JPH10322388A - Digital signal transmission method and digital signal transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a transmission rate of an entire signal from being changed even when a distribution rate of a transmission parameter of each system or a signal to each system is flexibly set in the case of transmitting a digital signal to one system or over through distribution such as hierarchical transmission. SOLUTION: The digital signal transmission system 1 selects number of packets included in one frame time to be a maximum packet number depending on all transmission parameters and combinations of distribution rates to each system or over and to be an integer packet number and allows a digital transmitter 2 to send a difference between the maximum packet number to be sent and a packet number sent actually as null packets based on combination of the distribution rate of th digital signal to each system and the transmission parameter of each system and allows a digital receiver 4 to insert the null packet to the same position and to reproduce a reception signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital signal transmission method and a digital signal transmission apparatus for transmitting a time-division multiplexed digital signal in a fixed-length packet format. TECHNICAL FIELD The present invention relates to a digital signal transmission method and a digital signal transmission device that divide a digital signal and transmit it.

[Summary of the Invention] The present invention relates to a digital signal transmission method for transmitting a time-division multiplexed digital signal in a fixed-length packet format by dividing it into one or more systems and transmitting the digital signal. Null packet (invalid data of the same length as the packet) related to the signal transmission device
To the appropriate number and at the appropriate positions to absorb digital signal transmission ratio fluctuations caused by the distribution ratio of digital signals to each system and differences in transmission parameters of each system, and to transmit digital signals. The rate is kept constant, thereby making it unnecessary to generate a plurality of transmission clocks.

[0003]

2. Description of the Related Art When a time-division multiplexed digital signal is divided into one or more systems and transmitted in a fixed-length packet format, transmission parameters such as transmission capacity of each system are different. When the distribution ratio of the digital signal to the digital signal changes, the transmission rate of the entire digital signal changes. That is, as a specific example of the case where the signal is divided into one or more systems and transmitted, for example, even in the case of one system, the transmission parameter of the digital signal changes as the transmission parameter changes with time. In the case of two or more systems, the transmission rate of the digital signal changes as the transmission parameters of each system and the distribution ratio of the digital signal to each system change over time.

For this reason, when a time-division multiplexed digital signal is divided into one or more systems and transmitted in a fixed-length packet format, a clock signal corresponding to each transmission rate is generated and the digital signal is generated. Is to be processed.

[0005]

However, in the conventional digital signal transmission method described above, if the type of transmission rate is small, a clock signal corresponding to each transmission rate can be generated. When the transmission parameters of each system and the distribution ratio of digital signals to each system are flexibly changed, the burden on the device side increases because clock signals corresponding to all transmission rates must be generated. However, in a case where the cost is required as in the case of a broadcast receiver, there is a problem that the burden on the viewer becomes too large.

In view of the above circumstances, when transmitting a digital signal by dividing it into one or more systems, such as hierarchical transmission, the present invention flexibly changes the transmission parameters of each system and the distribution ratio of signals to each system. , The transmission rate of the entire signal can be kept unchanged, thereby simplifying the clock generator of the transceiver and achieving a low cost receiver. And a digital signal transmission device.

[0007]

In order to achieve the above object, according to the present invention, a time division multiplexed digital signal in a fixed length packet format is divided into one or more systems. In the digital signal transmission method for transmission, among all combinations for distributing each packet to each system, the transmission clock signal corresponding to the combination that has the maximum number of packets is used, and the ratio of distributing the digital signal to each system is The transmission / reception is characterized in that the difference between the actual number of packets determined by the combination of the transmission parameters of each system and the maximum number of packets is a null packet.

According to a second aspect of the present invention, in the digital signal transmission method according to the first aspect, a time information such as a clock reference is correctly added to a digital signal including a null packet, so that a fixed clock signal is received on a receiving side. It is characterized in that the received signal can be reproduced using the signal.

According to a third aspect of the present invention, in the digital signal transmission method according to the first or second aspect, the receiving side inserts a null packet at the same position as the null packet inserted on the transmitting side to convert the received signal. It is characterized by reproduction.

