JP2000099945A - Reproduced light quantity controlling device for optical storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent data from being erased and to prevent a semiconductor laser from being broken by providing a means detecting a state in which a reproduced signal form marks for controlling a reproducing power can not be correctly reproduced and fixing the reproducing power when an abnormal state is detected. SOLUTION: A data pattern verifying circuit 10 inputs a binary data pattern to be outputted from a data reproducing circuit 7 in accordance with the reproduced signal of an area for controlling a reproducing power to verify the pattern coincides with a pattern for controlling the reproducing power or not. The circuit outputs the signal of '1' when they coincide and the signal of '0' when they do not coincide to supply the signals to a reproducing power fixing circuit 11. The circuit 11 drives a semiconductor laser 2 by a driving current to be outputted from a reproducing power driving circuit 9 when the coincident signal '1' is inputted to the circuit 11 and drives the laser 2 by a prescribed fixed current when the noncoincident signal '0' is inputted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light source for irradiating an optical recording medium of a magnetic super-resolution type with a light beam and controlling the light amount of the light beam so that a reproduction signal from a recording mark approaches a predetermined value. The present invention relates to a reproduction light amount control device in a storage device.

[0002]

2. Description of the Related Art In a magneto-optical disk drive, a magneto-optical disk of a magnetic super-resolution type having a recording layer and a reproducing layer having in-plane magnetization is irradiated with a light beam from the reproducing layer side. The reproducing layer only in a portion (hereinafter, referred to as an aperture) whose temperature has risen to a predetermined temperature or higher in the irradiation area transfers the magnetization of the corresponding recording layer and shifts from in-plane magnetization to perpendicular magnetization, so that the light beam It is possible to reproduce a recording mark smaller than the spot diameter.

In this method, even if the driving current for generating the light beam is kept constant, the reproduction power of the light beam may fluctuate in accordance with the change in the environmental temperature during reproduction. If the reproduction power becomes too strong, the aperture becomes too large, the output of the reproduction signal from the adjacent track increases, and the ratio of the noise signal included in the reproduced data increases, causing a reading error. The probability increases. On the other hand, if the reproduction power becomes too weak, the aperture becomes smaller than that of the recording mark, and the output of the reproduction signal from the track to be read becomes smaller, which also increases the probability of occurrence of a read error.

Japanese Patent Laid-Open Publication No. Hei 8-63817 discloses reproducing power control marks of two different lengths on a magneto-optical disk and reproducing power control marks such that the ratio of the reproduced signals approaches a predetermined value. By controlling
The reproduction power is always kept at an optimum value, and the probability of occurrence of a reading error is reduced.

FIG. 8 schematically shows the structure of this device.
FIG. 9 schematically shows a sector structure of the magneto-optical disk 1 of FIG. In FIG. 9, a sector 100 includes a sector synchronization mark 101 indicating the head of the sector, a reproduction power control area 102 on which a short mark repetition pattern and a long mark repetition pattern are recorded as reproduction power control marks, a digital data Is recorded in the data recording area 103.

In FIG. 8, when the light emitted from the semiconductor laser 2 reaches the sector synchronization mark 101 of the sector 100 on the magneto-optical disk 1, it recognizes that it is the head of the sector. Subsequently, the emitted light is applied to the reproduction power control area 102.
, The reflected light from the repetitive pattern of short marks and long marks recorded in that area is converted into a reproduction signal by the photodiode 3. The playback signal is A /
It is input to a D (Analog / Digital) converter 5 and a clock generation circuit 4. The clock generation circuit 4
A clock signal that is phase-synchronized with the reproduction signal is generated by LL (Phase Locked Loop). Then, in the A / D converter 5, the reproduction signal is converted into digital data based on the clock signal. The amplitude ratio detection circuit 6 detects only the digital data at the upper and lower peak points from among the digital data input for each clock signal, and averages them by a predetermined number of samples, thereby detecting the average value of the amplitude values. As described above, the average amplitude values of the long mark and the short mark are detected, the ratio between them is obtained, and the ratio is output as the average amplitude ratio. The differential amplifier 8 compares the average amplitude ratio with the target value, and the reproduction power control circuit 9 controls the drive current of the semiconductor laser 2 so that feedback is applied in a direction to reduce the difference. In this way, after the driving current of the laser beam is controlled so that the optimum reproducing power is given, the emitted light is irradiated to the data recording area 103,
The read reproduction signal is input to the data reproduction circuit 7 via the A / D converter 5, and binary data having a low error rate is output. Then, when the emitted light reaches the next sector, the same processing is repeated, and a new optimum reproduction power is newly set. As described above, the recording area of the reproduction power control mark is provided separately for each sector, and the reproduction signal control for the reproduction power control is detected for each sector, whereby the reproduction power control responds at a short time interval. Thus, it is possible to follow a short-term fluctuation of the optimum reproducing power.

