JP2005038572A - Optical disk device, optical head, and detection signal processing method for optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique which realizes stable high-speed recording and reproducing in an optical disk device. <P>SOLUTION: The optical disk device has a constitution of being provided with a second circuit for sampling and holding an analog electric signal based on reflected laser beam from an optical disk and a third circuit for converting the sampled and held signal to a digital signal, in an optical head together with a circuit for driving a laser diode, and the signal digitized in the optical head is transmitted to a device main body side in time division. The first, second, and third circuits are formed in one substrate or one IC. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an optical disc apparatus, and more particularly to a signal processing technique for supporting high-speed recording / reproduction.

  As a prior art related to the present invention, for example, there is one described in Patent Document 1. Patent Document 1 describes an optical head including an amplifier with two sample and hold circuits.

Japanese Patent Laid-Open No. 7-320282

The prior art described in the above patent document is a technique for outputting a sampled and held signal from an optical head as an analog signal, and a detection signal is transmitted from the optical head to the control unit on the apparatus body side in the state of the analog signal. In this case, it is easily affected by impedance, noise, etc. on the transmission line, and waveform distortion is also expected to occur.
The problem of the present invention is that, in view of the above-described prior art situation, in an optical disc apparatus, a detection signal can be transmitted from an optical head to a control unit on the apparatus main body side while suppressing the occurrence of waveform distortion. It is to be able to cope with recording.
An object of the present invention is to provide a technique capable of solving such problems.

  In order to solve the above problems, in the present invention, basically, in an optical disc apparatus, a first circuit for driving a laser diode (corresponding embodiments: reference numerals 251, 252, 253, 250) in an optical head, and In addition, a second circuit that samples and holds an analog electric signal based on the reflected laser light from the optical disk (corresponding embodiment: reference numerals 257, 258, and 260), and a third circuit that converts the sampled and held signal into a digital signal. (Corresponding embodiment: reference numeral 259). In addition, the first circuit, the second circuit, and the third circuit are formed in one substrate or one IC. Specifically, the present invention proposes an optical head and an optical disc apparatus having the above basic configuration and a detection signal processing method of the optical disc apparatus having the above basic operation over time.

  According to the present invention, the optical disc apparatus can cope with high-speed recording / reproducing, and stable recording / reproducing operation is possible.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing a circuit configuration example in an optical head in an optical disk apparatus as a first embodiment of the present invention. In the first embodiment, a circuit that samples and holds an analog electric signal (hereinafter referred to as a sample and hold circuit) and a circuit that converts an analog electric signal into a digital signal are provided in a laser diode driving circuit (laser diode driver). It is an example.

  In FIG. 1, 25 is a laser diode drive circuit, 250 is a high-frequency oscillator, 251 is a power for outputting a recording / reproducing signal of a DVD optical disk and a recording / reproducing signal of a CD optical disk to each laser diode. DAC, 252 generates a multi-pulse, Time Ganger, 253 generates a recording strategy and determines the timing for generating the multi-pulse, WR STRATEGY, 254 a Mark Space Detector, 255 a serial interface, 256 generates reproduction power The read DAC 257 is a sample and hold circuit that samples and holds the reproduction signal, 258 is the sample and hold circuit that samples and holds the output from the front monitor detection circuit, and 259 is the support An AD converter circuit that converts the output from the pull hold circuits 257 and 258 into a digital signal, 23 is an IC (OEIC) that detects the state of the optical system, a reproduction signal and a servo signal, and 24 is for performing laser power control. FMD (Front Monitor Detector) for detecting a signal, 4 is a DSP (Digital Signal Processor) as a control unit, 53 is a recording control unit in the DSP 4, 47 is the same serial interface, 15 is a laser diode drive circuit 25 and DSP 4 FPC (flexible printed circuit board) that connects between them, 101 is a WR gate signal / WR that makes the laser diode drive circuit 25 recordable during recording, 102 is an NRZI signal that is modulation data, and 103 is an NRZI signal 102 Synchronized black Signal.

