JPH0810489B2 - Optical disc recording method and optical disc device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc recording method and an optical disc device, and specifically, irradiates a laser beam having a diameter of about 1 μm on the optical disc to record and reproduce signals at high density. Then
Further, the present invention relates to a rewritable optical disc recording method capable of repeatedly recording and reproducing a signal by erasing a signal once recorded by laser irradiation, and an optical disc apparatus according to this method.

2. Description of the Related Art Recording in an optical disk device is performed by intensity-modulating the laser light intensity with the recording data using a signal indicating a recording section and the recording data.

An example of the above optical disk device is shown in FIG. In the figure, 1 is an address reproducing circuit, which is an RF reproduced from an optical disk
The address signal Ad is extracted from the signal. Reference numeral 2 denotes an address detection circuit, which extracts a sector pulse SP indicating a sector section from the address signal Ad. The sector pulse SP is sent to the delay circuit 3 to be delayed by a predetermined time and becomes a start pulse STP. Reference numeral 4 denotes a data generation circuit, which is a recording data WDT (including a synchronization signal described later) to be recorded on the optical disc, triggered by the input of the start pulse STP
A recording gate WGT indicating a recording section is generated. Recorded data W
The DT and the recording gate WGT are sent to the laser drive circuit of 5,
The intensity of the laser light is modulated, and the recording data WDT is recorded on the optical disc.

FIG. 6 shows an operation timing chart of the optical disk device of FIG. In FIG. 6, a is an address signal Ad generated from the RF signal in the address reproducing circuit. b
Is a sector pulse SP representing a sector section and is obtained from the address signal Ad. The sector pulse SP is given a time delay ΔT so that the recording enters the sector section, and is sent to the data generating circuit 4 as a start pulse STP indicated by c. The start pulse STP serves as a trigger for the data generation circuit 4, and recording data WDT of e and recording gate WGT of d.
Occur at the same time. The recording data WDT and recording gate WGT are
It is turned off within the range of the sector section.

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention In the device, the recording gate WGT and the recording data WDT are
Since the start point of is accurately determined by the start pulse STP, the recording start point is always the same place in the sector,
The same location is used for repeated recordings. As a property of the rewritable optical disc, if the recording mark is repeatedly recorded in the same place many times, the recording mark and its periphery are deteriorated by thermal stress and the like, and when the different signal is recorded next time, the mark cannot be accurately recorded. For example, an experiment result has shown that the number of repetitions is improved by about one digit when different data is recorded for each repetition as compared with the number of repetitions of recording the same data.

Actually, even if the data to be recorded is different, the position of the sync signal portion which is important during reproduction is fixed, and therefore the number of repetitions cannot be improved by the conventional method.

That is, since the sync signal portion having the same signal pattern is recorded at the same location in each sector every time, even if different data is recorded, the fatigue of the disc material cannot be prevented.

In view of such a point, the present invention randomly changes the recording start point in a sector to prevent repeated use of the same location, thereby averaging and reducing the fatigue of the disc material, and as a result, repeatedly using the same. An object of the present invention is to provide an optical disk recording method and an optical disk device that improve the number of times.

Means for Solving the Problems The present invention is characterized in that a recording start point in a sector of an optical disk is randomly changed within a range in which recording data fits in the sector.

Effect The present invention reduces the fatigue of the optical disc material due to the repeated use of the same place in the sector by changing the recording start point on the optical disc, and improves the number of times of repeated use of the rewritable optical disc.

Embodiment 1 FIG. 1 is a partial configuration diagram of an optical disk device in a first embodiment adopting an optical disk recording method according to the present invention. FIG. 2 shows a time chart for explaining the operation of the device.

First, in FIG. 1, a portion added to the conventional example of FIG. 5 described above will be described.

