KR20050099863A - Optimum power controlling method for optical recorder - Google Patents

Abstract

A method of setting an optimal recording power of an optical recording medium according to the present invention includes reading a gamma target value recorded on an optical recording medium, and dividing a test area of the optical recording medium into n (n ≧ 2) divided areas. Recording test data at an optimum double speed while changing recording power to a predetermined step for m (0 <m <n) divided areas among the n divided areas; and (nm) divided areas Recording the test data at a lower speed than the optimum double speed while changing the recording power to a predetermined step, and performing test data reproduction on the n divided areas to calculate gamma values for each recording power; Extracting a gamma value close to a gamma target value from among gamma values, and acquiring a recording power corresponding to the extracted gamma values. setting an average value of the recording powers corresponding to the m divisions to an optimum recording power according to the optimum double speed, and setting an average value of the recording powers corresponding to the (nm) divisions to an optimum recording power suitable for low double speed. do.

As described above, the present invention can improve the accuracy of the optimum recording power at the optimum double speed and the low double speed by setting the optimum recording power according to the low speed and the optimum double speed.

Description

Optimal power setting method of optical record player {OPTIMUM POWER CONTROLLING METHOD FOR OPTICAL RECORDER}

The present invention relates to a method for setting an optimum recording power of an optical recorder, and more particularly, to a method for setting an optimum recording power in consideration of a double speed when setting an optimum recording power.

In general, an optical recording medium is a read-only disc such as a CD-ROM (CD-Read Only Memory), a DVD-ROM or the like, and a CD-WORM (CD-Write Once Read Many) or the like, depending on whether recording is possible. Discs can be classified as recordable discs and discs capable of repeatable recording such as CD-Rewritable (CD-RW) and DVD-Random Access Memory (DVD-RAM).

On the other hand, the recording area arrangement of the recordable discs includes a power calibration area (PCA), a program memory area (PMA), a lead-in area, a program area, and a lead-out area. Separated by. Here, the PCA is an area for calibrating the laser recording power for recording data on the disk, and the PMA has head address information of the track on which data is recorded in the program area. Further, data recording information and the like stored in the program area are recorded in the lead-in area and the lead-out area, and actual data to be recorded on the disc is recorded in the program area.

An optical recording / reproducing apparatus for recording and reproducing information on such an optical recording medium drives a laser diode to irradiate a relatively large energy light beam that can change the physical characteristics of the information recording layer existing on the optical disk, thereby providing information to the optical disk. The information is reproduced from the optical disc by using a light beam of small energy that does not change the physical characteristics of the information recording layer.

Before storing the information on the optical recording medium, the optical recording player performs an optimal power setting, that is, an OPC (Optimum Power Control) process for setting a recording power suitable for the inserted disc.

Hereinafter, the process of controlling the recording power in the conventional optical recorder will be described with reference to FIG. 1. 1 is a flowchart showing a recording power control process of a conventional optical recording and reproducing apparatus.

Referring to FIG. 1, first, an optimal recording power display value recorded on a disc, that is, a gamma target value, is read for each disc manufacturer according to insertion of a rewritable disc (S1).

Then, the PCA counter area of the rewritable disc is inspected to determine a position to perform the PC and move to the PCA test area, and the data recorded in the test area is deleted (S2).

Then, the reference recording power and the power conversion step are determined using the read optimal recording power display value (S3).

Here, the reference recording power uses the optimal recording power display value recorded on the disc at 1x speed, and records data on the disc at different reference recording powers according to the double speed.

Then, the test data is recorded at an optimal double speed provided by the disk in one of the test areas, that is, the test area (hereinafter, referred to as the recording area) (S4). At this time, the laser recording power used in the actual recording is increased every ADIP (Address In Pregroove). That is, the laser recording power is output in increments of the power conversion step in steps for a total of 21 AI's.

Thereafter, the test data recorded in the recording area is reproduced, and the signals RF reflected from the pits formed on the disc by the laser recording pulses are respectively selected for 21 a dips, i. After sampling and digitizing, a gamma value corresponding to each A-Dip is calculated for the recording area (S5 and S6).

In step S6, a gamma value similar to the gamma target value is extracted by comparing the gamma values corresponding to each A-DIP with the gamma target value recorded on the disk, and the recording power corresponding to the extracted gamma value is set as an optimal recording power ( S7, S8).

The optical record player records the information on the disc at the optimal recording power and optimal speed set in this way, and if the recording speed needs to be reduced before events such as buffer under run and server error during recording, Calculate the optimal recording power. That is, the optical record player calculates an optimum recording power corresponding to the reduced recording speed when a buffer underrun or a server error occurs, and then records information on the disc at the calculated optimum recording power and the reduced recording speed.

