JPS598460A - Digital radiotelephony system - Google Patents

Abstract

PURPOSE:To transmit each data of voice and control on the same radio channel without relation mutually, by adding the data with a sound synchronizing signal at each prescribed time at the sound transmission and a control synchronizing signal at the control data transmission respectively for transmitting signals. CONSTITUTION:A voice is applied with A/D conversion 1 in a coding speed determined for a radiotelephony system and stored 21 at the transmission of data between opposing radio sets, the coded voice is sectioned at each prescribed time, read out at a speed faster than the coding speed, a voice synchronizing signal is added to a space time produced at each prescribed time with the difference between the coding speed and the transmission speed, and the voice synchronizing signal is added at the same speed as the transmission speed at the transmission of control data for transmtting respectively signals. On the other hand, each data of voice and control is sectioned based on two kinds of synchronizing signals at the reception and the control data is transmitted to a control section 23 and the voice data is transmitted to a storage circuit 22. Further, the stored voice data is read out in the coding speed and D/A-converted 22.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a digital radiotelephone system that transmits voice data or control data using the same radio channel.

Conventionally, in this type of system, once a call is established, only digitized voice is transmitted over the radio section. For this reason, if control data such as channel switching is sent during a call, it will be treated as voice data until it is recognized as control data by the control unit on the receiving side, and will be treated as quantization noise that is unpleasant to the caller. There are audible flaws.

Or when switching from control unit data to voice.

Control data may malfunction due to digitized audio.

On the other hand, in the receiver 4, as shown in FIG. 1, the digital data obtained by demodulating the data shown in FIG. 0 During the period ■■■ shown in diagram M2, the control section 7 opens the switch 9 to prevent the control data from being input to the D/A converter. When the connection control in state (2) is completed and state (2) is reached, the audio data becomes input to the D/A converter. However, when the condition (■) occurs, the control section 7 cannot open the switch 9 until it recognizes that it is control data, and the control data will be heard as a harsh noise when it is input to the D/A converter. . Alternatively, even when the state of ■ changes to the state of ■, that is, from control data to voice data, unless it is recognized that the control data has ended, the digitized voice data will not be input to the control unit 7, which may cause malfunction. becomes.

FIG. 1 is a block diagram of a wireless device used in a conventional system, and the wireless devices facing each other have the configuration as shown in FIG.

The audio input through the signal line 101 is encoded into fbit/see digital data by the A/D converter 1, and then sent to the switch 8. The control unit 7 still generates control data at fbit/sec through the control data output line 107. 10 is a coding frequency generator. The switch 8 is operated according to the instructions from the control section 7.

A signal line 103 or a control data output line 107 is connected to the transmission input line 105. Therefore, when sending out either audio data or control data from the transmitter 3, f
It is transmitted at a data rate of bit/sec.

When the data sent out from the transmitter 3 is viewed according to time, it becomes as shown in FIG.

In FIG. 2, ■, ■, and ■ are the transmission of control data, and at ■, a communication state is established and encoded voice is transmitted. When it becomes necessary to send out some control data during a telephone call, sideways data is sent out as shown in (3), and voice data is sent out again in (2).

The present invention is intended to enable control data to be transmitted without interfering with telephone calls in the above-mentioned Dinotal wireless telephone system, and conversely to enable voice to be transmitted without causing malfunctions in the control data.

In the present invention, when audio is encoded and transmitted, the audio data encoded by an A/D converter is temporarily stored in a storage circuit at the encoding speed, and the stored audio data is divided into fixed time intervals. At this time, a synchronization signal (hereinafter referred to as "synchronization signal") indicating audio transmission is placed before the separated audio data.

(referred to as an audio synchronization signal) is added to configure the frame,
When transmitting control data, a synchronization signal indicating control data transmission (hereinafter referred to as a control synchronization signal) is added to form a frame, and the frame is transmitted. In this way, on the receiving side, by detecting whether the synchronization signal at the beginning of each frame is an audio synchronization signal or a control synchronization signal, it is possible to distinguish whether audio is being transmitted or control data is being transmitted. It's easy to do. Control data is still sent to the control unit, and audio data is stored in a storage circuit separate from the sending side. Once the audio data has entered the storage circuit, it is read out at the same encoding speed as on the sending side and is output as continuous audio without inputting it to the D/A converter, but the control data has already been cut into pieces. Since the control data is not input to the D/A converter, there is no noise caused by the control data. In addition, there is no possibility of malfunction due to voice data being input to the control unit.

Next, an embodiment of the present invention will be described with reference to FIG. 3, which is a configuration diagram thereof.

In FIG. 3, 1 is an A/D converter, 2 is a D/A converter, 21 is a memory circuit on the transmitting side, 22 is a memory circuit on the receiving side,
23 is a control section, 26 is an audio synchronization signal generator, 27 is a control synchronization signal generator, 28 is an audio synchronization signal detector, and 29 is a control synchronization signal detector.

FIG. 4 is a time chart showing the control operation of this embodiment.

