JP2006294081A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk device capable of maintaining good recording/reproducing quality without deteriorating tilt servo performance even when the disk of low reflectance is subjected to recording/playing. <P>SOLUTION: An RF circuit 9 generates a total signal based on the reflected light of a light applied to a disk 1 by the laser diode 4 of a pickup 7, a system controller 18 decides a current value supplied to the LED of a tilt sensor 24 based on this total signal, and the LED of the tilt sensor 24 emits a light according to the current of the decided current value. Then, a servo DSP 16 detects a tilt angle based on a sense signal obtained by the tilt sensor 24, and a tilt motor 22 is driven based on a detected signal. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a tilt control operation of an optical disc apparatus.

  In an optical disc apparatus, a laser beam is irradiated from a pickup onto a disc surface to focus a light spot on a track on the disc surface, and information is reproduced and recorded. At this time, if the optical axis of the laser beam irradiated to the disk surface is not perpendicular to the disk surface due to the warp of the disk but has a relative inclination, the light spot is also irradiated to the adjacent track, and the light on the disk surface Aberrations are generated in the spots, and the reproduction quality and recording quality are greatly reduced.

Therefore, in the conventional optical disc apparatus, tilt servo, which is servo control for suppressing the tilt angle, which is the tilt angle of the optical axis of the pickup with respect to the vertical axis of the disc surface, to a predetermined angle or less is performed. In the tilt servo, the pickup is driven so as to change the relative tilt between the pickup and the disk based on a sense signal from a tilt sensor that detects a tilt angle. The tilt sensor has an LED and a light receiving element, and a sense signal is obtained by irradiating the disk with light from the LED and converting the reflected light from the disk into an electrical signal with the light receiving element, so when the reflectivity of the disk is low, The sense signal is amplified by a later stage amplifier to obtain a signal level sufficient to drive the servo.
JP 2002-109767 A

  However, in the optical disk device described above, when the reflectivity of the disk is low, the sense signal of the tilt sensor is amplified by an amplifier, so that a sufficient S / N ratio cannot be secured, resulting in a large tilt angle detection error and servo performance. Sometimes deteriorated. Also, in the case of a disk with extremely low reflectivity, even if the sense signal is amplified with an amplifier, the signal level required by the servo cannot be obtained, and the tilt servo itself may not operate, and the disk cannot be recorded or reproduced. There was also.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical disc apparatus capable of maintaining good recording / reproducing quality without deterioration of tilt servo performance even when recording / reproducing a disc having low reflectivity. .

  In order to achieve the above object, an optical disc apparatus according to the present invention includes a pickup for irradiating light on a disc, reflectance detection means for detecting a signal indicating the reflectance of the disc, and irradiating the disc with light from the disc. Tilt detection means for detecting a signal indicating the tilt of the optical axis of the pickup with respect to the vertical axis of the disk surface based on the reflected light of the disk, and the light of the pickup with respect to the vertical axis of the disk surface based on the detection signal of the tilt detection means Inclination correction means for correcting the inclination of the axis; and first control means for changing the amount of light irradiated to the disk by the inclination detection means in accordance with a detection signal of the reflectance detection means. And

  According to such a configuration, even when recording / reproducing a disk with low reflectivity, the amount of light emitted from the tilt sensor to the disk can be increased, and the level of the sense signal of the tilt sensor is increased. The sense signal amplification factor can be suppressed, the S / N ratio is improved, the tilt angle detection error is reduced, and the performance of the tilt servo does not deteriorate.

  In addition, the optical disk apparatus of the present invention includes a second control unit that causes the tilt detection unit to intermittently perform an operation of irradiating the disk with light.

  According to such a configuration, it is possible to reduce the power consumption of the optical disk device, and it is possible to suppress the wear of mechanical parts and reduce the life of the device by reducing the mechanical operation time by the tilt servo.

  Further, the second control unit causes the tilt detection unit to irradiate the disc with light when the reflectivity of the disc indicated by the detection signal of the reflectivity detection unit is lower than a predetermined reflectivity. You may make it carry out intermittently.

  According to such a configuration, when the reflectance of the disk is low, it is possible to suppress as much as possible that the amount of light applied to the disk is increased and the life of the tilt sensor is shortened.

