KR20030033832A - Apparatus for equalizing of optical record media - Google Patents

Abstract

The present invention relates to an optical record carrier equalizer, and more particularly, to multiply and accumulate N tap delays for digitizing and inputting RF signals by one symbol, and multiplying and accumulating the outputs and error values of the input RF signals and N tap delays, respectively. An N + 1 coefficient updater for performing an update, an adder that adds all of the outputs of the N + 1 coefficient updater, a sync pattern is detected from the input RF signal, and the sync pattern is run during the detected sync interval. And a sync pattern detector for outputting a sequence, and an error detector for calculating a difference between the output of the adder and the running sequence output from the sync pattern detector, and outputting an error value to the coefficient update unit. By performing coefficient updates only during this time, data demodulation can be accurately performed even if there is a fatal noise in the RF signal. have.

Description

Apparatus for equalizing of optical record media

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical recording medium recording / reproducing system, and more particularly to an apparatus for performing equalization by detecting a synchronization pattern of an optical recording medium when recording and reproducing an optical recording medium.

In general, an optical recording medium, that is, an optical disc recording and reproducing apparatus for recording and reproducing an optical disc, reproduces data recorded on the optical disc using an optical disc such as a compact disc (CD), a digital versatile disc (DVD), or the like as a recording medium. And a device for recording data on the disc.

For example, in the case of data recording on a rewritable optical disc in which the recording material is formed of a phase change material, the amount of reflection is changed by converting the light focused at the optical head into heat and then changing the state of the phase change recording medium with the heat. . Then, pits are recorded while marks are formed on the phase change type disk.

At this time, the laser light is incident on the opposite side of the reflective surface with a pit. Therefore, the pit appears as a projection when viewed from the laser incident side.

The pit has a width of 0.4 to 0.6 mu m, the length of one pit and the interval between the pit and the pit in 9 steps from 3T to 11T for a compact disc (CD) and 12T to 14T for a digital multifunction disc (DVD). Are divided into stages. Here, T means the length of one clock pulse, 3T means three clock pulses, and 11T corresponds to the length of 11 clock pulses.

Fig. 1 is a block diagram of a component related to a signal processing portion in a general optical disc recording and reproducing apparatus, wherein the optical pickup 102 is an optical disc for recording data on the optical disc 101 or reproducing data recorded on the optical disc 101. The laser is incident on the designated position of the disk 101, the reflected light is picked up, converted into an electrical signal, and then output to the RF and servo error generation unit 103.

The RF and servo error generator 103 combines electrical signals output from the optical pickup 102 to generate a focus error signal, a tracking error signal, an RF signal for data reproduction, and the like, and then the RF signal. Outputs to the analog equalizer 104.

The analog equalizer 104 removes noise and distortion of the RF signal, performs phase correction, and outputs the data to the slicing unit 105.

The data slicing unit 105 slices the waveform equalized RF signal to a predetermined slice level, converts the converted RF signal into a digital signal, and outputs the digital signal to the digital equalizer 106.

That is, in order to accurately convert an analog signal obtained from the optical pickup 102 to digital data after securing a servo characteristic of a predetermined level or more, an RF level and size must be secured. In particular, in the case of short T having a high frequency, such as 3T and 4T, the necessity of securing it is more significant. This is why the analog equalization unit 104 performs equalization.

For example, in the case of DVD, the pit length has 9 steps from 3T to 14T, and each T has a different frequency. Here, the shorter the length of T, the higher the frequency. The longer the length of T, the lower the frequency. That is, the frequency of 3T is the highest and the frequency of 14T is the lowest. In other words, 3T is 14/3 higher than 14.

Therefore, in the case of a short T, a portion of the input signal may be cut off due to the high frequency. When the signal is converted into a digital signal by the data slicing unit 105, even if the slicing level is slightly shaken, it may be converted into an incorrect signal. For example, if T was originally 3T, it could be converted to 2T or 4T instead of digitized to 3T.