According to the first to third aspects, when a digital signal is transmitted after being divided into one or more systems such as hierarchical transmission, the transmission parameters of each system and the distribution of signals to each system are transmitted. Even if the ratio is set flexibly, it is possible to prevent the transmission rate of the entire signal from changing. This simplifies the clock generator of the transceiver and achieves a low cost receiver.

According to a fourth aspect of the present invention, there is provided a digital signal transmission apparatus for transmitting and receiving a time-division multiplexed digital signal in one or more systems in a fixed-length packet format.
Among all combinations for distributing each packet to each system, use the transmission clock signal corresponding to the combination that maximizes the number of packets, and distribute the digital signal to each system and the transmission parameter of each system. It is characterized in that a transmitter for generating a transmission signal by converting a difference between the actual number of packets transmitted in combination and the maximum number of packets into a null packet is provided.

According to a fifth aspect of the present invention, there is provided a digital signal transmission apparatus for transmitting / receiving a time-division multiplexed digital signal in one or more systems in a fixed-length packet format.
Among all combinations for distributing each packet to each system, use the transmission clock signal corresponding to the combination that maximizes the number of packets, and distribute the digital signal to each system and the transmission parameter of each system. It is characterized in that a receiver for reproducing a received signal by converting a difference between the actual number of packets transmitted in combination and the maximum number of packets into a null packet is provided.

According to claim 6, claim 4 or claim 5
In the digital signal transmission device according to the above, the transmitter correctly attaches time information such as a clock reference to the digital signal including the null packet, the receiver uses a fixed clock signal, the received signal It is characterized by reproducing.

According to a seventh aspect of the present invention, in the digital signal transmission apparatus according to the fifth aspect, the receiver reproduces a received signal by inserting a null packet at the same position as the null packet inserted on the transmitter side. It is characterized by doing.

According to the fourth to seventh aspects, when a digital signal is transmitted after being divided into one or more systems such as hierarchical transmission, the transmission parameters of each system and the distribution of signals to each system Even if the ratio is set flexibly, the transmission rate of the entire signal is kept unchanged, thereby simplifying the clock generator of the transceiver and achieving a lower cost on the receiver side.

<< Description of the Principle of the Invention >> First, prior to the detailed description of the digital signal transmission method and the digital signal transmission device according to the present invention, the basic principle of the present invention will be described.

As a digital signal time-division multiplexed in a fixed-length packet format, an international standard (ISO / IEC13)
Consider the MPEG-2 transport stream (TS) of 818-1).

This transport stream is basically based on a transport stream packet (TSP) having a packet length of 188 bytes, as shown in FIG. 3, but is used as an error correction code of this transport stream packet (204, 204). 188) Reed-Solomon code,
Alternatively, a check code (C) such as another block code is added, and in the case of a Reed-Solomon code of (204, 188), 204 bytes as a whole, and in the case of another block code, (188 + C) bytes as a transport stream. It may be treated as the packet length of the packet.

As a digital transmission system for dividing and transmitting such a digital signal into one or more systems, there are various methods, for example, using a certain fixed time (frame time) as a cycle unit, a temporal modulation system, an error There is a time division multiplexing method for switching a correction method and the like. Further, in a frequency division multiplexing method for transmitting digital signals using a plurality of carriers such as OFDM, there is a method of changing a modulation method and an error correction method for each carrier.

Here, of these digital signal transmission methods, the basic principle of the present invention will be described by taking the OFDM system as an example.

First, in all combinations of the distribution ratio of digital signals to each system and the transmission parameters of each system, the amount of digital signals transmitted by all the systems in a certain time (frame time) is calculated. , Can be transmitted by an integer number of packets, as shown in FIG.
Consider a case in which an integer number of OFDM blocks having a bandwidth of 100 kHz are continuously arranged in the frequency axis direction to form an OFDM signal.