[0007]

However, in the state where the reproduction power control is performed as in the above-mentioned conventional example, a situation may occur in which the reproduction power control area on the magneto-optical disk cannot be normally reproduced. . For example, there is a case where dust or dirt is present in the reproduction power control area. In this case, since the reproduced amplitude ratio has an abnormal value, erroneous feedback is applied to the reproduction power control circuit. Then, the drive current of the semiconductor laser becomes an abnormal value. For example, there is a danger that the recorded data is erased due to an excessively high reproducing power, or the semiconductor laser is destroyed in the worst case.

As a method for solving this problem, the following known examples are considered. In Japanese Patent Application Laid-Open No. 3-1333, in an optical information reproducing apparatus that detects the amount of light reflected from an optical recording medium with a photodetector and controls the output of a semiconductor laser based on the detected amount, the detected amount is continuously increased. There is a method of fixing the output of the semiconductor laser when it becomes lower than a predetermined value. According to this method, when there is dust or dirt on the optical recording medium, the amount of reflected light is reduced and the reproduction power is fixed.

However, in a situation where the reproduction power control area cannot be reproduced normally, the amount of reflected light does not always decrease. For example, if there is a pinhole in a part of the magnetic layer of the magneto-optical disk, the amount of reflected light increases, and the reproduced magneto-optical signal may become abnormal. In such a case, in the above method, the reproduction power is controlled based on the abnormal reproduction signal.

[0010] An object of the present invention is to detect a cause of a state where the amplitude ratio cannot be normally detected, and fix the reproduction power to the value at that time. An object of the present invention is to provide a reproduction light amount control device in an optical storage device that does not have a risk of erasing data or destroying a semiconductor laser.

[0011]

According to a first aspect of the present invention, there is provided a reproduction light amount control device for an optical storage device, wherein an aperture smaller than a light spot diameter of an irradiated light beam is generated in a reproduction layer to record from a recording layer. In a reproduction light amount control device in an optical storage device that controls a reproduction power by detecting a reproduction signal from a reproduction power control mark recorded on an optical recording medium that transfers and reproduces information, Control signal abnormality detection means for detecting a state in which a reproduction signal cannot be reproduced normally, and reproduction power fixing means for fixing reproduction power when the control signal abnormality detection means detects a state in which reproduction cannot be performed normally. It is characterized by the following.

According to a second aspect of the present invention, there is provided a reproduction light amount control device for an optical storage device, wherein the control signal abnormality detecting means is configured to detect the reproduction power control mark and a predetermined value. A state in which normal reproduction cannot be performed by matching with the reproduction power control pattern.

According to a third aspect of the present invention, there is provided a reproduction light amount control device for an optical storage device, wherein the control signal abnormality detecting means includes an optical pickup for accessing a target track. Until the tracking state is detected again, a state where normal reproduction cannot be performed is detected.

According to a fourth aspect of the present invention, there is provided a reproducing light amount control device for an optical storage device, wherein the control signal abnormality detecting means detects a signal from the reproducing power control mark. A state in which the clock synchronized with the reproduction signal is not normally synchronized in phase with the reproduction signal from the reproduction power control mark is detected, thereby detecting a state in which the reproduction cannot be normally performed.

According to a fifth aspect of the present invention, in the reproduction light amount control device for an optical storage device, the reproduction power fixing means may be arranged such that the control signal abnormality detection means is normally operated. The reproduction power is fixed by retaining the reproduction power value immediately before detecting the state in which reproduction cannot be performed.

