JP3849459B2 - Transmission data information detection method and transmission data information detection apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a transmission data information detection method and a transmission data information detection apparatus in a transmission method for generating transmission packets by interleaving processing.
[0002]
[Prior art]
When transmitting a series of transmission data in a communication network, transmission data information indicating transmission data delimiters, adding a synchronization pattern to synchronize transmission and reception, and indicating transmission data attributes It is common to add and transmit. An example of transmission data information is transmission format information. Here, the transmission format is format information when, for example, video / audio (sound) is recorded on a tape or a disk. In addition, packet discard during transmission and error correction of bit errors are performed, and even when error correction is impossible, the packet discard and video error are distributed and distributed so that they are not part of the transmission data direction. It is well known to those skilled in the art to perform interleaving for the purpose of eliminating. That is, the synchronization pattern and the transmission data information are added to the transmission data by the processing of the application layer, the interleaving processing is performed in the lower layer, the transmission packet is generated, and the transmission packet is transmitted in the lower layer.
[0003]
As a conventional technology for performing interleave processing and error correction in a high-speed communication network, for example, in an ATM communication network using ATM (Asynchronous Transfer Mode) cells as transmission packets, error correction is performed in an adaptation layer, which is an upper layer of the ATM layer. There is a way. ATM adaptation layer type 1 (hereinafter referred to as AAL1) defined in ITU-T I363.1 performs interleaving processing and error correction using a long interleaver matrix. It is used for video transmission at a fixed data rate (CBR: Constant Bit Rate).
[0004]
FIG. 3 shows a schematic diagram of a transmission method using a long interleaver matrix. On the transmitting side, the transmission data is divided into 124 bytes, a 4-byte forward error correction code (FEC: Forward Error Correction in the figure) is added to the 124-byte transmission data, and writing is performed in the row direction indicated by the writing direction 500. Is repeated 47 times to generate a long interleaver matrix composed of 128 × 47 pieces of transmission data. Reading is performed sequentially for 47 bytes in the column direction indicated by the reading direction 501, and 1 byte including a sequence number in the read 47-byte transmission packet (SAR-PDU payload: Segmentation And Reassembly Protocol Data Unit described below). Header (SAR-PDU header described below) is added to 48 bytes of the effective data transmission portion in the ATM cell, and further, a 5-byte ATM header is added to transmit as an ATM cell. On the receiving side, reverse processing is performed to extract transmission data.
[0005]
FIG. 4 is a block diagram of an ATM cell. The SAR-PDU header is divided into SN field and SNP field. The SN field is further divided into a CSI bit and a sequence count field (SC). SC is 3 bits, and values (sequence numbers) from 0 to 7 are assigned in order in the order of reading from the long interleaver matrix. Further, the head of the long interleaver matrix is displayed by setting the CSI bit to 1 at the beginning of reading of the long interleaver matrix and 0 otherwise. That is, CSI is 1 and SC is 0 at the head of the long interleaver matrix. The SNP field is a parity for performing error correction on the SN field, and is composed of a 3-bit CRC field and CSI bit for the SN field, and a 1-bit even parity for the SC and CRC fields.
[0006]
By detecting the SAR-PDU header at the receiving terminal, the position of the SAR-PDU payload of the received cell on the long interleaver matrix can be specified. In other words, cells with CSI = 1 and SC = 0 are stored in the long interleaver matrix in the order of 0 to 7 with the sequence number from 0 to 7 as the head of the long interleaver matrix (the leftmost cell in FIG. 3) for reconfiguration. . The AAL1 is mainly used for CBR video signal transmission as an upper layer application than the AAL1. In video transmission, as already described, transmission data (video data) delimiter is added, a synchronization pattern is added to synchronize transmission and reception, and transmission data information indicating transmission data attributes such as format information is added. It is common to add and transmit.
[0007]
FIG. 5 is a schematic diagram showing a transmission format of transmission data. In FIG. 5, for example, a format in which transmission data information is added to the head of video data for one frame is used as transmission data, and video data is continuously transmitted by repeating this. S 0, S 1, S 2, S 3, S 4, S 5, S 6, and S 7 indicate frame data delimiters and form a synchronization pattern for video synchronization between transmission and reception. Further, F0, F1, F2, and F3 are data indicating the format of video data to be transmitted (hereinafter referred to as transmission format). FIG. 5 illustrates four transmission formats. Each transmission format has a different video data length for one frame. Transmission format 1 is 480165 bytes, transmission format 2 is 480642 bytes, transmission format 3 is 240165 bytes, Transmission format 4 is composed of 120165 bytes.
