KR100997481B1 - Apparatus and method for controling a writing pulse wave for phase change optical disc - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for adjusting a recording pulse waveform of a phase change optical disc, wherein a mark and space are repeatedly recorded by irradiating a laser beam to a rewritable phase change optical disc such as a CD-RW, DVD-RW, BD-RE, or the like. However, by varying one or more of the width, level, and position of a recording pulse corresponding to a mark of 4 T or more in length, the area of the leading edge of the mark is greater than or equal to a predetermined size, thereby providing 4 T length. Among the recording pulses corresponding to the above marks, due to the heat applied by the multi-pulse between the first and the last pulses, re-crystallization occurs at the leading edge of the mark, thereby making it amorphous. It is possible to effectively prevent the reduction of the area of, to improve the jitter characteristic of the mark shape, etc., and to accurately reproduce the signal recorded on the phase change optical disk. It will be very useful inventions.

Phase Change Optical Disc, Multi Pulse, Mark, Leading Edge, Jitter Characteristics, Blu-ray Disc

Description

Apparatus and method for controling a writing pulse wave for phase change optical disc}             

1 shows an embodiment of a recording pulse waveform of a general phase change optical disk,

2 shows a process in which a laser beam scans a space and a mark of a typical phase change optical disk,

3 shows a configuration of a recording pulse waveform adjusting apparatus for a phase change optical disk according to the present invention;

4 to 6 illustrate an embodiment of a recording pulse waveform adjusting method of a phase change optical disk according to the present invention;

7 to 10 show comparison of characteristics of a phase change optical disc to which the present invention is applied and a conventional phase change optical disc,

11 illustrates a specific embodiment of variably adjusting multi-pulse among recording pulses of a phase change optical disk according to the present invention;

12 illustrates a specific embodiment of variably adjusting a last pulse of a recording pulse of a phase change optical disk according to the present invention,                 

13 and 14 are graphs showing the power margin of data repeatedly recorded according to the present invention.

FIG. 15 shows the comparison of the equivalence between a state in which the position of the multi-pulse is variably adjusted and a state in which the position of the last pulse is variably adjusted according to the present invention.

[Description of Drawings]

10: phase change optical disk 11: focus lens

12 laser diode 13 beam splitter

14 Photo Detector 15 LD Driver

The present invention relates to a mark shape of a phase change optical disc such as a rewritable CD (CD-RW), a rewritable DVD (RW-RW), and a rewritable Blu-ray Rewritable (BD-RE). The present invention relates to a recording pulse waveform control apparatus and method for a phase change optical disk for intentionally changing the recording.

Recently, multimedia devices capable of recording and reproducing high quality video data, high quality audio data, and various computer data are expected to be developed and commercialized.

On the other hand, rewritable optical discs such as rewritable CDs (CD-RW) and rewritable DVD (RW-RW) are widely available and commercialized, and standardization of rewritable Blu-ray discs (BD-RE) is in progress. There is.

In addition, in the recording layer of the rewritable optical disc, marks and spaces having different degrees of reflex are repeatedly recorded by the phase change caused by the laser beam irradiation. For example, in an LD driver (Laser Diode Driver) included in a general optical disc recorder, recording corresponding to a Non Return Zero Inverting (NRZI) signal based on a reference clock of a predetermined period, as shown in FIG. It generates a pulse.                         

Then, a recording optical power corresponding to the recording pulse is applied to the laser diode LD provided in the optical pickup, and a mark of n T length (for example, 2 to 8 T) corresponding to the NRZI signal is applied. And space are repeatedly recorded in the recording layer of the phase change optical disk.

For example, when the NRZI signal corresponds to a mark having a length of 2 T, a corresponding leading edge (2LE), a front pulse (2FP), and a tailing edge (2TE) are corresponding thereto. When the NRZI signal corresponds to a mark having a length of 3 T, a leading edge 3LE, a front pulse 3FP, and a last pulse 3LP (3LP) corresponding thereto are generated. A write pulse consisting of the tailing edge 3TE is generated.

In addition, when the NRZI signal corresponds to a mark having a length of 4T to 8T, the leading edges 4 to 8LE, front pulses 4 to 8FP, and multi pulses 4 to 8MP corresponding to 4 to 8T are corresponding. 8 multi pulses), last pulses (4 to 8 LP: 4 to 8 last pulses), and tailing edges (4 to 8 TEs).