A D-type flip-flop (hereinafter abbreviated as D-FF) 11 latches the pulse SPD from the delay circuit 3 as a data input, and outputs the output Q as the start pulse STP.
Is sent to the data generation circuit 4. The D-FF 11 gives a random time delay to the start pulse STP at the cycle of the clock input CK1 that oscillates asynchronously with the data input SPD. Therefore, the data generation circuit 4 simultaneously generates the recording data WDT and the recording gate WGT with a random time delay of the start pulse STP, and changes the recording start point in the sector.

Reference numeral 10 denotes a counter, which divides a clock CK2 having a certain period to generate a clock CK1 having an appropriate period which is asynchronous with the data input pulse SPD and supplies it to the D-FF11. The cycle of the clock CK1 is selected such that the recording data WDT and the recording gate WGT fall within the sector interval even if the time delay given to the start pulse STP is maximum.

Next, the operation will be described with reference to FIG. As shown in the conventional example, the sector pulse SP of b indicating the sector section is generated from the address signal of a. The sector pulse SP is
A predetermined time delay ΔT is given by the delay circuit 3, and a pulse SPD of c is input to the D-FF 11. d is a clock input CK1 of the D-FF and oscillates at a certain frequency asynchronous with the data input SPD of the D-FF. Therefore, the D-FF11 randomly latches the SPD of c as data and outputs the start pulse STP of e depending on the oscillation period of the clock CK1. That is, the start pulse of e changes with a random time delay in the cycle of the clock CK1.

The start pulse STP of e enters into the data generation circuit as a trigger, and the recording data with a random time delay.
WDT and recording gate WGT are generated simultaneously. Recorded data
The WDT and the recording gate WGT are sent to the laser driving circuit, the recording start point in the sector changes randomly, and the recording data WDT and the recording gate WGT are shifted and recorded.

As described above, according to the present embodiment, the recording start point in the sector can be randomly changed only by inserting the D-FF in front of the data generating circuit, and the repeated use of the same location in the sector is possible. It is possible to reduce deterioration of the disc material.

FIG. 3 is a partial block diagram of an optical disk device according to the second embodiment of the present invention. FIG. 4 shows a time chart for explaining the operation of the device.

In the second embodiment, the variable width of the recording start point is set to a desired set value by a delay so that it can be changed randomly.

First, in FIG. 3, a portion added to the conventional example shown in FIG. 5 will be described.

20 is a counter, a clock oscillating at a certain frequency
The count of CK ₃ is controlled by the control line AS. The outputs Q _A and Q _B of the counter 20 are randomly selected from four combinations of “H” and “L”. The counter 20 stops counting by the control line AS before the start of recording and holds the randomly selected values of Q _A and Q _B during recording. The outputs Q _A and Q _{B of the} counter 20 are connected to the inputs A and B of the selection circuit 21.

The connection circuit 21 randomly selects one of the four address signals Ad _{0 to} Ad ₃ connected to the data inputs D _{A to} D _D by the combination of the inputs A and B.

Reference numerals 22, 23 and 24 denote analog delay circuits which give time delays ΔT, 2ΔT and 3ΔT to the input address signals.

Next, the operation will be described with reference to FIG. First, when the output Q _A = L, Q _B = L of the counter 20, the selection circuit
21 is an address signal that does not pass the delay of the data input D _A
Select Ad ₀ . The operation at this time is exactly the same as in the conventional example, and the address signal Ad _{0 of a} is the address detection circuit 2
Then, it becomes a sector pulse SP _{0 of} b, is given a certain time delay by the delay circuit 3, and a start pulse STP _{0 of} c
Becomes The C start pulse STP ₀ enters the data generation circuit 4 as a trigger to generate the recording gate WGT _{0 of} d and the recording data WDT ₀ at the same timing.