[0008]
FIG. 6 is a diagram showing details of transmission data information. The numbers in the figure are displayed in hexadecimal. The synchronization pattern is composed of the same fixed pattern from S0 to S7. F0, F1, F2, and F3 indicating the transmission format indicate the length of the transmission data. F0 is fixed at 83, and the actual length is indicated by F1, F2, and F3. This notation method conforms to ISO / IEC 8825-1, where the most significant bit of the first byte (F0) is 1, and the remaining lower 7 bits are the number of bytes (F1, 3 bytes of F2 and F3). Therefore, F0 is 10000011 in binary display and is fixed to 83 in hexadecimal display. The actual transmission data length is indicated by F1, F2 and F3, the transmission format 1 is 480165 bytes and 0753A5H (H indicates hexadecimal notation), the transmission format 2 is 480642 bytes and 075582H, and the transmission format 3 is The 240165 bytes are 03AA25H, and the transmission format 4 is 120165 bytes and 01D565H.
[0009]
The transmission data shown in FIG. 5 is transmitted after the processing of the long interleaver matrix of FIG. FIG. 7 is a schematic diagram showing the arrangement of transmission data information in the long interleaver matrix. The long interleaver matrix in FIG. 7 is the same as that in FIG. In FIG. 7, 700 is transmission data information. Since the transmission data is written in the row direction, the transmission data information is arranged in the row direction. Reading is performed in the column direction, and a SAR-PDU payload which is a transmission packet is generated. Accordingly, each byte data constituting the transmission data information is stored in a different ATM cell (transmission packet).
[0010]
FIG. 8 is a schematic diagram showing transmission data information in an ATM cell. Each byte data constituting the transmission data information is stored one byte at a time in successive ATM cells. The position from the beginning of each byte data in each ATM cell is the same. In other words, since transmission data is received in units of ATM cells on the receiving side, transmission data information is not continuously received in units of bytes in ATM cell level processing, that is, in the ATM layer. In FIG. 8, only the SAR-PDU payload is shown, and the SAR-PDU header and ATM cell header are not shown.
[0011]
In the conventional technique, the transmission packet transmitted as described above is subjected to the reverse processing (deinterleaving) of the long interleaver matrix processing on the transmission side and returned to the transmission data stream, that is, the state shown in FIG. Video synchronization is established by the synchronization pattern (S0 to S7) in the transmission data information, and then the transmission format is determined by detecting the transmission format information (F0 to F3). That is, the transmission data information is determined in the application layer higher than the processing layer of AAL1.
[0012]
[Problems to be solved by the invention]
However, the above conventional configuration has the following problems. Since deinterleaving is performed, the transmission format determination is delayed by the delay due to error correction processing and the processing time for storing received cells in the deinterleaving buffer.
[0013]
In addition, since the video synchronization establishment generally establishes a synchronization state by detecting two or more consecutive synchronization patterns at a predetermined interval (one video frame period shown in FIG. 5), at least one predetermined period ( In the case of the above example, one video frame period) is required.
[0014]
Furthermore, if the transmission format is changed during communication, the video synchronization process determines that the synchronization pattern has not been detected due to an error or the like, and protects synchronization at the interval of the previous transmission format for a certain period of time. After that, since the synchronization state is once canceled and video synchronization is established again with the new transmission format, it takes time to determine the new transmission format when changing the transmission format.
[0015]
Further problems arise when the adaptive clock method defined in ITU-T Recommendation I363.1 2.5.2.2.1 is used as a synchronization method between transmitting and receiving terminals. In the adaptive clock system, received data (ATM cells) is stored in a buffer memory in a certain amount with respect to CBR transmission data, data is read from the buffer memory in a certain amount according to the transmission format, and the data in the buffer memory is increased or decreased. This is a method of detecting a relative difference in system clock between transmitting and receiving terminals by monitoring and synchronizing the receiving terminal clock with the transmitting terminal clock by a PLL. Therefore, a delay corresponding to the buffer memory occurs, and there are the following problems.