For example, when the NRZI signal corresponds to a mark having a length of 4 T, a leading edge 4LE, a front pulse 4FP, a multi pulse 4MP, a last pulse 4LP, and tailing corresponding thereto To generate a write pulse consisting of the edge (4TE), one multi-pulse present between the front pulse and the last pulse, can be referred to as a center pulse (CP).

On the other hand, when the NRZI signal corresponds to a mark of 8T length, the leading edge 8LE, the front pulse 8FP, the five multi-pulses 8MP, the last pulse 8LP, and the tailing edge corresponding thereto are corresponding. A recording pulse consisting of (8TE) is generated. Five multi-pulses (MP) existing between the front pulse and the last pulse and one center pulse (CP) described above are referred to as multi-pulses below. Collectively.

On the other hand, the width and level of the front pulse, the last pulse, and the multi-pulse present between the pulses are directly proportional to the recording optical power forming the mark by phase change. In order to prevent the mark shape from being precisely adjusted due to the heat accumulated by the laser beam irradiated when using (Single Pulse), the mark shape is adjusted using the Multi Pulse as described above.

However, in order to normally record and reproduce computer data having a much higher number of rewrites than video and audio data on the phase change optical disc as described above, recording characteristics in the shape of marks must be good, for example, rewriting with high recording density. In the case of a possible Blu-ray Disc (BD-RE), as shown in Fig. 2, the leading edge of the mark when the reproduction laser beam is moved from the crystalline (space) of the crystalline to the amorphous mark area, The jitter characteristic at (LE) becomes worse than the jitter characteristic at the tailing edge TE.

The reason for this is that Blu-ray discs that record using the blue band wavelength generally use 'Eutectic Based Material' that is fused at low temperatures, and also have 'Growth Dominant' characteristics. Since the shape of the mark changes sensitively depending on the position, etc., due to the heat of the laser beam accumulated by the multi-pulse existing between the front pulse and the last pulse, recrystallization occurs at the leading edge LE of the mark, resulting in an amorphous mark. Since the area of the leading edge is reduced, when the reproduction laser beam is moved, the difference in reflectance between the crystalline space and the amorphous mark is reduced, thereby causing an error in data reproduction.

Accordingly, the present invention was created to solve the above problems, and intentionally variably adjusts the recording pulse of a rewritable phase change optical disk such as CD-RW, DVD-RW, BD-RE, etc. To provide a recording pulse waveform control apparatus and method for a phase change optical disc for improving the recording characteristics and reproduction characteristics by preventing the area of the leading edge LE of the mark from being reduced by the heat of the beams. The purpose is to.

In the recording pulse waveform adjusting method of a phase change optical disc according to the present invention for achieving the above object, while recording a mark and a space repeatedly by irradiating a laser beam to the phase change optical disc, recording corresponding to a mark of 4 T or more in length It is characterized in that for controlling any one or more of the width, level, position of the pulse,                     

In addition, the recording pulse waveform control apparatus for a phase change optical disk according to the present invention comprises: light emitting means for repeatedly recording a mark and a space by irradiating a laser beam to the phase change optical disk; And driving means for generating a recording pulse corresponding to an NRZI signal based on a reference clock of a predetermined period and applying the same to the light emitting means, wherein the driving means includes a recording corresponding to a mark of 4 T or more in length. It is characterized in that the one or more of the width, level, position of the pulse is variably adjusted.

Best Mode for Carrying Out the Invention Preferred embodiments of a recording pulse waveform adjusting apparatus and method for a phase change optical disk according to the present invention will be described in detail with reference to the accompanying drawings.

First, the recording pulse waveform control apparatus and method for a phase change optical disc according to the present invention is applicable to a rewritable phase change optical disc such as CD-RW, DVD-RW, BD-RE, and the like. As shown in FIG. 3, the optical disk recorder includes a focus lens 11, a laser diode 12, a beam splitter 13, a photo detector 14, an LD driver 15, and the like.

On the other hand, the LD driver 15 generates a writing pulse corresponding to the NRZI signal based on a predetermined reference clock ref_CLK as described above with reference to FIG. 1, and then writes the writing pulse. Corresponding recording optical power is applied to the laser diode 12 provided in the optical pickup, so that the mark and space of length n T (e.g., 2 to 8 T) corresponding to the NRZI signal are transferred to the phase change optical disk 10. The recording layer is repeatedly recorded on the recording layer.

