KR100546636B1 - Error Correction Method and Device of Digital VR - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to digital VCRs and to methods and apparatus for error correction for playback signals on tapes. The digital VCR error correction circuit of the present invention receives a signal reproduced from a tape and recovers the clock of the signal, a clock recovery unit receives a signal output from the clock recovery unit, a synchronization signal detection unit detecting a synchronization signal, Internal error decoding to correct the dropout error by receiving the signal from the position information generator that detects the position where the dropout error of the signal is received, and the position of the error from the position information generator, and receiving the playback signal from the synchronization signal detector. The internal error decoding unit includes an external error decoding unit for correcting the error by receiving a reproduction signal corrected for the drop error and a signal for correcting the error.

Description

Error correction method and device of digital VC R

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to digital VCR, and more particularly, to an error correction method and apparatus for correcting a drop out error caused by overheating of a magnetic recording medium such as a video tape.

Drop out means that a magnetic recording medium such as a video tape performs a function as a predetermined signal while the strength or position of the magnetic material changes. The drop out error is a phenomenon in which the strength and position of the magnetic material of the magnetic recording medium cannot be adjusted, and thus recording and reproduction of signals on the tape are not performed.

There are many causes of this dropout error. Dropout errors occur when the magnetic material is not evenly applied on the tape surface or when the tape surface is physically damaged. Conventional analog VCRs compensated for these dropout errors using a 1H delay line. That is, the analog VCR may correct an error of one scan line.

In the case of a digital VCR, a two-dimensional structure of an inner ECC decoder 15 and an outer ECC decoder 16 is used as shown in FIG. 1 to indirectly improve an error correction capability. . The internal ECC mainly performs error correction for random errors, and the external ECC performs error correction by distributing an error that cannot be corrected by the internal correction, in particular, a burst error. Errasure Decording has typically been employed to correct this burst error.

The driving principle of the conventional digital VCR shown in FIG. 1 will be described. When the video signal recorded on the tape is read by the head 11, the video signal is amplified and reproduced by the amplifier 12. The reproduced video signal is composed of reproduction information through the clock recoverer 13 and the synchronization signal detector 14. This reproduction information contains an error due to the condition of the head or the tape. This reproduction information is outputted to the image processor by random error correction in the internal ECC decoder 15 and burst error correction in the external ECC decoder 16.

However, the error correction method of the conventional digital VCR has the following problems. Conventional digital VCRs can detect whether an error occurs in a video signal reproduced from a tape by the head, but is not directly used for error correction. Therefore, there is a problem that the ability to correct the burst error is poor.

An object of the present invention is to determine whether or not a dropout error occurs in the video signal and to detect a location where a dropout error occurs, thereby improving the correction ability for error correction.

The present invention is characterized by increasing the correction ability for error correction by more than two times by detecting the position of the dropout error before the error correction in the ECC decoder and input to the internal ECC decoder.

As shown in FIG. 2, the error correction circuit of the present invention includes a clock recovery unit 120, a synchronization signal detection unit 130, a position information generation unit 200, an internal error decoder 140, and an external error decoder 150. Consists of The clock recovery unit 120 receives the signal reproduced from the tape and recovers the clock of the signal. This clock is later used as a pulse of the delay time of the reproduction signal. The synchronization signal detector 130 receives a signal output from the clock recovery unit and detects synchronization of the signal.

The position information generation unit 200 receives the same signal as that applied to the clock recovery unit and a signal reproduced from the tape, detects a position where a dropout error of the reproduction signal occurs, and applies the error position information to the internal error decoder. The position information generation unit is composed of an envelope detection unit 160, a comparator 170 and a delay unit 180. The envelope detection unit 160 receives the signal reproduced from the tape and outputs a change value S (t) of the output peak value of the reproduction signal over time. The graph for this S (t) signal is as shown in FIG. The comparator 170 receives S (t) and an error threshold value TH and outputs 0 when the S (t) value is larger than the error threshold value and 1 when the value is smaller than the error threshold value. This value corresponds to D (t) in the graph of FIG. The delay unit 180 delays this D (t) for a predetermined time and applies it to the internal error decoding unit. This D (t) corresponds to the position of the failed tape.

The internal error decoding unit 140 receives the dropout error position 181 from the position information generation unit 200 and corrects the error by receiving the reproduction signal from the synchronization signal detection unit 130. In addition, the external error decoding unit 150 receives the reproduction signal 141 corrected by the internal error decoding unit 140 and the correction whether or not the signal 142 is corrected to correct the remaining error after dispersing the burst error (burst error) .

