JP2016110673A - Disc apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disc apparatus capable of reducing the power consumption of a light-emitting element and increasing the lifetime of the light-emitting element.SOLUTION: A disc apparatus 100 comprises: an optical pickup 2 including an LD emitting a laser beam, and a PD receiving reflectance formed by the laser beam reflected on a disc media A and converting the reflectance into an electric signal having an amplitude corresponding to a light amount of the reflectance; an LD driving circuit 7 supplying a driving current for the LD to the optical pickup 2; a signal detection circuit 3 detecting a comparison signal from the electric signal; and a determination unit 6 that compares the amplitude of the comparison signal to an amplitude reference value, and instructs the LD driving circuit 7 to decrease the driving current and causes the amplitude of the comparison signal to be closer to the amplitude reference value when the amplitude of the comparison signal is larger than the amplitude reference value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a disk device for reproducing information recorded on a disk medium such as an optical disk or a magneto-optical disk.

  2. Description of the Related Art Conventionally, a disc device has been developed that reproduces information such as video or audio recorded on an optical disc such as a CD (Compact Disc), a DVD (Digital Versatile Disc), or a BD (Blu-ray Disc, registered trademark). The disk device receives a light emitting element such as an LD (Laser Diode) that emits laser light to an optical disk and the reflected light reflected by the optical disk, and converts it into an electrical signal having an amplitude corresponding to the amount of reflected light. A light receiving circuit.

  The reflectivity of the laser beam of the optical disk varies from one optical disk to another due to manufacturing errors. In general, since the disk device sets the emitted light amount of the LD to a constant light amount, the light amount of reflected light differs for each individual optical disk. However, in order to normally read the information recorded on the optical disc, it is required that the amplitude of the electric signal obtained by converting the reflected light is a certain amplitude. Therefore, in the conventional disk device, the amplitude of the electric signal obtained by converting the reflected light reflected by each optical disk is brought close to a constant amplitude by changing the gain of the amplifier provided in the light receiving circuit.

  The conventional disk device has a problem that it is difficult to reduce the current consumption of the LD or to extend the life of the LD because the emitted light amount of the LD is set to a constant light amount. On the other hand, Patent Document 1 and Patent Document 2 disclose disk devices that change the amount of light emitted from an LD.

  In the disc reproducing apparatus of Patent Document 1, the amount of light emitted from the LD is changed for each media area of the optical disc. The disk reproducing device of Patent Document 1 reduces the current consumption of the LD, particularly by reducing the amount of light emitted from the LD with respect to the prepit area.

  The disk recording apparatus of Patent Document 2 controls the amount of light emitted from a recording LD according to the amplitude of a TE (Tracking Error) signal acquired from an electric signal obtained by converting reflected light. The disc recording apparatus of Patent Document 2 emits light from an LD when the ratio (B1 / A1) of the maximum value (B1) of the TE signal after control and the maximum value (A1) of the TE signal before control exceeds a threshold value. By suppressing this, the recording quality of the optical disc is stabilized.

JP 2001-297464 A JP 2002-140818 A

  The disk reproducing apparatus of Patent Document 1 does not consider the reflectance that differs for each optical disk. For example, when the reflectivity of the optical disk is higher than the standard value, it is considered preferable to reduce the amount of light emitted from the LD even in a region outside the prepit area such as a recordable area. However, the disk reproducing apparatus of Patent Document 1 has a problem that wasteful power is consumed by the LD or the life of the LD is shortened because the emitted light quantity of the LD is not lowered in such a case.

  The disc recording apparatus of Patent Document 2 controls the amount of emitted light from the LD so that the recording quality of the optical disc is stable, and does not control the amount of emitted light from the LD for the purpose of reducing the power consumption of the LD. For this reason, there existed a subject which cannot reduce the power consumption of LD or lengthen the lifetime of LD.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a disk device capable of reducing the power consumption of a light emitting element and extending the life of the light emitting element. .

