KR100636353B1 - Adaptive Boost­Gain Controlled Limit Equalizer and Gain Calculation Method in above Limit Equalizer - Google Patents

Abstract

 An adaptive limiting equalizer according to the present invention comprises: an interpolator for calculating an intermediate value of an output sampling value of a general equalizer; The median value output from the interpolator is compared with a threshold value calculated in advance, and when the median value is greater than the threshold value, a threshold value having a sign of the median value is output. When the median value is less than the threshold value, the median value is output. Output limiter; A threshold value calculator for calculating a threshold value at a zero crossing portion of the output signal of the limiter and the output signal of the interpolator; An amplifying filter unit passing only a frequency of a minimum length signal of the output signal of the limiter; An envelope detector for calculating an amplitude of the general equalizer output signal; A gain calculator which compares the amplitude information of the limiting equalizer input signal calculated by the envelope detector with the output signal of the limiting equalizer and calculates a gain suitable for the currently inputted reproduction waveform; A multiplier multiplying the gain calculated by the gain calculator and the output signal of the amplification filter; And a delay unit configured to delay the general equalizer output for a predetermined time, and the output signal is added to an output signal of the multiplier to be output.

In addition, the gain calculation method in the adaptive limiting equalizer according to the present invention comprises the steps of determining a zero crossing by comparing the output value of the limiting equalizer and the one clock delayed output value of the limiting equalizer output signal; Obtaining a distance difference between the two values when it is determined as zero crossing; Compare the value of the distance difference with the envelope value calculated by the envelope detector. If the value of the distance difference is greater than the envelope value, the value of the variable sigma is increased, and the value of the distance difference is the envelope. Decreasing the value of the variable sigma if less than the value; When the variable sigma is sigma> K compared to the user-defined reference value K, the gain of the current high frequency amplification filter is decreased by one, and when sigma <-K, the gain of the current high frequency amplification filter is increased by one.

As described above, the present invention can improve the operation and improve the performance in a realistic environment by improving the limit equalizer proposed in the optical disc format, in particular the Blu-ray Disc standard, which is the next generation optical disc format.

Blu-ray Disc (BD), Equalizer, Gain

Description

Adaptive Boost­Gain Controlled Limit Equalizer and Gain Calculation Method in above Limit Equalizer             

1 is a view showing a connection between a general equalizer and a limit equalizer.

2 is a block diagram showing the structure of a limit equalizer according to the prior art.

FIG. 3 is a graph illustrating the characteristics of a signal passed through the limiting equalizer of FIG. 2.

4 is a block diagram showing the structure of a limit equalizer according to an embodiment of the present invention.

5 is a flowchart illustrating a method of calculating an optimum gain in the gain calculator of FIG. 4.

<Description of the symbols for the main parts of the drawings>

310: interpolator 320: limiter

330: threshold value calculation unit 340: amplification filter unit

350: delay unit 360: multiplier

370: envelope detector 380: gain calculation unit

The present invention relates to an adaptive limiting equalizer and a method of calculating a gain in the equalizer, and in particular, a limitation that assists signal reproduction by selectively amplifying a signal having a minimum length in a reproduction signal processing portion of an optical disc. An adaptive limiting equalizer capable of stabilizing the operation of the equalizer and increasing the performance thereof, and a method for calculating the gain in the equalizer.

The equalizer refers to a device which has a function of inserting into an amplification or transmission path in order to correct distortion occurring in the process of amplifying or transmitting a signal and synthesizing the characteristics to equalize the characteristics.

In particular, the limit equalizer is a signal processing device appearing in the specification of the next-generation high-capacity optical disc format, the Blu-ray Disc (BD).

In the case of the next-generation optical disc format, the minimum signal length has a shorter length (3T-> 2T, T is one bit length) than the previous formats such as CD and DVD. Therefore, the higher frequency component suppresses the optical disc channel. These short length signals are particularly vulnerable to noise components and various distortion components because of their small amplitude.

The limited equalizer is a nonlinear equalizer designed to compensate for the signal characteristics of the next-generation optical disk, and in particular, amplifies a small length signal, that is, a high frequency signal component, thereby reducing the effects of signal distortion, and detecting bit data correctly. It helps to get things done.

Hereinafter, the equalizer will be described in more detail with reference to FIGS. 1 to 3.

FIG. 1 is a diagram showing a connection relationship between a general equalizer and a limit equalizer proposed in a next-generation optical disc (Blu-ray Disc).