  According to the optical disk apparatus of the present invention, even when recording / reproducing a disk having a low reflectance, the tilt servo performance is not deteriorated and the recording / reproducing quality can be maintained satisfactorily.

  Embodiments of an optical disc apparatus according to the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of an optical disc apparatus according to the present invention.

  The pickup 7 includes an objective lens 2, an actuator 3 that drives the objective lens 2 in the axial direction and the radial direction with respect to the disk 1, a laser diode 4, and a photo detector 5 for detecting direct light from the laser diode 4. And a photodetector 6 for detecting the reflected light that is reflected from the disk 1 after the laser light emitted from the laser diode 4 is focused by the objective lens 2. The pickup 7 is driven in the radial direction of the disk 1 by a thread motor 8.

  The laser diode 4 is driven by a laser driver 14 to emit light. At this time, direct light from the laser diode 4 is detected by the photodetector 5 and input to the APC circuit 15. The APC circuit 15 compares the level of the laser beam detected by the photodetector 5 with a reference level, and if the level detected by the photodetector 5 is larger than the reference, the intensity of the laser beam is lowered with respect to the laser driver 14. On the contrary, if the level detected by the photodetector 5 is smaller than the reference, the laser driver 14 is instructed to increase the intensity of the laser beam so that the output from the laser diode 4 becomes constant. APC represents automatic power control.

  The reflected light from the disk 1 detected by the photodetector 6 is converted into an electric signal and sent to the RF circuit 9. The RF circuit 9 generates focus servo and tracking servo error signals from the electrical signal from the photodetector 6. The servo error signal generated by the RF circuit 9 is input to the servo DSP 16 and arithmetic processing is performed to generate a drive signal from the servo DSP 16 to the actuator driver 13. With this drive signal, the actuator driver 13 drives the actuator 3 so that the objective lens 2 is always in a specified position.

  The servo DSP 16 generates a thread drive signal for driving the thread motor 8 from the tracking servo error signal, and drives the thread motor 8 via the thread driver 10.

  The spindle motor 11 has a built-in circuit for generating a pulse along with the rotation of the motor. This pulse is input to the servo DSP 16, and the servo DSP 16 uses this pulse to drive the spindle motor 11 at a constant rotational speed. Drive signal is generated. The spindle motor drive signal generated by the servo DSP 16 rotates the spindle motor 11 at a constant rotational speed via the spindle motor driver 12.

  The photodetector 6 detects a signal written on the disk 1 in addition to the servo error signal. Here, the signals written on the disk 1 include an RF signal serving as data and a wobble signal for indicating an address on the disk 1.

  For example, in an optical recording disk, data “1” and “0” are represented by the difference in reflectance of the recording film on the disk, “1” has a low reflectance, and “0” has a high reflectance. Such a light / dark signal of light is converted into an electric signal by the photodetector 6 and expressed by a voltage value. The signal represented by this voltage value becomes the RF signal.

  The wobble signal is carved as a groove on the disk 1, and an absolute address is represented by a slight fluctuation of the groove.

  In reproduction from the disc 1, these reproduction signals detected by the photodetector 6 are sent to the RF circuit 9, subjected to waveform shaping processing, and sent to the signal processing circuit 17. The signal processing circuit 17 performs demodulation and waveform shaping processing of the RF signal, and further performs error correction processing to extract the original data. The extracted data is sent to the host computer 20 via the host interface 19. The wobble signal is demodulated, waveform-shaped, and error-corrected by the signal processing circuit 17, and an address signal is extracted. This address signal is sent to the system controller 18 and used as address information.

  The signal processing circuit 17 generates a clock signal for generating a synchronization signal from the RF signal and the wobble signal. This clock signal is sent to the servo DSP 16 and used to control the rotation of the spindle motor 11 in synchronization with the RF signal.

  When recording data on the disk 1, data from the host computer 20 is sent to the signal processing circuit 17 via the host interface 19, where the data is added with a flag for error correction and further subjected to modulation processing. And sent to the laser driver 14.