[0016]

(Embodiment 1) Embodiment 1 of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram in a case where the present invention is applied to a magnetic super-resolution magneto-optical disk reproducing device. However, portions having the same functions as those of the conventional device shown in FIG. 8 are denoted by the same reference numerals and description thereof is omitted. The structure of the magneto-optical disk 1 is the same as that shown in FIG.

Referring to FIG. 1, the reproducing apparatus further includes a data pattern verifying circuit 10 and a reproducing power fixing circuit 11 as compared with the conventional apparatus. The data pattern verification circuit 10 inputs a binary data pattern output from the data reproduction circuit 7 in response to a reproduction signal of the reproduction power control area 102, and the pattern is used as a reproduction power control pattern (short mark or short mark). (Repeated pattern of long mark), and as a result of the verification, if they match, outputs '1' as a match signal,
If they do not match, '0' is output as a mismatch signal. Here, the determination as to whether or not they match is made by outputting a match signal only when all the binarized data corresponding to the playback signal in the playback power control area 102 completely match the playback power control pattern. However, if the number of mismatched bits is about several bits, it is considered that there will be no problem with the reproduction power control. A mismatch signal may be output only when there is the above mismatch bit.

The read power fixing circuit 11 receives the output of the data pattern verifying circuit 10 and drives the semiconductor laser 2 by the drive current output from the read power control circuit 9 when the match signal '1' is input. On the other hand, when the mismatch signal '0' is input, the semiconductor laser 2 is driven by a predetermined fixed current value. Here, it is assumed that the fixed current value is not a predetermined value, but the current value of the previous reproduction power is stored and that value is used.

FIG. 2 is a time chart showing a reproduction power control state when the sector 200 having a defect in the reproduction power control area and the sector 300 having no defect are reproduced. FIG.
(A) shows an area for two sectors to be reproduced. The reproduction power control area 202 of the sector 200 includes a defect due to dust or dirt, and the reproduction power control area 302 of the sector 300 includes a defect. It is not assumed. FIG. 2B shows the reproduced binary data, and FIG.
2 shows an output of the data pattern verification circuit 10, and FIG. 2D shows a drive current for driving the semiconductor laser 2 by the reproduction power fixing circuit 11.

When the sector synchronization mark 201 is detected at t0 to t1 and the start of the sector 200 is recognized, the reproduction signal of the reproduction power control area 202 is detected by the A / D converter 5 for amplitude ratio detection. It is input to the circuit 6 and the calculation of the average amplitude ratio is started. Data pattern verification circuit 10
Detects that the binarized data pattern reproduced at the time t2 does not match the reproduction power control pattern, and outputs a mismatch signal '0'. On the other hand, since the average amplitude ratio obtained from t1 to t3 is an abnormal value, the drive current value output from the reproduction power control circuit 9 also becomes an abnormal value. However, since the reproduction power fixing circuit 11 inputs the mismatch signal '0' at time t3, the drive current value I1 set in the immediately preceding sector is used without using the abnormal drive current value.
Is held as it is, the semiconductor laser 2 is driven, and the data recording area 203 is reproduced.

Subsequently, the sector synchronization mark 3 is set between t4 and t5.
01 is detected and recognized as being the head of the sector 300, the data pattern verification circuit 10 performs t5 to t6.
Detects that the binarized data obtained by reproducing the reproduction power control area 302 matches the reproduction pattern control pattern, and outputs a coincidence signal '1'. On the other hand, since the normal reproduction signal of the reproduction power control area 302 is input to the amplitude ratio detection circuit 6, the optimum drive current value I2 is output from the reproduction power control circuit 9. Since the read power fixing circuit 11 receives the coincidence signal '1' at the time t6, the semiconductor laser 2 is driven by the drive current value I2 and the data recording area 303 is reproduced.

As described above, when it is detected that the binary data pattern obtained by reproducing the reproduction power control area does not match the reproduction power control pattern, the semiconductor laser is driven by using a predetermined driving current value. With this configuration, even when the reproduction power control area cannot be reproduced normally due to dust or dirt on the disk, the drive current of the semiconductor laser is set to an abnormal value to erase recorded data, It is possible to eliminate the risk of destruction.

Further, without setting the predetermined drive current value to a fixed value,
By adopting a configuration using the value at the time of setting the previous reproduction power, even when the reproduction power cannot be controlled, it is possible to bring the power closer to the optimum power.

