JPH11110922A - Optical disk device and method for inspecting the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and surely count CI errors by incorporating a detecting means detecting the CI errors and a counting means counting the detected CI errors. SOLUTION: At the time of recording data in an optical disk device 1, the data are inputted to an EFM/CDROM encoder control part 24 to be coded based on a clock signal from a clock 34 to become an ENCODED EFM signal. A laser control part 14 changes over the level of a WRITE POWER signal from a control means 13 to a high level and a low level based on the ENCODED EFM signal to output them to control the driving of the laser diode of an optical head 3. A CD servo controller 21 performs an error correction and performs an error correction while detecting CI errors with respect to the EFM signal and counts the number of the errors to store it in a memory 26 and also performs the judging of an inspection with a computer 41 via an interface control part 31.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to an optical disk device for reproducing or recording / reproducing an optical disk and a method for inspecting the optical disk device.

[0002]

2. Description of the Related Art An optical disk device (for example, a CD-R drive device) for reproducing or recording / reproducing an optical disk is known.

In an optical disk device, a C1 error may be counted (measured) in an inspection on a production line or an inspection at the time of repair. For example, when the count value of the C1 error exceeds the reference value, it is determined that the optical disk device is abnormal.

Conventionally, when counting this C1 error, an error rate counter is externally connected (connected) to the optical disk device.

However, in order to be able to attach an error rate counter for counting the C1 error to the optical disk device, it is necessary to separately provide a connector for connecting the error rate counter to the optical disk device. Then, in order to provide the connector in the optical disk device, it is necessary to disassemble the optical disk device, and thus there is a problem that it takes time and effort.

Another disadvantage is that an error rate counter is required when counting C1 errors.

In particular, when C1 errors are counted in a production line, it is necessary to install an error rate counter for counting C1 errors in the production line, which causes a problem that equipment is increased.

[0008]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical disk device capable of easily counting C1 errors and a method for inspecting an optical disk device using the optical disk device.

[0009]

This and other objects are achieved by the present invention which is defined below as (1) to (6).

(1) A rotation drive mechanism for mounting and rotating an optical disk, an optical head, signal processing means for processing a signal read from the optical disk by the optical head, and at least the rotation drive mechanism, an optical head, and a signal An optical disc device for controlling the driving of a processing means for reproducing or recording / reproducing the optical disc, comprising: a detecting means for detecting a C1 error; and a counting means for counting the detected C1 errors. An optical disk device having a built-in optical disk.

(2) The optical disc device according to (1), further comprising a memory for storing the count value of the C1 error.

(3) The optical disk device according to the above (1) or (2), wherein the detection means forms a part of the signal processing means.

(4) The optical disk device according to any one of (1) to (3), wherein the counting means forms a part of the control means.

(5) The optical disk device according to any one of (1) to (4), further including a transmission unit configured to transmit a count value of the C1 error or information obtained from the count value to an external device.

(6) The optical disk apparatus according to any one of (1) to (5), based on the count value of the C1 error obtained when reproducing or recording / reproducing the reference disk in the optical disk apparatus. An inspection method for an optical disk device, wherein a reproduction capability or a recording / reproduction capability is determined.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an optical disk device and an inspection method of the optical disk device according to the present invention will be described in detail based on preferred embodiments shown in the accompanying drawings.

FIG. 1 is a block diagram showing a state in which the optical disk device of the present invention is connected to a computer, and FIG. 2 is a block diagram showing an embodiment of the optical disk device of the present invention.

The optical disk device 1 shown in these figures is a CD-R drive device for recording and reproducing an optical disk (CD-R) 2.

A spiral pre-groove (WOBBLE: not shown) is formed on the optical disk 2.

This pre-groove meanders at a predetermined period (22.05 kHz at 1 × speed), and the pre-groove has an ATIP (Absolute Time In Pre-Groove).
) Information (time information) is recorded. In this case, A
The TIP information is bi-phase modulated.
It is FM-modulated and recorded at a carrier frequency of 05 kHz.

The pregroove functions as a guide groove when forming pits / lands on the optical disc 2 (pit / land recording). Also, this pre-groove is played,
It is used for controlling the rotation speed of the optical disc 2 and for specifying the recording position (absolute time) on the optical disc 2.

The optical disk device 1 includes a turntable and a spindle motor 8 for rotating the turntable.
It has a rotation drive mechanism (not shown) for mounting the optical disk 2 on the turntable and rotating it. A Hall element 9 is installed near the spindle motor 8.

The optical disk apparatus 1 has an optical head (optical pickup) 3 that can move in the radial direction of the optical disk 2 (radial direction of the turntable) with respect to the loaded optical disk 2 (turntable), and An optical head main body moving mechanism (not shown) including a sled motor 5 for moving the head 3 in the radial direction, that is, an optical head main body (optical pickup base) of the optical head 3 described later in the radial direction, and drivers 6 and 11 And PWM
Signal smoothing filters 7 and 12, control means 13,
A laser control unit 14, an HF signal generation circuit 15, an HF signal gain switching circuit 16, a peak / bottom detection circuit 17, an error signal generation circuit 18, a WOBBLE signal detection circuit 19, a CD servo controller 21, a WO
BBLE servo controller 22, FG signal binarization circuit 23, EFM / CDROM encoder control unit 24
, Memories 25, 26 and 29, a sync signal generation / ATIP decoder 27, a CDROM decoder control unit 28, an interface control unit 31, a clock 3
2, 33, 34 and 35 and a casing 10 for accommodating them. Hereinafter, the radial direction of the optical disk 2 is simply referred to as “radial direction”.

