JP2004194234A - Method, device and system for transmitting data - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To minimize quality deterioration in communication even when a failure occurs in a line. <P>SOLUTION: A data transmitting device of a receiving side transmits a "stop-channel" message to a data transmitting device of a transmitting side (S3) when it is determined that an abnormal state exists in a certain line (S2), and the data transmitting device of the transmitting side excludes the line determined to have the abnormal state from a target of multilink communication (S4). The data transmitting device of the transmitting side uses the excluded line to continuously transmit data of a prescribed pattern (S5). The data transmitting device of the receiving side transmits a "restart-channel" message to the data transmitting device of the transmitting side (S8) when the data of the prescribed pattern received through the excluded line is determined to be normal (S7), and the data transmitting device of the transmitting side adds the excluded line to the target of the multilink communication (S9). <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a data transmission method, a data transmission device, and a data transmission system.
[0002]
[Prior art]
Conventionally, the H.32x series standardized by ITU-T (International Telecommunication Union-Telecommunication Standardization Division) has been known as a real-time video communication system such as a videophone. In this method, a plurality of input data, for example, video data and audio data are combined into one data for communication. Further, in the H.32x series, various extension models are defined, and in H.324 Annex H, one of them, a multi-path for transmitting one data by using a plurality of lines (channels). It specifies the link communication. The technology related to H.324 AnnexH is disclosed in Non-Patent Document 1, for example.
[0003]
With reference to FIG. 9, a functional configuration for processing video / audio data using H.324 Annex H will be described. The video encoding unit J1 encodes the input video using a video encoding method such as MPEG4. The audio encoding unit J2 encodes the input audio using an audio encoding method such as AMR. The communication control unit J3 controls a communication system such as a capability exchange between communication devices using a message specified by H.245. The multiplexing unit J4 adopts multiplexing processing based on the H223 system, and the mobile multilinking unit J5 that converts video / audio data into one multiplexed data uses the multilinking according to AnnexH for the converted multiplexed data. Processing is performed to divide the multiplexed data into a plurality.
[0004]
Next, the procedure of the multilink process in the mobile multilink unit J5 will be described with reference to FIG. First, the multiplexed data D1 is divided into SS (Sampling Size) bytes, and is sequentially distributed to a transmission line buffer. At the time when the SS byte data is accumulated in SPF (Sample Per Frame), the multilink frame MF is generated by adding a synchronization flag F, header information H, and CRC information of the header information to the data. The multi-link frame MF is transmitted to another terminal. As shown in FIG. 11, the header information H includes full header information H1 and compressed header information H2. The header information H includes the number (CT) of the line transmitting the multilink frame and the line having the largest CT value among the lines used as the transmission line for the multilink communication. Of the multilink frame, a number (SN) indicating the order of transmitting the multilink frame, and a flag (FT) indicating the type of the multilink frame. Further, the full header information H1 further includes the size of SS and SPF.
[0005]
Further, a procedure of a restoration process of the divided data performed in the mobile multilink unit J5 will be described. First, a synchronization flag is searched for each line, and if a synchronization flag is detected, the SN and L of the header information immediately after the synchronization flag are referred to. At this time, if the SN of each line is the same, it can be determined that the multilink frame is data transmitted at the same timing. If the L flag is in the "ON" state, it is known that the line is the last line. In this way, the data transmitted from each line can be synchronized, and the multiplexed data divided and transmitted by each line can be restored to the original multiplexed data. Since SN can only take a value from 0 to 7, synchronization may not be achieved depending on the magnitude of the transmission delay. For this reason, the values of SS and SPF are set in consideration of the communication environment and the buffer size on the receiving side. After being restored to the original multiplexed data, the data is divided into video data, audio data, and H.245 data according to the H.223 scheme, and each is decoded. Then, by simultaneously reproducing the decoded data, real-time video communication becomes possible.
[0006]
By the way, when performing a multi-link communication based on the above H.324 AnnexH, if a failure occurs on any line, the data transmitted by the failed line must be received normally. Therefore, there is a problem in that an error occurs in the transmission data combined on the receiving side. In addition, there is also a problem that, when a failure occurs in any one of the lines, a transmission delay occurs, and an error occurs in transmission data combined on the receiving side. Therefore, for the former problem, for example, in H.324 AnnexH, if it is found that there is an error in the header information received from a certain line, instead of this header information, it has normal header information By using the header information received from another line, data bodies received from a plurality of lines are combined. This is based on the fact that the header information of each line received at the same time generally has almost the same contents. For the latter problem, the effect of transmission delay can be eliminated to some extent by increasing the reception buffer.
[0007]
[Non-patent document 1]
"ITU-T Recommendation on CD-ROM", Disc-2, T-REC-H.324-200011-I! AnnH! MSW-E.zip, November 2000 (zip file) March 2000 (CD- ROM)
[Problems to be solved by the invention]
However, if an error occurs in the data body of the transmission data, data received from multiple lines can be combined using other header information, but the combined data contains errors. I will be. Further, when a delay exceeding the reception buffer occurs, data that should not be combined is combined, and the data cannot be decoded correctly. When such a situation occurs, decoding of transmission data including video / audio data that has been encoded with high efficiency becomes incomplete, and a failure occurs in reproduced video and audio. In particular, when a video coding method such as MPEG4 is used, prediction in the time direction is performed, so that an error due to incomplete decoding is propagated by the prediction, and the influence of a failure on the video continues for a long time. Cause it to do so. Therefore, if a failure occurs in any of the lines used for multilink communication, it is necessary to exclude the failed line from the target of the multilink communication in order to prevent deterioration in communication quality. is there.
[0008]
However, in the multilink communication based on H.324 Annex H, it is not possible to determine which of the multiple lines has failed, so in order to exclude the failed line, all the additional lines must be removed. It had to be disconnected and changed from multi-link communication using a plurality of lines to communication using a single line. For this reason, when a fault occurs in a line in the multilink communication, there is a problem that the quality of the communication is apt to be rapidly reduced.
[0009]
Therefore, the present invention provides a data transmission method, a data transmission device, and a data transmission system that can minimize a decrease in communication quality even when a line failure occurs, in order to solve the above-described problem. With the goal.
