JP2002344965A - Data transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data transmission system that uses a transmission line with a narrow band so as to transmit/receive a transport stream at a high bit rate. SOLUTION: A transmitter side divides a transport stream in the unit of TS (transport) packets to generate a plurality of data streams. Then each divided data stream is transmitted to a receiver side via different channels. The receiver side receives the signals sent via a plurality of channels and multiplexes them in the unit of TS packets to restore one transport stream.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a satellite wave, a terrestrial wave,
MPEG (Moving Pict) via a transmission path such as a cable
ur Experts Group) The present invention relates to a data transmission system, a transmission device, a reception device, and a data transmission method for transmitting a transport stream specified by 2 Systems.

[0002]

2. Description of the Related Art In recent years, the number of cases in which high-quality video data such as HDTV data is stored and transmitted in a transport stream defined by MPEG2 Systems has increased. When transmitting high-quality video data in this way, it is necessary to perform data transmission using a wideband transmission path. For example, when transmitting HDTV video data stored in a transport stream, a bit rate of 22 Mbps is required to maintain image quality, and a sufficient bandwidth is required to transmit data at this bit rate. It is.

[0003]

However, when a terrestrial radio communication path, for example, is used as the transmission path, the bandwidth is narrow. Therefore, in order to maintain the bit rate of high-quality video data, the amount of transmission information per unit frequency is usually increased by using a multi-level modulation technique.

[0004] However, the higher the value of multi-level coding, the shorter the distance between code points, and the greater the transmission error. Therefore, there is a limit in increasing the amount of transmission information per unit frequency.

The present invention has been made in view of such circumstances, and a data transmission system, a transmission apparatus, and a data transmission method capable of transmitting and receiving a high bit rate transport stream using a narrow band transmission path. An object of the present invention is to provide a receiving device and a data transmission method.

[0006]

A data transmission system according to the present invention is a data transmission system for transmitting digital data in the form of an MPEG transport stream via a transmission path, wherein a data supply for supplying the transport stream is provided. Means for dividing the transport stream supplied by the data supply means into transport packet units to generate a plurality of divided data streams of a transport packet sequence; and A transmitting apparatus having a plurality of data transmitting means for transmitting data via different transmission paths, a plurality of data receiving means for receiving the respective divided data streams transmitted via the respective transmission paths, and each of the received divided data streams In the transport packet unit. Turned into it and a receiving apparatus and a data synthesizing means for generating a single transport stream.

[0007] In this data transmission system, a transport stream is divided into a plurality of data streams of a transport packet sequence by dividing the transport stream into transport packet units. Then, the plurality of data streams are transmitted through a plurality of different transmission paths. Further, in the present invention, one transport stream is restored by multiplexing divided data streams of a transport packet sequence received from a plurality of different transmission paths in units of transport packets.

[0008] A transmitting apparatus according to the present invention is a transmitting apparatus for transmitting digital data in the form of an MPEG transport stream via a transmission path, comprising: a data supply unit for supplying the transport stream; A data dividing unit that divides the supplied transport stream in units of transport packets to generate a plurality of divided data streams of a transport packet sequence, and a plurality of units that transmit each of the divided divided data streams via different transmission paths. Data transmission means.

[0009] In this transmitting apparatus, a transport stream is divided in units of transport packets and divided into a plurality of data streams of a transport packet sequence. Then, the plurality of data streams are transmitted through a plurality of different transmission paths.

[0010] A receiving apparatus according to the present invention is a data receiving apparatus for receiving digital data in the form of an MPEG transport stream transmitted via a transmission path. It has a plurality of data receiving means for receiving a divided data stream of a port packet sequence, and data combining means for multiplexing the received divided data streams in units of transport packets to generate one transport stream.

[0011] In this receiving apparatus, a divided data stream of a transport packet sequence received from a plurality of different transmission paths is multiplexed on a transport packet unit basis.
Restore one transport stream.

[0012] A data transmission method according to the present invention is a data transmission method for transmitting digital data in the form of an MPEG transport stream via a transmission path, wherein the transport stream is input, and the input transport stream is input. Is divided into transport packet units to generate a plurality of divided data streams of a transport packet sequence, each of the divided data streams is transmitted by a different transmission path, and transmitted via each transmission path. Each of the divided data streams is received, and the received divided data streams are multiplexed in units of transport packets to generate one transport stream.

