KR20040078387A - Apparatus for writing in optical disc and method thereof - Google Patents

Abstract

PURPOSE: An optical disk recording device is provided to vary the power level of a multi-pulse by using a power varying apparatus, thereby preventing a programmable delay element from being complex and improving recording precision. CONSTITUTION: An EFM(Eight-to-Fourteen Modulation) encoder(3) modulates the recording information supplied from a microcomputer(1) to generate an NRZI(Non Return to Zero Inverted) signal. An NRZI pattern analyzer(5) calculates a recording mark length and space lengths before and after a recording mark from the NRZI signal supplied from the EFM encoder(3), combines the mark length with space lengths, and then supplies the combined results. A write strategy RAM(Random Access Memory)(21) has time delay values and recording power values set previously for generating a multi-pulse, and supplies time delay values and recording power values corresponding to the results supplied from the NRZI pattern analyzer(5). A programmable delay element(23) delays the NRZI signal according to the time delay values to generate the multi-pulse. A power varying apparatus(25) performs a DAC(Digital to Analog Conversion) process for the recording power values. An LD(Laser Diode) driver(27) supplies an LD driving signal obtained by varying the power of the multi-pulse supplied from the programmable delay element by using the recording power values supplied form the power varying apparatus(25). A pickup(15) irradiates light on a disk(17) according to the LD driving signal.

Description

Apparatus for writing in optical disc and method

TECHNICAL FIELD The present invention relates to an optical disc recording apparatus, and more particularly, to an optical disc recording apparatus and a recording method capable of forming a more accurate mark in high speed recording in consideration of a recording power level as well as a time delay.

In general, in the case of a rewritable disc, the recording material is usually formed of a phase change material. In such a phase change disc, an optically discernible mark is formed by heat generated by irradiating light onto the disc forming the recording layer. That is, in the phase change disk, the heating temperature and the cooling rate are controlled to reversibly change between the crystalline structure and the amorphous structure, so that information is recorded and erased.

In a phase change disk, the recording and erasing of information is related to the intensity of the laser beam being irradiated. For example, when a high power laser beam is irradiated to the recording layer, the recording layer is locally melted and then quenched, the recording portion is formed while the irradiated portion is amorphous. Further, when a laser beam having an output of about 30 to 50% of power is irradiated to the recording mark thus formed, the recorded information is erased while the recording mark portion is crystallized.

On the other hand, when applying a pulse width modulation (PWM) method to a phase change disk, when the recording mark is formed by using a single pulse, the width of the recording mark increases toward the rear end of the recording mark due to the thermal accumulation effect accompanying the irradiation of light. There was a problem that the recording and reproduction characteristics were deteriorated. Therefore, in recent years, by forming a recording mark using a plurality of divided optical pulses, i.e., multi-pulse, a method capable of preventing the degradation of recording characteristics caused by a single single pulse has been generally used.

However, even when recording using the multi-pulse as described above, the start edge and the end edge of the mark actually formed are shifted at a predetermined position according to the length of the recording mark and the space length before and after the recording mark. There was a tendency to deteriorate the characteristics.

A method for preventing the recording mark length from being changed by the length of the recording mark and the space length before and after the recording mark and improving the accuracy of the recording mark has been proposed. That is, the method of performing recording in the state which shifted the position of head and tail in advance according to the length of a recording mark and the space length before and behind a recording mark is this.

A method of generating a pre-shifted write pulse using the preset time delay value as described above is called a write strategy. By using the pre-shifted recording pulse generated in this way, the accuracy of the recording mark is improved and the jitter characteristic is improved.

Fig. 1 shows the structure of an optical disc recording apparatus using a conventional light stratification.

Referring to FIG. 1, a conventional optical disc recording apparatus provides an information to be recorded, a microcomputer 1 for controlling the entire system, and an EFM encoder for generating an NRZI signal by modulating the recording information provided from the microcomputer 1. (3), an NRZI pattern analyzer (5) which provides a result calculated by calculating an NRZI signal provided from the EFM encoder (3), and a light storage RAM storing time delay values for generating a multi-pulse ( 7) a programmable delay element 9 for generating a multi-pulse by delaying the NRZI signal provided from the EFM encoder 3 according to the time delay value provided from the write strategy RAM 7, and the programmable delay element ( LD driver 13 for providing a laser diode driving signal in accordance with the multi-pulse provided from 9), and light is emitted from the laser diode according to the driving signal. It consists of a pick-up (15) for irradiating (17).