[0010]
[Means for Solving the Problems]
In the data transmission method according to the present invention, a transmission-side terminal divides data to be transmitted, distributes the divided data to a plurality of transmission paths, and transmits the divided data. A data transmission method for receiving data transmitted by being distributed to a path and combining the received data, wherein transmission / reception of data is controlled for each transmission path based on transmission results for each transmission path. And
[0011]
Further, the data transmission apparatus of the present invention includes: a dividing unit that divides data to be transmitted; a transmitting unit that distributes the data divided by the dividing unit to a plurality of transmission paths and transmits the data to an external terminal; Receiving means for receiving data distributed from a terminal located on a plurality of transmission paths and transmitting data, coupling means for coupling data received by the receiving means, and transmission results for each transmission path based on the coupled data. And transmission / reception control means for controlling transmission / reception of data for each transmission path based on the determination by the determination means.
[0012]
Furthermore, the data transmission system of the present invention is a data transmission system for transmitting and receiving data between a first data transmission device and a second data transmission device, wherein the first data transmission device is a transmission target. And a transmission unit for distributing the data divided by the division unit to a plurality of transmission paths and transmitting the divided data to the second data transmission device, wherein the second data transmission device comprises: Receiving means for receiving data distributed from a data transmission apparatus to a plurality of transmission paths, combining means for combining data received by the receiving means, and transmission for each transmission path based on the combined data. It is characterized by comprising a judgment means for judging the performance and a transmission / reception control means for controlling data transmission / reception for each transmission path based on the judgment by the judgment means.
[0013]
According to these inventions, transmission and reception of data can be controlled for each transmission path based on the transmission results for each transmission path. For example, even if a failure occurs in any one of the transmission paths, Data transmission and reception can be continuously performed on transmission paths other than the above, and deterioration in communication quality can be suppressed as much as possible.
[0014]
In the data transmission method of the present invention, a transmission-side terminal divides data to be transmitted, distributes the divided data to a plurality of transmission paths, and transmits the divided data to a plurality of transmission paths. A data transmission method for receiving data transmitted in a distributed manner and combining the received data, wherein transmission and reception of data are controlled for each transmission path based on a predetermined agreement.
[0015]
Further, the data transmission apparatus of the present invention includes: a dividing unit that divides data to be transmitted; a transmitting unit that distributes the data divided by the dividing unit to a plurality of transmission paths and transmits the data to an external terminal; Receiving means for receiving data distributed from a terminal located on a plurality of transmission paths and transmitting the data, coupling means for coupling the data received by the receiving means, and transmission and reception of data for each transmission path based on a predetermined agreement. And transmission / reception control means for controlling
[0016]
Furthermore, the data transmission system of the present invention is a data transmission system for transmitting and receiving data between a first data transmission device and a second data transmission device, wherein the first data transmission device is a transmission target. And a transmission unit for distributing the data divided by the division unit to a plurality of transmission paths and transmitting the divided data to the second data transmission device, wherein the second data transmission device includes: Receiving means for receiving data distributed from one data transmission device to a plurality of transmission paths, coupling means for coupling the data received by the reception means, and data for each transmission path based on a predetermined agreement. Transmission / reception control means for controlling transmission / reception of data.
[0017]
According to these inventions, since transmission and reception of data can be controlled for each transmission line based on a predetermined agreement, for example, there is a case where transmission inspection is performed on a part of a plurality of transmission lines. Also, data transmission / reception can be continuously performed using another transmission path, and a decrease in communication quality can be suppressed as much as possible.
[0018]
In the data transmission method of the present invention, it is possible to control transmission and reception of data for each of a plurality of transmission paths based on transmission results found by transmission inspection on some of the plurality of transmission paths performed according to a predetermined agreement. preferable. Further, in the data transmission device of the present invention, the transmission / reception control means performs data transmission for each of the plurality of transmission paths based on transmission results determined by transmission inspection on a part of the plurality of transmission paths performed according to a predetermined agreement. It is preferable to control the transmission and reception of data. Further, in the data transmission system according to the present invention, the transmission / reception control means transmits / receives data for each transmission path based on a transmission result determined by a transmission inspection on a part of the plurality of transmission paths performed according to a predetermined agreement. Is preferably controlled.
[0019]
According to these inventions, transmission and reception of data can be controlled for each transmission path based on transmission results determined by transmission inspection performed on a part of the transmission path according to a predetermined agreement. As a result, even if a failure in one of the transmission paths is found, data transmission / reception can be continuously performed on another transmission path, and a decrease in communication quality can be suppressed as much as possible. .
[0020]
In the data transmission method of the present invention, it is preferable that the transmission result is a frequency of occurrence of an abnormality for each transmission path or a transmission delay difference between each transmission path.
[0021]
In this way, transmission and reception of data can be controlled for each transmission path based on the frequency of occurrence of an abnormality for each transmission path or the transmission delay difference between each transmission path. Therefore, even if an abnormality occurs in any one of the transmission paths, data transmission and reception can be continuously performed on transmission paths other than the transmission path. Further, even when a delay occurs in any one of the transmission lines, the delay in the transmission line can be eliminated.
[0022]
In the data transmission method according to the present invention, the above-described control causes the reception-side terminal to transmit a signal indicating that the transmission path is abnormal to the transmission-side terminal. It is preferable to stop the transmission of data on the transmission path indicated as abnormal based on the signal indicating the existence.
[0023]
In this way, the transmission of data on the transmission path determined to be abnormal is stopped, so that even if an abnormality occurs on any of the transmission paths, transmission / reception of data is continued on transmission paths other than the transmission path concerned. You can do it.
[0024]
In the data transmission method of the present invention, the above-described control indicates that the receiving terminal restarts data transmission on the stopped transmission path based on the transmission results of the stopped transmission path. It is preferable that the signal is transmitted to the transmitting terminal, and the transmitting terminal restarts the data transmission on the stopped transmission path based on the signal indicating the restart.
[0025]
By doing so, the transmission of data on the transmission line that has been temporarily stopped is restarted, so that it is possible to recover a decrease in communication capability due to the stoppage of some transmission lines.