In this data transmission method, a transport stream is divided in units of transport packets and divided into a plurality of transport stream data streams. Then, the plurality of data streams are transmitted through a plurality of different transmission paths. Further, in the present invention, one transport stream is restored by multiplexing divided data streams of a transport packet sequence received from a plurality of different transmission paths in units of transport packets.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, as an embodiment of the present invention, for example, a terrestrial digital radio relay system (hereinafter referred to as a radio system) used for photographing a relay site of a television broadcast of a news program, a sports program, an event program, etc. An example in which the present invention is applied to a relay system will be described.

FIG. 1 shows a configuration diagram of a wireless relay system according to an embodiment of the present invention.

As shown in FIG. 1, the wireless relay system 1 includes a wireless camera 11 for photographing a subject and a receiving relay station 12 for receiving a transmission signal from the wireless camera 11. The receiving relay station 12 includes an external receiving unit 13 and an internal receiving unit 14, which are connected by an IF cable 15.

The wireless relay system 1 is used, for example, for photographing a broadcast site of a television broadcast such as a news program, a sports program, an event program, and the like.
1 is a system for transmitting a video signal or the like of a material video photographed by the terrestrial radio wave to the receiving relay station 12. The wireless relay system 1 is a system in which the camera angle and the shooting position are not restricted by a cable or the like connecting the camera and the relay station, and the mobility of the camera at the shooting site is improved.

The wireless relay system 1 employs a transport stream defined by MPEG2 Systems as a wireless transmission signal from the wireless camera 11 to the wireless relay station 12, and further employs an OFDM as a modulation method.
(Orthogonal Frequency Division Multiplexing) modulation method. By converting the video material into a digitized transport stream in this way, the S / N can be reduced as compared with the case where the video material is transmitted in an analog system.
It is possible to transmit high-quality images and sounds with little deterioration. In the OFDM modulation method, image quality deterioration due to fluctuations in electric field strength due to mobile reception is small, and the influence of multipath interference is small. Therefore, by adopting the OFDM modulation method, it is possible to transmit high-quality images and sounds.

Next, the configuration of the wireless camera 11 will be described with reference to FIG.

The wireless camera 11 transmits a signal to the receiving relay station 12 using a plurality of transmission paths (channels). Here, a case where k channels are used will be described.

As shown in FIG. 2, the wireless camera 11 includes an image pickup section 21, an MPEG2 encoder 22,
An encoder 23, a packet synchronization circuit 24, a demultiplexer 25, buffer circuits 26-1 to 26-k for the number (k) of channels used, and several buffers (k
Channel coding / OFDM modulators 27-1 to 27-
k and several (k) frequency conversion units 28 of the used channels
-1 to 28-k, several (k) high frequency amplifiers 29-1 to 29-k of the used channels, and several (k) transmitting antennas 30-1 to 30-k of the used channels. It is provided with.

The image pickup section 21 includes an image pickup optical system, a CCD image sensor, an A / D converter, a camera signal processing section, and the like. The imaging unit 21 is a module that performs an analog / digital conversion process, a timing process, and the like on an image signal converted into an electric signal by the CCD image sensor and converts the image signal into a digital video signal. The digital video signal output from the imaging unit 21 is supplied to the MPEG2 encoder 22.

The MPEG2 encoder 22 includes an image pickup unit 21
, A digital audio signal that has been collected by a microphone or the like and then digitized, and a predetermined data signal.
Perform compression encoding according to the method. Then, these compressed data are multiplexed to generate a transport stream defined in MPEG2 Systems. This transport stream is a sequence of 188-byte fixed-length transport packets (TS packets) as shown in FIG. The TS packet includes a 4-byte packet header and a 184-byte payload.
The packet header includes a synchronization byte (47h) for identifying the head of the packet, a packet ID, and the like. In the payload, video, audio, data, and the like are described. The transport stream generated by the MPEG2 encoder 22 is supplied to the RS encoder 23.

The RS encoder 23 has a 188-byte T
Perform Reed-Solomon encoding for each S packet,
A transmission packet is generated by adding, for example, a 16-byte RS parity to the S packet. The transport stream to which the RS parity has been added is supplied to the packet synchronization circuit 24 and the demultiplexer 25.