[0016]
Reading from the buffer memory requires reading a certain amount in accordance with the transmission format. That is, when the transmitted transmission format is not fixed, the read amount is not fixed, and it must be read on the assumption that the transmission format of the received transmission data is one of the transmission formats. In this case, if the difference in the amount of data between the transmission format of the actually received transmission data and the assumed transmission format is significantly different, an underflow or overflow of the buffer memory occurs, establishing synchronization in the application layer and determining the transmission format. Previously, the continuity of received data broke down, and it was necessary to repeat the process from the beginning with the data amount of another transmission format until the transmission format was determined. That is, since a considerable amount of time is consumed until the transmission format is determined, there is a problem in that the quality of the application deteriorates at the initial stage of communication, for example, the video image is significantly disturbed.
[0017]
When the transmission data amount differs for each transmission format, there is a means for measuring the flow rate of the ATM cell as another means for detecting the transmission format. For example, the transmission data amount has a close value as in transmission format 1 and transmission format 2. In some cases, an error may occur in the flow rate measurement due to fluctuations in the network, resulting in erroneous detection of the transmission format. Further, since the flow rate detection is averaged over a predetermined period, there is a problem that it takes time to establish the transmission format.
[0018]
In view of the above problems, the present invention provides a transmission data information detection method and transmission data information detection device that enable early establishment of a transmission format by detecting transmission data information in a lower layer than interleaving processing and adaptive clock processing. The purpose is to provide.
[0019]
[Means for Solving the Problems]
In order to solve the above problems, the present invention provides a matrix in which the direction of transmission data is a row direction of a predetermined length N (N is a natural number) and the direction of transmission packets is a column direction of a predetermined length M (M is a natural number). A transmission data information detection method for detecting transmission data information for identifying the transmission data included in the transmission data and stored in the payload of the packet in the transmission method for performing interleaving and transmission in units of the transmission packets Because The transmission data is written in the row direction, and the transmission packet is read and generated in the column direction, so that the transmission data information is arranged in the row direction of the matrix, and in the same matrix When distributed among a plurality of the transmission packets, Detecting the leading data of the transmission data information from the transmission packet, storing the position on the matrix where the leading data is detected as the leading position; In the transmission packet located in the row direction from the head position on the matrix, the data in the row direction from the head position is sequentially compared with the transmission data information, When the predetermined transmission data information is detected, the transmission data information is output.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
The present invention performs interleaving in a matrix in which the direction of transmission data is a row direction of a predetermined length N (N is a natural number) and the direction of transmission packets is a column direction of a predetermined length M (M is a natural number), and the transmission packet unit A transmission data information detection method for detecting transmission data information included in the transmission data and specifying the transmission data in the transmission method in which transmission is performed using the transmission data, wherein the head data of the transmission data information is detected from the transmission packet Then, the position on the matrix where the head data is detected is stored as a head position, and the transmission packet and the transmission data information are sequentially compared in the row direction from the head position. When detected, the transmission data information is output, and the transmission data information detection method performs interleaving processing. By determining the transmission data information in the lower layer than the layer (pre-treated), it enables early transmit data information finalized.
[0021]
In the present embodiment, the present invention will be described by taking as an example the case of using the AAL1 long interleaver matrix method for interleaving in ATM transmission.
[0022]
FIG. 1 shows a configuration diagram of a transmission data information detection apparatus according to an embodiment of the present invention. In FIG. 1, 100 is a transmission packet input (ATM cell), 101 is a SAR-PDU header to monitor the position of the transmission packet input 100 on the matrix, column position information 104, row position information 105, transmission data information head detection signal. 106 is a transmission packet monitoring means for outputting 106, 102 is a head position storage means for storing the column position information 104 and row position information 105 at the timing when the transmission data information head detection signal 106 is outputted, 103 is a column position information 104, a row According to the position information 105 and the transmission data information head detection signal 106, the data of the transmission packet 100 is compared with the transmission data information, the transmission data information 108 is output when the transmission format matches, and the reset signal 107 is output when the mismatch occurs. Data information comparison means.
[0023]
The transmission packet 100 is a SAR-PDU payload using AAL1 for adaptation layer processing, and is input with a SAR-PDU header. The transmission packet monitoring means 101 specifies the position on the matrix of the row direction N = 124 and the column direction M = 47 shown in FIG. 7 by the SAR-PDU header shown in FIG. That is, with the transmission packet 100 with CSI = 1 and SC = 0 as the head of the row direction position of the matrix and the first byte of the SAR-PDU payload of the cell as the head of the column position information 104, the data in the SAR-PDU payload The column position information 104 is increased, and the row position information 105 is increased every time a new transmission packet is received. Information detected as described above is output as column position information 104 and row position information 105. Further, the transmission packet monitoring means 101 outputs a transmission data information head detection signal 106 when the head of transmission data information (S0 in FIG. 6) is detected from the data on the matrix.