[0026]
In the data transmission method of the present invention, it is preferable that the above-described control disconnects the transmission path and causes data transmission and reception to be performed on a transmission path other than the disconnected transmission path.
[0027]
In this way, the transmission path that is determined to be abnormal is disconnected, so that even if an abnormality occurs in any one of the transmission paths, data transmission / reception can be continuously performed on transmission paths other than the transmission path concerned. Can be.
[0028]
In the data transmission method according to the present invention, it is preferable that, in the above-described control, after the transmission path is disconnected, a connection process of the disconnected transmission path is started.
[0029]
In this way, the transmission of data on the transmission line once disconnected is resumed, so that a decrease in communication capability due to disconnection of some transmission lines can be recovered.
[0030]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of an apparatus according to the present invention will be described with reference to the drawings. In each of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.
[0031]
[First Embodiment]
First, a first embodiment of the present invention will be described. FIG. 1 is a diagram illustrating a functional configuration of the data transmission device 1 according to the first embodiment. As shown in FIG. 1, the data transmission device 1 includes a data input / output unit 11, a multiplexing unit 12A, a demultiplexing unit 12B, a multilink frame configuration unit 13A, a multilink frame decoding unit 13B, a determination unit 14, , A line input / output unit 15. As such a data transmission device 1, for example, there is a multimedia communication terminal used for a video conference system, a video phone system, and the like. The data transmission device 1 according to the first embodiment employs H.324 AnnexH standardized by ITU-T.
[0032]
The data input / output unit 11 includes a video encoding unit 11Aa, a video decoding unit 11Ab, an audio encoding unit 11Ba, an audio decoding unit 11Bb, and a communication control unit 11C. The video encoding unit 11Aa employs ITU-T H.263 or ISO / IEC MPEG (Moving a Picture Experts Group) -4 as a video encoding method. Is encoded by MPEG-4. The video decoding unit 11Ab employs ITU-T H.263 or ISO / IEC MPEG-4 as a video encoding system, and decodes video data output from the data transmission device 1 using MPEG-4. I do. The audio encoding unit 11Ba employs ITU-T G.723.1 or AMR (Adaptive Multi-Rate) as an audio encoding method, and encodes audio data input to the data transmission device 1 by AMR. I do. The audio decoding unit 11Bb employs ITU-T G.723.1 or AMR as an audio encoding method, and decodes audio data output from the data transmission device 1 by AMR. By playing back the decoded video data and audio data at the same time, real-time video communication becomes possible.
[0033]
The communication control unit 11C includes a message generation unit 11CA, a message recognition unit 11CB, an H245 processing unit 11CC, and an SRP processing unit 11CD. The message generator 11CA generates various messages (signals) such as a “Stop-Channel” message, a “Restart-Channel” message, and a “Delay-Channel” message. Here, the "Stop-Channel" message includes a code indicating that the line (channel; transmission path) is abnormal, and the line number (CT) of the line in which the abnormality has been found. The “Restart-Channel” message includes a code indicating that the line has been recovered and the line number (CT) of the line that has been recovered. The “Delay-Channel” message includes a code indicating that a specific line is delayed, a line number (CT) of the line for which the delay is found, and a delay amount.
[0034]
The message recognition unit 11CB recognizes that the data received from another data transmission device includes a “Stop-Channel” message, a “Restart-Channel” message, a “Delay-Channel” message, and the like. , And notifies the line input / output unit 15 of the line number and the like included in the message.
[0035]
The H245 processing unit 11CC adopts ITU-T H.245, and various types of multimedia communication performed with the other data transmission device 1, such as line assignment processing and message exchange processing, for example. Perform processing. The SRP processing unit 11CD employs SRP (Simple Retransmission Protocol), which is a retransmission procedure protocol defined in H.324 of ITU-T, and includes NSRP (Numbered SRP) and CCSRL (Control Channel Segmentation and Reassembly Layer). The data is retransmitted at the time of the transmission error using the procedure.
[0036]
The multiplexing unit 12A employs ITU-T H.223 (or H.223 AnnexA or H.223 AnnexB), and converts the video data and audio data encoded by the data input / output unit 11 into one. The multiplexed data is multiplexed with data to generate multiplexed data, and the generated multiplexed data is transmitted to the multilink frame forming unit 13A. The demultiplexing unit 12B employs ITU-T H.223 (H.223 AnnexA or H.223 AnnexB), and converts the multiplexed data combined in the multilink frame decoding unit 13B into video data or video data. The data is separated into audio data and the like, and the separated video data and audio data are transmitted to the data input / output unit 11.
[0037]
The multilink frame forming unit 13A adopts H.324 AnnexH of ITU-T, and divides the multiplexed data multiplexed in the multiplexing unit 12A according to the number of communicable lines by the multilink communication. (Split processing). Further, the multilink frame decoding unit 13B combines data received from another data transmission device via a plurality of lines into one data to restore multiplexed data (combination processing). Details of the dividing process and the combining process will be described later.
[0038]
The determining unit 14 determines whether or not each line has an abnormality based on the header information included in the multilink frame received from another data transmission device. More specifically, for example, the frequency of determining that the header information has an error compared to the header information of another multilink frame, the frequency of occurrence of data indicating an abnormality included in the CRC information of the header information, and the like. Based on the transmission results, it is determined whether or not each line has an abnormality. Further, the determination unit 14 determines whether or not a transmission delay has occurred in each line based on the multilink frame of each line received from another data transmission device. More specifically, for example, based on transmission results such as a transmission delay difference between each line that is determined by a time when a multilink frame is received for each line, it is determined whether a transmission delay has occurred in each line. judge.
[0039]
The line input / output unit 15 performs control for excluding a specific line from the lines targeted for multilink communication and control for adding the line to the line. Further, the line input / output unit 15 controls to transmit data to be transmitted from the delayed line earlier than other lines by the amount of delay. Note that control may be performed such that data transmitted from a line other than the delayed line is delayed by a delay amount from the delayed line and transmitted.