In this case, each OFDM block has 24 carriers and uses QPSK as a carrier modulation method.
One of three modulation schemes, a modulation scheme, a 16QAM modulation scheme, and a 64QAM modulation scheme, is used, and a Reed-Solomon code of (204, 188) is used as an error correction scheme.
It is assumed that a method of combining with a convolutional code is used. As a coding rate of the convolutional code, a 1/2 convolutional coding method in which one digital signal is convoluted into two digital signals, and a 3/4 convolutional code in which three digital signals are convolved into four digital signals. And any one of three types of a 7/8 convolutional coding method for convolving 7 digital signals into 8 digital signals, and further, for each OFDM block, these carrier modulation method and error correction method. And can be set.

Here, assuming that the number of effective symbols of the OFDM frame is 272, the number of transport stream packets included in the OFDM frame of one OFDM block changes as shown in FIG. 5 according to the transmission parameters of each system. I do.

In a system that continuously transmits an arbitrary number of OFDM blocks, for example, a transmission system having a bandwidth of 5.6 MHz composed of 56 OFDM blocks, each OFDM block determines which transmission parameter in FIG. Even if used, an integer number of transport stream packets are transmitted during the OFDM frame time.

At this time, even if an OFDM wave having the same 5.6 MHz bandwidth is focused on the number of transport stream packets transmitted within the same OFDM frame length, the carrier modulation method is the QPSK modulation method, the convolutional code. If the conversion rate is halved, 4 × 56 transport stream packets can be transmitted,
If the carrier modulation scheme is 64QAM and the convolutional coding rate is 7/8, 21 × 56 transport stream packets can be transmitted. Therefore, according to the carrier modulation scheme and the convolutional coding rate, The number of transport stream packets that can be transmitted changes to various values in a range from 4 × 56 to 21 × 56.

For this reason, it is necessary to generate various kinds of clock signals according to the change in the number of transport stream packets for the transport stream encoding processing on the transmitter side and the transport stream decoding processing on the receiver side. is there. For this reason, this has been a major problem in receivers that are required to be inexpensive.

Therefore, in the digital signal transmission method and the digital signal transmission device according to the present invention, as shown in FIG. 6, a transport stream encoding process on a transmitter side and a transport stream decoding process on a receiver side are performed. As a port stream, the number of transport stream packets included in one frame time is equal to or larger than the maximum number of transport stream packets among combinations of all transmission parameters and distribution ratios to each system, and an integer. The maximum number of transport stream packets that can be transmitted, and the transport stream that is actually transmitted, in combination with the number of transport stream packets, the distribution ratio of digital signals to each system, and the transmission parameters of each system Difference from the number of packets The by the null packet, the distribution ratio of the digital signal to the respective systems, the combination of the transmission parameters of each system, transmission capacity be varied, and a constant transmission rate of the digital signal.

That is, considering the case of FIG.
64 QAM for a transmission system with a bandwidth of MHz
When the modulation scheme is combined with the convolutional coding rate of 7/8, the number of transport stream packets included in the frame time is set to the maximum of 2 among all combinations.
1 × 56 = 1176. Thus, the frequency C of the transport stream transmission clock signal
Is selected as C ≧ (21 × 56) / (frame time) (1), and this is kept constant.

Here, in order to minimize the frequency C of the transport stream transmission clock signal, C = (21 × 56) / (frame time).
For example, it is possible to select a clock signal having a simple integer ratio with respect to a clock signal generated in another part on the receiver side, such as a sample clock signal of an OFDM signal. In order to simplify the generation circuit, the above equation (1) is made unequal, leaving a range of choices.

When the transmission clock signal of the transport stream satisfies the condition of the above equation (1), the clock signal becomes a clock signal having a frequency higher than a required frequency by the number of transport stream packets actually transmitted. And null data (invalid data) for interpolation between the transport stream packet and the transport stream packet. However, when considered on the receiver side, if the interval of the transport stream packets input to the transport stream decoder becomes irregular due to the inserted null data, the processing becomes complicated.

Therefore, as shown in the following equation, the frequency C of the clock signal is selected and the length of the null data is set to the length of the transport stream packet so that an integer number of transport stream packets can be transmitted in one frame time. Thus, the processing on the transport stream decoder side is facilitated. This gives the integer N
Is appropriately selected to ensure consistency with the clock signal generated in another part of the receiver.