In the LD driver 15, when the NRZI signal corresponds to a mark having a length of 4T to 8T, the leading edge LE, the front pulse FP, the multi-pulse MP, and the last corresponding to the NRZI signal Generating a recording pulse consisting of a pulse LP and a tailing edge TE, and by varying one or more of the width, level, and position of the multi-pulse, leading edges of the mark. (LE) The area is prevented from being recrystallized and reduced by the heat of the laser beam according to the multi-pulse.

For example, as shown in FIG. 4, in a typical conventional LD driver, a write pulse corresponding to a 4 T length mark is divided into a front pulse (FP), a multi pulse (MP), and a last like 'Pulse_A'. Generating a pulse (LP), but the same level and width (W) of the pulses, while maintaining the same cooling period (CP: Cooling Period), the interval between each pulse, leading edge of the mark (LE) The area is recrystallized and reduced by the heat of the laser beam according to the multi-pulse,

On the other hand, in the LD driver 15 to which the present invention is applied, as a first embodiment, a write pulse corresponding to a mark having a length of 4 T is applied to the front pulse FP, the multi pulse MP, and the like as 'Pulse_B'. While generating the last pulse (LP), by varying the position of the multi-pulse, the distance between the front pulse (FP) and the multi-pulse (MP), the distance between the more than within a predetermined range, and the It extends the width (W '> W).

Accordingly, the cooling period CP '> CP, which is an interval between the front pulse and the multi-pulse, can be extended, thereby preventing the area of the leading edge LE' of the mark from being reduced by the heat of the laser beam according to the multi-pulse. In addition, by extending the width of the multi-pulse, it is possible to compensate for the cooling state after the front pulse recording with a high recording optical power, thereby minimizing the neck shape in the multi-pulse recording portion It becomes possible.

Meanwhile, as a second embodiment according to the present invention, a recording pulse corresponding to a mark having a length of 4 T is generated as a front pulse FP, a multi pulse MP, and a last pulse LP such as 'Pulse_C'. In addition, the position of the multi-pulse is fixed, and instead, the position of the front pulse and the last pulse is variably adjusted so that the distance between the front pulse FP and the multi-pulse MP is further separated from within a predetermined range, The width (W '> W) of the multi-pulse is expanded.

As a third embodiment according to the present invention, a recording pulse corresponding to a mark having a length of 4 T is generated as a front pulse FP, a multi pulse MP, and a last pulse LP, such as 'Pulse_D'. In addition, the position of each pulse is variably adjusted, and the interval between the front pulse and the multi-pulse is further spaced apart within a predetermined range, and the width (W '> W) of the multi-pulse is expanded.

Accordingly, the cooling period CP '> CP, which is an interval between the front pulse and the multi-pulse, can be extended, thereby preventing the area of the leading edge LE' of the mark from being reduced by the heat of the laser beam according to the multi-pulse. In addition, by extending the width of the multi-pulse, it is possible to compensate for the cooling state after the front pulse recording with a high recording optical power, thereby minimizing the neck shape in the multi-pulse recording portion It becomes possible.

On the other hand, as another embodiment according to the present invention, as shown in Fig. 5, instead of maintaining the width W of the multi-pulse as it is, the level of the multi-pulse is increased variably to increase the recording optical power of the multi-pulse. As a result, the cooling state after the front pulse recording can be compensated by the high recording optical power, thereby minimizing the neck shape in the multi-pulse recording portion.

In addition, as shown in FIG. 6, the front pulse and the last pulse are variably adjusted for the recording pulses corresponding to the 2 T length mark and the 3 T length mark, so that the shape of the mark can be intentionally variably adjusted. do.

Meanwhile, FIGS. 7 to 10 show comparisons of characteristics of the phase change optical disc and the conventional phase change optical disc to which the present invention is applied. For example, recording is performed by using a recording pulse frequency and an optical disc rotation speed suitable for double speed. The results were evaluated.

