBps.
The data processing unit 191 performs the following processing on the data DVS10 or DTS10 supplied as shown in FIG.
47. First, as shown in FIG. 47, of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVS10 or DTS10, every first two frame portions Frame 1, Frame 4,. Frame 7, Frame 2, Frame 5, Frame 8, Frame 8, and so on, and third and third frame portions Frame 3, Frame 6, Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. G data sequence and B data forming a segmented frame digital video signal having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,... With 90 Hz / 3 = 30 Hz. 30-bit parallel data including a sequence and an R data sequence, whereby 30-bit word string data DVS10A or DTS1 having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps Get the A. Also, each of the frame portions Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by a field interlace method, and a series of segmented operations is performed by setting the frame rate to 24 Hz, 25 Hz, or 30 Hz. Forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence, which form a segmented frame digital video signal, having a frame section Segmented Frame 2, Segmented Frame 5, Segmented Frame 8,... Thus, 30-bit word string data DVS10B or DTS10B having a word transmission rate of 74.25 MBps is obtained. Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by a field interlace method, and a series of segmented operations is performed in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. Forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence, which form a segmented frame digital video signal, having a frame section Segmented Frame 3, Segmented Frame 6, Segmented Frame 9,... Thus, 30-bit word string data DVS10C or DTS10C having a word transmission rate of 74.25 MBps is obtained.
The 30-bit word string data DVS10A, DVS10B, and DVS10C, or the DTS10A, DTS10B, and DTS10C are 10-bit words GD0, GD1, GD2, and GD2 that form a G data sequence as shown in A, B, and C of FIG. , And 10-bit words BD0, BD1, BD2, BD3,... Forming a B data sequence, and 10-bit words RD0, RD1, RD2, RD3, forming an R data sequence .. Are formed as parallel links A, B, and C.
Subsequently, as shown in FIG. 48A, 10-bit words GD0, GD1, GD2, GD3,..., And B data series constituting a G data series in 30-bit word string data DVS10A or DTS10A are constituted. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and auxiliary data added to the 10-bit words BD0, BD1, BD2, BD3,. The auxiliary 10-bit words ad0, ad1, ad2, ad3,... Constituting the sequence are divided as separated by a thick solid line in FIG. 24 to form a 10-bit word GD0 forming a G data sequence. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. The 10-bit word group 1 including the 10-bit words RD0, RD2,... Forming the R data sequence, and the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence. Then, 20-bit word string data DVS10A1 or DTS10A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link A-1 as shown in FIG. 49A. At the same time, 20-bit word string data DVS10A2 or DTS10A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link A-2 as shown in FIG. Form.
Also, as shown in FIG. 48B, 10-bit words GD0, GD1, GD2, GD3,..., And B data series that constitute a G data series in the 30-bit word string data DVS10B or DTS10B. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and an auxiliary data sequence added thereto Are divided in such a manner as to be separated by a thick solid line in FIG. 24, and a 10-bit word GD0 that forms a G data sequence is also divided into the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. ··· and a 10-bit word group 1 including 10-bit words RD0, RD2, ··· forming an R data sequence and auxiliary 10-bit words ad0, ad1, ad2, ad3, ··· forming an auxiliary data sequence .. and 10-bit word groups 2 including 10-bit words BD1, BD3,... Forming the B data sequence and 10-bit words RD1, RD3,. . Then, 20-bit word string data DVS10B1 or DTS10B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link B-1 as shown in FIG. 49A. At the same time, 20-bit word string data DVS10B2 or DTS10B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link B-2 as shown in FIG. Form.
Further, as shown in C of FIG. 48, the 10-bit words GD0, GD1, GD2, GD3,..., And the B data series that constitute the G data series in the 30-bit word string data DVS10C or DTS10C are constructed. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and an auxiliary data sequence added thereto Are divided in such a manner as to be separated by a thick solid line in FIG. 24, and a 10-bit word GD0 that forms a G data sequence is also divided into the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. .. and a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming an R data sequence, and auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence Distribute. Then, 20-bit word string data DVS10C1 or DTS10C1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link C-1 as shown in FIG. 49A. At the same time, 20-bit word string data DVS10C2 or DTS10C2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link C-2 as shown in FIG. Form.
That is, in the data processing unit 191, the data DVS10 or DTS10 forming the 30-bit word string data with the word transmission rate of 222.75 MBps is converted to the 20-bit word string data DVS10A1, with the word transmission rate of 74.25 MBps. The data is converted into six-system word string data of DVS10A2, DVS10B1, DVS10B2, DVS10C1, and DVS10C2, or DTS10A1, DTS10A2, DTS10B1, DTS10B2, DTS10C1, and DTS10C2.
When the digital data DVX is data shown as the data DVS12 shown in FIG. 3, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080 lines, and A G data sequence that forms a 4: 4: 4 format digital video signal in which the number of valid data samples is set to 1920 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 12 bits, B A data sequence and an R data sequence are input.
When the digital data DVX is data indicated as the data DTS12 shown in FIG. 4, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, and sets the number of effective lines in each frame to 720 lines. A G data sequence that forms a 4: 4: 4 format digital video signal in which the number of valid data samples in a line is set to 1280, and each has a word transmission rate of 222.75 MBps and a quantization bit number of 12 bits , B data sequence and R data sequence are input.
As shown in FIG. 50, the G data sequence, the B data sequence, and the R data sequence constituting these data DVS12 or DTS12 are word transmission rates obtained by performing parallel multiplexing under frame synchronization and line synchronization. Is supplied to the data processing unit 191 as 36-bit parallel data having a value of 222.75 MBps.
The data processing unit 191 performs the following processing on the data DVS12 or DTS12 supplied as shown in FIG.
First, as shown in FIG. 50, the first two frame parts Frame 1, Frame 4, Frame 4, Frame 3, Frame 2, Frame 3, etc. forming the data DVS12 or DTS12 are formed. .., The second alternate frame portion Frame 2, Frame 5, Frame 8,..., And the third alternate frame portion Frame 3, Frame 6, Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a G data sequence and a B data which form a segmented frame digital video signal having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,... With 90 Hz / 3 = 30 Hz. 36-bit parallel data including the data sequence and the R data sequence, thereby forming 36-bit word string data DVS12A or DTS1 having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps. Get the A. Also, each of the frame portions Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by a field interlace method, and a series of segmented operations is performed by setting the frame rate to 24 Hz, 25 Hz, or 30 Hz. Forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence, which form a segmented frame digital video signal, having a frame section Segmented Frame 2, Segmented Frame 5, Segmented Frame 8,... Accordingly, 36-bit word string data DVS12B or DTS12B having a word transmission rate of 74.25 MBps is obtained. Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by a field interlace method, and a series of segmented operations is performed in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. Forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence, which form a segmented frame digital video signal, having a frame section Segmented Frame 3, Segmented Frame 6, Segmented Frame 9,... Thereby, 36-bit word string data DVS12C or DTS12C having a word transmission rate of 74.25 MBps is obtained.
The 36-bit word string data DVS12A, DVS12B, and DVS12C, or the DTS12A, DTS12B, and DTS12C are 12-bit words GD0, GD1, and GD2 that form a G data sequence, respectively, as shown in A, B, and C of FIG. , GD3,..., 12-bit words BD0, BD1, BD2, BD3,... Constituting the B data sequence, and 12-bit words RD0, RD1, RD2, RD3 constituting the R data sequence ,... Are formed as links A, B and C by parallel multiplexing.
Subsequently, as shown in FIG. 51A, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 36-bit word string data DVS12A or DTS12A is constituted. .., And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are represented by the upper 10 bits G0. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0-1, G3 0-1, B1; 0-1, B2; 0-1, B3; 0-1,..., And R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, G1 are obtained by adding a 4-bit auxiliary bit f0. 0-1 and B1; 10 bits [GBR1; 0-1] + f1, G2; 0-1 obtained by multiplexing bits 0-1 and R1; 0-1 and adding 4 auxiliary bits f1. B2; 0-1 and R2; 0-1 are bit-multiplexed, and 10 bits [GBR2; 0] obtained by adding 4-bit auxiliary bit f2. 1] + f2, G3; 10 bits [GBR3; 0-1] + f3, obtained by multiplexing bits 0-1 and B3; 0-1 and R3; 0-1 and adding a 4-bit auxiliary bit f3. ... are formed.
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVS12A1 or DTS12A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link A-1 as shown in FIG. 52A. At the same time, 20-bit word string data DVS12A2 or DTS12A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is used as a link A-2 as shown in FIG. Form.
Subsequently, as shown in FIG. 51B, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in 36-bit word string data DVS12B or DTS12B is constructed. .., And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are represented by the upper 10 bits G0. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0-1, G3 0-1, B1; 0-1, B2; 0-1, B3; 0-1,..., And R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, G1 are obtained by adding a 4-bit auxiliary bit f0. 0-1 and B1; 10 bits [GBR1; 0-1] + f1, G2; 0-1 obtained by multiplexing bits 0-1 and R1; 0-1 and adding 4 auxiliary bits f1. B2; 0-1 and R2; 0-1 are bit-multiplexed, and 10 bits [GBR2; 0] obtained by adding 4-bit auxiliary bit f2. 1] + f2, G3; 10 bits [GBR3; 0-1] + f3, obtained by multiplexing bits 0-1 and B3; 0-1 and R3; 0-1 and adding a 4-bit auxiliary bit f3. ... are formed.
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVS12B1 or DTS12B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link B-1 as shown in FIG. 52A. As shown in FIG. 52B, 20-bit word string data DVS12B2 or DTS12B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. Form.
Also, as shown in FIG. 51C, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 36-bit word string data DVS12C or DTS12C is constituted. .., And 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence, the upper 10 bits G0 are also set for each of the 12-bit words BD0, BD1, BD2, BD3,. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0-1 , B0; 0-1, B1; 0-1, B2; 0-1, B3; 0-1, ..., and R0; R1; 0-1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, G1 are obtained by adding a 4-bit auxiliary bit f0. 0-1 and B1; 10 bits [GBR1; 0-1] + f1, G2; 0-1 obtained by multiplexing bits 0-1 and R1; 0-1 and adding 4 auxiliary bits f1. B2; 0-1 and R2; 0-1 are bit-multiplexed, and 10 bits [GBR2; 0] obtained by adding 4-bit auxiliary bit f2. 1] + f2, G3; 10 bits [GBR3; 0-1] + f3, obtained by multiplexing bits 0-1 and B3; 0-1 and R3; 0-1 and adding a 4-bit auxiliary bit f3. ... are formed.
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVS12C1 or DTS12C1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link C-1 as shown in FIG. 52A. In addition, 20-bit word string data DVS12C2 or DTS12C2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is used as a link C-2 as shown in FIG. 52B. Form.
That is, in the data processing unit 191, the data DVS12 or DTS12 forming the 36-bit word string data having the word transmission rate of 222.75 MBps is converted to the 20-bit word string data having the word transmission rate of 74.25 MBps. The data is converted into six-system word string data of DVS12A1, DVS12A2, DVS12B1, DVS12B2, DVS12C1, and DVS12C2, or DTS12A1, DTS12A2, DTS12B1, DTS12B2, DTS12C1, and DTS12C2.
When the digital data DVX is data DVR10 + DKR10, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is 1920. The Y data sequence and the P data which form a set digital video signal of 4: 2: 2 format, each having a quantization bit number of 10 bits and a word transmission rate of 222.75 MBps. _B / P _R A data sequence (DVR10) and a Key signal data sequence (DKR10) having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
When the digital data DVX is the data DTR10 + DYR10, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, 720 effective lines in each frame, and 1280 effective data samples in each line. The Y data sequence and the P data which form a digital video signal of 4: 2: 2 format set in the sample, each having a quantization bit number of 10 bits and a word transmission rate of 222.75 MBps. _B / P _R A data sequence (DTR10) and a Key signal data sequence (DYR10) having a data format equivalent to that of the Y data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, the Y data series, P, constituting these data DVR10 + DKR10 or data DTR10 + DYR10, _B / P _R As shown in FIG. 53, the data sequence and the Key signal data sequence are obtained as 30-bit parallel data having a word transmission rate of 222.75 MBps, which is obtained by parallel multiplexing with frame synchronization and line synchronization. It is supplied to the processing unit 191.
The data processing unit 191 performs the following processing on the data DVR10 + DKR10 or DTR10 + DYR10 supplied as shown in FIG.
53. First, as shown in FIG. 53, the first two alternate frame portions Frame 1, Frame 4, Frame 4, among the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVR10 + DKR10 or DTR10 + DYR10. ,..., The second alternate frame portion Frame 2, Frame 5, Frame 8, and the third alternate frame portion Frame 3, Frame 6, Frame 9,. Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a Y data sequence and P having a series of segmented frame sections, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,..., At 90 Hz / 3 = 30 Hz, forming a segmented frame digital video signal. _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVR10A + DKR10A or DTR10A + DYR10A having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps.
Also, each of the frame parts Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal having a segmented frame section 2, a segmented frame 5, a segmented frame 8,... _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVR10B + DKR10B or DTR10B + DYR10B having a word transmission rate of 74.25 MBps.
Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal and have a segmented frame portion 3, a segmented frame 6, a segmented frame 9,... _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVR10C + DKR10C or DTR10C + DYR10C with a word transmission rate of 74.25 MBps.
30-bit word string data DVR10A + DKR10A, DVR10B + DKR10B and DVR10C + DKR10C, or DTR10A + DYR10A, DTR10B + DYR10B and DTR10C + DYR10C, respectively, are Y bits of the Y data series as shown in FIG.・ ・ 、 P _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series, and the 10-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel and formed as link A, link B or link C.
Subsequently, as shown in FIG. 54, 10-bit words YD0, YD1, YD2, YD3,... Constituting a Y data sequence in the 30-bit word string data DVR10A + DKR10A or DTR10A + DYR10A, and P _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are parallel-multiplexed, and the word transmission rate is 74.25 MBps as shown in FIG. The 20-bit word string data DVRK10A1 or DTRY10A1 is formed as a link A-1. .., And auxiliary 10-bit words αD0, αD1, αD1, αD2, αD3, which constitute 10-bit words AD0, AD1, AD2, AD3,. ,... Are parallel-multiplexed to form 20-bit word string data DVRK10A2 or DTRY10A2 having a word transmission rate of 74.25 MBps as a link A-2, as shown in FIG. 55B.
Also, as shown in FIG. 54, 10-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in the 30-bit word string data DVR10B + DKR10B or DTR10B + DYR10B _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are parallel-multiplexed, and the word transmission rate is 74.25 MBps as shown in FIG. The 20-bit word string data DVRK10B1 or DTRY10B1 is formed as a link B-1. In addition, 10-bit words AD0, AD1, AD2, AD3,... Constituting a Key signal data sequence in the 30-bit word string data DVR10B + DKR10B or DTR10B + DYR10B, and auxiliary 10-bit words αD0, αD1, αD2, αD3,. .. Are parallel-multiplexed to form 20-bit word string data DVRK10B2 or DTRY10B2 having a word transmission rate of 74.25 MBps as shown in FIG. 55B as link B-2.
Further, as shown in FIG. 54, 10-bit words YD0, YD1, YD2, YD3,... And P forming a Y data sequence in the 30-bit word string data DVR10C + DKR10C or DTR10C + DYR10C _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are parallel-multiplexed, and the word transmission rate is 74.25 MBps as shown in FIG. The 20-bit word string data DVRK10C1 or DTRY10C1 is formed as a link C-1. At the same time, 10-bit words AD0, AD1, AD2, AD3,... Constituting a Key signal data sequence in the 30-bit word string data DVR10C + DKR10C or DTR10C + DYR10C, and auxiliary 10-bit words αD0, αD1, αD2, αD3,. .. Are formed in parallel to form 20-bit word string data DVRK10C2 or DTRY10C2 having a word transmission rate of 74.25 MBps as a link C-2, as shown in FIG. 55B.
That is, in the data processing unit 191, data DVR10 + DKR10 or DTR10 + DYR10 forming 30-bit word string data having a word transmission rate of 222.75 MBps, and 20-bit word string data each having a word transmission rate of 74.25 MBps The data is converted into word string data of 6 systems of DVRK10A1, DVRK10A2, DVRK10B1, DVRK10B2, DVRK10C1, and DVRK10C2, or DTRY10A1, DTRY10A2, DTRY10B1, DTRY10B2, DTRY10C1, and DTRY10C2.
When the digital data DVX is data DVC12 + DKC12, the data processing unit 191 sets the frame rate to 50 Hz or 60 Hz, sets the number of valid lines in each frame to 1080 lines, and sets the number of valid data samples in each line to 1920 samples. And a Y data sequence and a Y data sequence which form a digital video signal of 4: 2: 2 format, each having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps. _B / P _R A data sequence (DVC12) and a Key signal data sequence (DKC12) having a data format equivalent to that of the Y data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
When the data DVX is the data DTU12 + DYU12, the data processing unit 191 sets the frame rate to 120 Hz, sets the number of valid lines in each frame to 720 lines, and sets the number of valid data samples in each line to 1280 samples. , A Y data sequence and a Y data sequence which form a digital video signal of 4: 2: 2 format, each having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps. _B / P _R A data sequence (DTU12) and a Key signal data sequence (DYU12) having a data format equivalent to that of the Y data sequence and having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, a Y data series constituting these data DVC12 + DKC12 or DTU12 + DYU12, P _B / P _R As shown in FIG. 56, the data sequence and the key signal data sequence are 36-bit parallel data having a word transmission rate of 148.5 MBps, which is obtained by performing parallel multiplexing under the condition of frame synchronization and line synchronization. It is supplied to the processing unit 191.
The data processing unit 191 performs the following processing on the data DVC12 + DKC12 or DTU12 + DYU12 supplied as shown in FIG.
56. First, as shown in FIG. 56, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVC12 + DKC12 or DTU12 + DYU12, Frame 1, Frame 3, Frame 3. .. And the second alternate frame portions Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a Y data sequence and P having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 3, Segmented Frame 5,..., Of 120 Hz / 2 = 60 Hz, forming a segmented frame digital video signal _B / P _R It is assumed that 36-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 36-bit word sequence data DVC12A + DKC12A or DTU12A + DYU12A having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. Y data sequence and segmented frame digital video signal having segmented frame 2, Segmented Frame 4, Segmented Frame 6,... _B / P _R It is assumed that 36-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 36-bit word sequence data DVC12B + DKC12B or DTU12B + DYU12B with a word transmission rate of 74.25 MBps.
As shown in FIG. 57A, the 36-bit word string data DVC12A + DKC12A or DTU12A + DYU12A is composed of 12-bit words YD0, YD1, YD2, YD3,. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel and formed as a link A. As shown in FIG. 57B, the 36-bit word string data DVC12B + DKC12B or DTU12B + DYU12B also has 12-bit words YD0, YD1, YD2, YD3,. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel and formed as a link B.
Subsequently, as shown in FIG. 57A, 12-bit words YD0, YD1, YD2, YD3,..., P constituting a Y data sequence in 36-bit word string data DVC12A + DKC12A or DTU12A + DYU12A. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11, ..., Pb0; 2-11, Pr0; Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11,..., And A0; 2-11, A1; 2-11, A2; 2-11, .. And lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1,..., Pb0; , Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, P , and A0; 0-1 A1; 0-1, A2; 0-1, A3; 0-1,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVCK12A1 or DTUY12A1 having a transmission rate of 74.25 MBps is formed as a link A-1 as shown in FIG. 58A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower two bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, so that 10 bits [Pb0; 0-1] + d0, [Pr0; [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 string: [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 parallel-multiplexed, and the 20-bit word string data DVCK12A2 or DTUY12A2 having a word transmission rate of 74.25 MBps is used as a link A-2 as a link A-2 in FIG. It is formed as shown in FIG.
Further, 8-bit auxiliary bits e0, e1 e2, e3 are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; ,... Are added, and 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,. , And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11, and the 10-bit sequence: [A0; 0-1] + e0, [A1; 0-1] + e1, A2; 0-1] + e2, [A3; 0-1] + e3,. Of the 20-bit word string data DVCK12A3 or DTUY12A3 having a value of 74.25 MBps as a link A-3. Formed as shown at 58C.
Similarly, as shown in FIG. 57B, 12-bit words YD0, YD1, YD2, YD3,..., P constituting a Y data sequence in 36-bit word string data DVC12B + DKC12B or DTU12B + DYU12B. _B / P _R Of the 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1 AD2, AD3,. Each of the upper 10 bits 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,..., And A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11,..., And lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1,..., Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2 0-1, ..., and, A0; 0-1 A1; 0-1, A2; 0-1, A3; 0-1, is divided into a ......
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVCK12B1 or DTUY12B1 having a transmission rate of 74.25 MBps is formed as a link B-1 as shown in FIG. 58A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. 10-bit string: [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 parallel-multiplexed, and the 20-bit word string data DVCK12B2 or DTUY12B2 having a word transmission rate of 74.25 MBps is used as a link B-2 as a link B-2 in FIG. It is formed as shown in FIG.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 , And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11, and a 10-bit sequence : [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVCK12B3 or DTUY12B3 having a transmission rate of 74.25 MBps as link B-3 Formed as shown in C in FIG. 58.
That is, in the data processing section 191, data DVC12 + DKC12 or DTU12 + DYU12 forming 36-bit word string data having a word transmission rate of 148.5 MBps, and 20-bit word string data having a word transmission rate of 74.25 MBps, respectively. The data is converted into six-system word string data of DVCK12A1, DVCK12A2, DVCK12A3, DVCK12B1, DVCK12B2, and DVCK12B3, or DTUY12A1, DTUY12A2, DTUY12A3, DTUY12B1, DTUY12B2, and DTUY12B3.
In the data processing unit 191, the data DVC12A + DKC12A and DVC12B + DKC12B or the data DTU12A + DYU12A and DTU12B + DYU12B obtained as shown in FIGS. Is performed.
First, as shown in FIG. 57A, 12-bit words YD0, YD1, YD2, YD3,..., P constituting a Y data series in 36-bit word string data DVC12A + DKC12A or DTU12A + DYU12A. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11, ..., Pb0; 2-11, Pr0; Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11,..., And A0; 2-11, A1; 2-11, A2; 2-11, .. And lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1,..., Pb0; , Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, P , and A0; 0-1 A1; 0-1, A2; 0-1, A3; 0-1,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVCK12A1 or DTUY12A1 having a transmission rate of 74.25 MBps is formed as a link A-1 as shown in FIG. 59A.
Also, the lower two bits Y0; 0-1 and Pb0; 0-1 and Pr0; 0-1 are multiplexed, and 10 bits [Y0BR0; 0-1] obtained by adding 4-bit auxiliary bit d0 are added. + D0, divided lower 2 bits Y1; 10-bit [Y1; 0-1] + e0 obtained by adding 8-bit auxiliary bit e0 to 0-1; divided lower 2 bits Y2; 0-1 and Pb1 0-1 and Pr1; 0-1 are multiplexed and 10 bits [Y2BR1; 0-1] + d1, which are obtained by adding 4-bit auxiliary bit d1, to the divided lower 2 bits Y3; 0-1 10 bits [Y3; 0-1] + e1 obtained by adding 8 auxiliary bits e1; divided lower 2 bits Y4; 0-1 and Pb2; 0-1 and Pr2; 0-1 and , 4-bit auxiliary video 10 bits [Y4BR2; 0-1] + d2 obtained by adding the data d2 and 10 bits [Y5; 0-1] obtained by adding the 8-bit auxiliary bit e2 to the divided lower 2 bits Y5; 0-1. + E2,... Then, a 10-bit sequence obtained in this way and auxiliary 10-bit words αD0, αD1, αD2, αD3,... Are multiplexed in parallel to form a 20-bit word sequence having a word transmission rate of 74.25 MBps. The data DVCK12A2 or DTUY12A2 is formed as a link A-2 as shown in FIG. 59B.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 , And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11, and a 10-bit sequence : [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVCK12A3 or DTUY12A3 having a transmission rate of 74.25 MBps as link A-3 Formed as shown in C in FIG. 59.
Similarly, as shown in FIG. 57B, 12-bit words YD0, YD1, YD2, YD3,..., P constituting a Y data sequence in 36-bit word string data DVC12B + DKC12B or DTU12B + DYU12B. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11, ..., Pb0; 2-11, Pr0; Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11,..., And A0; 2-11, A1; 2-11, A2; 2-11, .. And lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1,..., Pb0; , Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, P r2; 0-1,..., and A0; 0-1
A1; 0-1, A2; 0-1, A3; 0-1,...
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVCK12B1 or DTUY12B1 having a transmission rate of 74.25 MBps is formed as a link B-1 as shown in FIG. 59A.
Also, the lower two bits Y0; 0-1 and Pb0; 0-1 and Pr0; 0-1 are multiplexed, and 10 bits [Y0BR0; 0-1] obtained by adding 4-bit auxiliary bit d0 are added. + D0, divided lower 2 bits Y1; 10-bit [Y1; 0-1] + e0 obtained by adding 8-bit auxiliary bit e0 to 0-1; divided lower 2 bits Y2; 0-1 and Pb1 0-1 and Pr1; 0-1 are multiplexed and 10 bits [Y2BR1; 0-1] + d1, which are obtained by adding 4-bit auxiliary bit d1, to the divided lower 2 bits Y3; 0-1 10 bits [Y3; 0-1] + e1 obtained by adding 8 auxiliary bits e1; divided lower 2 bits Y4; 0-1 and Pb2; 0-1 and Pr2; 0-1 and , 4-bit auxiliary video 10 bits [Y4BR2; 0-1] + d2 obtained by adding the data d2 and 10 bits [Y5; 0-1] obtained by adding the 8-bit auxiliary bit e2 to the divided lower 2 bits Y5; 0-1. + E2,... Then, a 10-bit sequence obtained in this way and auxiliary 10-bit words αD0, αD1, αD2, αD3,... Are multiplexed in parallel to form a 20-bit word sequence having a word transmission rate of 74.25 MBps. The data DVCK12B2 or DTUY12B2 is formed as a link B-2 as shown in FIG. 59B.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 , And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11, and a 10-bit sequence : [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVCK12B3 or DTUY12B3 having a transmission rate of 74.25 MBps as link B-3 Formed as shown in C in FIG. 59.
That is, even in such a case, data DVC12 + DKC12 or DTU12 + DYU12 forming 36-bit word string data having a word transmission rate of 148.5 MBps, and 20-bit word string data DVCK12A1 and DVCK12A2 each having a word transmission rate of 74.25 MBps. , DVCK12A3, DVCK12B1, DVCK12B2, and DVCK12B3, or DTUY12A1, DTUY12A2, DTUY12A3, DTUY12B1, DTUY12B2, and six-system word string data of DTUY12B3.
When the digital data DVX is data DVC14 + DKC14 or DVC16 + DKC16, the data processing unit 191 sets the frame rate to 50 Hz or 60 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is 1920. The Y data sequence and the P data which form a set digital video signal of 4: 2: 2 format, each having a quantization bit number of 14 bits or 16 bits and a word transmission rate of 148.5 MBps. _B / P _R A key signal data sequence (DKC14 or DKC16) having a data format (DVC14 or DVC16) and a data format equivalent to that of the Y data sequence, a quantization bit number of 14 or 16 bits, and a word transmission rate of 148.5 MBps. Is input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
When the digital data DVX is data DTU14 + DYU14 or DTU16 + DYU16, the data processing unit 191 sets the frame rate to 120 Hz, the number of effective lines in each frame is 720, and the number of effective data samples in each line is 1280. The Y data sequence and the P data which form a set digital video signal of 4: 2: 2 format, each having a quantization bit number of 14 bits or 16 bits and a word transmission rate of 148.5 MBps. _B / P _R A key signal data sequence (DYU14 or DYU16) having a data sequence (DTU14 or DTU16) and a data format equivalent to that of the Y data sequence, with a quantization bit number of 14 or 16 bits and a word transmission rate of 148.5 MBps. Is input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, these data DVC14 + DKC14 or DVC16 + DKC16, or the DTU14 + DYU14 or the Y data series constituting DTU16 + DYU16, P _B / P _R The data sequence and the Key signal data sequence are parallel-multiplexed under frame synchronization and line synchronization, and are obtained as 42-bit parallel data or 48-bit parallel data with a word transmission rate of 148.5 MBps as a data processing unit 191. Supplied to
In such a case, the data processing unit 191 performs the same processing as that on the data DVC12 + DKC12 or DTU12 + DYU12 on the data DVC14 + DKC14 or DVC16 + DKC16, or on the DTU14 + DYU14 or DTU16 + DYU16. Where Y data series, P _B / P _R Instead of dividing each of the 12-bit words constituting the data sequence and the Key signal data sequence into upper 10 bits and lower 2 bits, a Y data sequence, P data _B / P _R The operation of dividing each of the 14-bit words constituting the data sequence and the Key signal data sequence into upper 10 bits and lower 4 bits, or Y data sequence, P data _B / P _R An operation of dividing each of the 16-bit words constituting the data sequence and the Key signal data sequence into upper 10 bits and lower 6 bits is performed.
Then, data DVC14 + DKC14 or DVC16 + DKC16 forming 42-bit word string data or 48-bit word string data having a word transmission rate of 148.5 MBps, or DTU14 + DYU14 or DTU16 + DYU16, each having a word transmission rate of 74.25 MBps, are 20 bits. Word string data DVCK14A1 or DVCK16A1, DVCK14A2 or DVCK16A2, DVCK14A3 or DVCK16A3, DVCK14B1 or DVCK16B1, DVCK14B2 or DVCK16B2, and DVCK14B3 or DVCKDTB16A1 DTUY16A2, DTUY14A3 or DTUY16A3, DTUY14B1 or DTUY16B1, DTUY14B2 or DTUY16B2, and are converted into word sequence data of six systems of DTUY14B3 or DTUY16B3.
When the digital data DVX is data indicated as data DVD12 + DKD12, the data processing unit 191 sets the frame rate to 50 Hz or 60 Hz, the number of valid lines in each frame is 1080, and the number of valid data samples in each line is 1920 samples. , A G data sequence, a B data sequence, and an R data sequence (each having a word transmission rate of 148.5 MBps and a quantization bit number of 12 bits). DVD12) and a Key signal data sequence (DKD12) having a data format equivalent to the G data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
When the digital data DVX is data represented as data DTV12 + DYV12, the data processing unit 191 sets the frame rate to 120 Hz, the number of valid lines in each frame is 720, and the number of valid data samples in each line is 1280 samples. , A G data sequence, a B data sequence, and an R data sequence (each having a word transmission rate of 148.5 MBps and a quantization bit number of 12 bits). DTV12) and a Key signal data sequence (DYV12) having a data format equivalent to that of the G data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
The G data sequence, B data sequence, R data sequence, and Key signal data sequence constituting these data DVD12 + DKD12 or DTV12 + DYV12 are parallel-multiplexed under frame synchronization and line synchronization as shown in FIG. The resultant data is supplied to the data processing unit 191 as 48-bit parallel data having a word transmission rate of 148.5 MBps.
The data processing unit 191 performs the following processing on the data DVD12 + DKD12 or DTV12 + DYV12 supplied as shown in FIG.
First, as shown in FIG. 60, every other one of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVD 12 + DKD 12 or DTV 12 + DYV 12 is Frame 1, Frame 3, Frame 3. .. And the second alternate frame portions Frame 2, Frame 4, Frame 6,... Are stored in the memory A and the memory B, respectively.
Next, each of the frame parts Frame 1, Frame 3, Frame 5,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 50 Hz / 2 = 25 Hz, 60 Hz / 2 = 30 Hz. Alternatively, a G data sequence and a B data which constitute a segmented frame digital video signal having a series of segmented frame portions 1, 2, 3, 4, 5,... Which are set to 120 Hz / 2 = 60 Hz. 48-bit parallel data including the sequence and the R data system and the Key signal data sequence, thereby forming a 48-bit word string data DV having a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Obtaining 12A + DKD12A or DTV12A + DYV12A. Also, each of the frame parts Frame 2, Frame 4, Frame 6,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 25 Hz, 30 Hz or 60 Hz. A G data sequence, a B data sequence, an R data sequence, and a Key signal data sequence that constitute a segmented frame digital video signal having a Ted frame portion Segmented Frame 2, Segmented Frame 4, Segmented Frame 6,... 48-bit parallel data including a 12-bit word data DVD12B + DKD12B or DTV with a word transmission rate of 148.5 MBps / 2 = 74.25 MBps. Obtaining a 2B + DYV12B.
The 48-bit word string data DVD12A + DKD12A or DTV12A + DYV12A is, as shown in FIG. 61A, a 12-bit word GD0, GD1, GD2, GD3,... , Constituting the R data sequence, and the 12 bits constituting the Key signal data sequence, bit lines BD0, BD1, BD2, BD3,..., And R bit sequence RD0, RD1, RD2, RD3,. The words AD0, AD1, AD2, AD3,... Are multiplexed in parallel and formed as a link A.
Also, as shown in FIG. 61B, the 48-bit word string data DVD12B + DKD12B or DTV12B + DYV12B also forms the 12-bit words GD0, GD1, GD2, GD3,... , Constituting the R data sequence, and the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence and the Key signal data sequence The 12-bit words AD0, AD1, AD2, AD3,... Are formed by parallel multiplexing and formed as a link B.
Subsequently, as shown in FIG. 61A, the 12-bit words GD0, GD1, GD2, GD3,..., And B data series constituting the G data series in the 48-bit word string data DVD12A + DKD12A or DTV12A + DYV12A are Constituting 12-bit words BD0, BD1, BD2, BD3,..., Composing 12-bit words RD0, RD1, RD2, RD3,. Each of the 12-bit words AD0, AD1, AD2, AD3,... To be processed is represented by the upper 10 bits G0; 2-11, G1; 2-11, G2; 2-11, G3; 2-11,. , B0; 2-11, B1; 2-11, B2; 2-11, B3; 2-11, ..., R0; 2-11, R1; -11, R2; 2-11, R3; 2-11, ..., and A0; 2-11, A1; 2-11, A2; 2-11, A3; .. and lower two bits G0; 0-1, G1; 0-1, G2; 0-1, G3; 0-1,..., B0; 0-1, B1; 0-1, B3; 0-1, ..., R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1, ..., and A0 0-1, A1; 0-1, A2; 0-1, A3; 0-1,...
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Then, as shown in FIG. 62, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 thick solid line in FIG. 62, and the divided upper 10-bit columns: G0; 2-11, G1; , G2; 2-11, G3; 2-11,... And the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVDK12A1 or DTVY12A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 62 is formed as a link A-1 as shown in FIG. 63A. I do. Also, 20-bit word string data DVDK12A2 or DTVY12A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 62 is formed as a link A-2 as shown in FIG. 63B. I do.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 ... And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11,. : [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVDK12A3 or DTVY12A3 having a transmission rate of 74.25 MBps as link A-3 Formed as shown in C in FIG. 63.
Also, as shown in FIG. 61B, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 48-bit word string data DVD12B + DKD12B or DTV12B + DYV12B. , Constituting the R data sequence, and the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence and the Key signal data sequence Each of the 12-bit words AD0, AD1, AD2, AD3,... Is represented by upper 10 bits G0; 2-11, G1; 2-11, G2; 2-11, G3; ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; 2-11, ..., R0; 2-11, R1; ..., 11, R2; 2-11, R3; 2-11, ..., and A0; 2-11, A1; 2-11, A2; 2-11, A3; And the lower 2 bits G0; 0-1, G1; 0-1, G2; 0-1, G3; 0-1,..., B0; 0-1, B1; 0-1, B2; .., R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,..., And A0; 0-1, A1; 0-1, A2; 0-1, A3; 0-1,.
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Then, as shown in FIG. 62, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 thick solid line in FIG. 62, and the divided upper 10-bit columns: G0; 2-11, G1; , G2; 2-11, G3; 2-11,... And the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVDK12B1 or DTVY12B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 62 is formed as a link B-1 as shown in FIG. 63A. I do. Also, 20-bit word string data DVDK12B2 or DTVY12B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 62 is formed as a link B-2 as shown in FIG. 63B. I do.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 ... And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11,. : [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVDK12B3 or DTVY12B3 having a transmission rate of 74.25 MBps as link B-3 Formed as shown in C in FIG. 63.
That is, in the data processing section 191, a data DVD12 + DKD12 or a data DTV12 + DYV12 forming 48-bit word string data having a word transmission rate of 148.5 MBps, and a 20-bit word string having a word transmission rate of 74.25 MBps, respectively. The data is converted into six-system word string data of data DVDK12A1, DVDK12A2, DVDK12A3, DVDK12B1, DVDK12B2 and DVDK12B3, or DTVY12A1, DTVY12A2, DTVY12A3, DTVY12B1, DTVY12B2 and DTVY12B3.
When the digital data DVX is data indicated as data DVS10 + DKS10, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is A G data sequence, a B data sequence, and R data each forming a 4: 4: 4 format digital video signal set to 1920 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 10 bits. A sequence (DVS10) and a Key signal data sequence (DKS10) having a data format equivalent to that of the G data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps are input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
When the digital data DVX is data indicated as data DTS10 + DYS10, the data processing unit 191 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the effective data sample in each line is 720. A G data sequence, a B data sequence, and a digital video signal of a 4: 4: 4 format in which the number is set to 1280 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 10 bits. An R data sequence (DTS10) and a Key signal data sequence (DYS10) having a data format equivalent to that of the G data sequence and having a quantization bit number of 10 bits and a word transmission rate of 222.75 MBps are input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
Then, the G data sequence, B data sequence, R data sequence and Key signal data sequence constituting these data DVS10 + DKS10 or DTS10 + DYS10 are parallel-multiplexed under frame synchronization and line synchronization as shown in FIG. The resultant data is supplied to the data processing unit 191 as 40-bit parallel data having a word transmission rate of 222.75 MBps.
The data processing unit 191 performs the following processing on the data DVS10 + DKS10 or DTS10 + DYS10 supplied as shown in FIG.
First, as shown in FIG. 64, the first two alternate frame portions Frame 1, Frame 4, Frame 4, among the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVS10 + DKS10 or DTS10 + DYS10. ,..., The second alternate frame portion Frame 2, Frame 5, Frame 8,... And the third alternate frame portion Frame 3, Frame 6, Frame 9,. .. Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a G data sequence and a B data which form a segmented frame digital video signal having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,... With 90 Hz / 3 = 30 Hz. 40-bit parallel data including the sequence and the R data system and the Key signal data sequence, thereby forming a 40-bit word string data DV having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps. Obtaining 10A + DKS10A or DTS10A + DYS10A.
Also, each of the frame portions Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by a field interlace method, and a series of segmented operations is performed by setting the frame rate to 24 Hz, 25 Hz, or 30 Hz. .. Having a frame part Segmented Frame 2, Segmented Frame 5, Segmented Frame 8,..., Which includes a G data sequence, a B data sequence, an R data system, and a Key signal data sequence which form a segmented frame digital video signal. It is assumed that 40-bit parallel data is formed, thereby obtaining 40-bit word string data DVS10B + DKS10B or DTS10B + DYS10B having a word transmission rate of 74.25 MBps.
Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by a field interlace method, and a series of segmented operations is performed in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. .. Having a frame section Segmented Frame 3, Segmented Frame 6, Segmented Frame 9,..., Including a G data sequence, a B data sequence, an R data system, and a Key signal data sequence forming a segmented frame digital video signal. It is assumed that 40-bit parallel data is formed, thereby obtaining 40-bit word string data DVS10C + DKS10C or DTS10C + DYS10C having a word transmission rate of 74.25 MBps.
Forty-bit word string data DVS10A + DKS10A, DVS10B + DKS10B and DVS10C + DKS10C, or DTS10A + DYS10A, DTS10B + DYS10B and DTS10C + DYS10C, respectively, constitute G data series G, G, D, G, D, G, D, G as shown in FIG. .., 10-bit words BD0, BD1, BD2, BD3,... Constituting the B data sequence, 10-bit words RD0, RD1, RD2, RD3,. The 10-bit words AD0, AD1, AD2, AD3,... Constituting the Key signal data sequence are multiplexed in parallel and formed as link A, link B or link C.
Subsequently, as shown in FIG. 65, the 10-bit words GD0, GD1, GD2, GD3,..., And 10 constituting the G data sequence in the 40-bit word string data DVS10A + DKS10A or DTS10A + DYS10A Bit data BD0, BD1, BD2, BD3,..., 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and 10 bits forming a Key signal data sequence The words AD0, AD1, AD2, AD3,... Are divided as indicated by thick solid lines in FIG. 37, and 10-bit words GD0, GD1, GD2, GD3,. ..., 10-bit words BD0, BD2,. . And a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming a R data sequence, and 10-bit words AD0, AD1, AD2, AD3,. .. and 10-bit word groups 2 including 10-bit words BD1, BD3,... Forming the B data sequence and 10-bit words RD1, RD3,. . Then, 20-bit word string data DVSK10A1 or DTSY10A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 37 is formed as a link A-1 as shown in FIG. 66A. At the same time, 20-bit word string data DVSK10A2 or DTSY10A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 37 is used as a link A-2 as shown in FIG. Form.
Also, as shown in FIG. 65, 10-bit words GD0, GD1, GD2, GD3,..., 10-bit constituting a G data sequence in 40-bit word string data DVS10B + DKS10B or DTS10B + DYS10B. Words BD0, BD1, BD2, BD3,..., 10-bit words RD0, RD1, RD2, RD3,... Forming an R data sequence, and 10-bit words forming a Key signal data sequence , AD0, AD1, AD2, AD3,... Are divided as shown by thick solid lines in FIG. 37, and 10-bit words GD0, GD1, GD2, GD3,. ..., 10-bit words BD0, BD2, ... forming a B data sequence , And a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming a R data sequence, and 10-bit words AD0, AD1, AD2, AD3,. .. Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence. Then, 20-bit word string data DVSK10B1 or DTSY10B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 37 is formed as a link B-1 as shown in FIG. 66A. At the same time, 20-bit word string data DVSK10B2 or DTSY10B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 37 is used as a link B-2 as shown in FIG. Form.
Further, as shown in FIG. 65, 10-bit words GD0, GD1, GD2, GD3,..., 10-bit constituting a G data series in 40-bit word string data DVS10C + DKS10C or DTS10C + DYS10C Words BD0, BD1, BD2, BD3,..., 10-bit words RD0, RD1, RD2, RD3,... Forming an R data sequence, and 10-bit words forming a Key signal data sequence , AD0, AD1, AD2, AD3,... Are divided as shown by thick solid lines in FIG. 37, and 10-bit words GD0, GD1, GD2, GD3,. ..., 10-bit words BD0, BD2, ... forming a B data sequence . And a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming a R data sequence, and 10-bit words AD0, AD1, AD2, AD3,. .. and 10-bit word groups 2 including 10-bit words BD1, BD3,... Forming the B data sequence and 10-bit words RD1, RD3,. . Then, 20-bit word string data DVSK10C1 or DTSY10C1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 37 is formed as a link C-1 as shown in FIG. 66A. At the same time, 20-bit word string data DVSK10C2 or DTSY10C2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 37 is used as a link C-2 as shown in FIG. Form.
That is, in the data processing unit 191, the data DVS10 + DKS10 or DTS10 + DYS10 forming 40-bit word string data having a word transmission rate of 222.75 MBps, and the 20-bit word string data DVSK10A1, having a word transmission rate of 74.25 MBps. The data is converted into six-system word string data of DVSK10A2, DVSK10B1, DVSK10B2, DVSK10C1, and DVSK10C2, or DTSY10A1, DTSY10A2, DTSY10B1, DTSY10B2, DTSY10C1, and DTSY10C2.
The data processing unit 191 is a set of 20-bit word string data DVR12A1, DVR12A2, DVR12B1, DVR12B2, DVR12C1, and DVR12C2, which are six kinds of word string data, and 20-bit word string data DVR14A1, DVR14A2, DVR14B1, DVR14C2, and DVR14C1 and DVR14C2. Set, 20-bit word string data DVR16A1, DVR16A2, DVR16B1, DVR16B2, DVR16C1 and DVR16C2, 20-bit word string data DVS10A1, DVS10A2, DVS10B1, DVS10B2, DVS10C1, and DVS10C1, DVS10C2 and VS12A1 data , DVS12B2, DVS12C1, and DVS 2C2, 20-bit word string data DTR12A1, DTR12A2, DTR12B1, DTR12B2, DTR12C1 and DTR12C2, 20-bit word string data DTR14A1, DTR14A2, DTR14B1, DTR14B2, DTR14C1 and DTR14C2, 20-bit word string data DTR16A1, DTRA , DTR16B1, DTR16B2, DTR16C1 and DTR16C2, a set of 20-bit word string data DTS10A1, DTS10A2, DTS10B1, DTS10B2, DTS10C1 and DTS10C2, a set of 20-bit word string data DTS12A1, DTS12A2, DTS12B1, DTS12B2, STS12C2DT20 Bit word string data A set of DVRK10A1, DVRK10A2, DVRK10B1, DVRK10B2, DVRK10C1 and DVRK10C2, a set of 20-bit word string data DVCK12A1, DVCK12A2, DVCK12A3, DVCK12B1 Set, set of 20-bit word string data DVCK16A1, DVCK16A2, DVCK16A3, DVCK16B1, DVCK16B2 and DVCK16B3, set of 20-bit word string data DVDK12A1, DVDK12A2, DVDK12A3, DVDK12B1, DVDK12B2 and DVDK12B3, A set of 20-bit word string data DVSK10A1, DVSK10A2, DVSK10B1, DVSK10B2, DVSK10C1 and DVSK10C2, and a set of 20-bit word string data DTRY10A1, DTRY10A2, DTRY10B1, DTRY10B2, DTRY10C1, and DTRY10C2A A set of DTTU12A3, DTTU12B1, DTTU12B2, and DTTU12B3, a set of 20-bit word string data DTTU14A1, DTTU14A2, DTTU14A3, a set of DTTU14B1, DTTU14B2, and DTTU14B3, a set of 20-bit word string data DTUI16A1, DTUY16A2, DTUY16ADT3 6B2 and DTUY16B3; 20-bit word string data DTVY12A1, DTVY12A2, DTVY12A3, DTVY12B1, DTVY12B2 and DTVY12B3; 20-bit word string data DTSY10A1, DTSY10A2; It is derived as a set of word string data DPA1 (20), DPA2 (20), DPB1 (20), DPB2 (20), DPC1 (20), and DPC2 (20).
20-bit word string data DPA1 (20) with a word transmission rate of 74.25 MBps sent from the data processing unit 191 is supplied to the data insertion unit 192. The data insertion unit 192 inserts auxiliary data DAA1 including channel identification data as needed into the 20-bit word string data DPA1 (20), and the 20-bit word string data DPA1 ′ into which the auxiliary data DAA1 has been inserted. (20) is formed. The 20-bit word string data DPA1 ′ (20) obtained from the data insertion unit 192 is supplied to the P / S conversion unit 193.
The P / S conversion section 193 performs P / S conversion on the 20-bit word string data DPA1 ′ (20) to increase the bit transmission rate based on the 20-bit word string data DPA1 ′ (20) to 74.25 Mbps. The serial data DSA1 with 20 = 1.485 Gbps is formed, and the serial data DSA1 is supplied to the E / O converter 194.
The E / O conversion unit 194 performs an electro-optical conversion process on the serial data DSA1, and converts the optical signal OSA1 having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSA1 to a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
The 20-bit word string data DPA2 (20), DPB1 (20), DPB2 (20), DPC1 (20), and DPC2 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 191 are: These are supplied to the data insertion units 195, 196, 197, 198 and 199, respectively. In the data insertion units 195 to 199, the channel identification data as required is added to the 20-bit word string data DPA2 (20), DPB1 (20), DPB2 (20), DPC1 (20), and DPC2 (20). The auxiliary data DAA2, DAB1, DAB2, DAC1 and DAC2 are inserted, and the 20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20) into which the auxiliary data has been inserted. And a DPC 2 ′ (20). The 20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20), and DPC2 '(20) obtained from the data insertion units 195 to 199 are respectively P / S It is supplied to the conversion units 200, 201, 202, 203 and 204.
In the P / S converters 200 to 204, the 20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20) and DPC2 '(20) S-conversion is performed to form serial data DSA2, DSB1, DSB2, DSC1 and DSC2 with a bit transmission rate based on them of 74.25 MBps × 20 = 1.485 Gbps, and these are converted into E / O converters 205, 206, 207, 208 and 209.
In the E / O converters 205 to 209, the serial data DSA2, DSB1, DSB2, DSC1 and DSC2 are subjected to electro-optical conversion processing, and the optical signals OSA2 and OSB1 whose central wavelength is set to, for example, approximately 1.3 μm based on them. , OSB2, OSC1, and OSC2 each having a bit transmission rate of 1.485 Gbps, and transmitting it as a transmission signal.
Under these circumstances, the E / O converters 194 and 205 to 209 transmit the serial data DSA1, DSA2, DSB1, DSB2, DSC1 and DSC2 obtained from the P / S converters 193 and 200 to 204, respectively, for transmission. To form a data transmission unit.
The optical signal OSA1, which is a transmission signal transmitted from the E / O conversion unit 194, is guided to the optical fiber transmission line 211 through the optical connector 210, and is transmitted to the receiving side through the optical fiber transmission line 211. Optical signals OSA2, OSB1, OSB2, OSC1 and OSC2, which are transmission signals transmitted from the E / O converters 205 to 209, are transmitted through the optical connectors 212, 213, 214, 215 and 216, respectively. 218, 219, 220 and 221 and transmitted to the receiving side through optical fiber transmission lines 217 to 221. Each of the optical fiber transmission lines 211 and 217 to 221 is formed using, for example, a quartz SMF.
On the receiving side, the optical signal OSA1 transmitted through the optical fiber transmission line 211 is guided to the O / E converter 226 through the optical connector 225. Also, the optical signals OSA2, OSB1, OSB2, OSC1 and OSC2 transmitted through the optical fiber transmission lines 217 to 221 are respectively transmitted through the optical connectors 227, 228, 229, 230 and 231 to the O / E converters 232, 233 and 234. 235 and 236.
The O / E conversion unit 226 performs a photoelectric conversion process on the optical signal OSA1 having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OSA1. The serial data DSA1 having 1.485 Gbps is reproduced. Then, the reproduced serial data DSA1 is supplied to the S / P converter 240. The S / P converter 240 performs S / P conversion on the serial data DSA1 to reproduce 20-bit word string data DPA1 ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSA1. Then, it is supplied to the data time difference absorption unit 241.
In the O / E converters 232 to 236, photoelectric conversion processing is performed on optical signals OSA2, OSB1, OSB2, OSC1, and OSC2 having a center wavelength of about 1.3 μm and a bit transmission rate of 1.485 Gbps. Then, the serial data DSA2, DSB1, DSB2, DSC1 and DSC2 having the bit transmission rate of 1.485 Gbps based on them are reproduced. The reproduced serial data DSA2, DSB1, DSB2, DSC1 and DSC2 are supplied to S / P converters 242, 243, 244, 245 and 246, respectively. The S / P converters 242 to 246 perform S / P conversion on the serial data DSA2, DSB1, DSB2, DSC1, and DSC2, and based on them, a 20-bit word string having a word transmission rate of 74.25 MBps. The data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20), and DPC2 '(20) are reproduced and supplied to the data time difference absorption unit 241.
In the data time difference absorption unit 241, the 20-bit word string data DPA1 '(20) from the S / P conversion unit 240 and the 20-bit word string data DPA2' (20) from the S / P conversion units 242 to 246, The mutual time difference generated between DPB1 '(20), DPB2' (20), DPC1 '(20) and DPC2' (20) is absorbed, and the word transmission rate based on the 20-bit word string data DPA1 '(20) is reduced. 20-bit word string data DPA1Q '(20) at 74.25 MBps, and 20-bit word string data DPA2' (20), DPB1 '(20), DPB2' (20), DPC1 '(20), and DPC2' ( 20), 20-bit word string data DPA2Q '(20), DPB1Q' (20), and a word transmission rate of 74.25 MBps, respectively. PB2Q '(20), DPC1Q' (20), and sends the DPC2Q '(20), as the mutual time difference is aimed to be kept in the absence substantially.
The 20-bit word string data DPA1Q ′ (20) obtained from the data time difference absorption unit 241 is supplied to the data separation unit 247. In the data separation unit 247, 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 separately transmitted. The bit word string data DPA1Q (20) is supplied to the data reproduction processing unit 248.
Also, the 20-bit word string data DPA2Q ′ (20), DPB1Q ′ (20), DPB2Q ′ (20), DPC1Q ′ (20), and DPC2Q ′ (20) obtained from the data time difference absorption unit 241 are respectively separated from the data. 249, 250, 251, 252 and 253. The data separation units 249 to 253 convert the auxiliary data DAA2 from the 20-bit word string data DPA2Q '(20), DPB1Q' (20), DPB2Q '(20), DPC1Q' (20) and DPC2Q '(20). , DAB1, DAB2, DAC1 and DAC2 are separated and the 20-bit word string data DPA2Q (20), DPB1Q (20), DPB2Q (20), DPC1Q (20) and DPC2Q (20) and auxiliary data DAA2, DAB1, DAB2 , DAC1 and DAC2 are sent separately, and the 20-bit word string data DPA2Q (20), DPB1Q (20), DPB2Q (20), DPC1Q (20) and DPC2Q (20) are supplied to the data reproduction processing unit 248. You.
The data reproduction processing unit 248 sends the 20-bit word string data DPA1Q (20), DPA2Q (20), DPB1Q (20), DPB2Q (20), DPC1Q (20), and DPC2Q (20) to the transmission side. Performs a data reproduction process that is the reverse of the data conversion process performed on the digital data DVX by the data processing unit 191 in the above, and generates 20-bit word string data DPA1Q (20), DPA2Q (20), DPB1Q (20), and DPB2Q (20). , DPC1Q (20) and DPC2Q (20).
Such digital data DVX includes data DVR12, DVR14, DVR16, DVS10, and DVS12 shown in FIG. 3 and data DTR12, DTR14, DTR16, DTS10, and DTS12 shown in FIG. 4, and further, data DVR10 + DKR10, DVC12 + DKC14, and DVC14. , DVC16 + DKC16, DVD12 + DKD12 and DVS10 + DKS10, and data DTR10 + DYR10, DTU12 + DYU12, DTU14 + DYU14, DTU16 + DYU16, DTV12 + DYV12, and DTS10 + DYS10.
In the above description, in the data forming the digital video signal having a quantization bit number of 12 bits or more, the upper 10-bit column divided from each of the 12-bit, 14-bit, and 16-bit words constituting the Y data sequence , P _B / P _R 20-bit word string data DVR12A1, DVR12B1, DVR12C1, DVR14A1, DVR14B1, formed by parallel multiplexing a 12-bit, 14-bit, or higher 10-bit string divided from each of the 12-bit, 14-bit, or 16-bit words constituting the data sequence DVR14C1, DVR16A1, DVR16B1 and DVR16C1, 20-bit word string data DTR12A1, DTR12B1, DTR12C1, DTR14A1, DTR14B1, DTR14C1, DTR16A1, DTR16B1 and DTR16C1, etc. Further, each of the G data series, B data series and R data series is constituted. 20-bit word string data DVS12A1, DV formed based on the upper 10-bit string divided from each of the 12-bit words 12B1 and DVS12C1,20 bit word sequence data DTS12A1, DTS12B1 and DTS12C1 etc., each of which, for example, those capable of recording and reproduction by the present HD for VTR. Therefore, using the current HD VTR, the 20-bit word string data DVR12A1, DVR12B1, DVR12C1, DVR14A1, DVR14B1, DVR14C1, DVR16A1, DVR16B1, DVR16C1, DTR12A1, DTR12B1, DTR12C1, DTR14A1, DTR14D DTR16B1, DTR16C1, DVS12A1, DVS12B1, DVS12C1, DTS12A1, DTS12B1 and DTS12C1 can be checked, edited, etc., respectively. Further, using a current HD VTR and an image monitor, 20 bits can be used. Word string data DVR12A1, DVR12B1, DVR12C1, DVR14A1, DVR14B1, DVR14C , DVR16A1, DVR16B1, DVR16C1, DTR12A1, DTR12B1, DTR12C1, DTR14A1, DTR14B1, DTR14C1, DTR16A1, DTR16B1, DTR16C1, DVS12A1, DVS12B1, DVS12C1, DTS12A1, DTS12B1 Accordingly, when handling data forming a digital video signal having a quantization bit number of 12 bits or more, it is possible to perform a confirmation operation or the like using an existing device, which is extremely convenient.
67 and 68 show an example in which any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. And a data transmission / reception device including a second example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. Show the part.
The data transmission / reception device whose parts are shown in FIGS. 67 and 68 has many parts configured similarly to the data transmission / reception device shown in FIGS. 42 and 43, and FIGS. 43, and only a portion different from the data transmitting / receiving device shown in FIG. 43 and a portion related thereto are shown.
In the data transmission / reception device whose parts are shown in FIGS. 67 and 68, the E / O conversion units 194 and 205 to 209 and the O / E conversion unit provided in the data transmission / reception device shown in FIGS. Instead of 226 and 232 to 236, E / O converters 256, 258 and 260 and O / E converters 268, 270 and 272 are provided. Further, instead of the optical connectors 210 and 212 to 216 and the optical fiber transmission lines 211 and 217 to 221, and the optical connectors 225 and 227 to 231 provided in the data transmitting and receiving apparatus shown in FIGS. 261, 263 and 265, optical fiber transmission lines 262, 264 and 266, and optical connectors 267, 269 and 271. Each of the optical fiber transmission paths 262, 264, and 266 is formed using, for example, a quartz SMF.
67 and 68, the serial data DSA1 having a bit transmission rate of 1.485 Gbps from P / S conversion section 193 and the bit transmission rate from P / S conversion section 200 are provided. Is set to 1.485 Gbps, and the serial data DSA2 is supplied to the bit multiplexing unit 255. The bit multiplexing unit 255 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSA1 and DSA2, and performing a bit multiplexing / combining process on the serial data DSA1 and DSA2 to reduce the bit transmission rate. The composite serial data DZA with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZA obtained from the bit multiplexing unit 255 is supplied to the E / O conversion unit 256. In the E / O converter 256, an optical signal OZA having a center wavelength of, for example, about 1.3 μm based on the composite serial data DZA is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Also, the serial data DSB1 from the P / S converter 201 at a bit transmission rate of 1.485 Gbps and the serial data DSB2 from the P / S converter 202 at a bit transmission rate of 1.485 Gbps are combined with a bit multiplexing unit 257. Supplied to The bit multiplexing unit 257 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSB1 and DSB2, and performing bit multiplexing / combining processing on the serial data DSB1 and DSB2 to reduce the bit transmission rate. The composite serial data DZB with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZB obtained from the bit multiplexing unit 257 is supplied to the E / O conversion unit 258. In the E / O converter 258, an optical signal OZB having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZB is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Further, the serial data DSC1 with a bit transmission rate of 1.485 Gbps from the P / S conversion unit 203 and the serial data DSC2 with a bit transmission rate of 1.485 Gbps from the P / S conversion unit 204 are combined with a bit multiplexing unit 259. Supplied to The bit multiplexing unit 259 performs an operation of alternately extracting and sequentially arranging one bit from each of the serial data DSC1 and DSC2, performing bit multiplexing / combining processing on the serial data DSC1 and DSC2, and reducing the bit transmission rate. The composite serial data DZC having 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZC obtained from the bit multiplexing unit 259 is supplied to the E / O conversion unit 260. In the E / O converter 260, an optical signal OZC having a center wavelength of, for example, about 1.3 μm based on the composite serial data DZC is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Under these circumstances, the bit multiplexing units 255, 257, and 259 and the E / O conversion units 256, 258, and 260 correspond to the serial data DSA1, DSA2, DSB1, A data transmission unit for transmitting DSB2, DSC1 and DSC2 is formed.
The optical signal OZA, which is a transmission signal transmitted from the E / O converter 256, is guided to the optical fiber transmission line 262 through the optical connector 261 and transmitted to the receiving side through the optical fiber transmission line 262. The optical signal OZB, which is a transmission signal transmitted from the E / O converter 258, is guided to the optical fiber transmission line 264 through the optical connector 263, and is transmitted to the receiving side through the optical fiber transmission line 264. Further, the optical signal OZC, which is a transmission signal transmitted from the E / O converter 260, is guided to the optical fiber transmission line 266 through the optical connector 265, and is transmitted to the receiving side through the optical fiber transmission line 266.
On the receiving side, the optical signal OZA transmitted through the optical fiber transmission line 262 is guided to the O / E converter 268 through the optical connector 267. Further, the optical signal OZB transmitted through the optical fiber transmission line 264 is guided to the O / E converter 270 through the optical connector 269. Further, the optical signal OZC transmitted through the optical fiber transmission line 266 is guided to the O / E converter 272 through the optical connector 271.
The O / E conversion unit 268 performs a photoelectric conversion process on the optical signal OZA having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and obtains a bit transmission rate based on the optical signal OZA. The composite serial data DZA at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZA is supplied to the bit separation unit 273.
The bit separation unit 273 takes out one bit at a time from the composite serial data DZA, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZA. Then, a channel is specified by using the channel identification data included in the composite serial data DZA, and based on the composite serial data DZA, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSA1 and DSA2 are formed. The serial data DSA1 is supplied to the S / P converter 240, and the serial data DSA2 is supplied to the S / P converter 242.
The O / E converter 270 performs photoelectric conversion processing on the optical signal OZB having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and performs bit transmission based on the optical signal OZB. The composite serial data DZB having a rate of 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZB is supplied to the bit separation unit 274.
The bit separation unit 274 takes out one bit at a time from the composite serial data DZB, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZB. Then, a channel is specified by using the channel identification data included in the composite serial data DZB, and based on the composite serial data DZB, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSB1 and DSB2 are formed. The serial data DSB1 is supplied to the S / P converter 243, and the serial data DSB2 is supplied to the S / P converter 244.
Further, the O / E converter 272 performs a photoelectric conversion process on the optical signal OZC having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and performs bit transmission based on the optical signal OZC. The composite serial data DZC whose rate is 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZC is supplied to the bit separation unit 275.
The bit separation unit 275 takes out one bit at a time from the composite serial data DZC, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZC. Then, a channel is specified by using the channel identification data included in the composite serial data DZC, and based on the composite serial data DZC, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSC1 and DSC2 are formed. The serial data DSC1 is supplied to the S / P converter 245, and the serial data DSC2 is supplied to the S / P converter 246.
Other operations are the same as those of the data transmitting / receiving apparatus whose parts are shown in FIGS. 42 and 43.
FIGS. 69 and 70 show examples in which any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. And a data transmission / reception device including a third example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. Show the part.
The data transmission / reception device whose parts are shown in FIGS. 69 and 70 has many parts configured similarly to the data transmission / reception device whose parts are shown in FIGS. 67 and 68. Blocks corresponding to the respective blocks in the data transmitting / receiving apparatus shown in FIGS. 67 and 68 are denoted by the same reference numerals as those in FIGS. 67 and 68, and redundant description thereof will be omitted.
In the data transmission / reception device whose parts are shown in FIGS. 69 and 70, composite serial data DZB having a bit transmission rate of 2.97 Gbps from the bit multiplexing unit 257 is supplied to the E / O conversion unit 280. In the E / O converter 280, an optical signal OZB having a center wavelength of, for example, approximately 1.48 μm based on the composite serial data DZB is formed with a bit transmission rate of 2.97 Gbps. Further, composite serial data DZC having a bit transmission rate of 2.97 Gbps from the bit multiplexing unit 259 is supplied to the E / O conversion unit 281. In the E / O converter 281, an optical signal OZC having a center wavelength of, for example, about 1.55 μm based on the composite serial data DZC is formed with a bit transmission rate of 2.97 Gbps.
An optical signal OZA having a bit transmission rate of 2.97 Gbps and a center wavelength of approximately 1.3 μm from the E / O conversion unit 256 and a bit transmission rate of 2.97 Gbps from the E / O conversion unit 280, An optical signal OZB having a center wavelength of about 1.48 μm and an optical signal OZC from the E / O converter 281 having a bit transmission rate of 2.97 Gbps and a center wavelength of about 1.55 μm are combined. 282. The multiplexing unit 282 is formed by, for example, a fiber type WDM coupler and a dielectric multilayer type WDM coupler. In the multiplexing unit 282, an optical signal OZA having a center wavelength of about 1.3 μm, an optical signal OZB having a center wavelength of about 1.48 μm, and an optical signal OZC having a center wavelength of about 1.55 μm are provided. Are combined and multiplexed to form a multiplexed optical signal OZZ, which is transmitted as a transmission signal. Under these circumstances, bit multiplexing sections 255, 257 and 259, E / O conversion sections 256, 280 and 281 and multiplexing section 282 are provided with serial data DSA1 obtained from P / S conversion sections 193 and 200 to 204, respectively. , DSA2, DSB1, DSB2, DSC1 and DSC2.
The multiplexed optical signal OZZ, which is a transmission signal transmitted from the multiplexing unit 282, is guided through the optical connector 283 to an optical fiber transmission line 284 formed using, for example, a silica-based SMF, and is transmitted through the optical fiber transmission line 284. Transmitted to.
On the receiving side, the multiplexed optical signal OZZ transmitted through the optical fiber transmission line 284 is guided to the demultiplexer 286 through the optical connector 285. The demultiplexing unit 286 is formed by using, for example, a fiber WDM coupler and a dielectric multilayer WDM coupler as demultiplexing means. In the demultiplexing unit 286, the multiplexed optical signal OZZ is divided into a component having a center wavelength of approximately 1.3 μm, a component having a center wavelength of approximately 1.48 μm, and a component having a center wavelength of approximately 1.55 μm. An optical signal OZA having a bit transmission rate of 2.97 Gbps and a center wavelength of about 1.3 μm, and an optical signal OZB having a bit transmission rate of 2.97 Gbps and a center wavelength of about 1.48 μm And an optical signal OZC having a bit transmission rate of 2.97 Gbps and a center wavelength of about 1.55 μm.
The optical signals OZA, OZB and OZC reproduced by the demultiplexer 286 are guided to O / E converters 268, 287 and 288, respectively. The O / E converter 287 performs a photoelectric conversion process on an optical signal OZB having a bit transmission rate of 2.97 Gbps and a center wavelength of approximately 1.48 μm, and obtains a bit transmission rate based on the optical signal OZB. The composite serial data DZB at 2.97 Gbps is reproduced. The O / E converter 288 performs a photoelectric conversion process on an optical signal OZC having a bit transmission rate of 2.97 Gbps and a center wavelength of about 1.55 μm, and performs bit transmission based on the optical signal OZC. The composite serial data DZC whose rate is 2.97 Gbps is reproduced.
Then, the composite serial data DZA, DZB, and DZC reproduced by the O / E conversion units 268, 287, and 288 are supplied to the bit separation units 273, 274, and 275, respectively. Other operations are the same as those of the data transmitting / receiving apparatus whose parts are shown in FIGS. 67 and 68.
FIG. 71 is a diagram illustrating a data transmission method according to the present invention, in which an example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. Of the data transmission / reception device including a fourth example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-sixth aspects of the data transmission device according to the present invention. .
The data transmission / reception device whose part is shown in FIG. 71 has many portions configured similarly to the data transmission / reception device shown in FIGS. 42 and 43, and FIG. 71 shows the data transmission / reception device shown in FIGS. 42 and 43. Only the parts different from the data transmitting / receiving device and the parts related thereto are shown.
In the data transmission / reception device whose part is shown in FIG. 71, the E / O conversion units 194 and 205 to 209 and the O / E conversion units 226 and 232 provided in the data transmission / reception device shown in FIGS. 236C, and E / O converters 194C and 205C to 209C, and O / E converters 226C and 232C to 236C. Further, instead of the optical connectors 210 and 212 to 216 and the optical fiber transmission lines 211 and 217 to 221 and the optical connectors 225 and 227 to 231 provided in the data transmitting and receiving apparatus shown in FIGS. A section 282C, an optical connector 283C, an optical fiber transmission line 284C, an optical connector 285C, and a demultiplexing section 286C. The optical fiber transmission path 284C is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 71, the bit transmission rate from P / S conversion section 193 is 1.485 Gbps. 485 Gbps serial data DSA2, serial data DSB1 from which the bit transmission rate from P / S converter 201 is 1.485 Gbps serial data DSB2, P from which bit transmission rate from P / S converter 202 is 1.485 Gbps The serial data DSC1 having a bit transmission rate of 1.485 Gbps from the / S conversion section 203 and the serial data DSC2 having a bit transmission rate of 1.485 Gbps from the P / S conversion section 204 are connected to the E / O conversion section 194C. And 205C to 209C.
The E / O conversion unit 194C forms an optical signal OZA1 having a center wavelength of, for example, about 1.511 μm based on the serial data DSA1 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OZA1 with the optical signal OZA1. 282C. The E / O conversion unit 205C forms an optical signal OZA2 having a center wavelength of, for example, approximately 1.531 μm based on the serial data DSA2 as a signal having a bit transmission rate of 1.485 Gbps, and combines it with a multiplexing unit. 282C. The E / O conversion unit 206C forms an optical signal OZB1 having a center wavelength of, for example, approximately 1.551 μm based on the serial data DSB1 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OZB1 with the optical signal OZB1. 282C. The E / O conversion unit 207C forms an optical signal OZB2 having a center wavelength of, for example, approximately 1.571 μm based on the serial data DSB2 as a signal having a bit transmission rate of 1.485 Gbps, and combines the optical signal OZB2 with the optical signal OZB2. 282C. The E / O converter 208C forms an optical signal OZC1 having a center wavelength of, for example, about 1.591 μm, based on the serial data DSC1, assuming that the bit transmission rate is 1.485 Gbps, and combines the optical signal OZC1 with the optical signal OZC1. 282C. Further, the E / O conversion unit 209C forms an optical signal OZC2 having a center wavelength of, for example, approximately 1.611 μm based on the serial data DSC2 as a signal having a bit transmission rate of 1.485 Gbps, and combines them. It supplies to wave part 282C.
In the multiplexing section 282C, the optical signal OZA1 having a center wavelength of approximately 1.511 μm, the optical signal OZA having a center wavelength of approximately 1.531 μm, the optical signal OZB1 having a center wavelength of approximately 1.551 μm, and the center wavelength The optical signal OZB2 having a wavelength of approximately 1.571 μm, the optical signal OZC1 having a central wavelength of approximately 1.591 μm, and the optical signal OZC2 having a central wavelength of approximately 1.611 μm are multiplexed and multiplexed to form a multiplexed optical signal OZZC. Then, it is transmitted as a transmission signal. Under these circumstances, the E / O conversion units 194C and 205C to 209C and the multiplexing unit 282C correspond to the serial data DSA1, DSA2, DSB1, DSB2, DSC1 and DS1 obtained from the P / S conversion units 193 and 200 to 204, respectively. A data transmission section for transmitting DSB2 is formed.
In this way, the optical signals OZA1, OZA2, OZB1, OZB2, OZC1, and OZC2 multiplexed in the multiplexing unit 282C have their center wavelengths separated by only about 0.020 μm (20 nm). Are multiplexed under the condition that the wavelengths are very close to each other to form a multiplexed optical signal OZZC. In a portion including the E / O conversion units 194C and 205C to 209C and the multiplexing unit 282C, A wavelength multiplexing technique called CWMD is used.
The multiplexed optical signal OZZC, which is a transmission signal transmitted from the multiplexing unit 282C, is guided to an optical fiber transmission line 284C formed using, for example, a silica-based SMF through an optical connector 283C, and is received through the optical fiber transmission line 284C. Transmitted to.
On the receiving side, the multiplexed optical signal OZZC transmitted through the optical fiber transmission line 284C is guided to the demultiplexer 286C through the optical connector 285C. In the demultiplexer 286C, the multiplexed optical signal OZZC is converted 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. Is divided into a component having a center wavelength of approximately 1.571 μm, a component having a center wavelength of approximately 1.591 μm, and a component having a center wavelength of approximately 1.611 μm. The bit transmission rate is set to 1.485 Gbps, and the center wavelength is set to approximately 1. An optical signal OZA1 at .511 μm, a bit transmission rate of 1.485 Gbps, an optical signal OZA at a center wavelength of about 1.531 μm, and an optical signal at a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.551 μm OZB1, an optical signal OZB2 having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.571 μm, and a center wavelength of about 1.591 μm And an optical signal OZC2 having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.611 μm.
The optical signals OZA1, OZA2, OZB1, OZB2, OZC1 and OZC2 reproduced by the demultiplexer 286C are guided to O / E converters 226C and 232C to 236C, respectively. The O / E conversion unit 226C performs a photoelectric conversion process on the optical signal OZA1 having a center wavelength of approximately 1.511 μm to convert the serial data DSA1 based on the optical signal OZA1 and having a bit transmission rate of 1.485 Gbps. Reproduce. The O / E converter 232C performs a photoelectric conversion process on the optical signal OZA2 having a center wavelength of about 1.531 μm, and converts the serial data DSA2 based on the optical signal OZA2 to have a bit transmission rate of 1.485 Gbps. Reproduce. The O / E conversion unit 233C performs a photoelectric conversion process on the optical signal OZB1 having the center wavelength of about 1.551 μm, and converts the serial data DSB1 based on the optical signal OZB1 to have a bit transmission rate of 1.485 Gbps. Reproduce. The O / E conversion unit 234C performs a photoelectric conversion process on the optical signal OZB2 having the center wavelength of about 1.571 μm, and converts the serial data DSB2 based on the optical signal OZB2 and having a bit transmission rate of 1.485 Gbps. Reproduce. The O / E conversion unit 235C performs a photoelectric conversion process on the optical signal OZC1 having a center wavelength of approximately 1.591 μm, and converts the serial data DSC1 based on the optical signal OZC1 to a bit transmission rate of 1.485 Gbps. Reproduce. Then, the O / E converter 236C performs a photoelectric conversion process on the optical signal OZC2 having a center wavelength of about 1.611 μm, and generates a serial data having a bit transmission rate of 1.485 Gbps based on the optical signal OZC2. Play DSC2.
Then, the serial data DSA1, DSA2, DSB1, DSB2, DSC1 and DSC2 reproduced by the O / E converters 226C and 232C to 236C are supplied to the S / P converters 240 and 242 to 246, respectively.
Other operations are the same as those of the data transmitting / receiving apparatus shown in FIGS. 42 and 43.
FIGS. 72 and 73 show a data transmission method according to the present invention in which an example of any one of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the data transmission method according to the present invention is implemented. 10 shows a part of a data transmitting / receiving device including a first example of any of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the transmission device.
In the data transmission / reception device shown in FIGS. 72 and 73, digital data DVX forming a digital video signal is supplied to a data processing unit 291 on the transmission side which is an example of the data transmission device according to the present invention.
The digital data DVX is one of the data DVV10 and DVV12 shown in FIG. 3, the data DTV10 and DTV12 shown in FIG. 4, and the data DVU10 + DKU10 and DVV10 + DKV10.
When the digital data DVX is DVV10 shown in FIG. 3, the data processing unit 291 sets the frame rate to 120 Hz, sets the number of valid lines in each frame to 1080 lines, and sets the number of valid data samples in each line to 1920 samples. G, B, and R data sequences each having a word transmission rate of 297 MBps and a quantization bit number of 10 bits are input.
When the digital data DVX is the DTV 10 shown in FIG. 4, the data processing unit 291 sets the frame rate to 120 Hz, the number of effective lines in each frame is 720 lines, and the number of effective data samples in each line is 1920 samples. , A G data sequence, a B data sequence, and an R data sequence, each having a word transmission rate of 297 MBps and a quantization bit number of 10 bits, are input. You.
As shown in FIG. 74, the G data sequence, B data sequence, and R data sequence constituting these data DVV10 or DTV10 are word-transmitted by parallel multiplexing under frame synchronization and line synchronization. The data is supplied to the data processing unit 291 as 30-bit parallel data having a rate of 297 MBps.
The data processing unit 291 performs the following processing on the data DVV10 or DTV10 supplied as shown in FIG.
74. First, as shown in FIG. 74, of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVV10 or DTV 10, the first every third frame portion Frame 1, Frame 5,. Frame 9, Frame 6, Frame 10, Frame 10, Second third frame portion Frame 3, Frame 7, Frame 11, Third every third frame portion , And the fourth every third frame portion Frame 4, Frame 8, Frame 12,... Are stored in the memory A, the memory B, the memory C, and the memory D, respectively.
Next, each of the frame portions Frame 1, Frame 5, Frame 9,... Stored in the memory A is read out by the field interlace method, and a series of segments in which the frame rate is set to 120 Hz / 4 = 30 Hz. 30 bit parallel data including a G data sequence, a B data sequence, and an R data sequence constituting a segmented frame digital video signal having a segmented frame portion 1, a segmented frame 5, a segmented frame 9,... Thus, 30-bit word string data DVV10A or DTV10A having a word transmission rate of 297 MBps / 4 = 74.25 MBps is obtained. Further, each of the frame portions Frame 2, Frame 6, Frame 10,... Stored in the memory B is read out by the field interlace method, and a series of segmented frame portions having a frame rate of 30 Hz is obtained. , Segmented Frame 6, Segmented Frame 10,..., And forms 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a segmented frame digital video signal. As a result, 30-bit word string data DVV10B or DTV10B having a word transmission rate of 74.25 MBps is obtained.