  The disk device of the present invention includes a light emitting element that emits laser light and a light receiving element that receives reflected light reflected by the disk medium and converts the light into an electric signal having an amplitude corresponding to the amount of reflected light. An optical pickup, a drive circuit for supplying a drive current of a light emitting element to the optical pickup, a signal detection circuit for detecting a comparison signal from an electrical signal, and comparing the amplitude of the comparison signal with an amplitude reference value, A determination unit that instructs the drive circuit to decrease the drive current when the amplitude is larger than the amplitude reference value, and causes the amplitude of the comparison signal to approach the amplitude reference value;

  Since the disk device of the present invention is configured as described above, when the reflectivity of the disk medium is high, the amount of light emitted from the light emitting element is reduced, the power consumption of the light emitting element is reduced, and the life of the light emitting element is extended. can do.

It is a block diagram which shows the principal part of the disk apparatus of Embodiment 1 of this invention. 3 is a flowchart showing the operation of the disk device according to the first embodiment of the present invention. It is a flowchart which shows the other operation | movement of the disk apparatus of Embodiment 1 of this invention. It is a characteristic view which shows the emitted light quantity with respect to the drive current of general LD. It is explanatory drawing which shows an example of the waveform of the signal for data of Embodiment 1 of this invention. It is explanatory drawing which shows an example of the waveform of the signal for servos of Embodiment 1 of this invention. It is a block diagram which shows the principal part of the disk apparatus of Embodiment 2 of this invention. It is a flowchart which shows operation | movement of the disk apparatus of Embodiment 2 of this invention. It is a flowchart which shows the other operation | movement of the disk apparatus of Embodiment 2 of this invention. It is a block diagram which shows the principal part of the disk apparatus of Embodiment 3 of this invention. It is a flowchart which shows operation | movement of the disk apparatus of Embodiment 3 of this invention. It is a flowchart which shows the other operation | movement of the disc apparatus of Embodiment 3 of this invention.

Embodiment 1 FIG.
FIG. 1 shows a block diagram of a main part of the disk device of the first embodiment. A disk device 100 according to the first embodiment will be described with reference to FIG.
The disk medium A is, for example, an optical disk such as a CD, DVD, or BD inserted into a housing (not shown) of the disk device 100 from an insertion opening (not shown). Information such as video or audio is recorded on the disk medium A.

  The spindle motor 1 is a motor that rotates the disk medium A.

  The optical pickup 2 has a light emitting element that emits laser light to the disk medium A. The optical pickup 2 has a light receiving element that receives the reflected light reflected by the disk medium A and converts it into an electric signal having an amplitude corresponding to the amount of the reflected light. The optical pickup 2 outputs an electrical signal converted by the light receiving element to the signal detection circuit 3.

  The light emitting element of the optical pickup 2 is composed of, for example, an LD. The light receiving element of the optical pickup 2 is composed of, for example, a PD (Photodiode). Hereinafter, an example in which the light emitting element of the optical pickup 2 is configured by an LD and the light receiving element is configured by a PD will be described. The LD receives the drive current supplied from the LD drive circuit 7 and emits laser light. The greater the drive current, the greater the amount of emitted laser light.

  The signal detection circuit 3 detects a signal (hereinafter referred to as “data signal”) indicating information read from the disk medium A such as an RF (Radio Frequency) signal from the electrical signal output from the optical pickup 2. The signal detection circuit 3 detects signals (hereinafter referred to as “servo signals”) used for servo control of the optical pickup 2 such as an FE (Focus Error) signal and a TE signal from the electrical signal output from the optical pickup 2. Is.

  The signal detection circuit 3 is configured to output the detected data signal to the reproduction processing unit 4. In addition, the signal detection circuit 3 outputs the detected servo signal to the servo processing unit 5. Furthermore, the signal detection circuit 3 outputs at least one signal included in the detected data signal and servo signal to the determination unit 6 as a comparison signal.

  The reproduction processing unit 4 converts the data signal output from the signal detection circuit 3 into a video signal or an audio signal. The video signal converted by the reproduction processing unit 4 is output to a display unit (not shown) and reproduced as a video. The audio signal converted by the reproduction processing unit 4 is output to a speaker (not shown) and reproduced as audio.

  The servo processing unit 5 causes the servo mechanism 9 to perform servo control of the optical pickup 2 using the servo signal output from the signal detection circuit 3. That is, the servo processing unit 5 uses the FE signal output from the signal detection circuit 3 to perform focus pull-in to the servo mechanism 9 so that the laser beam emitted from the LD is focused on the information recording surface of the disk medium A. Let Further, the servo processing unit 5 causes the servo mechanism 9 to perform tracking pull-in so that the laser light emitted from the LD follows the data track of the disk medium A using the TE signal output from the signal detection circuit 3.