In addition, the result using the recording pulse waveform of this invention is the left graph in each figure, The result using the conventional recording pulse waveform used at 1x speed is the graph on the right of each figure, and the recording method in each figure (Write Strategy). The reference jitter for each comparison is 10% of the upper limit of jitter evaluated using a conventional equalizer, and 6.5% of the upper limit of jitter evaluated using a limit equalizer.

As shown in Fig. 7, when the conventional recording pulse waveform is used, a portion exceeding the upper limit of 10% of jitter is generated. However, when the recording pulse waveform of the present invention is used, the jitter characteristic is repeatedly recorded than before. We can see that the characteristics are low at the absolute jitter level, and all are below the reference jitter.                     

On the other hand, as shown in Fig. 8, when the recording power Pw margin is used, the range having the upper limit of jitter of 10% or less is 4.9 mW to 5.7 mW when the recording pulse of the present invention is used. When a write pulse is used, it is out of specification for any optical power range.

In addition, as shown in FIGS. 9 and 10, the margins of the tangential tilt and the radial tilt are shown in degrees θ, and have a range of 10% or less jitter evaluated using a general equalizer. On the basis of the reference, when the recording pulse of the present invention is used, all of the margins are widened so that recording and reproducing can be stably performed in any optical disk drive.

Meanwhile, in the Timing Shift of Multi-Pulse (TSMP) method, which is newly defined as a specific embodiment according to the present invention, a mark and a space are repeatedly recorded by irradiating a laser beam onto a rewritable optical disc. Among the recording pulses corresponding to the mark of 4 T length or more, the position of the multi-pulse (mp) existing between the first pulse (top) and the last pulse (lp) is variably adjusted so that the leading edge area of the mark is larger than or equal to a predetermined size. To be

For example, in the timing shift multi-pulse (TSMP) method of the present invention, as shown in Fig. 11, among the recording pulses corresponding to marks of 4 T or more length recorded by 17 pp modulation, the multi-pulse (mp ), The 2 T mark consists of only one first pulse (top), and the 3 T mark consists of the first pulse (top) and the last pulse (lp).

The 4 T mark consists of the first pulse (top) and the last pulse (lp), and one multi-pulse (mp), and the 5 T mark, the first pulse (top) and the last pulse (lp). ), And two multi-pulses (mp), the 6 T mark consists of the first pulse (top) and the last pulse (lp), and three multi-pulses (mp), the 7 T mark, It consists of the first pulse (top) and the last pulse (lp) and four multi-pulses (mp), and the 8 T mark, the first pulse (top) and the last pulse (lp), and five multi-pulses (mp).

Meanwhile, in the timing shift multi-pulse (TSMP) method, the width and the position of the pulses constituting each T mark are set, but the position of the multi-pulse lp is variably adjusted, for example, the position of the first pulse. Can be variably adjusted by dTtop = i * (Tw / 16), i = -16, -15, ..,-1,0,1,2, .. 15, for a mark of 4 T or more, All of the above dTtop = i * (Tw / 16) is applied.

Further, the width of the first pulse is set to Ttop = j * (Tw / 16) + k * (1ns), j, k = 0,1,2..15, Ttop≥2.5ns, and each T mark The Ttop = j * (Tw / 16) + k * (1ns) may be equally applied to a mark of 4 T or more.

And, the position of the multi-pulse (mp) existing between the first and the last pulse, dTmp = m * (Tw / 16), m = -16, -15, ..., -1, 0, 1, 2,... 15 can be variably adjusted, and for all multi pulses (mp), the dTmp = m * (Tw / 16) is applied equally.

On the other hand, the width of the last pulse is set to Tlp = s * (Tw / 16) + t * 1ns, s, t = 0, 1, 2, ..., 15, Tlp ≥ 2.5ns, and more than 4 T The Tlp = s * (Tw / 16) + t * 1ns is equally applied to the last pulse width of the mark, and the Tlp = s * (Tw / 16) to the width of the last pulse of the 3 T mark You can apply a value other than + t * 1ns.

Also, after the last pulse lp, the position of the erase pulse for forming a space is dTe = u * (Tw / 16), u = -24, -23, .. , -1,0,1,2, .., 15 can be variably adjusted, and can be set to different values for each T mark. For marks above 4 T, the dTe = u * (Tw / 16 ) Can all be applied equally.

For reference, in the dTtop and dTmp, the '-' value means moving later than the reference clock, and the '+' value means moving earlier than the reference clock.