Similarly, each of the frame parts Frame 3, Frame 7, Frame 11,... Stored in the memory C is read out by the field interlace method, and a series of segmented frame parts in which the frame rate is set to 30 Hz. Forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence, which form a segmented frame digital video signal, having Segmented Frame 3, Segmented Frame 7, Segmented Frame 11, ... Thus, 30-bit word string data DVV10C or DTV10C with a word transmission rate of 74.25 MBps is obtained. Further, each of the frame portions Frame 4, Frame 8, Frame 12,... Stored in the memory D is read out by a field interlace method, and a series of segmented frame portions having a frame rate of 30 Hz are read. , Having a segmented frame 8, a segmented frame 12,..., And forming 30-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a segmented frame digital video signal; Thereby, 30-bit word string data DVV10D or DTV10D having a word transmission rate of 74.25 MBps is obtained.
The 30-bit word string data DVV10A, DVV10B, DVV10C and DVV10D, or DTV10A, DTV10B, DTV10C and DTV10D form a G data sequence as shown in FIGS. 75A and 76B and FIGS. 76A and 76B, respectively. , A 10-bit word GD0, GD1, GD2, GD3,..., A 10-bit word BD0, BD1, BD2, BD3,. The words RD0, RD1, RD2, RD3,... Are parallel-multiplexed and formed as links A, B, C and D.
Subsequently, as shown in FIG. 75A, 10-bit words GD0, GD1, GD2, GD3,..., And B data series constituting a G data series in the 30-bit word string data DVV10A or DTV10A are constituted. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and auxiliary data added to the 10-bit words BD0, BD1, BD2, BD3,. The auxiliary 10-bit words ad0, ad1, ad2, ad3,... Constituting the sequence are divided as separated by a thick solid line in FIG. 24 to form a 10-bit word GD0 forming a G data sequence. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. The 10-bit word group 1 including the 10-bit words RD0, RD2,... Forming the R data sequence, and the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence. Then, 20-bit word string data DVV10A1 or DTV10A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link A-1 as shown in FIG. 77A. At the same time, 20-bit word string data DVV10A2 or DTV10A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link A-2 as shown in FIG. 77B. Form.
Also, as shown in FIG. 75B, a 10-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 30-bit word string data DVV10B or DTV10B is constituted. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and an auxiliary data sequence added thereto Are divided in such a manner as to be separated by a thick solid line in FIG. 24, and a 10-bit word GD0 that forms a G data sequence is also divided into the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. ··· and a 10-bit word group 1 including 10-bit words RD0, RD2, ··· forming an R data sequence and auxiliary 10-bit words ad0, ad1, ad2, ad3, ··· forming an auxiliary data sequence .. and 10-bit word groups 2 including 10-bit words BD1, BD3,... Forming the B data sequence and 10-bit words RD1, RD3,. . Then, 20-bit word string data DVV10B1 or DTV10B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link B-1 as shown in FIG. 77A. At the same time, 20-bit word string data DVV10B2 or DTV10B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link B-2 as shown in FIG. Form.
Similarly, as shown in FIG. 76A, the 10-bit words GD0, GD1, GD2, GD3,..., And the B data series that constitute the G data series in the 30-bit word string data DVV10C or DTV10C are configured. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and auxiliary data added to the 10-bit words BD0, BD1, BD2, BD3,. The auxiliary 10-bit words ad0, ad1, ad2, ad3,... Constituting the sequence are also divided as shown by the thick solid line in FIG. GD0, GD1, GD2, GD3,..., 10-bit words BD0, BD2,. .. and a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming an R data sequence, and auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence Distribute. Then, 20-bit word string data DVV10C1 or DTV10C1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link C-1 as shown in FIG. 77A. At the same time, 20-bit word string data DVV10C2 or DTV10C2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 24 is used as a link C-2 as shown in FIG. 77B. Form.
Further, as shown in FIG. 76B, 10-bit words GD0, GD1, GD2, GD3,..., And B data series constituting a G data series in 30-bit word string data DVV10D or DTV10D are constituted. , And 10-bit words RD0, RD1, RD2, RD3,... Constituting an R data sequence, and an auxiliary data sequence added thereto Are divided in such a manner as to be separated by a thick solid line in FIG. 24, and a 10-bit word GD0 that forms a G data sequence is also divided into the auxiliary 10-bit words ad0, ad1, ad2, ad3,. , GD1, GD2, GD3,..., 10-bit words BD0, BD2,. .. and a 10-bit word group 1 including 10-bit words RD0, RD2,... Forming an R data sequence, and auxiliary 10-bit words ad0, ad1, ad2, ad3,. , Forming a B data sequence and a 10-bit word group 2 including 10-bit words RD1, RD3,... Forming a R data sequence Distribute. Then, 20-bit word string data DVV10D1 or DTV10D1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 24 is formed as a link D-1 as shown in FIG. 77A. As shown in FIG. 77B, 20-bit word string data DVV10D2 or DTV10D2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. Form.
That is, in the data processing unit 291, the data DVV10 or DTV10 forming 30-bit word string data having a word transmission rate of 297 MBps is converted to the 20-bit word string data DVV10A1, DVV10A2 having a word transmission rate of 74.25 MBps. The data is converted into eight-system word string data of DVV10B1, DVV10B2, DVV10C1, DVV10C, DVV10D1, and DVV10D2, or DTV10A1, DTV10A2, DTV10B1, DTV10B2, DTV10C1, DTV10C2, DTV10D1, and DTV10D2.
When the digital data DVX is the data DVV12 shown in FIG. 3, the data processing unit 291 sets the frame rate to 120 Hz, the number of effective lines in each frame to 1080, and the number of effective data samples in each line to 1920. A G data sequence, a B data sequence, and an R data sequence each forming a set 4: 4: 4 format digital video signal, each having a word transmission rate of 297 MBps and a quantization bit number of 12 bits, are input. .
When the digital data DVX is the data DTV12 shown in FIG. 4, the data processing unit 291 sets the frame rate to 120 Hz, the number of valid lines in each frame is 720, and the number of valid data samples in each line is 1280. A G data sequence, a B data sequence, and an R data sequence each having a word transmission rate of 297 MBps, a quantization bit number of 12 bits, and inputting a 4: 4: 4 format digital video signal set in the sample. Is done.
A G data sequence, a B data sequence, and an R data sequence constituting these data DVV12 or DTV12 are word-transferred and obtained by parallel multiplexing under frame synchronization and line synchronization as shown in FIG. The data is supplied to the data processing unit 291 as 36-bit parallel data having a rate of 297 MBps.
The data processing unit 291 performs the following processing on the data DVV12 or DTV12 supplied as shown in FIG.
First, as shown in FIG. 78, the first every third frame portion Frame 1, Frame 5, among frame portions Frame 1, Frame 2, Frame 3,... Forming data DVV12 or DTV12. Frame 9, Frame 6, Frame 10, Frame 10, Second third frame portion Frame 3, Frame 7, Frame 11, Third every third frame portion ,..., And the fourth every third frame part Frame 4, Frame 8, Frame 12,... Are stored in the memory A, the memory B, the memory C, and the memory D, respectively. .
Next, each of the frame portions Frame 1, Frame 5, Frame 9,... Stored in the memory A is read out by the field interlace method, and a series of segments in which the frame rate is set to 120 Hz / 4 = 30 Hz. .. Having a Ted frame portion of Segmented Frame 1, Segmented Frame 5, Segmented Frame 9,..., And composes 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence constituting a segmented frame digital video signal. Thus, 36-bit word string data DVV12A or DTV12A having a word transmission rate of 297 MBps / 4 = 74.25 MBps is obtained. Also, each of the frame parts Frame 2, Frame 6, Frame 10,... Stored in the memory B is read out by the field interlace method, and a series of segmented frame parts having a frame rate of 30 Hz. .., Having a segmented frame 6, a segmented frame 10,..., And forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence that form a segmented frame digital video signal; Thereby, 36-bit word string data DVV12B or DTV12B having a word transmission rate of 74.25 MBps is obtained.
Similarly, each of the frame portions Frame 3, Frame 7, Frame 11,... Stored in the memory C is read out by the field interlace method, and a series of segmented frame portions Segmented in which the frame rate is set to 30 Hz. Forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence constituting a segmented frame digital video signal having Frame 3, Segmented Frame 7, Segmented Frame 11,... Thereby, 36-bit word string data DVV12C or DTV12C having a word transmission rate of 74.25 MBps is obtained. Further, each of the frame portions Frame 4, Frame 8, Frame 12,... Stored in the memory D is read out by the field interlace method, and a series of segmented frame portions Segmented in which the frame rate is set to 30 Hz. Forming 36-bit parallel data including a G data sequence, a B data sequence, and an R data sequence, which constitutes a segmented frame digital video signal, having Frame 4, Segmented Frame 8, Segmented Frame 12, ... Thus, 36-bit word string data DVV12D or DTV12D having a word transmission rate of 74.25 MBps is obtained.
The 36-bit word string data DVV12A, DVV12B, DVV12C and DVV12D, or DTV12A, DTV12B, DTV12C and DTV12D constitute a G data sequence as shown in FIGS. 79A and B and FIGS. 80A and B, respectively. , And 12-bit words BD0, BD1, BD2, BD3,... Forming a B data sequence, and 12 forming an R data sequence The bit words RD0, RD1, RD2, RD3,... Are parallel multiplexed and formed as links A, B, C and D.
Subsequently, as shown in FIG. 79A, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 36-bit word string data DVV12A or DTV12A is constructed. .., And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are represented by the upper 10 bits G0. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0-1, G3 0-1, B1; 0-1, B2; 0-1, B3; 0-1,..., And R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVV12A1 or DTV12A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link A-1 as shown in FIG. 81A. As shown in FIG. 81B, 20-bit word string data DVV12A2 or DTV12A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. Form.
Also, as shown in FIG. 79B, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in 36-bit word string data DVV12B or DTV12B is constructed. The 12-bit words BD0, BD1, BD2, BD3,... And the 12-bit words RD0, RD1, RD2, RD3,. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; , And R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. G1: 0-1, G2; 0-1, G3; ..., B0; 0-1, B1; 0-1, B2; 0-1, B3; 0-1, ..., and R0; 0-1, R1; -1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVV12B1 or DTV12B1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link B-1 as shown in FIG. 81A. At the same time, 20-bit word string data DVV12B2 or DTV12B2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is used as a link B-2 as shown in FIG. Form.
Similarly, as shown in FIG. 80A, the 12-bit words GD0, GD1, GD2, GD3,..., And the B data series that constitute the G data series in the 36-bit word string data DVV12C or DTV12C are constructed. .., And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence are represented by the upper 10 bits G0. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; .., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. , G1; 0-1, G2; 0-1, G3 0-1, B1; 0-1, B2; 0-1, B3; 0-1,..., And R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVV12C1 or DTV12C1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link C-1 as shown in FIG. 81A. As shown in FIG. 81B, 20-bit word string data DVV12C2 or DTV12C2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. Form.
Also, as shown in FIG. 80B, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in 36-bit word string data DVV12D or DTV12D is constituted. The 12-bit words BD0, BD1, BD2, BD3,... And the 12-bit words RD0, RD1, RD2, RD3,. 2-11, G2; 2-11, G3; 2-11, ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; , And R0; 2-11, R1; 2-11, R2; 2-11, R3; 2-11,. G1: 0-1, G2; 0-1, G3; ..., B0; 0-1, B1; 0-1, B2; 0-1, B3; 0-1, ..., and R0; 0-1, R1; -1, R2; 0-1, R3; 0-1,...
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVV12D1 or DTV12D1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link D-1 as shown in FIG. 81A. At the same time, 20-bit word string data DVV12D2 or DTV12D2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is used as a link D-2 as shown in FIG. Form.
That is, in the data processing unit 291, the data DVV12 or DTV12 forming the 36-bit word string data having the word transmission rate of 297 MBps is converted to the 20-bit word string data DVV12A1 having the word transmission rate of 74.25 MBps. DVV12A2, DVV12B1, DVV12B2, DVV12C1, DVV12C2, DVV12D1, and DVV12D2, or DTV12A1, DTV12A2, DTV12B1, DTV12B2, DTV12C1, DTV12C2, and DTV12D1 and DTV12D2, which are converted into eight-system word string data, are converted into eight series of word string data.
When the digital data DVX is data indicated as data DVU10 + DKU10, the data processing unit 291 sets the frame rate to 120 Hz, sets the number of valid lines in each frame to 1080 lines, and sets the number of valid data samples in each line to 1920 samples. And a Y data sequence having a word transmission rate of 297 MBps and a quantization bit number of 10 bits, _B / P _R A data series (DVU10) and a Key signal data series (DKU10) having a data format equivalent to that of the Y data series and having a quantization bit number of 10 bits and a word transmission rate of 297 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, the Y data series, P, constituting these data DVU10 + DKU10, _B / P _R As shown in FIG. 82, the data sequence and the Key signal data sequence are obtained by performing parallel multiplexing under the condition of frame synchronization and line synchronization, and are obtained as 30-bit parallel data having a word transmission rate of 297 MBps. 291.
The data processing unit 291 performs the following processing on the data DVU10 + DKU10 supplied as shown in FIG.
82. First, as shown in FIG. 82, of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVU10 + DKU10, the first every third frame portion Frame 1, Frame 5, Frame 9 ,..., Second every third frame portion Frame 2, Frame 6, Frame 10,..., Third every third frame portion Frame 3, Frame 7, Frame 11, and , The fourth every third frame part Frame 4, Frame 8, Frame 12. .. Are stored in the memory A, the memory B, the memory C, and the memory D, respectively.
Next, each of the frame portions Frame 1, Frame 5, Frame 9,... Stored in the memory A is read out by the field interlace method, and a series of segments in which the frame rate is set to 120 Hz / 4 = 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal and have a segmented frame portion 1, a segmented frame 5, a segmented frame 9,... _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVU10A + DKU10A having a word transmission rate of 297 MBps / 4 = 74.25 MBps. Further, each of the frame portions Frame 2, Frame 6, Frame 10,... Stored in the memory B is read out by the field interlace method, and a series of segmented frame portions having a frame rate of 30 Hz is obtained. , Segmented Frame 6, Segmented Frame 10,..., And Y data sequence and P which form a segmented frame digital video signal _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVU10B + DKU10B having a word transmission rate of 297 MBps / 4 = 74.25 MBps.
Similarly, each of the frame portions Frame 3, Frame 7, Frame 11,... Stored in the memory C is read out by the field interlace method, and a series of segmented frame portions Segmented in which the frame rate is set to 30 Hz. .. Having a Frame 3, a Segmented Frame 7, a Segmented Frame 11,... _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVU10C + DKU10C having a word transmission rate of 297 MBps / 4 = 74.25 MBps. Further, each of the frame portions Frame 4, Frame 8, Frame 12,... Stored in the memory D is read out by the field interlace method, and a series of segmented frame portions having a frame rate of 30 Hz is set. , Segmented Frame 8, Segmented Frame 12,..., And a Y data sequence and P forming a segmented frame digital video signal _B / P _R It is assumed that 30-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 30-bit word sequence data DVU10D + DKU10D having a word transmission rate of 297 MBps / 4 = 74.25 MBps.
Each of the 30-bit word string data DVU10A + DKU10A, DVU10B + DKU10B, DVU10C + DKU10C and DVU10D + DKU10D is composed of 10-bit words YD0, YD1, YD2, YD3,... _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 10-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel, and are formed as links A, B, C or D.
Then, as shown in FIG. 83, 10-bit words YD0, YD1, YD2, YD3,... Constituting the Y data series in the 30-bit word string data DVU10A + DKU10A, and P _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence are multiplexed in parallel, and the word transmission rate is 74.25 Mbps as shown in FIG. The 20-bit word string data DVUK10A1 is formed as a link A-1. Also, 10-bit words AD0, AD1, AD2, AD3,... Constituting the Key signal data sequence in the 30-bit word string data DVU10A + DKU10A, and auxiliary 10-bit words αD0, αD1, αD2, αD3,. ... are parallel-multiplexed to form 20-bit word string data DVUK10A2 having a word transmission rate of 74.25 MBps as shown in FIG. 84B as a link A-2.
Also, as shown in FIG. 83, each of the 30-bit word string data DVU10B + DKU10B, DVU10C + DKU10C and DVU10D + DKU10D also has a 10-bit word YD0, YD1, YD2, YD3,. P _B / P _R The 10-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series, and the 10-bit words AD0, AD1, AD2, AD3,. . Are added with auxiliary 10-bit words αD0, αD1, αD2, αD3,..., And the same processing as in the case of 30-bit word string data DVU10A + DKU10A is performed, as shown in FIG. The 20-bit word string data DVUK10B1, DVUK10C1 or DVUK10D1 having a word transmission rate of 74.25 MBps is formed as a link B-1, C-1 or D-1, and a word as shown in FIG. 20-bit word string data with a transmission rate of 74.25 MBps DVUK10B2, to form a DVUK10C2 or DVUK10D2 as a link B-2, C-2 or D-2.
That is, in the data processing unit 291, data DVU10 + DKU10 forming 30-bit word string data having a word transmission rate of 297 MBps, and 20-bit word string data DVUK10A1, DVUK10A2 each having a word transmission rate of 74.25 MBps. The data is converted into eight-system word string data of DVUK10B1, DVUK10B2, DVUK10C1, DVUK10C2, DVUK10D1, and DVUK10D2.
When the digital data DVX is data represented as data DVV10 + DKV10, the data processing unit 291 sets the frame rate to 120 Hz, sets the number of valid lines in each frame to 1080 lines, and sets the number of valid data samples in each line to 1920 samples. And a G data sequence, a B data sequence and an R data sequence (DVV10) each having a word transmission rate of 297 MBps and a quantization bit number of 10 bits. A Key signal data sequence (DKV10) having a data format equivalent to the data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps is input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence. These G data sequence, B data sequence, R data sequence and Key signal data sequence are obtained by parallel multiplexing with frame synchronization and line synchronization as shown in FIGS. 85 and 86. The data is supplied to the data processing unit 291 as 40-bit parallel data having a word transmission rate of 297 MBps.
The data processing unit 291 performs the following processing on the data DVV10 + DKV10 supplied as shown in FIGS.
First, as shown in FIG. 85 and FIG. 86, the first every third frame part Frame 1, Frame 5 among the frame parts Frame 1, Frame 2, Frame 3,... Forming the data DVV10 + DKV10. , Frame 9,..., Second every third frame portion Frame 2, Frame 6, Frame 10,..., Third every third frame portion Frame 3, Frame 7, Frame 11. and fourth fourth frame part Frame 4, Frame 8, Frame 12. .. Are stored in the memory A, the memory B, the memory C, and the memory D, respectively.
Next, each of the frame portions Frame 1, Frame 5, Frame 9,... Stored in the memory A is read out by the field interlace method, and a series of segments in which the frame rate is set to 120 Hz / 4 = 30 Hz. A G frame, a B frame, an R frame, and a Key signal data sequence forming a segmented frame digital video signal having a segmented frame portion 1, a Segmented Frame 5, a Segmented Frame 9,... Thus, 40-bit word data DVV10A + DKV10A having a word transmission rate of 297 MBps / 4 = 74.25 MBps is obtained. Further, each of the frame portions Frame 2, Frame 6, Frame 10,... Stored in the memory B is read out by the field interlace method, and a series of segmented frame portions having a frame rate of 30 Hz is obtained. , Segmented Frame 6, Segmented Frame 10,..., And 40-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and a Key signal data sequence that form a segmented frame digital video signal. Thus, 40-bit word string data DVV10B + DKV10B having a word transmission rate of 297 MBps / 4 = 74.25 MBps is obtained.
Similarly, each of the frame portions Frame 3, Frame 7, Frame 11,... Stored in the memory C is read out by the field interlace method, and a series of segmented frame portions Segmented in which the frame rate is set to 30 Hz. 40-bit parallel including a G data sequence, a B data sequence, an R data sequence, and a Key signal data sequence that constitute a segmented frame digital video signal having Frame 3, Segmented Frame 7, Segmented Frame 11,... Data is formed, thereby obtaining 30-bit word string data DVV10C + DKV10C having a word transmission rate of 297 MBps / 4 = 74.25 MBps. Further, each of the frame portions Frame 4, Frame 8, Frame 12,... Stored in the memory D is read out by the field interlace method, and a series of segmented frame portions having a frame rate of 30 Hz is set. , Segmented Frame 8, Segmented Frame 12,..., And 40-bit parallel data including a G data sequence, a B data sequence, an R data sequence, and a Key signal data sequence that form a segmented frame digital video signal. Thus, 30-bit word string data DVV10D + DKV10D having a word transmission rate of 297 MBps / 4 = 74.25 MBps is obtained.
Each of the 40-bit word string data DVV10A + DKV10A, DVV10B + DKV10B, DVV10C + DKV10C and DVV10D + DKV10D is a 10-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series as shown in FIG. , And the 10-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence, and the Key signal data sequence The constituent 10-bit words AD0, AD1, AD2, AD3,... Are formed by parallel multiplexing and formed as links A, B, C or D.
Then, as shown in FIG. 87, 10-bit words GD0, GD1, GD2, GD3,... Constituting the G data series in the 40-bit word string data DVV10A + DKV10A, 10-bit words constituting the B data series BD0, BD1, BD2, BD3,..., 10-bit words RD0, RD1, RD2, RD3,... Forming an R data sequence, and 10-bit words AD0 forming a Key signal data sequence , AD1, AD2, AD3,... Are divided by a thick solid line in FIG. 37, and 10-bit words GD0, GD1, GD2, GD3,. , Forming 10-bit words BD0, BD2,... Forming the B data sequence and forming the R data sequence A 10-bit word group 1 including 0-bit words RD0, RD2,... And a 10-bit word AD0, AD1, AD2, AD3,. , And 10-bit word groups 2 including 10-bit words RD1, RD3,... Forming the R data sequence. Then, 20-bit word string data DVVK10A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 37 is formed as a link A-1, as shown in FIG. 88A. The 20-bit word string data DVVK10A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 37 is formed as a link A-2 as shown in FIG. 88B.
Also, as shown in FIG. 87, for each of the 40-bit word string data DVV10B + DKV10B, DVV10C + DKV10C and DVV10D + DKV10D, the 10-bit words GD0, GD1, GD2, GD3,. .., 10-bit words RD0, RD1, RD2, RD3,... Constituting the R data series, and the Key signal The same processing as in the case of the 40-bit word string data DVV10A + DKV10A is performed on the 10-bit words AD0, AD1, AD2, AD3,... Constituting the data sequence, and the words as shown in FIG. 20 videos with a transmission rate of 74.25 MBps The word string data DVVK10B1, DVVK10C1 or DVVK10D1 is formed as a link B-1, C-1 or D-1 and a 20-bit word string data having a word transmission rate of 74.25 MBps as shown in FIG. 88B. The DVVK10B2, DVVK10C2 or DVVK10D2 is formed as a link B-2, C-2 or D-2.
That is, in the data processing unit 291, data DVV10 + DKV10 forming 40-bit word string data having a word transmission rate of 297 MBps, and 20-bit word string data DVVK10A1 and DVVK10A2 each having a word transmission rate of 74.25 MBps. The data is converted into eight-system word string data of DVVK10B1, DVVK10B2, VVK10C1, DVVK10C2, DVVK10D1, and DVVK10D2.
The data processor 291 is a set of 20-bit word string data DVV10A1, DVV10A2, DVV10B1, DVV10B2, DVV10C1, DVV10C2, DVV10D1, and DVV10D2, which are eight-word word string data. A set of DVV12C1, DVV12C2, DVV12D1 and DVV12D2, a set of 20-bit word string data DTV10A1, DTV10A2, DTV10B1, DTV10B2, a set of DTV10C1, DTV10C2, DTV10D1 and DTV10D2, a set of 20-bit word string data DTV12A1, DTV12, CTV12A12, DTV12V12, CTV12B12 DTV12D1 and DT A set of 12D2, a set of 20-bit word string data DVUK10A1, DVUK10A2, DVUK10B1, DVUK10B2, DVUK10C1, DVUK10C2, a set of DVUK10D1 and DVUK10D2, and a set of 20-bit word string data DVK10, DVK10, DVK10A2, DVK10D2, DVK10D2 One of the sets is converted to 20-bit word string data DPA1 (20), DPA2 (20), DPB1 (20), DPB2 (20), DPC1 (20), DPC2 (20), DPD1 (20), and DPD2 (20). Is derived as a set.
20-bit word string data DPA1 (20) with 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 needed into the 20-bit word string data DPA1 (20), and the 20-bit word string data DPA1 ′ into which the auxiliary data DAA1 has been 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.
The P / S conversion unit 293 performs P / S conversion on the 20-bit word string data DPA1 ′ (20) to increase the bit transmission rate based on the 20-bit word string data DPA1 ′ (20) to 74.25 Mbps. The serial data DSA1 with 20 = 1.485 Gbps is formed, and the serial data DSA1 is supplied to the E / O converter 294.
The E / O converter 294 performs an electro-optical conversion process on the serial data DSA1, and converts the optical signal OSA1 having a center wavelength of, for example, approximately 1.3 μm based on the serial data DSA1 to a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
Also, 20-bit word string data DPA2 (20), DPB1 (20), DPB2 (20), DPC1 (20), DPC2 (20), DPD1 with a word transmission rate of 74.25 MBps sent from data processing section 291. (20) and DPD2 (20) are supplied to the data insertion units 295 to 301, respectively. In the data insertion units 295 to 301, the 20-bit word string data DPA2 (20), DPB1 (20), DPB2 (20), DPC1 (20), DPC2 (20), DPD1 (20), and DPD2 (20) , Auxiliary data DAA2, DAB1, DAB2, DAC1, DAC2, DAD1 and DAD2 including channel identification data as required, and 20-bit word string data DPA2 ′ (20), DPB1 ′ (20) into which the auxiliary data has been inserted. 20), DPB2 '(20), DPC1' (20), DPC2 '(20), DPD1' (20) and DPD2 '(20).
20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20), DPC2 '(20), DPC1' (20) obtained from data insertion units 295-301. And DPD2 ′ (20) are supplied to P / S converters 302 to 308, respectively.
In the P / S converters 302 to 308, the 20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20), DPC2 '(20), DPD1' (20) and DPD2 ′ (20) are subjected to P / S conversion, and the serial data DSA2, DSB1, DSB2, DSC1, DSC2, DSD1 and the bit transmission rate based on them are set to 74.25 MBps × 20 = 1.485 Gbps. The DSDs 2 are formed and supplied to the E / O converters 310 to 316.
In the E / O converters 310 to 316, the serial data DSA2, DSB1, DSB2, DSC1, DSC2, DSD1, and DSD2 are subjected to light-to-light conversion processing, and a light having a center wavelength of, for example, about 1.3 μm based on them. The signals OSA2, OSB1, OSB2, OSC1, OSC2, OSD1, and OSD2 are each formed to have a bit transmission rate of 1.485 Gbps, and are transmitted as transmission signals.
Under these circumstances, the E / O converters 294 and 310 to 316 convert the serial data DSA1, DSA2, DSB1, DSB2, DSC1, DSC2, DSD1, and DSD2 obtained from the P / S converters 293 and 302 to 308, respectively. A data transmitting unit for transmitting the data is formed.
The optical signal OSA1, which is a transmission signal transmitted from the E / O conversion unit 294, is guided to the optical fiber transmission line 321 through the optical connector 320, and is transmitted to the receiving side through the optical fiber transmission line 321. The optical signals OSA2, OSB1, OSB2, OSC1, OSC2, OSD1, and OSD2, which are transmission signals transmitted from the E / O converters 310 to 316, are transmitted to the optical fiber transmission lines 329 to 335 through the optical connectors 322 to 328, respectively. It is guided and transmitted to the receiving side through optical fiber transmission lines 329 to 335. Each of the optical fiber transmission lines 321 and 329 to 335 is formed using, for example, a quartz SMF.
On the receiving side, the optical signal OSA1 transmitted through the optical fiber transmission line 321 is guided to the O / E converter 337 through the optical connector 336. The optical signals OSA2, OSB1, OSB2, OSC1, OSC2, OSD1 and OSD2 transmitted through the optical fiber transmission lines 329 to 335 are guided to the O / E converters 350 to 356 through the optical connectors 339 to 345, respectively.
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, thereby obtaining a bit transmission rate based on the optical signal OSA1. The serial data DSA1 having 1.485 Gbps is reproduced. Then, 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, and reproduces 20-bit word string data DPA1 ′ (20) having a word transmission rate of 74.25 MBps based on the serial data DSA1. Then, it is supplied to the data time difference absorption unit 361.
In the O / E converters 350 to 356, the optical signals OSA2, OSB1, OSB2, OSC1, OSC2, OSD1, and OSD2 having a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.3 μm are provided. The conversion processing is performed, and the serial data DSA2, DSB1, DSB2, DSC1, DSC2, DSD1, and DSD2 whose bit transmission rate is 1.485 Gbps are reproduced based on the conversion processing. Then, the reproduced serial data DSA2, DSB1, DSB2, DSC1, DSC2, DSD1, and DSD2 are supplied to the S / P converters 362 to 368, respectively. In the S / P converters 362 to 368, the serial data DSA2, DSB1, DSB2, DSC1, DSC2, DSD1, and DSD2 are subjected to S / P conversion, and the word transmission rate based thereon is set to 74.25 MBps. 20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '(20), DPC1' (20), DPC2 '(20), DPD1' (20) and DPD2 '(20) are reproduced; These are supplied to the data time difference absorption unit 361.
In the data time difference absorption unit 361, the 20-bit word string data DPA1 ′ (20) from the S / P conversion unit 360 and the 20-bit word string data DPA2 ′ (20) from the S / P conversion units 362 to 368, DPB1 '(20), DPB2' (20), DPC1 '(20), DPC2' (20), DPD1 '(20) and the mutual time difference generated between DPD2' (20) are absorbed, and a 20-bit word string is absorbed. 20-bit word string data DPA1Q '(20) having a word transmission rate based on data DPA1' (20) of 74.25 MBps, and 20-bit word string data DPA2 '(20), DPB1' (20), DPB2 '( 20), a word transmission rate of 74.25 MB based on each of DPC1 '(20), DPC2' (20), DPD1 '(20) and DPD2' (20). The 20-bit word string data DPA2Q '(20), DPB1Q' (20), DPB2Q '(20), DPC1Q' (20), DPC2Q '(20), DPD1Q' (20) and DPD2Q '(20) , Are sent to be maintained to have substantially no mutual time difference.
The 20-bit word string data DPA1Q ′ (20) obtained from the data time difference absorption unit 361 is supplied to the data separation unit 370. In the data separation unit 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 separately transmitted. The bit word string data DPA1Q (20) is supplied to the data reproduction processing unit 371.
Also, 20-bit word string data DPA2Q '(20), DPB1Q' (20), DPB2Q '(20), DPC1Q' (20), DPC2Q '(20), DPD1Q' (20) obtained from data time difference absorbing section 361. And DPD2Q ′ (20) are supplied to the data separation units 372 to 378, respectively. In the data separation units 372 to 378, the 20-bit word string data DPA2Q '(20), DPB1Q' (20), DPB2Q '(20), DPC1Q' (20), DPC2Q '(20), DPD1Q' (20 ) And DPD2Q '(20), the auxiliary data DAA2, DAB1, DAB2, DAC1, DAC2, DAD1 and DAD2 are separated, and the 20-bit word string data DPA2Q (20), DPB1Q (20), DPB2Q (20), DPC1Q (20), DPC2Q (20), DPD1Q (20), and DPD2Q (20), and auxiliary data DAA2, DAB1, DAB2, DAC1, DAC2, DAD1, and DAD2 are individually transmitted, and the 20-bit word string data DPA2Q (20 ), DPB1Q (20), DPB2Q (20), DPC1 Q (20), DPC2Q (20), DPD1Q (20) and DPD2Q (20) are supplied to the data reproduction processing unit 371.
In the data reproduction processing unit 371, 20-bit word string data DPA1Q (20), DPA2Q (20), DPB1Q (20), DPB2Q (20), DPC1Q (20), DPC2Q (20), DPD1Q (20) and DPD2Q (20) is subjected to data reproduction processing opposite to the data conversion processing performed on digital data DVX by data processing section 291 on the transmission side, and 20-bit word string data DPA1Q (20), DPA2Q (20). , DPB1Q (20), DPB2Q (20), DPC1Q (20), DPC2Q (20), DPD1Q (20) and digital data DVX based on DPD2Q (20). Such digital data DVX is one of the data DVV10 and DVV12 shown in FIG. 3, the data DTV10 and DTV12 shown in FIG. 4, and further, the data DVU10 + DKU10 and DVV10 + DKV10.
In the above description, in data forming a digital video signal having a quantization bit number of 12 bits or more, the upper 10 bits divided from each of the 12-bit words constituting each of the G data sequence, the B data sequence, and the R data sequence. The 20-bit word string data DVV12A1, DVV12B1, DVV12C1, DVV12D1, and the like formed based on the bit string can each be recorded and reproduced by, for example, a current HD VTR. Therefore, the contents of the 20-bit word string data DVV12A1, DVV12B1, DVV12C1, DVV12D1, etc. can be confirmed and edited using the current HD VTR. Using a video monitor, it is possible to obtain a reproduced image based on each of the 20-bit word string data DVV12A1, DVV12B1, DVV12C1, DVV12D1, etc., whereby a digital video signal having a quantization bit number of 12 bits or more can be obtained. When handling generated data, it is possible to perform a confirmation operation or the like using an existing device, which is extremely convenient.
FIGS. 89 and 90 show data according to the present invention in which an example of any of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the data transmission method according to the present invention is implemented. 15 shows a part of a data transmitting / receiving device including a second example of any of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the transmission device.
The data transmission / reception device whose parts are shown in FIGS. 89 and 90 has many parts configured similarly to the data transmission / reception device shown in FIGS. 72 and 73, and FIGS. Only the parts different from the data transmission / reception device shown in FIG. 73 and the parts related thereto are shown.
In the data transmission / reception device whose parts are shown in FIGS. 89 and 90, the E / O conversion units 294 and 310 to 316 and the O / E conversion unit provided in the data transmission / reception device shown in FIGS. E / O converters 385 to 388 and O / E converters 404 to 407 are provided instead of 337 and 350 to 356. Further, instead of the optical connectors 320 and 322 to 328, the optical fiber transmission lines 321 and 329 to 335, and the optical connectors 336 and 339 to 345 provided in the data transmitting and receiving apparatus shown in FIGS. 389 to 392, optical fiber transmission paths 395 to 398, and optical connectors 400 to 403. Each of the optical fiber transmission paths 395 to 398 is formed using, for example, a quartz SMF.
In the data transmission / reception device whose parts are shown in FIGS. 89 and 90, the serial data DSA1 having a bit transmission rate of 1.485 Gbps from P / S conversion section 293 and the bit transmission rate from P / S conversion section 302 Is supplied to the bit multiplexing unit 381. The bit multiplexing unit 381 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSA1 and DSA2, and performing bit multiplexing and combining processing on the serial data DSA1 and DSA2 to reduce the bit transmission rate. The composite serial data DZA with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZA obtained from the bit multiplexing unit 381 is supplied to the E / O conversion unit 385. In the E / O converter 385, an optical signal OZA having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZA is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
The serial data DSB1 from the P / S conversion unit 303 with a bit transmission rate of 1.485 Gbps and the serial data DSB2 from the P / S conversion unit 304 with a bit transmission rate of 1.485 Gbps are supplied to the bit multiplexing unit 382. Is done. The bit multiplexing unit 382 performs an operation of alternately extracting and sequentially arranging one bit from each of the serial data DSB1 and DSB2, and performing a bit multiplexing / combining process on the serial data DSB1 and DSB2 to reduce the bit transmission rate. The composite serial data DZB with 1.485 Gbps × 2 = 2.97 Gbps is formed.
Composite serial data DZB obtained from bit multiplexing section 382 is supplied to E / O conversion section 386. In the E / O conversion unit 386, an optical signal OZB having a center wavelength of, for example, about 1.3 μm based on the composite serial data DZB is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
The serial data DSC1 with a bit transmission rate of 1.485 Gbps from the P / S converter 305 and the serial data DSC2 with a bit transmission rate of 1.485 Gbps from the P / S converter 306 are supplied to the bit multiplexing unit 383. Is done. The bit multiplexing unit 383 performs an operation of alternately extracting and sequentially arranging 1-bit addresses from each of the serial data DSC1 and DSC2, and performing bit multiplexing and combining processing on the serial data DSC1 and DSC2 to reduce the bit transmission rate. The composite serial data DZC having 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZC obtained from the bit multiplexing unit 383 is supplied to the E / O conversion unit 387. In the E / O converter 387, an optical signal OZC having a center wavelength of, for example, about 1.3 μm based on the composite serial data DZC is formed with a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Further, the serial data DSD1 from the P / S converter 307 with a bit transmission rate of 1.485 Gbps and the serial data DSD2 from the P / S converter 308 with a bit transmission rate of 1.485 Gbps are combined with a bit multiplexing unit 384. Supplied to The bit multiplexing unit 384 performs an operation of alternately extracting and sequentially arranging one bit from each of the serial data DSD1 and DSD2, and performing a bit multiplexing / combining process on the serial data DSD1 and DSD2 to reduce the bit transmission rate. The composite serial data DZD with 1.485 Gbps × 2 = 2.97 Gbps is formed.
The composite serial data DZD obtained from the bit multiplexing unit 384 is supplied to the E / O conversion unit 388. The E / O conversion unit 388 forms an optical signal OZD having a center wavelength of, for example, approximately 1.3 μm based on the composite serial data DZD as having a bit transmission rate of 2.97 Gbps. Is transmitted as a transmission signal.
Under these circumstances, the bit multiplexing units 381 to 384 and the E / O conversion units 385 to 388 correspond to the serial data DSA1, DSA2, DSB1, DSB2, DSC1, and DS1 obtained from the P / S conversion units 293 and 302 to 308, respectively. A data transmission unit for transmitting DSC2, DSD1 and DSD2 for transmission is formed.
The optical signal OZA, which is a transmission signal transmitted from the E / O converter 385, is guided to the optical fiber transmission line 395 through the optical connector 389, and is transmitted to the receiving side through the optical fiber transmission line 395. The optical signal OZB, which is a transmission signal transmitted from the E / O converter 386, is guided to the optical fiber transmission line 396 through the optical connector 390, and is transmitted to the receiving side through the optical fiber transmission line 396. The optical signal OZC, which is a transmission signal transmitted from the E / O conversion unit 387, is guided to the optical fiber transmission path 397 through the optical connector 391, and is transmitted to the receiving side through the optical fiber transmission path 397. Further, the optical signal OZD, which is a transmission signal transmitted from the E / O conversion unit 388, is guided to the optical fiber transmission line 398 through the optical connector 392, and is transmitted to the receiving side through the optical fiber transmission line 398.