The optical head 3 includes an optical head body (optical pickup base) (not shown) having a laser diode (light source) and a split photodiode (light receiving element),
An objective lens (condensing lens). The driving of the laser diode is controlled by the laser controller 14.

The objective lens is supported by a suspension spring (not shown) provided on the optical head main body, and can move in the radial direction and the rotation axis direction of the optical disk 2 (turntable) with respect to the optical head main body. ing. When the objective lens deviates from its neutral position (middle point), the objective lens is urged toward the neutral position by the restoring force of the suspension spring. Hereinafter, the direction of the rotation axis of the optical disc 2 will be simply referred to as “the direction of the rotation axis”.

The optical head 3 has an actuator 4 for moving the objective lens in the radial direction and the rotation axis direction with respect to the optical head body.

The control means 13 is usually constituted by a microcomputer (CPU), and comprises an optical head 3 (actuator 4), a sled motor 5, a spindle motor 8, a laser control unit 14, an HF signal gain switching circuit 16, a peak / bottom Detection circuit 17, CD servo controller 2
1, WOBBLE servo controller 22, EFM / C
DROM encoder control unit 24, memories 25 and 26,
29, sync signal generation / ATIP decoder 27, CDR
OM decoder control unit 28, interface control unit 31
For example, the entire optical disk device 1 is controlled.

The address, data, and COMMAN are sent from the control means 13 via an address / data bus 36.
D (command) and the like are input to the EFM / CDROM encoder control unit 24, the memory 26, the sync signal generation / ATIP decoder 27, the CDROM decoder control unit 28, the interface control unit 31, and the like.

An external device (computer 41 in this embodiment) is detachably connected to the optical disk device 1 via an interface control section 31 so that communication between the optical disk device 1 and the computer 41 can be performed. it can.

The interface control unit 31 includes, for example, ATAPI (IDE) (Attape standard), SC
SI (squay standard) or the like is used.

The computer 41 has a keyboard 4
2. The mouse 43 and the monitor 44 are connected respectively. Note that a transmission unit is configured by the interface control unit 31.

Further, an HF signal generation circuit 15, an HF signal gain switching circuit 16, a peak / bottom detection circuit 17,
Error signal generation circuit 18, WOBBLE signal detection circuit 1
9. The signal processing means is constituted by the CD servo controller 21 and the WOBBLE servo controller 22.

Next, the operation of the optical disk device 1 will be described. The optical disc device 1 records (writes) and reproduces (reads) information (data) on the optical disc 2 while performing focus control, tracking control, thread control, and rotation speed control (rotation speed control) on a predetermined track. I do. Hereinafter, recording, reproduction, focus control, tracking control and thread control,
The operation at the time of rotation speed control (rotation speed control) will be described.

First, as a premise, a predetermined COMMAND signal is input from the control means 13 to the CD servo controller 21 as shown in FIG. Control means 1
From 3, a predetermined COMMAND signal is input to the WOBBLE servo controller 22.

This COMMAND signal is supplied to the control means 13
Is a signal indicating a predetermined command (for example, start of control, etc.) to the CD servo controller 21 or the WOBBLE servo controller 22 from the controller.

Then, a predetermined STATUS signal is input to the control means 13 from the CD servo controller 21. Further, a predetermined STATUS signal is input from the WOBBLE servo controller 22 to the control means 13.

The STATUS signal is a signal indicating a response to the command, that is, information on the control (for example, statuses such as control success, control failure, and control execution).

[Recording] Recording (writing) data (signal) on the optical disc 2
At this time, the pre-groove formed on the optical disc 2 is reproduced (read), and thereafter, data is recorded along the pre-groove.

When data (signal) to be recorded on the optical disk 2 is input to the optical disk device 1 via the interface control unit 31, the data is converted into EFM / CRO.
It is input to the M encoder control unit 24.

In the EFM / CDROM encoder control section 24, the data is encoded based on the clock signal from the clock 34 (at the timing of the clock signal), and modulated by a modulation method called EFM (Eight to Fourteen Modulation). EFM modulation) and ENC
This is an ORDE EFM signal.

As shown in FIG. 3, this ENCODE
The EFM signal is a signal composed of pulses having a length (period) of 3T to 11T.

As shown in FIGS. 4 and 5, EF
In the M / CDROM encoder control unit 24, the clock 3
4 is divided to generate a SUBCODE-SYNC signal (subcode sync signal) composed of pulses of a predetermined cycle. This SUBCODE-SY
Cycle of NC signal pulse (interval between adjacent pulses)
Is 1/75 second at 1 × speed.

At the time of encoding, the synchronization signal, that is, the SYNC pattern (sync pattern)
Based on the BCODE-SYNC signal (SUBCODE
-At the timing of the SYNC signal), the ENCODE
It is added to the EFM signal. That is, SYNC is added to the portion corresponding to the head of each subcode frame.
A pattern is added.

This ENCODE EFM signal is output from the EF
The data is input from the M / CDROM encoder control unit 24 to the laser control unit 14.

Further, the analog signal WRITE P
An OWER signal (voltage) is output from a D / A converter (not shown) built in
Is input to

The laser control unit 14 has an ENCODE E
On the basis of the FM signal, the WRITE
The level of the POWER signal is switched between a high level (H) and a low level (L) and output, whereby the driving of the laser diode of the optical head 3 is controlled.

More specifically, the laser control unit 14
While the level of the ORDE EFM signal is high (H), the level of the WRITE POWER signal is set to high (H) and output. That is, the output of the laser is increased (write output). And ENCODE
While the level of the EFM signal is low (L), the WRI
The level of the TE POWER signal is set to a low level (L) and output. That is, the output of the laser is reduced (return to read output).