[0024]
At the timing when the transmission data information head detection signal 106 is output, the column position information 104 and the row position information 105 are stored in the head position storage means 102 as positions on the head matrix of the transmission data information. At the same time, the transmission data information comparison means 103 sets a flag in which the head of the transmission data information is detected. Specifically, since the beginning of the transmission data information is “E3” common to all transmission formats as shown in S0 of FIG. 6, the column position information 104 in which “E3” is detected in the ATM cell (FIG. 7). ROW) and line position information 105 (COL in FIG. 7) are stored in the head position storage means 102.
[0025]
Hereinafter, a comparison process performed by the transmission data information comparison unit 103 will be described. When a new transmission packet 100 is input, the row position information 105 increases by 1, and it can be seen that the row position information 105 has advanced by 1 in the row direction of the matrix, so the column position information 104 is stored in the head position storage means 102. The transmission data information comparing means 103 compares the data of the transmission packet 100 with the second byte (S1 in FIG. 6) of the transmission data information at the timing coincident with the ROW of 7. S1 is “CB” common to all formats. Similarly, the transmission data information comparison unit 103 repeats the comparison between the transmission data information and the data of the transmission packet 100 in the row direction of the matrix at the column position ROW. Transmission data information is common to each transmission format up to S0, S1, S2, S3, S4, S5, S6, S7, and F0.
[0026]
At the comparison timing of F1, transmission format 1 or transmission format 2 (F1 = 07), transmission format 3 (F1 = 03), or transmission format 4 (F1 = 01) can be determined. At the comparison timing of F2, transmission format 1 (F1 = 53) and transmission format 2 (F1 = 55) can be determined. Transmission data 3 and transmission format 4 are F2 = AA when transmission data information is transmission format 3, respectively. In the case of format 4, it is compared whether F2 = D5. At the timing of F3, the transmission format 1 is compared with F3 = A5, the transmission format 2 is compared with F3 = 82, the transmission format 3 is compared with F3 = 25, In the case of transmission format 4, it is compared whether F3 = 65. When all the data from S0 to F3 matches one of the transmission formats, the transmission data information comparing means 103 outputs the transmission format as transmission data information 108.
[0027]
When a mismatch with the transmission format occurs during the comparison in the row direction, the flag in the transmission data information comparison unit 103 is reset and a reset signal 107 is issued, and the transmission packet monitoring unit 101 starts the transmission format head. (S0) starts to be detected from the beginning. The above configuration can be realized with a simple configuration using a counter, some memory, and a comparison circuit.
[0028]
FIG. 2 is a flowchart showing the processing flow of the present invention.
[0029]
First, after the processing is started, the transmission packet monitoring unit 101 inputs the data of the transmission packet input 100 (SAR-PDU payload) in byte units (step 201 in FIG. 2). The row position information 105 and the column position information 104 on the input data matrix are updated (step 202). The transmission data information comparison unit 103 determines whether or not the input transmission packet data matches the head of the transmission data information (S0: actual data is “E3”). If they do not match, the process returns to step 201. If they match, the process proceeds to step 204 (step 203). The head position storage means 102 stores the row position information 105 and the column position information 104 when the head of the transmission data information is detected (step 204). The transmission data information comparison means 103 sets a detection flag that the head of transmission data information has been detected (step 205).
[0030]
Next, the transmission data information comparison means 103 inputs the data of the transmission packet input 100 (SAR-PDU payload) in units of bytes (step 206), and the transmission packet monitoring means 101 inputs the row position information on the matrix of the input data. 105 and column position information 104 are updated (step 207). The transmission data information comparison means 103 determines whether or not it is a comparison position between the data of the transmission packet (SAR-PDU payload) and the transmission data information (step 208). That is, the column position information stored in step 204 is the same as the column position information updated in step 207, and the difference between the row position information stored in step 204 and the row position information updated in step 207 is If it is within the size in the row direction of the transmission data information, the process proceeds to step 209 as the comparison execution position. If it is not the comparison execution position, the process proceeds to 206 to input the next transmission packet data.