On the receiving side, the optical signal OZA transmitted through the optical fiber transmission line 395 is guided to the O / E converter 404 through the optical connector 400. The optical signal OZB transmitted through the optical fiber transmission path 396 is guided to the O / E converter 405 through the optical connector 401. The optical signal OZC 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 OZD transmitted through the optical fiber transmission line 398 is guided to the O / E converter 407 through the optical connector 403.
The O / E conversion unit 404 performs a photoelectric conversion process on the optical signal OZA having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and obtains a bit transmission rate based on the optical signal OZA. The composite serial data DZA at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZA is supplied to the bit separation unit 408.
The bit separation section 408 takes out one bit at a time from the composite serial data DZA, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZA. Then, a channel is specified by using the channel identification data included in the composite serial data DZA, and based on the composite serial data DZA, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The 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.
The O / E conversion unit 405 performs a photoelectric conversion process on the optical signal OZB having a center wavelength of about 1.3 μm and a bit transmission rate of 2.97 Gbps, and adjusts the bit transmission rate based on the optical signal OZB. The composite serial data DZB at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZB is supplied to the bit separation unit 409.
The bit separation unit 409 extracts one bit at a time from the composite serial data DZB, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZB. Then, a channel is specified by using the channel identification data included in the composite serial data DZB, and based on the composite serial data DZB, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSB1 and DSB2 are formed. The serial data DSB1 is supplied to the S / P converter 363, and the serial data DSB2 is supplied to the S / P converter 364.
The O / E conversion unit 406 performs a photoelectric conversion process on the optical signal OZC having a center wavelength of approximately 1.3 μm and a bit transmission rate of 2.97 Gbps, and determines a bit transmission rate based on the optical signal OZC. The composite serial data DZC at 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZC is supplied to the bit separation unit 410.
The bit separation unit 410 takes out one bit at a time from the composite serial data DZC, performs an operation of forming every other two bit groups, and performs bit separation processing on the composite serial data DZC. Then, a channel is specified by using the channel identification data included in the composite serial data DZC, and based on the composite serial data DZC, a two-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSC1 and DSC2 are formed. The serial data DSC1 is supplied to the S / P converter 365, and the serial data DSC2 is supplied to the S / P converter 366.
Further, the O / E converter 407 performs a photoelectric conversion process on the optical signal OZD having a center wavelength of approximately 1.3 μm and a bit transmission rate of 2.97 Gbps, and performs bit transmission based on the optical signal OZD. The composite serial data DZD having a rate of 2.97 Gbps is reproduced. Then, the reproduced composite serial data DZD is supplied to the bit separation unit 411.
The bit separation unit 411 extracts one bit at a time from the composite serial data DZD, performs an operation of forming every other bit group, and performs bit separation processing on the composite serial data DZD. Then, a channel is specified by using the channel identification data included in the composite serial data DZD, and based on the composite serial data DZD, a 2-channel serial whose bit transmission rate is 2.97 Gbps / 2 = 1.485 Gbps. The data DSD1 and DSD2 are formed. The serial data DSD1 is supplied to the S / P converter 367, and the serial data DSD2 is supplied to the S / P converter 368.
Other operations are the same as those of the data transmitting / receiving apparatus whose parts are shown in FIGS. 72 and 73.
FIGS. 91 and 92 show a data transmission method according to the present invention in which an example of any one of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the data transmission method according to the present invention is implemented. 15 shows a portion of a data transmission / reception device including a third example of any of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the transmission device.
The data transmission / reception device whose parts are shown in FIGS. 91 and 92 has many parts configured similarly to the data transmission / reception device shown in FIGS. 72 and 73, and FIGS. Only the parts different from the data transmission / reception device shown in FIG. 73 and the parts related thereto are shown.
In the data transmission / reception device whose parts are shown in FIGS. 91 and 92, the E / O conversion units 294 and 310 to 316 and the O / E conversion unit provided in the data transmission / reception device shown in FIGS. Instead of 337 and 350 to 356, E / O converters 294C and 310C to 316C and O / E converters 337C and 350C to 356C are provided. Furthermore, instead of the optical connectors 320 and 322 to 328, the optical fiber transmission lines 321 and 329 to 335, and the optical connectors 336 and 339 to 345 provided in the data transmitting / receiving apparatus shown in FIGS. A section 415, an optical connector 416, an optical fiber transmission path 417, an optical connector 418, and a demultiplexing section 419 are provided. The optical fiber transmission path 417 is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIGS. 91 and 92, the bit transmission rate from P / S conversion section 293 is 1.485 Gbps. Is set to 1.485 Gbps. Serial data DSA2, the bit transmission rate from the P / S converter 303 is set to 1.485 Gbps. The serial data DSB1, the bit transmission rate from the P / S converter 304 is set to 1.485 Gbps. DSB2, serial data DSC1 with a bit transmission rate of 1.485 Gbps from P / S conversion section 305, serial data DSC2 with a bit transmission rate of 1.485 Gbps from P / S conversion section 306, P / S conversion section 307 Bit rate from 1.485 Gbps That the bit transmission rate of the serial data DSD1 and P / S conversion unit 308 is a serial data DSD2 to 1.485 Gbps, respectively, are supplied to the E / O conversion unit 294C and 310C～316C.
The E / O conversion unit 294C forms an optical signal OSA1 having a center wavelength of, for example, approximately 1.471 μm based on the serial data DSA1 as a signal having a bit transmission rate of 1.485 Gbps, and combines it with a multiplexing unit. 415. The E / O converter 310C forms an optical signal OSA2 having a center wavelength of, for example, approximately 1.491 μm, based on the serial data DSA2, with a bit transmission rate of 1.485 Gbps, and combines the optical signal OSA2 with the optical signal OSA2. 415. The E / O conversion unit 311C forms an optical signal OSB1 having a center wavelength of, for example, approximately 1.511 μm based on the serial data DSB1 at a bit transmission rate of 1.485 Gbps, and combines it with a multiplexing unit. 415. The E / O conversion unit 312C forms an optical signal OSB2 having a center wavelength of, for example, approximately 1.531 μm based on the serial data DSB2 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OSB2 with the multiplexing unit. 415.
Further, the E / O conversion unit 313C forms an optical signal OSC1 having a center wavelength of, for example, approximately 1.551 μm based on the serial data DSC1 at a bit transmission rate of 1.485 Gbps, and combines the signals. It supplies to the wave part 415. The E / O conversion unit 314C forms an optical signal OSC2 having a center wavelength of, for example, approximately 1.571 μm based on the serial data DSC2 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OSC2 with the multiplexed unit. 415. The E / O conversion unit 315C forms an optical signal OSD1 having a center wavelength of, for example, approximately 1.591 μm based on the serial data DSD1 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OSD1 with the multiplexing unit. 415. The E / O conversion unit 316C forms an optical signal OSD2 having a center wavelength of, for example, approximately 1.611 μm based on the serial data DSD2 at a bit transmission rate of 1.485 Gbps, and combines the optical signal OSD2 with the multiplexing unit. 415.
In the multiplexing unit 415, an optical signal OSA having a center wavelength of about 1.471 μm, an optical signal OSA having a center wavelength of about 1.491 μm, an optical signal OSB having a center wavelength of about 1.511 μm, and a center wavelength , An optical signal OSC1 having a center wavelength of about 1.551 μm, an optical signal OSC1 having a center wavelength of about 1.571 μm, an optical signal OSD1 having a center wavelength of about 1.591 μm, and An optical signal OSD2 having a center wavelength of about 1.611 μm is multiplexed and multiplexed to form a multiplexed optical signal OCW, which is transmitted as a transmission signal. Under these circumstances, the E / O conversion units 294C and 310C to 316C and the multiplexing unit 415 correspond to the serial data DSA1, DSA2, DSB1, DSB2, DSC1, and DS1 obtained from the P / S conversion units 293 and 302 to 308, respectively. A data transmission unit for transmitting DSC2, DSD1 and DSD2 for transmission is formed.
In this way, the optical signals OSA1, OSA2, OSB1, OSB2, OSC1, OSC2, OSD1, and OSD2 multiplexed in the multiplexing unit 415 have their center wavelengths separated by about 0.020 μm (20 nm). And are multiplexed with wavelengths very close to each other to form a multiplexed optical signal OCW, including E / O converters 294C and 310C-316C and a multiplexer 415. In part, a wavelength multiplexing technique called CWMD is used.
The multiplexed optical signal OCW, which is a transmission signal transmitted from the multiplexing unit 415, is guided to the optical fiber transmission line 417 through the optical connector 416, and is transmitted to the receiving side through the optical fiber transmission line 417.
On the receiving side, the multiplexed optical signal OCW transmitted through the optical fiber transmission line 417 is guided to the demultiplexer 419 through the optical connector 418. The demultiplexing unit 419 converts the multiplexed optical signal OCW into 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. , A component having a center wavelength of approximately 1.551 μm, a component having a center wavelength of approximately 1.571 μm, a component having a center wavelength of approximately 1.591 μm, and a center wavelength of approximately 1.611 μm. The optical signal OSA has a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.471 μm, and an optical signal with a bit transmission rate of 1.485 Gbps and a center wavelength of about 1.491 μm. OSA2, the bit transmission rate is 1.485 Gbps, the optical signal OSB has a center wavelength of about 1.511 μm, and the bit transmission rate is 1.485 Gbps. The optical signal OSB2 has a core wavelength of about 1.531 μm, the bit transmission rate is 1.485 Gbps, the optical signal OSC has a center wavelength of about 1.551 μm, the bit transmission rate is 1.485 Gbps, and the center wavelength is about 1.85 Gbps. An optical signal OSC1 having a wavelength of 571 μm, an optical signal OSD1 having a bit transmission rate of 1.485 Gbps and a center wavelength of approximately 1.591 μm, and an optical signal OSD1 having a bit transmission rate of 1.485 Gbps and a center wavelength of approximately 1.611 μm The signal OSD2 is reproduced.
The optical signals OSA1, OSA2, OSB1, OSB2, OSC1, OSC2, OSD1 and OSD2 reproduced by the demultiplexer 419 are guided to O / E converters 337C and 350C to 356C, respectively. The O / E converter 337C performs a photoelectric conversion process on the optical signal OSA1 having a center wavelength of approximately 1.471 μm, and converts the serial data DSA1 based on the optical signal OSA1 and having a bit transmission rate of 1.485 Gbps. Reproduce. The O / E converter 350C performs a photoelectric conversion process on the optical signal OSA2 having a center wavelength of approximately 1.491 μm, and converts the serial data DSA2 based on the optical signal OSA2 and having a bit transmission rate of 1.485 Gbps. Reproduce. The O / E converter 351C performs a photoelectric conversion process on the optical signal OSB1 having a center wavelength of about 1.511 μm, and converts the serial data DSB1 having a bit transmission rate of 1.485 Gbps based on the optical signal OSB1. Reproduce. The O / E conversion unit 352C performs a photoelectric conversion process on the optical signal OSB2 having the center wavelength of about 1.531 μm, and converts the serial data DSB2 having the bit transmission rate of 1.485 Gbps based on the optical signal OSB2. Reproduce.
The O / E conversion unit 353C performs a photoelectric conversion process on the optical signal OSC1 having the center wavelength of about 1.551 μm, and converts the serial data DSC1 based on the optical signal OSC1 and having a bit transmission rate of 1.485 Gbps. Reproduce. The O / E conversion unit 354C performs a photoelectric conversion process on the optical signal OSC2 having the center wavelength of about 1.571 μm, and converts the serial data DSC2 having a bit transmission rate of 1.485 Gbps based on the optical signal OSC2. Reproduce. The O / E conversion unit 355C performs a photoelectric conversion process on the optical signal OSD1 having the center wavelength of about 1.591 μm to convert the serial data DSD1 based on the optical signal OSD1 and having the bit transmission rate of 1.485 Gbps. Reproduce. Then, the O / E conversion unit 356C performs a photoelectric conversion process on the optical signal OSD2 having the center wavelength of about 1.611 μm to obtain a serial data having a bit transmission rate of 1.485 Gbps based on the optical signal OSD2. Play DSD2.
Then, the serial data DSA1, DSA2, DSB1, DSB2, DSC1, DSC2, DSD1, and DSD2 reproduced by the O / E converters 337C and 350C to 356C are supplied to the S / P converters 360 and 362 to 368, respectively. You.
Other operations are the same as those of the data transmitting / receiving apparatus shown in FIGS. 72 and 73.
FIGS. 93 and 94 show the 31st, 32nd, 40th, and 41st embodiments of the data transmission method according to the present invention. 30 shows a data transmission / reception device including a first example of any of the 32nd, 40th, and 41st modes.
In the data transmission / reception device shown in FIGS. 93 and 94, digital data DVX forming a digital video signal is supplied to the data processing unit 421 on the transmission side constituting an example of the data transmission device according to the present invention.
The digital data DVX is one of the data DVR12 + DKR12, DVR14 + DKR14, DVR16 + DKR16, DVS12 + DKS12, DTR12 + DYR12, DTR14 + DYR14, DTR16 + DYR16 and DTS12 + DYS12.
When the digital data DVX is data indicated as data DVR12 + DKR12, the data processing unit 421 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is Are set to 1920 samples, form a digital video signal of 4: 2: 2 format, each of which has a quantization bit number of 12 bits and a word transmission rate of 222.75 MBps. _B / P _R A data sequence (DVR12) and a Key signal data sequence (DKR12) having a data format equivalent to that of the Y data sequence, a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
When the digital data DVX is data indicated as data DTR12 + DYR12, the data processing unit 421 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the effective data in each line is 720. A Y data sequence and a Y data sequence which form a digital video signal of 4: 2: 2 format in which the number of samples is set to 1280 and each have a quantization bit number of 12 bits and a word transmission rate of 222.75 MBps. _B / P _R A data sequence (DTR12) and a Key signal data sequence (DYR12) having a data format equivalent to that of the Y data sequence and having a quantization bit number of 12 bits and a word transmission rate of 222.75 MBps are input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, a Y data series constituting these data DVR12 + DKR12 or DTR12 + DYR12, P _B / P _R As shown in FIG. 95, the data sequence and the key signal data sequence are 36-bit parallel data having a word transmission rate of 222.75 MBps, which is obtained by parallel multiplexing with frame synchronization and line synchronization. It is supplied to the processing unit 421.
The data processing unit 421 performs the following processing on the data DVR12 + DKR12 or DTR12 + DYR12 supplied as shown in FIG.
First, as shown in FIG. 95, the first two frame portions Frame 1 and Frame 4 of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVR12 + DKR12 or DTR12 + DYR12. , Frame 7,..., A second alternate frame portion Frame 2, Frame 5, Frame 8,..., And a third alternate frame portion Frame 3, Frame 6 , Frame 9,... Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a Y data sequence and P having a series of segmented frame sections, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,..., At 90 Hz / 3 = 30 Hz, forming a segmented frame digital video signal. _B / P _R It is assumed that 36-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 36-bit word sequence data DVR12A + DKR12A or DTR12A + DYR12A having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps.
Also, each of the frame parts Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal having a segmented frame section 2, a segmented frame 5, a segmented frame 8,... _B / P _R It is assumed that 36-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 36-bit word sequence data DVR12B + DKR12B or DTR12B + DYR12B having a word transmission rate of 74.25 MBps.
Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A Y data sequence and a P which form a segmented frame digital video signal and have a segmented frame portion 3, a segmented frame 6, a segmented frame 9,... _B / P _R It is assumed that 36-bit parallel data including a data sequence and a Key signal data sequence is formed, thereby obtaining 36-bit word sequence data DVR12C + DKR12C or DTR12C + DYR12C having a word transmission rate of 74.25 MBps.
96-bit word string data DVR12A + DKR12A, DVR12B + DKR12B and DVR12C + DKR12C, or DTR12A + DYR12A, DTR12B + DYR12B and DTR12C + DYR12C, respectively, are Y bits of the Y data sequence as shown in FIG.・ ・ 、 P _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are multiplexed in parallel and formed as link A, link B or link C.
Subsequently, as shown in FIG. 96, 12-bit words YD0, YD1, YD2, YD3,..., P constituting a Y data sequence in 36-bit word string data DVR12A + DKR12A or DTR12A + DYR12A. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11, ..., Pb0; 2-11, Pr0; Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11,..., And A0; 2-11, A1; 2-11, A2; 2-11, .. And lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1,..., Pb0; , Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, P , and A0; 0-1 A1; 0-1, A2; 0-1, A3; 0-1,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVRK12A1 or DTRY12A1 having a rate of 74.25 MBps is formed as a link A-1 as shown in FIG. 97A.
The lower two bits Y0; 0-1, Y1; 0-1, Y2; 0-1, Y3; 0-1,... Are replaced by 8-bit auxiliary bits c0, c1, c2. are added to each other to add 10 bits [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3 ... And the lower 2 bits Pb0; 0-1, Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, Pr2; ,... Are added with 8-bit auxiliary bits d0, d1, d2, d3,..., Respectively, and 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 .... And a 10-bit string: [Y0; 0-1] + c0, [Y1; 0-1] + c1, [Y2; 0-1] + c2, [Y3; 0-1] + c3,. 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 parallel-multiplexed, and the 20-bit word string data DVRK12A2 or DTRY12A2 having a word transmission rate of 74.25 MBps is used as a link A-2 in FIG. Form as shown.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 ... And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVRK12A3 or DTRY12A3 having a rate of 74.25 MBps is used as a link A-3. It formed as shown in the 97 C.
Similarly, as shown in FIG. 96, the 12-bit word YD0, YD1, YD2, YD3,. ..., P _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data series, and the 12-bit words AD0, AD1, AD2, AD3,.・ The same processing as in the case of the 36-bit word string data DVR12A + DKR12A or DTR12A + DYR12A is applied to each of. As a result, as shown in FIG. 97A, 20-bit word string data DVRK12B1 or DTRY12B1 having a word transmission rate of 74.25 MBps, or DVRK12C1 or DTRY12C1 is formed as link B-1 or link C-1. As shown in FIG. 97B, 20-bit word string data DVRK12B2 or DTRY12B2 having a word transmission rate of 74.25 MBps or DVRK12C2 or DTRY12C2 is formed as a link B-2 or a link C-2. 97, 20-bit word string data DVRK12B3 or DTRY12B3 having a word transmission rate of 74.25 MBps, or DVRK12C3 or DTRY12C3, as shown in FIG. , Formed as a link B-3 or the link C-3.
That is, in the data processing unit 421, the data DVR12 + DKR12 or the data DTR12 + DYR12 forming the 36-bit word string data having the word transmission rate of 222.75 MBps, and the 20-bit word string having the word transmission rate of 74.25 MBps, respectively. Data DVRK12A1, DVRK12A2, DVRK12A3, DVRK12B1, DVRK12B2, DVRK12B3, DVRK12C1, DVRK12C2 and DVRK12C3, or DTRY12A1, DTRY12A2, DTRY12B3, DTRY12B1, DTRY12B3 .
In the data processing unit 421, the data DVR12A + DKR12A, DVR12B + DKR12B and DVR12C + DKR12C obtained as shown in FIG. Perform processing.
First, as shown in FIG. 96, 12-bit words YD0, YD1, YD2, YD3,..., P constituting a Y data sequence in 36-bit word string data DVR12A + DKR12A or DTR12A + DYR12A. _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. Are represented by the upper 10 bits Y0; 2-11, Y1; 2-11, Y2; 2-11, Y3; 2-11, ..., Pb0; 2-11, Pr0; Pb1; 2-11, Pr1; 2-11, Pb2; 2-11, Pr2; 2-11,..., And A0; 2-11, A1; 2-11, A2; 2-11, .. And lower two bits Y0; 0-1 Y1; 0-1, Y2; 0-1, Y3; 0-1,..., Pb0; , Pr0; 0-1, Pb1; 0-1, Pr1; 0-1, Pb2; 0-1, P .. and A0; 0-1, A1; 0-1, A2; 0-1, A3; 0-1,.
A sequence of the divided upper 10 bits: 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,. The 20-bit word string data DVRK12A1 or DTRY12A1 having a transmission rate of 74.25 MBps is formed as a link A-1 as shown in FIG. 98A.
Also, the lower two bits Y0; 0-1 and Pb0; 0-1 and Pr0; 0-1 are multiplexed, and 10 bits [Y0BR0; 0-1] obtained by adding 4-bit auxiliary bit d0 are added. + D0, divided lower 2 bits Y1; 10-bit [Y1; 0-1] + e0 obtained by adding 8-bit auxiliary bit e0 to 0-1; divided lower 2 bits Y2; 0-1 and Pb1 0-1 and Pr1; 0-1 are multiplexed and 10 bits [Y2BR1; 0-1] + d1, which are obtained by adding 4-bit auxiliary bit d1, 8 divided into lower 2 bits Y3; 0-1 10 bits [Y3; 0-1] + e1 obtained by adding the auxiliary bit e1 of the bits, and the lower two divided bits Y4; 0-1 and Pb2; 0-1 and Pr2; Auxiliary bits of bits 10 bits [Y4BR2; 0-1] + d2 obtained by adding 2 bits, and 10 bits [Y5; 0-1] + e2 obtained by adding 8 auxiliary bits e2 to the divided lower 2 bits Y5; 0-1. , ... are formed. Then, a 10-bit sequence obtained in this way and auxiliary 10-bit words αD0, αD1, αD2, αD3,... Are multiplexed in parallel to form a 20-bit word sequence having a word transmission rate of 74.25 MBps. The data DVRK12A2 or DTRY12A2 is formed as a link A-2 as shown in FIG. 98B.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 ... And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVRK12A3 or DTRY12A3 having a rate of 74.25 MBps is used as a link A-3. It formed as shown in 98 of the C.
Similarly, as shown in FIG. 96, the 12-bit word YD0, YD1, YD2, YD3,. ..., P _B / P _R The 12-bit words PbD0, PrD0, PbD1, PrD1, PbD2, PrD2,... Constituting the data sequence and the 12-bit words AD0, AD1, AD2, AD3,. The same processing as in the case of 36-bit word string data DVR12A + DKR12A or DTR12A + DYR12A is performed on each of. As a result, as shown in FIG. 98A, 20-bit word string data DVRK12B1 or DTRY12B1 having a word transmission rate of 74.25 MBps, or DVRK12C1 or DTRY12C1, is formed as link B-1 or link C-1. 98B, a 20-bit word string data DVRK12B2 or DTRY12B2 having a word transmission rate of 74.25 MBps or a DVRK12C2 or DTRY12C2 is formed as a link B-2 or a link C-2. 98C, 20-bit word string data DVRK12B3 or DTRY12B3 having a word transmission rate of 74.25 MBps, or DVRK12C3 or DTRY12C3, as shown in FIG. , Formed as a link B-3 or the link C-3.
That is, even in such a case, the data DVR12 + DKR12 or DTR12 + DYR12 forming the 36-bit word string data having the word transmission rate of 222.75 MBps, and the 20-bit word string data DVRK12A1 and DVRK12A2 each having the word transmission rate of 74.25 MBps. , DVRK12B1, DVRK12B2, DVRK12B3, DVRK12C1, DVRK12C2, and DVRK12C3, or DTRY12A1, DTRY12A2, DTRY12A3, DTRY12B1 and DTRY12C3 of the DTRY12C3, which are the DTRY12C3 and DTRY12C3 of the DTRY12C3, which are the DTRY12C3 and the DTRY12C3, which are the DTRY12C3 and the DTRY12C3 of the DTRY12C3 which are the DTRY12C3.
When the digital data DVX is the data DVR14 + DKR14 or DVR16 + DKR16, the data processing unit 421 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080 lines, and the number of effective data samples in each line is 1920 samples. And a Y data sequence having a quantization bit number of 14 bits or 16 bits and a word transmission rate of 222.75 MBps, respectively, and P _B / P _R A key signal data sequence (DKR14 or DKR16) having a data sequence (DVR14 or DVR16) and a data format equivalent to the Y data sequence, with a quantization bit number of 14 or 16 bits and a word transmission rate of 222.75 MBps. Is input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
When the digital data DVX is the data DTR14 + DYR14 or DTR16 + DYR16, the data processing unit 421 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, 720 effective lines in each frame, and 720 effective data samples in each line. A Y data sequence and a Y data sequence each forming a digital video signal of 4: 2: 2 format set to 1280 samples, each having a quantization bit number of 14 bits or 16 bits and a word transmission rate of 222.75 MBps. _B / P _R A key signal data sequence (DYR14 or DYR16) having a data sequence (DTR14 or DTR16) and a data format equivalent to that of the Y data sequence, a quantization bit number of 14 or 16 bits, and a word transmission rate of 222.75 MBps. Is input. The Key signal data sequence is a Y data sequence and P _B / P _R It forms an additional data sequence accompanying the data sequence.
Then, the data DVR14 + DKR14 or DVR16 + DKR16, or the Y data series constituting DTR14 + DYR14 or DTR16 + DYR16, P _B / P _R The data sequence and the Key signal data sequence are obtained by performing parallel multiplexing under the condition of frame synchronization and line synchronization, and are obtained as data processing unit 421 as 42-bit parallel data or 48-bit parallel data having a word transmission rate of 222.75 MBps. Supplied to
In such a case, the data processing unit 421 performs the same processing on the data DVR14 + DKR14 or DVR16 + DKR16, or on the DTR14 + DYR14 or DTR16 + DYR16 as in the case of the data DVR12 + DKR12. Where Y data series, P _B / P _R Instead of dividing each of the 12-bit words constituting the data sequence and the Key signal data sequence into upper 10 bits and lower 2 bits, a Y data sequence, P data _B / P _R The operation of dividing each of the 14-bit words constituting the data sequence and the Key signal data sequence into upper 10 bits and lower 4 bits, or Y data sequence, P data _B / P _R An operation of dividing each of the 16-bit words constituting the data sequence and the Key signal data sequence into upper 10 bits and lower 6 bits is performed.
Then, data DVR14 + DKR14 or DVR16 + DKR16 forming 42-bit word string data or 48-bit word string data with a word transmission rate of 222.75 MBps, or DTR14 + DYR14 or DTR16 + DYR16, each having a word transmission rate of 74.25 MBps, are 20 bits. The word string data DVRK14A1 or DVRK16A1, DVRK14A2 or DVRK16A2, DVRK14A3 or DVRK16A3, DVRK14B1 or DVRK16B1, DVRK14B2 or DVRK16B2, DVRK14B3, DVRK14K3, DVK16R3, DVRK16B3, DVRK16B3, DVRK14K3, DVRK14K3, DVRK16K3, DVRK16K3, DVRK16K3, DVRK14K3, DVRK16B3 C3 or DVRK16C3, or DTRY14A1 or DTRY16A1, DTRY14A2 or DTRY16A2, DTRY14A3 or DTRY16A3, DTRY14B1 or DTRY16B1, DTRY14B2 or DTRY16B2, DTRY14C3 or DTRY16C3 Convert to
When the digital data DVX is data indicated as data DVS12 + DKS12, the data processing unit 421 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 1080, and the number of effective data samples in each line is A G data sequence, a B data sequence, and R data each forming a 4: 4: 4 format digital video signal set to 1920 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 12 bits. A sequence (DVS12) and a Key signal data sequence (DKS12) having a data format equivalent to that of the G data sequence, a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps are input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
When the digital data DVX is data represented as data DTS12 + DYS12, the data processing unit 421 sets the frame rate to 72 Hz, 75 Hz or 90 Hz, the number of effective lines in each frame is 720, and the effective data sample in each line is 720. A G data sequence, a B data sequence, and a digital video signal in a 4: 4: 4 format with the number set to 1280 samples, each having a word transmission rate of 222.75 MBps and a quantization bit number of 12 bits. An R data sequence (DTS12) and a Key signal data sequence (DYS12) having a data format equivalent to that of the G data sequence and having a quantization bit number of 12 bits and a word transmission rate of 222.75 MBps are input. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence.
The G data sequence, B data sequence, R data sequence, and Key signal data sequence constituting these data DVS12 + DKS12 or DTS12 + DYS12 are parallel-multiplexed under frame synchronization and line synchronization as shown in FIG. The resultant data is supplied to the data processing unit 421 as 48-bit parallel data having a word transmission rate of 222.75 MBps.
The data processing unit 421 performs the following processing on the data DVS12 + DKS12 or DTS12 + DYS12 supplied as shown in FIG.
First, as shown in FIG. 99, the first two frame portions Frame 1 and Frame 4 of the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVS12 + DKS12 or DTS12 + DYS12. , Frame 7,..., A second alternate frame portion Frame 2, Frame 5, Frame 8,..., And a third alternate frame portion Frame 3, Frame 6 , Frame 9,... Are stored in the memory A, the memory B, and the memory C, respectively.
Next, each of the frame parts Frame 1, Frame 4, Frame 7,... Stored in the memory A is read out by the field interlace method, and the frame rate is set to 72 Hz / 3 = 24 Hz, 75 Hz / 3 = 25 Hz. Alternatively, a G data sequence and a B data which form a segmented frame digital video signal having a series of segmented frame portions, Segmented Frame 1, Segmented Frame 4, Segmented Frame 7,... With 90 Hz / 3 = 30 Hz. 48-bit parallel data including a sequence and an R data system and a Key signal data sequence, thereby forming a 48-bit word string data DV having a word transmission rate of 222.75 MBps / 3 = 74.25 MBps. Obtaining 12A + DKS12A or DTS12A + DYS12A.
Also, each of the frame parts Frame 2, Frame 5, Frame 8,... Stored in the memory B is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A G data sequence, a B data sequence, an R data system, and a Key signal data sequence that constitute a segmented frame digital video signal having a segmented frame portion 2, a segmented frame 5, a segmented frame 8,... 48-bit parallel data including DVS12B + DKS12B or DTS12B + DYS12B having a word transmission rate of 74.25 MBps.
Further, each of the frame portions Frame 3, Frame 6, Frame 9,... Stored in the memory C is read out by the field interlace method, and a series of segments in which the frame rate is set to 24 Hz, 25 Hz or 30 Hz. A G frame, a B frame, an R frame, and a Key signal data sequence forming a segmented frame digital video signal having a segmented frame portion 3, a Segmented Frame 6, a Segmented Frame 9,... 48-bit parallel data including DVS12C + DKS12C or DTS12C + DYS12C having a word transmission rate of 74.25 MBps. .
48-bit word string data DVS12A + DKS12A, DVS12B + DKS12B and DVS12C + DKS12C, or DTS12A + DYS12A, DTS12B + DYS12B and DTS12C + DYS12C, respectively, constitute G data series as shown in FIG. .., 12-bit words BD0, BD1, BD2, BD3,... Forming a B data sequence, 12-bit words RD0, RD1, RD2, RD3,. , Constituting a Key signal data sequence, are formed as a link A, a link B or a link C by parallel multiplexing of 12-bit words AD0, AD1, AD2, AD3,.
Subsequently, as shown in FIG. 100, a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series in the 48-bit word string data DVS12A + DKS12A or DTS12A + DYS12A is constructed. , 12-bit words RD0, RD1, RD2, RD3,... Constituting a R data sequence and 12 constituting a Key signal data sequence Each of the bit words AD0, AD1, AD2, AD3,... Is represented by the upper 10 bits G0; 2-11, G1; 2-11, G2; 2-11, G3; 2-11,. ..., B0; 2-11, B1; 2-11, B2; 2-11, B3; 2-11, ..., R0; 2-11, R1; ..., 11, R2; 2-11, R3; 2-11, ..., and A0; 2-11, A1; 2-11, A2; 2-11, A3; And the lower 2 bits G0; 0-1, G1; 0-1, G2; 0-1, G3; 0-1,..., B0; 0-1, B1; 0-1, B2; .., R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1,..., And A0; 0-1, A1; 0-1, A2; 0-1, A3; 0-1,.
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVSK12A1 or DTSY12A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link A-1 as shown in FIG. 101A. I do. Also, 20-bit word string data DVSK12A2 or DTSY12A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is formed as a link A-2 as shown in FIG. 101B. I do.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 ... And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11,. : [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,... 20-bit word string data DVSK12A3 or DTSY12A3 having a transmission rate of 74.25 MBps as link A-3 It formed as shown in C of FIG. 101.
Similarly, as shown in FIG. 100, for each of 48-bit word string data DVS12B + DKS12B or DTS12B + DYS12B and DVS12C + DKS12C or DTS12C + DYS12C, 12-bit words GD0, GD1, GD2, GD3,. .., 12-bit words BD0, BD1, BD2, BD3,... Constituting the B data sequence, 12-bit words RD0, RD1, RD2, RD3,. , And 12-bit words AD0, AD1, AD2, AD3,... Constituting the Key signal data series are subjected to the same processing as the case of 48-bit word string data DVS12A + DKS12A or DTS12A + DYS12A. . As a result, as shown in FIG. 101A, 20-bit word string data DVSK12B1 or DTSY12B1 having a word transmission rate of 74.25 MBps, or DVSK12C1 or DTSY12C1 is formed as link B-1 or link C-1. As shown in FIG. 101B, 20-bit word string data DVSK12B2 or DTSY12B2 having a word transmission rate of 74.25 MBps, or DVSK12C2 or DTSY12C2 is formed as a link B-2 or a link C-2. 101C, 20-bit word string data DVSK12B3 or DTSY12B3 having a word transmission rate of 74.25 MBps, or DVSK12C3 or DTSY1. The C3, formed as a link B-3 or Link C3.
That is, in the data processing unit 421, the data DVS12 + DKS12 or DTS12 + DYS12 forming the 48-bit word string data having the word transmission rate of 222.75 MBps, and the 20-bit word string data having the word transmission rate of 74.25 MBps, respectively. DVSK12A1, DVSK12A2, DVSK12B3, DVSK12B2, DVSK12B3, DVSK12C1, DVSK12C2, DVSK12C2 and DVSK12C3, or DTSY12A1, DTSY12A2, DTSY12B3, DTSY12B1, DTSY12B1
The data processing unit 421 includes a set of 20-bit word string data DVRK12A1, DVRK12A2, DVRK12A3, DVRK12B1, DVRK12B2, DVRK12B3, DVRK12C1, DVRK12C2, DVRK12C2, and DVRK12C1, DVRK14A14, and DRK14A14, which are nine-system word string data. DVRK14B1, DVRK14B2, DVRK14B3, DVRK14C1, a set of DVRK14C2 and DVRK14C3, 20-bit word string data DVRK16A1, DVRK16A2, DVRK16A3, DVRK16B1, DVRK16B1, DVRK16B1, DVRK16B3, DVK16B1 DVSK12A2, DVSK12A3, DVSK12B1, DVSK12B2, DVSK12B3, DVSK12C1, DVSK12C2 and DVSK12C3, a set of 20-bit word string data DTRY12A1, DTRY12A1, DTRY12C3, DTRY12C3, DTRY12C3 DTRY14A2, DTRY14A3, DTRY14B1, DTRY14B2, DTRY14B3, DTRY14C1, DTRY14C2, and a set of DTRY14C3, 20-bit word string data DTRY16A1, DTRY16A2, DTRY16A3, DTRY16B1, DTRY16B2, DTRY16B3 A set of DTRY16C1, DTRY16C2, and DTRY16C3, and a set of 20-bit word string data DTSY12A1, DTSY12A2, DTSY12A3, DTSY12B1, DTSY12B2, DTYK12B3, DTSY12C1, DTSY12C2, and DTSY12C3, and a 20-bit word string DP1 (20 bits) ).
The 20-bit word string data DP1 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 421 is supplied to the data insertion unit 422. The data insertion unit 422 inserts auxiliary data DA1 including channel identification data as needed into the 20-bit word string data DP1 (20), and the 20-bit word string data DP1 ′ into which the auxiliary data DA1 has been inserted. (20) is formed. The 20-bit word string data DP1 ′ (20) obtained from the data insertion unit 422 is supplied to the P / S conversion unit 423.
The P / S conversion unit 423 performs P / S conversion on the 20-bit word string data DP1 ′ (20) to increase the bit transmission rate based on the 20-bit word string data DP1 ′ (20) to 74.25 Mbps. The serial data DS1 with 20 = 1.485 Gbps is formed, and the serial data DS1 is supplied to the E / O converter 424.
The E / O conversion unit 424 performs electro-optical conversion processing on the serial data DS1 to convert the optical signal OS1 based on the serial data DS1 to have a center wavelength of, for example, approximately 1.3 μm and a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
The 20-bit word string data DP2 (20) to DP9 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 421 are supplied to the data insertion units 425 to 432, respectively. In the data insertion units 425 to 432, auxiliary data DA2 to DA9 including necessary channel identification data are inserted into the 20-bit word string data DP2 (20) to DP9 (20), and the auxiliary data is inserted. 20-bit word string data DP2 '(20) to DP9' (20). The 20-bit word string data DP2 ′ (20) to DP9 ′ (20) obtained from the data insertion units 425 to 432 are supplied to P / S conversion units 436 to 443, respectively.
The P / S converters 436 to 443 perform P / S conversion on the 20-bit word string data DP2 ′ (20) to DP9 ′ (20), and set the bit transmission rate based on them to 74.25 MBps × 20. Then, serial data DS2 to DS9 with 1.485 Gbps are formed and supplied to the E / O converters 447 to 454.
In the E / O conversion units 447 to 454, the serial data DS2 to DS9 are subjected to electro-optical conversion processing, and the optical signals OS2 to OS9 having a center wavelength of, for example, about 1.3 μm are transmitted based on them. The rate is set to 1.485 Gbps, and it is transmitted as a transmission signal.
The optical signal OS1, which is a transmission signal transmitted from the E / O conversion unit 424, is guided to the optical fiber transmission line 461 through the optical connector 460, and is transmitted to the receiving side through the optical fiber transmission line 461. Optical signals OS2 to OS9, which are transmission signals transmitted from the E / O converters 447 to 454, are guided to optical fiber transmission paths 473 to 480 through optical connectors 462 to 469, respectively, and are transmitted through optical fiber transmission paths 473 to 480, respectively. It is transmitted to the receiving side. Each of the optical fiber transmission lines 461 and 473 to 480 is formed using, for example, a quartz-based SMF.
On the receiving side, the optical signal OS1 transmitted through the optical fiber transmission line 461 is guided to the O / E converter 486 through the optical connector 485. The optical signals OS2 to OS9 transmitted through the optical fiber transmission paths 473 to 480 are guided to the O / E converters 496 to 503 through the optical connectors 488 to 495, respectively.
The O / E converter 486 performs a photoelectric conversion process on the optical signal OS1 having a center wavelength of about 1.3 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OS1. The serial data DS1 having 1.485 Gbps is reproduced. Then, the reproduced serial data DS1 is supplied to the S / P converter 487. The S / P converter 487 performs S / P conversion on the serial data DS1 to reproduce 20-bit word string data DP1 ′ (20) based on the serial data DS1 and having a word transmission rate of 74.25 MBps. Then, it is supplied to the data time difference absorption unit 481.