As a result, the optical disk 2 has an ENCO
When the level of the RDE EFM signal is high (H), a pit of a predetermined length is written, and ENCODE EFM is written.
When the level of the FM signal is low (L), a land of a predetermined length is written.

In this way, data is written (recorded) on a predetermined track of the optical disc 2.

EFM / CDROM encoder control unit 24
In, a predetermined ENCODE EFM signal (random EFM signal) is generated in addition to the above-mentioned ENCODE EFM signal. This random EFM signal is output from the OPC (Opti
mum Power Control) is used for laser output adjustment (power control) at the time of test writing to the test area.

At the time of test writing in the test area in the OPC, the random EFM signal is generated by the EFM / CRO
The data is input from the M encoder control unit 24 to the laser control unit 14.

At the time of test writing in the test area in the OPC, the control means 13 generates a WRITE POWER signal of 15 levels and outputs the WRITE POWER signal.
The EPOWER signal is output from a D / A converter (not shown) built in the control unit 13 and input to the laser control unit 14.

Then, the laser control unit 14 receives the WRIT from the control unit 13 based on the random EFM signal.
The level of the E POWER signal is switched between a high level (H) and a low level (L) and output, thereby controlling the driving of the laser diode of the optical head 3. This is performed for each of the WRITE POWER signals of 15 levels.

In the OPC operation, the test writing to the test area is performed with the laser light having the 15-step output in this manner.

When data is written to the optical disk 2, a laser beam of read output is irradiated from the laser diode of the optical head 3 to the pregroove of the optical disk 2, and the reflected light is received by the divided photodiode of the optical head 3. Is done.

The split photodiode outputs a WOBBLE signal shown in FIG. As described above, the WOBBLE signal includes a signal having a frequency of 22.05 kHz at 1 × speed, and a signal obtained by performing biphase modulation on ATIP information and further performing FM modulation at a carrier frequency of 22.05 kHz.

The WOBBLE signal is input to the WOBBLE signal detection circuit 19, and is binarized by the WOBBLE signal detection circuit 19.

The binarized WOBBLE signal is the WOB signal.
This is input to the BLE servo controller 22.

In the WOBBLE servo controller 22, the FM-modulated AT of the WOBBLE signal is used.
The IP information is demodulated to obtain a BIDATA signal (bi-phase data signal) shown in FIG. This BIDATA signal is a signal (pulse signal) of 1T to 3T. Note that this BIDATA signal is bi-phase demodulated and then decoded to obtain ATIP information.

The WOBBLE servo controller 2
2, a digital PLL circuit (not shown) generates a clock based on the BIDATA signal,
The BICLOCK signal shown in FIG. 7 is obtained. This BICLO
The CK signal is used for decoding timing of a BIDATA signal described later.

The BIDATA signal and the BICLOC
The K signals are input to the sync signal generation / ATIP decoder 27, respectively.

The sync signal generation / ATIP decoder 27 bi-phase demodulates the BIDATA signal based on the BICLOCK signal, and then decodes and decodes the ATIP signal.
Information is obtained, and an ATIP-SYNC signal (ATIP sync signal) shown in FIG. 7 is generated.

In this case, as shown in FIG.
When a SYNC pattern included in the A signal is detected, a pulse of the ATIP-SYNC signal is generated. The period of the pulse of the ATIP-SYNC signal (the interval between adjacent pulses) is 1/75 second at 1 × speed.

This ATIP-SYNC signal is input to each of the control means 13 and the WOBBLE servo controller 22.

The decoded ATIP information is input to the control means 13. The control means 13 grasps the absolute time on the optical disc 2 based on the ATIP information.

The SUBCODE-SYNC signal from the EFM / CDROM encoder control unit 24 is input to a sync signal generation / ATIP decoder 27.
And WOBBLE servo controller 22.

FIG. 8 is a diagram showing the format of an ATIP frame. As shown in the figure, the data of the ATIP frame is a 4-bit synchronization signal, that is, a sync (S
yn), an 8-bit minute (Min), an 8-bit second (Sec), an 8-bit frame, and a 14-bit error detection code (CRC: Cyclic Redundancy Code).

In the WOBBLE servo controller 22, an error (error) in the ATIP information is detected for each ATIP frame (determining whether or not the ATIP information is incorrect).

In the error detection of the ATIP information, the ATI
"Normal" means that the result of performing a predetermined operation on the Sync, minute (Min), second (Sec) and frame data of the P frame matches the error detection code (CRC), Say "ATIP error."

In this case, as shown in FIG.
In the E servo controller 22, an error in the ATIP information,
That is, when an ATIP error is detected, a pulse 51 is generated and output.

ATIP E composed of this pulse 51
The RROR signal is input to a counter (counter) 131 of the controller 13. And this counter 13
1, the number of pulses of the ATIP ERROR signal becomes A
It is counted (measured) as a TIP error.

The error detection of the ATIP information is performed by the ATIP
Since it is performed for each frame, the ATIP error is 75 A
There are a maximum of 75 TIP frames (1 second at 1 × speed).

The WOBBLE servo controller 2
2 constitutes a detecting means for detecting an ATIP error.

The count value of the ATIP error is stored in the memory 26 and the interface control unit 3
1 and transmitted to the computer 41 for use in the inspection of the optical disk device 1 (determination of the recording capability of the optical disk device 1).

The ATIP-input to the control means 13
The SYNC signal is used for updating the ATIP time information.

Further, the WOBBLE servo controller 2
2, the ATIP-SYNC signal is input to the SUBCO
Used for synchronization with the DE-SYNC signal.

The SUBCODE input to the control means 13
The -SYNC signal is used for interpolation of ATIP time information and measurement of the ATIP error described above.