However, according to the conventional method for setting the optimum recording power as described above, there is a limit in finding a stable optimal recording power for recording since the OPC is performed at an optimum double speed in any one of the test regions.

In addition, the conventional optical recording and reproducing apparatus has a problem in that its accuracy is lowered because the optimum recording power is obtained through simple calculation when the recording speed needs to be reduced before a situation such as servo error and buffer underrun.

SUMMARY OF THE INVENTION An object of the present invention is to solve such a problem of the prior art, and performs an optimal power setting at an optimum double speed for any of a plurality of divided areas of a test area, and reduces the optimal power speed for other divided areas. By setting the optimum power at the low speed and the optimum speed by setting the optimum power at the high speed, it provides the optimal power setting method of the optical recorder that can improve the accuracy of the optimal recording power at the optimum speed and the low speed. I will.

In order to achieve the above object, the present invention provides a method for setting an optimal recording power of an optical recording medium, the method comprising: reading a gamma target value recorded on the optical recording medium; dividing the data into (n≥2) partitions and recording the test data at an optimum double speed while changing the recording power to a predetermined step for m (0 <m <n) of the n partitions. Recording test data at a lower speed than the optimum double speed while changing recording power for the (nm) divided areas, and performing test data reproduction for the n divided areas. Calculating gamma values for each of the recording powers, and for each of the divided regions, a gamma value close to a gamma target value among the gamma values, respectively. Acquiring the recording power corresponding to the extracted gamma values, setting an average value of the recording powers corresponding to m divided regions among the recording powers as an optimal recording power according to an optimum double speed, and (nm) And setting an average value of the recording powers corresponding to the divided regions to an optimal recording power suitable for low speed.

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

2 is a block diagram showing an optical record player for explaining a process of setting an optimum recording power according to the present invention.

As shown in FIG. 2, the optical recorder includes a recording pulse generator 203 for generating an actual recording pulse by including auxiliary information from the microcomputer 205 in recording information transmitted from a host (not shown). The laser diode driver 204 for driving the laser diode included in the optical pickup unit 202 according to the recording pulse generated by the recording pulse generator 203 and the laser power step set by the microcomputer 205, and the disk 201. Amplified by the optical pick-up unit 202 for detecting the optical signal reflected from the optical waveguide), the RF signal amplifying unit 206 for amplifying the RF signal detected by the optical pick-up unit 202, and the RF signal amplifying unit 206. And a signal processor 207 for reproducing the RF signal.

Here, the disc 201 used in the present invention is a rewritable optical recording medium such as DVD-RW (+ RW).

3 is a flowchart illustrating a process of setting an optimum recording power by an optical recording player according to an exemplary embodiment of the present invention.

As shown in FIG. 3, the control unit 205 first reads the disc information recorded on the disc 201, that is, the gamma target value, upon insertion of the disc 201 (S300).

Then, the PCA counter area of the rewritable disc is checked to determine the position to perform the PC, and the PC area is moved to the test area. After deleting the data recorded in the test area, the test area is n (n≥2). ) Into two divided regions (S302 and S304).

After deleting the data recorded in the test area, the microcomputer 205 determines the reference recording power and the power conversion step by using the optimum recording power display value read from the disc 201. Here, the reference recording power uses the optimal recording power display value recorded on the disc at 1x speed, and data is recorded in the divided area of the test area at different reference recording powers according to the double speed.

Then, the microcomputer 205 selects m (0 <m <n) partitions from among the n partitions, that is, the optimum OPC, and records the test data in the selected m partitions. 202 is moved to any one of the m divided areas. Then, the microcomputer 205 records the test data at the optimum double speed provided by the disk 201 in m divided areas using the optical pickup unit 202 (S306). At this time, the microcomputer 205 controls the laser diode driver 204 to record the test data in m divided regions while changing the laser recording power according to the set power step. That is, when recording test data in the partitioned area, the laser recording power is increased and outputted every A-DIP, and the test data is recorded in the first partitioned area according to the power step in the first partitioned area of the m partitioned areas. Record the test data in the area. These m divided areas are areas for setting the optimum recording power according to the optimum double speed.

After recording the test data for setting the optimum recording power according to the optimum double speed in the m divided areas, the microcomputer 205 records the test data in the (n-m) divided areas at a lower speed than the optimum double speed (S308). The process of recording test data in the (n-m) partitions is the same as recording the test data in the m partitions, but the test data is recorded in the (n-m) partitions only at a recording speed lower than the optimum speed.