  The NRZI signal 102 and the clock signal 103 are connected to each other through an LVDS (Low Voltage Differential Signaling) interface in order to cope with a higher speed. The laser diode drive circuit 25, the OEIC 23, and the FMD 24 are all provided in the optical head, and the DSP 4 is provided in a main substrate (not shown) on the apparatus main body side. The laser diode drive circuit 25 is configured as one IC in the optical head, and is mounted on one substrate together with the OEIC 23 and the FMD 24. The high frequency oscillator 250, the power DAC 251, the time gang 252 and the WR strategy 253 correspond to the first circuit, the sample hold circuits 257 and 258 correspond to the second circuit, the AD conversion circuit 259 corresponds to the third circuit, and the OEIC 23 Corresponds to the fourth circuit, and the FMD 24 corresponds to the fifth circuit.

  In the above configuration, at the time of recording, a detection signal (analog signal) from the OEIC 23 is input to the sample hold circuit 257, sampled and held by the sample hold circuit 257, and then input to the AD conversion circuit 259. Is converted into a time-division digital signal. The detection signal (analog signal) from the FMD 24 is input to the sample hold circuit 258, sampled and held by the sample hold circuit 258, input to the AD conversion circuit 259, and converted into a digital signal time-divided by AD conversion. Converted. These converted digital signals are transmitted to the DSP 4 side through the serial interface 255 in a time division manner. In the DSP 4, a control signal is formed by exchanging information with a microcomputer (not shown). The control signal is transmitted to the laser diode drive circuit 25 via the FPC 15.

  The Mark Space Detector 254 in the laser diode driving circuit 25 receives the WR gate signal / WR101, the NRZI signal 102, and the clock signal 103, and detects the time length of the mark of the NRZI signal 102. In WR STRATEGY 253, the timing for generating a multi-pulse corresponding to the time length of the mark is determined. The Time Ganger 252 generates a multi pulse according to the timing. The multi-pulse is input to the Power DAC 251, and based on this, a recording / reproducing signal for the DVD optical disk and a recording / reproducing signal for the CD optical disk are output to the respective laser diodes. Each laser diode generates laser light based on this. The laser beam is focused by an optical system and irradiated onto a recording surface of an optical disc (not shown) to record information on the recording surface. The reproduction power generated by the Read DAC 256 is superimposed on the multi-pulse via the Power DAC 251. The multi-pulse is used to divide the recording power and cope with high-speed recording so that marks or pits formed on the optical disk can be recorded at high density. The level of the pulse is changed to multiple values (for example, 2 to 4 values) by power control.

  A time signal of the sample and hold in the sample and hold circuits 257 and 258 is output from the time ganger 252. The timing signal from the Time Ganger 252 is set in consideration of the delay time of the OEIC 23 and the FMD 24. The serial interface 105 includes a transmission path for an enable signal (SEN), a clock (SCK), and a data (SDIO) 3 signal. The data is a bidirectional signal. The signal from the OEIC 23 is used for running OPC (R-OPC). The signal from the FMD 24 is used for recording power control (WRAPC) during recording. The two signals are required to have a high-frequency response because the output of the OEIC 23 corresponding to the R-OPC corresponds to a high-speed change with respect to uneven sensitivity of the optical disk position, fingerprints, and the like. On the other hand, a low frequency response is sufficient as the response of WRAPC to the IL change due to the temperature of the laser diode. Therefore, the rate of switching the amount of data when sending to the main board through the serial interface is sufficient if RF> FMD. , It may be 1 digit or more slower than RF.

