JPS63116532A - Data switching circuit - Google Patents

Abstract

PURPOSE:To prevent the output of the '0' continuity of the sound data of silence to an output signal due to the switching of data by selecting the delaying sound data with a delaying part added to a sound data input terminal and the original sound data not to be delayed and inputting them to a silence detecting part. CONSTITUTION:First, the silence part of sound data is continuous to a sound data input terminal 11 and the output of a silence detecting part 15 is 'L'. A switch A14 selects delaying sound data 26 and a switch B17 selects the silence data of a '1010' pattern. Continuously, when the head of the sound part of delaying sound data is detected, the silence detecting part 15 outputs 'H', the switch A14 selects and outputs the sound part of the sound data not to be delayed and the switch B17 selects and outputs the sound part of the delaying sound data. Thus, by the output signal of an output terminal 13, the silence data of the '1010' pattern are inserted into all sound data of the sound and the '0' continuity of (n) bits can be removed.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention is directed to CVSD (Continuously Variable Slope Delta Modulation)
Related to the data switching circuit required when a transmission path is shared, such as in a half-duplex communication system between stations, using a system that converts audio into a digital signal and transmits it using an encoding/decoding circuit such as It is.

[Conventional technology]

FIG. 3 is a block diagram showing the configuration of a conventional data switching circuit. In FIG. 3, 11 is an audio data input terminal, 12 is an rlo10j7g turn silent data input terminal, 13 is an output terminal, and 15 detects a silent state of n bits or more of audio data input from the audio data input terminal 11. The silence detection unit 17 is a switch B that switches between audio data input from the audio data input terminal 11 and silence data input from the silence data input terminal 12 in response to a switching signal output from the silence detection unit 15.

Next, the operation of the conventional data switching circuit will be explained. In systems that share a transmission path, such as when communicating in half duplex between stations, the transmission path is set to "0" when there is no sound.
” level, and audio signals are transmitted in bursts only during transmission.

In a code/decoding circuit such as CVSD, a succession of the same level of the digital signal corresponds to the maximum amplitude of the analog signal, and a turn of [1o1oJ] of the digital signal corresponds to silence of the analog signal. Therefore, in a system like the one above,
When the transmission path is silent, that is, "O" (level) is continuous in the receiving section, it is necessary to input the silent data of the rlO10J pattern to a coding/decoding circuit such as a CVSD.

In the conventional data switching circuit shown in FIG. 3, the silence detector 15 monitors the silence state of the audio data input from the audio data input terminal 11, detects rOJ continuity, that is, the silent state of the transmission path, and switches B17 to r10
Switch to the silent data input terminal 12 of the 10J pattern.

FIG. 4 is a timing chart of operations in the data switching circuit of FIG. 3. In FIG. 4, 21 is input audio data, 21-a is a silent part, 21-
b is the sound part. 22 is silent data of rlO10J pattern. Reference numeral 23 indicates a switching signal of the switch B17, which is an output signal of the silence detection section 15. 24 is an output signal switched by switch B17, and 24-
a is silent data of rlo10J pattern, 24-b is voice data with sound, and 24-C is silent voice data.

First, the silence detection section 15 detects continuous "0" from the audio data input terminal 11 and outputs rLJ as the switching signal 23. The switch B17 selects and outputs the silent data 22 of the rlo10J pattern. Furthermore, when the sound part 21-b of the audio data 21 is input, the silence detection unit 15 outputs rHJ as the switching signal 23. Based on this output, the switch B17 selects and outputs the audio data 21.

Next, from the sound part 21-b to the silent part 21-a of the audio data 21 input from the audio data input terminal 11, "0" is input.
”, the silence detection unit 15 detects the n-bit “
Time to detect “O” continuity, that is, silence state detection time 2
After a 5-delay, the switching signal 23 changes to rLJ, and switch B
Switch 17. Therefore, the output of switch B17 is
During the silent state detection time 25, silent audio data 24-c
n bits of "0" are output. The bit length n for detecting consecutive "0"s is determined by the code decoding circuit such as CVSD and the system used.

[Problem that the invention seeks to solve]

In the conventional data switching circuit as described above, the sound part 21-b of the input audio data 21 to the silent part 21-
a, the output signal 24 switched by the switch B17 is "0" of the silent audio data 24-C.
Since a continuous signal is output, when this output is input to a code decoding circuit such as a CVSD, it is demodulated as an output of an analog signal with the maximum amplitude, resulting in a problem that a large noise sound is generated.

The present invention was made to solve this problem, and an object of the present invention is to provide a data switching circuit that does not output continuous "0" of silent audio data as an output signal due to data switching.

[Means for solving problems]

The data switching circuit according to the present invention is such that a delay section is added to the audio data input terminal, and the delayed audio data by the delay section and the original audio data that are not delayed are selectively added to the input to the silence detection section. It is.

[Effect]

In the data switching circuit of the present invention, the delayed audio data by the delay unit added to the audio data input terminal and the original audio data that is not delayed are selected and input to the silence detection unit, so that the decoding in the encoding/decoding circuit is performed. In the case of
Noise generated when switching between audio data and silent data can be reduced.