Referring to FIG. 1, a general equalizer 100, a limit equalizer 200 for processing a signal by receiving an output of the general equalizer 100 as an input, and an output signal of the limit equalizer 200 as an input. A PRML detector 300 and a phase detector 400.

The general equalizer 100 serves to amplify the signal in the high frequency region, but the effect is not as large as the limiting equalizer, and because the frequency region to amplify is wide, only the minimum length signal cannot be amplified.

Generally, the general equalizer is included in an analog signal filtering chip called an RF chip, and is designed to be adjusted so that a user can obtain an optimal performance.

The limit equalizer 200 is a non-linear equalizer for selectively amplifying a signal having a minimum length from the output signal of the general equalizer 100. In the standard, the design standard of the general equalizer is fixed according to the disk, but in reality, the standard of the equalizer is different from the Blu-ray disc standard because the standard of the equalizer is different for each RF chip and the user can control it. The input of is bound to the limit equalizer. In this case, the output of the limiting equalizer cannot produce the effect proposed by the standard.

The Partial Response Maximum Likelihood (PRML) detector 300 intentionally uses interference between symbols to detect the interfering data sequence with the Viterbi algorithm while suppressing the deterioration of the Signal Noise Rate (SNR).

Figure 2 shows the structure of the limit equalizer proposed in the Blu-ray Disc standard.

The limiting equalizer has a structure that adds the value selectively amplified by the limiting equalizer to the output value passed through the general equalizer.

That is, as shown in FIG. 2, first, an intermediate value is obtained through an interpolator 210 that obtains an intermediate value of an output sampling value of a general equalizer, and the limiter 220 calculates the intermediate value in advance. If the median value is smaller than the absolute value of the threshold value, the result is passed as it is. If the median value is greater than the absolute value, the threshold value having the sign of the median value is output. .

The output value of the limiter 220 is then added to the value passed through the general equalizer via the filter 242 passing the frequency portion of the minimum length signal.

The amplification filter unit 240 may include first, second and third clock delay units 241a, 241b and 241c for delaying the output signal of the limiter 320 by one clock; And an adder 242 for adding output signals of the first, second, and third clock delay units.

The reproduction signal passing through the general equalizer has a small amplitude in the case of the signal having the minimum length. However, when the signal passes through the limiting equalizer, the amplitude of the minimum length signal is amplified to be similar to that of the long length signal.

Using the limited equalizer as described above, since the signal having the smallest length also has a large amplitude, it is easy to determine the bit signal, thereby increasing the level of signal reproduction.

However, in the Blu-ray Disc standard, different values are set and fixed according to the type of the disc to reproduce the characteristics of the general equalizer, the gain value of the limited equalizer, and the like.

Accordingly, conventionally, in the case of a general equalizer, the boost gain is adjusted differently from the standard so as to have an optimal performance. As a result, the signal input to the limiting equalizer has characteristics different from those of the signal defined in the standard. Have

In addition, in reality, the reproduction signal processing unit including the general equalizer of the optical disc is hardly implemented as the standard, so the operation of the limited equalizer proposed by the standard is inevitably different from the standard. For example, in the general equalizer of the front end, if the high frequency component is amplified larger than that suggested in the standard, the signal is greatly amplified at the edge part of the signal as shown in FIG. Or the high frequency signal is amplified too large and the signal shape is distorted. This adversely affects the behavior of phase detectors, PRML detectors, and so forth, behind the limiting equalizer.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide an operation of a limit equalizer which helps signal reproduction by selectively amplifying a signal having a minimum length in a reproduction signal processing portion of an optical disc. The present invention provides an adaptive limiting equalizer capable of stabilizing and improving performance and a method for calculating gain in the equalizer.

In order to achieve the above object, the adaptive limiting equalizer according to the present invention includes an interpolator for calculating an intermediate value of an output sampling value of a general equalizer; The median value output from the interpolator is compared with a threshold value calculated in advance, and when the median value is greater than the threshold value, a threshold value having a sign of the median value is output. When the median value is less than the threshold value, the median value is output. Output limiter; A threshold value calculator for calculating a threshold value at a zero crossing portion of the output signal of the limiter and the output signal of the interpolator; An amplifying filter unit passing only a frequency of a minimum length signal of the output signal of the limiter; An envelope detector for calculating an amplitude of the general equalizer output signal; A gain calculator which compares the amplitude information of the limiting equalizer input signal calculated by the envelope detector with the output signal of the limiting equalizer and calculates a gain suitable for the currently inputted reproduction waveform; A multiplier multiplying the gain calculated by the gain calculator and the output signal of the amplification filter; And a delay unit configured to delay the general equalizer output for a predetermined time, and the output signal is added to an output signal of the multiplier so as to be output.

