KR100202392B1 - Adaptive equalizer with variable training array in a digital video cassette recorder - Google Patents

Abstract

The present invention relates to a digital video cassette recorder, comprising: a feed forward section (1) for equalizing and outputting an input signal (6) in accordance with a transform coefficient (14); A data determination section (3) for determining the level of the output of the feed forward section (1) and outputting it as detection data (5); A data determination unit 3 outputting the detection data 5; A preamble detection unit (9) for detecting a preamble from the detection data (5) and selectively outputting a synchronization signal (10); A preamble generator (8) for sequentially outputting the preamble of the track as training data (11) in accordance with the input of the synchronization signal (10); A reference signal switching unit (2) for switching in accordance with the synchronization signal (10) to selectively output detection data (5) or training data (11); An error calculator (4) for calculating the difference between the output of the switching section (2) and the output of the feed forward section (1) and outputting it as an error signal (7); And a coefficient adaptation unit 13 for inputting the synchronization signal 10 as an adaptation start signal 12 and outputting the conversion coefficient 14 according to the adaptation start signal and the error signal 7.

Therefore, the present invention has the structure of the adaptive equalizer without having to put a specific training period and training sequence in the digital VCR, so that the performance is improved compared to the fixed equalizer, and the structure of the adaptive equalizer is simplified.

Description

Adaptive Equalizer with Variable Training Rows in Digital Video Cassette Recorder

1 is a block diagram of an adaptive equalizer with a variable training sequence in a digital video cassette recorder in accordance with the present invention.

2 shows a state of a signal input to an adaptive equalizer having a variable training sequence in a digital video cassette recorder according to the present invention.

3 is a block diagram of a preamble detection unit configured in an adaptive equalizer having a variable training sequence in a digital video cassette recorder according to the present invention.

4 is a block diagram of a preamble generation unit configured in an adaptive equalizer having a variable training sequence in a digital video cassette recorder according to the present invention.

* Explanation of symbols for main parts of the drawings

1: feed forward part 2: reference signal switching part

3: data determining unit 4: error calculating unit

8: preamble generating unit 9: preamble detecting unit

The present invention relates to an equalizer for removing signal distortion generated in a channel, and more particularly, an adaptive having a variable training sequence in a digital VCR using a preamble of a digital video cassette recorder (hereinafter referred to as a digital VCR) as a training sequence. It is about an equalizer.

In normal wired or wireless transmissions, the transmitted signal passes through a channel that is noisy and introduces signal distortion. In this environment, channel compensation is required to maintain performance and to improve transmission efficiency. Equalizers are commonly used to remove distortions in channels.

The equalizer can be largely classified into a fixed equalizer and an adaptive equalizer, and it can be seen through various references or commercial systems that the performance of the adaptive equalizer is superior to that of the fixed equalizer. However, the adaptive equalizer must have a training sequence that is known to both the transmitting and receiving parties. For this reason, the fixed training sequence is transmitted at the beginning of transmission to train the adaptive equalizer to adapt its channel. Therefore, it is difficult to award an adaptive equalizer in the absence of a special training sequence.

In particular, when designing a new system, a system design is made with an adaptive equalizer in mind, but it is not easy to use an adaptive equalizer for a system that does not consider existing equipment or an adaptive equalizer. However, if there is a preamble of a suitable length in such a system, training using it and then operating the system may improve the performance of the system to some extent.

On the other hand, in the standard definition digital VCR standard, a preamble is recorded in the first part of data recorded in a track in order to distinguish the tracks and tracks of the tape and keep the data synchronized.

The recording / reproducing format set in the current digital VCR standard is not specifically defined to use an equalizer, but there is a problem in that the performance of the system is fixed because a fixed coefficient equalizer is usually used. In particular, since the preamble recorded on the tape is used only in terms of track division and synchronous clock reproduction, there is a problem of inefficiency.

The present invention has been made to solve this problem, and as described above, if there is a preamble having a proper length in the system, it can be used as a training train, and the adaptive equalization is performed in the digital VCR using the preamble. It is possible to provide an adaptive equalizer with a variable training sequence in one digital VCR.

An adaptive equalizer having a variable training sequence in a digital VCR according to the present invention includes: a feed forward unit for equalizing and outputting an input signal according to a transform coefficient; A data determination unit which determines the level of the output of the feed forward unit and outputs the detected data as detection data; A preamble detector for detecting a preamble from the detection data and selectively outputting a synchronization signal; A preamble generator for sequentially outputting a preamble of a track as training data according to the input of the synchronization signal; A reference signal switching unit which is switched according to the synchronization signal and selectively outputs detection data or training data; An error calculator which calculates a difference between the output of the switching unit and the output of the feed forward unit and outputs an error signal; And a coefficient adaptation unit for inputting the synchronization signal as an adaptation start signal and outputting the transform coefficient according to the adaptation start signal and the error signal.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of an adaptive equalizer having a variable training sequence in a digital VCR according to the present invention. The feedforward 1 converts the input signal 6 of FIG. Is equalized and output.

The feed forward unit 1 output is applied to the data determination unit 3, and the data determination unit 3 determines the output level of the feed forward unit 1 and outputs it as the detection data 5.

The detection data 5 is applied to the reference signal switching unit 2, which will be described later, while being applied to the preamble detection unit 9, and the preamble detection unit 9 is a preamble detector for each track as shown in FIG. (91), (92), (93), a sync block detector (94), and a preamble error detection and sync block input determiner (95).

In this case, the preamble detectors 91, 92, and 93 for each track may store the corresponding preamble for each track and may determine a preamble based on currently detected detection data. In addition, the sync block detector 94 determines whether the preamble of the detection data ends and data is detected.

