JP2002009727A - Ac transmission/reception method for ofdm transmission system, transmitting apparatus and receiving apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To overcome a problem of a conventional AC transmission/reception method for the OFDM transmission system that some difficulties are caused when applying this method to an audio signal transmission-back or the like and in the production of a relay program because of production of a frame delay causing a transmission delay of 100 ms or over when an audio signal subjected to error correction similar to the case of the TMCC is transmitted through an AC(Auxiliary Channel) of a ground digital broadcast. SOLUTION: In the transmission of an audio signal through the use of the AC of the ground digital broadcast, the configuration of an AC packet is designated by a bit placed in the vicinity of the head of a frame, and a parity bit for error correction in the unit of frames is not transmitted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an AC (Auxiliary Channel) for an OFDM transmission system for digital terrestrial broadcasting and the like.
: Additional information channel) transmission / reception method and transmission device,
It relates to a receiving device.

[0002]

2. Description of the Related Art The transmission systems of Japanese terrestrial digital television broadcasting and terrestrial digital audio broadcasting have different bandwidths, but the transmission systems are almost the same. Hereinafter, unless otherwise specified, both transmission systems are collectively referred to as terrestrial digital broadcasting.

[0003] Digital terrestrial broadcasting in Japan is called ISDB-T and employs a modulation method called OFDM. OF
DM is a multi-carrier modulation method using a plurality of carriers. ISDB-T is composed of an OFDM segment having a bandwidth of about 430 kHz, and becomes a terrestrial digital television broadcasting system when 13 OFDM segments are used, and becomes a terrestrial digital audio broadcasting system when one or three OFDM segments are used. . Note that there are two types of OFDM segments: a synchronous system segment configuration and a differential system segment configuration.

[0004] Table 1 shows ISDB-T transmission specifications.

[0005]

[Table 1] ISDB-T has three types of modes, each having a different number of carriers, a carrier interval, an effective symbol length, and the like. The number of carriers per OFDM segment is
There are 108 lines in mode 1, 216 lines in mode 2, and 432 lines in mode 3. The carrier intervals are about 4 kHz, about 2 kHz, and about 1 kHz, respectively, corresponding to the above. The effective symbol length is the reciprocal of the carrier interval, which is 252 μs, 5
04 μs and 1008 μs.

[0006] In addition, there is a guard interval in the effective symbol, which is a time zone for reducing interference, and the effective symbol and the guard interval are collectively called a symbol. The guard interval length is １ ／, ８ of the effective symbol length,
There are four types, 1/16 and 1/32. One frame is 204
Since one frame length is a symbol, the guard interval length is set to 1/4 of the effective symbol length.
About 65 ms in mode 2, about 130 ms in mode 2, mode 3
It is about 260 ms.

[0007] Further, among OFDM carriers,
In addition to a carrier for transmitting data, there is a transmission control carrier called TMCC and a carrier for an additional information transmission channel called AC. Both TMCC and AC can transmit 204 bits per frame. There are two types of ACs, AC1 and AC2. AC1 is a carrier common to both the synchronous segment configuration and the differential segment configuration, and AC2 is a carrier only available in the differential segment configuration. For example, in the case of mode 1, there are two AC1 in the synchronous system segment, and there are two AC1 and four AC2 in the differential system segment. In the case of mode 3, there are eight ACls in the synchronous system segment, eight ACls in the differential system segment, and AC
There are 19 of them.

[0008]

When an audio signal is transmitted using the AC of an OFDM transmission system such as terrestrial digital broadcasting, a frame delay occurs if the same error correction is performed as in the case of TMCC. Due to the above transmission delay, for example, when producing a relay program,
There is a problem to be solved that is difficult to use when used for sending back audio.

It is an object of the present invention to provide a digital broadcasting system for digital terrestrial broadcasting and the like.
When transmitting an audio signal using the AC of the FDM transmission system, the transmission delay between transmission and reception is made as short as possible (for example, 100 ms or less) by devising a transmission method and a reception method.
It is to make.

