JP2543940B2 - Voice exchange system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] A voice exchange method for transmitting high-efficiency-encoded voice data by multiplexing other data when there is no voice, and also relates to a voice exchange method when passing through a multistage relay exchange. For the purpose of preventing deterioration of the voice signal, a voice interface unit for generating voice detection information indicating the presence or absence of voice data and voice data encoded with high efficiency from the voice signal, and the voice detection information in the empty area of the voice data. Is multiplexed and given to the transit exchange, and a relay interface unit for separating the voice detection information by the voice data from the relay exchange; and the voice data and the voice detection information provided from the relay interface unit with other data. The signal from the line is multiplexed and transmitted to the line, and the signal from the line is separated into the voice data, the voice detection information and other data, and the voice data and It is composed of a multiplexing / separating unit which gives the voice detection information to the relay interface unit.

[Industrial applications]

The present invention relates to a voice exchange system, and more particularly to a voice exchange system in which high-efficiency coded voice data is multiplexed with other data when there is no voice and transmitted.

As a technique for effectively utilizing a digital line, there is a method of performing high-efficiency coding of a voice signal, performing voice detection, and multiplexing other data when there is no voice. The latter method, which improves the efficiency of voice detection, is a normal telephone conversation and utilizes the fact that the speech rate is 50% or less. When a network is constructed using an efficiency digital multiplexer that combines these two technologies, it is necessary to perform relay exchange with less deterioration of sound quality.

[Conventional technology]

FIG. 3 shows a conventional voice exchange system in an intra-station configuration. 1 is a digital repeater exchange for voice signals connected to a local exchange (PBX), 2 _l to 2 _n are high efficiency digital multiplexers, 3 Is a packet switch, and the voice signal is exchanged by the repeater exchange 1 and sent to any of the efficiency digital multiplexers 2 _l to 2 _n for high efficiency encoding and voice detection to detect voice. The voice data is sent to the line, and when there is no sound, the data from the packet switch 3 is multiplexed and sent.

FIG. 4 shows the above-described efficiency digital multiplexer, in which the voice signal output from the exchange 1 is input to any of the voice interface units 221 to 22m and the voice detecting unit 25i (i) therein. = 1 to m). Then, voice detection is performed here, and the result is sent to the multiplexing / demultiplexing (MUX / DMUX) unit 21. The voice signal is further encoded by the efficiency encoding unit 26i and sent to the multiplexing / separating unit 21, and if the result of voice detection is voiced, the encoded voice signal is
If there is no sound, the packet data from the data interface unit 23 is multiplexed and transmitted to the line via the line interface unit 24. At that time, the multiplexing information indicating which of the packet data the audio signal has multiplexed is also transmitted at the same time.

When receiving from the line, the multiplexing / separating unit 21 determines whether the received data is packet data based on the multiplexing information received. If the data is voice, the data is sent to the voice interface unit 22i, and if it is silent, the data is sent to the data interface unit 23. Communication becomes possible by sending out.

[Problems to be Solved by the Invention]

Conventionally, when the voice signal received from the line is relay-exchanged by the repeater exchange 1 and then sent to the line again, the voice signal is once decoded by the high-efficiency coding unit on the transmission side and is then coded again on the reception side. As shown in FIG. 5, if the voice level at the beginning of the speech is low, the transmitting side determines that the voice is silent and discards the voice signal. Since the sound is judged to be silent, even if there is sound, it is further judged to be silent on the receiving side, and voice degradation due to repeated head disconnection, etc. is unavoidable, and if the number of transit exchanges passing through increases, There is a problem that it gets worse.

Therefore, it is an object of the present invention to realize a voice exchange system in which voice does not deteriorate even when passing through a multistage relay exchange.

[Means for solving the problem]

In the present invention, it has been noticed that it is possible to avoid the voice deterioration due to the multi-stage connection of the voice interface units that perform high-efficiency encoding / decoding and voice detection during the relay exchange of the voice signal. Therefore, when exchanging high-efficiency coded voice data, the fact that empty bits are generated is used to insert voiced / non-voiced voice detection information into voice data and exchange the voice data at the same time. The purpose of this is to eliminate the need for detection, thereby avoiding voice deterioration due to multistage processing of voice detection.

As a means for solving this, a voice exchange system of the present invention is shown in FIG. 1. In the present invention, a voice generating high-efficiency-coded voice data from a voice signal and voice detecting information indicating voice presence / absence are output. Interface units 221 to 22m, and a relay interface unit 4 that multiplexes the voice detection information in an empty area of the voice data and supplies it to the transit exchange 1, and separates the voice detection information from the voice data from the transit exchange 1. , The voice data and the voice detection information provided from the relay interface unit 4 are multiplexed with other data and transmitted to a line, and a signal from rotation is separated into the voice data, the voice detection information and other data. Then, the multiplexer / demultiplexers 211 to 21n for providing the voice data and the voice detection information to the relay interface unit 4 are provided.