  The laser driver 14 performs a write strategy process in order to write the recording signal sent to the disk 1. The write strategy is a method for improving the recording performance when the sent data is actually recorded on the disc 1, and utilizes the fact that the recording of the optical disc apparatus is thermal recording.

  The APC circuit 15 switches the reference laser power to the recording power to perform the APC operation, the laser diode 4 emits pulses, and data is recorded on the disk 1. At this time, since the laser diode 4 emits light with the recording power, the level of the reflected light signal from the disk 1 detected by the photodetector 6 becomes larger than that during reproduction. Therefore, gain switching means is provided in the photodetector 6 so that the level of the servo error signal generated by the RF circuit 9 does not increase.

  The system controller 18 controls the operation of each circuit block so that the entire system can perform a predetermined operation.

  The optical disk apparatus according to the present invention is characterized by tilt servo, and will be described below.

  The tilt sensor 24 is a sensor for detecting the tilt angle between the pickup 7 and the disk 1 and is provided on the pickup 7. The tilt angle represents an angle formed by an axis that stands perpendicular to the recording surface of the disc and the axis of the optical system of the pickup. If this angle is large, the recording and reproduction quality deteriorates as described above. Therefore, the tilt angle is detected by the tilt sensor 24, the servo DSP 16 generates a tilt drive signal based on the detected tilt angle, and the tilt angle is corrected by driving the tilt motor 22 via the tilt driver 23. Maintains optimal recording and playback quality.

  As shown in FIG. 2, the tilt sensor 24 includes detectors 24 a and 24 b composed of LEDs and photodetectors arranged side by side in the disk radial direction, and these are opposed to the recording surface of the disk 1. Light emitted from the LEDs of the detection units 24a and 24b is reflected by the surface of the disk 1 and converted into a sense signal by the photodetectors of the detection units 24a and 24b. The sense signal passes through the RF circuit 9 and is input to the servo DSP 16. The servo DSP 16 has an amplifier 16a, a comparator 16b, and a servo drive signal generator 16c. The sense signal input from the tilt sensor 24 is amplified by the amplifier 16a, the comparator 16b generates a difference signal based on the amplified signal, and the servo drive signal generator generates a tilt drive signal based on the difference signal. The tilt motor 22 is driven through the tilt driver 23. When the tilt motor 22 is driven, the tilt of the pickup 7 with respect to the disk 1 is changed by a known tilt mechanism (for example, see Patent Document 1 above), and the tilt angle is corrected.

  As shown in FIG. 2, the recording surface of the disk 1 is normally inclined in the radial direction due to warping, and therefore the distance between the detection units 24a and 24b and the recording surface of the disk 1 is different as X and Y. Therefore, the level of the sense signal obtained from the photo detector differs between the detectors 24a and 24b, and the tilt angle can be detected as the difference signal. When the tilt angle is 0, the difference signal is also 0, and when the tilt angle is a positive or negative value, the difference signal is a positive or negative value corresponding to the tilt angle.

  During the tilt servo operation, the RF circuit 9 adds up all electrical signals detected by the photodetector 6 to generate a total signal. The total signal is a signal representing the amount of laser reflected light from the disk 1. The generated total signal is input to the system controller 18 via the servo DSP 16.

The system controller 18 determines a current value to be passed through the LED of the tilt sensor 24 based on the input total signal and, for example, the expression (1). However, V ₀ is the voltage value of the total signal when the reference disc (a standard disc in the production process and the reflectivity is known) is irradiated with the laser at the recording and reproducing laser power, I ₀ Represents the current value to be passed through the LED of the tilt sensor so that the tilt servo operates normally when using the reference disk, and is stored in the system controller 18 as a parameter. V is the voltage value of the total signal input to the system controller 18.

I = I ₀ × 1 / α (1)
However, α = V / V ₀
The system controller 18 sends a drive signal to the LED driver 25 so that the current of the current value determined by the equation (1) flows through the LED of the tilt sensor 24. The current of the current value determined by equation (1) flows through the LED of the tilt sensor 24, and the LED irradiates the recording surface of the disk 1 with a light amount corresponding to the current.