In order to solve this problem, the analog equalizer 104 performs equalization by raising a level of a signal (eg, 3T, 4T, ...) of a high frequency band. Therefore, even if analog equalization is performed, phase characteristics or signal characteristics (ie, delays) may occur, and phase distortion may occur.

In addition, analog equalization has a disadvantage in that the burden increases as the speed increases.

Thus, the analog equalized signal is equalized once more by the digital equalizer 106.

In this case, the digital equalizer 106 uses a finite impulse response (FIR) filter close to the characteristics of the inverter channel with respect to the digital RF signal because it is easy and stable to implement.

FIG. 2 is a diagram illustrating an example of a conventional FIR filter. The filter coefficient is updated by applying a Least Mean Square (LMS) algorithm.

In other words, in case of FIR filter with fixed coefficient, it is difficult to cope with RF type that changes according to various states such as disk and servo, so it is necessary to change the coefficient of filter adaptively. To update the coefficients of the filter. In addition to this, a recursive least square (RLS) algorithm may be used to reduce an update error, but a large amount of calculation is disadvantageous.

Referring to FIG. 2, N tap delayers 201 for delaying a sliced input RF signal by one symbol, each output of the input RF signal and the tap delayer 201, and an error value e (k) are used. N + 1 coefficient updater 202 for performing coefficient update by adding the sum of the outputs of the coefficient updater 202, the output of the adder 203, and the running sequence inputted. It is composed of an error detection unit 204 for estimating the error value e (k) by using.

In FIG. 2, the sliced RF signal is delayed by one symbol while passing through the N tap delay units 201.

Each coefficient of the coefficient updater 202 is updated by an input RF signal, an output of each tap delayer 201, and the error value e (k).

Here, it is assumed that x (k) is an RF signal value input to the filter, x (ki) is an i symbol delay value through the tap delay unit 202, and the i th coefficient value of the filter is c _i (k). .

Then, the output of the FIR filter, that is, the output d '(k) of the adder 203 may be expressed by Equation 1 below.

The update expression of the filter coefficient using the LMS algorithm may be expressed as in Equation 2 below.

In Equation 2, c _i (k + 1) is an updated filter coefficient, and e (k) is an error value.

Each updated coefficient as shown in Equation 2 is added to the adder 203 and input to the error detector 204. The error detecting unit 204 sets the N + 1 coefficient updating unit 202 by setting the difference between the output d '(k) of the adder 203 and the input running sequence d (k) as an error value e (k). Will output

Here, the running sequence d (k) is a known sequence and is a random sequence using statistical characteristics.

However, the digital equalization method using the conventional FIR filter described above performs channel equalization through FIR filtering for all signal intervals including the data interval. Therefore, even when there is a fatal noise in the input RF signal, it is applied to the LMS algorithm as it is to update the filter coefficients, thereby causing a problem that incorrect data demodulation is performed in the PLL unit 107 and the decoder 108 at the rear stage. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide an optical recording medium equalization apparatus that detects a synchronization pattern from an input RF signal and performs equalization only in the detected synchronization period.

1 is a view showing a signal processing portion of a general optical recording and reproducing system

FIG. 2 is a block diagram of the digital equalizer of FIG. 1

3 is a block diagram of a digital equalizer according to the present invention

Explanation of symbols for main parts of the drawings

301: tap delay unit 302: coefficient update unit

303: adder 304: sync pattern detection unit

305: error detection unit

The optical recording medium equalizing device according to the present invention for achieving the above object, N (N is a natural number) tap delay for delaying the digitized RF signal by one symbol, the input RF signal and N N + 1 coefficient updater for multiplying and accumulating the output of the tap delayer and the error value to perform coefficient update, an adder for adding all the outputs of the N + 1 coefficient updater, and a synchronization pattern from the input RF signal. A synchronization pattern detector for outputting the sync pattern as a running sequence during the detected sync interval, and calculating a difference between the output of the adder and the running sequence output from the sync pattern detector, And an error detection unit outputting a value.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings illustrating the configuration and operation of the embodiment of the present invention, the configuration and operation of the present invention shown in the drawings and described by it will be described as at least one embodiment, By the technical spirit of the present invention described above and its core configuration and operation is not limited.