In the O / E converters 496 to 503, the optical signals OS2 to OS9 having a center wavelength of about 1.3 μm and a bit transmission rate of 1.485 Gbps are subjected to photoelectric conversion processing, and The serial data DS2 to DS9 whose bit transmission rate is 1.485 Gbps are reproduced. Then, the reproduced serial data DS2 to DS9 are supplied to S / P converters 504 to 511, respectively. The S / P converters 504 to 511 perform S / P conversion on the serial data DS2 to DS9, and based on them, 20-bit word string data DP2 ′ (20) with a word transmission rate of 74.25 MBps. To DP9 ′ (20) and supplies them to the data time difference absorption unit 481.
In the data time difference absorption unit 481, the 20-bit word string data DP1 '(20) from the S / P conversion unit 487 and the 20-bit word string data DP2' (20) to 20-bit word data from the S / P conversion units 504 to 511. 20-bit word string data having a word transmission rate of 74.25 MBps based on each of the 20-bit word string data DP1 '(20) to DP9' (20), absorbing the mutual time difference generated between DP9 '(20). DP1Q ′ (20) to DP9Q ′ (20) are transmitted as being intended to be maintained in a state where there is substantially no mutual time difference.
The 20-bit word string data DP1Q ′ (20) obtained from the data time difference absorption unit 481 is supplied to the data separation unit 512. In the data separation unit 512, the auxiliary data DA1 is separated from the 20-bit word string data DP1Q ′ (20), and the 20-bit word string data DP1Q (20) and the auxiliary data DA1 are separately transmitted. The bit word string data DP1Q (20) is supplied to the data reproduction processing unit 513.
Also, the 20-bit word string data DP2Q ′ (20) to DP9Q ′ (20) obtained from the data time difference absorption unit 481 are supplied to the data separation units 514 to 521, respectively. In the data separation units 514 to 521, the auxiliary data DA2 to DA9 are separated from the 20-bit word string data DP2Q '(20) to DP9Q' (20), and the 20-bit word string data DP2Q (20) to DP9Q. (20) and the auxiliary data DA2 to DA9 are separately transmitted, and the 20-bit word string data DP2Q (20) to DP9Q (20) are supplied to the data reproduction processing unit 513.
In the data reproduction processing section 513, the data conversion processing performed on the 20-bit word string data DP1Q (20) to DP9Q (20) by the data processing section 421 on the transmission side is performed in reverse to the data conversion processing performed on the digital data DVX. A data reproduction process is performed to reproduce digital data DVX based on the 20-bit word string data DP1Q (20) to DP9Q (20). Such digital data DVX is one of the data DVR12 + DKR12, DVR14 + DKR14, DVR16 + DKR16, DVS12 + DKS12, DTR12 + DYR12, DTR14 + DYR14, DTR16 + DYR16, and DTS12 + DYS12.
In the above description, in the data forming the digital video signal having a quantization bit number of 12 bits or more, the upper 10-bit column divided from each of the 12-bit, 14-bit, and 16-bit words constituting the Y data sequence , P _B / P _R 20-bit word string data DVRK12A1, DVRK12B1, DVRK12C1, DVRK14A1, DVRK14B1, 20-bit word string data DVRK12A1, DVRK12B1, DVRK12C1, DVRK14A1, and DVRK12B1, each of which is formed by parallel multiplexing a 12-bit, 14-bit, or 16-bit word divided from a 12-bit, 14-bit, or 16-bit word that constitutes a data sequence. DVRK14C1, DVRK16A1, DVRK16B1 and DVRK16C1, etc., or DTRY12A1, DTRY12B1, DTRY12C1, DTRY14A1, DTRY14B1, DTRY14C1, DTRY16A1, DTRY16B1 and DTRY16C1, etc. 20-bit word string data formed based on the upper 10-bit string divided from each of the bit words DVSK12A1, DVSK12B1 and DVSK12C1 like, or, DTSY12A1, etc. DTSY12B1 and DTSY12C1 are each of them, for example, those capable of recording and reproduction by the present HD for VTR. Therefore, using the current HD VTR, the 20-bit word string data DVRK12A1, DVRK12B1, DVRK12C1, DVRK14A1, DVRK14B1, DVRK14C1, DVRK16A1, DVRK16B1 and DVRK16C1, DVRK16C1, etc. , DTRY16A1, DTRY16B1 and DTRY16C1, etc., or DVSK12A1, DVSK12B1 and DVSK12C1, etc., or DTSY12A1, DTSY12B1 and DTSY12C1, etc., can be checked and edited. Using a monitor, 20-bit word string data DVR 12A1, DVRK12B1, DVRK12C1, DVRK14A1, DVRK14B1, DVRK14C1, DVRK16A1, DVRK16B1 and DVRK16C1 like, or, DTRY12A1, DTRY12B1, DTRY12C1, DTRY14A1, DTRY14B1, DTRY14C1, DTRY16A1, DTRY16B1 and DTRY16C1 like, or, DVSK12A1, DVSK12B1 and DVSK12C1 like, or , DTSY12A1, DTSY12B1 and DTSY12C1 can be obtained, so that, when handling data forming a digital video signal having a quantization bit number of 12 bits or more, a confirmation operation using an existing device, etc. Can be done very conveniently The good
FIG. 102 shows a data transmission apparatus according to the present invention, in which an example of any one of the 31st, 32nd, 40th, and 41st aspects of the data transmission method according to the present invention is implemented. 41 shows a portion of a data transmission / reception device including a second example of any one of the fortieth and forty-first aspects.
The data transmission / reception device whose part is shown in FIG. 102 has many parts configured similarly to the data transmission / reception device shown in FIG. 93 and FIG. 94, and FIG. Only the parts different from the data transmitting / receiving device and the parts related thereto are shown.
In the data transmission / reception device whose part is shown in FIG. 102, E / O conversion units 424 and 447 to 454 and O / E conversion units 486 and 496 provided in the data transmission / reception device shown in FIGS. 503C, E / O converters 424C and 447C to 454C, and O / E converters 486C and 496C to 503C. Further, instead of the optical connectors 460 and 462 to 469, the optical fiber transmission lines 461 and 473 to 480, and the optical connectors 485 and 488 to 495 provided in the data transmitting / receiving apparatus shown in FIGS. A section 525, an optical connector 526, an optical fiber transmission line 527, an optical connector 528, and a branching section 529 are provided. The optical fiber transmission line 527 is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 102, serial data DS1 to DS9 whose bit transmission rates from P / S converters 423 and 436 to 443 are 1.485 Gbps are respectively converted into E / O converters. 424C and 447C-454C.
The E / O converters 424C and 447C to 454C sequentially separate the center wavelengths from, for example, approximately 1.451 μm to approximately 1.611 μm by approximately 0.020 μm (20 nm) based on the serial data DS1 to DS9, respectively. The optical signals OS1 to OS9 are respectively formed so as to have a bit transmission rate of 1.485 Gbps, and are supplied to the multiplexing unit 525.
In the multiplexing unit 525, optical signals OS1 to OS9 whose center wavelengths are sequentially separated from each other by approximately 0.020 μm from approximately 1.451 μm to approximately 1.611 μm are multiplexed and multiplexed, and the multiplexed optical signal OCZ is obtained. And sends it out as a transmission signal. Under these circumstances, the E / O conversion units 424C and 447C to 454C and the multiplexing unit 525 transmit data to transmit the serial data DS1 to DS9 obtained from the P / S conversion units 423 and 436 to 443, respectively. A sending section is formed.
In this way, the optical signals OS1 to OS9 multiplexed in the multiplexing unit 525 are multiplexed under the condition that their center wavelengths are only approximately 0.020 μm apart and have wavelengths extremely close to each other. To form a multiplexed optical signal OCZ. In a portion including the E / O converters 424C and 447C to 454C and the multiplexing unit 525, a wavelength multiplexing technique called CWMD is used. .
The multiplexed optical signal OCZ, which is a transmission signal transmitted from the multiplexing unit 525, is guided to the optical fiber transmission line 527 through the optical connector 526, and is transmitted to the receiving side through the optical fiber transmission line 527.
On the receiving side, the multiplexed optical signal OCZ transmitted through the optical fiber transmission line 527 is guided to the demultiplexer 529 through the optical connector 528. In the demultiplexing unit 529, the multiplexed optical signal OCZ is demultiplexed into nine components whose center wavelength is sequentially separated by approximately 0.020 μm from approximately 1.451 μm to approximately 1.611 μm. Reproduces the optical signals OS1 to OS9 whose bit transmission rate is 1.485 Gbps and whose center wavelength is sequentially separated by approximately 0.020 μm from approximately 1.451 μm to approximately 1.611 μm.
The optical signals OS1 to OS9 reproduced by the demultiplexer 529 are guided to O / E converters 486C and 496C to 503C, respectively. The O / E converters 486C and 496C to 503C perform a photoelectric conversion process on each of the optical signals OS1 to OS9 whose center wavelengths are sequentially separated by approximately 0.020 μm from approximately 1.451 μm to approximately 1.611 μm. , And reproduces serial data DS1 to DS9 each having a bit transmission rate of 1.485 Gbps based on the optical signals OS1 to OS9. Then, the serial data DS1 to DS9 reproduced by the O / E converters 486C and 496C to 503C are supplied to the S / P converters 487 and 504 to 511, respectively.
Other operations are the same as those of the data transmitting / receiving apparatus shown in FIGS. 93 and 94.
FIG. 103 and FIG. 104 show data transmission / reception including the first example which constitutes the 33rd aspect of the data transmission apparatus according to the present invention, in which the example which constitutes the 33rd aspect of the data transmission method according to the present invention is implemented. 2 shows a part of the device.
In the data transmission / reception device shown in FIGS. 103 and 104, digital data DVX forming a digital video signal is supplied to a data processing unit 557 on the transmission side forming an example of the data transmission device according to the present invention.
The digital data DVX is data DVV12 + DKV12. The data processing unit 557 provides a digital video signal of 4: 4: 4 format in which the frame rate is set to 120 Hz, the number of effective lines in each frame is set to 1080, and the number of effective data samples in each line is set to 1920. Each has a G data sequence, a B data sequence, and an R data sequence (DVV12) with a quantization bit number of 12 bits and a word transmission rate of 297 MBps, and a data format equivalent to the G data sequence. And a Key signal data sequence (DKV12) having a word transmission rate of 297 MBps with the number of coded bits being 12 bits. The Key signal data sequence forms an additional data sequence attached to the G data sequence, B data sequence, and R data sequence. These G data sequence, B data sequence, R data sequence, and Key signal data sequence are obtained by parallel multiplexing under frame synchronization and line synchronization as shown in FIGS. 105 and 106. The data is supplied to the data processing unit 557 as 48-bit parallel data having a word transmission rate of 297 MBps.
The data processing unit 557 performs the following processing on the data DVV12 + DKV12 supplied as shown in FIGS.
First, as shown in FIG. 105 and FIG. 106, the first three frame portions Frame 1 and Frame 5 among the frame portions Frame 1, Frame 2, Frame 3,... Forming the data DVV12 + DKV12. , Frame 9,..., Second every third frame portion Frame 2, Frame 6, Frame 10,..., Third every third frame portion Frame 3, Frame 7, Frame ,... And the fourth every third frame part Frame 4, Frame 8, Frame 12,... Are stored in the memory A, the memory B, the memory C, and the memory D, respectively. I do.
Next, each of the frame portions Frame 1, Frame 5, Frame 9,... Stored in the memory A is read out by the field interlace method, and a series of segments in which the frame rate is set to 120 Hz / 4 = 30 Hz. The G data sequence, the B data sequence, the R data system, and the Key signal data sequence that constitute a segmented frame digital video signal having a segmented frame portion 1, a segmented frame 5, a segmented frame 9,... 48-bit parallel data including the word transmission rate 297 MBps / 4 = 74.25 MBps to obtain 48-bit word string data DVV12A + DKV12A.
Each of the frame portions Frame 2, Frame 6, Frame 10,... Stored in the memory B is read out by the field interlace method, and a series of segmented frame portions Segmented Frame 2 having a frame rate of 30 Hz is set. , Segmented Frame 6, Segmented Frame 10,..., And 48-bit parallel data including a G data sequence, a B data sequence, an R data system, and a Key signal data sequence that constitute a segmented frame digital video signal. Thus, 48-bit word string data DVV12B + DKV12B having a word transmission rate of 74.25 MBps is obtained.
Each of the frame parts Frame 3, Frame 7, Frame 11,... Stored in the memory C is read out by the field interlace method, and a series of segmented frame parts Segmented Frame 3 in which the frame rate is set to 30 Hz. , Segmented Frame 7, Segmented Frame 11,..., And 48-bit parallel data including a G data sequence, a B data sequence, an R data system, and a Key signal data sequence forming a segmented frame digital video signal. Thus, 48-bit word string data DVV12C + DKV12C having a word transmission rate of 74.25 MBps is obtained.
Further, each of the frame portions Frame 4, Frame 8, Frame 12,... Stored in the memory D is read out by the field interlace method, and a series of segmented frame portions Segmented in which the frame rate is set to 30 Hz. 48-bit parallel including a G data sequence, a B data sequence, an R data system, and a Key signal data sequence constituting a segmented frame digital video signal having Frame 4, Segmented Frame 8, Segmented Frame 12,... Data is to be formed, thereby obtaining 48-bit word string data DVV12D + DKV12D having a word transmission rate of 74.25 MBps.
Each of the 48-bit word string data DVV12A + DKV12A, DVV12B + DKV12B, DVV12C + DKV12C and DVV12D + DKV12D is a 12-bit word GD0, GD1, GD2, GD3,..., B data series constituting a G data series as shown in FIG. , And the 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence, and the Key signal data sequence The constituent 12-bit words AD0, AD1, AD2, AD3,... Are multiplexed in parallel and formed as link A, link B, link C or link D.
Then, as shown in FIG. 107, in the 48-bit word string data DVV12A + DKV12A, 12-bit words GD0, GD1, GD2, GD3,... Constituting the G data series, and 12 bits constituting the B data series Words BD0, BD1, BD2, BD3,..., 12-bit words RD0, RD1, RD2, RD3,... Constituting the R data sequence, and 12-bit words constituting the Key signal data sequence Each of AD0, AD1, AD2, AD3,... Is represented by upper 10 bits G0; 2-11, G1; 2-11, G2; 2-11, G3; 2-11,. B0; 2-11, B1; 2-11, B2; 2-11, B3; 2-11, ..., R0; 2-11, R1; 2-11, R2; 2-11, R3; 2 , And A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11,..., And the lower two bits G0; G1, 0-1, G2; 0-1, G3; 0-1, ..., B0; 0-1, B1; 0-1, B2; 0-1, B3; 0-1, ... ..., R0; 0-1, R1; 0-1, R2; 0-1, R3; 0-1, ..., and A0; 0-1, A1; 0-1, A2; 0-1, A3; 0-1,...
Next, the lower two 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; , G0; 0-1 and B0; 0-1 and R0; 0-1 are multiplexed, and 10 bits [GBR0; 0-1] + f0, obtained by adding 4 auxiliary bits f0, G1; 0-1 and B1; 0-1 and R1; 0-1 are bit-multiplexed, and 10-bit [GBR1; 0-1] + f1, G2; 0- obtained by adding 4 auxiliary bits f1. 1 and B2; 0-1 and R2; 0-1 are bit-multiplexed, and a 10-bit [GBR] obtained by adding a 4-bit auxiliary bit f2. 0-1] + f2, G3; 0-1 and B3; 0-1 and R3; 0-1 and 10-bit [GBR3; 0-1] obtained by adding 4-bit auxiliary bit f3 + F3,...
Subsequently, as shown in FIG. 28, a sequence of the divided upper 10 bits: 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; R3; 2-11,..., And a 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 the upper 10 bits divided: B0; 2-11, B2; ., And R0; 2-11, R2; 2-11, R4; 2-11,... .. And R1; 2-11, R3; 2-11, R5; 2-11,... And R1; 2-11, B3; 2-11, B5; , 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.
Then, 20-bit word string data DVVK12A1 having a word transmission rate of 74.25 MBps based on the 10-bit word group 1 shown in FIG. 28 is formed as a link A-1, as shown in FIG. 108A. Also, 20-bit word string data DVVK12A2 having a word transmission rate of 74.25 MBps based on the 10-bit word group 2 shown in FIG. 28 is formed as a link A-2 as shown in FIG. 108B.
Further, 8-bit auxiliary bits e0, e1, e2, are added to the divided lower two bits A0; 0-1, A1; 0-1, A2; 0-1, A3; .. are added to each other to add 10 bits [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3 ... And the upper 10-bit sequence divided: A0; 2-11, A1; 2-11, A2; 2-11, A3; 2-11,. Column: [A0; 0-1] + e0, [A1; 0-1] + e1, [A2; 0-1] + e2, [A3; 0-1] + e3,. FIG. 108C shows 20-bit word string data DVVK12A3 having a word transmission rate of 74.25 MBps as link A-3. Form to as that.
Similarly, as shown in FIG. 107, for each of the 48-bit word string data DVV12B + DKV12B, DVV12C + DKV12C and DVV12D + DKV12D, the 12-bit words GD0, GD1, GD2, GD3,. , 12-bit words BD0, BD1, BD2, BD3,... Constituting the B data series, 12-bit words RD0, RD1, RD2, RD3,. The same processing as in the case of the 48-bit word string data DVV12A + DKV12A is performed on each of the 12-bit words AD0, AD1, AD2, AD3,... As a result, as shown in FIG. 108A, 20-bit word string data DVVK12B1, DVVK12C1, or DVVK12D1 having a word transmission rate of 74.25 MBps is formed as link B-1, link C-1, or link D-1. Then, as shown in FIG. 108B, 20-bit word string data DVVK12B2, DVVK12C2 or DVVK12D2 having a word transmission rate of 74.25 MBps is formed as link B-2, C-2 or link D-2. Further, as shown in FIG. 108C, 20-bit word string data DVVK12B3, DVVK12C3 or DVVK12D3 having a word transmission rate of 74.25 MBps is formed as link B-3, C-3 or link D-3.
That is, in the data processing unit 557, the data DVV12 + DKV12 forming the 48-bit word string data having the word transmission rate of 297 MBps and the 20-bit word string data DVVK12A1, DVVK12A2 each having the word transmission rate of 74.25 MBps. The data is converted into 12-system word string data of DVVK12A3, DVVK12B1, DVVK12B2, DVVK12B3, DVVK12C1, DVVK12C2, DVVK12C3, DVVK12D1, DVVK12D2 and DVVK12D3.
The data processing unit 557 includes 20-bit word string data DVVK12A1, DVVK12A2, DVVK12A3, DVVK12B1, DVVK12B2, DVVK12B3, DVVK12C1, DVVK12C2, DVVK12C3, DVVK12D1, DVVK12D3, and DVVK12D3, which are 12-system word string data. (20) to DP12 (20).
The 20-bit word string data DP1 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 557 is supplied to the data insertion unit 558. The data insertion unit 558 inserts auxiliary data DA1 including channel identification data as needed into the 20-bit word string data DP1 (20), and inserts the 20-bit word string data DP1 ′ into which the auxiliary data DA1 has been inserted. (20) is formed. The 20-bit word string data DP1 ′ (20) obtained from the data insertion unit 558 is supplied to the P / S conversion unit 559.
The P / S conversion section 559 performs P / S conversion on the 20-bit word string data DP1 '(20) to increase the bit transmission rate based on the 20-bit word string data DP1' (20) to 74.25 Mbps. The serial data DS1 with 20 = 1.485 Gbps is formed, and the serial data DS1 is supplied to the E / O converter 560.
The E / O conversion unit 560 performs electro-optical conversion processing on the serial data DS1 to convert the optical signal OS1 based on the serial data DS1 to have a center wavelength of, for example, approximately 1.3 μm and a bit transmission rate of 1.485 Gbps. And transmit it as a transmission signal.
The 20-bit word string data DP2 (20) to DP12 (20) having a word transmission rate of 74.25 MBps sent from the data processing unit 557 are supplied to the data insertion units 561 to 571, respectively. In the data insertion units 561 to 571, auxiliary data DA2 to DA12 including channel identification data as necessary are inserted into the 20-bit word string data DP2 (20) to DP12 (20), and the auxiliary data is inserted. 20-bit word string data DP2 '(20) to DP12' (20). The 20-bit word string data DP2 ′ (20) to DP12 ′ (20) obtained from the data insertion units 561 to 571 are supplied to P / S conversion units 572 to 582, respectively.
The P / S converters 572 to 582 perform P / S conversion on the 20-bit word string data DP2 ′ (20) to DP12 ′ (20), and set the bit transmission rate based on them to 74.25 MBps × 20. Then, the serial data DS2 to DS12 having 1.485 Gbps are formed and supplied to the E / O converters 583 to 593.
In the E / O converters 583 to 593, the serial data DS2 to DS12 are subjected to electro-optical conversion processing, and based on them, optical signals OS2 to OS12 having a center wavelength of, for example, about 1.3 μm are transmitted by bits. The rate is set to 1.485 Gbps, and it is transmitted as a transmission signal.
The optical signal OS1, which is a transmission signal transmitted from the E / O converter 560, is guided to the optical fiber transmission line 595 through the optical connector 594, and is transmitted to the receiving side through the optical fiber transmission line 595. Optical signals OS2 to OS12, which are transmission signals transmitted from the E / O converters 583 to 593, are guided to optical fiber transmission lines 607 to 617 through optical connectors 596 to 606, respectively, and are transmitted through optical fiber transmission lines 607 to 617. It is transmitted to the receiving side. Each of the optical fiber transmission paths 595 and 607 to 617 is formed using, for example, a quartz SMF.
On the receiving side, the optical signal OS1 transmitted through the optical fiber transmission line 595 is guided to the O / E converter 619 through the optical connector 618. The optical signals OS2 to OS12 transmitted through the optical fiber transmission lines 607 to 617 are guided to the O / E converters 631 to 641 through the optical connectors 620 to 630, respectively.
The O / E conversion unit 619 performs photoelectric conversion processing on the optical signal OS1 having a center wavelength of approximately 1.3 μm and a bit transmission rate of 1.485 Gbps, and adjusts the bit transmission rate based on the optical signal OS1. The serial data DS1 having 1.485 Gbps is reproduced. Then, the reproduced serial data DS1 is supplied to the S / P converter 642. The S / P converter 642 performs S / P conversion on the serial data DS1 to reproduce 20-bit word string data DP1 ′ (20) based on the serial data DS1 and having a word transmission rate of 74.25 MBps. Then, it is supplied to the data time difference absorption unit 643.
In the O / E converters 631 to 641, the optical signals OS2 to OS12 having a center wavelength of about 1.3 μm and a bit transmission rate of 1.485 Gbps are subjected to photoelectric conversion processing, and The serial data DS2 to DS12 whose bit transmission rate is 1.485 Gbps are reproduced. Then, the reproduced serial data DS2 to DS12 are supplied to S / P converters 644 to 654, respectively. The S / P converters 644 to 654 perform S / P conversion on the serial data DS2 to DS12 and, based on them, 20-bit word string data DP2 ′ (20) with a word transmission rate of 74.25 MBps. To DP12 ′ (20), and supplies them to the data time difference absorption unit 643.
In the data time difference absorbing section 643, the 20-bit word string data DP1 '(20) from the S / P conversion section 642 and the 20-bit word string data DP2' (20)-from the S / P conversion sections 644 to 654. 20-bit word string data having a word transmission rate of 74.25 MBps based on each of the 20-bit word string data DP1 '(20) to DP12' (20) by absorbing a mutual time difference generated between DP12 '(20). DP1Q ′ (20) to DP12Q ′ (20) are transmitted as being intended to be maintained in a state where there is substantially no mutual time difference.
The 20-bit word string data DP1Q ′ (20) obtained from the data time difference absorption unit 643 is supplied to the data separation unit 655. In the data separation unit 655, the auxiliary data DA1 is separated from the 20-bit word string data DP1Q '(20), and the 20-bit word string data DP1Q (20) and the auxiliary data DA1 are separately transmitted. The bit word string data DP1Q (20) is supplied to the data reproduction processing unit 656.
Also, the 20-bit word string data DP2Q ′ (20) to DP12Q ′ (20) obtained from the data time difference absorption unit 643 are supplied to the data separation units 657 to 667, respectively. In the data separation units 657 to 667, the auxiliary data DA2 to DA12 are separated from the 20-bit word string data DP2Q '(20) to DP12Q' (20), and the 20-bit word string data DP2Q (20) to DP12Q. (20) and the auxiliary data DA2 to DA12 are separately transmitted, and the 20-bit word string data DP2Q (20) to DP12Q (20) are supplied to the data reproduction processing unit 656.
In the data reproduction processing unit 656, the data conversion processing performed on the 20-bit word string data DP1Q (20) to DP12Q (20) by the data processing unit 557 on the transmission side on the digital data DVX is reversed. A data reproduction process is performed to reproduce digital data DVX based on the 20-bit word string data DP1Q (20) to DP12Q (20). The digital data DVX is DVV12 + DKV12.
In the above description, in data forming a digital video signal having a quantization bit number of 12 bits or more, the upper 10 bits divided from each of the 12-bit words constituting each of the G data sequence, the B data sequence, and the R data sequence. Each of the 20-bit word string data DVVK12A1, DVVK12B1, DVVK12C1 and DVVK12D1 formed based on the bit string is capable of performing recording and reproduction by, for example, a current HD VTR. Therefore, the contents of the 20-bit word string data DVVK12A1, DVVK12B1, DVVK12C1, and DVVK12D1 can be checked and edited using the current HD VTR. Using the monitor, a reproduced image based on the 20-bit word string data DVVK12A1, DVVK12B1, DVVK12C1, and DVVK12D1 can be obtained, thereby handling data forming a digital video signal having a quantization bit number of 12 bits or more. In doing so, it is possible to perform confirmation work and the like using current equipment, which is extremely convenient
FIG. 109 is a diagram showing a part of the data transmitting / receiving apparatus including the second example forming the 33rd aspect of the data transmission apparatus according to the present invention, in which the example forming the 33rd aspect of the data transmitting method according to the present invention is implemented. Is shown.
The data transmission / reception device whose part is shown in FIG. 109 has many parts configured similarly to the data transmission / reception device shown in FIGS. 103 and 104, and FIG. 109 shows the data transmission / reception device shown in FIGS. 103 and 104. Only the parts different from the data transmitting / receiving device and the parts related thereto are shown.
In the data transmission / reception device shown in FIG. 109, the E / O conversion units 560 and 583 to 593 and the O / E conversion units 619 and 631 provided in the data transmission / reception device shown in FIGS. And E / O converters 560C and 583C to 593C, and O / E converters 619C and 631C to 641C in place of ６４641. Further, instead of the optical connectors 594 and 596 to 606, the optical fiber transmission lines 595 and 607 to 617, and the optical connectors 618 and 620 to 630 provided in the data transmitting and receiving apparatus shown in FIGS. 670 and 673, optical connectors 671 and 674, optical fiber transmission lines 672 and 675, optical connectors 676 and 678, and demultiplexers 677 and 679. Each of the optical fiber transmission lines 672 and 675 is formed using, for example, a quartz-based SMF.
In the data transmission / reception device whose part is shown in FIG. 109, serial data DS1 to DS12 whose bit transmission rates from P / S converters 559 and 572 to 582 are 1.485 Gbps are respectively converted into E / O converters. 560C and 583C-593C.
The E / O converters 560C and 583C to 587C sequentially separate the center wavelengths from, for example, about 1.511 μm to about 1.611 μm by about 0.020 μm (20 nm) based on the serial data DS1 to DS6, respectively. The optical signals OS1 to OS6 are formed so that each has a bit transmission rate of 1.485 Gbps, and are supplied to the multiplexing unit 670.
The E / O converters 588C to 593C sequentially separate the center wavelengths based on the serial data DS7 to DS12 from, for example, approximately 1.511 μm to approximately 1.611 μm by approximately 0.020 μm (20 nm). The optical signals OS7 to OS12 are respectively formed so as to have a bit transmission rate of 1.485 Gbps, and are supplied to the multiplexer 673.
The multiplexing unit 670 multiplexes and multiplexes the optical signals OS1 to OS6 whose center wavelengths are sequentially separated by about 0.020 μm from about 1.511 μm to about 1.611 μm to form a multiplexed optical signal OCZA. And sends it out as a transmission signal. Under these circumstances, the E / O conversion units 560C and 583C to 587C and the multiplexing unit 670 transmit data to transmit the serial data DS1 to DS6 obtained from the P / S conversion units 559 and 572 to 576, respectively. A sending section is formed.
The multiplexing unit 673 multiplexes and multiplexes the optical signals OS7 to OS12 whose center wavelengths are sequentially separated from each other by approximately 0.020 μm from approximately 1.511 μm to approximately 1.611 μm, and multiplexes the multiplexed optical signal OCZB. And transmit it as a transmission signal. Under these circumstances, the E / O conversion units 588C to 593C and the multiplexing unit 673 form a data transmission unit that transmits the serial data DS7 to DS12 obtained from the P / S conversion units 577 to 582, respectively. are doing.
In this way, each of the set of optical signals OS1 to OS6 multiplexed in the multiplexing section 670 and the set of optical signals OS7 to OS12 multiplexed in the multiplexing section 673 has a center wavelength of about 0.1. The multiplexed optical signals OCZA and OCZB are formed by being multiplexed with wavelengths very close to each other, which are separated by only 020 μm, and are E / O converters 560C and 583C to 587C. A wavelength multiplexing technique called CWMD is used in each of the portion including the multiplexing section 670 and the portion including the E / O conversion sections 588 to 593C and the multiplexing section 673.
The multiplexed optical signal OCZA, which is a transmission signal transmitted from the multiplexing unit 670, is guided to the optical fiber transmission line 672 through the optical connector 671, and is transmitted to the receiving side through the optical fiber transmission line 672. The multiplexed optical signal OCZB, which is a transmission signal transmitted from the multiplexing unit 673, is guided to the optical fiber transmission line 675 through the optical connector 674, and is transmitted to the receiving side through the optical fiber transmission line 675.
On the receiving side, the multiplexed optical signal OCZA transmitted through the optical fiber transmission line 672 is guided to the demultiplexer 677 through the optical connector 676, and the multiplexed optical signal OCZB transmitted through the optical fiber transmission line 675 is transmitted through the optical connector 678. The light is guided to the demultiplexer 679.
In the demultiplexing unit 677, the multiplexed optical signal OCZA is demultiplexed into six components whose center wavelength is sequentially separated by approximately 0.020 μm from approximately 1.511 μm to approximately 1.611 μm. Reproduces the optical signals OS1 to OS6 whose bit transmission rate is 1.485 Gbps and whose center wavelength is sequentially separated by about 0.020 μm from about 1.511 μm to about 1.611 μm. Further, in the demultiplexing unit 679, the multiplexed optical signal OCZB is demultiplexed into six components whose center wavelengths are sequentially separated by approximately 0.020 μm from approximately 1.511 μm to approximately 1.611 μm. The optical signals OS7 to OS12, each of which has a bit transmission rate of 1.485 Gbps and a center wavelength sequentially separated by about 0.020 μm from about 1.511 μm to about 1.611 μm, are reproduced.
The optical signals OS1 to OS6 reproduced by the demultiplexer 677 are guided to O / E converters 619C and 631C to 635C, respectively. The O / E converters 619C and 631C to 635C perform photoelectric conversion processing on each of the optical signals OS1 to OS6 whose center wavelengths are sequentially separated by about 0.020 μm from about 1.511 μm to about 1.611 μm. , And reproduces serial data DS1 to DS6 each having a bit transmission rate of 1.485 Gbps based on the optical signals OS1 to OS6. Then, the serial data DS1 to DS6 reproduced by the O / E converters 619C and 631C to 635C are supplied to the S / P converters 642 and 644 to 648, respectively.
The optical signals OS7 to OS12 reproduced by the demultiplexer 679 are guided to O / E converters 636C to 641C, respectively. The O / E converters 636C to 641C perform a photoelectric conversion process on each of the optical signals OS7 to OS12 whose center wavelengths are sequentially separated from each other by approximately 0.020 μm from approximately 1.511 μm to approximately 1.611 μm. Based on the signals OS7 to OS12, each reproduces serial data DS7 to DS12 whose bit transmission rate is 1.485 Gbps. Then, the serial data DS7 to DS12 reproduced by the O / E converters 636C to 641C are supplied to the S / P converters 649 and 654, respectively.
Other operations are the same as those of the data transmitting / receiving apparatus shown in FIGS. 103 and 104.
Industrial applicability
As is apparent from the above description, any one of the first to eleventh aspects of the data transmission method according to the present invention or any one of the first to eleventh aspects of the data transmission apparatus according to the present invention According to this, the frame rate is set to 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz, etc., including the D-Cinema signal in the broad sense, the D-Cinema signal system double-speed digital video signal, and the like, and 4: 2: 2 format or 4: Transmission of digital data forming a digital video signal of 4: 4 format can be appropriately realized, for example, by utilizing existing circuit components used for serial transmission according to HD SDI.
According to any one of the twelfth to twenty-second aspects of the data transmission method according to the present invention or any one of the twelfth to twenty-second aspects of the data transmission apparatus according to the present invention, the 720P signal system double speed digital Transmission of digital data forming a digital video signal of 4: 2: 2 format or 4: 4: 4 format having a frame rate of 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like, including a video signal, is performed by, for example, HD SDI. Appropriate realization can be achieved by utilizing existing circuit components used for the serial transmission according to the present invention.
According to any one of the twenty-third to thirty-third aspects of the data transmission method according to the present invention, or any one of the twenty-third to thirty-third aspects of the data transmission apparatus according to the present invention, D-Cinema in a broad sense A digital video signal of a 4: 2: 2 format or a 4: 4: 4 format having a frame rate of 50 Hz, 60 Hz, 72 Hz, 75 Hz, 90 Hz, 120 Hz, etc., including signals, Cinema signal system double-speed digital video signals, etc. According to HD SDI, for example, transmission of digital data and the associated Key signal data sequence is performed in a state where the Key signal data sequence is an additional information data sequence attached to digital data forming a digital video signal to be transmitted. It can be implemented properly using existing circuit components used for serial transmission. .
According to any one of the thirty-fourth to forty-first aspects of the data transmission method according to the present invention or any one of the thirty-fourth to forty-first aspects of the data transmission apparatus according to the present invention, the 720P signal system double speed digital A digital video signal having a frame rate of 72 Hz, 75 Hz, 90 Hz, 120 Hz or the like including a video signal and the like and 720 effective lines in each frame is formed in a 4: 2: 2 format or a 4: 4: 4 format. According to HD SDI, for example, transmission of digital data and the associated Key signal data sequence is performed in a state where the Key signal data sequence is an additional information data sequence attached to digital data forming a digital video signal to be transmitted. It can be implemented appropriately using existing circuit components used for serial transmission.
[Brief description of the drawings]
FIG. 1 and FIG. 2 are conceptual diagrams provided for explaining an example of the data format of an HD digital video signal.
FIGS. 3 and 4 are table diagrams for explaining digital data forming a digital video signal.
FIG. 5 includes the first example of the first or twelfth aspect of the data transmission apparatus according to the present invention, in which the example of the first or twelfth aspect of the data transmission method according to the present invention is implemented. FIG. 2 is a block connection diagram showing the data transmission / reception device.
FIGS. 6 and 7 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmitting / receiving apparatus shown in FIG.
FIG. 8 includes a second example that forms the first or twelfth aspect of the data transmission apparatus according to the present invention, in which the example that forms the first or twelfth aspect of the data transmission method according to the present invention is implemented. FIG. 3 is a block connection diagram showing a part of the data transmission / reception device.
FIG. 9 includes a third example that implements the first or twelfth aspect of the data transmission apparatus according to the present invention, in which the example that implements the first or twelfth aspect of the data transmission method according to the present invention is implemented. FIG. 3 is a block connection diagram showing a part of the data transmission / reception device.
FIG. 10 includes a first example that implements the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which the example that implements the second or thirteenth aspect of the data transmission method according to the present invention is implemented. FIG. 2 is a block connection diagram showing the data transmission / reception device.
FIGS. 11 and 12 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmitting / receiving apparatus shown in FIG.
FIG. 13 includes a second example of the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which the example of the second or thirteenth aspect of the data transmission method according to the present invention is implemented. FIG. 3 is a block connection diagram showing a part of the data transmission / reception device.
FIG. 14 includes a third example according to the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which an example according to the second or thirteenth aspect of the data transmission method according to the present invention is implemented. FIG. 3 is a block connection diagram showing a part of the data transmission / reception device.
FIG. 15 includes a fourth example which forms the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which the example which forms the second or thirteenth aspect of the data transmission method according to the present invention is implemented. FIG. 3 is a block connection diagram showing a part of the data transmission / reception device.
FIG. 16 includes a fifth example according to the second or thirteenth aspect of the data transmission apparatus according to the present invention, in which an example according to the second or thirteenth aspect of the data transmission method according to the present invention is implemented. FIG. 3 is a block connection diagram showing a part of the data transmission / reception device.
FIGS. 17 and 18 show an example in which any one of the third to sixth, fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission method according to the present invention is implemented. And a data transmission / reception device including a first example of any one of the third to sixth, fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission device according to the present invention. It is a block connection diagram shown.
FIGS. 19 to 38 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmitting / receiving apparatus shown in FIGS.
FIG. 39 is a diagram illustrating a data transmission method according to the present invention in which an example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission method according to the present invention is implemented. Of the data transmission / reception device including a second example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission device according to the present invention. It is a block connection diagram.
FIG. 40 is a diagram illustrating an example in which any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission method according to the present invention is implemented. 11 shows a part of a data transmission / reception device including a third example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission device according to the present invention. It is a block connection diagram.
FIG. 41 is a diagram illustrating a data transmission method according to the present invention, in which an example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth, and thirty-fifth aspects of the data transmission method is implemented. Of the data transmission / reception device including a fourth example of any one of the third to sixth and fourteenth to seventeenth, twenty-third, twenty-fourth, thirty-fourth and thirty-fifth aspects of the data transmission device according to the present invention. It is a block connection diagram.
FIGS. 42 and 43 show examples in which any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. A data transmission / reception device including a first example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. It is a block connection diagram shown.
FIGS. 44 to 66 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmitting / receiving apparatus shown in FIGS. 42 and 43.
67 and 68 show an example in which any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. And a data transmission / reception device including a second example of any one of the seventh to ninth and eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. It is a block connection diagram which shows a part.
FIGS. 69 and 70 show an example in which any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. And a data transmission / reception device including a third example of any of the seventh to ninth and eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. It is a block connection diagram which shows a part.