Here, consider the case where the output of the counter 20 is Q _A = H, Q _B = L. At this time, the selection circuit 21 selects the address signal Ad _{1 of} e having a time delay ΔT which enters the data input D _B. The address signal Ad _{1 of} e becomes the sector pulse SP ₁ of f in the address detection circuit 2, is given a certain time delay by the delay circuit 3, and becomes the start pulse STP _{1 of} g. The start pulse STP _{1 of} g is delayed by ΔT of the analog delay 22 with respect to the start pulse STP _{0 of} e. Therefore, the data generation circuit 4 triggered by the start pulse STP ₁ of g generates the recording gate WGT _{1 of} h and the recording data WDT ₁ having a time delay of ΔT with respect to the recording gate WGT _{0 of} d. .

Similarly, when the output of the counter 20 is Q _A = L, Q _B = H, the address signal Ad _{2 of} i having the time delay 2ΔT is selected, and the recording gate WGT ₂ and the recording data WDT ₂ are d The recording gate WGT _{0 has a} time delay of 2ΔT.

When the output of the counter 20 is Q _A = H, Q _B = H, the address signal Ad _{3 of} j having a time delay of 3ΔT is selected, and the recording gate WGT ₃ and the recording data WGT ₃ are equal to each other. There is a time delay of 3ΔT with respect to the recording gate WGT ₀ .

As described above, according to the present embodiment, the delay circuit and the selection circuit are provided in the address signal line, and the address signal is randomly selected by the output of the counter, so that the variable width of the recording start point in the sector is delayed. It can be set to a desired setting value and can be changed randomly, and fatigue of the disk material due to repeated use of the same place in the sector can be reduced.

The present invention can be applied to any rewritable recording device using heat such as a phase change type or magneto-optical type recording material. Especially, in consideration of thermal stress, the effect is great in the case of phase change recording.

Further, in the second embodiment, the delays 22 to 24 and the selection circuit 21 are placed before the address detection circuit 2, but they may be placed after the address detection circuit 2, the delay circuit 3 or the data generation circuit 4. Also, although three delays were used, any number may be used as long as it is at least one.

In addition, in the present invention, it goes without saying that the erase gate indicating the erase section is sufficiently longer than the recording gate and the recording data. Preferably, the erase gate should also be given the same time delay as the recording gate.

EFFECTS OF THE INVENTION As described above, according to the present invention, by changing the recording start point in a sector to a random number, deterioration of the disk material due to repeated use of the same place in the sector is reduced and the number of repetitions is reduced. It can be improved and its practical effect is great.

[Brief description of drawings]

FIG. 1 is a block diagram of an optical disk device in a first embodiment adopting an optical disk recording method according to the present invention, and FIG.
FIG. 7 is a timing chart for explaining the operation in the first embodiment, FIG. 3 is a block diagram of the optical disk device in the second embodiment of the present invention, and FIG. 4 is an operation in the second embodiment. 5 is a configuration diagram of a conventional optical disc device, and FIG. 6 is a timing chart for explaining the operation of the conventional optical disc device. 1 ... Address reproduction circuit, 2 ... Address detection circuit, 3
... delay circuit, 4 ... data generation circuit, 5 ... laser drive circuit, 11 ... D-flip-flop.

Claims (4)

[Claims] 1. A recording method of an optical disc, wherein a rewritable optical disc having a sector structure is irradiated with a laser beam to record recording data including a synchronization signal in each sector, wherein a recording start point of the recording data in each sector is set. A recording method for an optical disc, which is characterized by changing at random. 2. The optical disk recording method according to claim 1, wherein the rewritable optical disk is a phase change optical disk. 3. A recording / reproducing means for irradiating a rewritable optical disk having a sector structure with a laser beam to record / reproduce recording data including a synchronization signal in each sector, and the recording / reproducing means reproduces from the optical disk. Means for detecting an address signal from the reproduced signal, means for generating a pulse indicating a sector section from the address signal, and generation of a start pulse for defining a recording start point of recording data in each sector from the pulse indicating the sector section An optical disk device comprising: means for giving a random time delay to the start pulse to randomly change a recording start point in each sector. 4. The optical disk device according to claim 3, wherein the rewritable optical disk is a phase change optical disk.