  The determination unit 6 compares the amplitude of the comparison signal output from the signal detection circuit 3 with a preset amplitude reference value to determine the magnitude of the comparison signal amplitude and the amplitude reference value. The amplitude reference value to be compared with the RF signal is set to a value approximately equal to the maximum amplitude at which the reproduction processing unit 4 can normally process the RF signal, for example. The amplitude reference value to be compared with the TE signal is set to a value substantially equal to the maximum amplitude at which the servo processing unit 5 can normally process the TE signal, for example. The amplitude reference value to be compared with the FE signal is set to a value substantially equal to the maximum amplitude at which the servo processing unit 5 can normally process the FE signal, for example.

  This amplitude reference value may have a width between the upper limit value and the lower limit value. When the amplitude of the comparison signal exceeds the upper limit value, the determination unit 6 determines that the amplitude of the comparison signal is larger than the amplitude reference value. When the amplitude of the comparison signal is less than the lower limit value, the determination unit 6 determines that the amplitude of the comparison signal is smaller than the amplitude reference value. When the amplitude of the comparison signal is greater than or equal to the lower limit value and less than or equal to the upper limit value, the determination unit 6 determines that the amplitude of the comparison signal is equal to the amplitude reference value.

  If the determination unit 6 determines that the amplitude of the comparison signal is larger than the amplitude reference value, the determination unit 6 instructs the LD drive circuit 7 that supplies the LD drive current to the optical pickup 2 to reduce the drive current. It has become. If the determination unit 6 determines that the amplitude of the comparison signal is smaller than the amplitude reference value, the determination unit 6 instructs the LD drive circuit 7 to increase the drive current.

  Here, the increase width and decrease width of the drive current per time that the determination unit 6 instructs the LD drive circuit 7 are such that the change width of the amplitude of the comparison signal due to the decrease and increase of the drive current is the upper limit of the amplitude reference value. It is set to a certain width that is narrower than the width between the value and the lower limit value.

  The determination unit 6 does not instruct the LD drive circuit 7 to increase or decrease the drive current when determining that the amplitude of the comparison signal is equal to the amplitude reference value.

  The signal detection circuit 3, the reproduction processing unit 4, the servo processing unit 5, the determination unit 6, and the LD drive circuit 7 are configured by a dedicated integrated circuit, for example. The disk device 100 is configured by the spindle motor 1, the optical pickup 2, the signal detection circuit 3, the reproduction processing unit 4, the servo processing unit 5, the determination unit 6, the LD drive circuit 7 and the servo mechanism 9.

  Next, with reference to the flowchart of FIG. 2, an operation in which the determination unit 6 controls the drive current of the LD using the servo signal will be described. Here, in the initial state, it is assumed that the disc medium A is inserted in the disc device 100 in advance. The servo processing unit 5 causes the servo mechanism 9 to perform focus pull-in using the FE signal output from the signal detection circuit 3. The signal detection circuit 3 outputs the FE signal as a comparison signal to the determination unit 6.

  First, in step ST1, the determination unit 6 receives an input of an FE signal that is a comparison signal.

  Next, in steps ST2 and ST3, the determination unit 6 compares the amplitude of the FE signal with the amplitude reference value, and determines the magnitude of the amplitude of the FE signal and the amplitude reference value.

  If it is determined that the amplitude of the FE signal is larger than the amplitude reference value (step ST2 “YES”), then in step ST4, the determination unit 6 instructs the LD drive circuit 7 to decrease the drive current of the LD.

  On the other hand, if it is determined that the amplitude of the FE signal is smaller than the amplitude reference value (step ST2 “NO” and step ST3 “YES”), then in step ST5, the determination unit 6 causes the LD drive circuit 7 to store the LD. Instruct to increase drive current.

  After the processes of steps ST4 and ST5, the determination unit 6 returns to the process of step ST1. When it is determined that the amplitude of the FE signal is equal to the amplitude reference value (step ST2 “NO” and step ST3 “NO”), the determination unit 6 does not instruct the LD drive circuit 7 to increase or decrease the drive current, The process ends.

  Note that the order of step ST2 and step ST3 may be interchanged.