The operation principle of the error correction circuit of the present invention is as follows. A reproduction signal is detected from the head 100 of the VCR and passes through the amplifier stage 110. The reproduced signal is extracted through a clock recovery process, and a clock signal having an appropriate period is extracted, and the synchronized signal included in the reproduced signal is detected through the synchronized signal detection process. This reproduction signal is applied to the ECC decoders 140 and 150 to restore the image information.

On the other hand, a part of the reproduction signal passed through the amplifier stage 110 passes through the envelope detection unit 160 to detect the envelope and is output as the signal S (t). This S (t) is compared with the threshold TH and converted into a dropout detection signal Do (t). This Do (t) has a value of 1 when S (t) is smaller than TH and 0 when it is large. This Do (t) is delayed for a predetermined time in the delay unit and applied to the internal decoder to be used as the error position information 181 of the internal decoder 140.

At this time, the delayed time is considered in consideration of the delay time for the reproduction signal passing through the amplifying stage to pass through the clock recovery unit 120 and the synchronization signal detector 130 to the internal decoder 140, and the reproduction signal from which the synchronization signal is detected. Until the Do (t) signal is applied to the internal decoder at the same time. TH is set in consideration of the quality of the magnetic tape and the detection performance of the system. In other words, when the signal S (t) is smaller than the threshold value TH, which is an appropriate signal value, Do (t) becomes one. When this Do (t) becomes 1, the internal decoder 140 detects this part as a position where an error occurs in the reproduction signal.

The reproduction signal applied to the ECC decoder is first applied to an inner decorder 140. This reproduction signal is decoded by an internal decoder and output as an internal decoding signal and a correction signal. At this time, Do (t) received from the location information generator 200 is used as error location information of the internal decoder. If the section in which Do (t) is 1 is long in the graph as shown in Fig. 3, the internal decoder 140 decodes the reproduction signal by increasing the correction capability.

In this internal decoding process, the reproduction signal is output as the corrected reproduction signal 141 and correction signal 142 for the reproduction signal. The corrected reproduction signal 141 is then restored to the image information through an outer decoding process. At this time, the correction whether the signal 142 output during the internal decoding process is used as error position information of the external decoding process.

Fig. 4 shows the reproduction signal input to the internal decoder and the D (t) signal detected by the position information generator. As shown in Fig. 4, the reproduction signal in the section in which the D (t) signal is 1 is a signal in which a dropout error has occurred.

The error correction method and apparatus for the reproduction signal of the present invention have a higher correction capability than the conventional error correction method and apparatus. This is because the error correction method and apparatus of the present invention corrects the error by using the location information of the burst error in the internal decoder. Conventionally, there was no signal or means for informing the position where an error occurred in the internal decoder. Therefore, the present invention has the effect that the correction ability for the burst error is higher than in the prior art.

1 is a block diagram showing an error correction method and apparatus of a conventional digital VCR.

2 is a block diagram showing an error correction method and apparatus for a digital VCR of the present invention.

3 is a graph showing the values of the detected signal on the tape surface versus time, and the threshold and dropout signals.

4 is a graph showing a correlation between position information and a playback signal.

Explanation of symbols for main parts of the drawings

100: head 110: amplification stage

120: clock recovery unit 130: synchronous signal detector

140: inner decoder 141: corrected reproduction signal

142: correction signal (V_outer) 150: outer decoder (outer decoder)

160: Envelope detector

170: comparator 180: delay

181: error location information (V_inner) 200: location information generator

Claims (1)

A clock recovery unit receiving a signal reproduced from a tape and recovering a clock of the signal; A synchronization signal detector for detecting a synchronization signal by receiving the signal output from the clock recovery unit; An envelope detection unit receiving a signal reproduced from the tape and outputting a reproduction signal peak value; A comparator for receiving the reproduction signal peak value and the error threshold value and outputting a signal according to a comparison result of the reproduction signal peak value and the error threshold value; A delay unit which delays an output value of the comparator for a predetermined time and applies the internal error decoding unit; An internal error decoding unit receiving a position of a dropout error from the delay unit and correcting a burst error by receiving a reproduction signal from the synchronization signal detection unit; And an external error decoding unit configured to correct the burst error by receiving the reproduction signal corrected by the internal error decoding unit and the correction availability signal.

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