JPH0766904A - Multiplexed communication equipment - Google Patents

Abstract

PURPOSE:To provide the multiplexed communication equipment which can transmit non-voice data in a real time without causing the quality deterioration of voice data in the course of transmission. CONSTITUTION:This equipment is provided with a silent section detecting means 8 for detecting a silent section in the course of transmitting voice data, and a vowel stationary section detecting means 9 for detecting a vowel stationary section in the course of transmitting the voice data, and in the case the silent section and the vowel stationary section in the course of transmitting the voice data are detected by the silent section detecting means 8 and the vowel stationary section detecting means 9, it is instructed to transmit non-voice data, also, it is instructed to transmit the voice data in a sound section in the course of transmitting the voice data, and in the case the silent section and the vowel stationary section in the course of transmitting the voice data are detected by the silent section detecting means 8 and the vowel stationary section detecting means 9, it is instructed to stop the transmission of the voice data, and on the other hand, in the case the received non-voice data is that which is transmitted to the sound section, the voice is corrected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multiplex communication device for multiplexing voice data and non-voice data on a digital line by using slot switching.

[0002]

2. Description of the Related Art In recent years, a telewriting device has been developed for frequency-multiplexing voice data and non-voice data such as drawing information on an analog line for communication. Also, P
As various digital network platforms such as HP network and ISDN network have been developed, the need for a telewriting device for time-division multiplexing voice and non-voice data on a digital line for communication is increasing.

The time division multiplex communication system is a communication system in which a large number of digital signals are divided into pulses of each channel or pulse groups, and the signals are arranged in a staggered manner in time and transmitted, and the influence of nonlinear distortion on the transmission line. It has a feature that it is less likely to be received, and moreover, unlike the frequency multiplex communication system, it is not necessary to use a large number of filters, so that the price per channel becomes low.

As a telewriting apparatus using the time division multiplex communication system having such characteristics, for example, in Japanese Patent Laid-Open No. 01-016043, a silent part of an audio signal is detected, and a part between them is used to An apparatus has been proposed that transmits non-voice data instead of transmitting silence data.

[0005]

However, the above-described telewriting device has a problem that non-voice data such as drawing information cannot be transmitted in real time unless a silent portion of the voice signal is detected. .
That is, unless the voice call is completely interrupted,
Since non-voice data cannot be transmitted, real-time transmission is impossible.

The present invention has been made in order to solve such a problem, and provides a multiplex communication device capable of transmitting non-voice data in real time without causing quality deterioration of voice data being transmitted. It is intended to be provided.

[0007]

In order to achieve the above object, a multiplex communication apparatus according to a first aspect of the present invention holds a communication means for performing communication in slot units on a digital line, and a holding means through the communication means. The voice data transmitting means for transmitting the voice data, the non-voice data transmitting means for transmitting the non-voice data retained through the communication means, the voice data to be transmitted and the voice for giving an identifier to the non-voice data. A non-speech identifier assigning means, a reception data sorting means for sorting the data received through the communication means into voice data and non-speech data by the assigned identifier, and a reception voice for processing the sorted reception speech data. Multiplexing apparatus including data processing means and reception non-voice data processing means for processing distributed reception non-voice data In addition, a silent section detecting means for detecting a silent section during voice data transmission, a vowel steady section detecting means for detecting a vowel steady section during voice data transmission, the silent section detecting means and the vowel steady section detection. Non-voice data transmission instruction means for instructing the non-voice data transmission means to transmit the held non-voice data when a silent section and a vowel steady section during voice data transmission are detected by the means, The voice data transmitting means is instructed to transmit the voice data in the voiced section during the voice data transmission, and the silence section and the vowel steady section are detected by the silence section detecting means and the vowel steady section detecting means. Voice data transmission / stop instruction means for instructing the voice data transmission means to stop transmission of the held voice data when detected, When distributing the received data by the serial received data distributing means, when non-voice data received has been transmitted to the sound period, and the audio data correcting means for correcting the speech data,
It is characterized by having.

According to a second aspect of the present invention, there is provided the multiplex communication apparatus according to the first aspect, wherein the non-voice data transmitting means holds non-voice data,
It is characterized in that it is provided with vowel steady section detection instructing means for instructing the vowel steady section detecting means to detect a vowel steady section. Further, the multiplex communication apparatus according to the present invention is held by the multiplex communication apparatus according to claim 2 and further held by the non-voice data transmission means when the silent section detection means detects a silent section. A non-voice data is provided with a silent segment identifier indicating a silent segment, and when the vowel steady segment detecting means detects a vowel steady segment, it is provided with a silent / speech identifier assigning means for assigning a voice segment identifier. The non-speech data transmission instructing unit instructs the non-speech data to which the silent segment identifier is attached to be transmitted prior to the non-speech data to which the sound segment identifier is attached, The feature is that voice correction is performed on non-voice data to which a section identifier is added.

