KR101409713B1 - Audio signal processing system having prevention function of cutting of audio - Google Patents

Abstract

An audio signal processing system according to one preferable embodiment of the present invention, the disconnection of an audio signal can be prevented. An audio signal processing system having an audio disconnection prevention function according to one preferable embodiment of the present invention includes a codec which pressure-releases audio data and outputs the audio data by a block unit; an audio rate conversion filter which converts and outputs the audio data of the block unit according to a designated data rate; and a main buffer which includes N blocks which can store the audio data with a first constant size.

Description

TECHNICAL FIELD [0001] The present invention relates to an audio signal processing system having an audio disconnection prevention function,

The present invention relates to an audio signal processing system having an audio break prevention function.

FIG. 1 shows a configuration diagram of a conventional OFDM system 100. 1, when a transmitter transmits an audio signal of 48k / sample, a demodulator synchronizes a system oscillator clock and a received signal to output a demodulated audio signal to a DSP Signal Processor). At this time, the DSP operates as an oscillator clock. What is problematic is the error of the oscillator 130. A crystal oscillator used in commercial use has an error of several PPM to several hundred PPM. Also, it is vulnerable to heat, resulting in a larger error in a high temperature environment. (Output of the modulator 110 synchronized with 48 k / sample of the transmitter) input to the DSP and an audio signal output from the DSP and output to the speaker (including the error synchronized with the crystal oscillator 130 of the receiver) (Err) between the input and output occurs between the input signal and the operating signal. After a long time, the audio signal becomes insufficient or remains. At this time, audio interruption occurs.

2 is an example in which the audio data is not synchronized between the input and output in the audio buffer. In an ideal situation, the gap between the read / write pointers should be constant. However, if there is an error between the two, the gap becomes '0' after a long time, do. In this case, an audio interruption occurs.

An object of the present invention is to provide an audio signal processing system having an audio interruption prevention function.

An audio signal processing system having an audio interruption preventing function according to a preferred embodiment of the present invention includes: a codec for decompressing audio data and outputting the decompressed audio data in blocks; An audio rate conversion filter for converting the audio data of the block unit according to a specified data rate and outputting the audio data; And a main buffer including N blocks capable of storing audio data in a first predetermined size.

The audio signal processing system may further include a controller for controlling operations of the audio rate conversion filter and the main buffer. More specifically, the controller controls the main buffer in a ring buffer manner, and adjusts the data rate of the audio rate conversion filter when a buffer of the N blocks of the main buffer is out of a predetermined range. .

That is, the controller increases the number of data output through the interpolation of the audio rate conversion filter when the number of filled buffers among the N blocks of the main buffer is less than the predetermined number M, It is preferable to reduce the number of data output through the decimation of the audio rate conversion filter when the number of buffers exceeds the predetermined number L. [

According to the audio signal processing system of the preferred embodiment of the present invention, it is possible to prevent the audio signal from being broken.

1 is a block diagram of a conventional OFDM system.
FIG. 2 is an example in which audio data is not synchronized between input and output in an audio buffer; FIG.
3 is a configuration diagram of an audio signal processing system having an audio break prevention function according to a preferred embodiment of the present invention.
4 is an explanatory view of an operation of an audio signal processing system according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an audio signal processing system having an audio break prevention function according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

It should be understood that the following embodiments of the present invention are only for embodying the present invention and do not limit or limit the scope of the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

FIG. 3 is a configuration diagram of an audio signal processing system 200 having an audio break prevention function according to a preferred embodiment of the present invention.

3, an audio signal processing system 200 having an audio disconnection prevention function according to an exemplary embodiment of the present invention includes an audio buffer 210, a CODEC 220, a codec buffer 230, an audio rate conversion filter 240, an audio rate conversion filter buffer 250, a sub buffer 260, a main buffer 270, an I2S buffer 280, and a controller (not shown) .

First, the audio buffer 210 primarily stores input audio data. The codec 220 decompresses the audio data stored in the audio buffer 210 and outputs the decompressed audio data in the unit of the buffer 230 for the codec.

The audio rate conversion filter 240 converts the audio data in units of blocks stored in the buffer 230 for codec according to a specified data rate, that is, a sample rate, and outputs the converted data to the audio rate conversion filter buffer 250 . The sub-buffer 260 is a buffer for storing the data stored in the buffer 250 for the audio rate conversion filter into one block having a first predetermined size.

Next, the main buffer 270 includes N blocks capable of storing audio data of the sub-buffer 260 in a first predetermined size. The I2S buffer 280 is a buffer for outputting audio data to the I2S output terminal.

A controller (not shown) generates a control signal for controlling the operation of the audio rate conversion filter 240 and the main buffer 270. The controller (not shown) controls the main buffer 270 in a ring buffer manner.