In another specific embodiment according to the present invention, the timing shifting last pulse (TSLP) method repeatedly records marks and spaces by irradiating a laser beam onto a rewritable optical disc. The position of the last pulse lp is variably adjusted among the recording pulses corresponding to the mark of 4 T or more in length so that the leading edge area of the mark is equal to or larger than a predetermined size.

For example, in the timing shift last pulse (TSLP) method of the present invention, as shown in FIG. 12, the width and the position of the pulses constituting each T mark are set, but the last pulse, that is, the last pulse (lp). The position of the first pulse is dTtop = i * (Tw / 16), i = -16, -15, ..,-1,0,1,2 as described above. ..., 15 can be variably adjusted, and can be set to different values for each T mark. For the marks of 4 T or more, all of the above dTtop = i * (Tw / 16) is applied.

Further, the width of the first pulse is set to Ttop = j * (Tw / 16) + k * (1ns), j, k = 0,1,2..15, Ttop≥2.5ns, and each T mark The Ttop = j * (Tw / 16) + k * (1ns) may be equally applied to a mark of 4 T or more.

And, the width of the multi-pulse (mp) existing between the first and the last pulse, Tmp = p * (Tw / 16) + q * 1ns, p, q = 0, 1, 2 .... 15 Tmp ≥ 2.5 ns can be variably adjusted. For all multi-pulses (mp) of 4 T or more, the same applies to Tmp = p * (Tw / 16) + q * 1 ns.

Meanwhile, the position of the last pulse, that is, the last pulse, is variable by dTlp = l * (Tw / 16), l = -16, -15, ..,-1,0,1,2, .. 15 The dTlp = l * (Tw / 16) may be equally applied to all last pulses of 4 T or more, and other values may be applied to the last pulses of 3 T.

In addition, the width of the lattice pulse is set to Tlp = s * (Tw / 16) + t * 1ns, s, t = 0, 1, 2, ..., 15, Tlp ≥ 2.5ns, 4 T or more The Tlp = s * (Tw / 16) + t * 1ns are equally applied to the last pulse width of the mark, and the Tlp = s * (Tw / 16) + t to the width of the last pulse of the 3T mark. A value different from * 1 ns can be applied.                     

After the last pulse lp, the position of an erase pulse for forming a space is dTe = u * (Tw / 16), u = -16, -15, ..,-1 , 0,1,2, .., 15 can be variably adjusted, and can be set to different values for each T mark. For marks of 4 T or more, dTe = u * (Tw / 16) The same can be applied.

For reference, in the dTtop and dTmp, the '-' value means moving later than the reference clock, and the '+' value means moving earlier than the reference clock.

On the other hand, when the timing shift multi-pulse (TSMP) method according to the present invention is applied to a rewritable Blu-ray Disc (BD-RE), for example, the rewritable Blu-ray has a disc inner diameter of 15 mm, an outer diameter of 120 mm, and a thickness. Ag alloy reflective layer, ZnS-SiSO ₂ lower dielectric protective layer, first interface layer, Ge-Sb-Te on donut-shaped polycarbonate substrate with track pitch of 0.32um with land and groove The multilayer thin film is laminated in the order of the series recording layer, the second interface layer, and the ZnS-SiO ₂ upper dielectric protective layer.

Then, the 80um polycarbonate cover sheet was bonded to the 20um UV resin (Raisin), and the disk was initialized using an initialization device, and then an optical disk driver or a measurement device (e.g., an Pulstec ODU-1000 device) was used. To record and play back.

On the other hand, in the recording and reproducing conditions, the distribution of the size of the leading edge and the trailing edge where the position of the leading edge and the trailing edge deviates from the reference position according to the PLL clock is CBL (Channel Bit Length). Normalized, measured and quantified to jitter values, five tracks are recorded continuously in one recording to measure jitter on the third track, and repeat recording jitter, or DOW (direct overwrite) jitter, is also five tracks. Are recorded continuously, repeatedly recorded N times, and then the jitter of the third track is measured and recorded using a random pulse waveform in which 2T-8T pulses are arbitrarily mixed.

Channel bit clock 133 MHz (1T = 7.575ns), linear speed 9.84 m / s, disk performance 25 GB / single side, recording conditions, channel bit clock 66 MHz, linear speed 4.92 m / s, disk performance 25 GB / The single side is the playback condition.