  Further, when the servo processing unit 5 uses the TE signal to cause the servo mechanism 9 to perform tracking pull-in, the signal detection circuit 3 outputs the TE signal to the determination unit 6 as a comparison signal, and the determination unit 6 outputs the TE signal. Similarly, the drive current of the LD may be controlled using the signal.

  Further, when the disk device 100 is configured to execute focus pull-in and then perform tracking pull-in, the determination unit 6 controls the drive current using the FE signal when the focus is pulled in, and the TE signal during the tracking pull-in. The drive current may be controlled using Alternatively, the determination unit 6 may execute only one of the drive current control using the FE signal and the drive current control using the TE signal.

  Next, with reference to the flowchart of FIG. 3, an operation in which the determination unit 6 controls the drive current of the LD using the data signal will be described. Here, in the initial state, it is assumed that the disc medium A is inserted in the disc device 100 in advance. The disk device 100 has started reproducing information recorded on the disk medium A. The signal detection circuit 3 outputs the RF signal to the determination unit 6 as a comparison signal.

  First, in step ST11, the determination unit 6 receives an input of an RF signal that is a comparison signal.

  Next, in steps ST12 and ST13, the determination unit 6 compares the amplitude of the RF signal with the amplitude reference value, and determines the magnitude of the amplitude of the RF signal and the amplitude reference value.

  When it is determined that the amplitude of the RF signal is larger than the amplitude reference value (step ST12 “YES”), the determination unit 6 executes the process of step ST4 similar to FIG. On the other hand, when it is determined that the amplitude of the RF signal is smaller than the amplitude reference value (step ST12 “NO” and step ST13 “YES”), the determination unit 6 executes the process of step ST5 similar to FIG. When it is determined that the amplitude of the RF signal is equal to the amplitude reference value (step ST12 “NO” and step ST13 “NO”), the determination unit 6 does not instruct the LD drive circuit 7 to increase or decrease the drive current, and the process is performed. finish.

  When the disc device 100 is configured to perform focus pull-in, then perform tracking pull-in, and then start playback of information recorded on the disk medium A, the determination unit 6 outputs an FE signal when the focus is pulled in. The driving current may be controlled using the TE signal at the time of tracking pull-in, and the driving current may be controlled using the RF signal when information reproduction is started. Alternatively, the determination unit 6 controls any one or two of the control of the drive current using the FE signal, the control of the drive current using the TE signal, and the control of the drive current using the RF signal. It is also possible to execute only.

  The determination unit 6 may determine the magnitude between the amplitude of the comparison signal and the amplitude reference value, and may calculate a difference between the amplitude of the comparison signal and the amplitude reference value. In this case, the determination unit 6 sets the increase width and the decrease width of the drive current instructed to the LD drive circuit 7 to a width corresponding to the calculated difference. Thereby, the number of times of repeating the processes of steps ST1 to ST5 in FIG. 2 and the number of times of repeating the processes of steps ST11 to ST13, ST4, ST5 in FIG. 3 are reduced, and the amplitude of the comparison signal can be reduced in a shorter time. Can be approached.

Next, the effect of the disk device 100 will be described with reference to FIGS.
FIG. 4 is a characteristic diagram of the amount of emitted light with respect to a general LD drive current. The LD drive circuit 7 increases or decreases the LD drive current of the optical pickup 2 within a range (for example, a range indicated by an ellipse I in the figure) in which the amount of emitted light increases linearly as the drive current increases. . When the disk medium A is inserted into the disk device 100, the initial value of the LD drive current is set to the value indicated by the point II in the figure.

  FIG. 5 shows an example of the waveform of the RF signal when the LD drive current is set to the initial value. For example, the RF signal is at a high level when the digital data recorded on the disk medium A indicates “1”, and is at a low level when the digital data indicates “0”. In general, the higher the reflectivity of the disk medium A, the larger the reflected light amount with respect to the emitted light amount, and the larger the amplitude of the electrical signal photoelectrically converted by the PD, the larger the RF signal amplitude. Further, the lower the reflectivity of the disk medium A, the smaller the reflected light amount relative to the emitted light amount, and the smaller the amplitude of the electrical signal photoelectrically converted by the PD, the smaller the RF signal amplitude.

  When the disc medium A having a standard reflectance is inserted, the amplitude of the RF signal is equivalent to the amplitude reference value as shown in FIG. When the disc medium A having a reflectance higher than the standard value is inserted, the amplitude of the RF signal becomes larger than the amplitude reference value as shown in FIG. When the disc medium A having a reflectance lower than the standard value is inserted, the amplitude of the RF signal becomes smaller than the amplitude reference value as shown in FIG.