The controller (not shown) adjusts the data rate of the audio rate conversion filter 240 when the filled buffer out of N blocks of the main buffer 270 is out of the M to L number of ranges. The control of the audio rate conversion filter 240 by a specific controller (not shown) controls the interpolation of the audio rate conversion filter 240 in which the filled buffer among the N blocks of the main buffer 270 is less than M And if the number of buffers among the N blocks of the main buffer 270 exceeds a predetermined number L, the data rate of the data output through the decimation of the audio rate conversion filter 240 Thereby reducing the number.

That is, the audio rate conversion filter 240 of the present invention compensates for errors in the audio clock.

Different radio standards support various audio rates. 24k, 32k, 44.1k, 48k / sample, and the like are always outputted from the audio rate conversion filter 240 to 48k / sample. At this time, the audio rate conversion filter 240 can adjust the audio output at various rates such as 48.1k / sample or 47.9k / sample, which can compensate for the detected audio clock error.

The overall operation of the audio signal processing system 200 having the audio disconnection prevention function of the present invention will be described again with reference to a specific example.

When audio data such as MP2 / AAC is decompressed through the codec 220, the audio data is output in block units. 3, it is assumed that the output of the codec 220 is three, and four or two audio rate conversion filters 240 are displayed to be adjustable. The audio data is controlled by the main buffer 270 in a ring buffer manner, and four pieces of data are present in a total of eight blocks. In an ideal situation, there are four blocks of data in the main buffer 270, and four blocks are always empty. Because the number of inputs / outputs is the same, the main buffer 270 always remains filled with four blocks. However, when there is an error, the main buffer 270 can not hold four blocks and is reduced or expanded. At this time, when the number of blocks is reduced to one, feedback is performed to the audio rate conversion filter 240 to interpolate samples to increase data. On the other hand, when the number of blocks becomes seven, the audio rate conversion filter 240 decimates the data and reduces the data. When the number of blocks in the main buffer 270 becomes four as described above, the compensation circuit of the audio rate conversion filter 240 returns to its original state. As a result, it is possible to prevent overflow or underflow of the main buffer 270, thereby eliminating the audio interruption phenomenon.

4 is an operation explanatory diagram of an audio signal processing system 200 according to a preferred embodiment of the present invention. 4 is a graph showing a case where the number of the main buffers 270 filled in according to a crystal oscillator error changes in a direction of decreasing the number. The solid line represents the case where the conventional case is not compensated, and the dotted line represents the compensated case according to the present invention. That is, in the case of the solid line, the number of blocks should be kept at 4. However, the number of blocks is decreased to 0, under run occurs, and the number of blocks is filled up to 4, , And this phenomenon is repeated every 6 hours. However, as in the case of the dotted line, the interpolation of the audio rate conversion filter 240 is started when the number of blocks of the main buffer 270 becomes 1, the interpolation is stopped at the time when the number of blocks becomes 4 due to the increase of data The number of blocks filled in the main buffer 270, which is generated in the solid line, becomes 0, and the under-run phenomenon occurs, which is generated when the number of blocks becomes 1 again. In the opposite case, although not shown in FIG. 4, when the audio data increases due to the error, the number of filled blocks increases to 8, and an overflow occurs, so that the audio discontinuity disappears.

As described above, according to the audio signal processing system 200 of the preferred embodiment of the present invention, it is possible to prevent the audio signal from being interrupted.

That is, the audio signal processing system having the audio interruption prevention function of the present invention has the following effects.

(1) In digital radio system, it is possible to eliminate audio discontinuity caused by error of crystal oscillator.

(2) It can be applied to all digital radio standards (DAB / DRM / IBOC, etc.) using various audio rates.

(3) When several standards are implemented as one chip, they can be shared by various standards, and the chip size can be minimized.

100: Conventional OFDM system
110: OFDM modulator 120: OFDM demodulator
130: Oscillator 140: Audio rate conversion filter
150: I2S buffer
200: Audio signal processing system of the present invention
210: audio buffer 220: codec
230: Codec buffer 240: Audio rate conversion filter
250: buffer for audio rate conversion filter 260:
270: Main buffer 280: I2S buffer

Claims (7)

A codec for decompressing the audio data and outputting the decompressed audio data in blocks;
An audio rate conversion filter for converting the audio data in the block unit according to a designated data rate and outputting the audio data;
A main buffer which is composed of a plurality of N blocks and is capable of storing audio data in a first predetermined size in each of the N blocks; And
And a controller for controlling operations of the audio rate conversion filter and the main buffer,
Wherein the controller adjusts the data rate of the audio rate conversion filter when a filled buffer among all N blocks of the main buffer exceeds L number of predetermined blocks or less than M number of predetermined blocks, And decreasing the number of data output through decimation of the audio rate conversion filter when a filled buffer among the N blocks of the main buffer exceeds L number of predetermined blocks,
Wherein the N is greater than the L and the L is greater than the M. delete delete The method according to claim 1,
The controller comprising:
And the main buffer is controlled in a ring buffer manner. delete The method according to claim 1,
The controller comprising:
Characterized in that the number of data output through interpolation of the audio rate conversion filter is increased when the number of buffers among the N blocks of the main buffer is less than M, Audio signal processing system. delete

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