Here, the NRZI pattern analyzer 5 calculates the lengths of the recording marks and the spaces before and after the recording marks from the NRZI signals provided from the EFM encoder 3, and compares the result of the combination of the recording marks with the spaces before and after the recording marks. It is provided by the RAM 7. In the write storage RAM 7, time delay values corresponding to the combination result of the recording mark and the space before and after the recording mark are set in advance. Therefore, time delay values corresponding to the combination result of the recording mark calculated from the NRZI signal and the space before and after the recording mark are provided to the programmable delay element 9. The programmable delay element 9 generates a multi-pulse using the time delay value provided from the write strategy ram 7 from the NRZI signal provided from the EFM encoder 3. As shown in Fig. 2, the width of each pulse is determined in accordance with the time delay values T1, T2, T3 and T4 provided from the write strategy RAM 7. Accordingly, the start edge of the first pulse is delayed by T1 and the end edge of the first pulse is delayed by T2. In addition, the end edge of the intermediate pulse is delayed by T3, and the end edge of the last pulse is delayed by T4. In this manner, one recording mark section is long and several pulses are generated according to the length of the mark.

As described above, in the conventional optical recording apparatus, the multi-pulse is generated by using the time delay values stored in the write storage RAM 7.

By recording information on the disc using a pre-shifted multi-pulse generated according to the conventional optical recording apparatus configured as described above, recording accuracy can be improved.

However, in the conventional optical recording apparatus as described above, the programmable delay device for generating the multi-pulse has a problem that the circuit is complicated. In particular, when high recording speed is required, the precision requires hundreds of picoseconds of control, and correspondingly, the programmable delay device requires a more complicated circuit design. As a result, the cost is additionally increased and the apparatus is enlarged. That is, as the recording speed increases, the shifts for the start and end edges of the multi-pulse are controlled in 1 / 32T units, and the recording precision requires hundreds of ps to control in such shift units. To meet this need, programmable delay devices are designed to be more complex.

In addition, the programmable delay device has a large size in the case of IC, making it difficult to embed in the IC.

Accordingly, an object of the present invention is to provide an optical disk recording apparatus and method capable of improving recording accuracy at high speed by providing a power variable that varies recording power.

Another object of the present invention is to provide an optical disc recording apparatus and method which can prevent the cost increase and the increase in the size of the programmable delay element by varying the recording power, thereby reducing the burden on the programmable delay element.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing the configuration of an optical disk recording apparatus using a conventional light stratification.

2 shows a recording pulse according to FIG. 1;

Fig. 3 is a diagram showing the configuration of an optical disc recording apparatus using light stratification according to an embodiment of the present invention.

4 shows a recording pulse according to FIG. 3;

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

1: Microcomputer 3: EFM encoder

5: NRZI pattern analyzer 13: LD driver

15: pickup 17: disc

21: Light strateg RAM 23: Programmable delay element

25: power variable

According to a preferred embodiment of the present invention for achieving the above object, an optical disk recording apparatus includes an EFM encoder for generating an NRZI signal by modulating the recording information provided from the microcomputer; An NRZI pattern analyzer for calculating a NRZI signal provided from the EFM encoder and providing a calculated result; A write strategy RAM providing time delay values and write power values for generating a multi-pulse; A programmable delay element for delaying the NRZI signal provided from the EFM encoder according to the time delay values provided from the write strategy RAM to generate a multi-pulse; A power converter for DAC converting write power values provided from said write strategy RAM; An LD driver for providing a laser diode driving signal in which the power of the multi-pulse provided from the programmable delay element is varied by using the write power values provided from the power variable; And a pickup for irradiating the disk with light from the laser diode in accordance with a laser diode driving signal provided from the LD driver.

Here, the result calculated from the NRZI pattern analyzer is a combination of the recording mark length and the space length before and after the recording mark.

The write power values determine the power level of each pulse of the multi-pulse.

The programmable delay device is designed to control shift modulation of the multi-pulse in units of T / 8.

The recording power values are determined according to a combination of the recording mark length provided from the NRZI pattern analyzer and the space length before and after the recording mark.