The present invention is to detect a sync pattern from an input signal and perform digital equalization only in a section in which a sync pattern is detected.

3 is a block diagram illustrating an FIR filter for performing equalization according to the present invention.

Referring to FIG. 3, N tap delayers 301 for delaying a sliced input RF signal by one symbol and each output and error value e (k) of the input RF signal and tap delayer 301 are used. N + 1 coefficient updater 302 for performing coefficient update by using the above, an adder 303 which adds all the outputs of the coefficient updater 302, and detects a sync pattern from an input RF signal, and detects a sync pattern. The error value e (k) by using the sync pattern detector 304 which outputs the running sequence of the preset sync pattern only, and the output of the adder 303 and the running sequence output from the sync detector 304. It consists of the error detection part 304 which estimates.

In the present invention configured as described above, the sliced RF signal is delayed by one symbol while passing through the N tap delayers 301, and the delayed signals in the sliced RF signal and the N tap delayers 301 are respectively N. It is output to the +1 coefficient updater 302. In addition, the sliced RF signal is output to the sync pattern detector 304.

Each coefficient of the coefficient updater 202 is updated by the RF signal input during the detected sync pattern period, the output of each tap delayer 201, and the error value e (k), and then added by the adder 303. Is added.

At this time, the configuration and operation of the tap delayer 301, the coefficient updater 302, and the adder 303, which delay the input signal and update the respective coefficients, may use the above-described FIG. Omit.

The output of the adder 303 is output to the error detector 305, and the error detector 305 calculates an output difference between the running sequence and the adder 303 input during the synchronization period detected by the sync pattern detector 304. Then, this is outputted to each coefficient updater 302 as an error value e (k).

Meanwhile, the sync pattern detector 304 detects a sync pattern from an input RF signal. For example, in the case of the DVD standard, if the 14 and 4T are repeated, the sync pattern detector 304 determines the sync pattern. In the case of the CD standard, if 11T is repeated, it is determined as a synchronization pattern. The sync pattern is set in advance as a running sequence.

Then, when the sync pattern is detected, the sync pattern detector 304 outputs a running sequence corresponding to the detected sync pattern to the error detector 305.

In this way, since the error detector 305 detects the error value e (k) only during the synchronization period and outputs it to each coefficient updater 302, the coefficient updater 302 also performs the coefficient update only during the synchronization period.

The filtered signal is output to the decoder 108 through the PLL unit 107 and demodulated.

As described above, according to the optical recording medium equalizing apparatus according to the present invention, the RF signal is detected by detecting a synchronization pattern from an input signal and updating each coefficient using a running sequence composed of the synchronization pattern during the detected synchronization period. Even if there is a fatal noise, data demodulation can be performed accurately.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (2)

N (N is a natural number) tap delayers sequentially delaying the digitized and input RF signal by one symbol; N + 1 coefficient update units for multiplying and accumulating the input RF signals and the outputs of the N tap delay units and error values, respectively, to perform coefficient update; An adder for adding all of the outputs of the N + 1 coefficient update units; A sync pattern detector configured to detect a sync pattern from the input RF signal and output the sync pattern as a running sequence only during the detected sync period; And And an error detector which calculates a difference between the output of the adder and the running sequence output from the sync pattern detector and outputs the error value to the coefficient updater as an error value. An equalizer of an optical record carrier for digitally equalizing an RF signal that is digitized and input, A sync pattern detector configured to detect a sync pattern from the input RF signal and output the sync pattern as a running sequence during the detected sync period; And And a coefficient updater for updating the coefficients of the filter only when the learning sequence is input using the synchronization pattern.