[0040]
Note that the functional configuration of the data transmission device 1 is not limited to the configuration illustrated in FIG. For example, as a data transmission transmission device, a video encoding unit 11Aa, an audio encoding unit 11Ba, a communication control unit 11C, a multiplexing unit 12A, a multilink frame forming unit 13A, a determining unit 14, a line input / output unit 15 may be provided. Further, as a data transmission receiving device, a video decoding unit 11Ab, an audio decoding unit 11Bb, a communication control unit 11C, a separation unit 12B, a multilink frame decoding unit 13B, a determination unit 14, a line input / output unit 15, May be provided.
[0041]
Next, the above-described division processing of the multilink unit 13 will be described with reference to FIG. First, the multilink frame forming unit 13A divides the data D1 multiplexed in the multiplexing unit 12A into SS (Sampling Size) bytes. Next, the multilink frame forming unit 13A sequentially distributes the data divided in units of SS (Sampling Size) bytes to a plurality of transmission lines CH1 to CHn (n is a positive integer of 8 or less). When the SS byte data allocated to each of the transmission lines CH1 to CHn becomes SPF (Sample Per Frame), the multilink frame configuration unit 13A allocates the SPF data (SS bytes) allocated to the transmission line. As a set (hereinafter, referred to as a payload PL). Then, the multilink frame forming unit 13A generates one multilink frame MF by adding the synchronization flag F and the header information H corresponding to the payload PL. That is, the multilink frame MF includes the synchronization flag F, the header information H, and the payload PL including SS bytes × SPF. The multilink frame forming unit 13A transmits the generated multilink frame MF to another data transmission device via a transmission line corresponding to the multilink frame MF. By performing such a division process, it becomes possible to divide one piece of multiplexed data into a plurality of lines and transmit it.
[0042]
Here, FIG. 3 illustrates a conceptual diagram of the header information, and the header information will be described with reference to FIG. The header information H includes full header information H1 and compressed header information H2. In the first byte of the full header information H1, a line number (CT: Channel Tag) for transmitting the multilink frame MF including the full header information H1 and a number (SN: Serial) indicating the order in which the multilink frame MF is transmitted Number), a flag (L: Last) indicating that the multilink frame MF is transmitted by the line having the largest CT value among the lines used as the transmission lines for multilink communication, and the multilink frame A flag (FT: Frame Type) indicating the type of the MF is stored. The types of the multilink frame MF include a multilink frame MF for control data and a multilink frame MF for general data such as video and audio. In the second byte of the full header information H1, an SS (number of bytes) indicating the size of one piece of divided data stored in the multilink frame MF is stored. In the third byte of the full header information H1, an SPF (number) indicating the number of pieces of divided data stored in one multilink frame MF is stored. In the fourth to fifth bytes of the full header information H1, CRC (Cyclic Redundancy Check) information indicating whether or not the header information H has been transmitted normally is stored. On the other hand, the first byte of the compressed header information H2 stores the above-described CT, SN, L, and FT, and the second byte stores CRC information. Note that SS and SPF included in the previous multilink frame MF are used for SS and SPF not included in the compressed header information H2. If the previous multilink frame MF is the same as SS and SPF, the data can be reduced by using the compressed header information H2 in which SS and SPF are omitted. The synchronization flag of the multilink frame MF includes two types of flags indicating that the header information H is either the full header information H1 or the compressed header information H2.
[0043]
Next, the combining process of the multilink frame decoding unit 13B described above with reference to FIG. To simplify the description, a case will be described where multilink communication is performed on two lines CH1 and CH2. Further, in each multilink frame MF shown in FIG. 4, a number (SN) indicating the order in which the multilink frame MF is transmitted is displayed for convenience, and a number from 0 to 7 is assigned as SN. I have. Further, L of the line CH1 is turned off, and L of the line CH2 is turned on. This is because the line number (CT) of the line CH1 is "1" and the line number (CT) of the line CH2 is "2". It is because it is set to.
[0044]
First, the multilink frame decoding unit 13B of the data transmission device 1 on the receiving side JG searches the synchronization flag F for each of the channels CH1 and CH2. Next, when the multilink frame decoding unit 13B detects the synchronization flag F for each of the channels CH1 and CH2, the multilink frame decoding unit 13B refers to the SN and L included in the header information H immediately following the detected synchronization flag F. The multilink frame decoding unit 13B refers to the SN and L included in the header information H, and as a result, transmits the multilink frames MF having the same SN of the line CH1 and the line CH2 from the data transmission device 1 of the transmitting SG to the same. It is determined that the frame is the multilink frame MF transmitted at the timing. Specifically, as shown in FIG. 4, when a delay difference (D2-D1) occurs between the transmission line CH1 and the transmission line CH2, the multilink frame of the data transmission device 1 of the receiving side JG is generated. The decoding unit 13B detects the synchronization flag F of the multilink frame MF whose SN is “0” on the line CH1 after D1 [msec] from the start of transmission, and detects “0” on the line CH2 after D2 [msec] from the start of transmission. Is detected as the synchronization flag F of the multilink frame MF. In this case, the multilink frame decoding unit 13B determines that these multilink frames MF are multilink frames MF transmitted at the same timing from the data transmission device 1 on the transmission side SG. Also, the multilink frame decoding unit 13B of the data transmission device of the receiving side JG determines that the line in which L is ON is the line with the largest CT value among the lines used as the transmission line for multilink communication, that is, Judge as the last transmission line for link communication. As described above, by synchronizing the multilink frames MF of the channels CH1 and CH2, the data received from the channels CH1 and CH2 can be combined into one multiplexed data. That is, the data received from each of the channels CH1 and CH2 is combined by alternately combining the divided data included in each synchronized multilink frame MF in units of SS bytes in accordance with the order of the line number (CT). It can be combined into one multiplexed data. As a result, the multiplexed data divided in the data transmission device of the transmitting SG can be restored to the original multiplexed data. Note that, as shown in FIG. 3, the SN in the present embodiment is assigned a region of 3 bits, so that the multilink frame MF is identified only by eight numbers from 0 to 7. Therefore, if a transmission delay occurs that cannot be accommodated by only eight numbers, the multilink frames MF of the channels CH1 and CH2 cannot be synchronized. Therefore, it is desirable to set the values of SS and SPF in consideration of the communication environment and the buffer size on the receiving side.