[0031]
The transmission data information comparison unit 103 determines whether or not the transmission packet input in step 206 matches the transmission data information. If the transmission packet does not match, the detection flag is reset in step 210 and the process returns to step 201. If yes, the process proceeds to step 211 (step 209). As a result of checking the transmission data information in the row direction, the transmission data information comparing means 103 determines whether or not all 12 bytes of the transmission data information length of the specific transmission format match. Returning, the comparison of the next data in the row direction is continued, and if all match, the transmission format indicated by the transmission data information is output in step 212 (step 211). The transmission data comparison means 103 determines whether or not the process is completed. If not, the detection flag is reset in step 214, and the process returns to step 201 to detect the next transmission data information (step 213).
[0032]
As described above, in the flow shown in FIG. 2, the head of the transmission data information is detected in step 203, and if the detection flag is set, the loop of step 206, step 207, step 208, step 209 and step 211 is performed. The transmission data information is sequentially checked in the row direction of the matrix, and when all of the transmission data information in one of the transmission formats shown in FIG. 6 matches, the transmission format indicated by the transmission data information is output by the ATM layer. The transmission format can be detected.
[0033]
As described above, in the present invention, it is possible to determine transmission data information at an early stage by determining transmission data information in a lower layer (processing before) than a layer that performs interleaving processing. Further, since transmission data information is obtained directly from the transmission packet, it goes without saying that it is a lower layer (processed before) than the layer that performs adaptive clock processing.
[0034]
In this embodiment, detection is performed using a combination of a synchronization pattern and format information as transmission data information. However, the present invention is effective even when only transmission format information is detected, and is excluded from the scope of the present invention. is not.
[0035]
In this embodiment, the combination of the synchronization pattern and the format information is continuous bytes as the transmission data information. However, the present invention is not limited to this, and the data constituting the transmission data information may be dispersed. In this case, it can be easily realized by changing the comparison position in the row direction between the transmission data information and the transmission packet in the transmission data information comparison means.
[0036]
In the present embodiment, the length of each transmission format is used as information for specifying the transmission format. However, the present invention is not limited to this, and the scope of the present invention is applicable as long as the transmission format can be identified, such as a code indicating the transmission format. It is not excluded from.
[0037]
In this embodiment, the transmission format is determined as an example, but it goes without saying that the present invention is effective as long as it is necessary to determine in the transmission data stream.
[0038]
Further, although the transmission data information (format information) is determined by one detection, a protection process may be performed so as to be determined by a plurality of detections. In this case, the processing may be performed by transmission data information comparison means. Alternatively, the protection process may be performed after the transmission data information is output by the transmission data information comparison unit.
[0039]
In this embodiment, only the first byte (S0) of the transmission data information is detected, and the detection state is set. However, the transmission packet is temporarily stored using a buffer, and a plurality of byte strings arranged in the row direction are stored. By checking, the beginning of transmission data information may be detected. In this case, transmission data information can be detected more accurately.
[0040]
In the embodiment of the present invention, the error correction method using the long interleaver matrix has been described as an example. However, performing error correction has nothing to do with the essence of the present invention, and even when error correction is not performed. It is not excluded from the scope of the invention. Further, the present invention is effective even when the size of the interleaving matrix is different, and is not excluded from the scope of the present invention.
[0041]
Further, in the embodiment of the present invention, the case where the transmission data information completely matches has been described as an example. However, even when data omission due to a part of the transmission data information error or transmission packet (ATM cell) discarding is allowed, It is not excluded from the scope of the invention. In this case, a counter for counting the number of errors and the like is provided by the transmission data information comparison means, and when the transmission data information is completely inspected, if the value is equal to or less than the allowable value, the transmission format may be detected.
[0042]
In the embodiment of the present invention, the synchronization pattern is a fixed pattern from S0 to S7. However, even when a plurality of synchronization patterns are used, it is not excluded from the scope of the present invention. Further, the length of the synchronization pattern and transmission format information is not limited. In that case, it can be easily realized by corresponding detection processing of the head data in the transmission packet monitoring means and comparison processing in the transmission data information comparison means.
[0043]
In the embodiment of the present invention, CBR video transmission is taken as an example, but the present invention can be applied to transmission of variable-length data, and is not excluded from the scope of the present invention.
[0044]
In this embodiment, video transmission is used as an example, but it is needless to say that the present invention is not limited to this.
[0045]
In this embodiment, the case where the AAL1 long interleaver matrix method is used as an interleave in the ATM transmission has been described as an example, but it is needless to say that the present invention is not limited to this.
Further, although the case of using a matrix of N = 124 and M = 47 is taken as an example, it goes without saying that the present invention is not limited to this.
[0046]
【The invention's effect】
As described above, the present invention has the following effects.