[0010]

To achieve the above object, an AC transmission method for an OFDM transmission system according to the present invention comprises:
In the AC transmission method of the FDM transmission system, at the time of transmission, A
It is characterized in that the configuration of the C packet is specified.

Further, the AC of the OFDM transmission system of the present invention
The transmission method is characterized in that parity bits for error correction in frame units are not transmitted during transmission.

Also, the AC of the OFDM transmission system of the present invention
The transmission method is characterized in that a plurality of AC carriers are used, and when bits are allocated to data portions of the AC carriers, the bits are sequentially and cyclically allocated to different AC carriers.

Further, the AC of the OFDM transmission system of the present invention
The transmitting device includes: means for encoding voice to be transmitted by AC transmission; means for selecting an AC carrier for transmitting voice coded by the means; service identification of information to be transmitted prior to transmission; Means for specifying a number, a means for setting the packet header portion of the AC carrier selected by the means for selection on the basis of the service identification and line number specified by the means for specifying, and a means for setting In packet number order
The apparatus further comprises means for writing the voice encoded by the encoding means in the form of a packet header set by the setting means.

The AC of the OFDM transmission system of the present invention
The receiving method is characterized in that, in the AC receiving method for digital terrestrial broadcasting, the AC carrier data transmitted according to the present invention is sequentially decoded from the beginning of the frame.

Further, the AC of the OFDM transmission system of the present invention
The receiving apparatus includes: means for detecting all AC carriers from a received OFDM signal; checking the configuration of an AC packet for all AC carriers detected by the means; and extracting an AC packet having a configuration obtained as a result. Extracting means, prior to reception, means for specifying service identification and line number of information to be received, and among the AC packets extracted by the first extracting means, service identification and line number matching the specification. A second extraction unit for extracting the AC packet, the second extraction unit extracting the AC packet,
Reading means for reading the number of packets per frame of the service identification and line number matching the specification, reading data in order of packet number in ascending symbol number, decoding the data read by the reading means, It is characterized by comprising means for reproducing.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on embodiments of the present invention with reference to the accompanying drawings. Figure 1
Shows a configuration example of a 204-bit AC used in the terrestrial digital broadcast AC transmission / reception method to which the present invention is applied. FIG. 1A shows the basic configuration of an AC. At the beginning, there is a reference bit for differential demodulation, followed by a packet header, followed by data. The configuration of the AC packet is the same as the configuration of FIG.
The configuration shown in FIG. 1B is a configuration in which there is no error correction in a packet unit (this is referred to as a configuration 1), and the configuration shown in FIG. It is assumed that the configuration has error correction (this is referred to as configuration 2).
Note that a code obtained by shortening (273, 191) of the difference set cyclic code may be used as the correction code in the case where there is error correction.

Table 2 shows an example of the contents of a packet when an audio signal is transmitted using the AC packet having the configuration 1 shown in FIG. 1B.

[0018]

[Table 2]In Table 2, bit number C₀ Indicates the standard for differential demodulation
And bit number C₁ ~ C _Three Is FEC (Forward Error Co)
rrection) Identification of presence or absence (identification of configuration 1 or configuration 2)
Is shown. Bit number C_Four ~ C₆ Is service knowledge
Identify the audio coding system and identify the content to be transmitted
Is shown. Further, bit number C₇ ~ C_TenIs the line number
And the line segment when transmitting multiple lines of audio signals
Use for another. Bit number C₁₁~ C₁₄Is a packet
Number, bit number C_Fifteen~ C₁₈The packet indicated by
The number of the packet in the number is shown.

The bit numbers C _{15 to} C ₁₈ are the bit numbers C _{7 of the} service identification indicated by the bit numbers C _{4 to} C _6.
For line number indicated by -C _10, it indicates the number of packets transmitted in one frame. Bit number C ₁₉ ~C
₂₃ indicates the parity or error detection code of the packet header. Parity bit number C ₁₉ -C _23, for example, (31, 26) but codes shortened BCH code is considered, and may be other code. In addition, CRC (Cyclic R
An error detection code based on edundancy check) may be used. The bit number C ₂₄ -C ₂₀₃ is data.