According to a fourth aspect of the present invention, there is provided the multiplex communication apparatus according to the first aspect, wherein the non-voice data transmission instructing means in the multiplex communication apparatus according to the first aspect detects the vowel steady section. It is characterized in that the slot size of non-voice data is determined in accordance with the cycle of the vowel steady section and a transmission instruction is given.

[0010]

According to the above construction, in the multiplex communication device according to the first to fourth aspects, the communication means allows the voice data and the non-voice data to be communicated in the slot unit on the digital line. There is. In transmitting data, the voice data to be transmitted is temporarily held by the voice data transmitting means and then transmitted through the communication means. The non-voice data to be transmitted is temporarily held by the non-voice data transmitting means and then transmitted through the communication means. At this time, the voice / non-voice identifier assigning unit assigns an identifier to each of the voice data and the non-voice data to be transmitted.

Further, upon receiving the data, the data received through the communication means is sorted by the data sorting means into voice data and non-voice data according to the assigned identifier. Then, the distributed received voice data is processed by the received voice data processing means. Also, the received non-voice data distributed is processed by the reception non-voice data processing means.

Next, in the multiplex communication device according to the first aspect of the present invention, the silent section detecting means further detects the silent section during the voice data transmission. Further, the vowel steady section detecting means detects the vowel steady section during the voice data transmission. The non-voice data transmission instructing means, when the silent section and the vowel steady section during voice data transmission are detected by the silent section detecting means and the vowel steady section detecting means, ,
The user is instructed to transmit the non-voice data that is held. Also, by voice data transmission / stop instruction means,
The voice data transmitting means is instructed to transmit the voice data held in the voiced section during the voice data transmission, and further the voice data is transmitted by the silent section detecting means and the vowel steady section detecting means. When a silent section and a vowel steady section in the middle are detected, an instruction to stop the transmission of the held voice data is given to the voice data transmitting means.

On the other hand, when the received data is sorted by the received data sorting means, if the received non-voice data is transmitted in the voiced section, the voice data correction means corrects the voice data. Done. Further, in the multiplex communication device according to the present invention, the vowel steady-state section detection instructing means causes the vowel steady-state section detecting means to vowel steady-state when the non-voice data transmitting means holds non-voice data. It is instructed to detect the section.

Further, in the multiplex communication apparatus according to the present invention, the non-voice data transmitting means holds the silence / speech identifier assigning means when the silence section detecting means detects the silence section. A non-voice data is provided with a silent segment identifier indicating a silent segment, and when the vowel steady segment detecting means detects a vowel steady segment, a voiced segment identifier is provided. Then, the non-speech data transmission instructing means gives an instruction to transmit the non-speech data with the silent segment identifier prior to the non-speech data with the sound segment identifier. Further, at the time of data reception, the voice correction means performs voice correction on the non-voice data to which the voiced section identifier is added.

Further, in the multiplex communication device according to the present invention, when the non-voice data transmission instruction means detects the vowel steady section by the non-voice data transmission instructing means, the non-voice is transmitted in accordance with the cycle of the vowel steady section. The data slot size is determined and an instruction to transmit non-voice data is given. As a result, voice data and non-voice data are multiplexed while maintaining the voice quality as much as possible, and both data are
It becomes possible to transmit in real time.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be specifically described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a multiplex communication apparatus according to the present invention. In the figure, the arrows connecting the functional blocks indicate the direction of data flow. In order to perform data communication in slot units on the transmission side block 1, the reception side block 2 and the digital line 4, this multiplex communication device uses the multiplexed transmission data from the transmission side block 1 for the digital line. 4 and a communication unit 3 which sends the received data received through the digital line 4 to the receiving side block 2.