  The disk device 100 according to Embodiment 1 reduces the drive current of the LD when the amplitude of the RF signal is larger than the amplitude reference value. Thereby, when the disk medium A having a high reflectance is inserted, the amplitude of the RF signal can be made closer to the amplitude shown in FIG. 5B from the amplitude shown in FIG. Further, the disk device 100 increases the drive current of the LD when the amplitude of the RF signal is smaller than the amplitude reference value. Thereby, when the disk medium A having a low reflectance is inserted, the amplitude of the RF signal can be made closer to the amplitude shown in FIG. 5B from the amplitude shown in FIG.

  FIG. 6 shows an example of the waveforms of the FE signal and the TE signal when the LD drive current is set to an initial value. The FE signal and the TE signal generally have a sinusoidal waveform. In general, the higher the reflectivity of the disk medium A, the greater the reflected light amount with respect to the emitted light amount, and the larger the amplitude of the electrical signal photoelectrically converted by the PD, the larger the amplitude of the FE signal and TE signal. Further, the lower the reflectivity of the disk medium A, the smaller the reflected light amount relative to the emitted light amount, and the smaller the amplitude of the electrical signal photoelectrically converted by the PD, the smaller the amplitude of the FE signal and TE signal.

  When the disc medium A having the standard reflectivity is inserted, the amplitudes of the FE signal and the TE signal are equal to the amplitude reference value as shown in FIG. When the disc medium A having a reflectance higher than the standard value is inserted, the amplitudes of the FE signal and the TE signal are larger than the amplitude reference value as shown in FIG. When a disc medium A having a reflectance lower than the standard value is inserted, the amplitudes of the FE signal and the TE signal are smaller than the amplitude reference value as shown in FIG.

  The disk device 100 according to the first embodiment decreases the LD drive current when the amplitudes of the FE signal and the TE signal are larger than the amplitude reference value. Thereby, when the disk medium A having a high reflectance is inserted, the amplitude of the FE signal and the TE signal can be made closer to the amplitude shown in FIG. 6B from the amplitude shown in FIG. Further, the disk device 100 increases the drive current of the LD when the amplitude of the data signal is smaller than the amplitude reference value. Thereby, when the disk medium A having a low reflectance is inserted, the amplitudes of the FE signal and the TE signal can be made closer to the amplitude shown in FIG. 6B from the amplitude shown in FIG.

As described above, the disk device 100 according to the first embodiment receives the reflected light reflected by the disk medium A and the LD that emits the laser light, and an electric signal having an amplitude corresponding to the amount of the reflected light. An optical pickup 2 having a PD to be converted into a signal, an LD drive circuit 7 for supplying an LD drive current to the optical pickup 2, a signal detection circuit 3 for detecting a comparison signal from an electric signal, and an amplitude of the comparison signal. A determination unit 6 for comparing the amplitude reference value with the amplitude reference value and instructing the LD drive circuit 7 to reduce the drive current when the amplitude of the comparison signal is larger than the amplitude reference value, and bringing the amplitude of the comparison signal close to the amplitude reference value; Prepare.
When the amplitude of the comparison signal is larger than the amplitude reference value, the LD drive current is decreased so that the amplitude of the comparison signal approaches the amplitude reference value. By reducing the amount of light, the power consumption of the LD can be reduced, and the life of the LD can be extended.

  Further, when the amplitude of the comparison signal is smaller than the amplitude reference value, the determination unit 6 instructs the LD drive circuit 7 to increase the drive current so that the amplitude of the comparison signal approaches the amplitude reference value. As a result, the amplifier of the light receiving circuit is not required, and the disk device 100 can be configured to be small and inexpensive.

The comparison signal is an RF signal indicating information read from the disk medium A. Alternatively, the comparison signal is an FE signal or a TE signal used for servo control of the optical pickup 2.
When a dedicated signal different from the RF signal, the FE signal, or the TE signal is used as the comparison signal, it is necessary to add a light receiving element, a splitter, a prism, or the like for acquiring the comparison signal to the light receiving circuit. On the other hand, since it is not necessary to add a light receiving element, a splitter, a prism, or the like by using the RF signal, the FE signal, or the TE signal as a comparison signal, it is possible to avoid an increase in size and cost of the disk storage 100. it can.