(Embodiment 2) Embodiment 2 of the present invention will be described with reference to the drawings. FIG. 3 is a configuration diagram when the present invention is applied to a magnetic super-resolution magneto-optical disc reproducing apparatus. However, portions having the same functions as those of the conventional device shown in FIG. 8 are denoted by the same reference numerals and description thereof is omitted. The structure of the magneto-optical disk 1 is the same as that shown in FIG.

In FIG. 3, the reproducing apparatus further includes an access state detecting circuit 12 and a reproducing power fixing circuit 11 as compared with the conventional apparatus. The access state detection circuit 12 monitors the state of the optical head including the semiconductor laser 2 and the photodiode 3, and when the optical head is in a tracking state following a track on the magneto-optical disk 1, a non-access state signal '1'. And outputs an access state signal '0' during a period from the time when the optical head enters the non-tracking state to move to the target track to the time when the movement is completed and returns to the tracking state.

The reproduction power fixing circuit 11 has the same function as that of the first embodiment, and the description is omitted.

FIG. 4 is a time chart showing a reproduction power control state when an access operation is performed during reproduction. FIG. 4A shows an area of a sector to be reproduced. Access is started during reproduction of the reproduction power control area 402 of the sector 400, and after the access is completed, the sector 5 is read.
00 is played first. 4B shows a reproduction signal, FIG. 4C shows an output of the access state detection circuit 12,
FIG. 4D shows that the reproduction power fixing circuit 11 is the semiconductor laser 2.
Are respectively shown.

At t10 to t11, the sector synchronization mark 401
Is detected and the start of the sector 400 is recognized, the reproduction signal from the reproduction power control area 402 becomes A
The signal is input to the amplitude ratio detection circuit 6 via the / D converter 5, and the calculation of the average amplitude ratio is started. When access is started at t12, the access state detection circuit 12 outputs an access state signal '0'. On the other hand, a normal reproduction signal is not input to the amplitude ratio detection circuit 6 since the access state is from t12 to t14, and the average amplitude ratio obtained from t11 to t13 has an abnormal value. Therefore, the drive current value output from the reproduction power control circuit 9 also becomes an abnormal value. However, since the read power fixing circuit 11 inputs the access state signal '0' at the time t12, the drive current value I10 set in the immediately preceding sector is held without using this abnormal drive current value. The semiconductor laser 2 is driven.

When the access is completed at time t14, the access state detection circuit 12 outputs the non-access state signal '1'. When the sector synchronization mark 501 is detected at t15 to t16 and recognized as the head of the sector 500, the average amplitude ratio is obtained from the reproduction signal of the reproduction power control area 502 at t16 to t17. Based on this, the reproduction power control circuit 9 outputs the drive current value I11. The read power fixing circuit 11 receives the non-access state signal '1' at time t14, and drives the semiconductor laser 2 with this drive current value I11 to read the data recording area 503.

As described above, the period from the start of access to the completion thereof is determined based on an abnormal reproduction signal during access by driving the semiconductor laser using a predetermined drive current value. By driving the semiconductor laser with the abnormal driving current value thus obtained, it is possible to eliminate the danger of erasing recorded data or destroying the semiconductor laser.

(Embodiment 3) Embodiment 3 of the present invention will be described with reference to the drawings. FIG. 5 is a configuration diagram in the case where the present invention is applied to a magnetic super-resolution magneto-optical disk reproducing device. However, portions having the same functions as those of the conventional device shown in FIG. 8 are denoted by the same reference numerals and description thereof is omitted. The structure of the magneto-optical disk 1 is the same as that shown in FIG.

Referring to FIG. 5, the reproducing apparatus further includes an unlock detecting circuit 13 and a reproducing power fixing circuit 11 as compared with the conventional apparatus. Unlock detection circuit 1
3 outputs a lock signal "1" when the PLL of the clock generation circuit 4 is in the locked state during reproduction of the reproduction power control area, and outputs an unlock signal "0" when the PLL includes the unlocked state. 'Is output.

Since the reproduction power fixing circuit 11 has the same function as that of the first embodiment, the description is omitted.