[0045]
Next, the operation of the data transmission device according to the first embodiment will be described with reference to FIGS. First, an operation when a line abnormality is found in the data transmission device on the receiving side will be described with reference to FIG. Note that the operations described here are performed between a data transmission device on the transmission side and a data transmission device on the reception side by using a plurality of lines allocated for multilink communication, such as video data and audio data. This operation is performed between terminals when a line abnormality is found in the data transmission device on the receiving side during transmission / reception.
[0046]
First, the transmission-side data transmission apparatus transmits a multilink frame MF including video data, audio data, and the like to the reception-side data transmission apparatus by using a plurality of lines allocated for multilink communication (step S1). S1).
[0047]
Next, the determination unit 14 of the data transmission device on the reception side refers to the CRC information of the header information H included in the multilink frame MF received from the data transmission device on the transmission side, and determines whether there is an abnormality in the line. Is determined. As a result of this determination, when it is determined that there is an abnormality in the line (step S2), the message generator 11CA generates a “Stop-Channel” message (signal). The “Stop-Channel” message includes a code indicating that the line is abnormal and the line number (CT) of the line in which the abnormality has been found. Then, the message generating unit 11CA causes the generated “Stop-Channel” message to be transmitted to the transmission-side data transmission device (step S3).
[0048]
Next, when the message recognition unit 11CB of the transmission-side data transmission device recognizes that the data received from the reception-side data transmission device includes the “Stop-Channel” message, Is notified to the line input / output unit 15. Then, the line input / output unit 15 excludes the line corresponding to the notified line number from the target of the multilink communication (Step S4).
[0049]
Next, the multi-link frame forming unit 13A of the transmission-side data transmission device transmits video data, audio data, and the like to the reception-side data transmission device using a plurality of lines currently allocated for multi-link communication. Send to In parallel with this, the multilink frame forming unit 13A transmits data of a predetermined pattern using the line excluded by the line input / output unit 15 according to the StuffingMode defined in H.324 AnnexH. (Step S5). Here, the StuffingMode is, for example, data of a predetermined pattern used when exchanging information on the capabilities of each terminal between terminals performing communication, but this data itself is data having no meaning.
[0050]
Next, when the message recognition unit 11CB of the data transmission device on the receiving side recognizes that the data received from the data transmission device on the transmission side includes the data of the predetermined pattern in the StuffingMode, the fact is notified. Is notified to the line input / output unit 15. Then, the line input / output unit 15 excludes the line corresponding to the notified line number from the target of the multilink communication (step S6). Next, the determination unit 14 of the data transmission device on the receiving side determines whether there is an error in the data of the predetermined pattern received via the line excluded from the target of the multilink communication. As a result of this determination, when it is determined that the data of the predetermined pattern is normal (step S7), the message generator 11CA generates a “Restart-Channel” message. The “Restart-Channel” message includes a code indicating that the line has been recovered and the line number (CT) of the line that has been recovered. Then, the message generation unit 11CA causes the generated “Restart-Channel” message to be transmitted to the data transmission device on the transmission side (step S8). The determination unit 14 of the data transmission device on the receiving side repeats the above determination until there is no error in the data of the predetermined pattern received via the line excluded from the target of the multilink communication.
[0051]
Next, when the message recognition unit 11CB of the transmission-side data transmission device recognizes that the data received from the reception-side data transmission device includes the “Restart-Channel” message, Is notified to the line input / output unit 15. Then, the line input / output unit 15 adds the line corresponding to the notified line number to the target of the multilink communication (step S9). Next, the multi-link frame forming unit 13A of the transmission-side data transmission device transmits video data, audio data, and the like to the reception-side data transmission device using a plurality of lines currently allocated for multi-link communication. (Step S10).
[0052]
Next, when the message recognition unit 11CB of the data transmission device on the receiving side recognizes that the data of the predetermined pattern in the StuffingMode is no longer received, a signal indicating the fact and the line number transmitting the data are received. To the line input / output unit 15. Then, the line input / output unit 15 adds the line corresponding to the notified line number to the target of the multilink communication (step S11).
[0053]
In step S3, the data transmission device on the receiving side that has determined that there is an abnormality in the line transmits the “Stop-Channel” message, but the operation when there is an abnormality in the line is not limited to this. For example, the data transmission device on the receiving side that determines that there is an abnormality in a certain line may transmit data of a predetermined pattern in StuffingMode from the line that is determined to be abnormal. Thus, the transmission-side data transmission device that has received the data can recognize that there is an abnormality in the line that transmitted the data.
[0054]
As described above, the presence / absence of an abnormality is determined for each line, and according to this determination result, the line in which the abnormality is found can be excluded from the target of multilink communication. However, multi-link communication can be continuously performed on a line other than the line, and a decrease in communication quality can be suppressed as much as possible. Further, when the abnormality is eliminated from the excluded line, the line is added to the target of the multi-link communication, so that a decrease in the communication capability due to the exclusion of some lines can be recovered.
[0055]
Next, an operation when a delay occurs between data received for each line in the data transmission device on the receiving side will be described with reference to FIG. Note that the operations described here are performed between a data transmission device on the transmission side and a data transmission device on the reception side by using a plurality of lines allocated for multilink communication, such as video data and audio data. This operation is performed between terminals when a delay occurs between data received by the data transmission device on the receiving side during transmission and reception.
[0056]
First, the transmission-side data transmission apparatus transmits a multilink frame MF including video data, audio data, and the like to the reception-side data transmission apparatus by using a plurality of lines allocated for multilink communication (step S1). S21).
[0057]
Next, the determination unit 14 of the data transmission device on the receiving side determines whether or not a transmission delay has occurred on each line based on the multilink frame MF of each line received from the data transmission device on the transmission side. As a result of this determination, when it is determined that a transmission delay has occurred in a certain line (step S22), the message generator 11CA generates a “Delay-Channel” message. This “Delay-Channel” message includes a code indicating that a specific line is delayed, a line number (CT) of the line for which the delay is found, and a delay amount. Then, the message generation unit 11CA causes the generated “Delay-Channel” message to be transmitted to the transmission-side data transmission device (step S23).