FIG. 2 is a diagram showing an example of the entire circuit configuration of an optical disc apparatus using the optical head of FIG.
In FIG. 2, 1 is an optical disk, 2 is an optical head, 3 is an analog front end (AFE) on the main board on the apparatus main body side, 4 is a DSP, 5 is a DRAM, 6 is a connector, and 7 is a spindle that rotationally drives the optical disk. A motor, 8 is a connector, 9 is a slider for moving the optical head 2 in the radial direction of the optical disk 1, and 10 is a spindle motor 7, a motor for driving the slider 9, and a drive signal for driving an actuator. 1 is a microcomputer, 21 is an optical system in the optical head 2, 21a is an objective lens in the optical system 21, 22 is a laser diode, 23 is an OEIC, 24 is an FMD, and 25 is configured as shown in FIG. A laser diode drive circuit 31 is a calculation unit that performs calculation processing of various signals in the AFE 3, 32 is a reproduction signal processing unit (RF), and 33 is a watch. Signal signal processing unit (WOB), 34 is a servo signal processing unit (SRV), 41 is a DSL / DPLL circuit that binarizes an RF signal (analog signal) and then converts it into a synchronized digital signal, 42 is a DVD DVD / CD decoder 43 for demodulating system signal or CD system signal, LPP / ADIP circuit 43 for detecting address data in pre-pit (ADIP) of address data included in wobble signal, 44 generating reference clock RPLL (Phase Locked Loop for Reference Clock) circuit, 45 AD converter circuit for converting servo signal to digital signal, 46 servo circuit, 47 serial interface, 48 sampling timing signal generation circuit, 49 analog signal digital signal Signal DA conversion circuit for conversion, 50 is a motor control circuit for controlling the rotation of the spindle motor, 51 is a CD / DVD Encoder for supplying an NRZI signal necessary for recording to the laser diode drive circuit 25, and 52 is an ATAPI circuit. . The optical system 21, the laser diode 22, the OEIC 23, the FMD 24, and the laser diode drive circuit 25 are configured in the optical head 2. The laser diode drive circuit 25 has the configuration shown in FIG. 1 and includes sample hold circuits 257 and 258 and an AD conversion circuit 259 therein.

  In the above configuration, the optical disk 1 is rotated by the spindle motor 7 in a CAV (Constant Angular Velocity) control state or a CLV (Constant Linear Velocity) control state. The rotation state of the spindle motor 7 is controlled by the motor control circuit 50 and the drive circuit 10. As the optical disk 1, a recording film mainly composed of an organic dye such as DVD-R, DVD + R, and CD-R, and a phase change recording film such as DVD-RAM, DVD-RW, DVD + RW, and CD-RW are used. There are rewritable discs on which are formed. In the case of DVD-RAM, Land / Groove is formed in advance, and in the case of DVD-R, DVD + R, CD-R, DVD-RW, DVD + RW, CD-RW, etc., Groove is formed. Each track pitch is 0.615 μm for the 2X format of DVD-RAM, 0.74 μm for DVD-R / RW and DVD + R / RW, and 1.6 μm for CD-R / RW. As the laser diode 22, one that generates red laser light with a wavelength of 650 nm for a DVD optical disk and one that generates infrared laser light with a wavelength of 780 nm for a CD optical disk are mounted. The laser diode drive circuit 25 drives the laser diode based on a signal supplied from the DSP 4 to generate high speed and high output laser power. The slider 9 is driven by a step motor (not shown) to move the optical head 2 in the radial direction of the optical disc 1 so that high speed access is possible.

At the time of recording, the laser light emitted from the laser diode 22 is collimated by the optical system 21 and then irradiated on the optical disk 1 by the objective lens 21a while being focused on a light spot of about 1 × 10 ⁻⁶ m. Is done. At this time, in order to form a mark having a size of 0.5 × 10 ⁻⁶ m or less on the recording film, in the case of a DVD laser diode, light is emitted with a power of 10 × 10 ⁻³ W or more, and CD In the case of a system laser diode, light emission is performed with a power of 20 × 10 ⁻³ W or more.

  At the time of reproduction, the laser diode 22 is driven at a relatively low output, the reflected light from the optical disk 1 is taken in from the objective lens 21a, guided to the OEIC 23 via the optical system 21, and reproduced signals (RF signals) and Detect servo signals. The objective lens 21a is attached to an actuator, drives a focus coil (not shown) for up-and-down deflection of the optical disc 1, drives a tracking coil (not shown) for tracking the eccentricity of the disc, In order to absorb the relative tilt (tilt) of the spindle motor 7, a tilt coil (not shown) is driven so that a normal signal can be always taken in. The signal detected by the OEIC 23 is guided from the optical head 2 to the IC of the AFE 3 on the main board via the FFC (Flexible Flat Cable) and the connector 8 and also to the laser diode driving circuit 25. In the AFE 3, calculation is performed by the calculation unit 31, and a high frequency reproduction signal (RF signal), a wobble signal, and a servo signal are generated. Further, the signal detected by the FMD 24 is guided to the laser diode drive circuit 25 without being input to the AFE 3, and is used for power control.