FIG. 6 is a time chart showing a reproduction power control state when the sectors 600 and 700 are reproduced. FIG. 6 (a) shows an area for two sectors to be reproduced. It is assumed that the PLL of the clock generation circuit 4 is unlocked during the reproduction of the reproduction power control area 602 of the sector 600 and becomes unlocked. I do. This unlocked state is to return to the locked state by the time the sector 700 is reproduced. FIG. 6B shows the P of the clock generation circuit 4.
LL lock state, FIG. 6C shows unlock detection circuit 1
6 (d) shows the driving current for driving the semiconductor laser 2 by the reproduction power fixing circuit 11 respectively.

From t20 to t21, the sector synchronization mark 601
Is detected and it is recognized that it is the beginning of the sector 600, the reproduction signal from the reproduction power control area 602 is input to the amplitude ratio detection circuit 6 via the A / D converter 5 from time t21, The calculation of the average amplitude ratio is started. t22
When the PLL of the clock generation circuit 4 is unlocked and becomes unlocked, the unlock detection circuit 13 outputs an unlock signal '0'. On the other hand, during the period from t22 to t23, since a normal reproduction signal is not input to the amplitude ratio
The average amplitude ratio obtained from t23 is an abnormal value.
Here, FIG. 7 shows a short mark pattern (2Tc: T) when the PLL is locked and unlocked.
c indicates the A / D conversion sampling points of the reproduced signal having the channel bit length) and the average amplitude value obtained from those sampling points. If PLL as shown in FIGS. 7 (a) is in a locked state, since the upper and lower peak point of the reproduction signal of a short mark pattern is correctly converted A / D by a clock, the average value V _2T obtained accurately short mark Of the amplitude. On the other hand, when the PLL is in the unlocked state as shown in FIG. 7B, the reproduced signal of the short mark pattern is out of phase with the clock, so that the average value V _2T ′ of the A / D converted value has the correct amplitude. Not a value. When the PLL is unlocked during the reproduction of the reproduction power control area as described above, the calculated average amplitude ratio becomes an abnormal value, so that the drive current value output from the reproduction power control circuit 9 also becomes an abnormal value.

However, at time t23, the reproducing power fixing circuit 11 inputs the unlock signal "0", so that the abnormal driving current value is not used and the driving current value I20 set in the immediately preceding sector is used as it is. The semiconductor laser 2 is driven while being held, and the data recording area 603 is reproduced.

After the PLL returns at time t24 and returns to the locked state, from time t25 to time t26 the sector synchronization mark 7
When 01 is detected and it is recognized that it is the head of the sector 700, the unlock detection circuit 13 temporarily changes the output to the lock signal '1'. Since the PLL has been in the locked state from t26 to t27, the reproduction signal in the reproduction power control area 702 is A / D converted by a normal clock and input to the amplitude ratio detection circuit 6, and the reproduction power control circuit 9 An optimum drive current value I21 is output based on the average amplitude ratio. On the other hand, the output of the unlock detection circuit 13 remains at the lock signal '1'.

At time t27, the read power fixing circuit 11 receives the lock signal '1', so that the drive current value I2
1. The semiconductor laser 2 is driven by the
Play 03.

As described above, when it is detected that the PLL of the clock generation circuit is unlocked and becomes unlocked during the reproduction of the reproduction power control area, the semiconductor laser is driven by using the predetermined drive current value. By having a configuration that
The playback signal in the playback power control area is
Even if the / D conversion is performed, the semiconductor laser can be driven by an abnormal drive current value to eliminate the danger of erasing recorded data and destroying the semiconductor laser.

In each of the above embodiments, an example of a magneto-optical disk reproducing apparatus has been described.

[0041]

According to the reproducing light amount control device of the present invention, the abnormal reproduction power is fixed by detecting the factor that causes the reproduction signal from the reproduction power control mark to be in a state where the reproduction signal cannot be normally reproduced. It is possible to eliminate the danger of erasing recorded data or destroying a semiconductor laser by abnormal reproduction power control obtained from a reproduction signal.

According to the reproduction light amount control device of the present invention, the reproduction power is fixed by matching the reproduction pattern of the reproduction power control mark with the predetermined reproduction power control pattern, thereby enabling the reproduction power on the optical recording medium to be fixed. Even if the reproduction signal from the reproduction power control mark becomes abnormal due to dust or dirt, it is possible to eliminate the danger of erasing recorded data or destroying the semiconductor laser.

