KR0121703Y1 - Audio record and reproduction apparatus with error block compensation circuit - Google Patents

Abstract

The present invention converts an audio signal, which is a time axis signal, into a frequency axis signal, records it on a recording medium, picks up recording information from the recording medium, and converts the reproduced frequency axis signal into a time axis signal to reproduce the audio signal. An apparatus, comprising: an inverse transform unit for inputting the reproduced frequency axis signal in units of blocks to inversely convert the time axis signal into a time axis signal; A first delay unit for delaying the time base signal obtained by the inverse transform by one block; A second delay unit for delaying an error check signal in units of blocks of the reproduced frequency axis signal by one block; A third delayer for delaying the output of the second delayer by one block; A fourth delayer for delaying the output of the first delayer by one block; According to the combination of the two-block delayed error check signal, the one-block delayed error check signal and the currently input error check signal, the one-block delayed time axis signal is inputted to the two-block delayed time axis signal and the current input. And an error block adjusting unit for reconfiguring and outputting the connection to the time axis signal.

Accordingly, the present invention can prevent the generation of pulsed noise by reconstructing and outputting the data of the error block so that the data of the error block is smoothly changed from the boundary value of the adjacent block.

Description

Audio recording and playback device with error block compensation circuit

1 is a conceptual block diagram of a general audio recording and reproducing apparatus.

2 is a block diagram of a reproduction system of an audio recording and reproducing apparatus having an error block compensating circuit according to a preferred embodiment of the present invention.

3 is a view for explaining block error compensation according to an embodiment of the present invention.

4 is a block diagram of a reproduction system of an audio recording and reproducing apparatus having an error block compensating circuit according to another embodiment of the present invention.

5 is a diagram showing the relationship between the error check data and the adjustment data in FIG.

6 is a view for explaining error block compensation according to another embodiment of the present invention.

The present invention relates to an audio recording and reproducing apparatus, and more particularly, to an audio recording and reproducing apparatus capable of removing pulsed noise at a discontinuous point caused by an error block during reproduction of a magneto-optical disc player such as a mini disc player.

In general, a magneto-optical disc player such as a mini disc player, as shown in FIG. 1, converts an analog audio signal into a digital signal through the analog / digital conversion unit 10 and records more information during recording. For this purpose, the digitally converted time axis signal is converted into a frequency axis signal by the positive conversion unit 20, and converted into serial data via the parallel / serial conversion unit 30 to be magneto-optically recorded on the disc. At the time of reproduction, the recording information is picked up optically from the disk, the picked-up recording information is photoelectrically converted, and the photoelectrically converted serial data signal is converted into parallel data via the serial / parallel conversion unit 40, and the parallel data signal is converted into a frequency axis. Since it is a signal, it is converted into a time base signal through the inverse converter 50, and reproduced and outputted as an analog audio signal through the digital / analog converter 60.

In the above-described mini disc player, an error may occur when recording or reproducing an audio signal on a magneto-optical disc, which is a recording medium. However, such an error may cause a case in which data of more than one block cannot be restored. In particular, because of frequency conversion, even if only one sample of the transmitted frequency components is wrong, the entire block data cannot be restored. When a block error occurs, the data of the block is processed to zero, and thus a discontinuity point occurs at the boundary between adjacent normal blocks, and this discontinuity point is loaded with impulsive noise on the audio signal, causing a decrease in playback quality. It became.

An object of the present invention is to provide an audio recording and reproducing apparatus that can improve the playback sound quality by removing the discontinuities of the boundary between the normal block and the error block in order to solve the problems of the prior art.

In order to achieve the above object, an embodiment of the present invention converts an audio signal, which is a time axis signal, into a frequency axis signal, records it on a recording medium, picks up recording information from the recording medium, and reversely converts the reproduced frequency axis signal into a time axis signal. An audio recording and reproducing apparatus for reproducing the audio signal, comprising: an inverse change unit which inputs the reproduced frequency axis signal in units of blocks and inversely converts the time axis signal into a time axis signal; A first delayer for delaying the time base signal obtained by the inverse transformation by one block; A second delay unit for delaying an error check signal in units of blocks of the reproduced frequency axis signal by one block; A third delayer for delaying the output of the second delayer by one block; A fourth delayer for delaying the output of the first delayer by one block; According to the combination of the 2-block delayed error check signal, the 1-block delayed error check signal and the currently input error check signal, when the discontinuous error occurs between adjacent blocks, the 1-block delayed time axis signal is input to the 2 block delayed time axis signal and the current input signal. And an error block adjusting unit for reconfiguring and outputting the connection to the time axis signal.

Further, another embodiment of the present invention converts an audio signal, which is a time axis signal, into a frequency axis signal, records it on a recording medium, picks up recording information from the recording medium, and inversely converts the reproduced frequency axis signal into a time axis signal to convert the audio signal. An audio recording and reproducing apparatus, comprising: a first delay unit for delaying the reproduced frequency axis signal by one block; An inverse converter for inputting the reproduced frequency axis signal in units of blocks to inversely convert the time axis signal into a time axis signal; An address decoder for generating an address signal according to a combination of an error check signal in block units of the reproduced frequency axis signal, the error check signal delayed by one block, and an error check signal currently input; An error block adjusting unit which generates adjustment data preset by the address signal generated by the address decoder; And a multiplier for multiplying the inverse transformed time base signal by the generated adjustment data.