According to another preferred embodiment of the present invention, an optical disc recording method comprises the steps of: calculating a combination of a record mark length and a space length before and after a recording mark from an NRZI signal modulated from information to be recorded; Generating a shifted multi-pulse of the NRZI signal using time delay values corresponding to the combination; Varying the power level of each pulse using the generated multi-pulse using write power values corresponding to the combination; And writing to the disc according to the variable multi-pulse.

The time delay values and the write power values are preset.

The power level of the first pulse of the multi-pulse may be greater or less than the recording power level.

The power level of the last pulse of the multi-pulse may be greater or less than the cooling power level.

3 shows a configuration of an optical disc recording apparatus using a write stratification according to an embodiment of the present invention.

Referring to FIG. 3, an optical disc recording apparatus according to the present invention provides an information to be recorded, an EFM for controlling the overall system, and an EFM for modulating recording information provided from the micom 1 to generate an NRZI signal. An encoder (3), an NRZI pattern analyzer (5) for calculating the NRZI signal provided from the EFM encoder (3) and providing the calculated result, and time delay values and recording power values for generating a multi-pulse. Programmable delay line for generating a multi-pulse by delaying the NRZI signal provided from the write strategy RAM 21 and the EFM encoder 3 according to the time delay values provided from the write strategy RAM 21. (23), and a power variabler (25) for converting the digital power from the write strategy RAM 21 to digital to analog converting (DAC), and An LD driver 27 for providing a laser diode driving signal in which the power level of each pulse is varied by using the multi-pulse provided from the grammar delay element 23 using the write power values provided from the power variable 25; It consists of a pickup 15 for irradiating the disk 17 with light from the laser diode in accordance with a laser diode driving signal provided from the driver 27.

Here, the NRZI pattern analyzer 5 calculates the length of the recording mark and the space before and after the recording mark from the NRZI signal provided from the EFM encoder 3, and compares the result of the combination of the recording mark and the space before and after the recording mark. It is provided to the RAM 21.

In the write strategy RAM 21, time delay values and recording power values corresponding to the combination result of the recording mark and the space before and after the recording mark are set in advance. That is, the time delay values are determined according to the combination of the recording mark and the space length before and after the recording mark. The recording power values are also determined in accordance with the combination of the recording mark and the space length before and after the recording mark, similarly to the time delay values. That is, as shown in Fig. 4, P1 and P2 are determined in accordance with the combination of the length of the recording mark and the space length before the recording mark, and P3 and P4 are determined in accordance with the combination of the length of the recording mark and the length after the recording mark.

The programmable delay element 23 generates a multi-pulse consisting of several pulses using the NRZI signal provided from the EFM encoder 3 using the time delay values provided from the write strategy RAM 21. In this case, the time delay values are preferably values capable of shift control in units of T / 8. Of course, such time delay values cannot be used to cope with high-speed recording.

To this end, the present invention solves the problem of not being able to accurately record during high-speed recording by varying the levels of the recording power using the power variable 25. That is, the power variable unit 25 converts and provides write power values provided from the write storage RAM 21 by DAC conversion. Here, it is preferable that the write power values vary the power levels of the first and last pulses among the multi-pulses. That is, P1 for varying the recording power level of the first pulse is determined according to the combination of the recording mark length and the space length before the recording mark, and P2 for varying the recording power level of the last pulse is the length of the space after the recording mark and the recording mark. It depends on the combination. As a result, in the present invention, it is possible to generate a multi-pulse in which the power level varies depending on the recording mark length and the space length before and after the recording mark. Thus, the power level of the first pulse may be greater or less than the recording power level (Pa in FIG. 2), and the power level of the last pulse may be greater or less than the cooling power level (Pc in FIG. 2).

A recording operation using the optical disk recording apparatus according to the present invention configured as described above will be described.

First, information to be recorded from the microcomputer 1 is provided to the EFM encoder 3.

The EFM encoder 3 modulates the recording information to generate an NRZI signal corresponding to a mark and a space. That is, the mark on which information is to be recorded is represented by NRZI signal as '1', and the space where no information is recorded is represented by NRZI signal as '0' (see FIG. 4).

The NRZI signal is provided to the NRZI pattern analyzer 5 to calculate the recording mark length and the length of the space before and after the recording mark, and provide the result of the combination of the calculated lengths to the write storage RAM 21.

