JPS63116533A - Data switching circuit - Google Patents

Abstract

PURPOSE:To prevent the output of the continuity of an (n)-bit of '0' of silent sound data to an output signal by switching data by using two detecting parts, one is a silence detecting part to detect the continuity of a silence condition of (n) bits or above of the sound data, the other is a sound detecting part to detect the sound of the delaying sound data by a delaying part. CONSTITUTION:A silence detecting part 20 to detect a silence condition of (n) bits or above of sound data, and a sound detecting part 18 to detect the sound of delaying sound data due to a delaying part 16 to delay the sound data by (n) bits are added, a switch 22 is controlled by using two sound detecting signal and silence detecting signal, the continuity of the (n) bits of '0' which are the silence sound data is not outputted, the sound data and the silence data are switched to an output terminal 14 and can be changed. For such a reason, the analog signal of the maximum amplitude is not generated, and the data can be changed over smoothly without generating noise sound as the result.

Description

[Detailed Description of the Invention] [Field of Industrial Application] This invention is a half-duplex communication method between stations, and is based on CVSD (
The present invention relates to a data switching circuit required in a digital communication system using a code/decoding circuit (continuously variable slope delta modulation) or the like.

[Conventional technology]

FIG. 3 is a block diagram showing the configuration of a conventional data switching circuit. In FIG. 3, 50 is an input terminal for audio data coming from the other station, 52 is an input terminal for silent data generated within the own station, 54 is an output terminal, and 56 is more than n bits of audio data input from the input terminal 50. A silence detection section 58 is a switch for switching between audio data and silence data.

Next, the operation of the conventional data switching circuit will be described. When communicating in half duplex between stations using a code/decoding circuit such as CVSD, the transmission line is kept at the "0" level when there is no sound, and the audio signal (analog signal) is kept at the "0" level when there is sound.
is transmitted in bursts. In such a communication system, when there is no sound, silent data in the pattern "1010..." is required as input. For this reason, when the transmission path is in a silent state, that is, "0" (level) is continuous, in the receiving section, this is detected and the silent data of the "rlolo..." pattern is transmitted to a coding/decoding circuit such as a CVSD. Must be entered.

Therefore, when the transmission path is silent, the silence detection unit 56 detects the silence state, the switch 58 switches from the audio data input terminal 5o to the silence data input terminal 52, and outputs the data to the output terminal 54.

FIG. 4 is a timing chart of operations in the data switching circuit of FIG. 3. In FIG. 4, 60 is input audio data, 6Q-a is a silent part, and 60-
b is the sound part. 62 is silent data of the "rlolo..." pattern.

66 is a switching signal of the switch 58 which is an output signal of the silence detection section 56, 66-a is an rLJ switching signal, and 66
-b is the "H" switching signal. 64 is an output signal switched by the switch 58, and 64-a is rl
olo...'' pattern is silent data, 64-b is sound data, and 64-C is silent sound data.

First, the silence detection section 56 detects continuous "0" at the audio data input terminal 50 and outputs the rLJ switching signal 66-a as the switching signal 66.

As a result, the switch 58 selects and outputs the silent data 62 of the "rlolo..." pattern.

Further, the silence detection unit 56 detects the sound portion 6 of the audio data 60.
When 0-b is input, the rHJ switching signal 66-b is output as the switching signal 66. Based on this output, the switch 58 selects and outputs the audio data 60.

Next, when the sound part 60-b of the audio data 60 inputted from the audio data input terminal 5o changes to the silent part 60-a, the silence detection unit 56 detects consecutive "O" bits of n bits. The switching signal 66 is delayed by the time, that is, the silent state detection time 67 (corresponding to the silent audio data 64-c).
is changed to the rLJ switching signal 66-a, and the switch 58 is switched to the silent data input terminal 52 side. The bit length n for detecting rOJ continuity 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 60-b of the input audio data 6o to the silent part 60-
When changing to a, or depending on the system, the silent part 60-
When changing from a to a sound part 60-b, a series of n bits of "0" of the silent audio data 64-c is output as the output signal 64 switched by the switch 58, so this output is outputted to a CVSD etc. When input to the code/decoding circuit of , , is demodulated as an output of a large-amplitude analog signal, and as a result, there is a problem in that a large noise is generated.

The present invention has been made to solve this problem, and provides a data switching circuit that does not output continuous n bits of rOJ of silent audio data as an output signal due to data switching using a simple circuit configuration. With the goal.

[Means for solving problems]

The data switching circuit according to the present invention includes a delay section that delays the audio data by n bits to the audio data input terminal, a silence detection section that detects a continuous silence state of n bits or more of the audio data, and a delay section. The audio data and silent data are switched by using two detection units, including a voice detection unit that detects the presence of voice in delayed voice data.

[Effect]

The data switching circuit of the present invention includes a silence detection unit that detects a silence state of n bits or more of audio data, and a sound detection unit that detects the presence of sound in delayed audio data caused by a delay unit that delays the audio data by n bits. By controlling the switch using the silence detection signal and the sound detection signal, which are the switching signals output from the two silence detection sections and the sound detection section, audio data can be processed without generating large noises. It becomes possible to switch between silent data and silent data.

〔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, 10 is an input terminal for audio data, 12 is an input terminal for silent data of rlolo...'' pattern, 14 is an output terminal, 16 is a delay unit that delays the audio data by n bits, and 18 is a delay unit 16 20 is a silence detection unit that detects a continuous silent state of n bits or more in audio data; 22 is a voice detection unit 1;
This is a switch that switches between audio data and silence data based on the sound detection signal output from the sound detection section 8 and the silence detection signal output from the silence detection section 20.