[0058]
Next, when the message recognition unit 11CB of the transmission-side data transmission device recognizes that the data received from the reception-side data transmission device includes the “Delay-Channel” message, Is notified to the line input / output unit 15 of the line number and the delay amount included in the command. The line input / output unit 15 excludes the line corresponding to the notified line number from the target of the multilink communication (Step S24). Then, the multilink frame configuration unit 13A transmits the data of the predetermined pattern to the data transmission device on the receiving side by using the line excluded by the line input / output unit 15 according to the StuffingMode (step S25). In parallel with this, the line input / output unit 15 transmits the data so that the data transmitted from the line corresponding to the notified line number is transmitted earlier by the delay amount than the data transmitted from the other lines. In addition to controlling the setting of the buffer, the line corresponding to the notified line number is added to the target of the multilink communication (step S26). Using a plurality of lines allocated for link communication, video data, audio data, and the like are transmitted to the data transmission device on the receiving side while reflecting the delay control by the line input / output unit 15 (step S27).
[0059]
Next, the multi-link frame forming unit 13A of the transmission-side data transmission device transmits video data, audio data, and the like to the reception-side data transmission device using a plurality of lines currently allocated for multi-link communication. Send to In parallel with this, the multilink frame forming unit 13A transmits data of a predetermined pattern using the line excluded by the line input / output unit 15 according to the StuffingMode defined in H.324 AnnexH. (Step S5).
[0060]
As described above, the presence / absence of a delay is determined for each line, and the delay in the line can be eliminated by performing the delay control on the line for which the delay has been found according to the determination result. Can be minimized.
[0061]
[Modification]
In the above-described first embodiment, when an abnormality is found in a line, data of a predetermined pattern in StuffingMode is transmitted on the line in which the abnormality is found. Not limited. For example, a line in which an abnormality is found may be disconnected. With reference to FIG. 7, an operation of a disconnection process performed when disconnecting a line in which an abnormality is found will be described.
[0062]
First, the transmission-side data transmission apparatus transmits a multilink frame MF including video data, audio data, and the like to the reception-side data transmission apparatus by using a plurality of lines allocated for multilink communication (step S1). S31).
[0063]
Next, the determination unit 14 of the data transmission device on the reception side refers to the CRC information of the header information H included in the multilink frame MF received from the data transmission device on the transmission side, and determines whether there is an abnormality in the line. Is determined. As a result of this determination, when it is determined that there is an abnormality in the line (step S32), the line input / output unit 15 disconnects the line in which the abnormality is found (step S33). Next, the multi-link frame forming unit 13A of the receiving-side data transmission device transmits video data, audio data, and the like to the transmission-side data transmission device using a plurality of lines currently allocated for multi-link communication. (Step S34).
[0064]
Next, when the line input / output unit 15 of the transmission-side data transmission device detects that the line has been disconnected in the reception-side data transmission device (step S35), the line for multilink communication other than the line is disconnected. The video data, the audio data, and the like are transmitted to the data transmission device on the receiving side using the data (step S36).
[0065]
Next, the line input / output unit 15 of the data transmission device on the receiving side reconnects the disconnected line and, if there is no abnormality in the line, adds it to the target of the multilink communication (step S37). The method of determining the state of the reconnected line may be performed by determining whether there is an error in the data of the predetermined pattern in the StuffingMode performed in step S7 of FIG. 5 described above. It is desirable that the reconnection process be started immediately after the line is disconnected. In the multilink communication, since the communication capability is improved by using a plurality of lines, it is necessary to prevent a decrease in the communication capability due to disconnection of a part of the lines as much as possible. Therefore, when a part of the line is disconnected, by starting the reconnection process immediately after the disconnection, it is possible to minimize the period during which the communication capability is reduced.
[0066]
Next, the multi-link frame forming unit 13A of the receiving-side data transmission device transmits video data, audio data, and the like to the transmission-side data transmission device using a plurality of lines currently allocated for multi-link communication. (Step S38). As a result, the transmission-side data transmission device can detect the recovery of the disconnected line (step S39), and the multi-link communication is performed between the transmission-side data transmission device and the reception-side data transmission device. The transmission and reception of video data, audio data, and the like are performed using all the lines allocated for the communication (step S40).
[0067]
In step S7 in FIG. 5 described above, if it is determined that there is an error in the data of the predetermined pattern received from the transmission-side data transmission device even after the predetermined time has elapsed, the above-described disconnection processing (FIG. 7) may be performed.
[0068]
As described above, the presence / absence of an abnormality is determined for each line, and according to the result of the determination, the line in which the abnormality is found can be disconnected. In this case, the multilink communication can be continuously performed, and the deterioration in communication quality can be suppressed as much as possible. Further, when the abnormality is eliminated in the disconnected line, the line is added to the target of the multi-link communication, so that it is possible to recover a decrease in the communication capability due to disconnection of a part of the line.
[0069]
[Second embodiment]
Next, a second embodiment of the present invention will be described. First, the functional configuration of the data transmission device according to the second embodiment is the same as the functional configuration of the data transmission device according to the first embodiment (see FIG. 1). Are omitted, and differences from the first embodiment will be described in detail below.
[0070]
The data transmission device according to the second embodiment is different from the data transmission device according to the first embodiment in that, in the data transmission device according to the first embodiment, when an abnormality occurs in a certain line, the line is changed from a target of multi-communication. On the other hand, in the data transmission device according to the second embodiment, a predetermined line is excluded from the target of the multi-communication regardless of the presence or absence of a line abnormality, and a check is made as to whether the line is abnormal. It is.
[0071]
Hereinafter, the functions of the message generating unit 11CA, the message recognizing unit 11CB, and the line input / output unit 15 having the specific functions as the data transmission device 1 in the second embodiment will be described.
[0072]
The message generator 11CA generates a “Check-Channel” message and a “Next-Channel” message in addition to the various messages in the first embodiment. Here, the "Check-Channel" message includes a code indicating that a line check is to be started, and the "Next-Channel" message includes a code indicating that a check of a next line is to be started. .
[0073]
The message recognizing unit 11CB, in addition to the function of the first embodiment, receives a “Check-Channel” message or a “Next-Channel” message, and sets the line number of the line to be line-checked to the line input / output unit. 15 is notified. Here, the line to be subjected to the line inspection may be a single line or a plurality of lines. Further, it is desirable that the lines to be subjected to the line inspection be allocated in the order of the line numbers. This is because if the assignment is performed in the order of the line numbers, the inspection target can be controlled without including the line number of the line to be inspected next in the message.