  During the recording operation, a reflected light signal is obtained from the pulse light during the mark formation from the OEIC 23, and the block of the calculation unit 31 detects the reproduction power level of the reflected light signal. The servo system is stabilized by controlling to have the same amplitude. A signal from the FMD detects a reproduction power level between recording pulses and a recording pulse peak during recording, and guides the detection result to the laser diode drive circuit 25. The reproduction signal processing unit 32 includes an AGC circuit, a waveform equalization circuit, an LPF circuit, and the like, and controls the quality of signals from various DVD and CD optical discs to be constant. The wobble signal can be obtained by the same signal processing as that of the tracking signal because Groove and Land / Groove of various disks are swelled at a high frequency in advance. The bandwidth of the tracking signal is at most 10 kHz, but the wobble signal is about 315 kHz at the time of double-speed recording in the case of DVD-RAM / R / RW and about 800 kHz in the case of DVD + R / RW. Since the two signals have a large frequency difference, the wobble signal is usually detected by the BPF circuit.

  The RF signal, wobble signal, and servo signal detected by the AFE 3 are each input to the DSP 4. In the DSP 4, the RF signal is guided to the DSL / DPLL circuit 41, where the analog signal is binarized and then synchronized with a self-synchronous DPLL (Self-clocking type Phase locked loop for Data). Signal. Further, the digital signal is guided to a DVD or CD demodulation circuit (Decoder), where it is generated as original data. The generated data is sent from the ATAPI circuit 52 to a personal computer (not shown) via the connector 6 or the like.

  The wobble signal is sent to an RPLL (Phase locked loop for Reference clock) circuit 44 and an LPP / ADIP circuit 43 in the DSP 4. The PRLL circuit 44 generates a recording reference clock synchronized with the wobble signal. The reference clock from the RPLL circuit 44 is guided to a demodulation circuit in the DSP 4, that is, a DVD / CD decoder 42 during recording. Further, the wobble signal is, for example, an LPP (Land Pre-Pit) which is address data in an optical disc such as a DVD-R / RW, and an ADIP (Address In Groove) which is address data in an optical disc such as a DVD + R / RW. Is included. The LPP / ADIP circuit 43 detects these address data (LPP, ADIP). The address data is used for both recording and reproduction.

  The servo signal is input to the AD conversion circuit 45 in the DSP 4. In the AD conversion circuit 45, the focus signal, the tracking signal, and the like of the analog signal calculated by the AFE 3 are binarized. Thereafter, the servo circuit 46 performs digital processing. As the digital processing, amplification, phase compensation, addition, and the like are performed. These digital signals pass through the DA conversion circuit 49 and are led to the drive circuit 10 to drive and drive the actuator again to control the drive circuit 10. The drive circuit 10 drives the actuator with a drive signal. In addition, a sampling timing signal generation circuit 48 is provided in the DSP 4, and the signal from the OEIC 23 and the signal from the FMD 24 are sampled and held by the recording clock of the RPLL 44 and guided to the arithmetic unit 31 of the AFE 3. The modulation data NRZI signal necessary for recording is supplied from the CD / DVD Encoder 51, and the recording clock signal synchronized with this signal is supplied from the RPLL 44. Further, RAM data necessary for generating the WR STRATEGY 253 in the laser diode drive circuit 25 is sent from the DSP 4 to the laser diode drive circuit 25 via the serial interface 47. The RAM data is sent from the microcomputer 11.

  According to the first embodiment, in the optical disk apparatus, the analog detection signal of the optical head 2 is sampled and held in the optical head 2 and digitized, and the digitized signal is used as a DSP 4 as a control unit on the apparatus main body side. Therefore, it is difficult to be affected by impedance and noise on the transmission line, and signal transmission with suppressed waveform distortion is possible. For this reason, it is possible to cope with high-speed recording and reproduction. In particular, since the sample hold circuits 257 and 258 and the AD conversion circuit 259 are provided in the laser diode drive circuit 25, the laser diode drive circuit 25 can output a sampling timing pulse without delay, From this point, it becomes easier to cope with high-speed recording and reproduction.

