KR100334438B1 - Playback signal ash modeling device for optical disc system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for reproducing signal asymmetry modeling in an optical disc system for intentionally modeling a reproducing signal including an asymmetry for use in compensating for the asymmetry included in the reproducing signal. A zero signal detector for generating a basic signal for modeling an asymmetry component, a zero cross detector for detecting a zero cross point of the basic signal and outputting a zero cross detection signal, and a zero cross input from the zero cross detector A signal for use in the simulation of an optical disc system using a weighted ash geometry adding portion intentionally including an ash component component signal in a predetermined section of the signal, and a basic signal including the ash component components inputted from the weighted ash geometry adding portion. It includes a shaping unit for shaping and outputting. Accordingly, the present invention generates an RF signal to which an asymmetry is added for each sample signal, thereby generating a modeling signal to which an asymmetry is added without increasing the amount of processing data and signal processing time due to oversampling, There is an effect that can be effectively applied to the simulation.

Description

Playback signal ash modeling device for optical disc system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for testing an optical disc system for reproducing a signal recorded on an optical disc. More particularly, the present invention relates to an intentional reproduction of an reproduced signal including an asymmetry for use in compensating the asymmetry of a reproduction signal. The present invention relates to an apparatus for modeling reproduction signal asymmetry of an optical disc system, which is generated by modeling a signal.

In the simulation of the optical disc system to improve the reliability and accuracy of the optical disc system, the importance of how to model the signal processed by the optical disc system depends on its importance. Conventional modeling devices for experimenting with optical disc systems have generally been limited to MTF (Modulation Transfer Function) modeling, jitter time modeling, and Gaussian noise modeling. However, in addition to the above-described defect components such as interference caused by MTF, positional error such as jitter, Gaussian noise, and the like, there exist asymmetry and various defects of the optical disc reproduction signal.

The digital data recorded on the optical disc exists physically in the form of 'pit'. Since the pit is difficult to be ideally formed, in practice, the length of the pit increases or decreases in one direction. This phenomenon is called asymmetry. Asymmetry-causing factors come from a variety of sources, including manufacturing processes and pick-up performance, and are inevitable during disc handling. In addition, this asymmetry appears as an asymmetry component in the reproduced RF signal, resulting in a decrease in the accuracy of the optical disc system.

1 is a block diagram illustrating a conventional ash geometry modeling apparatus. FIG. 2 illustrates signals output from each component of the conventional modeling apparatus shown in FIG. 1.

The conventional asymmetry modeling apparatus focuses on modeling the shape of the pit generated on the optical disk, and as shown in FIG. 1, a modified run length limit (RLL) is described. There is an RLL modulated signal generator 10 for generating an NRZI signal. An oversampling section 12 for oversampling an NRZI modulated signal at the rear end of the RLL modulation signal generation section 10, an asymmetry section 14 for adding an asymmetry to the oversampled signal, The MTF filter unit 16 for shaping the signal to which the geometry is added to the MTF characteristic is sequentially connected. In addition, a downsampling unit 18 is connected to the rear end of the MTF filter unit 16 for down-sampling to simulate a sample-symbol from the oversampled signal.

Hereinafter, the operation of the conventional asymmetry modeling apparatus will be described with reference to FIGS. 1 and 2.

The RLL modulated signal generator 10 modulates and outputs an NRZI (Non Return to Zero Inverted) signal. The NRZI signal is a signal which inverts the state of the information signal only when the bit of each signal is '1', and the RLL code is a code in which the maximum length of the run is finite. 2ⓐ illustrates the NRZI signal output from the RLL modulated signal generator 10. The oversampling section 12 over-samples the NRZI signal of FIG. 2ⓐ and outputs the oversample signal of FIG. do. The asymmetry addition section 14 increases the interval of the oversampled signal to add an asymmetry to the oversample signal (Fig. 2ⓑ) as shown (Δt × 2), or decreases it by a predetermined length (not shown). By performing the process, the occurrence of asymmetry is considered. As shown in FIG. 2C, the asymmetry is generated in the (+) direction when the predetermined signal section t is increased, and the asymmetry in the (-) direction is generated when the section t is reduced although not shown. The MTF filter unit 16 filters the asymmetry unit of the FIG. 2 © signal to which the asymmetry is added to form a signal of the MTF function, and the downsampling unit 18 processes the oversampling state in order to pseudo-assemise the asymmetry. The sampled signal is downsampled again to generate a sample-symbol to facilitate simulation.

As described above, in the conventional optical disc system, simulation is performed to check the efficiency and accuracy of the system using the asymmetry signal generated by the above-described configuration.

However, in the conventional asymmetry modeling apparatus as described above, the amount of data to be processed is enormous because the asymmetry is added while the RLL-modulated NRZI signal is oversampled. As a result, the processing time is increased by that much, and the number of MTF filters in the MTF filter unit must also be increased by an oversampled multiple.

Accordingly, an object of the present invention is to detect the zero cross (ZC) point of a modulated NRZI signal without adding the NRZI signal to solve the above-mentioned problem, and to add an asymmetry to each sample-symbol. The present invention provides an apparatus for modeling reproduction signal asymmetry of an optical disc system.

1 is a block diagram illustrating a conventional ash geometry modeling apparatus;

2 is a view for explaining a signal output from each component of the conventional asymmetry modeling apparatus shown in FIG.