Also, the WOBBLE servo controller 2
The SUBCODE-SYNC signal input to 2 is used as a reference signal for synchronization, like the ATIP-SYNC signal.

The synchronization is performed so that the position of the SUBCODE-SYNC signal in the EFM data generated at the time of writing substantially matches the position of the ATIP-SYNC signal on the optical disk 2 where the ATIP-SYNC signal is generated.

As shown in FIG. 9, SUBCODE-SY
The difference between the NC signal and the ATIP-SYNC signal is usually
± 2E at each part of the entire optical disc 2
Up to FM frames are allowed.

[Reproduction] When reproducing (reading) data (signal) from the optical disc 2, the WRITE POW from the laser control unit 14 is used.
The level of the ER signal is a constant D corresponding to the read output.
The output is held at the C level, whereby the output of the laser is held at the read output. The read output (output of the main beam) is usually set to 0.7 mW or less.

When reading data from the optical disk 2,
A read output laser beam is radiated from a laser diode of the optical head 3 onto a predetermined track of the optical disc 2,
The reflected light is received by the split photodiode of the optical head 3.

Each light receiving section of the divided photodiode outputs a current (voltage) corresponding to the amount of received light, and these currents, ie, each signal (detection signal)
Each is input to the HF signal generation circuit 15 and the error signal generation circuit 18.

The HF signal generation circuit 15 generates an HF (RF) signal by adding or subtracting these detection signals.

The HF signal is an analog signal corresponding to pits and lands written on the optical disk 2.

This HF signal is input to the HF signal gain switching circuit 16 and is amplified. The amplification factor (gain) of the HF signal gain switching circuit 16 is
Is switched by a gain switching signal from the controller.

The amplified HF signal (hereinafter simply referred to as “HF signal”
Signal) is input to each of the peak / bottom detection circuit 17 and the CD servo controller 21.

The peak / bottom detection circuit 17
A tracking error (TE) signal described in the focus control, tracking control, and sled control is input.

As shown in FIG. 10, the peak / bottom detection circuit 17 extracts an amplitude (envelope) of an input signal, for example, an HF signal or a tracking error signal.

The upper side of the amplitude is called PEEK (TOP), the lower side of the amplitude is called BOTTOM, the signal corresponding to the upper side of the amplitude is called a PEEK (TOP) signal, and the signal corresponding to the lower side of the amplitude is called a BOTTOM signal.

The PEEK signal and the BOTTOM signal are
A (not shown) built in the control means 13
The signal is input to a / D converter, and is converted into a digital signal by the A / D converter.

The PEEK signal and the BOTTOM signal are used for, for example, amplitude measurement, amplitude adjustment of a tracking error signal, and β in OPC (Optimum Power Control).
It is used for calculating (β value), determining the presence or absence of an HF signal, and the like.

In the CD servo controller 21, the HF signal is binarized, EFM demodulated, and an EFM signal is obtained. This EFM signal is a signal composed of pulses having a length (period) of 3T to 11T.

Then, the CD servo controller 21 responds to the EFM signal with a CIRC (Cross Interl
Error correction (CIRC error correction) using an error correction code called “eaved Read Solomon Code” is performed twice.

In this case, the first CIRC correction is called C1 error correction, and the second CIRC correction is called C2 error correction.

A case where the first CIRC correction, ie, the C1 error correction cannot be performed, is referred to as “C1 error”, and a case where the second CIRC correction, ie, the C2 error correction cannot be performed, is referred to as “C2 error”.

As shown in FIG. 11, in the CD servo controller 21, when a C1 error is detected during the C1 error correction, a pulse 52 is generated and output.

C1 ERROR constituted by this pulse 52
The R signal is input to the counter 131 of the control means 13. The counter counts (measures) the number of pulses of the C1ERROR signal as a C1 error.

Since one subcode frame is composed of 98 EFM frames, the C1 error and the C2 error are
75 subcode frames each (1 second at 1x speed)
, There are a maximum of 7,350.

The CD servo controller 21 constitutes a detecting means for detecting a C1 error.

The count value of the C1 error is stored in the memory 26.
Is transmitted to the computer 41 via the interface control unit 31 and is used for the inspection of the optical disk device 1 (determination of the reproduction capability or the recording / reproduction capability of the optical disk device 1).

In the CD servo controller 21, the CIR
The EFM signal after the C error correction is decoded (converted) into data of a predetermined format, that is, a DATA signal.

Hereinafter, typically, audio data (music data) is recorded on the optical disc 2 and its EFM
A case where a signal is decoded into a DATA signal in an audio format will be described.

FIG. 12 is a timing chart showing the audio format DATA signal, LRCLOCK signal, and BITCLOCK signal.

As shown in the figure, in the CD servo controller 21, the EFM signal is composed of 16-bit L channel data and 16-bit R channel data based on the clock signal from the clock 33.
Decoded to ATA signal.

Further, in the CD servo controller 21,
BITC based on the clock signal from clock 33
A LOCK signal and an LRCLOCK signal are generated, respectively.

The BITCLOCK signal is a serial data transfer clock. The LRCLOCK signal is a signal for distinguishing L channel data and R channel data in the DATA signal. In this case, L
A high level (H) of the RCLOCK signal indicates L channel data, and a low level (L) indicates R channel data.

Even when ordinary data is recorded on the optical disk 2, the EFM signal is decoded into the above-mentioned DATA signal composed of 16-bit L channel data and 16-bit R channel data. .

The DATA signal, LRCLOCK signal and BITCLOCK signal are respectively
The data is input to the decoder control unit 28.

In the CDROM decoder control section 28, correction information such as ECC (Error Correc
If an error correction code of (Edtion Code) / EDC (Error Detecting Code) is recorded, the error correction is performed on the DATA signal.