The amplification filter unit may include: first, second and third clock delay units configured to delay the output signal of the limiter by one clock; And an adder for adding output signals of the first, second, and third clock delay units.

In addition, the gain calculation method in the adaptive limiting equalizer according to the present invention comprises the steps of determining a zero crossing by comparing the output value of the limiting equalizer and the one clock delayed output value of the limiting equalizer output signal; Obtaining a distance difference between the two values when it is determined as zero crossing; When the value of the distance difference is greater than the envelope value, the value of the variable sigma is increased by comparing the value of the distance difference with the envelope value calculated by the envelope detector, and the value of the distance difference is the envelope value. If smaller, decreasing the value of the variable sigma; When the variable sigma is sigma> K compared to the user-defined reference value K, the gain of the current high frequency amplification filter is decreased by one, and when sigma <-K, the gain of the current high frequency amplification filter is increased by one.

The determination of the zero crossing is characterized in that it is determined that zero crossing has occurred when the sign of the output value of the limited equalizer and the one-clock delayed output value of the limited equalizer output signal are different.

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

4 is a block diagram showing the structure of a limit equalizer according to an embodiment of the present invention.

4, the limit equalizer according to the present invention includes an interpolator 310, a limiter 320, a threshold value calculator 330, an amplification filter 340, a delay unit 350, and a multiplier 360. , An envelope detector 370 and a gain calculator 380.

The interpolator 310 calculates an intermediate value of output sampling values of the general equalizer.

The sampling of the general equalizer is sampled at a zero-crossing position. The value of the phase position shifted by 180 ° from the sampling position is called an output sampling value.

The limiter 320 compares a median value of the sampling value output from the interpolator 310 with a threshold value calculated in the threshold value calculation unit. If greater, a threshold value having a sign of an intermediate value is output. If the intermediate value is less than a threshold value, the intermediate value is output.

The threshold calculator 330 calculates an appropriate threshold value at the zero crossing portion of the output signal of the limiter 320 and the output signal of the interpolator 310.

A method of calculating a threshold value of the limit equalizer is as follows.

When the inputs to the limiter 320 are referred to as IP (n) and IP (n-1), where n-1 represents n by one clock delay,

sgn (IP (n))! = sgn (IP (n-1)), the threshold value TH = TH + [0.5 * abs {IP (n)-IP (n-1)}-TH] / 256, otherwise TH = TH. Here, sgn means a sign.

In other words, the input to the limiter is updated only when zero-crossing occurs.

The amplifying filter unit 340 passes only the frequency of the minimum length signal of the output signal of the limiter 320.

The amplification filter unit 340 may include: first, second and third clock delay units 341a, 341b, and 341c for delaying the output signal of the limiter 320 by one clock; And an adder 342 for adding output signals of the first, second, and third clock delay units.

The envelope detector 370 monitors an envelope of the output of the general equalizer to calculate an amplitude of the general equalizer output signal.

The gain calculator 380 compares the amplitude information of the limiting equalizer input signal calculated by the envelope detector 370 with the output signal of the limiting equalizer and calculates a gain suitable for the currently inputted reproduction waveform.

Since the gain calculation method performed by the gain calculator 380 is described in more detail in the following description of FIG. 5, a description thereof will be omitted.

The multiplier 360 multiplies the gain calculated by the gain calculator 380 and the output signal of the amplification filter unit, and the calculated value is transferred to a next stage (adder).

The delay unit 350 delays the general equalizer output for a predetermined time, and the output signal is added to an output signal of the multiplier and output.

5 is a flowchart illustrating a method of calculating an optimum gain in the gain calculator of FIG. 4.

Referring to FIG. 5, a method of calculating an optimum gain in the gain calculator will be described. Here, an edge of an output waveform of the limiting amplifier is adjusted by adjusting a gain value of the high frequency amplification filter of the limiting amplifier. It works with the goal that the limiting amplifier operates stably when the magnitude of the difference in the values in the portion (where the zero crossing occurs) is similar to the envelope.

In other words, the gain calculating unit first determines zero crossing by comparing the output value Op (n) of the limiting amplifier with the output value Op (n-1) delayed by one clock.

Here, the signs of the two values are compared, and if the signs are different from each other, it is determined that zero crossing has occurred.