The transmitting side block 1 uses the non-voice data transmitting section 5 for transmitting the non-voice data such as the drawing information held therein to the communication section 3 by using the silent section during the voice data transmission, and the held voice data. A voice data transmitting unit 6 for transmitting to the communication unit 3, and a voice / non-voice identifier assigning unit 7 for assigning an identifier for identifying voice data and non-voice data to be transmitted.
And a silent section detection unit 8 that detects a silent section during voice data transmission, and recognizes that the voice that is being transmitted shifts from a consonant to a vowel, and a steady section of the vowel (usually several 100 ms). And a stationary vowel section detecting unit 9 for detecting

Further, the receiving side block 2 sorts the data received from the digital line 4 through the communication section 3 into voice data and non-voice data according to an identifier given to the data, and a voice / non-voice data distribution section 11, When the non-voice data is transmitted in the voiced section, that is, when the non-voice data interrupts the voice data, the voice data is corrected (for example, by using a voice slot in advance, A voice data correction unit 12, a reception non-voice data processing unit 13 that processes the distributed reception non-voice data, and a reception voice data processing unit 14 that processes the distributed reception voice data. ing.
FIG. 2 is a flowchart showing a transmission data multiplexing operation performed by the multiplex communication device shown in FIG. First, voice input is enabled (S201). At the same time when the voice is input, the drawing information can be input with a pen or the like (S202). Then, the voice data transmitting unit 6 sends the input voice data to the voice / non-voice identifier assigning unit 7 to start the voice data transmission (S20).
3). Subsequently, it is checked whether or not the input drawing information is stored in the non-voice data transmitting unit 5 (S204). If the drawing information is stored (Yes in S204), the process of the next step S205 is performed. Go to. If not stored (No in S204),
The process of step S204 is repeated.

In step S205, the non-speech data transmission section 5 activates the vowel steady section detection section 9. Then, the vowel steady section detection unit 9 detects the vowel steady section (S206) and detects the vowel steady section (S2).
If Yes in 06), the process proceeds to step S208, and if a vowel steady section is not detected (S2).
(No in 06), the process proceeds to step S207. In step S207, when the silent section detection unit 8 detects a silent section in the audio data (S207
If Yes), the process proceeds to the first step S250 of the silent section process (described later), and if the silent section is not detected (No in S207), the process proceeds to step S206. .

In step S208, the non-voice data transmitting section 5 and the voice data transmitting section 6 are notified of the detected vowel steady section. Then, the non-voice data transmission unit 5
Determines the transmission slot size in accordance with the cycle of the vowel steady section, and passes the accumulated drawing information to the voice / non-voice identification giving unit 50 (S209). At this time, a voiced identifier is provided as a marker for indicating that the voiced section is present. Then, the audio data transmitting unit 6 stops the transmission of the audio data (S210).

Subsequently, the non-speech data transmission unit 6 confirms whether or not all the non-speech data has been transmitted (S211), and when all the non-speech data has been transmitted (Yes in S211), proceeds to the processing of step S214. If not (No in S211), go to Step S21.
Proceed to step 2. In step S212, it is confirmed whether or not the vowel steady section detected by the vowel steady section detection unit 9 is finished, and when it is finished (Yes in S212).
In step S213, the non-voice data transmission unit 5 and the voice data transmission unit 6 are notified that the vowel steady section has ended. If the vowel steady section has not ended (No in S212), step S2
The process proceeds to 09.

Next, in step S213, after the end of the vowel steady section is notified, the process proceeds to step S214, and the vowel steady section detection unit 9 is turned off. Then, the non-speech data transmission unit 5 sends the drawing information to the speech / non-speech identifier assigning unit 7
To stop sending (S215). Further, the voice data transmitting unit 6 restarts the transmission of voice data to the voice / non-voice identifier assigning unit 9 (S216), and shifts to the process of step 204 again.

On the other hand, the processing when a silent section is detected is as follows. First, the detected silent section is notified to the non-voice data transmitting unit 5 (S250). continue,
The vowel steady section detection unit 9 is turned off (S251). Therefore, the non-voice data transmitting unit 5 transmits the drawing information to the voice / non-voice identifier assigning unit 7 (S252). At this time, a silence identifier is added as a marker for indicating that the segment is a silent segment.

Then, the silent section detecting unit 8 detects whether or not the silent section has ended (S253). Then, when the silent section ends (Yes in S253)
(If No), the process proceeds to the subsequent step S254, and if not (No in S253), the process proceeds to step S252. Further, step S254
Then, the non-voice data transmitting unit 5 is notified that the silent section has ended (S254). Therefore, the non-voice data transmitting unit 5 stops transmitting the drawing information to the voice / non-voice identifier assigning unit 7 (S255), and again the step S2.
The processing moves to 04.

FIG. 3 is a flow chart showing a process at the time of receiving data which is also carried out by the multiplex communication device shown in FIG. First, the communication unit 3 receives, from the digital line 4, data in which voice data and non-voice data are multiplexed in slot units, and transfers the data to the voice / non-voice distribution unit 11 (S3).
01). Then, when the voice / non-voice distribution unit 11 recognizes that the non-voice data is inserted in the voiced section by the voiced identifier assigned to the data, the voice correction unit 12 corrects the voice. At the same time, the data is sorted according to the voice or non-voice identifier given to the received data, the non-voice data is passed to the reception non-voice data processing unit 13, and the voice data is received by the reception voice processing unit 14.
(S302). Therefore, the received non-voice data processing unit 13 performs processing such as display of the received non-voice data (S303). Further, the reception voice processing unit 14 performs a process of outputting the received voice data to a speaker or the like (S304).