C = (21 × 56 + N) / (frame time) (2) where N is an integer. Thus, the carrier modulation scheme and the convolutional code are 6
In the case of a combination other than the combination of 4QAM and 7/8, for example, a part of 2.0 MHz (20 OFDM blocks) is combined with a QPSK modulation scheme and a 1/2 convolutional coding rate, and 2 .6 MHz (2
(6 OFDM blocks) is combined with a 64QAM modulation scheme and a 3/4 convolutional coding rate, and when layered transmission is performed, the number of transport stream packets included in the frame time is 4 × 20 + 18 × 26.
= 548. At this time, if the frequency C of the transport clock signal of the transport stream is selected so as to satisfy the condition of the above equation (2), 1176 + N-548 = 628 + N null packets are inserted for the transport stream processing. Will be.

The transport stream is a PC
Since calibration information of standard time called R (Program Clock Reference) is transmitted and time information is sent to the receiver, FIG.
As shown in (1), when a null packet is inserted between the transport stream packet of PCR-0 and the transport stream packet of PCR-1, this P
The position of the CR-1 transport stream packet shifts, and time information cannot be transmitted accurately.

Therefore, in order to prevent such inconvenience, with the null packet inserted, the P time is adjusted so that the time information of each transport stream packet is correct.
Attach CR. However, since the null packet is not actually transmitted, it is necessary to insert the null packet at the same position as the transmitting side in order for the receiver to correctly reproduce the PCR correctly attached including the null packet. There is. Three examples for that purpose will be shown.

<First Method> In a first method, a null packet insertion position is transmitted as a signal different from a transport stream packet. For example, a number indicating the order is assigned to all packets including a null packet included in one frame, and the number of the position of the null packet or a packet number including information is transmitted as another signal.

<Second Method> In the second method, a null packet insertion position is indicated in a header of a transport stream packet. For example, included in one frame,
A number indicating the order is attached to the header part of all packets including the null packet. As a result, the number of the null packet is not transmitted, but becomes a missing number, so that the number of the position of the null packet can be known. <Third method> The third method is as follows.
The transmitting side and the receiving side use the same algorithm to insert a null packet at the same position.

<< Description of Embodiment >> FIG. 1 is a block diagram of a digital signal transmission device showing an embodiment of a digital signal transmission method and a digital signal transmission device according to the present invention.

The digital signal transmission device 1 shown in FIG.
As a digital signal to be transmitted, a transport stream in which null packets are inserted in a form suitable for a hierarchical structure is generated, and this transport stream is
A digital transmitter 2 that converts the signal into an FDM signal and sends the signal to a transmission path 3, and an OFDM signal that is sent to the transmission path 3
After receiving the signal and performing FFT processing on the signal to reproduce the transport stream packet for each layer, the transport stream packet for each layer and the null packet are combined to reproduce the transmitted digital signal. And a digital receiver 4.

The digital transmitter 2 inserts a required number of null packets as a digital signal to be transmitted using a preset algorithm to generate a transport stream suitable for a hierarchical structure. At the same time, after this signal is divided and processed into layers for each transport stream packet, an OFDM signal is generated and transmitted on the transmission path 3. Digital receiver 4
The side receives the OFDM signal transmitted on the transmission path 3, performs FFT processing on the OFDM signal, reproduces transport stream packets for each layer, and uses the same algorithm as the digital transmitter 2 side. , And combines the transport stream packet and the null packet of each layer, and reproduces the transmitted transport stream.