FIG. 2 shows an example of the transmission order when an audio signal is transmitted using AC packets having the packet contents shown in Table 2. Here, it is assumed that the AC packet having the configuration 1 transmits the service packet with the service identification S0 and the line number CH0. FIG. 2 shows the service identification S
0 indicates an AC packet of only the line number CH0, in which the number of packets is 4 and the packet number is 0 to 3. Bits are sequentially allocated in the order of packet numbers 0, 1, 2, 3, 0, 1, 2, 3,..., One bit at a time from the bit of the data portion next to the packet header, and transmitted.

FIG. 3 shows the AC of the terrestrial digital broadcasting described above.
FIG. 2 shows in a block diagram one embodiment of a transmission device according to the invention for use in a transmission / reception method. In FIG. 3, 1 is OFDM.
The modulator 2 is a speech coding device, 3 is a transmitter, and 4 is an antenna. In FIG. 3, a video / audio signal for broadcasting of digital terrestrial broadcasting is supplied to an OFDM modulator 1 and assigned to a data carrier. On the other hand, an audio signal to be transmitted using AC is first encoded by an audio encoding device 2 and then supplied to an OFDM modulator 1 and allocated to an AC carrier. The broadcast video / audio signal and the AC audio signal framed in the OFDM modulator 1 are sent to the transmitter 3 and radiated from the antenna 4 as terrestrial broadcast waves.

FIG. 4 supplements the description of the transmitting device.
As a more detailed description of transmitting audio information using AC, an example of the flow of signal processing is shown in a flowchart. Here, it is assumed that the voice information is transmitted using the service identification S0 and the line number CH0 as described above. First, the audio information (401) is encoded (402) by a low bit rate audio encoding method such as VSELP used in a mobile phone or the like. At the time of this encoding, the error may be protected by an error correction code such as convolutional encoding simultaneously with the audio encoding. Next, an AC carrier for transmitting the encoded audio information is selected (403).

In the selection of the AC carrier, a transmission capacity capable of sufficiently transmitting encoded audio information is ensured, and selection is made as randomly as possible within the transmission band. In order to send voice information, for example, the service identification S0 and the line number CH0 are designated (404). The packet header part of the AC carrier selected according to this designation is set (405). That is, as shown in FIG.
(Forward Error Correction) The identification is set to 000, the service identification is set to S0, the line number is set to CH0, the number of packets used in one frame, the packet number is set, and the parity of the packet header part is set (405). Next, audio data is written one bit at a time in the order of the set packet numbers (406). The selection of the AC carrier (4)
In 03), the same AC carrier may be selected for each frame.

FIG. 5 is a flowchart showing an example of the flow of signal processing in the case of receiving audio information transmitted using AC. Here also, the voice information includes the service identification S0 and the line number CH0 as described above.
And transmitted using First, the received OFD
All AC carriers are detected from the M signal (501). Next, for all the detected AC carriers, the configuration of the AC packet, for example, the FEC identification is checked, and the AC of configuration 1 is checked.
The packet is extracted (502). On the other hand, prior to the reception, the service identification S0 and the line number CH0 of the audio information to be received are designated (503). By this designation, only the AC packet with the service identification S0 and the line number CH0 is extracted from the extracted AC packets of the configuration 1 (5).
04).

Subsequently, service identification S0, line number C
The number of packets per frame of H0 is read, and data is read in the order of packet number from the smaller symbol number (505). The read data is sent to the audio decoding unit, and the transmitted audio is sequentially reproduced (506).

The speech coding methods usable in the present invention include VSELP, P
SI-CELP, CS-ACELP and the like are conceivable.
According to these encoding methods, 5.6 to 11.2 kbp
A telephone quality voice can be transmitted with a transmission capacity of s and a transmission delay time of 100 ms or less.