[0026]

As described above, according to the present invention, not only the non-voice data such as the drawing information can be transmitted only in the silent section during the voice data transmission like the conventional telewriting apparatus by the time division multiplexing system. Appear frequently in Japanese,
In addition, by detecting a vowel stationary section in a stable state (that is, a state in which correction is possible even if information is lost), it is possible to transmit non-voice data using the section. become able to. Further, the vowel steady section during voice data transmission can be detected only when there is non-voice data to be transmitted, and the transmission slot size of the non-voice data is equal to the detected vowel steady section. It can be determined according to the cycle.

Further, a voice correction process is applied to the received non-voice data corresponding to the latter by adding a marker for identifying the non-voice data transmitted in the silent period and the non-voice data interrupted in the voiced period. It becomes possible. As a result, the voice data and the non-voice data can be multiplexed and transmitted in real time without impairing the voice quality, the efficiency of information transmission can be improved, and the economical efficiency thereof can be remarkably improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a multiplex communication device according to the present invention.

FIG. 2 is a flowchart showing a transmission data multiplexing operation performed by the multiplex communication device shown in FIG.

FIG. 3 is a flowchart showing a process at the time of receiving data, which is performed by the multiplex communication device shown in FIG.

[Explanation of symbols]

 1 block on the transmitting side 2 block on the receiving side 3 communication section 4 digital line 5 non-voice data transmitting section 6 voice data transmitting section 7 voice / non-voice identifier assigning section 8 silent section detecting section 9 vowel steady section detecting section 11 voice / non-voice data Distribution unit 12 Audio data correction unit 13 Received non-audio data processing unit 14 Received audio data processing unit

Claims (4)

[Claims] 1. A communication unit for performing communication in slot units on a digital line, a voice data transmitting unit for transmitting voice data held by the communication unit, and a non-voice data held by the communication unit. A non-voice data transmitting means for transmitting and a voice / non-voice identifier assigning means for assigning an identifier to the voice data and the non-voice data to be transmitted are provided, and the data received through the communication means is assigned the assigned identifier. A received data distribution means for distributing the received data to the audio data and the non-voice data, a received voice data processing means for processing the distributed received voice data, and a received non-voice data processing means for processing the distributed received non-voice data. A multiplex communication device comprising: a silent section detecting means for detecting a silent section during voice data transmission; The vowel steady section detecting means for detecting a vowel steady section during data transmission, the silent section detecting means and the vowel steady section detecting section detects the silent section and vowel steady section during voice data transmission, For voice data transmission means,
A non-voice data transmission instructing means for instructing transmission of the non-voice data held therein, and instructing the voice data transmitting means to transmit voice data in a voiced section during voice data transmission, and detecting the silent section. Voice data for instructing the voice data transmitting means to stop the transmission of the held voice data when the silent segment and the vowel steady segment during the voice data transmission are detected by the means and the vowel steady segment detection means. A transmission / stop instruction means, and a voice data correction means for correcting the voice data when the received non-voice data is transmitted in the voiced section when the received data is distributed by the reception data distribution means, A multiplex communication device comprising: 2. The multiplex communication device according to claim 1, further comprising: when the non-speech data transmitting means holds non-speech data, the vowel steady segment of the vowel steady segment is detected. A multiplex communication apparatus comprising vowel stationary section detection instructing means for instructing detection. 3. The multiplex communication device according to claim 2, further comprising a non-voice section in the non-voice data held by the non-voice data transmitting section when the non-voice section detecting section detects the non-voice section. A non-speech data transmission, which is provided with a silence / speech identifier assigning unit that assigns a sound segment identifier when the vowel steady segment detecting unit detects a vowel steady segment. The instructing unit instructs the non-speech data with the silent segment identifier to be transmitted prior to the non-speech data with the sound segment identifier, and the sound correcting unit has the speech segment identifier. A multiplex communication device characterized by performing voice correction on non-voice data. 4. The multiplex communication device according to claim 1, wherein when the non-voice data transmission instruction means detects a vowel steady section, the non-voice data transmission instruction means sets a non-voice data according to a cycle of the vowel steady section. A multiplex communication device, characterized in that a slot size of voice data is determined and a transmission instruction is given.