〔Example〕

FIG. 1 is a block diagram showing the configuration of a data switching circuit according to an embodiment of the present invention. In FIG. 1, 11 is an audio data input terminal, 12 is a silent data input terminal with a "1010" pattern, 13 is an output terminal, and 14 is an audio data input from the audio data input terminal 11, and a delay unit for transmitting the audio data. A switch A115 for selecting delayed audio data via the audio data input terminal 16 is a silence detection unit that detects consecutive "0"s of n bits or more in the output of the switch A14; n
The bit delay section 17 is a switch B that switches between delayed audio data by the delay section 16 and silent data of the rlo10J pattern.

FIG. 2 is a timing chart of operations in the data switching circuit of FIG. 1. In FIG. 2, 21 is input audio data, 21-a is a continuous rOJ silent part, and 21-b is a sound part. 22 is rlo10J
This is the silent data of the pattern. 26 is the output of the delay unit 16, which is delayed audio data delayed by n bits, which is the same as the delay caused by the detection of n bits of consecutive "0" by the silence detector 15, and 26-a is the silent part of consecutive "0"s. , 26-b are the sound parts. Reference numeral 27 denotes a silence detection section input signal which is the output of the switch A14, 27-a is a silent part of continuous "0", and 27-b is a sound part. Reference numeral 23 indicates switching signals of switch A14 and switch B17, which are output signals of the silence detection section 15. 24 is an output signal switched by the switch B17, 24-a is silent data of rlo10J pattern, and 24-b is voice data with sound.

Next, the operation of the data switching circuit which is one embodiment of the present invention will be described. First, the silent portion 21-a of the voice data 21 is continuous at the voice data input terminal 11, and the output of the silence detector 15 is "L". Switch A14 selects delayed audio data 26, and switch B17 selects delayed audio data 26.
selects the silent data 22 of the r1010J pattern. Subsequently, when the beginning of the sound part 26-b of the delayed audio data 26 is detected, the silence detection unit 15 outputs "H",
The switch A14 selects and outputs the sound part 21-b of the undelayed audio data 21, and the switch B17 selects and outputs the sound part 26-b of the delayed audio data 26.

Therefore, the sound part 27-b of the silence detector input signal 27 contains the sound part 21-b of the audio data 21 excluding the first n bits, and the sound part 27-b of the output signal 24 contains the sound part 21-b of the sound data 21, excluding the first n bits. -b is the sound part 26-b of the delayed audio data 26.
enters. The change point from the sound portion 27-b to the silence portion 27-a in the silence detection unit input signal 27 to the silence detection unit 15 is the change point from the sound portion 26-b to the silence portion 26-a of the delayed audio data 26. It is located at a time position n bits before the change point.

Therefore, after the silence detection time 25 in which the silence detection m 15 detects n-bit "O" succession, the switching signal 2
3 changes from rHJ to rLJ, that is, at the end of the sound part 26-b of the delayed audio data 26, the output of the switch B17 switches to the silent data 22 of "1010" and 7th turn.

As a result, in the output signal 24 of the output terminal 13 of the data switching circuit according to the present invention, the silent data 24-a of the r1010J pattern is inserted into all the sound data 24-b, and the silent data 24-a in the conventional circuit described above is inserted. The n-bit series of "0"s in the audio data 24-C can be removed.

In the above embodiment, the case of half-duplex communication between two stations has been described, but it is also effective when a plurality of stations communicate using a common transmission path.

Further, in the above embodiments, a code/decoder circuit such as a CVSD is described, but the present invention is also effective for other speech code/decoder circuits or non-voice code/decoder circuits.

〔Effect of the invention〕

As explained above, the present invention adds a delay section to the audio data input terminal in the data switching circuit, and selects and adds the delayed audio data by the delay section and the original audio data that is not delayed to the input to the silence detection section. As a result, in the case of decoding in the code/decoding circuit, it is possible to reduce the noise generated when switching between audio data and silent data, which is an excellent effect.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of a data switching circuit which is an embodiment of the present invention, FIG. 2 is a timing -10= chart of operation in the data switching circuit of FIG. 1, and FIG. 3 is a conventional data switching circuit. FIG. 4, a block diagram showing the configuration of the switching circuit, is a timing chart of operations in the data switching circuit of FIG. 3. In the figure, 11... audio data input terminal, 12...
・Silent data input terminal, 13... Output terminal, 14...
-Switch A515...silence detection section, 16...delay section, 17...switch B521...audio data, 2
1-a...silent part of audio data 21, 21-b...
・Sound part of silent data 21, 22...silent data,
23...Switching signal, 24...Output signal, 24-a
...silent data, 24-b...sound data,
24-c... Silent audio data, 25... Silent state detection time, 26... Delayed audio data, 26-a...
Silent portion of delayed audio data 26, 26-b...Sound portion of delayed audio data 26, 27... Silence detector input signal, 27-a... Silent portion of silence detector input signal 27, 27 -b...This is a sound part of the silence detection section input signal 27. In each figure, the same reference numerals indicate the same or equivalent parts.

Claims (1)

[Claims] In a data switching circuit that switches the input data to the audio decoder so that audio data is input when there is a sound and silent data is input when there is no sound, there is a delay section that delays the audio data by n bits, and a delay section that delays the audio data by this delay section. a first switch that selects the original audio data; a silence detector that detects a continuous silence state of n bits or more in the data selected by the first switch; 1. A data switching circuit comprising: a second switch that switches and outputs data; and the first switch and the second switch are switched by a switching signal from the silence detector.