[0047]
Even in the case of interleaved transmission, transmission data information can be detected directly from the transmission packet before deinterleaving, and before the deinterleaving processing, adaptive clock processing and video synchronization establishment, regardless of the progress of the processing. Transmission data information can be determined quickly. Particularly in a high-quality communication network such as an ATM communication network, the establishment of packet discard (cell discard) and bit errors is extremely low, and transmission data information can be determined in the first few cells.
[0048]
Further, even when the transmission format changes, it can be quickly determined regardless of the processing.
[0049]
Even when the adaptive clock method is used for synchronization between the transmitting and receiving terminals, the transmission format is determined by the processing prior to storing in the adaptive clock buffer, so the adaptive clock functions effectively from the beginning of communication and synchronization between the transmitting and receiving terminals is possible. As a result, high-quality communication is possible without the application data failing.
[0050]
Also, by notifying the video synchronization processing unit of the transmission data information detected in the present invention, the interval of the synchronization pattern of the transmission data can be known in advance, so that the video synchronization circuit can be simplified.
[0051]
In addition, when the transmission format is changed, the present invention detects the format change and notifies the application layer processing such as video synchronization so that the transmission format after the change can be synchronized quickly. It becomes possible.
[0052]
In addition, when the transmission format is changed, notification to the processing unit of the application layer such as video synchronization makes it possible to quickly establish synchronization in the new transmission format.
[0053]
Furthermore, since the present invention is composed of a counter, a small storage circuit and a comparison circuit, it can be easily realized.
[0054]
As described above, data from the initial stage of communication is processed as valid data, and video synchronization can be established at an early stage, thereby providing high-quality communication from the initial stage of communication.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a transmission data information detection apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart showing a processing flow of a transmission data information detection method of the present invention.
FIG. 3 is a schematic diagram of a transmission method using a long interleaver matrix.
FIG. 4 is a block diagram of an ATM cell.
FIG. 5 is a schematic diagram showing a transmission format of transmission data.
FIG. 6 is a diagram showing details of transmission data information
FIG. 7 is a schematic diagram showing an arrangement of transmission data information in a long interleaver matrix.
FIG. 8 is a schematic diagram showing transmission data information in an ATM cell.
[Explanation of symbols]
100 Transmission packet input
101 Transmission packet monitoring means
102 Head position storage means
103 Transmission data information comparison means
104 Column position information
105 Line position information
106 Transmission data information head detection signal
107 Reset signal
108 Transmission data information

Claims (2)

Interleaving is performed in a matrix in which the direction of transmission data is a row direction of a predetermined length N (N is a natural number) and the direction of transmission packets is a column direction of a predetermined length M (M is a natural number), and transmission is performed in units of the transmission packets. In the transmission method, a transmission data information detection method for detecting transmission data information included in the transmission data and specifying the transmission data stored in a payload of the packet, wherein the transmission data is in the row direction. The transmission packet is written and read and generated in the column direction, whereby the transmission data information is arranged in the row direction of the matrix and distributed to a plurality of the transmission packets in the same matrix. If that, detects the head data of the transmission data information from said transmission packet, the leading data is detected the Storing the position on trix as the top position, in a transmission packet which is located in the row direction from the head position on the matrix, as compared to sequential the transmission data information data from the head position in the row direction, a predetermined A transmission data information detection method comprising: outputting the transmission data information when the transmission data information is detected. Interleaving is performed in a matrix in which the direction of transmission data is a row direction of a predetermined length N (N is a natural number) and the direction of transmission packets is a column direction of a predetermined length M (M is a natural number), and transmission is performed in units of the transmission packets. In the transmission method, a transmission data information detecting device for detecting transmission data information included in the transmission data and specifying the transmission data stored in a payload of the packet, the transmission data in the row direction The transmission packet is written and read and generated in the column direction, whereby the transmission data information is arranged in the row direction of the matrix and distributed to a plurality of the transmission packets in the same matrix. case, the row position information indicating the row direction position information in the matrix of each data in the transmission packet that, Column position information indicating direction position information is measured, transmission packet monitoring means for detecting the leading data of the transmission data information from the transmission packet, and the row position information and the column position information when the leading data is detected. In a transmission packet positioned in the row direction from the head position on the matrix , a head position storage unit that stores the head position as a head position, and sequentially compares the data in the row direction from the head position with the transmission data information A transmission data information detection apparatus comprising: transmission data information comparison means for outputting the transmission data information when the transmission data information is detected.

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