If it is determined in step 101 that zero crossing is obtained, a distance difference between the two values is obtained (S102).

The distance difference refers to an absolute value of the difference between the two values. That is, the distance difference Gap = abs {Op (n) -Op (n-1)} may be represented.

In the present invention, after calculating the distance difference between the two values as described above, the value of the distance difference (Gap) is the envelope amplitude value by comparing the value of the distance difference and the envelope amplitude value calculated by the envelope detector. If larger than Envelop, the value of the variable sigma is increased, and if the distance difference value is smaller than the envelope amplitude value Envelop, the value of the variable sigma is decreased.

If the value of the distance difference in zero-crossing is smaller than the envelope envelope value (Envelop), the value of sigma will continue to decrease, and conversely, the value of the distance difference in zero-crossing will be reduced. If the value is larger than the normal envelope amplitude value, the value of sigma will continue to increase.

In the present invention, if the sigma value obtained in step 103 is sigma > K (S104) compared with the reference value (positive value) K predetermined by the user (S104), the gain m of the current high frequency amplification filter is decreased by one (S105). If sigma < -K (S106), the gain m of the current high frequency amplification filter is increased by one (S107).

In the present invention, the optimum gain (m) can be obtained by repeating steps 103 to 107.

With the above algorithm, the magnitude of the amplitude of the edge portion of the limiting amplifier or the output value of the high frequency signal can be maintained almost similar to the amplitude of the envelope.

Accordingly, in the present invention, the output of the limiting amplifier is stably maintained, thereby stably maintaining the operation of a phase detector or a PRML detector of the rear stage using the output of the limiting amplifier, and no matter what characteristics the input signal has The output of the limiting amplifier can maintain nearly constant performance.

In addition, since the gain calculation method recognizes the characteristics of the input signal itself and operates appropriately, the gain can be facilitated.

The present invention can be applied to disc formats such as CD or DVD as well as Blu-ray discs proposed in the standard.

As described above, with reference to the preferred embodiment of the present invention, those skilled in the art will be variously modified and modified within the scope of the present invention without departing from the spirit and scope of the present invention described in the claims below. It will be appreciated that it can be changed.

As described above, the present invention can improve the operation and improve the performance in a realistic environment by improving the limit equalizer proposed in the optical disc format, in particular the Blu-ray Disc standard, which is the next generation optical disc format.

Claims (4)

An interpolator for calculating an intermediate value of output sampling values of a general equalizer; The median value output from the interpolator is compared with a threshold value calculated in advance, and when the median value is greater than the threshold value, a threshold value having a sign of the median value is output. When the median value is less than the threshold value, the median value is output. Output limiter; A threshold value calculator for calculating a threshold value at a zero crossing portion of the output signal of the limiter and the output signal of the interpolator; An amplifying filter unit passing only a frequency of a minimum length signal of the output signal of the limiter; An envelope detector for calculating an amplitude of the general equalizer output signal; A gain calculator which compares the amplitude information of the limiting equalizer input signal calculated by the envelope detector with the output signal of the limiting equalizer and calculates a gain suitable for the currently inputted reproduction waveform; A multiplier multiplying the gain calculated by the gain calculator and the output signal of the amplification filter; And And a delay unit for delaying the general equalizer output for a predetermined time, the output signal being added to an output signal of the multiplier for output. 2. The apparatus of claim 1, wherein the amplifying filter unit comprises: first, second and third clock delay units configured to delay the output signal of the limiter by one clock; And And an adder for adding output signals of the first, second, and third clock delay units. Determining a zero crossing by comparing an output value of the limit equalizer and a one clock delayed output value of the limit equalizer output signal; Obtaining a distance difference between the two values when it is determined as zero crossing; When the value of the distance difference is greater than the envelope value, the value of the variable sigma is increased by comparing the value of the distance difference with the envelope value calculated by the envelope detector, and the value of the distance difference is the envelope value. If smaller, decreasing the value of the variable sigma; If the variable sigma is sigma> K compared to the user-defined reference value K, the gain of the current high frequency amplification filter is decreased by one, and if sigma <-K, the gain of the current high frequency amplification filter is increased by one. A method for calculating the gain in an adaptive limit equalizer, characterized by obtaining a gain. 4. The adaptive limit equalizer of claim 3, wherein the determination of the zero crossing is determined by whether or not the sign of the output value of the limit equalizer and the one clock delayed output value of the limit equalizer output signal is different from each other. How to calculate gain in

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