  The disk device 100 is not limited to a disk reproducing device that reproduces information recorded on a disk medium. A disc playback / recording apparatus to which a function of recording information on a disc medium is added may be used.

  Further, the disk medium from which the disk device 100 reproduces information is not limited to an optical disk such as a CD, DVD, or BD. Any information recording surface may be used as long as it reads information by irradiating laser light onto the information recording surface, and a magneto-optical disk such as MD (Mini Disc, registered trademark) may be used.

Embodiment 2. FIG.
FIG. 7 shows a block diagram of a main part of the disk device of the second embodiment. With reference to FIG. 7, a disk device 100a in which the power consumption of the LD is further reduced by providing the head amplifier 8 will be described. In FIG. 7, the same components as those in the block diagram of the first embodiment shown in FIG.

  The head amplifier 8 is an amplifier that amplifies the amplitude of the electrical signal output from the optical pickup 2. The signal detection circuit 3 detects a data signal and a servo signal from the electric signal amplified by the head amplifier 8.

  Here, the gain of the head amplifier 8 is such that the amplitude of the comparison signal when the disk medium A having a reflectance lower than the standard value reflects the laser light having the initial output light amount is equal to the amplitude reference value. It is fixed as high as possible.

  The determination unit 6a compares the amplitude of the comparison signal output from the signal detection circuit 3 with the amplitude reference value to determine whether or not the amplitude of the comparison signal is larger than the amplitude reference value. When determining that the amplitude of the comparison signal is larger than the amplitude reference value, the determining unit 6a instructs the LD driving circuit 7 to decrease the LD driving current. If the determination unit 6a determines that the amplitude of the comparison signal is not greater than the amplitude reference value, the determination unit 6a does not instruct the LD drive circuit 7 to increase or decrease the drive current.

  Next, with reference to the flowchart of FIG. 8, the operation in which the determination unit 6a controls the drive current of the LD using the servo signal will be described. In FIG. 8, the same steps as those in the flowchart of the first embodiment shown in FIG.

  First, the determination part 6a performs the process of step ST1, ST2 similar to Embodiment 1. FIG.

  When it is determined that the amplitude of the FE signal is larger than the amplitude reference value (step ST2 “YES”), the determination unit 6a executes the process of step ST4 similar to that of the first embodiment.

  If it is determined that the amplitude of the FE signal is not greater than the amplitude reference value (step ST2 “NO”), the determination unit 6a does not instruct the LD drive circuit 7 to increase or decrease the drive current, and ends the process.

  Since the gain of the head amplifier 8 is fixed to a sufficiently high value, the disk medium A having a reflectance lower than the standard value is inserted in a state where the LD drive current is set to the initial value. However, the amplitude of the FE signal becomes equal to the amplitude reference value without changing the drive current of the LD. In addition, when the disc medium A having the standard reflectivity or the disc medium A having the reflectivity higher than the standard value is inserted, the amplitude of the FE signal becomes larger than the amplitude reference value, so that the LD drive current is reduced. The amplitude of the FE signal can be brought close to the amplitude reference value only by processing.

  Note that the determination unit 6a may control the drive current of the LD using the TE signal at the time of tracking pull-in.

  Next, with reference to the flowchart of FIG. 9, an operation in which the determination unit 6a controls the LD drive current using the data signal will be described. In FIG. 9, the same steps as those in the flowchart of the first embodiment shown in FIG.

  First, the determination part 6a performs the process of step ST11, ST12 similar to Embodiment 1. FIG.

  When it is determined that the amplitude of the RF signal is larger than the amplitude reference value (“YES” in step ST12), the determination unit 6a executes the process of step ST4 similar to FIG.

  If it is determined that the amplitude of the RF signal is not greater than the amplitude reference value (step ST2 “NO”), the determination unit 6a does not instruct the LD drive circuit 7 to increase or decrease the drive current, and ends the process.

  Since the gain of the head amplifier 8 is fixed to a sufficiently high value, the disk medium A having a reflectance lower than the standard value is inserted in a state where the LD drive current is set to the initial value. However, the amplitude of the RF signal becomes equal to the amplitude reference value without changing the drive current of the LD. In addition, when the disc medium A having a standard reflectivity or the disc media A having a reflectivity higher than the standard value is inserted, the amplitude of the RF signal becomes larger than the amplitude reference value, so that the drive current of the LD is reduced. The amplitude of the RF signal can be brought close to the amplitude reference value only by processing.