FIG. 71 is a diagram illustrating a data transmission method according to the present invention in which an example of any one of the seventh to ninth, eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission method according to the present invention is implemented. Of the data transmission / reception device including a fourth example of any one of the seventh to ninth and eighteenth to twentieth, twenty-fifth to twenty-eighth, and thirty-sixth to thirty-ninth aspects of the data transmission device according to the present invention. It is a block connection diagram.
FIGS. 72 and 73 show a data transmission method according to the present invention in which an example of any one of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the data transmission method according to the present invention is implemented. It is a block connection diagram which shows the data transmission / reception apparatus including the 1st example which comprises any of the 10th, 11th, 21st, 22nd, 29th, and 30th aspects of a transmission apparatus.
FIGS. 74 to 88 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmitting / receiving apparatus shown in FIGS. 72 and 73.
FIGS. 89 and 90 show data according to the present invention in which an example of any of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the data transmission method according to the present invention is implemented. It is a block connection diagram which shows the part of the data transmission / reception apparatus including the 2nd example which comprises any one of the 10th, 11th, 21st, 22nd, 29th, and 30th aspect of a transmission apparatus.
FIGS. 91 and 92 show a data transmission method according to the present invention in which an example of any one of the tenth, eleventh, twenty-first, twenty-second, twenty-ninth, and thirtieth aspects of the data transmission method according to the present invention is implemented. It is a block connection diagram which shows the part of the data transmission / reception apparatus including the 3rd example which comprises any one of the 10th, 11th, 21st, 22nd, 29th, and 30th aspect of a transmission apparatus.
FIGS. 93 and 94 show the 31st, 32nd, 40th, and 41st embodiments of the data transmission method according to the present invention. It is a block connection diagram showing the data transmission / reception device including the 1st example which constitutes one of the 32nd, 40th, and 41st modes.
FIGS. 95 to 101 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmitting / receiving apparatus shown in FIGS. 93 and 94.
FIG. 102 shows a data transmission apparatus according to the present invention, in which an example of any one of the 31st, 32nd, 40th, and 41st aspects of the data transmission method according to the present invention is implemented. FIG. 41 is a block connection diagram illustrating a portion of a data transmission / reception device including a second example that constitutes one of the fortieth and forty-first aspects.
FIG. 103 and FIG. 104 show data transmission / reception including the first example which constitutes the 33rd aspect of the data transmission apparatus according to the present invention, in which the example which constitutes the 33rd aspect of the data transmission method according to the present invention is implemented. It is a block connection diagram showing an apparatus.
FIGS. 105 to 108 are conceptual diagrams showing data used for explaining the operation of the data processing unit in the data transmission / reception device shown in FIGS. 103 and 104.
FIG. 109 is a diagram showing a part of the data transmitting / receiving apparatus including the second example forming the 33rd aspect of the data transmission apparatus according to the present invention, in which the example forming the 33rd aspect of the data transmitting method according to the present invention is implemented. FIG.

Claims (143)

A luminance signal data sequence having a frame rate of 50 Hz or 60 Hz, a number of effective lines in each frame being 1080 lines, and a digital transmission signal having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps, 20-bit parallel data including the color difference signal data series,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. 2 is read out as forming 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Performing data processing to obtain first and second 20-bit word string data each having a word transmission rate of 74.25 MBps;
A data transmission method for obtaining first and second serial data based on the first and second 20-bit word string data, respectively, and transmitting the first and second serial data for transmission. 2. The data transmission method according to claim 1, wherein the first and second serial data are subjected to bit multiplexing processing to obtain composite serial data, and the composite serial data is transmitted. The first and second serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. The data transmission method according to claim 1. Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. To 20-bit parallel data including a sequence and a color difference signal data sequence,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read out as forming 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence that form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. 3 to perform data processing to obtain 20-bit word string data,
Obtaining first, second, and third serial data based on the first, second, and third 20-bit word string data, respectively, and transmitting the first, second, and third serial data for transmission; Data transmission method to use. Bit multiplexing processing is performed on two of the first, second, and third serial data to obtain composite serial data, and the composite serial data and the rest of the first, second, and third serial data are obtained. 5. The data transmission method according to claim 4, wherein the data transmission is performed by using one of the following. Converting the composite serial data and the remaining one of the first, second, and third serial data into first and second optical signals having different center wavelengths from each other; 6. The data transmission method according to claim 5, wherein the optical signals are multiplexed and transmitted. The first, second, and third serial data are converted into first, second, and third optical signals having different center wavelengths, and the first, second, and third optical signals are combined. 5. The data transmission method according to claim 4, wherein the data is transmitted. A digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. 24 bit, 28 bit or 32 bit parallel data including the luminance signal data sequence and the color difference signal data sequence
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. 24, 28 or 32 bit parallel data including a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. To form first and second 24-bit, 28-bit or 32-bit word string data, each having a word transmission rate of 74.25 MBps,
The 12-bit, 14-bit, or 16-bit words forming the luminance signal data sequence and the chrominance signal data sequence included in the first 24-bit, 28-bit, or 32-bit word string data, respectively, are referred to as upper 10 bits. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Second 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data is obtained,
The 12-bit, 14-bit, or 16-bit word forming the luminance signal data sequence and the chrominance signal data sequence included in each of the second 24-bit, 28-bit, or 32-bit word string data is referred to as upper 10 bits. Third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of divided upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of divided lower bits Performing data processing to obtain fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 9. The method according to claim 8, further comprising: performing bit multiplexing processing on the remaining two of the data to obtain second composite serial data, and transmitting the first and second composite serial data. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. The data transmission method according to claim 9, wherein A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. , 30-bit parallel data including a blue primary color signal data sequence and a red primary color signal data sequence,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory 2 is composed of 30 bits including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence which form a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Reading as forming parallel data to obtain first and second 30-bit word string data, each having a word transmission rate of 74.25 MBps,
A 10-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A first word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a second word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the first and second word groups, respectively. .25 MBps to obtain first and second 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A third word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a fourth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and the word transmission rate based on the third and fourth word groups is set to 74. Performing data processing to obtain third and fourth 20-bit word string data of .25 MBps;
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 12. The method according to claim 11, wherein bit multiplexing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. 13. The data transmission method according to claim 12, wherein: A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. , Into 36-bit parallel data including a blue primary color signal data sequence and a red primary color signal data sequence,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory No. 2 is composed of 36 bits including a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Read as forming parallel data to obtain first and second 36-bit word string data, each having a word transmission rate of 74.25 MBps,
The 12-bit word forming each of the green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence included in the first 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, The over de transmission rate with obtaining a second 20-bit word sequence data to 74.25 MBps,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data of which is 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Subjected to data processing to obtain a fourth 20-bit word sequence data to 74.25MBps the over de transmission rate,
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 15. The method according to claim 14, wherein bit multiplexing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. The data transmission method according to claim 15, wherein A luminance signal data sequence and a chrominance signal data sequence each forming a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. To 20-bit parallel data including
A first tri-fold frame portion to a first memory, a second tri-fold frame portion to a second memory, a third tri-fold frame portion to a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and stored in the third memory. Each of the frame part stored in the fourth memory and the frame part stored in the fourth memory forms 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal having a frame rate of 30 Hz. And performing data processing to obtain first, second, third, and fourth 20-bit word string data each having a word transmission rate of 74.25 MBps,
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 18. The method according to claim 17, wherein bit multiplexing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. 19. The data transmission method according to claim 18, wherein: A frame rate is set to 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame is formed, and the number of quantization bits is set to 12, 14, or 16 bits, and the word transmission rate is set to 222. 24 bit, 28 bit or 32 bit parallel data including a luminance signal data sequence and a color difference signal data sequence of 75 MBps,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. And read out as forming 24-bit, 28-bit or 32-bit parallel data including a luminance signal data sequence and a color difference signal data sequence forming a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. Obtaining first, second and third 24-bit, 28-bit or 32-bit word string data;
The 12-bit, 14-bit, or 16-bit words forming the luminance signal data sequence and the chrominance signal data sequence included in the first 24-bit, 28-bit, or 32-bit word string data, respectively, are referred to as upper 10 bits. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Obtaining second 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
The 12-bit, 14-bit, or 16-bit word forming each of the luminance signal data sequence and the color difference signal data sequence included in the second 24-bit, 28-bit, or 32-bit word string data is referred to as the upper 10 bits. Third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Obtaining fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
The 12-bit, 14-bit, or 16-bit word forming each of the luminance signal data sequence and the color difference signal data sequence included in the third 24-bit, 28-bit, or 32-bit word string data is referred to as the upper 10 bits. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Performing data processing to obtain sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first to sixth 20-bit word string data, respectively, and obtaining the first to sixth serial data; A data transmission method for transmitting data to transmit. The first to sixth serial data are divided into two sets of first, second and third sets, and bit multiplex processing is performed on the two sets of serial data of the first, second and third sets, respectively. 21. The data transmission method according to claim 20, wherein the first, second, and third composite serial data are obtained by performing the following, and the first, second, and third composite serial data are transmitted. . The first, second and third composite serial data are converted into first, second and third optical signals having different center wavelengths, respectively, and the first, second and third optical signals are combined. 22. The data transmission method according to claim 21, wherein the transmission is performed by wave transmission. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 30-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Are read out to form 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color signal data sequence that form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. First, second and third 30-bit word string data
A 10-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A first word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a second word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the first and second word groups, respectively. .25 MBps first and second 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the second 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A third word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a fourth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the third and fourth word groups, respectively. .25 MBps to obtain third and fourth 20-bit word string data,
A 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the third 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A fifth word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a sixth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the fifth and sixth word groups, respectively. Performing data processing to obtain fifth and sixth 20-bit word string data of .25 MBps;
Obtaining first, second, third, fourth, fifth and sixth serial data based on the first to sixth 20-bit word string data, respectively, and obtaining the first to sixth serial data; A data transmission method for transmitting data to transmit. The first to sixth serial data are divided into two sets of first, second and third sets, and bit multiplex processing is performed on the two sets of serial data of the first, second and third sets, respectively. 24. The data transmission method according to claim 23, wherein the first, second, and third composite serial data are obtained by performing the following, and the first, second, and third composite serial data are transmitted. . The first, second and third composite serial data are converted into first, second and third optical signals having different center wavelengths, respectively, and the first, second and third optical signals are combined. 25. The data transmission method according to claim 24, wherein the transmission is performed by wave transmission. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. 36-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence,
A first alternate frame portion is stored in a first memory, a second alternate frame portion is stored in a second memory, and a third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Are read out to form 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence which form a segmented frame digital video signal, each having a word transmission rate of 74.25 Mbps. To obtain the first, second and third 36-bit word string data
The 12-bit word forming each of the green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence included in the first 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Obtain a second 20-bit word sequence data to 74.25MBps the over de transmission rate,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data of which is 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, The over de transmission rate obtained and the fourth 20-bit word sequence data to 74.25 MBps, further,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the third 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Subjected to data processing to obtain the sixth 20-bit word sequence data to 74.25MBps the over de transmission rate,
First, second, third, fourth, fifth, and sixth serial data based on the first to sixth 20-bit word string data are obtained, and the first to sixth serial data are obtained. A data transmission method that sends out data for transmission. The first to sixth serial data are divided into two sets of first, second and third sets, and bit multiplex processing is performed on the two sets of serial data of the first, second and third sets, respectively. 27. The data transmission method according to claim 26, wherein the first, second, and third composite serial data are obtained by performing the following, and the first, second, and third composite serial data are transmitted. . The first, second and third composite serial data are converted into first, second and third optical signals having different center wavelengths, respectively, and the first, second and third optical signals are combined. 28. The data transmission method according to claim 27, wherein the transmission is performed by wave transmission. A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. 30-bit parallel data including a data sequence and a red primary color signal data sequence,
A first tri-fold frame portion in a first memory, a second tri-fold frame portion in a second memory, a third tri-frame portion in a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and a frame portion stored in the third memory are stored. A green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 30 Hz. , And the first, second, third, and fourth 30-bit word string data each having a word transmission rate of 74.25 MBps. Obtained,
A 10-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A first word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a second word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the first and second word groups, respectively. .25 MBps first and second 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the second 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A third word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a fourth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the third and fourth word groups, respectively. .25 MBps third and fourth 20-bit word string data,
A 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the third 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A fifth word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a sixth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the fifth and sixth word groups, respectively. .5 MBps of the fifth and sixth 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the fourth 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A seventh word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And an eighth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and the word transmission rate based on the seventh and eighth word groups is set to 74. Performing data processing to obtain seventh and eighth 20-bit word string data at .25 MBps;
First, second, third, fourth, fifth, sixth, seventh and eighth serial data based on the first to eighth 20-bit word string data are obtained, and the first to eighth serial data are obtained. A data transmission method for transmitting serial data up to the eighth. The first to eighth serial data are divided into two first, second, third, and fourth sets, and two sets of the first, second, third, and fourth sets are formed. Performing bit multiplexing processing on the serial data to obtain first, second, third and fourth composite serial data, and transmitting the first, second, third and fourth composite serial data; 30. The data transmission method according to claim 29, wherein: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 297 MBps. Into 36-bit parallel data including the data sequence and the red primary color signal data sequence,
A first tri-fold frame portion in a first memory, a second tri-fold frame portion in a second memory, a third tri-frame portion in a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and stored in the third memory. A green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a segmented frame digital video signal having a frame rate of 30 Hz. Are read to form 36-bit parallel data including the first, second, third, and fourth 36-bit word string data each having a word transmission rate of 74.25 MBps. The resulting,
The 12-bit word forming each of the green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence included in the first 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Obtain a second 20-bit word sequence data to 74.25MBps the over de transmission rate,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data of which is 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Obtain a fourth 20-bit word sequence data to 74.25MBps the over de transmission rate,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the third 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, The over de transmission rate obtained and the sixth 20-bit word sequence data to 74.25 MBps, further,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the fourth 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Subjected to data processing to obtain the eighth 20-bit word sequence data to 74.25MBps the over de transmission rate,
First, second, third and fourth, fifth, sixth, seventh and eighth serial data based on the first to eighth 20-bit word string data are obtained, and the first serial data is obtained. A data transmission method for transmitting serial data from the first to the eighth. The first to eighth serial data are divided into two first, second, third, and fourth sets, and two sets of the first, second, third, and fourth sets are formed. Performing bit multiplexing processing on the serial data to obtain first, second, third and fourth composite serial data, and transmitting the first, second, third and fourth composite serial data; 32. The data transmission method according to claim 31, wherein: A luminance signal data sequence and a chrominance signal each having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. 20-bit parallel data including data series,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. 2 is read out as forming 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence that form a segmented frame digital video signal with a frame rate of 60 Hz. Performing data processing to obtain first and second 20-bit word string data each having a word transmission rate of 74.25 MBps;
A data transmission method for obtaining first and second serial data based on the first and second 20-bit word string data, respectively, and transmitting the first and second serial data for transmission. 34. The data transmission method according to claim 33, wherein bit multiplex processing is performed on the first and second serial data to obtain composite serial data, and the composite serial data is transmitted. The first and second serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. The data transmission method according to claim 33. Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. To 20-bit parallel data including a sequence and a color difference signal data sequence,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read out as forming 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence that form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. 3 to perform data processing to obtain 20-bit word string data,
Obtaining first, second, and third serial data based on the first, second, and third 20-bit word string data, respectively, and transmitting the first, second, and third serial data for transmission; Data transmission method to use. Bit multiplexing processing is performed on two of the first, second, and third serial data to obtain composite serial data, and the composite serial data and the first. 37. The data transmission method according to claim 36, wherein the remaining one of the second and third serial data is transmitted. Converting the composite serial data and the remaining one of the first, second, and third serial data into first and second optical signals having different center wavelengths from each other; 37. The data transmission method according to claim 36, wherein the optical signal is multiplexed and transmitted. The first, second, and third serial data are converted into first, second, and third optical signals having different center wavelengths, and the first, second, and third optical signals are combined. 37. The data transmission method according to claim 36, wherein the data transmission is performed. A luminance signal data sequence and a chrominance signal data sequence each having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. To 20-bit parallel data including
A first tri-fold frame portion to a first memory, a second tri-fold frame portion to a second memory, a third tri-fold frame portion to a third memory, and A fourth every third frame portion is stored in a fourth memory, and the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame stored in the third memory are stored. Forming 20-bit bit parallel data including a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal having a frame rate of 30 Hz, respectively, by using the frame unit and the frame unit stored in the fourth memory. And performs data processing to obtain first, second, third, and fourth 20-bit bit word string data each having a word transmission rate of 74.25 MBps,
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 41. The method according to claim 40, wherein bit multiplexing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. 42. The data transmission method according to claim 41, wherein A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, blue 30-bit parallel data including the primary color signal data sequence and the red primary color signal data sequence,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion is stored in the first memory. 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a segmented frame digital video signal having a frame rate of 60 Hz. To form first and second 30-bit word string data, each having a word transmission rate of 74.25 MBps,
A 10-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A first word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a second word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the first and second word groups, respectively. .25 MBps to obtain first and second 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A third word groove including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a fourth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and the word transmission rate based on the third and fourth word groups is set to 74. .25 MBps to obtain third and fourth 20-bit word string data,
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 44. The method according to claim 43, wherein bit multiplexing processing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. The data transmission method according to claim 44, wherein A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps, blue 36-bit parallel data including a primary color signal data sequence and a red primary color signal data sequence,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory 2 is composed of 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. , To obtain first and second 36-bit word string data, each having a word transmission rate of 74.25 MBps,
The 12-bit word forming each of the green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence included in the first 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, The over de transmission rate with obtaining a second 20-bit word sequence data to 74.25 MBps,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data of which is 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Subjected to data processing to obtain a fourth 20-bit word sequence data to 74.25MBps the over de transmission rate,
First, second, third and fourth serial data based on the first to fourth 20-bit word string data are obtained, and the first, second, third and fourth serial data are obtained. A data transmission method sent out for transmission. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 47. The method according to claim 46, wherein bit multiplexing processing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. 48. The data transmission method according to claim 47, wherein A digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. 24 bit, 28 bit or 32 bit parallel data including signal data sequence and color difference signal data sequence,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the second memory forms 24-bit, 28-bit, or 32-bit parallel data including a luminance signal data sequence and a color difference signal data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. To obtain first and second 24-bit, 28-bit or 32-bit word string data, each having a word transmission rate of 74.25 MBps,
The 12-bit, 14-bit, or 16-bit words forming the luminance signal data sequence and the chrominance signal data sequence included in the first 24-bit, 28-bit, or 32-bit word string data, respectively, are referred to as upper 10 bits. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Second 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data is obtained,
The 12-bit, 14-bit, or 16-bit word forming the luminance signal data sequence and the chrominance signal data sequence included in each of the second 24-bit, 28-bit, or 32-bit word string data is referred to as upper 10 bits. Third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of divided upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of divided lower bits Performing data processing to obtain fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
First, second, third, and fourth serial data are obtained based on the first through fourth 20-bit word string data, respectively, and transmitted to transmit the first through fourth serial data. Data transmission method. Bit multiplexing is performed on two of the first, second, third, and fourth serial data to obtain first composite serial data, and the first, second, third, and fourth serial data are obtained. 50. The method according to claim 49, wherein bit multiplexing processing is performed on the remaining two of the data to obtain second composite serial data, and the first and second composite serial data are transmitted. Data transmission method. The first and second composite serial data are converted into first and second optical signals having different center wavelengths from each other, and the first and second optical signals are combined and transmitted. 51. The data transmission method according to claim 50, wherein A frame rate is set to 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame is formed, and the number of quantization bits is set to 12, 14, or 16 bits, and the word transmission rate is set to 222. 24 bit, 28 bit or 32 bit parallel data including a luminance signal data sequence and a color difference signal data sequence of 75 MBps,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. And read out as forming 24-bit, 28-bit or 32-bit parallel data including a luminance signal data sequence and a color difference signal data sequence forming a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. Obtaining first, second and third 24-bit, 28-bit or 32-bit word string data;
The 12-bit, 14-bit, or 16-bit words forming the luminance signal data sequence and the chrominance signal data sequence included in the first 24-bit, 28-bit, or 32-bit word string data, respectively, are referred to as upper 10 bits. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Obtaining second 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
The 12-bit, 14-bit, or 16-bit word forming each of the luminance signal data sequence and the color difference signal data sequence included in the second 24-bit, 28-bit, or 32-bit word string data is referred to as the upper 10 bits. Third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Obtaining fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
The 12-bit, 14-bit, or 16-bit word forming each of the luminance signal data sequence and the color difference signal data sequence included in the third 24-bit, 28-bit, or 32-bit word string data is referred to as the upper 10 bits. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Performing data processing to obtain sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data;
Obtaining first, second, third, fourth, fifth and sixth serial data based on the first to sixth 20-bit word string data, respectively, and obtaining the first to sixth serial data; A data transmission method for transmitting data to transmit. The first to sixth serial data are divided into two sets of first, second and third sets, and bit multiplex processing is performed on the two sets of serial data of the first, second and third sets, respectively. 53. The data transmission method according to claim 52, wherein the first, second, and third composite serial data are obtained by performing the following, and the first, second, and third composite serial data are transmitted. . The first, second and third composite serial data are converted into first, second and third optical signals having different center wavelengths, respectively, and the first, second and third optical signals are combined. 54. The data transmission method according to claim 53, wherein the transmission is performed by wave transmission. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 30-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Are read out to form 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color signal data sequence that form a segmented frame digital video signal, each having a word transmission rate of 74.25 MBps. First, second and third 30-bit word string data
A 10-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A first word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a second word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the first and second word groups, respectively. .25 MBps first and second 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the second 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A third word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a fourth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the third and fourth word groups, respectively. .25 MBps to obtain third and fourth 20-bit word string data,
A 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the third 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A fifth word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a sixth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the fifth and sixth word groups, respectively. Performing data processing to obtain fifth and sixth 20-bit word string data of .25 MBps;
Obtaining first, second, third, fourth, fifth and sixth serial data based on the first to sixth 20-bit word string data, respectively, and obtaining the first to sixth serial data; A data transmission method for transmitting data to transmit. The first to sixth serial data are divided into two sets of first, second and third sets, and bit multiplex processing is performed on the two sets of serial data of the first, second and third sets, respectively. 55. The data transmission method according to claim 55, wherein the first, second, and third composite serial data are obtained by performing the following, and the first, second, and third composite serial data are transmitted. . The first, second and third composite serial data are converted into first, second and third optical signals having different center wavelengths, respectively, and the first, second and third optical signals are combined. 57. The data transmission method according to claim 56, wherein the transmission is performed by wave transmission. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. 36-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence,
A first alternate frame portion is stored in a first memory, a second alternate frame portion is stored in a second memory, and a third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Are read out to form 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence which form a segmented frame digital video signal, each having a word transmission rate of 74.25 Mbps. To obtain the first, second and third 36-bit word string data
The 12-bit word forming each of the green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence included in the first 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Obtain a second 20-bit word sequence data to 74.25MBps the over de transmission rate,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data of which is 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, The over de transmission rate obtained and the fourth 20-bit word sequence data to 74.25 MBps, further,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the third 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Subjected to data processing to obtain the sixth 20-bit word sequence data to 74.25MBps the over de transmission rate,
First, second, third, fourth, fifth, and sixth serial data based on the first to sixth 20-bit word string data are obtained, and the first to sixth serial data are obtained. A data transmission method that sends out data for transmission. The first to sixth serial data are divided into two sets of first, second and third sets, and bit multiplex processing is performed on the two sets of serial data of the first, second and third sets, respectively. 59. A data transmission method according to claim 58, wherein the first, second, and third composite serial data are obtained by performing the following, and the first, second, and third composite serial data are transmitted. . The first, second and third composite serial data are converted into first, second and third optical signals having different center wavelengths, respectively, and the first, second and third optical signals are combined. 60. The data transmission method according to claim 59, wherein the transmission is performed by wave transmission. A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. 30-bit parallel data including a data sequence and a red primary color signal data sequence,
A first tri-fold frame portion in a first memory, a second tri-fold frame portion in a second memory, a third tri-frame portion in a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and a frame portion stored in the third memory are stored. A green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 30 Hz. , And the first, second, third, and fourth 30-bit word string data each having a word transmission rate of 74.25 MBps. Obtained,
A 10-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A first word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a second word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the first and second word groups, respectively. .25 MBps first and second 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the second 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A third word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a fourth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the third and fourth word groups, respectively. .25 MBps third and fourth 20-bit word string data,
A 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the third 30-bit word string data is a 10-bit word forming the green primary color signal data sequence. A fifth word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And a sixth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and a word transmission rate of 74 based on the fifth and sixth word groups, respectively. .5 MBps of the fifth and sixth 20-bit word string data,
The 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the fourth 30-bit word string data is replaced with a 10-bit word forming the green primary color signal data sequence. A seventh word group including a word and a part of a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming an auxiliary data sequence; And an eighth word group including the other part of the 10-bit word forming each of the series and the red primary color signal data series, and the word transmission rate based on the seventh and eighth word groups is set to 74. Performing data processing to obtain seventh and eighth 20-bit word string data at .25 MBps;
First, second, third, fourth, fifth, sixth, seventh and eighth serial data based on the first to eighth 20-bit word string data are obtained, and the first to eighth serial data are obtained. A data transmission method for transmitting serial data up to the eighth. The first to eighth serial data are divided into two first, second, third, and fourth sets, and two sets of the first, second, third, and fourth sets are formed. Performing bit multiplexing processing on the serial data to obtain first, second, third and fourth composite serial data, and transmitting the first, second, third and fourth composite serial data; 62. The data transmission method according to claim 61, wherein: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 297 MBps. Into 36-bit parallel data including the data sequence and the red primary color signal data sequence,
A first tri-fold frame portion in a first memory, a second tri-fold frame portion in a second memory, a third tri-frame portion in a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and stored in the third memory. A green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a segmented frame digital video signal having a frame rate of 30 Hz. Are read to form 36-bit parallel data including the first, second, third, and fourth 36-bit word string data each having a word transmission rate of 74.25 MBps. The resulting,
The 12-bit word forming each of the green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence included in the first 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Obtain a second 20-bit word sequence data to 74.25MBps the over de transmission rate,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data of which is 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Obtain a fourth 20-bit word sequence data to 74.25MBps the over de transmission rate,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the third 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, The over de transmission rate obtained and the sixth 20-bit word sequence data to 74.25 MBps, further,
The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the fourth 36-bit word string data is divided into upper 10 bits and lower 2 bits. A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower two bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, Subjected to data processing to obtain the eighth 20-bit word sequence data to 74.25MBps the over de transmission rate,
First, second, third and fourth, fifth, sixth, seventh and eighth serial data based on the first to eighth 20-bit word string data are obtained, and the first serial data is obtained. A data transmission method for transmitting serial data from the first to the eighth. The first to eighth serial data are divided into two first, second, third, and fourth sets, and two sets of the first, second, third, and fourth sets are formed. Performing bit multiplexing processing on the serial data to obtain first, second, third and fourth composite serial data, and transmitting the first, second, third and fourth composite serial data; 64. The data transmission method according to claim 63, wherein: A luminance signal data sequence having a frame rate of 50 Hz or 60 Hz and a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps, 30-bit parallel data including a color difference signal data sequence and an additional information data sequence having a data format equivalent to that of the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps,
A first alternate frame portion is stored in a first memory, a second alternate frame portion is stored in a second memory, and the first alternate frame portion is stored in the first memory. 30-bit parallel data including a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. To form first and second 30-bit word string data, each having a word transmission rate of 74.25 MBps,
First 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the first 30-bit word string data, and the first 30-bit word Forming second 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the column data and the auxiliary 10-bit word string,
Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word string data, and the second 30-bit word Performing data processing to form fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
First, second, third, and fourth serial data based on the first, second, third, and fourth 20-bit word string data are obtained, and the first, second, third, and fourth serial data are obtained. 4. A data transmission method for transmitting serial data for transmission. 67. The data transmission method according to claim 65, wherein the additional information data sequence represents Key signal information on a digital video signal. A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. , A blue primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. And 40-bit parallel data including
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory 2 is divided into a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and additional information data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Read out as forming 40-bit parallel data including a sequence and first and second 40-bit word string data, each having a word transmission rate of 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 40-bit word sequence data are formed into the green primary color signal data sequence. A first word group including a 10-bit word to form the blue primary color signal data sequence and a part of the 10-bit word to form the red primary color signal data sequence; a 10-bit word forming the additional information data sequence; A second word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the first word group is set to 74.25 MBps. And a word based on the first 20-bit word string data and the second word group. With a feed rate to form a second 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the second 40-bit word sequence data are formed into the green primary color signal data sequence. A third word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A fourth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the third word group is set to 74.25 MBps. And a word based on the third 20-bit word string data and the fourth word group Performing data processing for forming a fourth 20-bit word sequence data having a transmission rate and 74.25 MBps,
First, second, third, and fourth serial data based on the first, second, third, and fourth 20-bit word string data are obtained, and the first, second, third, and fourth serial data are obtained. 4. A data transmission method for transmitting serial data for transmission. 67. The data transmission method according to claim 67, wherein the additional information data sequence represents key signal information on a digital video signal. Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 30-bit parallel data including a sequence and a chrominance signal data sequence, and an additional information data sequence having a data format equivalent to the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. To
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. And 30-bit parallel data including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence which form a segmented frame digital video signal. Obtaining first, second and third 30-bit word string data;
First 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the first 30-bit word string data, and the first 30-bit word Forming second 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word string data, and the second 30-bit word Forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the third 30-bit word string data, and the third 30-bit word Performing data processing to form sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. 70. The data transmission method according to claim 69, wherein the additional information data sequence represents key signal information on a digital video signal. A digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. Have the same data format as the above-mentioned luminance signal data sequence, the number of quantization bits is 12, 14, or 16 bits, and the word transmission rate is 148.5 MBps. 36-bit, 42-bit or 48-bit parallel data including an information data sequence,
A first alternate frame portion is stored in a first memory, a second alternate frame portion is stored in a second memory, and the first alternate frame portion is stored in the first memory. Each of the frame portions stored in the memory 2 is a 36-bit, 42-bit signal including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Read as forming bit or 48-bit parallel data to obtain first and second 36-bit, 42-bit or 48-bit word string data, each having a word transmission rate of 74.25 MBps,
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the key signal data sequence included in the first 36-bit, 42-bit or 48-bit word sequence data, It is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and the word transmission rate is set to 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the color difference signal data sequence. 1, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the data. Along with
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the second 36-bit, 42-bit or 48-bit word sequence data. A word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the upper 10 bits and lower 2 bits, 4 bits, or 6 bits based on the luminance signal data sequence and the color difference signal data sequence. 4, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the above. Data processing,
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. 72. The data transmission method according to claim 71, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. , A blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. And 48-bit parallel data including
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory 2 is divided into a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and additional information data forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. And read out as forming 48-bit parallel data including a sequence to obtain first and second 48-bit word string data, each having a word transmission rate of 74.25 MBps,
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A first 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the second 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Performing data processing to form sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. 74. The data transmission method according to claim 73, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. Additional information having a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 40-bit parallel data including data series
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read out as forming 40-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence, which form a segmented frame digital video signal, each of which is transmitted in words. Obtaining first, second and third 40-bit word string data having a rate of 74.25 MBps;
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 40-bit word sequence data are formed into the green primary color signal data sequence. A first word group including a 10-bit word to form the blue primary color signal data sequence and a part of the 10-bit word to form the red primary color signal data sequence; a 10-bit word forming the additional information data sequence; A second word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the first word group is set to 74.25 MBps. And a word based on the first 20-bit word string data and the second word group. The feed rate to form a second 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the second 40-bit word sequence data are formed into the green primary color signal data sequence. A third word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A fourth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the third word group is set to 74.25 MBps. And a word based on the third 20-bit word string data and the fourth word group The feed rate to form a fourth 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the third 40-bit word sequence data are formed into the green primary color signal data sequence. A fifth word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A word transmission rate of 74.25 MBps based on the fifth word group is divided into a sixth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence. And a word based on the fifth 20-bit word string data and the sixth word group. Performing data processing to form the sixth 20-bit word sequence data which the transmission rate and 74.25 MBps,
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. 76. The data transmission method according to claim 75, wherein the additional information data sequence represents key signal information on a digital video signal. A luminance signal data sequence and a chrominance signal data sequence each forming a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. And 30-bit parallel data having a data format equivalent to the luminance signal data sequence and an additional information data sequence having a quantization bit number of 10 bits and a word transmission rate of 297 MBps,
A first tri-fold frame portion in a first memory, a second tri-fold frame portion in a second memory, a third tri-frame portion in a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and a frame portion stored in the third memory are stored. And a frame portion stored in the fourth memory include a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence that form a segmented frame digital video signal having a frame rate of 30 Hz. Read as forming 30-bit parallel data to obtain first, second, third and fourth 30-bit word string data, each having a word transmission rate of 74.25 MBps,
First 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the first 30-bit word string data, and the first 30-bit word Forming second 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word string data, and the second 30-bit word Forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the third 30-bit word string data, and the third 30-bit word Forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the fourth 30-bit word string data, and the fourth 30-bit word Performing data processing to form eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
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. 78. The data transmission method according to claim 77, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. 40-bit parallel including a data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. In the data,
A first tri-fold frame portion to a first memory, a second tri-fold frame portion to a second memory, a third tri-fold frame portion to a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and stored in the third memory. A green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 30 Hz. And 40-bit parallel data including the additional information data sequence and the first, second, third and fourth fours each having a word transmission rate of 74.25 MBps. Give a bit word sequence data,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 40-bit word sequence data are formed into the green primary color signal data sequence. A first word group including a 10-bit word to form the blue primary color signal data sequence and a part of the 10-bit word to form the red primary color signal data sequence; a 10-bit word forming the additional information data sequence; A second word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the first word group is set to 74.25 MBps. And a word based on the first 20-bit word string data and the second word group. The feed rate to form a second 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the second 40-bit word sequence data are formed into the green primary color signal data sequence. A third word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A fourth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the third word group is set to 74.25 MBps. And a word based on the third 20-bit word string data and the fourth word group The feed rate to form a fourth 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the third 40-bit word sequence data are formed into the green primary color signal data sequence. A fifth word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A word transmission rate of 74.25 MBps based on the fifth word group is divided into a sixth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence. And a word based on the fifth 20-bit word string data and the sixth word group. The feed rate to form a sixth 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the fourth 40-bit word sequence data are formed into the green primary color signal data sequence. A seventh word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. An eighth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the seventh word group is set to 74.25 MBps. And a word based on the seventh 20-bit word string data and the eighth word group. Performing data processing to form the eighth 20-bit word sequence data which the transmission rate and 74.25 MBps,
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. 80. The data transmission method according to claim 79, wherein the additional information data sequence represents key signal information on a digital video signal. A frame rate is set to 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame is formed, and the number of quantization bits is set to 12, 14, or 16 bits, and the word transmission rate is set to 222. It has a luminance signal data sequence and a color difference signal data sequence of 75 MBps, a data format equivalent to the luminance signal data sequence, a quantization bit number of 12, 14, or 16 bits, and a word transmission rate of 222.75 MBps. 36-bit, 42-bit or 48-bit parallel data including the additional information data sequence
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. And read out as forming 36-bit, 42-bit or 48-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence and an additional information data sequence which form a segmented frame digital video signal. Obtaining first, second and third 36-bit, 42-bit or 48-bit word string data of 74.25 MBps;
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the first 36-bit, 42-bit or 48-bit word sequence data, It is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and the word transmission rate is set to 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the color difference signal data sequence. 1, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the data. And
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the second 36-bit, 42-bit or 48-bit word sequence data. A word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the upper 10 bits and lower 2 bits, 4 bits, or 6 bits based on the luminance signal data sequence and the color difference signal data sequence. 4, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the above. And
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence and the additional information data sequence included in the third 36-bit, 42-bit or 48-bit word sequence data. It is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and the word transmission rate is set to 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the color difference signal data sequence. 7, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series And ninth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits, or 6 bits and a plurality of auxiliary bits divided from the data. Data processing,
A data transmission method for obtaining first to ninth serial data based on the first to ninth 20-bit word string data and transmitting the first to ninth serial data for transmission. 82. The data transmission method according to claim 81, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. Additional information that has a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. 48-bit parallel data including data series
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read out as forming 48-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence, which form a segmented frame digital video signal, each of which is transmitted in words. Obtaining first, second and third 48-bit word string data having a rate of 74.25 MBps,
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A first 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the second 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the third 48-bit word sequence data are represented by upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 7th 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. An 8th 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Performing data processing to form ninth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
A data transmission method for obtaining first to ninth serial data based on the first to ninth 20-bit word string data and transmitting the first to ninth serial data for transmission. 84. The data transmission method according to claim 83, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 297 MBps. 48-bit parallel including a data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 297 MBps. In the data,
A first tri-fold frame portion to a first memory, a second tri-fold frame portion to a second memory, a third tri-fold frame portion to a third memory, and A fourth every third frame portion is stored in a fourth memory, and a frame portion stored in the first memory, a frame portion stored in the second memory, and stored in the third memory. A green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a segmented frame digital video signal having a frame rate of 30 Hz. And the additional information data sequence, are read out to form 48-bit parallel data, each of which has a word transmission rate of 74.25 MBps, a first, a second, a third and a fourth. Give a bit word sequence data,