At this time, the null packet insertion unit 6 provided on the digital receiver 4 side is, for example, divided into three systems and transmitted to the transmission path 3 as shown in FIG.
A DM signal is fetched, subjected to FFT processing, a serial signal arranged in a predetermined order, for example, from low symbol to high symbol on the frequency axis is input, and a hierarchical dividing circuit 7 for distributing this signal to each hierarchical layer; And three hierarchical processing circuits 8a to 8c for performing demodulation processing, error correction processing using convolutional codes, de-interleaving processing, and the like in the same processing time for each hierarchical layer output from each hierarchical layer. These hierarchical processing circuits 8a to 8c
Buffering the digital signal obtained in step 3 to absorb the processing time difference and temporarily store it for hierarchical synthesis 3
Buffer circuits 9a to 9c, a null packet circuit 10 for generating a null packet, and buffer circuits 9a to 9c
And a digital signal transmitted from the digital transmitter 2 is reproduced by inserting a null packet output from the null packet circuit 10 into a missing portion, and synthesizing the digital signal temporarily stored in the digital transmitter 2. And a circuit 11. The positions of the buffer circuits 9a to 9c have nothing to do with the actual positions on the circuits.

At this time, the OF inputted to the hierarchical division circuit 7
Since the DM signal is a serial signal, data of one packet is not simultaneously generated in each of the buffer circuits 9a to 9c.

When an OFDM signal is input via the transmission line 3, the OFDM signal is divided for each layer and processed by each of the layer processing circuits 8a to 8c of each layer. 9c.

After that, the buffer circuits 9a to 9c are checked by the hierarchical synthesizing circuit 11, and if there is a buffer circuit in which data of one packet is prepared, all the packets temporarily stored in this buffer circuit are read out. When data of one packet or more is stored in one or more layers, packets are read from these buffer circuits in the order of the buffer circuit stored first and the buffer circuit stored later. Then, when these data are combined and one or more blocks do not exist in any of the buffer circuits 9a to 9c, a null packet output from the packet circuit 10 is used to reproduce the data.

The null packet insertion unit 5 provided on the digital transmitter 2 also uses the same algorithm as the null packet insertion unit 6 provided on the digital receiver 4 to convert transport stream packets including null packets. Generate.

As described above, in this embodiment, the number of packets included in the frame time is determined by using all transmission parameters,
The number of packets must be an integer equal to or greater than the maximum number of packets in combination with the distribution ratio to each system, and the transmission is performed by combining the distribution ratio of the digital signal to each system and the transmission parameter of each system. By making the difference from the packet to be a null packet, the transmission rate of the digital signal is kept constant even if the transmission capacity fluctuates due to the combination of the distribution ratio of the digital signal to each system and the transmission parameter of each system. Therefore, when digital signals are transmitted by dividing them into one or more systems such as hierarchical transmission, even if the transmission parameters of each system and the distribution ratio of signals to each system are set flexibly, The overall transmission rate can be kept unchanged, thereby simplifying the clock generator of the transceiver and reducing the cost of the receiver.

Further, in this embodiment, a null packet insertion algorithm on the digital transmitter 2 side and a null packet insertion algorithm on the digital receiver 4 side are
Since the same algorithm is used, the digital receiver 4 can accurately reproduce the time information such as the time stamp included in the transport stream packet, and can convert the digital signal at a fixed rate. It can be decoded as it is.

Further, in this embodiment, the third method is used in order to correctly reproduce the PCR correctly attached in the form including the null packet by the receiver. Alternatively, the second method may be used.

[0048]

As described above, according to the present invention, when a digital signal is transmitted after being divided into one or more systems such as hierarchical transmission, the transmission parameters of each system and the transmission of signals to each system are Even if the distribution ratio is set flexibly, the transmission rate of the entire signal can be kept unchanged, whereby the clock generator of the transceiver can be simplified and the cost of the receiver can be reduced. .

[Brief description of the drawings]

FIG. 1 is a block diagram of a digital signal transmission device showing an embodiment of a digital signal transmission method and a digital signal transmission device according to the present invention.

FIG. 2 is a block diagram showing a detailed circuit configuration example of a null packet insertion unit provided on the digital receiver side shown in FIG.

FIG. 3 is a schematic diagram showing an example of a transport stream used for explaining a basic principle of the present invention.

FIG. 4 shows an OF used in explaining the basic principle of the present invention.
FIG. 3 is a schematic diagram illustrating an example of a DM signal.

FIG. 5: Transmission parameters and OFDM block 1 OFDM
FIG. 4 is an explanatory diagram showing the number of TSPs per frame.