As described above, the disk device 100a according to the second embodiment compares the amplitude of the comparison signal with the amplitude reference value, and reduces the drive current when the amplitude of the comparison signal is larger than the amplitude reference value. 7 has a determination unit 6a that instructs the amplitude of the comparison signal to approach the amplitude reference value. The disk device 100a also has a head amplifier 8 that amplifies the amplitude of the electric signal. The gain of the head amplifier 8 is such that the amplitude of the comparison signal when the disk medium A having a reflectivity lower than the standard value reflects the laser light having the initial output light quantity is equal to the amplitude reference value. It is fixed at a high value.
As a result, the amplitude of the comparison signal can be brought close to the amplitude reference value by only changing the LD drive current from the initial value or reducing it. That is, the process of increasing the emitted light quantity of the LD is not required, the power consumption of the LD can be further suppressed, and the life of the LD can be further extended.

Embodiment 3 FIG.
FIG. 10 is a block diagram of the main part of the disk device according to the third embodiment. With reference to FIG. 10, a disk device 100b in which the gain of the head amplifier 8 is made variable will be described. In FIG. 10, the same components as those in the block diagram of the second embodiment shown in FIG.

  The determination unit 6b compares the amplitude of the comparison signal output from the signal detection circuit 3 with the amplitude reference value, and determines the magnitude of the amplitude of the comparison signal and the amplitude reference value. When the determination unit 6b determines that the amplitude of the comparison signal is larger than the amplitude reference value, the determination unit 6b instructs the LD drive circuit 7 to decrease the drive current of the LD. Further, when the determination unit 6b determines that the amplitude of the comparison signal is smaller than the amplitude reference value, the determination unit 6b instructs the head amplifier 8 to increase the gain.

  Here, the decrease width of the drive current per time instructed by the determination unit 6b to the LD drive circuit 7 and the increase width of the gain per time instructed to the head amplifier 8 are compared by a decrease in the drive current or an increase in the gain. The change width of the amplitude of the signal for use is set to a constant width that is narrower than the width between the upper limit value and the lower limit value of the amplitude reference value.

  When determining that the amplitude of the comparison signal is equal to the amplitude reference value, the determination unit 6b does not instruct the LD drive circuit 7 to increase or decrease the drive current, and does not instruct the head amplifier 8 to increase or decrease the gain. It is like that.

  Next, an operation in which the determination unit 6b controls the drive current of the LD and the gain of the head amplifier 8 using the servo signal will be described with reference to the flowchart of FIG. In FIG. 11, the same steps as those in the flowchart of the first embodiment shown in FIG.

  First, the determination part 6b performs the process of step ST1-ST3 similar to Embodiment 1. FIG.

  When it is determined that the amplitude of the FE signal is larger than the amplitude reference value (step ST2 “YES”), the determination unit 6b executes the process of step ST4 similar to that of the first embodiment.

  On the other hand, if it is determined that the amplitude of the FE signal is smaller than the amplitude reference value (step ST2 “NO” and step ST3 “YES”), then in step ST21, the determination unit 6b increases the gain of the head amplifier 8. Instruct.

  After the processes of steps ST4 and ST21, the determination unit 6b returns to the process of step ST1. When it is determined that the amplitude of the FE signal is equal to the amplitude reference value (step ST2 “NO” and step ST3 “NO”), the determination unit 6b does not instruct the LD drive circuit 7 to increase or decrease the drive current, Further, the process is terminated without instructing the head amplifier 8 to increase or decrease the gain.

  Note that the determination unit 6b may similarly control the drive current of the LD and the gain of the head amplifier 8 using the TE signal at the time of tracking pull-in.

  Next, an operation in which the determination unit 6b controls the LD drive current and the gain of the head amplifier 8 using the data signal will be described with reference to the flowchart of FIG. In FIG. 12, the same steps as those in the flowchart of the first embodiment shown in FIG.

  First, the determination part 6b performs the process of step ST11-ST13 similar to Embodiment 1. FIG.

  When it is determined that the amplitude of the RF signal is greater than the amplitude reference value (step ST12 “YES”), the determination unit 6b executes the process of step ST4 similar to that of the first embodiment.