The packet synchronization circuit 24 detects a synchronization byte (47h) in the TS packet and generates a packet synchronization signal synchronized with the transmission packet. The generated packet synchronization signal is supplied to the demultiplexer 24.

The demultiplexer 24 divides one input transport stream at the boundary of a transmission packet based on a packet synchronization signal, and transmits the divided transport stream to k subsequent buffer circuits 26-1 to 26-k in transmission packet units. To distribute in order. That is, the demultiplexer 24 distributes the input transport stream while switching the buffer circuits 26-1 to 26-k for each transmission packet.

The buffer circuits 26-1 to 26-k are provided in a number corresponding to the number of transmission channels that can be used by the wireless relay system 1. Subsequent transmission line coding / OFDM modulators 27-1 to 27-k, frequency converters 28-1 to 28-k, and high frequency amplifiers 29-1 to 29-29
Similarly, -k and transmission antennas 30-1 to 30-k are provided corresponding to transmission channels.

The buffer circuits 26-1 to 26-k extend the packet transmission time by making the bit rate of the input transmission packet 1 / k times the bit rate of the original transport stream. As a result, each divided data stream output from each of the buffer circuits 26-1 to 26-k becomes a stream of TS packets having a bit rate lower than the bit rate of the original transport packet. The divided data stream output from each of the buffer circuits 26-1 to 26-k is supplied to the corresponding one of the transmission channel coding / OFDM modulators 27-1 to 27-k of the corresponding channel.

Transmission path coding / OFDM modulator 27-1
27-k is for a TS packet (transmission packet) to which RS parity is added, a convolutional interleaving process, an inner coding process, a bit interleaving process, a symbol interleaving process, a mapping process according to a modulation scheme, a predetermined process, A predetermined transmission line encoding process such as an OFDM frame configuration process such as insertion of a pilot signal or insertion of a null signal is performed. Further, the transmission path coding / OFDM modulators 27-1 to 27-k use an IFFT (Inverse Fast Fourier) for the transmission path coded data stream by using, for example, data of 2048 sets of IQ signals as one symbol.
Transform) processing to convert the OFDM signal into a time-domain OFDM signal, and the time-domain OFD by copying the second half of the effective symbol to the first half of the symbol.
An OFDM modulation process such as a guard interval addition process for adding a guard interval to the M signal, an orthogonal modulation process for orthogonally modulating a time domain OFDM signal to which the guard interval is added to generate an IF signal in an intermediate frequency band, and the like are performed. Each transmission line coding / OFDM modulator 27-1
Each IF signal output from 27-k is supplied to frequency converters 28-1 to 28-k of the corresponding channel.

The frequency converters 28-1 to 28-k are connected to IF
The carrier frequency of the signal is up-converted and converted into an RF signal for emission into the air. Note that each of the frequency conversion units 28-1 to 28-k generates an RF signal by up-converting an IF signal so as to have a different center frequency for each channel so as to propagate the RF signal to different transmission channels. I do. Each RF signal is supplied to the high-frequency amplifiers 29-1 to 29-k of the corresponding channel.

The high-frequency amplifiers 29-1 to 29-k are RF
The signal is amplified at high frequency, and each transmitting antenna 30-1 to 30-
Radiates from k into the air.

Each transmission signal transmitted from the wireless camera 11 having such a configuration is received by the reception relay station 12 via k transmission paths having different frequency bands.

In the wireless camera 11, the captured material video is encoded into a transport stream, the transport stream is OFDM-modulated, and terrestrial transmission to the reception relay station 12 is performed. Can be.

Further, in this wireless camera 11, 1
One transport stream is divided into TS packets to generate a plurality of data streams, and each data stream is divided into a plurality of different channels and transmitted.

The buffer circuits 26-1 to 26-k provided at the subsequent stage of the demultiplexer 25 are used for converting the data bit rate as shown in FIG. When the buffer is switched every time, the capacity may be at least one transmission packet. Of course, even if the demultiplexer 25 switches the buffer every n (n is an integer) transmission packets, it can distribute data, and in that case, the buffer circuit 26-
A transmission capacity of 1 to 26-k is required for n transmission packets.

Next, the receiving relay station 12 will be described.