Hereinafter, other objects and new features of the present invention will be described with reference to the accompanying drawings.

In the present invention, the error block compensating circuit is coupled to the inverse converting section 40 of the reproduction system in the audio recording and reproducing apparatus of FIG. Therefore, description of the same part as FIG. 1 is abbreviate | omitted.

2 is a block diagram of a preferred embodiment of the present invention, and shows only the inverse transform unit 40 and the error block compensation circuit unit of the reproduction system.

In FIG. 2, the reproduced frequency axis signal includes a demultiplexer 70 for separating error correction data and error check data in block units, an inverse transform unit 40 for inputting the separated data to inverse conversion into a time axis signal, and A first delay unit (72) for delaying the time-base signal obtained by inverse transformation by one block, a second delay unit (74) for delaying the separated error check data, and a block for outputting the second delay unit (74) A third delay unit 76 for delaying, a fourth delay unit 78 for delaying the output of the first delay unit 72 by one block, the two block delayed error check data E1 and the one block delayed error check According to the combination of the data E2 and the currently input error check data E3, when a discontinuous error occurs between adjacent blocks, the one-block delayed time axis signal is smoothly connected to the two-block delayed time axis signal and the currently input time axis signal. As far as possible And an error block adjusting unit 80 for reconfiguring and outputting the error block.

The error block adjusting unit 80 adjusts according to the adjustment algorithm shown in Table 1 according to the combination of the error check data.

Here, OK is an error check data of a block without an error and E is an error check data of a block with an error.

Therefore, when only one block among consecutive blocks is generated, the data of the error block is reconstructed and output so as to be linearly connected as shown in FIG. 3, and the first error is generated when more than two blocks of error blocks occur continuously. The block is processed as in row 5 of Table 1 and the second error block is processed as in row 6. In this way, the discontinuous points of the boundary point between the error block and the normal block are smoothly and linearly connected to remove the pulsed noise during the reproduction.

4 shows a block diagram of another embodiment of the present invention. In Fig. 4, the same parts as those of the embodiment are treated with the same reference numerals. Another embodiment of the present invention is a demultiplexer 70 for inputting a reproduced frequency axis signal in block units to separate the error correction data and the error check data, and a first delay unit 82 for delaying the separated data by one block. ), An inverse transformer 40 for inverting the one-block delayed data into a time axis signal, a second delayer 74 for delaying the separated error check signal by one block, and an output of the second delayer 74. A third delay unit (76) for delaying one block, an address decoder (84) for generating an address signal according to a combination of the two block delayed error check signal, the one block delayed error check signal, and the currently input error check signal, An error block adjusting unit 86 for generating adjustment data preset by the address signal generated by the address decoder; a product of multiplying the inversely converted time axis signal by the generated adjustment data And a group (88).

The relationship between the error check signals and the adjustment data is as shown in FIG. For example, if B2 is an error block among blocks B1, B2, B3, B4, and B5, the adjustment data is selected and output as shown in Table 2 below.

As shown in Table 2, the adjustment data are selected and output, and are multiplied by the data signal and the multiplier 88. Thus, as shown in the A waveform in FIG. .

As another example, when an error block occurs at one block interval, adjustment data is selectively output as shown in Table 3 below.

As shown in Table 3, the adjustment data are selected and output, and are multiplied by the data signal and the multiplier 88, so that the boundary points do not suddenly change stepwise like the B waveform of FIG. .

As described above, in the present design, the error block processes all values as zero data in order to solve the occurrence of pulse error due to the discontinuity generated at the boundary of the normal block and the error block. Pulsed noise can be prevented by reconstructing and outputting the data of the error block so as to change smoothly from the boundary value of the block.

Claims (2)

An audio recording and reproducing apparatus for converting an audio signal, which is a time axis signal, into a frequency axis signal and recording the same on a recording medium, and picking up recording information from the recording medium, and inverting the reproduced frequency axis signal into a time axis signal to reproduce the audio signal. An inverse transform unit for inputting the reproduced frequency axis signal in units of blocks to inversely convert the signal into a time axis signal; A first delayer for delaying the time base signal obtained by the inverse transformation by one block; A second delay unit for delaying an error check signal in units of blocks of the reproduced frequency axis signal by one block; A third delayer for delaying the output of the second delayer by one block; According to the combination of the two-block delayed error check signal, the one-block delayed error check signal and the currently input error check signal, the one-block delayed time axis signal is inputted to the two-block delayed time axis signal and the current input. And an error block adjusting unit for reconfiguring and outputting the connection to the time axis signal smoothly. An audio recording and reproducing apparatus for converting an audio signal, which is a time axis signal, into a frequency axis signal and recording the same on a recording medium, and picking up recording information from the recording medium, and inverting the reproduced frequency axis signal into a time axis signal to reproduce the audio signal. A first delayer for delaying the reproduced frequency axis signal by one block; An inverse transform unit which inputs the reproduced frequency axis signal in units of blocks and inverts the time axis signal into a time axis signal; A second delay unit for delaying an error check signal in units of blocks of the reproduced frequency axis signal by one block; A third delayer for delaying the output of the second delayer by one block; An address decoder configured to generate an address signal according to a combination of the two block delayed error check signal, the one block delayed error check signal, and the currently input error check signal; An error block adjusting unit which generates adjustment data preset by the address signal generated by the address decoder; And a multiplier for multiplying the inverse transformed time base signal by the generated adjustment data.