[0074]
The line input / output unit 15 performs, in addition to the functions in the first embodiment, control to exclude a line to be inspected from lines to be subjected to multilink communication and control to add the line to the line.
[0075]
Next, the operation of the data transmission device according to the second embodiment will be described with reference to FIG. Note that the operations described here are performed between a data transmission device on the transmission side and a data transmission device on the reception side by using a plurality of lines allocated for multilink communication, such as video data and audio data. This operation is performed between terminals when transmission and reception are being performed.
[0076]
First, the transmission-side data transmission apparatus transmits a multilink frame MF including video data, audio data, and the like to the reception-side data transmission apparatus by using a plurality of lines allocated for multilink communication (step S1). S51).
[0077]
Next, the message generator 11CA of the data transmission device on the receiving side generates a “Check-Channel” message. This “Check-Channel” message includes a code indicating that a line check should be started. Then, the message generation unit 11CA causes the generated “Check-Channel” message to be transmitted to the transmission-side data transmission device (step S52).
[0078]
Next, when the message recognition unit 11CB of the transmission-side data transmission device recognizes that the data received from the reception-side data transmission device includes the “Check-Channel” message, the line check is performed. Is notified to the line input / output unit 15. Then, the line input / output unit 15 excludes the line corresponding to the notified line number from the target of the multilink communication (Step S53).
[0079]
Next, the multi-link frame forming unit 13A of the transmission-side data transmission device transmits video data, audio data, and the like to the reception-side data transmission device using a plurality of lines currently allocated for multi-link communication. Send to In parallel with this, the multilink frame forming unit 13A transmits data of a predetermined pattern using the line excluded by the line input / output unit 15 according to the StuffingMode defined in H.324 AnnexH. (Step S54).
[0080]
Next, when receiving the data of the predetermined pattern in the StuffingMode from the transmission-side data transmission device, the message recognition unit 11CB of the reception-side data transmission device sets the line number of the line to be subjected to the current line inspection to the line number. Notify the input / output unit 15. Then, the line input / output unit 15 excludes the line corresponding to the notified line number from the target of the multilink communication (Step S55). Next, the determination unit 14 of the data transmission device on the receiving side determines whether there is an error in the data of the predetermined pattern received via the line excluded from the target of the multilink communication. As a result of this determination, when it is determined that the data of the predetermined pattern is normal (step S56), the message generator 11CA generates a “Next-Channel” message. This “Next-Channel” message includes a code indicating that the inspection of the next line to be inspected is started. Then, the message generation unit 11CA causes the generated “Next-Channel” message to be transmitted to the transmission-side data transmission device (Step S57). If the determination unit 14 of the data transmission device on the receiving side determines that there is an error in the data of the predetermined pattern received via the line excluded from the target of the multilink communication, the determination unit 14 in the first embodiment The processing after step S3 in FIG. 5 is performed.
[0081]
Next, when the message recognition unit 11CB of the transmission-side data transmission device recognizes that the “Next-Channel” message is included in the data received from the reception-side data transmission device, the fact is notified. And the line number of the line to be subjected to the line inspection next. Then, the line input / output unit 15 adds the line corresponding to the previously notified line number to the target of the multilink communication, and excludes the line corresponding to the line number notified this time from the target of the multilink communication. That is, the line input / output unit 15 switches the line to be subjected to the line inspection (step S58).
[0082]
Next, the multi-link frame forming unit 13A of the transmission-side data transmission device transmits video data, audio data, and the like to the reception-side data transmission device using a plurality of lines currently allocated for multi-link communication. Send to In parallel with this, the multilink frame forming unit 13A continues to transmit data of a predetermined pattern in the Stuffing Mode to the data transmission device on the receiving side using the line excluded by the line input / output unit 15 (step S59).
[0083]
Next, when the message recognition unit 11CB of the data transmission device on the receiving side detects that the line for receiving the data of the predetermined pattern in the StuffingMode has been switched, the line number of the line to be subjected to the line inspection this time. To the line input / output unit 15. Then, the line input / output unit 15 adds the line corresponding to the previously notified line number to the target of the multilink communication, and excludes the line corresponding to the line number notified this time from the target of the multilink communication. That is, the line input / output unit 15 switches the line to be subjected to the line inspection (step S60). Next, the determination unit 14 of the data transmission device on the receiving side determines whether there is an error in the data of the predetermined pattern received via the line excluded from the target of the multilink communication. As a result of this determination, when it is determined that the data of the predetermined pattern is normal (step S61), the message generating unit 11CA generates a “Next-Channel” message and transmits the generated “Next-Channel” message. The data is transmitted to the data transmission device on the transmission side (step S62). Thereafter, the processes of steps S58 to S62 are repeated until an error is found in the data of the predetermined pattern. On the other hand, when an error is found in the data of the predetermined pattern, the processing after step S3 in FIG. 5 in the first embodiment is performed.
[0084]
In the above-described second embodiment, a “Check-Channel” message and a “Next-Channel” message are transmitted as triggers for starting a line check. It is not limited to this. For example, a line inspection may be performed each time the connection time of each line elapses a predetermined time, or a line inspection may be performed each time the communication amount of each line reaches a predetermined communication amount. In addition, when decoding of received data fails, the line may be checked, or when a line is newly added, the line may be checked. That is, the line inspection may be started according to a predetermined agreement.
[0085]
As described above, the presence / absence of an abnormality is determined for each line by the line-by-line inspection performed according to a predetermined agreement such as message transmission, and the line where the abnormality is found is excluded from multilink communication targets according to the determination result. Therefore, even if an abnormality occurs in any one of the lines, multilink communication can be continuously performed on a line other than the line, and a decrease in communication quality can be suppressed as much as possible.
[0086]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to the data transmission method, the data transmission apparatus, and the data transmission system according to the present invention, even if a failure occurs in a line, it is possible to minimize deterioration in communication quality.
[Brief description of the drawings]
FIG. 1 is a functional configuration diagram of a data transmission device in each embodiment.