As shown in FIG. 5, the receiving relay station 12 includes an external receiving unit 13, an internal receiving unit 14, and a plurality of IF cables 15-1 to 15 that connect the external receiving unit 13 and the internal receiving unit 14. 15-k.

The external receiving unit 13 includes k receiving antennas 31-1 to 31-k and several channels (k
) High-frequency amplifiers 32-1 to 32-k, and several (k) frequency converters 33-1 to 33-k of the used channels. Also, the internal receiving unit 14
Are: several (k) OFDM demodulation / transmission path decoding units 34-1 to 34-k for use channels, several (k) packet synchronization circuits 35-1 to 35-k for use channels, Several (k) buffer circuits 36-1 to 3-3 used channels
6-k, the control unit 37, the multiplexer 38, the RS
A decoder 39 is provided.

Receiving antennas 31-1 to 31-k receive RF signals transmitted from wireless camera 11 via k transmission paths in different frequency bands, and receive the received RF signals.
High frequency amplifiers 32-1 to 32 of channels corresponding to signals
-K.

The high frequency amplifying units 32-1 to 32-k amplify the RF signal received by the receiving antenna 18 at a high frequency. The high-frequency amplified RF signal is supplied to the frequency converter 33-
1-3k.

Each of the frequency converters 33-1 to 33-k down-converts the RF signal into an IF signal of a predetermined carrier frequency based on a reference signal of a different center frequency corresponding to each channel. Each frequency-converted IF signal is
OFDM demodulation / transmission path decoding units 34-1 to 34-k of internal reception unit 14 via cables 15-1 to 15-k.
Supplied to

OFDM demodulation / transmission path decoding sections 34-1 to 3-4
4-k performs channel selection processing and quadrature demodulation processing on the input IF signal. Further, OFDM demodulation /
The transmission path decoding units 34-1 to 34-k perform FFT (Fast Fourier Tr) for each effective symbol while performing various synchronization processing such as FFT window synchronization processing and symbol timing synchronization.
ansform) processing to perform OFDM demodulation processing such as orthogonal transformation processing for converting into an OFDM signal in the frequency domain, waveform equalization processing, demapping processing, and the like, and demodulate transmission data. Further, the OFDM demodulation / transmission path decoding unit 34-
1 to 34-k perform symbol deinterleave processing, bit deinterleave processing on demodulated transmission data,
A transmission path decoding process such as an inner code decoding process and a convolution deinterleave process is performed, and a transmission data decoding process is performed. By performing OFDM demodulation / transmission decoding processing in this manner,
A divided data stream in the state of a transmission packet in which, for example, a 16-byte RS parity is added to a TS packet is output. Each OFDM demodulation / transmission path decoding unit 34-1-3
The divided data stream output from 4-k is supplied to packet synchronization circuits 35-1 to 35-k of the corresponding channel and buffer circuits 36-1 to 36-k of the corresponding channel.

The packet synchronization circuits 35-1 to 35-k
Synchronization byte (47h) in TS packet for each channel
Is detected, and a packet synchronization signal for each channel synchronized with the transmission packet is generated. The generated packet synchronization signal is supplied to the control unit 37.

Each of the buffer circuits 36-1 to 36-k
The divided data streams output from the FDM demodulation / transmission path decoding units 34-1 to 34-k are sequentially stored, and the stored data is read out at the switching timing by the multiplexer 38.

The control unit 37 controls each packet synchronization circuit 35-
An arbitrary one of the k packet synchronization signals supplied from 1 to 35-k is multiplied by k, and the clock of the transport stream generated on the transmission side is reproduced. The control unit 37 uses the generated clock as a data read clock as each of the buffer circuits 36-1 to 36-36.
-K. Therefore, each of the buffer circuits 36-1 to 36-3
In 6-k, the bit rate of the input divided data stream is increased by k times to compress the packet transmission time.
Further, the control unit 37 generates a signal indicating the boundary position of the transmission packet stored in the buffer circuits 36-1 to 36-k based on each packet synchronization signal.