In addition, the jitter measurement equipment uses a TA520 from Yokogawa, with 30,000 sampling, 0.35mW of reading laser power, 0.1mW of bottom laser power, 5.2mW of writing laser power, erasing The laser power is set to 3.4mW, the disk measuring position is 41mm, the on-recording recording is recorded on the convex part of the land / groove substrate, and the laser wave length is 408nm.

Meanwhile, the write pulse form variables for each mark are set values optimized to minimize the DOW (10) jitter under a condition that satisfies dTmp = 0. In the case of the 2T mark, dTtop (2T) = -0.5ns, Ttop (2T) =-2.75ns, dTe (2T) =-1ns, and for 3T marks, dTtop (3T) =-0.75ns, Ttop (3T) =-2.75ns, Tlp (3T ) = 3.25ns, dTe (3T) =-0.5ns, and more than 4 T marks, dTtop (≥4T) =-0.5ns, Ttop (≥4T) = 3ns, Tlp (≥4T) = 3.25ns, dTe (≥4T) = -1 ns, dTmp (≥4T) = 0 (-1) ns, and Tmp (≥4T) = 3.25 ns.

13 and 14 show jitter values measured as the recording power is changed, and the change in the dTmp = -1ns is measured to compare the jitter value according to the recording power. FIG. 13 shows the DOW (0), i.e., the first recording result, and FIG. 14 shows the jitter value after the DOW (10), i.e., 10 repeated overwrite recordings.

On the other hand, the dTmp =-1 ns means that the multi-pulse part of the 4 T to 8 T mark starts 1 ns later than the reference clock, dTmp = 0 ns when both dTmp =-1 ns as shown in Figs. It can be seen that the jitter value is lower than that when and the recording power margin is increased. The optimal dTmp value may vary depending on the recording film characteristics of the disc.

On the other hand, in the timing shift last pulse (TSLP) method according to the present invention, dTmp <0 is closer to the last pulse (lp) than the first pulse (top) than when the multi-pulse part is dTmp = 0 DTmp < 0 can also be implemented by moving dTtop, dTlp, dTe in the positive direction (+), as shown in FIG.

For example, as described above, if the equivalent of the case of dTmp = -1 is represented by the variables of the Write Pulse Form with dTmp = 0, in the case of the 2T mark, dTtop (2T) = 0.5ns, Ttop (2T) = 2.75ns, dTe (2T) = 0ns, dTtop (3T) = 0.25ns, Ttop (3T) = 2.75ns, Tlp (3T) = 3.25ns, dTe for 3 T mark (3T) = 0.5 ns, for more than 4 T marks, dTtop (≥4T) = 0.5 ns, Ttop (≥4T) = 3 ns, Tlp (≥4T) = 3.25 ns, dTe (≥4T) = 0 ns, dTmp ( 4T) = 0 ns, and Tmp (≥ 4T) = 3.25 ns.

Or more, preferred embodiments of the present invention described above, for the purpose of illustration, those skilled in the art, within the technical spirit and the technical scope of the present invention disclosed in the appended claims below, to further improve various other embodiments Changes, substitutions or additions will be possible.

The apparatus and method for adjusting the recording pulse waveform of the phase change optical disc according to the present invention, which is constructed and constructed as described above, irradiates a laser beam to a rewritable phase change optical disc such as a CD-RW, a DVD-RW, a BD-RE, and the like. The space is repeatedly recorded, but one or more of the width, level, and position of the recording pulse corresponding to the mark of 4 T or more in length is variably adjusted so that the leading edge area of the mark is larger than or equal to the predetermined size. Due to the heat applied by the multi-pulse between the first and last pulses among the corresponding write pulses, recrystallization occurs at the leading edge of the mark, which effectively prevents the reduction of the amorphous region. This improves the jitter characteristic of the mark shape and the like, and also makes it possible to accurately reproduce the signal recorded on the phase change optical disc. It is an invention.

