KR20040082722A - Track jumping method in optical-disc drive - Google Patents

Abstract

PURPOSE: A track jump method of an optical disk drive is provided to generate an RFZC(RF Zero Cross) signal from a TE(Tracking Error) signal when a track jump occurs to an unrecorded surface from a recorded surface, thereby realizing a stable track jump. CONSTITUTION: A top detector(11) detects a maximum peak value from an inputted TE signal. A bottom detector(13) detects a minimal peak value from the inputted TE signal. An RFZC signal generator(15) generates an RFZC signal by using the detected maximum peak value and the minimal peak value. If a track jump occurs to an unrecorded surface from a recorded surface, the TE signal and an RF signal are detected from a disk. The number of tracks to jump is calculated on the basis of a TZC(Tracking Zero Cross) signal. A direction of the track jump is determined on the basis of the generated RFZC signal by detecting the maximum/minimal peak values. A pickup is moved in the determined direction according to the calculated number of the tracks.

Description

Track jumping method in optical-disc drive

The present invention relates to a track jump method of an optical disc drive, and more particularly, to a track jump method in which a track jump can be stably implemented by generating a reference signal for determining a track direction in an optical disc drive from a tracking error signal.

In general, a CD-R / RW drive requires a control, or seek operation, to precisely move the pickup laser beam to a desired target position on the disc for playback or recording.

In this case, the laser beam must be forcibly jumped off the pickup from the current track on the disc to another target track on the outside or inside. As such, the most important information used in the case of track jumping is the direction of the track jump and the number of tracks to be track jumped.

In this case, the number of tracks that have been track jumped in general is calculated from a tracking zero cross (TZC) signal (hereinafter referred to as a TZC signal) obtained by converting a tracking error (TE) signal (hereinafter referred to as a TE signal) into pulses, and track jump. The direction of is obtained from an RF zero cross (RFZC) signal (hereinafter referred to as an RFZC signal) obtained by converting an RF signal reproduced from a disk into a pulse.

1 is a view showing various signals for a normal track jump in a conventional optical disk drive. Here, FIG. 1 is a diagram showing a case where a track jump occurs in the recording surface or in the unrecorded surface, and the TZC signal and the RFZC signal are normally calculated from the TE signal and the RF signal generated normally.

When a track jump occurs in the recording area or in the unrecorded area, the TE signal and the RF signal are normally detected as shown in FIG. Therefore, the TZC signal and the RFZC signal generated using the TE signal and the RF signal which are normally detected by using a preset slice level also appear normally. Here, the slice level means a threshold value for converting an envelope of the TE signal and the RF signal into a pulse waveform. The threshold is automatically set to a middle value between the maximum and minimum values of the TE and RF signals, respectively.

The TZC signal and the RFZC signal are converted to a high value when they are higher than the slice level and converted to a low value when the slice level is higher than the slice level, so that a pulse waveform as shown in FIG. 1 appears.

From the TZC and RFZC signals generated as described above, the number of tracks to track jump and the direction of track jump are determined. For example, since one track is usually used for one sine waveform, the number of tracks to be track jumped in the TZC signal as shown in FIG. 1 is six. In addition, in FIG. 1, the signal of the RFZC signal has a low value at the edge where the TZC signal becomes high, that is, the rising edge, from which the track direction to be track jumped is reverse track jump ( inverse track jump), that is, inward direction of the disc.

On the contrary, if the RFZC signal has a high value at the rising edge of the TZC signal, the track direction to be track jumped may be determined as the outer direction of the disc.

As such, the number of track jumps and the track jump direction are determined using the TZC signal and the RFZC signal, which are pulse signals generated from the TE signal and the RF signal detected from the disk, and the track jump is performed using the determined parameters. You can.