  On the other hand, when it is determined that the amplitude of the RF signal is smaller than the amplitude reference value (step ST12 “NO” and step ST13 “YES”), the determination unit 6b executes the process of step ST21 similar to FIG. When it is determined that the amplitude of the RF signal is equal to the amplitude reference value (step ST12 “NO” and step ST3 “NO”), the determination unit 6b does not instruct the LD drive circuit 7 to increase or decrease the drive current, Further, the process is terminated without instructing the head amplifier 8 to increase or decrease the gain.

As described above, the disk device 100b according to the third embodiment compares the amplitude of the comparison signal with the amplitude reference value, and reduces the drive current when the amplitude of the comparison signal is larger than the amplitude reference value. 7 is provided to determine that the amplitude of the comparison signal is close to the amplitude reference value. The disk device 100b also includes a head amplifier 8 that amplifies the amplitude of the electric signal. When the amplitude of the comparison signal is smaller than the amplitude reference value, the determination unit 6b instructs the head amplifier 8 to increase the gain so that the amplitude of the comparison signal approaches the amplitude reference value.
As a result, the amplitude of the comparison signal can be brought close to the amplitude reference value without increasing the LD drive current, so that the power consumption of the LD can be further suppressed and the life of the LD can be further increased. it can.

  Note that, similarly to the first embodiment, the determination unit 6b determines the magnitude between the amplitude of the comparison signal and the amplitude reference value, and calculates the difference between the amplitude of the comparison signal and the amplitude reference value. good. The determination unit 6b sets the drive current decrease range instructed to the LD drive circuit 7 and the gain increase range instructed to the head amplifier 8 to a width corresponding to the calculated difference. Accordingly, the number of times of repeating the processes of steps ST1 to ST4 and ST21 of FIG. 11 and the number of times of repeating the processes of steps ST11 to ST13, ST4 and ST21 of FIG. 12 are reduced, and the amplitude of the comparison signal is amplified in a shorter time. It can be close to the reference value.

  The determination unit 6b may be configured such that the upper limit value of the gain of the head amplifier 8 is set and the lower limit value of the LD drive current is set. Thereby, for example, the reflectivity differs for each part of the disk medium A, and the state where the amplitude of the comparison signal is higher and lower than the amplitude reference value is switched a plurality of times to increase the gain of the head amplifier 8 and the LD. Even when the process of reducing the drive current is alternately repeated, it is possible to prevent the LD from being turned off when the drive current is lowered too much or the head amplifier 8 to oscillate when the gain is raised too much. .

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  DESCRIPTION OF SYMBOLS 1 Spindle motor, 2 Optical pick-up, 3 Signal detection circuit, 4 Reproduction processing part, 5 Servo processing part, 6, 6a, 6b Judgment part, 7 LD drive circuit, 8 Head amplifier, 9 Servo mechanism, 100, 100a, 100b Disk apparatus.

Claims (5)

An optical pickup comprising: a light emitting element that emits laser light; and a light receiving element that receives the reflected light reflected by the disk medium and converts the light into an electric signal having an amplitude corresponding to the amount of the reflected light;
A drive circuit for supplying a drive current of the light emitting element to the optical pickup;
A signal detection circuit for detecting a comparison signal from the electrical signal;
The amplitude of the comparison signal is compared with an amplitude reference value. If the amplitude of the comparison signal is larger than the amplitude reference value, the drive circuit is instructed to reduce the drive current, and the amplitude of the comparison signal is set. A determination unit that approaches the amplitude reference value;
A disk device comprising:   When the amplitude of the comparison signal is smaller than the amplitude reference value, the determination unit instructs the drive circuit to increase the drive current so that the amplitude of the comparison signal approaches the amplitude reference value. The disk device according to claim 1. A head amplifier for amplifying the amplitude of the electrical signal;
When the amplitude of the comparison signal is smaller than the amplitude reference value, the determination unit instructs the head amplifier to increase the gain so that the amplitude of the comparison signal approaches the amplitude reference value. The disk device according to claim 1.   4. The disk device according to claim 1, wherein the comparison signal is a data signal indicating information read from the disk medium. 5.   4. The disk apparatus according to claim 1, wherein the comparison signal is a focus error signal or a tracking error signal used for servo control of the optical pickup.

Images