FIG. 2 is a diagram for explaining a function of a multilink frame forming unit of the data transmission device shown in FIG.
FIG. 3 is a conceptual diagram of header information.
FIG. 4 is a diagram for explaining a function of a multilink frame decoding unit of the data transmission device shown in FIG.
FIG. 5 is a flowchart illustrating an operation of the data transmission device according to the first embodiment.
FIG. 6 is a flowchart illustrating an operation of the data transmission device according to the first embodiment.
FIG. 7 is a flowchart illustrating an operation of the data transmission device according to a modification of the first embodiment.
FIG. 8 is a flowchart illustrating an operation of the data transmission device according to the second embodiment.
FIG. 9 is a functional configuration diagram of data transmission in the related art.
FIG. 10 is a diagram for explaining functions of a mobile multilink unit shown in FIG. 9;
FIG. 11 is a conceptual diagram of header information in the related art.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Data transmission apparatus, 11 ... Data input / output part, 11Aa ... Video encoding part, 11Ab ... Video decoding part, 11Ba ... Audio encoding part, 11Bb ... Audio decoding part , 11C communication control unit, 11CA message generation unit, 11CB message recognition unit, 11CC H245 processing unit, 11CD SRP processing unit, 12A multiplexing unit, 12B ··· Separation unit, 13A ··· Multilink frame configuration unit, 13B ··· Multilink frame decoding unit, 14 ··· determination unit, 15 ··· line input / output unit.

Claims (16)

The transmission-side terminal divides the data to be transmitted, distributes the divided data to a plurality of transmission paths, and transmits the data.The reception-side terminal also distributes the divided data to the plurality of transmission paths. And a data transmission method for combining the received data,
A data transmission method, wherein data transmission / reception is controlled for each transmission path based on transmission results for each transmission path. The transmission-side terminal divides the data to be transmitted, distributes the divided data to a plurality of transmission paths, and transmits the data.The reception-side terminal also distributes the divided data to the plurality of transmission paths. And a data transmission method for combining the received data,
A data transmission method, wherein data transmission / reception is controlled for each transmission path based on a predetermined agreement. The method according to claim 2, wherein data transmission / reception is controlled for each of the transmission paths based on a transmission result determined by a transmission inspection on a part of the plurality of transmission paths performed according to the predetermined agreement. The described data transmission method. The data transmission method according to claim 1, wherein the transmission result is a frequency of occurrence of an abnormality for each of the transmission paths. The data transmission method according to claim 1, wherein the transmission result is a transmission delay difference between the transmission paths. In the control, the reception-side terminal causes the transmission-side terminal to transmit a signal indicating that the transmission path is abnormal, and the transmission-side terminal has a signal indicating that the abnormality is present. The data transmission method according to any one of claims 1 to 3, wherein the transmission of data on the transmission path indicated as abnormal is stopped on the basis of the data transmission. In the control, the reception-side terminal transmits a signal indicating that data transmission on the stopped transmission line is restarted based on the transmission result of the stopped transmission line. 7. The data transmission according to claim 6, wherein the transmission-side terminal restarts data transmission on the stopped transmission path based on the signal indicating the restart. Method. The data according to any one of claims 1 to 3, wherein the control disconnects the transmission path and causes data transmission and reception to be performed on a transmission path other than the disconnected transmission path. Transmission method. 9. The data transmission method according to claim 8, wherein, after disconnecting the transmission path, the control starts connection processing of the disconnected transmission path. 3. The data transmission method according to claim 2, wherein the predetermined agreement is to perform a transmission check at a predetermined time interval. Division means for dividing data to be transmitted;
Transmission means for distributing the data divided by the division means to a plurality of transmission paths and transmitting the divided data to an external terminal,
Receiving means for receiving data transmitted by being distributed to the plurality of transmission paths from the external terminal,
Combining means for combining the data received by the receiving means;
Based on the combined data, a determination unit that determines a transmission result for each of the transmission paths,
A data transmission apparatus, comprising: transmission / reception control means for controlling data transmission / reception for each of the transmission paths based on the determination by the determination means. Division means for dividing data to be transmitted;
Transmission means for distributing the data divided by the division means to a plurality of transmission paths and transmitting the divided data to an external terminal,
Receiving means for receiving data transmitted by being distributed to the plurality of transmission paths from the external terminal,
Combining means for combining the data received by the receiving means;
A data transmission device, comprising: transmission / reception control means for controlling transmission / reception of data for each of the transmission paths based on a predetermined agreement. The transmission / reception control means controls transmission / reception of data for each of the transmission paths based on transmission results determined by transmission inspection on a part of the plurality of transmission paths performed according to the predetermined agreement. The data transmission device according to claim 12, wherein: A data transmission system for transmitting and receiving data between a first data transmission device and a second data transmission device,
The first data transmission device includes:
Division means for dividing data to be transmitted;
Transmitting means for distributing the data divided by the dividing means to a plurality of transmission paths and transmitting the divided data to the second data transmission apparatus,
The second data transmission device includes:
Receiving means for receiving data transmitted from the first data transmission device to the plurality of transmission paths;
Combining means for combining the data received by the receiving means;
Based on the combined data, a determination unit that determines a transmission result for each of the transmission paths,
A data transmission system, comprising: transmission / reception control means for controlling data transmission / reception for each of the transmission paths based on the determination by the determination means. A data transmission system for transmitting and receiving data between a first data transmission device and a second data transmission device,
The first data transmission device includes:
Division means for dividing data to be transmitted;
Transmitting means for distributing the data divided by the dividing means to a plurality of transmission paths and transmitting the divided data to the second data transmission apparatus,
The second data transmission device includes:
Receiving means for receiving data transmitted from the first data transmission device to the plurality of transmission paths;
Combining means for combining the data received by the receiving means;
A data transmission system comprising transmission / reception control means for controlling transmission / reception of data for each of the transmission paths based on a predetermined agreement. The transmission / reception control unit controls transmission / reception of data for each of the transmission paths based on transmission results found by a transmission inspection on a part of the plurality of transmission paths performed according to the predetermined agreement. The data transmission system according to claim 15, wherein

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