In addition, even when a track jump occurs from the unrecorded surface to the recording surface, similarly to FIG. 1, a TZC signal and an RFZC signal are calculated, thereby enabling stable track jump. That is, in general, in the case of track jump from the unrecorded surface to the recording surface, there is no pit on the unrecorded surface, so that the level of the RF signal detected therefrom is very small. In view of this, the track jump is performed with the gain value of the RF signal set very high. In this case, even if the pickup enters the recording surface, since the gain value of the RF signal is already set high, the level of the RF signal does not change, and stable track jump can be achieved.

However, when a track jump occurs from the recording surface of a couple having a pit to an unrecorded surface, which is a portion without a pit, a stable track jump cannot be implemented, which will be described below with reference to FIG. 2.

2 is a view showing various signals for unstable track jump in the conventional optical disk drive. As shown in FIG. 2, when a track jump occurs from the recording surface to the unrecorded surface, the gain value of the RF signal and the TX signal is set to small by AGC (Auto Gain Control), and thus the RF signal and the TX enter the unrecorded surface. The level change of the signal becomes small. In general, the difference between the unrecorded surface and the recording surface is determined by the presence or absence of pits. That is, since the average amount of reflection on the portion without the pit, that is, the unrecorded surface, is larger than the average amount of reflection on the portion with the pit, that is, the recording surface, the envelope of the RF signal is located at a DC level. As a result, the RF signal on the recording surface appears as a level change amount smaller than the level change amount of the RF signal on the recording surface at a position higher than the slice level.

In this case, no pulse is generated in the RFZC signal generated from the RF signal on the unrecorded surface. This is because, as shown in FIG. 2, the RF signal appears at a position higher than the slice level, so that there is no RF waveform larger than the slice level, so that no more pulses are formed. Accordingly, as the RF signal is not generated in the unrecorded surface as described above, the direction in which the track jump is determined is not determined, and thus a situation in which the pickup is not operated may occur.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a track jump method of an optical disk drive that can realize a stable track jump by generating an RFZC signal from a TE signal when a track jump occurs from a recording surface to an unrecorded surface. Has its purpose.

1 is a view showing various signals for a normal track jump in a conventional optical disk drive.

2 is a view showing various signals for unstable track jump in a conventional optical disk drive.

3 illustrates various signals for implementing stable track jump in an optical disk drive according to an embodiment of the present invention.

4 is a view showing an RFZC signal generating apparatus in an optical disk drive according to an embodiment of the present invention.

<Name of the code for the main part of the drawing>

11 top detector 13 bottom detector

13: RFZC signal generator

According to a preferred embodiment of the present invention for achieving the above object, in the track jump method of the optical disk drive, detecting a TE signal and an RF signal from the disk when a track jump occurs from the recording surface to the unrecorded surface in the disk; ; Calculating the number of tracks to track jump based on the TZC signal generated using the slice level from the TE signal; Detecting a maximum peak value and a minimum peak value from the TE signal and determining a direction to track jump based on the RFZC signal generated therefrom; And moving the pickup according to the calculated track number to track jump and the determined track jump direction. Here, the RFZC signal is generated by sequentially combining the maximum and minimum peak values alternately.

According to another preferred embodiment of the present invention, a track jump method of an optical disk drive includes detecting a TE signal and an RF signal from a disk when a track jump occurs from the recording surface to the unrecorded surface in the disk; Calculating the number of tracks to track jump based on the TZC signal generated using the slice level from the TE signal; Generating an RFZC signal differently according to the recording surface and the unrecorded surface section; Synthesizing the otherwise generated RFZC signal to generate a final RFZC signal and determining a direction from which to track jump; And moving the pickup according to the calculated track number to track jump and the determined track jump direction.

According to the track jump method of the optical disk drive, a recording surface RFZC signal is generated using the slice level from the RF signal in the recording surface section, and unrecorded using the maximum and minimum peak values detected from the TE signal in the unrecorded surface section. RFZC signal is generated.

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

Prior to describing the present invention, a conventional track jump method will be described.