FIG. 2 is a timing chart of operations in the data switching circuit of FIG. 1. In FIG. 2, 30 is input audio data, 30-a is a silent part of continuous "0", and 30-b is a sound part. 32 is rlOlo・
...'' pattern is silent data. 36 is the delay section 16
The output is delayed audio data for n bits, which is the same as the delay caused by n bits of continuous "O" in the silence detection section 20, and 36-a is a silent part of continuous "0", and 36-b is a sound part. It is a part. 38 is a voice presence detection signal, which is a voice detection output of the delayed audio data 36, 38-a is an rLJ voice presence detection signal, and 38-b is an "H" voice presence detection signal. 40
is a silence detection signal, which detects silence from voice by predicting the n-bit delay required for silence detection. Here, 40-a is rHJ silence detection signal,
40-b is an "L" silence detection signal. 34 is an output signal switched by the switch 22, and 34-a
ga rlolo...” pattern silent data, 34-b
is recorded as audible audio data.

Next, the operation of the data switching circuit which is one embodiment of the present invention will be described. Since the sound detection unit 18 is initially in a silent state, it outputs the rLJ sound detection signal 38 - a as the sound detection signal 38 .

Here, when the audio data 30 is manually inputted, the presence detection unit 1
8 is the rHJ sound detection signal 38- as the sound detection signal 38.
Output b. The rise of this output can be used to create a sound detection timing.

The silence detection signal 40 of the silence detection unit 20 detects silence from voice by predicting the n-bit delay required for silence detection. Since silence is detected by counting consecutive n bits of 0, there is actually a delay of n bits from the point where there is sound to silence.

That is, the time when silence in the undelayed audio data 30 is detected coincides with the time when the delayed audio data 36 becomes silent. This is because the delay unit 16 delays the above n bits. In this way, it is possible to detect silence in the delayed audio data 36, and at this time, the silence detection section 20 outputs the rHJ silence detection signal 40-a as the silence detection signal 40. In this way, the switch 2 uses the above two sound detection signals 38 and silence detection signals 40.
2, the output terminal 14 can be switched between audio data and silent data without outputting a series of n bits of "0", which is the silent audio data 64-C in the conventional circuit. can do. Therefore, an analog signal with the maximum amplitude is not generated, and as a result, data switching can be performed smoothly without generating noise or noise.

In the above embodiment, the case of half-duplex communication has been described, but it can also be used for full-duplex communication, unidirectional communication, etc., and the modulation method is not limited to CVSD.

Furthermore, in the above embodiment, the silent state of the transmission line is defined as a series of rOJ levels, but it may be at other levels depending on the system.
...'' pattern does not have to be used, and it is not necessarily necessary to create it within your own station.

Further, in the above embodiment, the sound detection signal 38 and the silence detection signal 40 are used as signals for switching and controlling the switch 22, but the signal is not necessarily limited to these two signals. Various uses of these signals can be considered, such as logical operations and setting/resetting of flip-flops.

〔Effect of the invention〕

As explained above, the present invention includes a data switching circuit in which a delay section that delays audio data by n bits is added to the audio data input terminal, and a silence detection section that detects a continuous silence state of n bits or more in the audio take. By using two detecting sections, a sound detecting section that detects the presence of sound in the delayed audio data by the delay section, it is possible to switch between audio data and silent data, so it is possible to reduce the cost without using a complicated circuit configuration. When switching between audio data and silent data, the switching can be performed smoothly without generating large noise, which is an excellent effect.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of a data switching circuit according to an embodiment of the present invention, FIG. 2 is a timing chart of the operation of the data switching circuit of FIG. 1, and FIG. 3 is a diagram of a conventional data switching circuit. FIG. 4, a block diagram showing the configuration, is a timing chart of operations in the data switching circuit of FIG. 3. In the figure, 10.50... audio data input terminal;
12.52... Silent data input terminal, 14°54.
... Output terminal, 16... Delay section, 18... Sound detection section, 20.56... Silence detection section, 22.58... Switch, 30.60... Audio data, 30- a...
Silent part of the audio data 30, 30-b...Sound part of the audio data 30, 32.62...Silent data, 34.
64... Output signal, 34-a... Silent data, 34
-b... Voice data with sound, 36... Delayed voice data, 36-a... Silent portion of delayed voice data 36, 3
6-b...Sound portion of delayed audio data 36, 38...
- Sound detection signal, 38-a...rLJ sound detection signal,
38-b...r HJ sound detection signal, 40... Silence detection signal, 40- a-r HJ silence detection signal, 4O-
b-rL” silence detection signal, 60-a...audio data 6
0 silent part, 60-b...Sound part of audio data 60, 64-a...Silent data, 64-b...Sound audio data, 64-C...Silent audio data , 66・
・・Switching signal, 66-a-r LJ switching signal,
66-b.=r HJ switching signal. In each figure, the same reference numerals indicate the same or equivalent parts.

Claims (1)

[Claims] A silence detection unit that detects a continuous silence state of n bits or more of audio data in a data switching circuit that switches to input audio data when there is a sound and input silence data when there is no sound as input data to the audio decoder; A delay unit that delays audio data by n bits, a sound detection unit that detects sound in the delayed audio data delayed by the delay unit, an output signal of the silence detection unit, and an output signal of the sound detection unit, A data switching circuit comprising a switch for switching between the delayed audio data and silent data.