FIG. 6 is a schematic diagram illustrating an example of a transmission signal used in a digital signal transmission method and a digital signal transmission device according to the present invention.

FIG. 7 is a schematic diagram showing an example of a transport stream used for explaining the basic principle of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Digital signal transmission apparatus 2 Digital transmitter 3 Transmission path 4 Digital receiver 5, 6 Null packet insertion part 7 Hierarchical division circuit 8a-8c Hierarchical processing circuit 9a-9c Buffer circuit 10 Null packet circuit 11 Hierarchical synthesis circuit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Shunji Nakahara 1-10-11 Kinuta, Setagaya-ku, Tokyo Inside the Japan Broadcasting Corporation Research Institute (72) Inventor Masayuki Takada 1-110 Kinuta, Setagaya-ku, Tokyo No. Japan Broadcasting Corporation Research Institute of Broadcasting (72) Kenichi Tsuchida 1-10-11 Kinuta, Setagaya-ku, Tokyo Japan Broadcasting Research Institute of Japan Broadcasting Corporation (72) Masahiro Okano 1-10 Kinuta, Setagaya-ku, Tokyo No. 11 Inside Japan Broadcasting Corporation Broadcasting Research Institute (72) Inventor Makoto Sasaki 1-10-11 Kinuta, Setagaya-ku, Tokyo Inside Japan Broadcasting Corporation Broadcasting Research Institute (72) Inventor Takeshi Kimura Nishi Asakusa, Taito-ku, Tokyo 1-1-1 1-1 Kan @ Asakusa Building 8F Next-generation Information Broadcasting System Laboratory Co., Ltd.

Claims (7)

[Claims] 1. A digital signal transmission method for dividing a time-division multiplexed digital signal into one or more systems in a fixed-length packet format and transmitting the divided signals, wherein all combinations of distributing each packet to each system are included. Then, using the transmission clock signal corresponding to the combination that provides the maximum number of packets, the ratio of distributing the digital signal to each system, the actual number of packets determined by the combination of the transmission parameters of each system, and the maximum number of packets A digital signal transmission method characterized in that the difference between the digital signal transmission and reception is performed by making a difference from the null packet a null packet. 2. The digital signal transmission method according to claim 1, wherein a time information such as a clock reference is correctly attached to the digital signal including the null packet, so that the receiving side uses a constant clock signal. A digital signal transmission method characterized in that a received signal can be reproduced. 3. The digital signal transmission method according to claim 1, wherein the receiving side reproduces the received signal by inserting a null packet at the same position as the null packet inserted on the transmitting side. Digital signal transmission method. 4. A digital signal transmission apparatus for transmitting and receiving a time-division multiplexed digital signal in one or more systems in a fixed-length packet format, wherein all combinations of distributing each packet to each system are provided. In this case, using the transmission clock signal corresponding to the combination that provides the maximum number of packets, the ratio of distributing the digital signal to each system, the actual number of packets transmitted in combination with the transmission parameters of each system, and the maximum A digital signal transmission device, comprising: a transmitter that generates a transmission signal by converting a difference from the number of packets into a null packet. 5. A digital signal transmission apparatus for transmitting / receiving a time-division multiplexed digital signal in one or more systems in a fixed-length packet format, wherein all combinations of distributing each packet to each system are included. In this case, using the transmission clock signal corresponding to the combination that provides the maximum number of packets, the ratio of distributing the digital signal to each system, the actual number of packets transmitted in combination with the transmission parameters of each system, and the maximum A digital signal transmission device comprising a receiver for converting a difference from the number of packets into a null packet to reproduce a received signal. 6. The digital signal transmission device according to claim 4, wherein the transmitter correctly attaches time information such as a clock reference to the digital signal including the null packet, and the receiver includes: A digital signal transmission device for reproducing a received signal using a fixed clock signal. 7. The digital signal transmission device according to claim 5, wherein the receiver inserts a null packet at the same position as the null packet inserted on the transmitter side, and reproduces a received signal. Digital signal transmission device.