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A first 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the second 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the third 48-bit word sequence data are represented by upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 7th 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. An 8th 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming ninth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the fourth 48-bit word sequence data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of the upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 10th 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. , A plurality of lower-order data divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Eleventh 20-bit word string data having a word transmission rate of 74.25 MBps based on bits and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence And performing data processing to form twelfth 20-bit word string data having a word transmission rate of 74.25 MBps based on and a plurality of auxiliary bits,
A data transmission method for obtaining first to twelfth serial data based on the first to twelfth 20-bit word string data, respectively, and transmitting the first to twelfth serial data for transmission. 86. The data transmission method according to claim 85, wherein the additional information data sequence represents key signal information on a digital video signal. A luminance signal data sequence and a chrominance signal each having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to that of the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the second memory forms 30-bit parallel data including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. To obtain first and second 30-bit word string data, each having a word transmission rate of 74.25 MBps,
First 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the first 30-bit word string data, and the first 30-bit word Forming second 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the column data and the auxiliary 10-bit word string,
Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word string data, and the second 30-bit word Performing data processing to form fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
First, second, third, and fourth serial data based on the first, second, third, and fourth 20-bit word string data are obtained, and the first, second, third, and fourth serial data are obtained. 4. A data transmission method for transmitting serial data for transmission. 88. The data transmission method according to claim 87, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, blue A primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. Including 40-bit parallel data,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the second memory is divided into a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence which form a segmented frame digital video signal having a frame rate of 60 Hz. Are read as forming 40-bit parallel data including the first and second 40-bit word string data each having a word transmission rate of 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 40-bit word sequence data are formed into the green primary color signal data sequence. A first word group including a 10-bit word to form the blue primary color signal data sequence and a part of the 10-bit word to form the red primary color signal data sequence; a 10-bit word forming the additional information data sequence; A second word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the first word group is set to 74.25 MBps. And a word based on the first 20-bit word string data and the second word group. With a feed rate to form a second 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the second 40-bit word sequence data are formed into the green primary color signal data sequence. A third word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A fourth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the third word group is set to 74.25 MBps. And a word based on the third 20-bit word string data and the fourth word group Performing data processing for forming a fourth 20-bit word sequence data having a transmission rate and 74.25 MBps,
First, second, third, and fourth serial data based on the first, second, third, and fourth 20-bit word string data are obtained, and the first, second, third, and fourth serial data are obtained. 4. A data transmission method for transmitting serial data for transmission. 90. The data transmission method according to claim 89, wherein the additional information data sequence represents key signal information on a digital video signal. Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 30-bit parallel data including a sequence and a chrominance signal data sequence, and an additional information data sequence having a data format equivalent to the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. To
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. And 30-bit parallel data including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence which form a segmented frame digital video signal. Obtaining first, second and third 30-bit word string data;
First 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the first 30-bit word string data, and the first 30-bit word Forming second 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word string data, and the second 30-bit word Forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the third 30-bit word string data, and the third 30-bit word Performing data processing to form sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the string data and the auxiliary 10-bit word string;
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. The data transmission method according to claim 91, wherein the additional information data sequence represents Key signal information on a digital video signal. A digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed, and each has a quantization bit number of 12, 14, or 16 bits and a luminance of 148.5 MBps at a word transmission rate. Additional information data having a signal data sequence, a color difference signal data sequence, and a data format equivalent to the luminance signal data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. Into 36-bit, 42-bit or 48-bit parallel data including the sequence
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory 2 is composed of 36 bits, 42 bits including a luminance signal data sequence, a color difference signal data sequence, Reading as forming 48-bit parallel data to obtain first and second 36-bit, 42-bit or 48-bit word string data, each having a word transmission rate of 74.25 MBps;
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the key signal data sequence included in the first 36-bit, 42-bit or 48-bit word sequence data, It is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and the word transmission rate is set to 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the color difference signal data sequence. 1, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the data. Along with
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the second 36-bit, 42-bit or 48-bit word sequence data. A word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the upper 10 bits and lower 2 bits, 4 bits, or 6 bits based on the luminance signal data sequence and the color difference signal data sequence. 4, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the above. Data processing,
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. The data transmission method according to claim 93, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps, blue A primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. Including 48-bit parallel data,
A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the second memory is divided into a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence which form a segmented frame digital video signal having a frame rate of 60 Hz. , To obtain first and second 48-bit word string data each having a word transmission rate of 74.25 MBps,
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A first 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the second 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Performing data processing to form sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. The data transmission method according to claim 95, wherein the additional information data sequence represents Key signal information on a digital video signal. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. Additional information that has a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, has a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 40-bit parallel data including data series,
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read out as forming 40-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence, which form a segmented frame digital video signal, each of which is transmitted in words. Obtaining first, second and third 40-bit word string data having a rate of 74.25 MBps;
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 40-bit word sequence data are formed into the green primary color signal data sequence. A first word group including a 10-bit word to form the blue primary color signal data sequence and a part of the 10-bit word to form the red primary color signal data sequence; a 10-bit word forming the additional information data sequence; A second word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the first word group is set to 74.25 MBps. And a word based on the first 20-bit word string data and the second word group. The feed rate to form a second 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the second 40-bit word sequence data are formed into the green primary color signal data sequence. A third word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A fourth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence, and the word transmission rate based on the third word group is set to 74.25 MBps. And a word based on the third 20-bit word string data and the fourth word group The feed rate to form a fourth 20-bit word sequence data to 74.25 MBps,
The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the third 40-bit word sequence data are formed into the green primary color signal data sequence. A fifth word group including a 10-bit word forming the additional information data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A word transmission rate of 74.25 MBps based on the fifth word group is divided into a sixth word group including the primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence. And a word based on the fifth 20-bit word string data and the sixth word group. Performing data processing to form the sixth 20-bit word sequence data which the transmission rate and 74.25 MBps,
Obtaining first, second, third, fourth, fifth, and sixth serial data based on the first, second, third, fourth, fifth, and sixth 20-bit word string data, respectively; , A data transmission method for transmitting the first to sixth serial data for transmission. The data transmission method according to claim 97, wherein the additional information data sequence represents key signal information on a digital video signal. A frame rate is set to 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame is formed, and the quantization bit number is set to 12, 14 or 16 bits, and the word transmission rate is set to 222. It has a luminance signal data sequence and a color difference signal data sequence of 75 MBps, a data format equivalent to the luminance signal data sequence, a quantization bit number of 12, 14, or 16 bits, and a word transmission rate of 222.75 MBps. 36-bit, 42-bit or 48-bit parallel data including the additional information data sequence
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. And read out as forming 36-bit, 42-bit or 48-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence and an additional information data sequence which form a segmented frame digital video signal. Obtaining first, second and third 36-bit, 42-bit or 48-bit word string data of 74.25 MBps;
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the first 36-bit, 42-bit or 48-bit word sequence data, It is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and the word transmission rate is set to 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the color difference signal data sequence. 1, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the data. And
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the second 36-bit, 42-bit or 48-bit word sequence data. A word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the upper 10 bits and lower 2 bits, 4 bits, or 6 bits based on the luminance signal data sequence and the color difference signal data sequence. 4, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series A sixth 20-bit word string data having a word transmission rate of 74.25 MBps is formed based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the above. And
A 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence and the additional information data sequence included in the third 36-bit, 42-bit or 48-bit word sequence data. It is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and the word transmission rate is set to 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the color difference signal data sequence. 7, a word transmission rate of 74.25 Mbps based on 20-bit word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. And the additional information data series And ninth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits, or 6 bits and a plurality of auxiliary bits divided from the data. Data processing,
A data transmission method for obtaining first to ninth serial data based on the first to ninth 20-bit word string data and transmitting the first to ninth serial data for transmission. The data transmission method according to claim 99, wherein the additional information data sequence represents key signal information on a digital video signal. A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. Additional information having a data format, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. 48-bit parallel data including data series
The first alternate frame portion is stored in a first memory, the second alternate frame portion is stored in a second memory, and the third alternate frame portion is stored in a third memory. Each of the frame portion stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory has a frame rate of 24 Hz, 25 Hz, or 30 Hz. Read out as forming 48-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence, which form a segmented frame digital video signal, each of which is transmitted in words. Obtaining first, second and third 48-bit word string data having a rate of 74.25 MBps,
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A first 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the second 48-bit word string data are divided into upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Forming a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the third 48-bit word sequence data are represented by upper 10 bits and lower 2 bits. Into a plurality of upper 10 bits divided from the green primary color signal data sequence, and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 7th 20-bit word string data having a word transmission rate of 74.25 MBps, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. An 8th 20-bit word string data having a word transmission rate of 74.25 MBps based on the bit and a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. Performing data processing to form ninth 20-bit word string data having a word transmission rate of 74.25 MBps based on the bits and the plurality of auxiliary bits;
A data transmission method for obtaining first to ninth serial data based on the first to ninth 20-bit word string data and transmitting the first to ninth serial data for transmission. 102. The data transmission method according to claim 101, wherein the additional information data sequence represents key signal information on a digital video signal. A luminance signal data sequence having a frame rate of 50 Hz or 60 Hz, a number of effective lines in each frame being 1080 lines, and a digital transmission signal having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps, In the 20-bit parallel data including the color difference signal data sequence, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. A frame portion stored in the first memory and a frame portion stored in the second memory are respectively composed of a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Read as forming 20-bit parallel data including A data processing unit, each performing data processing to obtain the first and second 20-bit word sequence data to 74.25MBps word transmission rate,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A data transmission unit for transmitting the first and second serial data for transmission;
A data transmission device comprising: Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 20-bit parallel data including a sequence and a color difference signal data sequence, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion to a third memory. Are stored in the third memory, and the frame part stored in the first memory, the frame part stored in the second memory, and the frame stored in the third memory are stored. Each of the sections forms a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. The data is read as forming 20-bit parallel data including the degree signal data sequence and the color difference signal data sequence, and first, second, and third 20-bit word string data each having a word transmission rate of 74.25 MBps are obtained. A data processing unit for performing data processing;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A data transmission unit for transmitting the first, second, and third serial data for transmission;
A data transmission device comprising: A digital video signal having a frame rate of 50 Hz or 60 Hz and an effective line number of 1080 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. The first alternate frame portion is stored in a first memory in a 24-bit, 28-bit or 32-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence. And a frame part stored in the first memory and a frame part stored in the second memory, each of which has a frame rate of 25 Hz or 30 Hz. Luminance signal data series and color difference signal data system forming signals Are read out as forming 24-bit, 28-bit or 32-bit parallel data, and first and second 24-bit, 28-bit or 32-bit word string data each having a word transmission rate of 74.25 MBps are obtained. The 12-bit, 14-bit, or 16-bit word forming the luminance signal data sequence and the chrominance signal data sequence included in the first 24-bit, 28-bit, or 32-bit word string data, respectively, is replaced with the upper 10 bits. And first 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, and a plurality of divided plurality of upper 10 bits. Based on lower 2 bits, 4 bits or 6 bits and auxiliary data, 20 bit word string data having a transmission rate of 74.25 MBps, and a luminance signal data sequence and chrominance signal data contained in the second 24 bit, 28 bit or 32 bit word string data, respectively. A word transmission rate based on a plurality of upper 10 bits obtained by dividing each 12-bit, 14-bit, or 16-bit word forming each of the series into upper 10 bits and lower 2 bits, 4 bits, or 6 bits. 20-bit word string data having a word transmission rate of 74.25 MBps, and a fourth 20-bit word transmission rate 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 data. A data processing unit for performing data processing for obtaining bit word string data;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. Storing the first alternate frame portion in the first memory and storing the second alternate frame portion in the 30-bit parallel data including the blue primary color signal data sequence and the red primary color signal data sequence in the second memory; And a frame part stored in the first memory and a frame part stored in the second memory, respectively, each of which is a green color which forms a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Primary color signal data sequence, blue primary color signal data sequence and red primary color signal data The data is read out as forming 30-bit parallel data including a sequence, and first and second 30-bit word string data each having a word transmission rate of 74.25 MBps are obtained. A 10-bit word forming each of the included green primary color signal data sequence, blue primary color signal data sequence and red primary color signal data sequence is defined as a 10-bit word forming the green primary color signal data sequence and the blue primary color signal data sequence and red color. A first word group including a part of a 10-bit word forming each of the primary color signal data sequences, a 10-bit word forming an auxiliary data sequence, and each of the blue primary color signal data sequence and the red primary color signal data sequence. A second word group including another part of the 10-bit word to be formed, First and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the first and second word groups, respectively, and a green primary color signal included in the second 30-bit word string data A 10-bit word forming each of the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence is defined as a 10-bit word forming the green primary color signal data sequence and the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A third word group including a part of the 10-bit word forming each, a 10-bit word forming the auxiliary data sequence, and a 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence And a fourth word group including the other part of the third and fourth word groups. A data processing unit for performing data processing for obtaining third and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on each of
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. The first alternate frame portion is stored in a first memory in the 36-bit parallel data including the blue primary color signal data sequence and the red primary color signal data sequence, and the second alternate frame portion is stored in a second memory. And a frame part stored in the first memory and a frame part stored in the second memory, respectively, each of which is a green color which forms a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Primary color signal data sequence, blue primary color signal data sequence and red primary color signal data The data is read as forming 36-bit parallel data including a sequence, and first and second 36-bit word string data each having a word transmission rate of 74.25 MBps are obtained. The 12-bit word forming each of the included green primary color signal data sequence, blue primary color signal data sequence, and red primary color signal data sequence is divided into upper 10 bits and lower 2 bits, and is divided from the green primary color signal data sequence. A first 20 bits having a word transmission rate of 74.25 MBps based on the plurality of upper 10 bits and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. The bit word string data is divided from the blue primary color signal data sequence and the red primary color signal data sequence, respectively. A word transmission rate of 74 based on another part of the plurality of upper 10 bits obtained and the plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. .25 MBps, and forms each of a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color signal data sequence included in the second 36-bit word sequence data. The 12-bit word is divided into upper 10 bits and lower 2 bits, and the upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data sequence and the red primary color signal data sequence, respectively. The third 20 bits having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits thus obtained. Bit word sequence data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color. A data processing unit that performs data processing to obtain fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower two bits divided from the signal data sequence;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A luminance signal data sequence and a chrominance signal data sequence each forming a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. In the 20-bit parallel data, the first every third frame portion in the first memory, the second every third frame portion in the second memory, and the third every third frame portion. A third memory, and a fourth every third frame portion stored in the fourth memory; a frame portion stored in the first memory; a frame portion stored in the second memory; Each of the frame part stored in the third memory and the frame part stored in the fourth memory is a segmented frame having a frame rate of 30 Hz. Read out as forming 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence that form a digital video signal, each having a word transmission rate of 74.25 MBps. 4, a data processing unit for performing data processing for obtaining 20-bit word string data;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A frame rate is set to 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame is formed, and the number of quantization bits is set to 12, 14, or 16 bits, and the word transmission rate is set to 222. In the 24-bit, 28-bit or 32-bit parallel data including the luminance signal data sequence and the color difference signal data sequence of 75 MBps, the first alternate frame portion is stored in the first memory, the second alternate frame portion is output. A second frame, and a third frame every third frame in a third memory, a frame stored in the first memory, and a frame stored in the second memory. And the frame portions stored in the third memory, respectively, at a frame rate of 24 Hz, 25 Hz or It is read out as forming 24-bit, 28-bit or 32-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal at 0 Hz, each of which has a word transmission rate of 74.25 MBps. First, second and third 24-bit, 28-bit or 32-bit word string data
The 12-bit, 14-bit, or 16-bit words forming the luminance signal data sequence and the chrominance signal data sequence included in the first 24-bit, 28-bit, or 32-bit word string data, respectively, are referred to as upper 10 bits. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into lower 2 bits, 4 bits or 6 bits, and a plurality of lower bits divided Second 20-bit word string data having a word transmission rate of 74.25 MBps based on 2 bits, 4 bits or 6 bits and auxiliary data is obtained, and the second 24 bit, 28 bit or 32 bit word string is obtained. Each of which forms a luminance signal data sequence and a chrominance signal data sequence included in each of the data. A 2-bit, 14-bit or 16-bit word is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a word transmission rate based on the plurality of divided upper 10 bits is set to 74.25 MBps. No. 3 20-bit word string data and fourth 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 data. Further, the 12-bit, 14-bit or 16-bit word forming each of the luminance signal data sequence and the chrominance signal data sequence included in the third 24-bit, 28-bit or 32-bit word string data, respectively, 10 bits and lower 2 bits, 4 bits or 6 bits The word transmission rate based on the fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the upper 10 bits, the plurality of divided lower 2 bits, 4 bits or 6 bits, and the auxiliary data is set as follows. A data processing unit for performing data processing for obtaining sixth 20-bit word string data of 74.25 MBps;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting the first to sixth serial data, and
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. A 30-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence, a first alternate frame portion in a first memory, and a second alternate frame portion in a second memory. And the third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the frame portion stored in the second memory, and the third frame portion are stored in the third memory. Each of the frame parts stored in the memory No. 3 is segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. A 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence which form a frame digital video signal is read out, each of which has a word transmission rate of 74.25 Mbps. , Second and third 30-bit word string data, and form a green primary color signal data series, a blue primary color signal data series and a red primary color signal data series included in the first 30-bit word string data, respectively. A first word group comprising a bit word comprising a 10-bit word forming the green primary color signal data sequence and a portion of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; The 10-bit word forming the auxiliary data sequence, the blue primary color signal data sequence and the red It is divided into a second word group including the other part of the 10-bit word forming each of the signal data sequences, and a word transmission rate based on the first and second word groups is set to 74.25 MBps. First and second 20-bit word string data are obtained, and each of the green primary color signal data series, blue primary color signal data series and red primary color signal data series included in the second 30-bit word string data is formed. A third word group comprising a bit word comprising a 10-bit word forming the green primary color signal data sequence and a portion of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; A 10-bit word forming an auxiliary data sequence and the above-described blue primary color signal data sequence and red primary color signal data sequence are formed. The third and fourth 20 bits that are assigned to a fourth word group including the other part of the 10-bit word and that have a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively. Word string data is obtained, and a 10-bit word forming each of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series included in the third 30-bit word string data is converted to the green primary color data. A fifth word group including a 10-bit word forming the signal data sequence, a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence, and 10 forming the auxiliary data sequence A bit word and another 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. Data processing for obtaining fifth and sixth 20-bit word string data at a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively. A data processing unit to be applied;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting the first to sixth serial data, and
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. A 36-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence, a first alternate frame portion in a first memory, and a second alternate frame portion in a second memory. Further, a third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the frame portion stored in the second memory, and the third frame portion are stored in the third memory. Each of the frame parts stored in the memory of No. 3 is segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. The first is read out as forming 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a frame digital video signal, each of which has a word transmission rate of 74.25 MBps. , Second and third 36-bit word sequence data, and form the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence respectively included in the first 36-bit word sequence data 12 The bit word is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and each of the blue primary color signal data sequence and the red primary color signal data sequence are divided. A word transmission rate of 74.25 Mbps based on a part of a plurality of upper 10 bits The first 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, the green primary color signal data sequence, and the blue primary color Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the signal data sequence and the plurality of lower 2 bits divided from the red primary color signal data sequence; The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the column data is divided into upper 10 bits and lower 2 bits, and the green primary color signal data sequence is divided. From the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. And a third 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits thus obtained, and each of the blue primary color signal data series and the red primary color signal data series. The word transmission rate based on the other part of the plurality of upper 10 bits and the plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. A fourth 20-bit word string data of 25 MBps is obtained, and further a green primary color signal data series, a blue primary color signal data series and a red primary color signal data series included in the third 36-bit word string data are formed. The 12-bit word to be divided into upper 10 bits and lower 2 bits, and the multiple A fifth 20-bit word having a word transmission rate of 74.25 MBps based on the upper 10 bits of the data and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence Column data, another part of the upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal A data processing unit for performing data processing for obtaining sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting the first to sixth serial data, and
A data transmission device comprising: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. In the 30-bit parallel data including the data sequence and the red primary color signal data sequence, the first every third frame portion is stored in the first memory, the second every third frame portion is stored in the second memory, and the third every third frame portion is stored in the second memory. The third frame portion is stored in a third memory, and the fourth third frame portion is stored in a fourth memory. The frame portion stored in the first memory and the second frame portion are stored in the third memory. Each of the frame part stored in the memory, the frame part stored in the third memory, and the frame part stored in the fourth memory is set to a frame rate. It is read as forming 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a segmented frame digital video signal at 0 Hz. First, second, third, and fourth 30-bit word string data of 25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the first 30-bit word string data are obtained. A 10-bit word forming each of the data sequences is defined as a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. A first group of words including the 10-bit words forming the auxiliary data sequence A word based on the first and second word groups, respectively, divided into a second word group including the other part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; First and second 20-bit word string data having a transmission rate of 74.25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data included in the second 30-bit word string data are obtained. The 10-bit words forming each of the sequences include a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit words forming each of the blue primary color signal data sequence and the red primary color signal data sequence. A third word group, a 10-bit word forming an auxiliary data sequence, the blue primary color signal data sequence and the red primary color data sequence; The color signal data sequence is divided into a fourth word group including another part of the 10-bit word forming each of the 10-bit words, and a word transmission rate based on the third and fourth word groups is set to 74.25 MBps. And the third and fourth 20-bit word string data to form a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series included in the third 30-bit word string data. A fifth word group comprising a bit word comprising a 10-bit word forming the green primary color signal data sequence and a portion of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; A 10-bit word forming an auxiliary data sequence and the above-described blue primary color signal data sequence and red primary color signal data sequence are formed. Fifth and sixth 20-bit words having a word transmission rate of 74.25 MBps based on the fifth word group and the sixth word group including the other part of the 0-bit word. Word string data is obtained, and further, a 10-bit word forming each of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series included in the fourth 30-bit word string data is converted into the green primary color. A seventh word group including a 10-bit word forming the signal data sequence, a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence, and 10 forming the auxiliary data sequence The other of the bit word and the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. Data processing is performed to obtain seventh and eighth 20-bit word string data at a word transmission rate of 74.25 MBps based on the seventh and eighth word groups, respectively. Alms,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A data transmission unit for transmitting the first to eighth serial data for transmission,
A data transmission device comprising: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 297 MBps. In the 36-bit parallel data including the data sequence and the red primary color signal data sequence, the first every third frame portion is stored in the first memory, the second every third frame portion is stored in the second memory, and the third Are stored in a third memory, and the fourth every third frame is stored in a fourth memory. The frame stored in the first memory and the second frame are stored in the third memory. Each of the frame part stored in the memory, the frame part stored in the third memory, and the frame part stored in the fourth memory is converted to a frame rate. It is read out as forming 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a 30 Hz segmented frame digital video signal, and each of them has a word transmission rate of 74. First, second, third, and fourth 36-bit word string data of 25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the first 36-bit word string data are obtained. A 12-bit word forming each of the data series is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data series, the blue primary color signal data series, and the red primary color signal. A part of a plurality of upper 10 bits divided from each of the data series; First 20-bit word string data having a transmission rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and Second 20-bit word string data having a word transmission rate of 74.25 MBps is obtained based on a plurality of lower two bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A plurality of upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data sequence Third 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the primary color signal data series, the blue primary color signal data series and the red primary color Another part of the plurality of upper 10 bits divided from each of the signal data sequences and the lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. And a fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the third 36-bit word string data. The 12-bit word forming each of the data sequences is divided into upper 10 bits and lower 2 bits, A word transmission rate of 74.25 Mbps based on a plurality of upper 10 bits divided from the data sequence and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fifth 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal data sequence A sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the primary color signal data sequence and a plurality of lower 2 bits divided from the red primary color signal data sequence is obtained. The husband of the green primary color signal data sequence, blue primary color signal data sequence and red primary color signal data sequence included in the 36-bit word string data Is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data sequence and the red primary color signal data sequence, respectively. And a seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from the above, and a blue primary color signal data sequence and a red primary color signal data sequence. The word transmission rate based on another part of the plurality of upper 10 bits divided and the plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence is determined. A data processing unit for performing data processing to obtain eighth 20-bit word string data having 74.25 MBps;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A data transmission unit for transmitting the first to eighth serial data for transmission,
A data transmission device comprising: A luminance signal data sequence and a chrominance signal each having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. In the 20-bit parallel data including the data series, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory. Each of the frame part stored in the memory and the frame part stored in the second memory is composed of 20 bits including a luminance signal data sequence and a chrominance signal data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. Read as forming parallel data, each having a word transmission rate of 74 A data processing unit for performing first and second data processing to obtain a 20-bit word sequence data to 25 Mbps,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A data transmission unit for transmitting the first and second serial data for transmission;
A data transmission device comprising: Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 20-bit parallel data including a sequence and a color difference signal data sequence, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion to a third memory. Are stored in the third memory, and the frame part stored in the first memory, the frame part stored in the second memory, and the frame stored in the third memory are stored. Each of the sections is defined as a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz. Data that is read as forming 20-bit parallel data including a signal data sequence and a color difference signal data sequence to obtain first, second, and third 20-bit word string data each having a word transmission rate of 74.25 MBps. A data processing unit for performing processing,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A data transmission unit for transmitting the first, second, and third serial data for transmission;
A data transmission device comprising: A luminance signal data sequence and a chrominance signal data sequence each having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. In the 20-bit parallel data, the first every third frame portion in the first memory, the second every third frame portion in the second memory, and the third every third frame portion. A third memory, and a fourth every third frame portion stored in the fourth memory; a frame portion stored in the first memory; a frame portion stored in the second memory; Each of the frame part stored in the third memory and the frame part stored in the fourth memory is a segmented frame having a frame rate of 30 Hz. It is read out as forming 20-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence that form a digital video signal, and each of the first, second, third, and fourth signals has a word transmission rate of 74.25 MBps. A data processing unit for performing data processing for obtaining 20-bit word string data of
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, blue In the 30-bit parallel data including the primary color signal data sequence and the red primary color signal data sequence, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. And a frame part stored in the first memory and a frame part stored in the second memory, each of which is a green primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. , 30-bit parallel data including the blue primary color signal data sequence and the red primary color signal data sequence , And obtains first and second 30-bit word string data each having a word transmission rate of 74.25 MBps. The green primary color signal data contained in the first 30-bit word string data is obtained. A 10-bit word forming each of a series, a blue primary color signal data series and a red primary color signal data series is formed, and a 10-bit word forming a green primary color signal data series and each of a blue primary color signal data series and a red primary color signal data series are formed. A first word group including a part of the 10-bit word to be formed, and another 10-bit word forming the auxiliary data sequence and another 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. And a second word group including a first word group and a second word group based on the first and second word groups. First and second 20-bit word sequence data having a word transmission rate of 74.25 MBps are obtained, and a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color sequence included in the second 30-bit word sequence data are obtained. The 10-bit word forming each of the signal data sequences includes the 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. A third word group and a fourth word group including a 10-bit word forming the auxiliary data sequence and another part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. And a word transmission rate of 74.25M based on the third and fourth word groups, respectively. A data processing unit for performing data processing for obtaining third and fourth 20-bit word string data of Bps;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps, blue In the 36-bit parallel data including the primary color signal data sequence and the red primary color signal data sequence, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory. And a frame part stored in the first memory and a frame part stored in the second memory, each of which is a green primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. , 36-bit parallel data including the blue primary color signal data sequence and the red primary color signal data sequence , The first and second 36-bit word string data each having a word transmission rate of 74.25 MBps are obtained, and the green primary color signal data included in the first 36-bit word string data is obtained. The 12-bit word forming each of the data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; Another plurality of upper 10 bits divided from each of the blue primary color signal data series and the red primary color signal data series And a second 20-bit word string having a word transmission rate of 74.25 MBps based on the first and second parts and a plurality of lower two bits divided from the green primary color signal data series, the blue primary color signal data series and the red primary color signal data series And a 12-bit word forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the second 36-bit word string data is converted into upper 10 bits and lower 10 bits. A plurality of upper 10 bits divided from the green primary color signal data sequence and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence; 20-bit word string data having a word transmission rate of 74.25 MBps based on Another part of the plurality of upper 10 bits divided from each of the color signal data sequence and the red primary color signal data sequence and the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence A data processing unit for performing data processing for obtaining fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of lower 2 bits;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. In the 24-bit, 28-bit or 32-bit parallel data including the signal data sequence and the color difference signal data sequence, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the first memory. The luminance stored in the second memory, and the luminance of each of the frame part stored in the first memory and the frame part stored in the second memory, which constitutes a segmented frame digital video signal having a frame rate of 60 Hz, 24 bits and 28 bits including signal data sequence and color difference signal data sequence Or read as forming 32-bit parallel data to obtain first and second 24-bit, 28-bit or 32-bit bit string data, each of which has a word transmission rate of 74.25 MBps, The 12-bit, 14-bit, or 16-bit words forming the luminance signal data sequence and the chrominance signal data sequence included in the 24-bit, 28-bit, or 32-bit word string data, respectively, are divided into upper 10 bits and lower 2 bits. First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided into 4 bits or 6 bits, and a plurality of lower 2 bits, 4 A word transmission rate of 74.25 based on bits or 6 bits and auxiliary data. Bps and second 20-bit word string data, and forming the luminance signal data series and the chrominance signal data series included in the second 24-bit, 28-bit or 32-bit word string data, respectively. A 12-bit, 14-bit or 16-bit word is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a word transmission rate based on the plurality of divided upper 10 bits is set to 74.25 MBps. 3 20-bit word string data and fourth 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 data. A data processing unit for performing data processing;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmission unit for transmitting the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A frame rate is set to 72 Hz, 75 Hz or 90 Hz, and a digital video signal having 720 effective lines in each frame is formed. Each has a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 222. In the 24-bit, 28-bit or 32-bit parallel data including the luminance signal data sequence and the color difference signal data sequence of 75 MBps, the first alternate frame portion is stored in the first memory, the second alternate frame portion is output. A second frame, and a third frame every third frame in a third memory, a frame stored in the first memory, and a frame stored in the second memory. The frame rate stored in the third memory and the frame rate is set to 24 Hz, 25 Hz or 3 Hz. And read out as forming 24-bit, 28-bit, or 32-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence that constitute a segmented frame digital video signal having a frequency of 74.25 MBps. The first, second, and third 24-bit, 28-bit, or 32-bit word string data are obtained, and the luminance signal data sequence and chrominance included in the first 24-bit, 28-bit, or 32-bit word string data, respectively. Each 12-bit, 14-bit, or 16-bit word forming each of the signal data series is divided into upper 10 bits and lower 2 bits, 4 bits, or 6 bits, and a word is formed based on the divided plural upper 10 bits. First 20 video with a transmission rate of 74.25 MBps And the second 20-bit word string data having a word transmission rate of 74.25 MBps based on the divided plurality of lower 2 bits, 4 bits, or 6 bits and the auxiliary data. The 12-bit, 14-bit, or 16-bit word forming each of the luminance signal data sequence and the chrominance signal data sequence included in each of the 24-bit, 28-bit, or 32-bit word string data is divided into upper 10 bits and lower 2 bits. , 4 bits or 6 bits, a third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided upper 10 bits, and a plurality of divided lower 2 bits, A word transmission rate based on 4 bits or 6 bits and auxiliary data is set to 74.25 MBps. And the fourth 24 bit, 28 bit or 32 bit word string data and forming the luminance signal data sequence and the color difference signal data sequence respectively included in the third 24 bit, 28 bit or 32 bit word sequence data. A 12-bit, 14-bit or 16-bit word is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a word transmission rate based on the plurality of divided upper 10 bits is set to 74.25 MBps. 5 20-bit word string data and sixth 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 data. A data processing unit for performing data processing;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit that transmits the first, second, third, fourth, fifth, and sixth serial data to transmit the data;
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. A 30-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence, a first alternate frame portion in a first memory, and a second alternate frame portion in a second memory. And the third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the frame portion stored in the second memory, and the third frame portion are stored in the third memory. Each of the frame portions stored in the memory 3 is a segmented frame whose frame rate is 24 Hz, 25 Hz or 30 Hz. Read out as forming 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color signal data sequence which form a digital video signal, each of which has a word transmission rate of 74.25 MBps. 10-bit data for obtaining second and third 30-bit word sequence data and forming each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the first 30-bit word sequence data A first word group including a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; A 10-bit word forming the sequence, the blue primary color signal data sequence and the red primary color signal A second word group including the other part of the 10-bit word forming each of the data sequences is divided into a second word group and a word transmission rate of 74.25 MBps based on the first and second word groups, respectively. 1 and second 20-bit word string data, and 10 bits forming each of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series included in the second 30-bit word string data A word group comprising a 10-bit word forming the green primary color signal data sequence and a portion of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; The 10-bit word forming the data sequence and the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence, respectively. A third and a fourth 20-bit word having a word transmission rate of 74.25 MBps based on the third and fourth word groups, respectively, which is divided into a fourth word group including another part of the bit word; Column data, and furthermore, the 10-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence contained in the third 30-bit word sequence data is converted into the green primary color signal. A fifth word group including a 10-bit word forming a data sequence, a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence, and a 10-bit word forming an auxiliary data sequence A word and another part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. Data to be subjected to data processing for obtaining fifth and sixth 20-bit word string data at a word transmission rate of 74.25 MBps based on the fifth and sixth word groups, respectively, based on the fifth and sixth word groups. A processing unit;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit that transmits the first, second, third, fourth, fifth, and sixth serial data to transmit the data;
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. A 36-bit parallel data including a data sequence, a blue primary color signal data sequence and a red primary color signal data sequence, a first alternate frame portion in a first memory, and a second alternate frame portion in a second memory. Further, a third alternate frame portion is stored in the third memory, and the frame portion stored in the first memory, the frame portion stored in the second memory, and the third frame portion are stored in the third memory. Each of the frame parts stored in the memory No. 3 is segmented with a frame rate of 24 Hz, 25 Hz or 30 Hz. A first read is performed as forming 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a frame digital video signal, each of which has a word transmission rate of 74.25 Mbps. , Second and third 36-bit word sequence data, and form the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence respectively included in the first 36-bit word sequence data 12 The bit word is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and each of the blue primary color signal data sequence and the red primary color signal data sequence are divided. A word transmission rate based on a part of a plurality of upper 10 bits is 74.25 MBps. A first 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, the green primary color signal data sequence, and the blue primary color Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the signal data sequence and the plurality of lower 2 bits divided from the red primary color signal data sequence; The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the column data is divided into upper 10 bits and lower 2 bits, and the green primary color signal data sequence is divided. From the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. And a third 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of upper 10 bits, and each of the blue primary color signal data sequence and the red primary color signal data sequence. A word transmission rate of 74.25 Mbps based on another part of the plurality of upper 10 bits and the plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. , And further forms each of a green primary color signal data sequence, a blue primary color signal data sequence and a red primary color signal data sequence included in the third 36-bit word sequence data. The 12-bit word is divided into upper 10 bits and lower 2 bits, and a plurality of divisions are performed from the green primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the upper 10 bits and a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence And another part of the upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. A data processing unit for performing data processing for obtaining sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit that transmits the first, second, third, fourth, fifth, and sixth serial data to transmit the data;
A data transmission device comprising: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and 720 effective lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. In the 30-bit parallel data including the data sequence and the red primary color signal data sequence, the first every third frame portion is stored in the first memory, the second every third frame portion is stored in the second memory, and the third every third frame portion is stored in the second memory. The third frame portion is stored in a third memory, and the fourth frame portion is stored in a fourth memory, and the frame portion stored in the first memory and the second Each of the frame part stored in the memory, the frame part stored in the third memory, and the frame part stored in the fourth memory has a frame rate of 3 Hz, and read out as forming 30-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence, which form a segmented frame digital video signal. First, second, third, and fourth 30-bit word string data of 25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the first 30-bit word string data are obtained. A 10-bit word forming each of the data sequences is defined as a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. A first group of words including the 10-bit words forming the auxiliary data sequence The word is divided into a second word group including the other part of the 10-bit word forming each of the color primary color signal data sequence and the red primary color signal data sequence, and the words are based on the first and second word groups, respectively. First and second 20-bit word string data having a transmission rate of 74.25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data included in the second 30-bit word string data are obtained. The 10-bit words forming each of the sequences include a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit words forming each of the blue primary color signal data sequence and the red primary color signal data sequence. A third word group, a 10-bit word forming an auxiliary data sequence, the blue primary color signal data sequence and the red primary color It is divided into a fourth word group including the other part of the 10-bit word forming each of the signal data sequences, and a word transmission rate based on the third and fourth word groups is set to 74.25 MBps. 10-bit data for obtaining third and fourth 20-bit word string data and forming each of a green primary color signal data series, a blue primary color signal data series and a red primary color signal data series included in the third 30-bit word string data A fifth word group comprising a 10-bit word forming the green primary color signal data sequence and a portion of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence; A 10-bit word forming a data sequence and a blue primary color signal data sequence and a red primary color signal data sequence are formed. Fifth and sixth 20-bit words having a word transmission rate of 74.25 MBps based on the fifth word group and the sixth word group including the other part of the 0-bit word. Word string data is obtained, and further, a 10-bit word forming each of a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data series included in the fourth 30-bit word string data is converted into the green primary color. And a seventh word group including a part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence, and a 10-bit word forming the auxiliary data sequence. An eighth part including another part of the 10-bit word forming each of the blue primary color signal data sequence and the red primary color signal data sequence. Allocated to a word groups, based respectively on the word groups of the seventh and eighth, the seventh and the data processing unit that performs data processing to obtain a 20-bit word sequence data of the eighth to 74.25MBps word transmission rate,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A data transmitting unit that transmits the first, second, third, fourth, fifth, sixth, seventh, and eighth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 297 MBps. In the 36-bit parallel data including the data sequence and the red primary color signal data sequence, the first every third frame portion is stored in the first memory, the second every third frame portion is stored in the second memory, and the third every third frame portion is stored in the second memory. Are stored in a third memory, and the fourth every third frame is stored in a fourth memory. The frame stored in the first memory is stored in the third memory. Each of the frame part stored in the memory, the frame part stored in the third memory, and the frame part stored in the fourth memory is set to a frame rate. It is read as forming 36-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence that form a segmented frame digital video signal of 0 Hz. First, second, third, and fourth 36-bit word string data of 25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the first 36-bit word string data are obtained. A 12-bit word forming each of the data series is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data series, the blue primary color signal data series, and the red primary color signal. A word based on a part of a plurality of upper 10 bits divided from each of the data series. First 20-bit word string data having a transmission rate of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the primary color signal data sequence, the blue primary color signal data sequence, and the plurality of lower two bits divided from the red primary color signal data sequence; The 12-bit word forming each of the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence included in the second 36-bit word string data is divided into upper 10 bits and lower 2 bits. A plurality of upper 10 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Third 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the color signal data series, the blue primary color signal data series and the red primary color Another part of the plurality of upper 10 bits divided from each of the signal data sequences and the lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. And a fourth 20-bit word string data having a word transmission rate of 74.25 MBps, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the third 36-bit word string data. The 12-bit word forming each of the data sequences is divided into upper 10 bits and lower 2 bits, and A word transmission rate of 74.25 Mbps based on a plurality of upper 10 bits divided from the data sequence and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A fifth 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, the green primary color signal data sequence, and the blue primary color A sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the signal data sequence and the plurality of lower two bits divided from the red primary color signal data sequence is obtained. Each of a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence included in the bit word string data A 12-bit word to be formed is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data sequence and the red primary color signal data sequence, respectively. The seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the plurality of divided upper 10 bits and each of the blue primary color signal data sequence and the red primary color signal data sequence The word transmission rate is set to 74 based on another part of the plurality of upper 10 bits thus obtained and the plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence. A data processing unit for performing data processing for obtaining eighth 20-bit word string data of .25 MBps;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A data transmitting unit that transmits the first, second, third, fourth, fifth, sixth, seventh, and eighth serial data for transmission;