This ECC / EDC is a CD-ROM M
This is an error correction code in the ODE1 format.
By this error correction, the bit error rate can be reduced to about 10 ⁻¹² .

In the CDROM decoder control unit 28, the DATA signal is decoded into data of a predetermined format for communication (transmission) based on the clock signal from the clock 35, and the decoded data (decoded data) Is transmitted to the computer 41 via the interface control unit 31.

On the computer 41 side, for example, the decoded data is encoded, and the encoded data (encoded data) is recorded (copied) on a predetermined recording medium (for example, an optical disk).

Further, in the CD servo controller 21,
The FRAME SYNC signal shown in FIG. 13 is generated.

The level of the FRAME SYNC signal becomes a high level (H) when the HF signal is input to the CD servo controller 21 and the EFM signal is synchronized at a specified period (3T to 11T). And HF
When a signal (EFM signal) is not input (when synchronization is lost), FRAME S is output in EFM frame units.
The level of the YNC signal changes from a high level (H) to a low level (L).

The length (period) of one EFM frame
Is 136 μsec at 1 × speed, and 98 EFM frames are one subcode frame.

The FRAME SYNC signal is input to the control means 13 and used for detecting the end of the HF signal.

The SUBQ DATA signal is input from the CD servo controller 21 to the control means 13.

This SUBQ DATA signal is a signal indicating Q data of the subcode data.

The subcodes include P, Q, R, S, T,
There are eight types, U, V and W. One EFM frame has one byte of subcode, and one byte of each of the data P to W is recorded in one byte.

Each data of P to W is one bit, and one subcode frame is a 98 EFM frame. Therefore, each data of P to W in one subcode frame is 98 bits. However, the first 2EF
Since the M frame is used for a SYNC pattern (synchronization signal), the actual data is 96 bits.

FIG. 14 shows a format of 96 bits of Q data. The controls (4 bits) of Q1 to Q4 shown in FIG. 6 are used for discriminating normal data / audio data.

Addresses Q5 to Q8 (4 bits)
Indicates the contents of data (72 bits) from Q9 to Q80.

The CRC (Cyclic R) of Q81 to Q96
The edundancy code (16 bits) is used for error (error) detection (determination of whether or not data is incorrect).

From the Q data, further, absolute time information on the optical disk 2, current track information, lead-in / lead-out, music number, and a table of contents called TOC (Table Of Contents) recorded in the lead-in. Contents and the like can be obtained.

The control means 13 obtains information from such Q data and performs predetermined control.

The SUBCODE-SYNC signal is input from the CD servo controller 21 to the control means 13.

As shown in FIG. 15, the subcode data has 98 bytes in the 98 EFM frame. As described above, the two bytes of the first 2 EFM frames, ie, S0 and S1, have the SYNC pattern (synchronous signal). ) Is recorded.

In the CD servo controller 21, this S
When the YNC pattern is detected, a pulse is generated and output. That is, one subcode frame (98EF)
For every M frames), a pulse is generated and output. The signal composed of this pulse is SUBCODE-SYN
This is the C signal. The SYNC pattern is detected 75 times per second at 1 × speed.

Note that the CD servo controller 21
After detecting the pulse of the SUBCODE-SYNC signal, the above-described Q data is updated. Then, the updated Q data is read into the control means 13.

[Focus Control, Tracking Control, and Thread Control] The error signal generation circuit 18 performs addition and subtraction of the detection signals from the divided photodiodes described above, and so on.
A focus error (FE) signal, a tracking error (TE) signal, and a thread error (SE) signal are respectively generated.

This focus error signal is a signal indicating the magnitude and direction of the shift of the objective lens from the focus position in the direction of the rotation axis (the shift amount of the objective lens from the focus position).

The tracking error signal is a signal indicating the magnitude of the displacement of the objective lens in the radial direction from the center of the track (pre-groove) and its direction (the amount of displacement of the objective lens from the center of the track).

The thread error signal is an error (error) signal used for thread control, that is, thread servo (feed servo of the optical head body of the optical head 3). In other words, it is a signal indicating the magnitude and direction of the displacement of the optical head 3 in the radial direction (the feed direction of the optical head 3) from the target position (proper position) of the optical head 3. The focus error signal is input to the CD servo controller 21.

The tracking error signal is input to the CD servo controller 21 and also to the peak / bottom detection circuit 17 as described above. The thread error signal is output from the CD servo controller 2
1 is input.

Using the focus error signal, tracking error signal and thread error signal, the optical disc device 1 performs focus control, tracking control and thread control on a predetermined track.

At the time of focus control, the CD servo controller 21 performs focus PWM (Puls Width Modulation) control for driving the actuator 4 in the rotation axis direction.
) A signal is generated. This focus PWM signal is
It is a digital signal (continuous pulse).

The focus PWM signal is input from the CD servo controller 21 to the PWM signal smoothing filter 7, and is smoothed by the PWM signal smoothing filter 7, that is, converted into a control voltage (control signal).
Is input to Then, the driver 6 applies a focus signal (predetermined voltage) to the actuator 4 based on the control voltage, and drives the actuator 4 in the rotation axis direction (focus direction).

In this case, the CD servo controller 21
Is to adjust the pulse width (duty ratio) of the focus PWM signal so that the level of the focus error signal becomes 0 (as much as possible), and
The sign (positive / negative) of the WM signal is inverted. This allows
The objective lens of the optical head 3 is located at the focus position. That is, focus servo is applied.

In the tracking control, the CD servo controller 21 generates a tracking PWM signal for controlling the radial driving of the actuator 4.
This tracking PWM signal is a digital signal (continuous pulse).