According to the reproduction light amount control device of the third aspect, the reproduction power is fixed during the period from the start of the access to the completion of the access, so that the abnormal light obtained based on the abnormal reproduction signal being accessed is abnormal. By controlling the reproduction power, it is possible to eliminate the danger of erasing recorded data and destroying the semiconductor laser.

According to the reproducing light quantity control device of the present invention, the reproducing power is fixed when the reproducing clock is not normally synchronized in phase with the reproducing signal from the reproducing power control mark, so that the reproducing clock is obtained by the abnormal clock. The abnormal reproduction power control makes it possible to eliminate the danger of erasing recorded data and destroying the semiconductor laser.

According to the reproducing light amount control apparatus of the fifth aspect, the reproducing power is fixed by holding the value at the time of setting the previous reproducing power, so that even if the reproducing power cannot be controlled, Reproduction can be performed in a state close to the optimum reproduction power.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a super-resolution magneto-optical disk reproducing apparatus according to a first embodiment.

FIG. 2 is a time chart for explaining the operation of the disc reproducing apparatus shown in FIG. 1;

FIG. 3 is a configuration diagram of a super-resolution magneto-optical disk reproducing apparatus according to a second embodiment.

FIG. 4 is a time chart for explaining the operation of the disc reproducing apparatus shown in FIG. 2;

FIG. 5 is a configuration diagram of a super-resolution magneto-optical disk reproducing device according to a third embodiment.

FIG. 6 is a time chart for explaining the operation of the disc reproducing apparatus shown in FIG. 3;

FIG. 7 is a schematic diagram showing a relationship between a clock state and an A / D sampling point.

FIG. 8 is a configuration diagram of a conventional reproduction light amount control device.

FIG. 9 is a schematic diagram illustrating a sector structure of the magneto-optical disk in FIG.

[Explanation of symbols]

 Reference Signs List 1 magneto-optical disk 2 semiconductor laser 3 photodiode 4 clock generation circuit 5 A / D converter 6 amplitude ratio detection circuit 7 data reproduction circuit 8 differential amplifier 9 reproduction power control circuit 10 data pattern verification circuit 11 reproduction power fixing circuit 12 access State detection circuit 13 Unlock detection circuit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5D075 BB04 CC11 CC24 CD03 CD11 CE04 5D090 CC04 CC16 CC18 DD03 DD05 EE13 FF02 FF25 FF38 HH01 JJ03 KK03

Claims (5)

[Claims] 1. A reproducing power control mark recorded on an optical recording medium for transferring and reproducing recorded information from a recording layer by generating an aperture smaller than a light spot diameter of an irradiated light beam in the reproducing layer. In a reproduction light amount control device in an optical storage device that controls a reproduction power by detecting a reproduction signal from a control signal abnormality detection unit that detects a state in which a reproduction signal from the reproduction power control mark cannot be normally reproduced, A reproduction power fixing unit for fixing a reproduction power when the control signal abnormality detection unit detects a state in which reproduction cannot be performed normally; 2. The apparatus according to claim 1, wherein the control signal abnormality detecting means detects a state in which normal reproduction cannot be performed by matching the reproduction power control mark with a predetermined reproduction power control pattern. A reproduction light amount control device in the optical storage device of FIG. 3. The optical device according to claim 1, wherein the control signal abnormality detection means detects a state in which the optical pickup cannot access the target track and detects a tracking state again, thereby preventing normal reproduction. A reproduction light amount control device in a storage device. 4. The control signal abnormality detection means detects a state in which a clock synchronized with a reproduction signal from the reproduction power control mark is not normally synchronized in phase with a reproduction signal from the reproduction power control mark. 2. A reproduction light amount control device in an optical storage device according to claim 1, wherein a state in which reproduction cannot be performed normally is detected by performing the operation. 5. The reproduction power fixing unit fixes the reproduction power by holding a reproduction power value immediately before the control signal abnormality detection unit detects a state in which normal reproduction cannot be performed. 2. A reproduction light amount control device in the optical storage device according to 1.