The multiplexer 38 is connected to each buffer circuit 3
One transmission packet is read from 6-1 to 36-k,
By sequentially switching the buffer circuits 36-1 to 36k to be read, a plurality of divided data streams are multiplexed in units of transmission packets and one transport stream is output. Each of the buffer circuits 36-1 to 36-3
As the 6-k selection order, an order corresponding to the selection order on the transmission side may be preset, or a continuity counter or PID value described in the header of the TS packet may be referred to. Then, the switching order may be set. The multiplexed transport stream is supplied to the RS decoder 39.

The RS decoder 39 performs Reed-Solomon decoding on the transport stream based on the RS parity added to the TS packet, and performs transmission error correction. Then, the transport stream that has been subjected to the error correction processing is transmitted to the outside.

With the above configuration, the receiving relay station 12 can OFDM demodulate the received RF signal and output a transport stream.

Further, the receiving relay station 12 receives the divided data streams transmitted via a plurality of channels, multiplexes these in units of TS packets, and outputs one transport stream.

When data is transmitted by being divided into a plurality of different channels, the modulation method may be different for each channel, or the delay amount of the transmission system may be different. Therefore, the propagation delay time for each channel is not always the same. Therefore, wireless camera 1
Buffer circuits 26-1 to 26-k on the side
The buffer circuits 36-1 to 36-1 k on the receiving side need to have a capacity larger than the transmission packet length so as to absorb the propagation delay time between channels. Becomes

As described above, in the wireless relay system 1 according to the embodiment of the present invention, the transport stream is divided by the
The data stream is divided into a plurality of data streams in a packet sequence, and the plurality of data streams are transmitted through a plurality of different transmission paths. Then, the receiving relay station 12 restores one transport stream by multiplexing the divided data streams of the TS packet sequence received from a plurality of different transmission paths in units of TS packets.

As a result, in the wireless relay system 1 according to the present embodiment, a transport stream having a high bit rate can be transmitted by being distributed to a plurality of channels having a narrow bandwidth. Therefore, high-quality video such as HDTV can be transmitted. Data can be transmitted without deteriorating image quality. In particular,
In the transmission method using the MPEG transport stream, the data format, the modulation method, and the transmission path coding method are closely related, but in the present invention, the original transport stream is divided into transport packet units. Then, since the divided data stream of the transport packet sequence is generated, it is possible to divide and multiplex the data without affecting the modulation scheme and the encoding scheme.

Although the embodiment of the present invention has been described with reference to an example in which the external receiving unit 13 transmits an IF signal, the external receiving unit 13 and the internal receiving unit 14 may be integrated. Good.

Further, in the embodiment of the present invention, the OFDM modulation method is used as the modulation coding method of the transport stream. However, the modulation coding method is not limited to the OFDM method, but may be any method. Is also good.

Further, in the embodiment of the present invention, an example has been described in which a plurality of transmission antennas are used for transmitting a signal using a plurality of channels. A system in which signals of a plurality of frequency bands are transmitted by the above antenna may be used.

As an embodiment of the present invention, an example in which the present invention is applied to a wireless camera system has been described. The present invention is applicable not only to such a wireless camera system but also to a system for transmitting a transport stream. If so, it may be applied to any system. Further, the transmission path is not limited to wireless communication, and may be applied to satellite relay using a transponder, digital satellite broadcasting, terrestrial digital broadcasting, and the like. Further, one transport stream may be divided into different types of transmission paths and transmitted. For example, one transport stream may be divided into a cable transmission channel and a wireless transmission channel and transmitted.

[0057]

The data transmission system according to the present invention,
In the transmission device, the reception device, and the data transmission method, the transport stream is divided into transport packet units to divide the transport stream into a plurality of data streams of a transport packet sequence, and the plurality of data streams are transmitted through a plurality of different transmission paths. Send. Then, according to the present invention, one transport stream is restored by multiplexing divided data streams of a transport packet sequence received from a plurality of different transmission paths in units of transport packets.

As a result, according to the present invention, a high bit rate transport stream can be distributed and transmitted to a plurality of transmission paths having a narrow bandwidth.
Etc. can be transmitted without deteriorating the image quality. In particular, in a transmission system employing an MPEG transport stream, a data format is closely related to a modulation system and a transmission line encoding system. However, in the present invention, the original transport stream is used in units of transport packets. Is divided to generate a divided data stream of a transport packet sequence,
Data division and multiplexing can be performed without affecting the modulation scheme and coding scheme.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram of a wireless relay system according to an embodiment of the present invention.