The determiner 95 determines whether or not the actual data is input to the sync block detector 94 by the preambles of the preamble detectors 91, 92, and 93 and the sync signal of the sync block detector 94. It is determined whether the detection is an error, and the synchronization signal 10 is output when the preamble synchronization is assured.

The preamble generator 8, which inputs the sync signal 10 from the preamble detector 9, sequentially outputs training data 11 for training the preamble of the track according to the input of the sync signal 10. .

That is, the preamble generator 8 is composed of the preamble generators 81, 82, 83, and the track preamble selector 84, as shown in FIG. At this time, the preamble generators 81, 82, and 83 output preambles for each track upon input of the sync signal 10, and the track preamble selector 84 preambles according to the sync signal 10. The preambles of the generators 81, 82, and 83 are sequentially output as the training data 11.

The training data 11 of the preamble generator 8 is applied to the reference signal switching unit 2, and the reference signal switching unit 2 is switched in accordance with the synchronization signal 10 to perform the The detection data 5 or the training data 11 are selectively output.

The output of the switching section 2 is applied to the error calculating section 4, and the error calculating section 4 calculates the difference between the output of the switching section 2 and the output of the feed forward section 1 and outputs an error signal (7). ) Is applied to the coefficient adaptation unit 13 as.

The coefficient adaptor 13 inputs the synchronization signal 10 as the adaptation start signal 12, and when the adaptation start signal 13 is input, updates the transform coefficient 14 according to the error signal 7 to feed forward. It is configured to apply to the unit (1).

The operation of the adaptive equalizer with variable training sequence in the digital VCR configured as described above is as follows.

That is, the received signal input as the input signal 6 is input to the feed forward section 1, multiplied by the current conversion coefficient 14, and then output to the data determination section 3. The data determination unit 3 determines the level of the transmitted data and outputs the detection data 5.

The output data 5 is input to the preamble detection unit 9 to check that the current preamble data is input. That is, the detection data 5 output from the data determination unit 3 is input to the preamble detection unit 9 for searching for the preamble of the track. The input data 5 is input to the preamble detectors 91, 92, and 93 for each track, and attempts to detect which track's preamble has been input. At the moment of detection, the preamble error detection and When it is transmitted to the sync block input determiner 95, the determiner 95 determines whether the actual data is detected by the sync block detector 94 or is a preamble detection error, thereby determining that the preamble synchronization is assured. The detected synchronization signal 10 is outputted so that another device can operate.

The preamble data generator 8 generates and outputs data corresponding to the next data after the detected sync signal 10 is generated. That is, the detected sync signal 10 controls the track preamble selector 84 while initializing the respective preamble generators 81, 82, and 83 to output the preamble of the corresponding track, thereby training data 11 To be used).

The reference signal switching unit 2 does not operate in the initial state, but switches to the preamble data generator output at the moment when the synchronization signal 10 is generated, and enters the training mode, and the error calculating unit 4 is free. The error signal 7 is calculated and output by using the signal output from the amble data generator 8 and the signal fed back through the reference signal switching unit 2 and the signal passed through the feed forward unit 1.

When the adaptation start signal 14 appears, the adaptation calculation unit 13 updates the transform coefficients 14 by the input signal 6 and the error signal 7 and transmits them to the feed forward unit 1.

When the preamble is no longer input during the training and thus does not receive the detected synchronization signal 7, the reference signal switching unit 2 detects the detection data from the training data input 11 to receive the determined detection data 5. 5) Switch the switching to input. At this time, since the conversion coefficient 14 keeps the value set by the training data by the preamble as described above, the feed forward unit 1 equalizes the transmission data by this coefficient value.

As described above, according to the present invention, the preamble data is generated in accordance with the change of the preamble data in the preamble data input period by the synchronization signal detected by the preamble data detection unit, thereby training and application occur.

Therefore, the present invention has the structure of the adaptive equalizer without having to put a specific training period and training sequence in the digital VCR, so that the performance is improved compared to the fixed equalizer, and the structure of the adaptive equalizer is simplified.

Claims (3)

A digital video cassette recorder comprising: a feed forward section (1) for equalizing and outputting an input signal (6) in accordance with a transform coefficient (14); A data determination unit (3) which determines the level of the output of the feed forward unit (1) and outputs it as detection data (5); A preamble detection unit (9) for detecting a preamble from the detection data (5) and selectively outputting a synchronization signal (10); A reference signal switching unit (2) for selectively outputting training data (11) to the preamble of the track according to the input of the synchronization signal (10); An error calculator (4) for calculating the difference between the output of the switching section (2) and the output of the feed forward section (1) and outputting it as an error signal (7); A digital video cassette recorder having a coefficient adaptation unit 13 for inputting the registration signal 10 as an adaptation start signal 12 and outputting the transform coefficients 14 according to the adaptation start signal and the error signal 7. Adaptive equalizer with variable training trains in. The track preamble detector (91) according to claim 1, wherein the preamble detection unit (9) stores the preamble for each track and can determine the preamble by the detection data (5) currently input. 92), 93; A sync block detector 94 for determining whether the preamble of the detection data 5 is finished and data is detected; The preamble of the preamble detectors 91, 92, and 93 and the synchronization signal of the sync block detector 94 determine whether real data is input to the sync block detector 94 or a preamble detection error. Adaptive equalizer having a variable training sequence in a digital video cassette recorder having a preamble and a sync block input determiner (5) for outputting a sync signal (10) when preamble synchronization is assured. The preamble generator (8), (82), (83) according to claim 1 or 2, wherein the preamble generator (8) outputs a preamble for each track upon input of the synchronization signal (10). )Wow; In a digital video cassette recorder having a preamble selector 84 for sequentially outputting the preambles of the preamble generators 81, 82, and 83 as training data 11 according to the synchronization signal 10. Adaptive equalizer with variable training sequence.