[Action]

In FIG. 1, a voice signal is first input to a voice interface unit 22i (i = 1 to m), and after voice detection and high efficiency coding, voice data and voice detection information are multiplexed by a relay interface unit 4. Then, it is input to the transit exchange 1. At this time, in the relay interface unit 4, since the voice signal is compressed and input by the efficiency coding, the voice detection information is inserted into the surplus bit of the voice data and the voice detection information is passed to the relay exchange 1 like normal voice data. It is possible.

After being exchanged by the repeater exchange 1, the relay interface unit 4 separates the voice data and voice detection information, and the multiplexing / separating unit 21i performs multiplexing with other data according to the voice detection information. Send to the line.

Further, the signal from the line side is separated into voice data, voice detection information and other data by a multiplexing / separating unit 21i, and then the relay interface unit 4 multiplexes the voice detection information into an empty area of the voice data and the relay exchange. 1, and after exchange, the relay interface unit 4 separates the voice data and voice detection information, and based on these, the voice interface unit 22i reproduces the voice signal and sends it out.

Therefore, when the input signal from the line is relay-switched to another line, it does not have to pass through the voice interface unit for high-efficiency coding / voice detection.

〔Example〕

FIG. 2 shows an embodiment of the voice exchange system according to the present invention. In this embodiment, the relay interface unit 4 of FIG. 1 is provided with voice data output from each of the voice interface units 221 to 22m. Multiplexing units 271 to 27m for multiplexing voice detection information, and voice interface units 221 to 22m for separating the signal from the repeater exchange 1 into voice data and voice detection information.
Demultiplexing units 281 to 28m, demultiplexing signals from the repeater exchange 1 into voice data and voice detection information and demultiplexing and demultiplexing units 211 to 29n, and demultiplexing units 291 to 29n. Multiplexing units 301 to 30n that multiplex voice data and voice detection information from the demultiplexing units 211 to 21n and send them to the repeater exchange 1, and an interface circuit 41 that performs a digital multiplex interface between the repeater exchange 1 and the relay interface unit 4. ,,. The same one can be used for each of the multiplexing units 271 to 27m and 301 to 30n, and the separating units 281-28m and 291-2 can be used.
The same applies to 9n. Other parts are the same as the conventional ones.

 Next, the operation will be described.

From line i (i = 1 to n) to line interface unit 24i
The signal input via the above is separated into voice data, voice detection information, and packet data inserted when the voice detection information is silent, by the multiplexing / separation unit 21i, of which the packet data is the data interface unit 23. Then, the voice data and the voice detection information are multiplexed by the multiplexing unit 30i of the relay interface unit 4 and transmitted to the relay switch 1 via the interface circuit 41 as if they were normal signals.

The signal exchanged by the repeater exchange 1 is sent to the demultiplexing unit 29j via the interface circuit 41 and again demultiplexed into voice data and voice detection information, and the multiplexing / demultiplexing unit 21j multiplexes the packet data (voice detection information is (When detecting silence)
Then, it is sent from the line interface unit 24j to the line j.

As a result, the signal exchanged from the line i to the line j is a voice interface circuit which performs high efficiency coding and voice detection.
It does not need to pass through 221 to 22m, and there is no disconnection at the beginning of the voice, which does not cause voice deterioration.

When the input signal from the line i is exchanged to the local exchange side, it is separated into voice data and voice detection information by one of the separating units 281 to 28m, and the voice interface unit 221
~ 22m decoding unit 261-26m is reproduced as an audio signal,
In this case and in the case of taking a route opposite to this, the operation is the same as the conventional one.

In addition, the relay interface unit 4 uses, for example, 64 channels per channel in the interface with the relay exchange 1.
It has a capacity of kbps (usually 8 bits in an 8 KHz frame), and voice detection information can be assigned to the surplus bits.

〔The invention's effect〕

As described above, according to the voice exchange system of the present invention, since only voice data and voice detection information are used when the input signal from the line is exchanged with another line, it is necessary to perform high-efficiency coding and voice detection again. In addition, it is possible to prevent the sound quality from being deteriorated at the time of multistage relay exchange.

[Brief description of drawings]

FIG. 1 is a conceptual diagram of a voice exchange system according to the present invention, FIG. 2 is a block diagram showing an embodiment of a voice exchange system according to the present invention, and FIG. 3 is a block showing a voice exchange system in a conventional exchange. FIG. 4 is a block diagram showing the configuration of a conventional high efficiency digital multiplexer, and FIG. 5 is a waveform diagram for explaining voice detection. In FIG. 1, 1 ... Relay switch, 4 ... Relay interface section, 211-21n ... Multiplexing / separating section, 221-22m ... Voice interface section. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

(57) [Claims] 1. A voice interface unit for generating voice data highly efficient encoded from a voice signal and voice detection information indicating presence / absence of voice, and a repeater exchange for multiplexing the voice detection information in an empty area of the voice data. A relay interface section for separating the voice detection information by the voice data from the repeater exchange, and the voice data and the voice detection information given from the relay interface section are multiplexed with other data and sent to a line. In addition, the signal from the line is separated into the voice data, the voice detection information, and other data, and the voice data and the voice detection information are given to the relay interface unit.
A voice exchange system characterized by having a separation section.