Claims (46)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete In accordance with the reference clock signal having a unique signal rate, marks and spaces are formed on the phase change optical disk with a plurality of recording pulses, The plurality of write pulses are composed of a sequence in which a second pulse is continuous after a first pulse, The rise time of the first pulse coincides with the rise time of the first clock signal, and the rise time of the second pulse occurs within a preset period after the rise time of the second clock signal, And the width of the second pulse is wider than the width of the first pulse. In accordance with the reference clock signal having a unique signal rate, marks and spaces are formed on the phase change optical disk with a plurality of recording pulses, The plurality of write pulses are composed of a sequence in which a second pulse is continuous after a first pulse, The rise time of the first pulse occurs within a predetermined period before the rise time of the first clock signal, the rise time of the second pulse corresponds to the rise time of the second clock signal, And the width of the second pulse is wider than the width of the first pulse. In accordance with the reference clock signal having a unique signal rate, marks and spaces are formed on the phase change optical disk with a plurality of recording pulses, The plurality of write pulses are composed of a sequence in which a second pulse is continuous after a first pulse, The rise time of the first pulse occurs within a preset first period after the rise time of the first clock signal, and the rise time of the second pulse occurs within a preset second period after the rise time of the second clock signal, And the predetermined second period of time is longer than the predetermined first period of time, and the width of the second pulse is wider than the width of the first pulse. In accordance with the reference clock signal having a unique signal rate, marks and spaces are formed on the phase change optical disk with a plurality of recording pulses, The plurality of write pulses are composed of a sequence in which a second pulse is continuous after a first pulse, The rise time of the first pulse coincides with the rise time of the first clock signal, and the rise time of the second pulse occurs within a preset period after the rise time of the second clock signal, And the height of the second pulse is higher than the height of the first pulse. 31. The method of claim 30, The plurality of write pulses consist of a last pulse following the second pulse, And the rising time of the last pulse coincides with the rising time of the last clock signal. The method of claim 31, wherein The plurality of write pulses consist of a last pulse following the second pulse, And the rising time of the last pulse occurs within a second period set before the rising time of the last clock signal. 33. The method of claim 32, The plurality of write pulses consist of a last pulse following the second pulse, And the rising time of the last pulse occurs within a third predetermined period after the rising time of the last clock signal. The method of claim 36, And the predetermined third period is the same time as the predetermined first period. The method according to any one of claims 34 to 36, And said last pulse is directly contiguous with said second pulse. 31. The method of claim 30, The plurality of write pulses consist of a last pulse following the second pulse, The rise time of the last pulse is generated after the rise time of the last clock signal or within a preset second period, And the predetermined second period is shorter or equal to 3/16 times one cycle of a reference clock signal. The method according to any one of claims 30 to 33, wherein And the phase change optical disc is any one of a rewritable CD, a rewritable DVD, and a rewritable Blu-ray disc. In accordance with the reference clock signal having a unique signal rate, marks and spaces are formed on the phase change optical disk with a plurality of recording pulses, The plurality of write pulses are composed of a sequence in which a second pulse is continuous after a first pulse, The interval between the rise time of the first pulse and the rise time of the second pulse is wider than the rise time interval between the pulses of the reference clock signal, And the width of the second pulse is wider than the width of the first pulse, or the height of the second pulse is higher than the height of the first pulse. The method of claim 41, wherein The rise time of the first pulse is generated within a predetermined period before the rise time of the first clock signal, And the rising time of the second pulse coincides with the rising time of the second clock signal. The method of claim 42, wherein The plurality of write pulses consist of a last pulse following the second pulse, And the rising time of the last pulse coincides with the rising time of the last clock signal. The method of claim 41, wherein The rise time of the first pulse is generated within a predetermined period before the rise time of the first clock signal, And the rising time of the second pulse coincides with the rising time of the second clock signal. The method of claim 41, wherein The plurality of write pulses consist of a last pulse following the second pulse, And the rising time of the last pulse occurs within a second period set before the rising time of the last clock signal. Light emitting means for irradiating a laser beam onto the phase change optical disk to record marks and spaces; A driving means for generating a recording pulse and supplying it to said light emitting means, The driving means forms a mark and a space on the phase change optical disk in a plurality of recording pulses according to a reference clock signal having a unique signal rate, The plurality of write pulses comprise a sequence comprising a second pulse subsequent to the first pulse, wherein an interval between the rise time of the first pulse and the rise time of the second pulse is greater than the rise time interval between the pulses of the reference clock signal. Wide, And the width of the second pulse is wider than the width of the first pulse, or the height of the second pulse is higher than the height of the first pulse.

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