The tracking PWM signal is input from the CD servo controller 21 to the PWM signal smoothing filter 7, and smoothed by the PWM signal smoothing filter 7.
That is, it is converted into a control voltage (control signal) and input to the driver 6. The driver 6 applies a tracking signal (predetermined voltage) to the actuator 4 based on the control voltage, and drives the actuator 4 in the radial direction (tracking direction).

In this case, the CD servo controller 21
The tracking PWM is adjusted so that the level of the tracking error signal becomes zero (as much as possible).
The pulse width (duty ratio) of the signal is adjusted, and the sign (positive or negative) of the thread PWM signal is inverted. Thereby, the objective lens of the optical head 3 is located at the center of the track (pre-groove). That is, tracking servo is applied.

At the time of thread control, the CD servo controller 21 generates a thread PWM signal for controlling the drive of the thread motor 5. This thread PW
The M signal is a digital signal (continuous pulse).

The thread PWM signal is input from the CD servo controller 21 to the PWM signal smoothing filter 7, smoothed by the PWM signal smoothing filter 7, that is, converted into a control voltage (control signal) and input to the driver 6. You. The driver 6 sends a sled signal (predetermined voltage) to the sled motor 5 based on the control voltage.
To drive the thread motor 5 to rotate.

In this case, the CD servo controller 21
Is to adjust the pulse width (duty ratio) of the thread PWM signal and to reverse the sign (positive / negative) of the thread PWM signal so that the level of the thread error signal becomes 0 (as much as possible). I do. Thereby, the optical head main body of the optical head 3 is located at the target position (appropriate position). That is, the thread servo is applied.

Incidentally, in addition to tracking control, the tracking error signal is generated by, for example, connecting the optical head 3 to the optical disk 2.
This is also used for control (track jump operation) when moving to a predetermined track (target track).

[Rotation Number Control (Rotation Speed Control)] In the optical disk device 1, for example, during recording and reproduction,
The rotation speed (rotation speed) of the spindle motor 8 is controlled. The method of controlling the number of rotations includes WOBBLEPWM
(Puls Width Modulation) signal, that is, a spindle servo (W) using a WOBBLE signal.
OBBLE servo) and a method of controlling with an FG PWM signal, that is, a spindle servo (F
G servo) and a method of controlling with an EFM PWM signal, that is, a spindle servo (EFM) using an EFM signal
Servo). Hereinafter, these will be sequentially described.

The WOBBLE PWM signal is WOBBL
This is a spindle motor control signal generated by the E servo controller 22. Specifically, it is a digital signal (continuous pulse) of 0-5V level.

This WOBBLE PWM signal is
The signal is input from the BLE servo controller 22 to the PWM signal smoothing filter 12, smoothed by the PWM signal smoothing filter 12, that is, converted into a control voltage (control signal), and input to the driver 11. And driver 1
1 drives the spindle motor 8 to rotate based on the control voltage.

In this case, the WOBBLE servo controller 22 sets the pulse width (duty ratio) of the WOBBLE PWM signal so that the frequency (period) of the WOBBLE signal becomes a target value (for example, 22.05 kHz at 1 × speed). Adjust). Thus, the spindle servo is operated so that the rotation speed (rotation speed) of the spindle motor 8 becomes the target value.

The FG PWM signal is a spindle motor control signal generated by the control means 13. In particular,
It is a digital signal (continuous pulse) of 0-5V level.

The FG PWM signal is input from the control means 13 to the PWM signal smoothing filter 12,
The signal is smoothed by an M signal smoothing filter 12, that is, converted into a control voltage (control signal) and input to the driver 11. Then, the driver 11 drives the spindle motor 8 to rotate based on the control voltage.

On the other hand, from the Hall element 9, the FG (Frequenc) corresponding to the rotation speed (rotation speed) of the spindle motor 8 is obtained.
y Generator) signal is output. This FG signal is
The signal is binarized by a G signal binarization circuit 23 and input to a frequency measurement unit (period measurement unit) (not shown) of the control unit 13.

The frequency measuring section of the control means 13 measures the frequency (period) of the FG signal based on the clock signal from the clock 32. Then, the control means 13
The pulse width (duty ratio) of the FG PWM signal is adjusted so that the frequency (cycle) of the G signal becomes a target value. Thus, the spindle servo is operated so that the rotation speed (rotation speed) of the spindle motor 8 becomes the target value.

The EFM PWM signal is a spindle motor control signal generated by the CD servo controller 21. Specifically, it is a digital signal (continuous pulse) of 0-5V level.

The EFM PWM signal is input from the CD servo controller 21 to the PWM signal smoothing filter 12, and is smoothed by the PWM signal smoothing filter 12.
That is, it is converted into a control voltage (control signal) and input to the driver 11. Then, the driver 11 drives the spindle motor 8 to rotate based on the control voltage.

In this case, the CD servo controller 21
Adjusts the pulse width (duty ratio) of the EFM PWM signal such that the period of a predetermined pulse of the EFM signal, that is, the pulse having a period of 3T to 11T, becomes a target value. Thus, the spindle servo is operated so that the rotation speed (rotation speed) of the spindle motor 8 becomes the target value.

Next, a method for inspecting the optical disk device 1 will be described. Hereinafter, the reproduction capability or recording /
A method for checking the reproduction ability and a method for checking the recording ability of the optical disc device 1 will be sequentially described.

The reproduction capability or recording /
In the case of the inspection of the reproduction capability, a reference disk (an optical disk having substantially no defect) is mounted on the optical disk device 1 and C
The number (count value) of one error is obtained.

In this case, the data is read out from the reference disk in which the data is recorded in advance, and the C1 at that time is read.
Find the number of errors.