Thereafter, the microcomputer 205 controls the optical pickup unit 202 to reproduce the test data recorded in the n divided regions, respectively.

Through this reproducing process, the microcomputer 205 receives a signal reflected from the pit formed on the disc 201 by the laser recording pulse through the RF signal amplifying unit 206 during each A-DIP, so that the specific section of the signal, In other words, the maximum value, the minimum value and the intermediate value are sampled and digitized, and then a gamma value for each power is calculated for any one of the n divided areas (S312). That is, the microcomputer 205 repeats this process n times to calculate a gamma value for each power for every n partitions.

Then, in order to set the optimal recording power according to the optimum double speed, the microcomputer 205 extracts a gamma value close to the target gamma value among the gamma values extracted from the first partition of m partitions, and then repeats this process m times. In order to extract gamma values approximating m target gamma values, and extracting gamma values approximating target gamma values among gamma values extracted from the first partition of (nm) partitions in order to set an optimal recording power according to the low speed. Repeated (nm) times to extract a gamma value approximating the (nm) target gamma values (S314).

After that, the microcomputer 205 obtains m recording powers corresponding to m gamma values, and then calculates an average value for the n recording powers, and sets the average value as the optimal recording power according to the optimum double speed. In the same storage space. In addition, the microcomputer 205 obtains (nm) recording powers corresponding to (nm) gamma values, and then calculates an average value for the (nm) recording powers, and calculates the average recording power according to the low speed. In this case, it is stored in the same storage space as the memory (S316).

After performing the optimal recording power setting process as described above, the microcomputer 205 controls the laser diode driver 204 so that the laser diode in the optical pickup unit 202 outputs the optimal recording power according to the optimum double speed. Is recorded on the disc 201 at an optimum double speed (S318).

While recording the information as described above, the microcomputer 205 determines whether the buffer amount falls below a predetermined amount or the servo error exceeds a preset number of times, that is, whether the speed needs to be lowered at the optimum speed (S320).

As a result of the determination in step S320, when it is not necessary to decrease the speed, the microcomputer 205 proceeds to step S318 to continue recording information at the optimum speed, and when it is necessary to decrease the speed, the recording speed is reduced and the optical pickup unit ( The laser diode driver 204 is controlled so that the laser diode in 202 outputs the optimum recording power at low speed, and information is recorded on the disk 201 at low speed (S322).

In the foregoing description of the present invention, only one embodiment has been described, but it is obvious that the technology of the present invention can be easily modified by those skilled in the art. Such modified embodiments should be included in the technical spirit described in the claims of the present invention.

As described above, the present invention performs optimal power setting at an optimum double speed for any of the plurality of divided areas of the test area, and sets optimum power at a reduced double speed than the optimum double speed for other divided areas. By setting the optimum recording power according to the low speed and the optimum double speed, the accuracy of the optimum recording power at the optimum double speed and the low double speed can be improved.

1 is a flowchart illustrating a recording power control process of a conventional optical recording / reproducing apparatus;

2 is a block diagram showing an optical record player for explaining a process of setting an optimum recording power according to the present invention;

3 is a flowchart illustrating a process of setting an optimum recording power by an optical recording player according to an exemplary embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

201: disc 202: optical pickup

203: Recording pulse generating unit 204: Laser diode driving unit

205: microcomputer 206: RF signal amplifier

207: signal processing unit

Claims (2)

A method of setting an optimal recording power of an optical record carrier, Reading a gamma target value recorded on the optical record carrier; Dividing a test area of the optical record carrier into n (n ≧ 2) divided areas; Recording test data at an optimum double speed while changing recording power to a predetermined step for m (0 <m <n) divided areas among the n divided areas; Recording test data at a lower speed than the optimum double speed while changing recording power to a predetermined step for the (n-m) divided regions, respectively; Calculating gamma values for each of the recording powers by performing test data reproduction on the n divided regions; Extracting a gamma value close to a gamma target value among the gamma values for each of the divided regions, and obtaining a recording power corresponding to the extracted gamma values; An optimum recording power of the recording powers corresponding to the m divisions among the recording powers is set to an optimum recording power according to the optimum double speed, and an average of the recording powers corresponding to the (nm) divisions is suitable for the low speed. To set to Optimal power setting method of the optical record player comprising a. The method of claim 1, While recording the information at the optimal recording power according to the optimum double speed on the optical recording medium, if the amount of buffer falls below a preset value or if a servo error occurs a predetermined number of times, the optical recording information is recorded at the optimum recording power corresponding to the low double speed. An optimal power setting method for an optical recorder, characterized by recording on a medium.