The write strategy RAM 21 stores the time delay values and the recording power values according to the combination of the recording mark and before and after the recording mark.

Therefore, the write strategy RAM 21 is a programmable delay element based on a combination result of the recording mark length and the space length before and after the recording mark provided from the NRZI pattern analyzer 5, respectively. 23 and the power variable device 25 are provided.

The programmable delay element 23 generates a multi-pulse using the NRZI signal provided from the EFM encoder 3 using the time delay values provided from the write strategy RAM 21. The multi-pulse thus generated is provided to the LD driver 27.

Meanwhile, the power variable device 25 performs DAC conversion on the write power values provided from the write strategy RAM 21 and then provides the converted write power values to the LD driver 27.

The LD driver 27 picks up a laser diode driving signal in which the power level of each pulse is varied according to the multi-pulse provided from the programmable delay element 23 according to the converted power write values provided from the power variabler 25. Provided by (15).

Accordingly, the laser diode of the pickup 15 writes to the disc 17 using the variable multi-pulse.

Therefore, the optical disc recording apparatus according to the present invention conventionally controls the shift of the recording pulse in 1 / 32T units to cope with the high speed, so as to solve the problem that the circuit of the programmable delay element is complicated, the degree of shift of the multi-pulse By varying the power level of each pulse by using a power variable instead of controlling by T / 8 units, it is possible to have a more precise recording accuracy while corresponding to a high speed.

As described above, according to the optical disc recording apparatus and method according to the present invention, by varying the power level of the multi-pulse using a power variable, it is possible to prevent the complexity of the programmable delay element according to the high-speed recording in the related art. In addition, the recording accuracy can be further improved.

Accordingly, the conventional programmable delay element can be used as it is. Therefore, the ease of design of the programmable delay element and the easier integration into the IC become easier.

Claims (11)

An optical disc recording apparatus for recording information on an optical disc, An EFM encoder for generating an NRZI signal by modulating recording information provided from the microcomputer; An NRZI pattern analyzer for calculating a NRZI signal provided from the EFM encoder and providing a calculated result; A write strategy RAM providing time delay values and write power values for generating a multi-pulse; A programmable delay element for delaying the NRZI signal provided from the EFM encoder according to the time delay values provided from the write strategy RAM to generate a multi-pulse; A power converter for DAC converting write power values provided from said write strategy RAM; An LD driver for providing a laser diode driving signal in which the power of the multi-pulse provided from the programmable delay element is varied by using the write power values provided from the power variable; And Pick-up that irradiates the disk with light from a laser diode in accordance with a laser diode driving signal provided from the LD driver Optical disc recording device composed of. The optical disc recording apparatus according to claim 1, wherein the result calculated from the NRZI pattern analyzer is a combination of a recording mark length and a space length before and after the recording mark. The optical disc recording apparatus of claim 1, wherein the time delay values determine a shift degree of a multi-pulse. The optical disc recording apparatus of claim 1, wherein the recording power values determine a power level of each pulse of the multi-pulse. 5. An optical disc recording apparatus according to claim 1 or 4, wherein a power level of the first pulse of the multi-pulse is larger or smaller than a recording power level. The optical disc recording apparatus according to claim 1, wherein the programmable delay element is designed to control shift tuning of the multi-pulse in units of T / 8. The optical disc recording apparatus according to claim 1, wherein the recording power values are determined according to a combination of a recording mark length provided from the NRZI pattern analyzer and a space length before and after the recording mark. In the method for recording information on an optical disc, Calculating a combination of the recording mark length and the space length before and after the recording mark from the NRZI signal modulated from the information to be recorded; Generating a shifted multi-pulse of the NRZI signal using time delay values corresponding to the combination; Varying the power level of each pulse using the generated multi-pulse using write power values corresponding to the combination; And Performing recording on a disc according to the variable multi-pulse Optical disc recording method comprising a. 9. The optical disc recording method according to claim 8, wherein the time delay values and the recording power values are preset. 9. The optical disc recording method according to claim 8, wherein the power level of the first pulse of the multi-pulse is larger or smaller than a recording power level. The optical disc recording method according to claim 1 or 8, wherein the power level of the last pulse of the multi-pulse is larger or smaller than a cooling power level.