Further, predetermined data is written to an unrecorded reference disk, and the data is read out.
Find the number of errors.

Next, the control operation of the control means 13 at the time of inspection of the optical disk device 1 will be described.

FIG. 16 is a flowchart showing the control operation of the control means 13. Hereinafter, description will be made with reference to FIG.

When a C1 error reading command is received, this program (C1 error reading routine) is executed.

First, a C1 error reading mode is set (step S101). Next, initialization is performed (step S102). In this initial setting, the count value of a counter 131 incorporated in the control means 13 is set to 0, and the count value N of a subcode sync counter (not shown) is set to 0.

Next, it is determined whether or not a SUBCODE-SYNC signal from the CD servo controller 21 has been detected (step S103).
When it is determined that the YNC signal has been detected, the counter 131 is activated to count (count) the C1 error.
Is started (step S104).

Next, it is determined whether or not a SUBCODE-SYNC signal from the CD servo controller 21 has been detected (step S105), and the SUBCODE-S signal is detected.
If it is determined that the YNC signal has been detected, the count value N of the subcode sync counter is incremented by one (N = N + 1) (step S106).

Next, it is determined whether or not N = 75 (step S107). If it is determined in step S107 that N ≦ 74, the process returns to step S105, and steps S105 and subsequent steps are executed again.

In step S107, N = 75.
When it is determined that the counter 131 is stopped,
The counting of the C1 error ends (step S10).
8).

Steps S104 to S10
8, 75 subcode frames (1 second at 1x speed)
The number of C1 errors per 7350 (98 × 75) EFM frames (count value) is determined. In other words, the count value of the counter 131 is the number of C1 errors per 75 subcode frames.

Next, the count value of the counter 131 is read out and stored in the memory 26 (step S).
109). This ends the program.

The number of C1 errors is read from the memory 26, and is read as a command response message from the computer 41.
Send to

The computer 41 displays the number of C1 errors on the monitor 44. In this inspection, for example, when data is read from the reference disk at 6 × speed and the number of C1 errors per 75 subcode frames (1/6 second at 6 × speed) is 20 or less, the optical disk device 1 It is determined that there is no problem in the reproduction ability of the player, and if it exceeds 20, it is determined that there is a problem.

In the case of testing the recording capability (strictly speaking, the WOBBLE signal reproduction capability) of the optical disk device 1,
Number of ATIP errors (count value) when a reference disk (optical disk having substantially no defect) is mounted on the optical disk device 1.
Ask for.

In this case, A from the unrecorded reference disk
TIP errors are counted to determine the number of ATIP errors.

Further, predetermined data is written on an unrecorded reference disk, and A
TIP errors are counted to determine the number of ATIP errors.

Next, the control operation of the control means 13 at the time of inspection of the optical disk device 1 will be described.

FIG. 17 is a flowchart showing the control operation of the control means 13. Hereinafter, description will be made with reference to FIG.

Upon receiving an ATIP error reading command, this program (ATIP error reading routine) is executed.

First, an ATIP error reading mode is set (step S201). Next, initialization is performed (step S202). In this initial setting, the control means 1
The count value of the counter 131 built in 3 is set to 0
At the same time, the count value N of the subcode sync counter (not shown) is set to 0.

Next, the SUBCODE-SYNC signal from the sync signal generation / ATIP decoder 27 and the ATIP-SY signal from the sync signal generation / ATIP decoder 27
Synchronize with the NC signal (step S203).

In step S203, a synchronization command is issued as shown in FIG. Thereby, in the sync signal generation / ATIP decoder 27,
SUBCODE-SYNC signal and ATIP-SYNC
Synchronization with the signal is performed, and the subsequent SUBCODE-
The SYNC signal and the ATIP-SYNC signal are synchronized.

Next, it is determined whether or not the SUBCODE-SYNC signal from the sync signal generation / ATIP decoder 27 has been detected (step S204).
If it is determined that the ODE-SYNC signal has been detected, the counter 131 is activated to start counting the ATIP error (step S205).

Next, it is determined whether or not the SUBCODE-SYNC signal from the sync signal generation / ATIP decoder 27 has been detected (step S206).
When it is determined that the ODE-SYNC signal has been detected, the count value N of the subcode sync counter is counted.
Is incremented by one (N = N + 1) (step S
207).

Next, it is determined whether or not N = 75 (step S208). If it is determined in step S208 that N ≦ 74, the process returns to step S206, and step S206 and subsequent steps are executed again.

In step S208, N = 75.
When it is determined that the counter 131 is stopped,
The counting of the ATIP error ends (step S20).
9).

Steps S205 to S20
According to 9, 75 subcode frames (1 second at 1x speed)
The number (count value) of ATIP errors per unit is obtained. In other words, the count value of the counter 131 is the number of ATIP errors per 75 subcode frames.

Next, the count value of the counter 131 is read and stored in the memory 26 (step S).
209). This ends the program.

The number of ATIP errors is read from the memory 26 and transmitted to the computer 41 as a command response message.

On the computer 41 side, the number of ATIP errors is displayed on the monitor 44. In this inspection, for example, when data writing to the reference disk is performed at 1 × speed and the number of ATIP errors per 75 subcode frames (1 second at 1 × speed) is 0, the recording of the optical disk device 1 is performed. It is judged that there is no problem in the ability, and when it is 1 or more, it is judged that there is a problem.

As described above, according to the optical disk device 1, since the counter 131 for counting the C1 error is built in, the optical disk device 1 does not need to externally connect (connect) an error rate counter. When performing a service such as repair, the C1 error can be easily and reliably counted without disassembling the optical disk device 1.