In general, conventional track jump methods include detecting a TE signal and an RF signal from a disk; Calculating the number of tracks to track jump based on the TZC signal generated using the slice level from the TE signal; Determining a direction to track jump based on an RFZC signal generated using a slice level from the RF signal; And moving the pickup according to the calculated track number to track jump and the determined track jump direction.

On the contrary, the present invention has been proposed to solve a problem in that when a track jump occurs from the recording surface to the unrecorded surface, the RFZC signal is not generated at the unrecorded surface and thus the pickup cannot be moved because the direction to track jump is not determined. .

Accordingly, the track jump method according to the present invention includes detecting a TE signal and an RF signal from the disc when a track jump occurs from the recording surface to the unrecorded surface in the disk; Calculating the number of tracks to track jump based on the TZC signal generated using the slice level from the TE signal; Detecting maximum and minimum peak values from the TE signal; Generating an RFZC signal using the detected maximum and minimum peak values; Determining a direction to track jump from the RFZC signal; And moving the pickup according to the calculated track jump number and the determined track jump direction.

As the track jump is performed in this way, the RFZC signal is generated even in the unrecorded area to determine the direction in which the track jump is to be performed, whereby the pickup can be stably tracked.

As described above, when a track jump occurs from the recording surface to the unrecorded surface, the amount of change in the level of the RF signal is small on the unrecorded surface, so that the RFZC signal cannot be generated using the slice level.

However, the present invention can simply generate the RFZC signal from the TE signal with the device as shown in FIG.

4 is a diagram illustrating an RFZC signal generating apparatus in an optical disk drive according to an embodiment of the present invention.

Referring to FIG. 4, the RFZC signal generator includes a top detector 11 for detecting a maximum peak value from an input TE signal, a bottom detector 13 for detecting a minimum peak value from the input TE signal, And an RFZC signal generator 15 for generating an RFZC signal using the maximum and minimum peak values detected by the top detector 11 and the bottom detector 13.

An operation of the RFZC signal generation device configured as described above will be described with reference to FIG. 3.

As shown in Fig. 3, a TE signal and an RF signal are detected from an optical disk having a recording surface and an unrecorded surface. At this time, the amount of change in the level of the TE signal and the RF signal is large on the recording surface in which the pit is present, whereas the amount of change in the level of the TE signal and the RF signal is small on the non-recording surface without the pit.

In particular, the level of the RF signal detected on the unrecorded surface appears to be DC higher than the level of the RF signal detected on the recording surface. Accordingly, the level of the RF signal detected on the unrecorded surface is higher than the slice level preset as the intermediate value between the maximum value and the minimum value of the RF signal, so that the RFZC signal is not generated by the RF signal on the unrecorded surface.

In this way, when the track jump is generated from the recording surface to the unrecording surface, the RFZC signal can be generated using the TE signal detected from the disk.

Looking at the track jump operation, when a track jump occurs from the recording surface to the unrecorded surface, first, the TE signal and the RF signal are detected from the disk. At this time, the TE signal is simultaneously input to the top detector 11 and the bottom detector 13, respectively. The top detector sequentially detects maximum peak values from the TE signal. The bottom detector 13 sequentially detects maximum peak values from the TE signal. As such, both the detected maximum peak values and minimum peak values are input to the RFZC signal generator 15.

The RFZC signal generator 15 generates an RFZC signal composed of pulses using the maximum and minimum peak values input from the top detector 11 and the bottom detector 13. That is, a low pulse is generated in the section from the maximum peak value to the minimum peak value, and conversely, a section from the minimum peak value to the maximum peak value is generated as the high pulse.

In this case, the maximum peak values and the minimum peak values are alternately input to the RFZC signal generator 15 sequentially. The RFZC signal is generated by combining the maximum and minimum peak values in the input order. Then, the RFZC signal receives the maximum peak values and the minimum peak values sequentially from the top detector 11 and the bottom detector 13, and generates an RFZC signal by combining the maximum peak values and the minimum peak values. .