First, in FIG. 3, audio is encoded by the A/D converter 1 through an audio input line 201. The encoding speed at this time is determined by the encoding frequency generator 10, and here, fc
Let it be bit/sec. The output of the A/D converter 1 is stored in the storage circuit 21 at the encoding rate fc. Note that as the memory circuit, for example, a FIFO memory element is used in which write speed and read speed can be set independently. When the number of audio data to be transmitted in one frame is stored in the storage circuit, the data is read out at a transmission rate determined by the frequency from the transmission frequency supply line 217. The transmission rate at this time is assumed to be ftbit/see, which is faster than the sign (hi rate fc).

Now, prior to reading the audio data, an audio synchronizing signal is outputted from the audio synchronizing signal generator 26 using the time based on the difference between the transmission speed ft and the encoding speed fc described above, and is used as the human power of the transmitter 3. .

Subsequently, the control unit 23 inputs the audio data to the transmitter 3 through the switch 24 . On the other hand, when transmitting control data, the control synchronization signal generator 27, υ control data output line 207. Through the switch 24, the control data is transmitted to the transmitter 30.

The sequence of this series of operations is shown in FIG.

When the first switching data ■ of audio data is stored,
The audio synchronization signal ■ is sent out using the time based on the speed difference mentioned above.1. Subsequently, audio data 0 is sent out. Similarly, the second switching data (2) of audio data is also sent out.

Here, it is assumed that the control data is sent at the time of the third switching data 0. At this time, the control synchronization signal ■ is sent out before the control data, and then the control data @ is sent out. Therefore, looking at the output of the transmitter 3, as shown in Figure 4, ■'-〇'-o'-■'-@'-@'-[
Continuous data of ftbit/3ee will be sent in the order of phase]'-■'. Similarly, on the receiving side, data is received in the above order. ■' with the audio synchronization signal detector 28
, o', @', it means that what is subsequently received is audio data, and the received data is sent to the storage circuit 22 by the switch 25 controlled through the switch control line 209. . Note that since the input to the storage circuit 22 is in ftbit/see, reading is again performed in fcbit/see via the encoding frequency supply line 216, and the data is input to the D/A converter 2. The voice demodulated by such an operation is not interfered with by the control data.

On the other hand, when the control synchronization signal detector 29 detects the control synchronization signal ■', it means that the next data to be received is side tilt data. Received data is sent through. Therefore, the received data sent to the control unit 23 is not interfered with by audio.

As explained above, when transmitting audio, the encoded audio is temporarily stored in a memory circuit and an audio synchronization signal is added at regular intervals, and when transmitting control data, the control synchronization signal is added and sent out. .

On the receiving side, by separating control data and audio data according to the type of synchronization signal, it is possible to transmit audio data or control data using the same wireless channel without interfering with each other.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a transceiver used in a conventional digital telephone system. FIG. 2 is a time chart of data when the transceiver shown in FIG. 1 is used. FIG. 3 is a configuration diagram of a transceiver according to an embodiment of the present invention. FIG. 4 is a time chart of data and synchronization signals when the transceiver shown in FIG. 3 is used. In the figure, 1... A/D converter, 2... D/A converter,
3...Transmitter, 4...Receiver, 5...Sharing unit, 6...
...Aerial line. 7123...Control unit, 8.9, 24.25...Switch, 10...Encoding frequency generator, 21.22...
Memory circuit, 26...Audio synchronization signal generator, 27...
Control synchronization signal generator, 28...Audio synchronization signal detector. 29... Control synchronization signal detector, 101, 201...
Audio input line, 102, 202... Audio output line, 103
゜203...A/D converter output line, 104,204.
・A/D converter input line, 105,205...Transmitter input line, 106.206...Receiver output line, 107°20
7... Control data output line, 108, 109°208.
209.214...switch control line, to 11). 210... Reception clock output line, 111... Transmitter output line, 112... Receiver input line, 113, 215°2
16... Encoding frequency supply line, 211... Reception control data output line, 212... Storage circuit input line, 213...
...Memory circuit output line, 217...Transmission frequency supply line. 218...Audio synchronization signal output line, 219...Control synchronization signal output line. (heart () phrase\ノ(-1)\ノ\J

Claims (1)

[Claims] 1. In a digital radio telephone system that transmits voice data or control data using the same radio channel, when both radio devices facing each other transmit voice data, the transmitting side Speech is converted into a width at a coding speed determined by the system, is stored in a storage circuit, and the coded speech is divided into sections at fixed time intervals at a speed faster than the coding speed (hereinafter referred to as synchronization indicating that audio is being read out from the storage circuit at the transmission rate (referred to as the transmission rate) and that audio is being transmitted at the transmission rate during blank time that occurs at intervals of the fixed time due to the difference between the encoding rate and the transmission rate. When transmitting control data by adding a signal (hereinafter referred to as an audio synchronization signal), a synchronization signal indicating that control data different from the audio synchronization signal is being transmitted at the same speed as the aforementioned transmission speed. transmitting a signal (hereinafter referred to as a control synchronization signal), while the receiving side separates the control data and audio data according to the two types of synchronization signals received, and sends the control data to the control section, respectively; The audio data is stored in another storage circuit, and the stored audio data is read out at the encoding speed and output to D/D.
By converting A. A digital wireless telephone system that enables the transmission of voice data or control data without interfering with the call or causing the control data to malfunction due to voice during a call.