  In the equation (1), α indicates the reflectivity of the disc (if the reflectivity of the reference disc is 50%, the reflectivity is 50 × α%), and the reflectivity of the disc to be recorded / reproduced The lower the value is (the smaller α is), the larger the current flows through the LED of the tilt sensor, and the greater the amount of light emitted from the LED to the disk. Therefore, the level of the sense signal from the tilt sensor is also increased, the amplification factor in the amplifier can be suppressed, the S / N ratio is improved, the tilt angle detection error is reduced, and the reflectivity of the recording / reproducing disc is increased. Even if it is low, the performance of the tilt servo does not deteriorate.

  Here, when α in equation (1) is smaller than a predetermined value (for example, 0.8), the system controller 18 intermittently applies the current of the current value determined in equation (1) to the LED of the tilt sensor 24. A drive signal is sent to the LED driver 25 so as to flow, and the LED of the tilt sensor 24 emits light intermittently. While the current does not flow through the LED of the tilt sensor 24, the difference signal is 0. Therefore, the tilt motor 22 is not driven and the servo operation is intermittent as a whole.

  According to this, when recording / reproducing a disk having a reflectance lower than a predetermined reflectance (in the above, specified by a predetermined value of α), as described above, the light emission amount of the LED of the tilt sensor 24 increases, and the tilt sensor Therefore, the life of the tilt sensor can be reduced as much as possible by causing the LED to emit light intermittently. Here, the tilt angle of the disc changes continuously, and the change amount itself is small. Therefore, since the servo for tilt angle correction is a very slow servo, it is not always necessary to perform the servo operation continuously. Further, since the disc, the pickup, and the signal processing circuit each have a margin for the tilt angle, even if the intermittent servo operation as described above is performed, the influence on the recording / reproducing operation of the disc is extremely small.

  In the above description, intermittent servo operation is performed when recording / reproducing a disk having a reflectance lower than a predetermined reflectance. However, the system controller 18 always operates the tilt sensor (regardless of the number α in the above). The intermittent servo operation may be performed by sending a drive signal to the LED driver 25 so that the current of the current value determined by the expression (1) is intermittently supplied to the 24 LEDs. As a result, the power consumption of the optical disk device can be reduced, and the wear of the mechanical parts can be suppressed by reducing the mechanical operation time by the tilt servo, and the life of the device can be extended.

  In the above embodiment, the current value to be supplied to the LED of the tilt sensor 24 is determined by the expression (1). However, the table showing the correspondence between α in the expression (1) and the current value to be supplied to the LED of the tilt sensor 24. May be prepared in advance, and the current value may be determined based on the table.

These are block diagrams of the optical disk apparatus according to the present invention. FIG. 5 is a diagram for explaining a tilt angle detection method.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Disc 2 Objective lens 3 Actuator 4 Laser diode 5 Photo detector 6 Photo detector 7 Pickup 8 Thread motor 9 RF circuit 10 Thread driver 11 Spindle motor 12 Spindle motor driver 13 Actuator driver 14 Laser driver 15 APC circuit 16 Servo DSP
17 Signal Processing Circuit 18 System Controller 19 Host Interface 20 Host Computer 21 Display Device 22 Tilt Motor 23 Tilt Driver 24 Tilt Sensor 25 LED Driver

Claims (3)

A pickup that irradiates the disc with light,
Reflectivity detecting means for detecting a signal indicating the reflectivity of the disk;
Tilt detecting means for irradiating the disk with light and detecting a signal indicating the tilt of the optical axis of the pickup with respect to the vertical axis of the disk surface based on reflected light from the disk;
Tilt correcting means for correcting the tilt of the optical axis of the pickup with respect to the vertical axis of the disk surface based on the detection signal of the tilt detecting means;
First control means for changing the amount of light applied to the disk by the tilt detection means in accordance with a detection signal of the reflectance detection means;
An optical disc apparatus comprising:   2. The optical disk apparatus according to claim 1, further comprising second control means for causing the tilt detection means to intermittently perform an operation of irradiating the disk with light.   The second control means intermittently causes the tilt detection means to irradiate the disk with light when the reflectance of the disk indicated by the detection signal of the reflectance detection means is lower than a predetermined reflectance. The optical disk apparatus according to claim 2, wherein the optical disk apparatus is performed.

Images