  FIG. 3 is a diagram showing a circuit configuration example in the optical head in the optical disk apparatus as the second embodiment of the present invention. The second embodiment is also an example in the case where the sample hold circuit and the AD conversion circuit are provided in the laser diode drive circuit. The sample hold circuit for the reproduction signal and the output of the front monitor detection circuit (FMD) This is different from the first embodiment in that the common sample and hold circuit is a common circuit.

  In FIG. 3, 25 'is a laser diode drive circuit, 260 is a sample hold circuit shared by the sample hold of the reproduction signal from the OEIC 23 and the sample hold of the output from the FMD 24, and 261 is the reproduction signal and front monitor detection circuit. This is a switching circuit (switch circuit) for switching the output signal from the. Since the configuration of other parts is the same as that of the first embodiment, the same reference numerals as those of the first embodiment are used. The signal from the OEIC 23 and the signal from the FMD 24 are switched by the switching circuit 261 and input to the sample and hold circuit 260. The switching is performed by a timing signal output from the Timer Ganger 252. The sample hold circuit 260 samples and holds the reproduction signal when the reproduction signal is input from the OEIC 23, and samples and holds the signal when the signal from the FMD 24 is input. The sampled and held signal (analog signal) is input to the AD conversion circuit 259 and converted into a digital signal by the AD conversion circuit 259. The functions and operations of the other parts are the same as those in the first embodiment. The laser diode drive circuit 25 ′ is also configured as one IC in the optical head and is mounted on one substrate together with the OEIC 23 and the FMD 24. The high-frequency oscillator 250, Power DAC 251, Time Ganger 252, and WR STRATEGY 253 correspond to the first circuit, the sample hold circuit 260 corresponds to the second circuit, the AD conversion circuit 259 corresponds to the third circuit, and the OEIC 23 corresponds to the first circuit. 4, the FMD 24 corresponds to the fifth circuit, and the switching circuit 261 corresponds to the sixth circuit.

  Also in the second embodiment, as in the case of the first embodiment, in the optical disk apparatus, it is difficult to be affected by impedance and noise on the transmission path from the optical head 2 to the DSP 4 on the apparatus body side, and waveform distortion is caused. Thus, signal transmission can be performed in a state in which the above is suppressed, and high-speed recording and reproduction can be supported. In addition, since the sample hold circuit 260 and the AD conversion circuit 259 are provided in the laser diode drive circuit 25 ′, the laser diode drive circuit 25 can generate a sampling timing pulse without delay. In view of this, it becomes easier to handle high-speed recording / reproduction.

  In the above embodiment, the microcomputer 11 is provided outside the DSP 4. However, the present invention is not limited to this. The microcomputer 11 may be provided inside the DSP 4, or provided both inside and outside the DSP 4. Also good.

1 is a diagram illustrating an example of a circuit configuration in an optical head in an optical disc apparatus as a first embodiment of the present invention. FIG. It is a figure which shows the example of a whole circuit structure of the optical disk apparatus using the optical head of FIG. It is a figure which shows the circuit structural example in the optical head in the optical disk apparatus as 2nd Example of this invention.

Explanation of symbols

1 ... Optical disc,
2 ... Optical head,
3 ... AFE,
4 ... DSP,
5 ... DRAM,
6, 8 ... Connector,
7 ... Spindle motor,
9 ... Slider,
10 ... Drive circuit,
11 ... Microcomputer,
15 ... FPC,
21 ... Optical system,
21a ... objective lens,
22 ... Laser diode,
23 ... OEIC,
24 ... FMD,
25, 25 '... laser diode drive circuit,
47, 255 ... serial interface,
251 ... Power DAC,
252 ... Time Ganger,
253 ... WR STRATEGY,
254 ... Mark Space Detector,
256 ... Read DAC,
257, 258, 260 ... Sample and hold circuit,
259 ... AD conversion circuit,
261: switching circuit.