3 is a block diagram of an ash geometry modeling apparatus according to the present invention,

4 is a view for explaining a signal output from each component of the asymmetry modeling apparatus shown in FIG.

FIG. 5 is a diagram illustrating an RF signal generated by an asymmetry modeling apparatus according to an embodiment of the present invention. FIG.

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

10: RLL modulated signal generator 12: oversampling unit

14: ash metrology section 16: MTF filter section

18: downsampling part

50: RLL modulated signal generator 52: ZC detector

54 weighted ash metrology section 56 MTF filter section

In order to achieve the above object, an apparatus for modeling a reproduction signal of an optical disc system according to the present invention includes a basic signal generator for generating a predetermined basic signal used for modeling an ash component; A zero cross detector for detecting a zero-cross point of the basic signal received from the basic signal generator and outputting a zero cross detection signal; A weighted ash metrology unit for intentionally including an asymmetry component signal in a predetermined section of the zero cross signal received from the zero cross detection unit; And a shaping unit for shaping and outputting a basic signal including an ash metrology component received from the weighted ash metrology unit into a signal for use in simulation of the optical disc system.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 3 is a block diagram illustrating an asymmetry modeling apparatus according to the present invention, and FIG. 4 illustrates signals output from each component of the asymmetry modeling apparatus illustrated in FIG. 3.

As shown in FIG. 3, the asymmetry modeling apparatus according to the present invention includes an RLL modulated signal generator 50 for generating an NRZI signal such as the signal used in the related art of FIG. 1. At the rear end of the RLL modulated signal generator 50, a ZC detector 52 for detecting a zero cross point (hereinafter referred to as 'ZC') of the RLL modulated NRZI signal, and a weighted signal is added to the detected ZC section. As a result, the weighted ash geometry adding portion 54 which intentionally adds the ash geometry is connected, and the MTF filter portion 66 which filters and outputs the ash geometry added signal by weighting the ash geometry to the MTF function is sequentially connected.

3 and 4 will be described in detail the operation of the asymmetry modeling apparatus according to the present invention. In the present embodiment, an asymmetry modeling apparatus in the case of adding the asymmetry in the negative direction will be described.

The RLL modulated signal generation unit 50 modulates and outputs the NRZI signal by RLL modulation as described in the related art (FIG. 1), and the output NRZI signal is as shown in FIG. The ZC detector 52 detects a zero cross point from the NRZI signal output from the RLL modulated signal generator 50, and the zero cross detection is based on the zero point (center point) of a signal (NRZI signal in this embodiment). By detecting the point of change from the (+) to (-) direction or from (-) to (+) direction, this ZC detection is a well-known universal technique. The weighted geometry adding portion 54 outputs a weighted geometry signal (Fig. 4B) in which the weighted signal is intentionally included in a predetermined section z of the ZC detection signal. Thereafter, the MTF filter unit 56 filters the weighted ash geometry signal (FIG. 4), and shapes and outputs the MTF signal. As such, the present invention does not perform oversampling, and thus, there is no need for the oversampling process and the downsampling process according to the prior art.

5 is a diagram illustrating an RF signal generated by an asymmetry modeling apparatus according to an embodiment of the present invention. As shown in the figure, it can be seen that the asymmetry exists in the negative direction by ΔV from the reference level indicated by the dotted line.

As described above, the present invention generates an RF signal with an asymmetry added to each sample signal without performing oversampling, thereby increasing the amount of processing data and signal processing time due to the oversampling of the prior art. By generating the modeling signal to which the geometry is added, there is an effect that can be effectively applied to the simulation of the optical disk system.

Claims (6)

In the signal modeling device for an optical disk system, A basic signal generator for generating a predetermined basic signal used for modeling the asymmetry component; A zero cross detector for detecting a zero-cross point of the basic signal received from the basic signal generator and outputting a zero cross detection signal; A weighted ash metrology unit for intentionally including an asymmetry component signal in a predetermined section of the zero cross signal received from the zero cross detection unit; And, And a shaping unit for shaping and outputting a basic signal including an ash metrology component inputted from the weighted asymmetry unit into a signal for use in simulation of the optical disc system. Modeling device. The method of claim 1, wherein the basic signal is A RUN length limited modulated non-return to zero inverted (NRZI) signal. The method of claim 1 or 2, wherein the shaping unit And a predetermined MTF filter for shaping an NRZI signal including the asymetry component received from the weighted asymmetry unit into a modulation transfer function (MTF). The method of claim 1 or 2, wherein each of the zero cross detection portion and the weighted geometry addition portion A signal processing model for reproducing an optical disc system according to claim 1, wherein the RLL modulation signal generating unit adds an asymmetry by processing a sample-symbol of one cycle among the NRZI signals input from the RLL modulation signal generator. The method of claim 1, wherein the weighted ash geometry portion Reproducing signal ash geometry modeling of an optical disc system, wherein the ash signal is intentionally included in a predetermined section of the zero cross signal inputted from the zero cross detector by weighting a component signal for generating an ash structure. Device. The method of claim 1, wherein the weighted ash geometry portion An apparatus for modeling reproduction signals of an optical disc system, wherein the generation period of the ash structure is increased or decreased by adjusting an ash component component signal that is weighted to a predetermined section of the zero cross signal received from the zero cross detection unit.