FIG. 2 is a block diagram of a wireless camera used in the wireless relay system.

FIG. 3 is a diagram illustrating a TS packet.

FIG. 4 is a diagram illustrating time expansion of a plurality of divided data streams generated on the transmission side.

FIG. 5 is a block diagram of a receiving relay station used in the wireless relay system.

[Explanation of symbols]

11 wireless camera, 12 wireless relay station, 13 external receiving unit, 14 internal receiving unit, 15 IF cable

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 7/08 H04L 13/00 307Z 7/081 F term (Reference) 5C059 KK34 MA00 RA04 RA06 RB01 RB16 SS02 SS03 UA02 UA05 UA09 UA32.2

Claims (13)

[Claims] 1. A data transmission system for transmitting digital data in an MPEG transport stream format via a transmission path, comprising: a data supply unit for supplying the transport stream; and a transport stream supplied by the data supply unit. It has a data dividing unit that generates a plurality of divided data streams of a transport packet sequence by dividing the data in units of transport packets, and a plurality of data transmitting units that transmit each of the divided divided data streams through different transmission paths. A transmitting device, a plurality of data receiving means for receiving each of the divided data streams transmitted via each transmission path, and multiplexing each of the received divided data streams in transport packet units to form one transport stream Generated data Data transmission system and a receiving apparatus and a data combining unit. 2. The data transmission system according to claim 1, wherein said data division means stores each divided data stream in a buffer, converts a transmission rate of the divided data stream, and outputs the converted data. 3. The data synthesizing means stores the received divided data streams in a plurality of buffers, reads out the divided data streams from each buffer in a predetermined order in units of transport packets, and generates the transport stream. The data transmission system according to claim 1, wherein: 4. The data synthesizing means reproduces a clock of the transport stream based on one of the divided data streams and reads the divided data stream from each buffer using the clock. The data transmission system according to claim 3, wherein: 5. A transmitting apparatus for transmitting digital data in an MPEG transport stream format via a transmission line, comprising: a data supply unit for supplying the transport stream; and a transport stream for supplying the transport stream supplied by the data supply unit. A transmission unit comprising: a data division unit configured to generate a plurality of divided data streams of a transport packet sequence by dividing in units of port packets; and a plurality of data transmission units configured to transmit each of the divided divided data streams via different transmission paths. apparatus. 6. The transmitting apparatus according to claim 5, wherein said data dividing means stores each divided data stream in a buffer, converts a transmission rate of the divided data stream, and outputs the converted data. 7. A data receiving apparatus for receiving digital data in the form of an MPEG transport stream transmitted via a transmission path, comprising the steps of: transmitting a divided data stream of a transport packet sequence transmitted via a plurality of different transmission paths; A receiving device comprising: a plurality of data receiving means for receiving; and a data synthesizing means for multiplexing each of the received divided data streams in units of transport packets to generate one transport stream. 8. The data synthesizing means stores the received divided data streams in a plurality of buffers, and reads the divided data streams from each buffer in a predetermined order in units of transport packets to generate the transport stream. The receiving device according to claim 7, wherein 9. The data synthesizing means reproduces a clock of the transport stream based on one of the divided data streams and reads the divided data stream from each buffer using the clock. The receiving device according to claim 8, wherein: 10. A data transmission method for transmitting digital data in an MPEG transport stream format via a transmission path, wherein the transport stream is input, and the input transport stream is divided into transport packet units. Generating a plurality of divided data streams of a transport packet sequence, transmitting the respective divided data streams by different transmission paths, receiving the respective divided data streams transmitted through the respective transmission paths, A data transmission method characterized by multiplexing received divided data streams in units of transport packets to generate one transport stream. 11. The data transmission method according to claim 10, wherein each divided data stream is stored in a buffer, and a transmission rate of the divided data stream is converted and output. 12. The method according to claim 11, wherein each of the received divided data streams is stored in a plurality of buffers, and the divided data streams are read from each buffer in a predetermined order in units of transport packets to generate the transport stream. The data transmission method according to claim 11. 13. The transport stream clock is reproduced based on one of the divided data streams, and the divided data stream is read from each buffer using the clock. 13. The data transmission method according to item 12.