Claims (9)

An optical disk apparatus that irradiates an optical disk with a laser beam from an optical head to record or reproduce information or both,
A laser diode that generates the laser beam; an optical system that focuses the laser beam and irradiates the information recording surface of the optical disc; and a reflected laser beam from the optical disc is received through the optical system and converted into an analog electrical signal. A photodetection unit that converts and outputs, a first circuit that drives the laser diode, a second circuit that samples and holds the analog electrical signal, and converts the sampled and held signal into a digital signal and outputs the digital signal An optical head comprising a third circuit;
A controller that receives the digital signal from the optical head via a serial interface and forms a control signal for controlling the device;
An optical disc device characterized by comprising the above. An optical disk apparatus that irradiates an optical disk with a laser beam from an optical head to record or reproduce information or both,
A laser diode that generates the laser beam; an optical system that focuses the laser beam and irradiates the information recording surface of the optical disc; and a reflected laser beam from the optical disc is received through the optical system and converted into an analog electrical signal. A photodetection unit that converts and outputs, a first circuit that drives the laser diode, a second circuit that samples and holds the analog electrical signal, and a third circuit that converts the sampled and held signal into a digital signal And an optical head comprising a serial interface unit that time-divides and outputs the digital signal to the outside,
A controller that receives the digital signal from the optical head via a serial interface and forms a control signal for controlling the device;
An optical disc device characterized by comprising the above. An optical disk apparatus that irradiates an optical disk with a laser beam from an optical head to record or reproduce information or both,
A laser diode that generates the laser beam; an optical system that focuses the laser beam and irradiates the information recording surface of the optical disc; and a reflected laser beam from the optical disc is received through the optical system and converted into an analog electrical signal. A photodetection unit that converts and outputs, a first circuit that drives the laser diode, a second circuit that samples and holds the analog electrical signal, and a third circuit that converts the sampled and held signal into a digital signal A fourth circuit for detecting the state of the optical system, the reproduction signal and the servo signal based on the analog electrical signal, and a fifth circuit for controlling the intensity of the laser light emitted from the laser diode. An optical head having a fourth circuit and a sixth circuit for switching the connection of the fifth circuit;
A controller that receives the digital signal from the optical head via a serial interface and forms a control signal for controlling the device;
An optical disc device characterized by comprising the above.   4. The optical disk device according to claim 1, wherein the first circuit, the second circuit, and the third circuit are configured on one substrate or in one IC. 5.   4. The optical disc apparatus according to claim 3, wherein the first circuit, the second circuit, the third circuit, and the sixth circuit are configured on one substrate or in one IC. An optical head of an optical disc apparatus that records or reproduces information by irradiating an optical disc with laser light,
A laser diode for generating the laser beam;
An optical system for focusing the laser beam and irradiating the information recording surface of the optical disc;
A light detection unit that receives reflected laser light from the optical disc through the optical system, converts the light into an analog electrical signal, and outputs the analog electrical signal;
A first circuit for driving the laser diode;
A second circuit that samples and holds the analog electrical signal;
A third circuit for converting the sampled and held signal into a digital signal;
And an optical head characterized by irradiating the optical disk with laser light and transmitting data detected from the reflected laser light as a digital signal to the disk apparatus main body. An optical head of an optical disc apparatus that records or reproduces information by irradiating an optical disc with laser light,
A laser diode for generating the laser beam;
An optical system for focusing the laser beam and irradiating the information recording surface of the optical disc;
A light detection unit that receives reflected laser light from the optical disc through the optical system, converts the light into an analog electrical signal, and outputs the analog electrical signal;
A first circuit for driving the laser diode;
A second circuit that samples and holds the analog electrical signal;
A third circuit for converting the sampled and held signal into a digital signal;
A serial interface unit that time-divides and outputs the digital signal to the outside;
And an optical head characterized by irradiating the optical disk with laser light and transmitting a plurality of data detected from the reflected laser light as a digital signal to the disk apparatus main body side in a time-sharing manner.   The optical head according to claim 6, wherein the first circuit, the second circuit, and the third circuit are configured on one substrate or in one IC. A detection signal processing method for an optical disc apparatus for recording or reproducing information by irradiating an optical disc with laser light,
Receiving reflected laser light from the optical disk and converting it into an analog electrical signal in the optical head;
Sampling and holding the analog electrical signal in an optical head;
Converting the sampled and held signal into a digital signal in an optical head;
Transmitting the digital signal to the control unit on the apparatus main body side by time division via a serial interface;
Forming a control signal based on the digital signal on the apparatus body side;
And a detection signal processing method for processing a detection signal from the optical head.

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