A data transmission device comprising: A luminance signal data sequence having a frame rate of 50 Hz or 60 Hz, a number of effective lines in each frame being 1080 lines, and a digital transmission signal having a quantization bit number of 10 bits and a word transmission rate of 148.5 MBps, 30-bit parallel data including a color difference signal data sequence and an additional information data sequence having a data format equivalent to that of the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory, and the first alternate frame portion and the second frame portion are stored in the first memory. Each of the frame portions stored in the memory 2 is set to a frame rate of 25 Hz or 30 Hz. and z is read out as forming 30-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence and a supplementary information data sequence that form a segmented frame digital video signal, each having a word transmission rate of 74.25 Mbps. First and second 30-bit word string data to be obtained, and a first transmission rate of 74.25 MBps based on a luminance signal data sequence and a chrominance signal data sequence included in the first 30-bit word string data. And a second 10-bit word string based on the additional information data sequence and the auxiliary 10-bit word string included in the first 30-bit word string data, the word transmission rate being 74.25 MBps. And the second 30-bit word string data. , The third 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data series and the chrominance signal data series, and the additional information data series included in the second 30-bit word string data. A data processing unit for performing data processing for forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the auxiliary 10-bit word string and
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmitting unit for transmitting the first to fourth serial data obtained from the first to fourth parallel / serial conversion units, respectively;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. , A blue primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. And storing the first alternate frame portion in the first memory and the second alternate frame portion in the second memory in the 40-bit parallel data including And the frame portion stored in the second memory, respectively. It is assumed to form 40-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence, which form a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. Reading, to obtain first and second 40-bit word string data each having a word transmission rate of 74.25 MBps, and a green primary color signal data sequence and a blue primary color signal data included in the first 40-bit word string data. A 10-bit word forming the green primary color signal data sequence and a 10-bit word forming the green primary color signal data sequence and a 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A first word that includes a portion of a word And a second word group including a 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. The first 20-bit word string data having a word transmission rate of 74.25 MBps based on the first word group, and the second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group. 10-bit data forming a 20-bit word string data and forming a green primary color signal data series, a blue primary color signal data series, a red primary color signal data series, and an additional information data series included in the second 40-bit word string data. The word is composed of a 10-bit word forming the green primary color signal data sequence and the blue primary color signal data. A third word group including a part of a 10-bit word forming a data sequence and a red primary color signal data sequence; a 10-bit word forming the additional information data sequence; and a blue primary color signal data sequence and a red primary color signal data. Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the third word group and divided into a fourth word group including another part of the 10-bit word forming the sequence. A data processing unit that performs data processing for forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fourth word group;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data transmitting unit for transmitting the first to fourth serial data obtained from the first to fourth parallel / serial conversion units, respectively;
A data transmission device comprising: Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 30-bit parallel data including a sequence and a chrominance signal data sequence, and an additional information data sequence having a data format equivalent to the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. The first alternate frame portion to the first memory, the second alternate frame portion to the second memory, and the third alternate frame portion to the third memory. And the frame portion stored in the first memory and the frame portion stored in the second memory Each of the frame portions stored in the third memory is converted into a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz, or 30 Hz. And read out as forming 30-bit parallel data including the first, second, and third 30-bit word string data each having a word transmission rate of 74.25 MBps. , A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a luminance signal data series and a chrominance signal data series, and an additional information data series included in the first 30-bit word string data. Word transmission rate of 7 based on the .25 MBps, and a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word sequence data. A fourth 20-bit word transmission rate of 74.25 MBps based on the third 20-bit word string data, the additional information data sequence included in the second 30-bit word string data, and the auxiliary 10-bit word string And a fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the color difference signal data sequence included in the third 30-bit word string data. , An additional information data sequence included in the third 30-bit word string data and an auxiliary 10-bit word sequence. A data processing unit for performing data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the data string;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting first to sixth serial data obtained from the first to sixth parallel / serial conversion units, respectively;
A data transmission device comprising: A digital video signal having a frame rate of 50 Hz or 60 Hz and an effective number of runs of 1080 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. Have the same data format as the above-mentioned luminance signal data sequence, the number of quantization bits is 12, 14, or 16 bits, and the word transmission rate is 148.5 MBps. A first alternate frame portion is stored in a first memory and a second alternate frame portion is stored in a second memory in 36-bit, 42-bit or 48-bit parallel data including an information data sequence. And the frame portion stored in the first memory. Each of the frame portions stored in the second memory includes a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence which form a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz. The first and second 36-bit, 42-bit or 48-bit word string data are read out as forming bit, 42-bit or 48-bit parallel data, each of which has a word transmission rate of 74.25 MBps. The 12-bit, 14-bit, or 16-bit word forming each of the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the 36-bit, 42-bit, or 48-bit word sequence data of 1 Bits, lower 2 bits, and 4 bits First 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the chrominance signal data sequence. A second 20-bit word string having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits, or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the chrominance signal data sequence. A third word transmission rate of 74.25 MBps based on data, a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the additional information data sequence. 20-bit word string data and the second 36 bits, 42 bits or 4 bits. The 12-bit, 14-bit or 16-bit words forming the luminance signal data sequence, the chrominance signal data sequence, and the additional information data sequence included in the 8-bit word string data are respectively composed of upper 10 bits, lower 2 bits, and 4 bits. Or fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data sequence and the chrominance signal data sequence; Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the color difference signal data sequence And a plurality of upper 10 bits and a plurality of upper bits divided from the additional information data sequence. Lower 2 bits, 4 based on bits or 6 bits and a plurality of auxiliary bit, a data processing unit that performs data processing to form the sixth 20-bit word sequence data to 74.25MBps word transmission rate,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting first to sixth serial data obtained from the first to sixth parallel / serial conversion units, respectively;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 50 Hz or 60 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. , A blue primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. Storing the first alternate frame portion in the first memory and storing the second alternate frame portion in the second memory in the 48-bit parallel data including And the frame portion stored in the second memory, respectively. It is assumed that 48-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence forming a segmented frame digital video signal having a frame rate of 25 Hz or 30 Hz is formed. Reading, first and second 48-bit word string data each having a word transmission rate of 74.25 MBps are obtained, and a green primary color signal data sequence and a blue primary color signal data included in the first 48-bit word string data are obtained. Each of the 12-bit words forming the sequence, the red primary color signal data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence; The blue primary color signal data series and the red primary color signal data series First 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each, and the blue primary color signal data series and the red primary color signal data series, respectively. And a plurality of lower two bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, and a plurality of auxiliary bits. Based on the second 20-bit word string data having a word transmission rate of 74.25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. , The third 48-bit word string data having a word transmission rate of 74.25 MBps, and the second 48-bit word string data. Each of the 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the code sequence data is divided into upper 10 bits and lower 2 bits, A word transmission rate based on a plurality of upper 10 bits divided from the green primary color signal data sequence and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 20-bit word string data having a value of 74.25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal A plurality of lower 2 bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, and A 20-bit word string data having a word transmission rate of 74.25 MBps based on the above information, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A data processing unit that performs data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting first to sixth serial data obtained from the first to sixth parallel / serial conversion units, respectively;
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. Additional information having a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. A 40-bit parallel data including a data sequence, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third The other frame part is stored in the third memory, and the frame part stored in the first memory is A green primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz, or 30 Hz, each of a frame portion stored in the second memory and a frame portion stored in the third memory. , 40-bit parallel data including the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence, each having a word transmission rate of 74.25 MBps. No. 3 10-bit word sequence data, and a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence included in the first 40-bit word sequence data Is a 10-bit word forming the green primary color signal data sequence. A first word group including a part of a 10-bit word forming a blue primary color signal data sequence and a red primary color signal data sequence; a 10-bit word forming the additional information data sequence; a blue primary color signal data sequence; A first 20-bit group is divided into a second word group including the other part of the 10-bit word forming the red primary color signal data sequence and having a word transmission rate of 74.25 MBps based on the first word group. Green word included in the second 40-bit word string data, forming bit word string data and second 20-bit word string data based on the second word group and having a word transmission rate of 74.25 MBps. Forming a primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence; A third word group including a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence; The tenth word forming the additional information data sequence and a fourth word group including another part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence; And a fourth 20-bit word string having a word transmission rate of 74.25 MBps based on the fourth word group and having a word transmission rate of 74.25 MBps. And a green primary color signal data sequence included in the third 40-bit word string data. A 10-bit word forming the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence is defined as a 10-bit word forming the green primary color signal data sequence and the blue primary color signal data sequence and the red primary color signal data sequence. A fifth word group including a part of the 10-bit word to be formed; a 10-bit word forming the additional information data sequence; and a 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. And a sixth word group including a part of the fifth word group, the fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth word group, and the sixth word group. 20-bit word string data with a word transmission rate of 74.25 MBps based on A data processing unit that performs data processing for forming a
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data transmission unit for transmitting first to sixth serial data obtained from the first to sixth parallel / serial conversion units, respectively;
A data transmission device comprising: A luminance signal data sequence and a chrominance signal data sequence each forming a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps And 30-bit parallel data having a data format equivalent to that of the luminance signal data series, an additional information data series having a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. Frame portion in the first memory, second every third frame portion in the second memory, third every third frame portion in the third memory, and fourth every third frame portion. Is stored in the fourth memory, and the frame part stored in the first memory and the frame part stored in the second memory are stored. Each of the frame part, the frame part stored in the third memory, and the frame part stored in the fourth memory is converted into a luminance signal data sequence and a chrominance signal forming a segmented frame digital video signal having a frame rate of 30 Hz. First, second, third and fourth 30-bit word strings read as forming 30-bit parallel data including a signal data sequence and an additional information data sequence, each having a word transmission rate of 74.25 MBps First 20-bit word string data having a word transmission rate of 74.25 MBps based on a luminance signal data sequence and a chrominance signal data sequence included in the first 30-bit word string data; Of the additional information data sequence included in the 30-bit word string data and the auxiliary 10-bit word string And a second 20-bit word string data having a word transmission rate of 74.25 MBps, based on the luminance signal data sequence and the chrominance signal data sequence included in the second 30-bit word string data. A word transmission rate of 74.25 MBps based on third 20-bit word string data having a rate of 74.25 MBps, an additional information data sequence included in the second 30-bit word string data, and an auxiliary 10-bit word string And a fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the third 30-bit word string data. And the additional information data included in the third 30-bit word string data. And the luminance signal data included in the fourth 30-bit word string data forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the data sequence and the auxiliary 10-bit word string data. Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on the sequence and the chrominance signal data sequence, an additional information data sequence included in the fourth 30-bit word string data, and an auxiliary 10-bit word string A data processing unit for performing data processing for forming an eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A data transmission unit for transmitting first to eighth serial data obtained from the first to eighth parallel / serial conversion units, respectively;
A data transmission device comprising: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 10 bits and a word transmission rate of 297 MBps. 40-bit parallel including a data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 297 MBps. In data, the first triad of frame parts is in the first memory, the second triad of frame parts is in the second memory, and the third triad of frame parts is in the third memory. , And a fourth every third frame portion is stored in a fourth memory, and a frame stored in the first memory is stored. Each of the frame part, the frame part stored in the second memory, the frame part stored in the third memory, and the frame part stored in the fourth memory are segmented with a frame rate of 30 Hz. It is read as forming 40-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence, which form a frame digital video signal, and each of them is read at a word transmission rate of 74. The first, second, third, and fourth 40-bit word string data of .25 MBps are obtained, and the green primary color signal data series, the blue primary color signal data series, and the red primary color included in the first 40-bit word string data are obtained. The 10-bit word forming the signal data sequence and the additional information data sequence is converted into the green primary color signal data sequence. A first word group including a 10-bit word to be formed and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence; a 10-bit word forming the additional information data sequence; A word transmission rate of 74.25 Mbps based on the first word group is divided into a second word group including a blue primary color signal data sequence and another part of the 10-bit word forming the red primary color signal data sequence. And a second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group, and forming the second 40-bit word string data. The green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence included in the column data And the 10-bit word forming the additional information data sequence includes the 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A fourth word group including a third word group, a 10-bit word forming the additional information data sequence, and another part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. And the third 20-bit word string data having a word transmission rate of 74.25 MBps based on the third word group and the word transmission rate of 74.25 MBps based on the fourth word group. The fourth 20-bit word string data is formed and included in the third 40-bit word string data. The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence are the 10-bit word forming the green primary color signal data sequence and the blue primary color signal data sequence. And a fifth word group including a part of the 10-bit word forming the red primary color signal data sequence, the 10-bit word forming the additional information data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth word group and divided into a sixth word group including another part of the 10-bit word to be formed; The word transmission rate based on the sixth word group is 74.25 MBps. And the 10-bit word sequence data forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the fourth 40-bit word sequence data. A seventh word group including a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence; The seventh word group is divided into an eighth word group including a 10-bit word forming a data sequence and another part of the 10-bit word forming a blue primary color signal data sequence and a red primary color signal data sequence. And a seventh 20-bit word string data with a word transmission rate of 74.25 MBps based on A data processing unit for performing data processing for forming eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on the eighth word group;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A data transmission unit for transmitting first to eighth serial data obtained from the first to eighth parallel / serial conversion units, respectively;
A data transmission device comprising: A frame rate is set to 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame is formed, and the number of quantization bits is set to 12, 14, or 16 bits, and the word transmission rate is set to 222. It has a luminance signal data sequence and a color difference signal data sequence of 75 MBps, a data format equivalent to the luminance signal data sequence, a quantization bit number of 12, 14, or 16 bits, and a word transmission rate of 222.75 MBps. The first alternate frame portion is stored in a first memory, and the second alternate frame portion is stored in a second memory. And the third alternate frame portion to the third And the frame portions stored in the first memory, the frame portion stored in the second memory, and the frame portion stored in the third memory are respectively frame rates of 24 Hz and 25 Hz. Alternatively, it is read out as forming 36-bit, 42-bit, or 48-bit parallel data including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence, which form a segmented frame digital video signal of 30 Hz, each of which is a word First, second and third 36-bit, 42-bit or 48-bit word string data having a transmission rate of 74.25 MBps are obtained, and the first 36-bit, 42-bit or 48-bit word string data included in the first 36-bit, 42-bit or 48-bit word string data is obtained. Luminance signal data sequence, chrominance signal data sequence and additional information data sequence Each 12-bit, 14-bit or 16-bit word forming each is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of divisions are made from the luminance signal data sequence and the chrominance signal data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on the upper 10 bits, and a plurality of lower 2 bits, 4 bits or 6 bits divided from the luminance signal data sequence and the color difference signal data sequence A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower 2 bits, 4 divided from the additional information data sequence. A word transmission rate of 74.25 based on bits or 6 bits and a plurality of auxiliary bits The second 20-bit word string data of MBps is formed, and the luminance signal data series, the chrominance signal data series, and the additional information data series included in the second 36-bit, 42-bit, or 48-bit word string data are formed. Each 12-bit, 14-bit or 16-bit word forming each is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of divisions are made from the luminance signal data sequence and the chrominance signal data sequence. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the upper 10 bits, and a plurality of lower 2 bits, 4 bits or 6 bits divided from the luminance signal data sequence and the color difference signal data sequence The word transmission rate is 74.25 MBps based on and a plurality of auxiliary bits. 5 based on 20-bit word string data and a plurality of upper 10 bits and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the additional information data sequence. And the sixth 20-bit word string data of 25 MBps, and the luminance signal data series, the chrominance signal data series and the additional information data series included in the third 36-bit, 42-bit or 48-bit word string data. Each 12-bit, 14-bit or 16-bit word forming each is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of divisions are made from the luminance signal data sequence and the chrominance signal data sequence. Seventh 20 bits based on the upper 10 bits and having a word transmission rate of 74.25 MBps An eighth word transmission rate of 74.25 MBps based on the word string data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the color difference signal data sequence. The word transmission rate is 74.25 Mbps based on the 20-bit word string data and a plurality of upper 10 bits and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the additional information data sequence. A data processing unit that performs data processing to form ninth 20-bit word string data
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A ninth parallel / serial converter that obtains ninth serial data based on the ninth 20-bit word string data,
A data transmission unit for transmitting the first to ninth serial data obtained from the first to ninth parallel / serial conversion units, respectively;
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 1080 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. Additional information that has a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. A 48-bit parallel data including a data series, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion to a second memory. The other frame part is stored in the third memory, and the frame part stored in the first memory is A green primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz, each of a frame portion stored in the second memory and a frame portion stored in the third memory. , 48-bit parallel data including a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence, each of which has a word transmission rate of 74.25 MBps. 3 of the 48-bit word string data, and 12 bits each forming the green primary color signal data series, blue primary color signal data series, red primary color signal data series and additional information data series included in the first 48-bit word string data. The word is divided into upper 10 bits and lower 2 bits, and The word transmission rate based on a plurality of upper 10 bits divided from the signal data sequence and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence is set to 74. First 20-bit word string data of 25 MBps, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data series and the red primary color signal data series, and the green primary color signal data series; A second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower two bits divided from the blue primary color signal data sequence and the red primary color signal data sequence and a plurality of auxiliary bits; Based on a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence, A third 20-bit word string data having a word transmission rate of 74.25 MBps, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal data included in the second 48-bit word string data. Each 12-bit word forming the sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data sequence. A fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the red primary color signal data sequence and the blue primary color signal data sequence; Another part of a plurality of upper 10 bits divided from each of the red primary color signal data series and the green primary color signal data 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the data sequence, the blue primary color signal data sequence and the red primary color signal data sequence and a plurality of auxiliary bits And sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. Each of the 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the third 48-bit word string data is defined as upper 10 bits. A plurality of upper 10 bits divided from the lower-order 2 bits and the green primary color signal data sequence; A seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the color primary color signal data sequence and the red primary color signal data sequence; Another part of the plurality of upper 10 bits divided from each of the primary color signal data sequence and the red primary color signal data sequence, and further divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits and a plurality of auxiliary bits, and a plurality of upper 10 bits and a plurality of upper bits divided from the additional information data sequence A ninth 20-bit code having a word transmission rate of 74.25 MBps based on the lower two bits of A data processing unit for performing data processing for forming word string data;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A ninth parallel / serial converter that obtains ninth serial data based on the ninth 20-bit word string data,
A data transmission unit for transmitting the first to ninth serial data obtained from the first to ninth parallel / serial conversion units, respectively;
A data transmission device comprising: A green primary color signal data sequence and a blue primary color signal which form a digital video signal having a frame rate of 120 Hz and an effective line number of 1080 lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 297 MBps. 48-bit parallel including a data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 297 MBps. In data, the first triad of frame parts is in the first memory, the second triad of frame parts is in the second memory, and the third triad of frame parts is in the third memory. , And a fourth every third frame portion is stored in a fourth memory, and a frame stored in the first memory is stored. Each of the frame part, the frame part stored in the second memory, the frame part stored in the third memory, and the frame part stored in the fourth memory are segmented with a frame rate of 30 Hz. It is read as forming 48-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, and a red primary color signal data sequence and an additional information data sequence, which form a frame digital video signal, and each of them has a word transmission rate of 74. First, second, third and fourth 48-bit word string data of .25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color included in the first 48-bit word string data are obtained. Each 12-bit word forming the signal data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits. A plurality of upper 10 bits divided from the green primary color signal data sequence and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 20-bit word string data having a word transmission rate of 74.25 MBps based on the above, and another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence And a second word transmission rate of 74.25 MBps based on the plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence, and the plurality of auxiliary bits. And a plurality of upper 10 bits and a plurality of lower 2 bits divided from the additional information data sequence. And a third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of auxiliary bits, and a green primary color signal data sequence and a blue primary color included in the second 48-bit word string data. Each 12-bit word forming the signal data sequence, the red primary color signal data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence. And fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. And a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. The word transmission rate is set to 74.25 Mbps based on a part, a plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence, and a plurality of auxiliary bits. A word transmission rate of 74.25 MBps based on the fifth 20-bit word string data and the plurality of upper 10 bits, the plurality of lower 2 bits, and the plurality of auxiliary bits divided from the additional information data sequence. And the 12-bit word sequence data forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the third 48-bit word sequence data. The bit word is divided into upper 10 bits and lower 2 bits, and is divided from the green primary color signal data sequence. A seventh twentieth example in which the word transmission rate is 74.25 MBps based on the upper 10 bits of the number and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. Bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal data sequence, the blue primary color signal data sequence, and the red Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the primary color signal data sequence and a plurality of auxiliary bits, and the additional information data sequence The word transmission rate based on the plurality of upper 10 bits, the plurality of lower 2 bits, and the plurality of auxiliary bits is 74.25. Ninth 20-bit word string data of MBps, and a green primary color signal data series, a blue primary color signal data series, a red primary color signal data series, and an additional information data series included in the fourth 48-bit word string data. Are divided into upper 10 bits and lower 2 bits, a plurality of upper 10 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence and the red primary color signal data sequence. And a tenth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. Another part of the plurality of upper 10 bits divided from each of them, the green primary color signal data series and the blue primary color signal data An eleventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the sequence and the red primary color signal data sequence and a plurality of auxiliary bits; Data to be subjected to data processing for forming twelfth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from A processing unit;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A ninth parallel / serial converter that obtains ninth serial data based on the ninth 20-bit word string data,
A tenth parallel / serial converter for obtaining tenth serial data based on the tenth 20-bit word string data,
An eleventh parallel / serial converter for obtaining eleventh serial data based on the eleventh 20-bit word string data,
A twelfth parallel / serial converter for obtaining twelfth serial data based on the twelfth 20-bit word string data,
A data transmission unit for transmitting the first to twelfth serial data obtained from the first to twelfth parallel / serial conversion units, respectively;
A data transmission device comprising: A luminance signal data sequence and a chrominance signal each having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. The 30-bit parallel data including a data sequence and an additional information data sequence having a data format equivalent to the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, includes The second alternate frame portion is stored in the first memory while the second alternate frame portion is stored in the second memory, and the frame portion stored in the first memory and the second Each of the frame parts stored in the memory is a segmented frame having a frame rate of 60 Hz. A first and a second read are performed to form 30-bit parallel data including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence that form a digital video signal, each of which has a word transmission rate of 74.25 MBps. The first 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the first 30-bit word string data And second 20-bit word string data having a word transmission rate of 74.25 MBps based on the additional information data sequence included in the first 30-bit word string data and the auxiliary 10-bit word string. , The luminance signal data sequence included in the second 30-bit word string data and Based on third 20-bit word sequence data having a word transmission rate of 74.25 MBps based on the color difference signal data sequence, the additional information data sequence included in the second 30-bit word sequence data, and the auxiliary 10-bit word sequence A data processing unit for performing data processing for forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data sending unit that sends the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps, blue A primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 148.5 MBps. In the 40-bit parallel data, the first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory, and is stored in the first memory. Each of the frame portion obtained and the frame portion stored in the second memory is set to a frame rate. The data is read out as forming 40-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence and an additional information data sequence, which form a segmented frame digital video signal of 0 Hz. First and second 40-bit word string data having a word transmission rate of 74.25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the first 40-bit word string data are obtained. The 10-bit word forming the data sequence and the additional information data sequence is a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. And a first word group including A second word group including a 10-bit word to be formed and another part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence, based on the first word group; First 20-bit word string data having a word transmission rate of 74.25 MBps and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group are formed. The 10-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the second 40-bit word sequence data are referred to as the green primary color signal data sequence. The 10-bit word to be formed and the blue primary color signal data sequence and the red primary color signal data sequence And a third word group including a part of a 10-bit word forming the additional information data sequence, a 10-bit word forming the additional information data sequence, and a 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. A third 20-bit word string data having a word transmission rate of 74.25 MBps based on the third word group and a fourth word group based on the third word group; A data processing unit for performing data processing for forming fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A data sending unit that sends the first, second, third, and fourth serial data for transmission;
A data transmission device comprising: Luminance signal data having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. 30-bit parallel data including a sequence and a chrominance signal data sequence, and an additional information data sequence having a data format equivalent to the luminance signal data sequence, a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. The first alternate frame portion to the first memory, the second alternate frame portion to the second memory, and the third alternate frame portion to the third memory. And a frame portion stored in the first memory and a frame portion stored in the second memory. Each of the frame portions stored in the third memory is converted into a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence that form a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz, or 30 Hz. And read out as forming 30-bit parallel data including the first, second, and third 30-bit word string data each having a word transmission rate of 74.25 MBps. , A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a luminance signal data series and a chrominance signal data series, and an additional information data series included in the first 30-bit word string data. The word transmission rate is 74 based on The second 20-bit word string data of 25 MBps is formed, and the word transmission rate is 74.25 MBps based on the luminance signal data sequence and the color difference signal data sequence included in the second 30-bit word string data. And a fourth 20-bit word having a word transmission rate of 74.25 MBps based on the 20-bit word string data of No. 3, the additional information data sequence included in the second 30-bit word string data, and the auxiliary 10-bit word string. And fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the luminance signal data sequence and the chrominance signal data sequence included in the third 30-bit word string data. Additional information data sequence and auxiliary 10-bit word included in the third 30-bit word string data A data processing unit for performing data processing for forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on the string;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data sending unit that sends the first, second, third, fourth, fifth, and sixth serial data for transmission;
A data transmission device comprising: A digital video signal having a frame rate of 120 Hz and an effective line number of 720 lines in each frame is formed, each having a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. Additional information data having a signal data sequence, a color difference signal data sequence, and a data format equivalent to the luminance signal data sequence, a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 148.5 MBps. The first alternate frame portion is stored in the first memory and the second alternate frame portion is stored in the second memory in the 36-bit, 42-bit or 48-bit parallel data including the sequence. The frame portion stored in the first memory and the second Each of the frame portions stored in the memory is composed of 36 bits, 42 bits, or 48 bits including a luminance signal data sequence, a color difference signal data sequence, and an additional information data sequence forming a segmented frame digital video signal having a frame rate of 60 Hz. The data is read as forming parallel data, and first and second 36-bit, 42-bit or 48-bit word string data each having a word transmission rate of 74.25 MBps are obtained. Alternatively, a 12-bit, 14-bit or 16-bit word forming each of a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence included in the 48-bit word string data is composed of upper 10 bits, lower 2 bits, and 4 bits Or it is divided into 6 bits and A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the signal data sequence and the chrominance signal data sequence, and the luminance signal data sequence and the chrominance signal data sequence. The second 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of divided lower 2 bits, 4 bits, or 6 bits and the plurality of auxiliary bits, and the above additional information data sequence And forming third 20-bit word string data having a word transmission rate of 74.25 MBps based on the plurality of upper 10 bits, the plurality of lower 2 bits, 4 bits or 6 bits, and the plurality of auxiliary bits, Brightness included in the second 36-bit, 42-bit or 48-bit word string data The 12-bit, 14-bit or 16-bit word forming each of the degree signal data sequence, the color difference signal data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits divided from the luminance signal data series and the chrominance signal data series, and the luminance signal data series and the chrominance signal data series A fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits, 4 bits, or 6 bits and a plurality of auxiliary bits, divided from the additional information data sequence Multiple upper 10 bits and multiple lower 2 bits, 4 bits or 6 bits And based on a plurality of auxiliary bit, a data processing unit that performs data processing to form the sixth 20-bit word sequence data to 74.25MBps word transmission rate,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data sending unit that sends the first, second, third, fourth, fifth, and sixth serial data for transmission;
A data transmission device comprising: A green primary color signal data sequence having a frame rate of 120 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits and a word transmission rate of 148.5 MBps, blue A primary color signal data sequence and a red primary color signal data sequence, and an additional information data sequence having a data format equivalent to that of the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 148.5 MBps. In the 48-bit parallel data, the first alternate frame portion is stored in the first memory, and the second alternate frame portion is stored in the second memory, and is stored in the first memory. Each of the frame portion obtained and the frame portion stored in the second memory is set to a frame rate. The data is read as forming 48-bit parallel data including a green primary color signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence, which form a segmented frame digital video signal at 0 Hz. First and second 48-bit word string data having a word transmission rate of 74.25 MBps are obtained, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the first 48-bit word string data are obtained. Each 12-bit word forming the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data. 10 and a plurality of upper 10 divided from each of the red primary color signal data sequence A first 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of the data and a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. A word transmission rate of 74 based on another part of the bits, a plurality of lower 2 bits divided from the green primary color signal data sequence, the blue primary color signal data sequence, and the red primary color signal data sequence, and a plurality of auxiliary bits. A word transmission rate of 74.25 MBps based on second 20-bit word string data of .25 MBps, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence , And a green primary color signal included in the second 48-bit word string data. Each of the 12-bit words forming the signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and is divided from the green primary color signal data sequence. A fourth word transmission rate of 74.25 MBps based on the plurality of upper 10 bits and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data series and the red primary color signal data series, the green primary color signal data series, the blue primary color signal data series, Word transmission rate based on a plurality of lower 2 bits divided from a red primary color signal data sequence and a plurality of auxiliary bits A word transmission rate of 74.25 MBps based on fifth 20-bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A data processing unit for performing data processing for forming sixth 20-bit word string data having a rate of 25 MBps;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data sending unit that sends the first, second, third, fourth, fifth, and sixth serial data for transmission;
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. Additional information that has a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, has a quantization bit number of 10 bits, and a word transmission rate of 222.75 MBps. A 40-bit parallel data including a data sequence, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third The other frame part is stored in the third memory, and the frame part stored in the first memory is A frame portion stored in the second memory and a frame portion stored in the third memory are respectively converted into a green primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz; The first, second, and third data are read out as forming 40-bit parallel data including the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence, each having a word transmission rate of 74.25 MBps. And the 10-bit words forming the green primary color signal data sequence, blue primary color signal data sequence, red primary color signal data sequence and additional information data sequence included in the first 40-bit word sequence data are obtained. And the 10-bit word forming the green primary color signal data sequence A first word group including a part of a 10-bit word forming a blue primary color signal data sequence and a red primary color signal data sequence; a 10-bit word forming the additional information data sequence; a blue primary color signal data sequence; A first 20-bit word having a word transmission rate of 74.25 MBps based on the first word group, which is divided into a second word group including another part of the 10-bit word forming the primary color signal data sequence; A green primary color included in the second 40-bit word string data which forms word string data and second 20-bit word string data having a word transmission rate of 74.25 MBps based on the second word group; Form a signal data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence A third word group including a 10-bit word forming the green primary color signal data sequence and a part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence; The fourth bit group including the 10-bit word forming the additional information data sequence and another part of the 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence; Third 20-bit word string data having a word transmission rate of 74.25 MBps based on the word group, and fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fourth word group And a green primary color signal data sequence included in the third 40-bit word string data, The 10-bit word forming the color primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence is defined as the 10-bit word forming the green primary color signal data sequence and the blue primary color signal data sequence and the red primary color signal data sequence. A fifth word group including a part of the 10-bit word to be formed; a 10-bit word forming the additional information data sequence; and a 10-bit word forming the blue primary color signal data sequence and the red primary color signal data sequence. And a sixth word group including a part of the fifth word group, the fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on the fifth word group, and the sixth word group. And a sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on A data processing unit that performs data processing for forming,
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth wial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A data sending unit that sends the first, second, third, fourth, fifth, and sixth serial data for transmission;
A data transmission device comprising: A frame rate is set to 72 Hz, 75 Hz or 90 Hz, and a digital video signal having 720 effective lines in each frame is formed. Each has a quantization bit number of 12, 14, or 16 bits and a word transmission rate of 222. It has a luminance signal data sequence and a color difference signal data sequence of 75 MBps, a data format equivalent to the luminance signal data sequence, a quantization bit number of 12, 14, or 16 bits, and a word transmission rate of 222.75 MBps. The first alternate frame portion is stored in a first memory, and the second alternate frame portion is stored in a second memory. And the third alternate frame portion in the third memo And the frame part stored in the first memory, the frame part stored in the second memory, and the frame part stored in the third memory, respectively, at a frame rate of 24 Hz, 25 Hz or It is read out as forming 36-bit, 42-bit or 48-bit parallel data including a luminance signal data sequence and a chrominance signal data sequence and a supplementary information data sequence which constitute a 30 Hz segmented frame digital video signal, and each is transmitted in words. First, second and third 36-bit, 42-bit or 48-bit word string data having a rate of 74.25 MBps are obtained, and the luminance signal included in the first 36-bit, 42-bit or 48-bit word string data is obtained. Data sequence, color difference signal data sequence and additional information data sequence respectively Each 12-bit, 14-bit or 16-bit word to be formed is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of upper 10 bits divided from the luminance signal data sequence and the chrominance signal data sequence. First 20-bit word string data having a word transmission rate of 74.25 MBps based on bits, and a plurality of lower 2 bits, 4 bits or 6 bits divided from the luminance signal data sequence and the chrominance signal data sequence. Second 20-bit word string data having a word transmission rate of 74.25 MBps based on the auxiliary bits of the above, and a plurality of upper 10 bits and a plurality of lower 2 bits, 4 bits or A word transmission rate of 74.25 MBp based on 6 bits and a plurality of auxiliary bits s, a third 20-bit word string data, and a luminance signal data sequence, a chrominance signal data sequence, and an additional information data sequence included in the second 36-bit, 42-bit, or 48-bit word sequence data, respectively. , Each 12-bit, 14-bit or 16-bit word is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and a plurality of upper bits divided from the luminance signal data sequence and the chrominance signal data sequence. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on 10 bits, and a plurality of lower 2 bits, 4 bits or 6 bits divided from the luminance signal data sequence and the chrominance signal data sequence. A fifth 20th word transmission rate of 74.25 MBps based on the plurality of auxiliary bits; A word transmission rate of 74.25 MBps based on the set word string data and a plurality of upper 10 bits and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the additional information data sequence. 6, 20-bit word string data, and a luminance signal data series, a chrominance signal data series, and an additional information data series included in the third 36-bit, 42-bit, or 48-bit word string data on the earth's soil. , Each 12-bit, 14-bit or 16-bit word is divided into upper 10 bits and lower 2 bits, 4 bits or 6 bits, and divided into a plurality of upper 10 bits divided from the luminance signal data sequence and the chrominance signal data sequence. And a seventh 20-bit word string data with a word transmission rate of 74.25 MBps. An eighth twentieth example in which the word transmission rate is set to 74.25 MBps based on data and a plurality of lower 2 bits, 4 bits or 6 bits and a plurality of auxiliary bits divided from the luminance signal data sequence and the color difference signal data sequence. The word transmission rate is set to 74.25 MBps based on the bit word string data, a plurality of upper 10 bits, a plurality of lower 2 bits, 4 bits or 6 bits, and a plurality of auxiliary bits divided from the additional information data sequence. A data processing unit for performing data processing for forming ninth 20-bit word string data;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A ninth parallel / serial converter that obtains ninth serial data based on the ninth 20-bit word string data,
A data transmission unit for transmitting the first, second, third, fourth, fifth, sixth, seventh, eighth, and ninth serial data to transmit the data;
A data transmission device comprising: A green primary color signal having a frame rate of 72 Hz, 75 Hz or 90 Hz, a digital video signal having 720 effective lines in each frame, each having a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. Additional information that has a data sequence, a blue primary color signal data sequence, a red primary color signal data sequence, and a data format equivalent to the green primary color signal data sequence, a quantization bit number of 12 bits, and a word transmission rate of 222.75 MBps. A 48-bit parallel data including a data series, a first alternate frame portion to a first memory, a second alternate frame portion to a second memory, and a third alternate frame portion to a second memory. The other frame part is stored in the third memory, and the frame part stored in the first memory is A frame portion stored in the second memory and a frame portion stored in the third memory are respectively converted into a green primary color signal data sequence forming a segmented frame digital video signal having a frame rate of 24 Hz, 25 Hz or 30 Hz; The first, second, and third data are read out as forming 48-bit parallel data including a blue primary color signal data sequence, a red primary color signal data sequence, and an additional information data sequence, each having a word transmission rate of 74.25 MBps. And the 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence and the additional information data sequence included in the first 48-bit word sequence data. Is divided into upper 10 bits and lower 2 bits. A word transmission rate of 74.25 Mbps based on a plurality of upper 10 bits divided from the data sequence and a part of the plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence. The first 20-bit word string data, another part of a plurality of upper 10 bits divided from each of the blue primary color signal data sequence and the red primary color signal data sequence, and the green primary color signal data sequence Second 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the primary color signal data sequence and the red primary color signal data sequence and a plurality of auxiliary bits; A W based on a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the information data sequence. And third primary 20-bit word string data having a code transmission rate of 74.25 MBps, and a green primary color signal data series, a blue primary color signal data series, and a red primary color signal included in the second 48-bit word string data. Each of the 12-bit words forming the data sequence and the additional information data sequence is divided into upper 10 bits and lower 2 bits, and a plurality of upper 10 bits divided from the green primary color signal data sequence and the blue primary color signal data. Fourth 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the red primary color signal data sequence and the blue primary color signal data sequence And another part of a plurality of upper 10 bits divided from each of the red primary color signal data series and the green primary color signal data. Fifth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of lower 2 bits divided from the sequence, the blue primary color signal data sequence and the red primary color signal data sequence, and a plurality of auxiliary bits. And forming sixth 20-bit word string data having a word transmission rate of 74.25 MBps based on a plurality of upper 10 bits, a plurality of lower 2 bits, and a plurality of auxiliary bits divided from the additional information data sequence. The 12-bit words forming the green primary color signal data sequence, the blue primary color signal data sequence, the red primary color signal data sequence, and the additional information data sequence included in the third 48-bit word sequence data are divided into upper 10 bits and lower 10 bits. A plurality of upper 10 bits divided from the green primary color signal data sequence, Seventh 20-bit word string data having a word transmission rate of 74.25 MBps based on a part of a plurality of upper 10 bits divided from each of the primary color signal data sequence and the red primary color signal data sequence, and the blue primary color Another part of a plurality of upper 10 bits divided from each of the signal data sequence and the red primary color signal data sequence, and a plurality of the higher 10 bits divided from the green primary color signal data sequence, the blue primary color data sequence and the red primary color signal data sequence. Eighth 20-bit word string data having a word transmission rate of 74.25 MBps based on the lower 2 bits and the plurality of auxiliary bits, a plurality of upper 10 bits and a plurality of lower bits divided from the additional information data sequence A ninth 20-bit word having a word transmission rate of 74.25 MBps based on 2 bits and a plurality of auxiliary bits A data processing unit for performing data processing for forming data string data;
A first parallel / serial converter for obtaining first serial data based on the first 20-bit word string data;
A second parallel / serial converter for obtaining second serial data based on the second 20-bit word string data;
A third parallel / serial converter for obtaining third serial data based on the third 20-bit word string data;
A fourth parallel / serial converter for obtaining fourth serial data based on the fourth 20-bit word string data;
A fifth parallel / serial converter for obtaining fifth serial data based on the fifth 20-bit word string data;
A sixth parallel / serial converter for obtaining sixth serial data based on the sixth 20-bit word string data;
A seventh parallel / serial converter for obtaining seventh serial data based on the seventh 20-bit word string data,
An eighth parallel / serial converter for obtaining eighth serial data based on the eighth 20-bit word string data,
A ninth parallel / serial converter that obtains ninth serial data based on the ninth 20-bit word string data,
A data transmission unit for transmitting the first, second, third, fourth, fifth, sixth, seventh, eighth, and ninth serial data to transmit the data;
A data transmission device comprising:

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