For example, if the peak value initially input to the RFZC signal generator 15 is the maximum peak value, then the minimum peak value, the maximum peak value, and the minimum peak value are input in this order. Accordingly, the RFZC signal generator 15 generates a low pulse by a combination of the first maximum peak value and the next minimum peak value, and the high pulse is generated by the combination of the previous minimum peak value and the next maximum peak value. Can be generated. In this order, pulses for the RFZC signal are sequentially generated.

As described above, when the RFZC signal is generated from the TE signal, the number of tracks to track jump and the direction to track jump are determined from the TZC signal and the RFZC signal generated in advance, and thus the pickup may be moved to the target track.

On the other hand, while the above has described the method for generating the RFZC signal from the TE signal regardless of the recording surface and the unrecorded surface, the RFZC signal on the recording surface is generated using the RF signal according to the conventional method, and RFZC on the unrecorded surface. The signal may be generated using the TE signal as in the present invention.

When the track jump is operated by this method, information on the boundary between the recording surface and the unrecorded surface is required, but the information can be easily known from the information recorded in the PMA (Programmable Memory Area) area of the disc. .

In this case, a method of track jumping is first described. First, the boundary between the recording surface and the unrecorded surface is identified through the PMA of the disc. Then, as described above, the TE signal and the RF signal are detected from the disk.

The number of tracks to track jump is calculated based on the TZC signal generated using the slice level from the TE signal.

Subsequently, in the region from the recording surface to the identified boundary surface, a recording surface RFZC signal is generated using the slice level from the RF signal.

On the other hand, in the region from the boundary surface to the unrecorded surface, an unrecorded surface RFZC signal is generated using the maximum and minimum peak values of the TE signal.

The recording surface RFZC signal and the unrecorded surface RFZC signal generated as described above are synthesized to generate a final RFZC signal to determine a direction to track jump.

Then, the pickup is moved according to the number of tracks to be track jumped and the track jump direction.

As described above, according to the track jump method of the optical disc drive according to the present invention, when a track jump occurs from a recording surface to an unrecorded surface, a stable track jump can be realized by generating an RFZC signal from a TE signal.

Meanwhile, a stable track jump can be realized by generating an RFZC signal using an RF signal in a recording surface section and an RFZC signal using a TE signal in an unrecorded section, based on an interface between a recording surface and an unrecorded surface.

Claims (6)

Detecting a TE signal and an RF signal from the disk when a track jump occurs from the recording surface to the unrecorded surface in the disk; Calculating the number of tracks to track jump based on the TZC signal generated using the slice level from the TE signal; Detecting a maximum peak value and a minimum peak value from the TE signal and determining a direction to track jump based on the RFZC signal generated therefrom; And Moving the pickup according to the calculated track number to track jump and the determined track jump direction; The track jump method of the optical disk drive comprising a. The track jump method of claim 1, wherein the RFZC signal is generated by sequentially combining the maximum and minimum peak values alternately. Detecting a TE signal and an RF signal from the disk when a track jump occurs from the recording surface to the unrecorded surface in the disk; Calculating the number of tracks to track jump based on the TZC signal generated using the slice level from the TE signal; Generating an RFZC signal differently according to the recording surface and the unrecorded surface section; Synthesizing the otherwise generated RFZC signal to generate a final RFZC signal and determining a direction from which to track jump; And Moving the pickup according to the calculated track number to track jump and the determined track jump direction; The track jump method of the optical disk drive comprising a. 4. The track jump method of claim 3, wherein a recording surface RFZC signal is generated using the slice level from the RF signal in the recording surface section. 4. The track jump method of claim 3, wherein an unrecorded surface RFZC signal is generated using the maximum and minimum peak values detected from the TE signal in the unrecorded surface section. 6. The track jump method of claim 5, wherein the recording surface RFZC signal is generated by sequentially combining the maximum peak values and the minimum peak values alternately.