Although the above-described embodiment of the present invention is an example in which short delay time transmission is performed using AC of terrestrial digital broadcasting, the present invention is not limited to terrestrial digital broadcasting. The present invention can be applied to other transmission systems such as a digital FPU using OFDM.

[0028]

According to the present invention, the digital terrestrial broadcasting A
When an audio signal is transmitted using C (Auxiliary Channel), A is transmitted by bits arranged near the beginning of the frame.
By specifying the configuration of the C packet and not transmitting parity bits for error correction in frame units, the audio signal can be transmitted with a short delay time without concern for the transmission frame length due to the difference in mode. It becomes possible to transmit.

[Brief description of the drawings]

FIG. 1 shows a configuration example of a 204-bit AC used in an AC transmission / reception method of digital terrestrial broadcasting to which the present invention is applied.

FIG. 2 shows an example of a transmission order when an audio signal is transmitted using an AC packet having the packet contents shown in Table 2.

FIG. 3 is a block diagram showing an embodiment of a transmission device according to the present invention.

FIG. 4 is a flowchart illustrating an example of a flow of signal processing in a case where audio information is transmitted using AC.

FIG. 5 is a flowchart illustrating an example of a flow of signal processing when audio information transmitted using AC is received.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 OFDM modulator 2 voice coding device 3 transmitter 4 antenna

Continued on the front page (72) Inventor Makoto Sasaki 1-10-11 Kinuta, Setagaya-ku, Tokyo Japan Broadcasting Corporation Japan Broadcasting Research Institute (72) Inventor Shigeki Moriyama 1-10-11 Kinuta, Setagaya-ku, Tokyo Japan Transmission Association F-Term (in reference) 5C063 AA20 AB03 AB07 AC01 AC05 CA11 CA12 CA20 DA05 DA07 DA13 5K022 DD01 DD13 DD17 DD19 DD21 DD31

Claims (6)

[Claims] 1. An AC transmission method for an OFDM transmission system, wherein the configuration of an AC packet is specified by bits arranged near the beginning of a frame during transmission. 2. The AC transmission method according to claim 1, wherein
An AC transmission method for an OFDM transmission system, wherein a parity bit for error correction in a frame unit is not transmitted during transmission. 3. The AC transmission method according to claim 1, wherein a plurality of AC carriers are used, and when bits are allocated to a data portion of the AC carriers, the bits are sequentially and cyclically allocated to different AC carriers. An AC transmission method for an OFDM transmission system. 4. A means for encoding audio to be transmitted by AC, and an AC for transmitting audio encoded by said means.
Means for selecting a carrier, prior to transmission, means for specifying service identification and line number of information to be transmitted, and a packet header portion of the AC carrier selected by the selecting means, specified by the specifying means. Service identification, means for setting based on the line number, and, in the order of the packet numbers set by the setting means, the voice coded by the coding means in the packet header portion set by the setting means. OFD comprising means for writing in an aspect
AC transmission device of M transmission system. 5. An OFDM transmission method according to claim 1, wherein the AC carrier data transmitted according to any one of claims 1 to 3 is sequentially decoded from the beginning of the frame. AC receiving method of transmission system. 6. A means for detecting all AC carriers from a received OFDM signal, wherein A means for all AC carriers detected by the means.
First extracting means for checking the structure of the C packet and extracting an AC packet having the resulting structure; means for designating a service identification and a line number of information to be received prior to reception; Second extraction means for extracting, from the AC packets extracted by the means, an AC packet having the designated line number and an AC packet having a line number; and a service identification extracted by the second extraction means and conforming to the designated section. Reading means for reading the number of packets per frame of the line number, reading data in order of packet number from the smallest symbol number, and means for decoding the data read by the reading means and sequentially reproducing audio. An AC receiving device for an OFDM transmission system.