In particular, when the C1 error is counted in the production line, it is not necessary to install an error rate counter for counting the C1 error in the production line, so that the C1 error can be counted without increasing the equipment. .

According to the optical disk device 1, A
Since the counter 131 for counting the TIP error is built in, the error rate counter is not externally connected (connected) to the optical disk device 1, and when a service such as repair is performed, the optical disk device 1 is not disassembled. ATIP errors can be counted easily and reliably.

In particular, when ATIP errors are counted on the production line, it is not necessary to install an error rate counter for counting the ATIP errors on the production line, so that the ATIP errors can be counted without increasing the equipment. .

The optical disk device of the present invention is the same as the above-described CD.
-R drive device, other than this, for example, CD-R
Various optical disk devices for recording and reproducing optical disks having a pre-groove such as W, DVD-R, DVD-RAM,
The present invention can be applied to various optical disk devices for reproducing optical disks such as CDs (compact disks) and CD-ROMs.

The optical disk device of the present invention has been described based on the illustrated embodiment. However, the present invention is not limited to this, and each component may have any configuration having the same function. Can be replaced by

[0197]

As described above, according to the optical disc apparatus of the present invention, the detecting means for detecting the C1 error,
Built-in counting means for counting one error, externally connecting (connecting) an error rate counter to the optical disk device
Therefore, the C1 error can be counted easily and reliably.

According to the optical disk device inspection method of the present invention, since the optical disk device has a built-in detecting means for detecting a C1 error and a counting means for counting the C1 error, it can be easily and reliably provided. The optical disk device can be inspected.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a state where an optical disk device of the present invention is connected to a computer.

FIG. 2 is a block diagram showing an embodiment of the optical disk device of the present invention.

FIG. 3 is a timing chart showing an ENCODE EFM signal from an EFM / CDROM encoder control unit and an ENCODE EFM signal from a laser control unit according to the present invention.

FIG. 4 shows an ATIP-SYNC signal according to the present invention and SUBCODE from a sync signal generation / ATIP decoder;
6 is a timing chart showing a -SYNC signal and an ATIP ERROR signal.

FIG. 5 shows an ATIP-SYNC signal according to the present invention and a SUBCODE from a sync signal generation / ATIP decoder.
-SYNC signal and SU from CD servo controller
6 is a timing chart showing a BCODE-SYNC signal.

FIG. 6 shows 1T Biphase ATI according to the present invention.
P timing, WOBBLE signal, WO after binarization
6 is a timing chart showing a BLE signal.

FIG. 7 shows a BIDATA signal and BICL according to the present invention.
5 is a timing chart showing an OCK signal and an ATIP-SYNC signal.

FIG. 8 is a diagram showing a format of an ATIP frame according to the present invention.

FIG. 9 shows an ATIP-SYNC signal and S
6 is a timing chart showing a UBCODE-SYNC signal.

FIG. 10 shows an input signal to a peak / bottom detection circuit according to the present invention, the amplitude (envelope) of the input signal,
6 is a timing chart showing a PEEK signal and a BOTTOM signal.

FIG. 11 is a timing chart showing a SUBCODE-SYNC signal and a C1ERROR signal from a CD servo controller according to the present invention.

FIG. 12 is a timing chart showing a DATA signal, an LRCLOCK signal, and a BITCLOCK signal in an audio format according to the present invention.

FIG. 13 shows a SUBCODE-SYNC signal from a CD servo controller and FRAME SY in the present invention.
6 is a timing chart showing an NC signal and an HF signal (EFM signal).

FIG. 14 is a diagram showing a format of 96 bits of Q data according to the present invention.

FIG. 15 is a diagram showing one subcode frame in the present invention.

FIG. 16 is a flowchart illustrating a control operation of a control unit according to the present invention.

FIG. 17 is a flowchart illustrating a control operation of a control unit according to the present invention.

FIG. 18 shows an ATIP-SYNC signal according to the present invention;
Sync signal generation / SUBCOD from ATIP decoder
5 is a timing chart showing an E-SYNC signal.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Optical disk drive 10 Casing 2 Optical disk 3 Optical head (optical pickup) 4 Actuator 5 Thread motor 6 Driver 7 PWM signal smoothing filter 8 Spindle motor 9 Hall element 11 Driver 12 PWM signal smoothing filter 13 Control means 131 Counter 14 Laser control unit 15 HF Signal generation circuit 16 HF signal gain switching circuit 17 Peak / bottom detection circuit 18 Error signal generation circuit 19 WOBLE signal detection circuit 21 CD servo controller 22 WOBBLE servo controller 23 FG signal binarization circuit 24 EFM / CDROM encoder control unit 25, 26 Memory 27 Sync signal generation / ATIP decoder 28 CDROM decoder controller 29 Memory 31 Interface controller 32 to 3 5 clock 36 address / data bus 41 computer 42 keyboard 43 mouse 44 monitor 51, 52 pulse S101-S109 step S201-S210 step

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI G11B 7/00 G11B 7/00 H 7/26 7/26

Claims (6)

[Claims] 1. A rotation drive mechanism for mounting and rotating an optical disk, an optical head, signal processing means for processing a signal read from the optical disk by the optical head, and at least the rotation drive mechanism, an optical head, and signal processing. An optical disk device for reproducing or recording / reproducing the optical disk, comprising a control unit for controlling the driving of the unit, comprising a detecting unit for detecting a C1 error, and a counting unit for counting the detected C1 error. An optical disc device characterized by performing: 2. The optical disk device according to claim 1, further comprising a memory for storing the count value of the C1 error. 3. The optical disk device according to claim 1, wherein the detection unit forms a part of the signal processing unit. 4. The optical disk device according to claim 1, wherein said counting means forms a part of said control means. 5. The optical disk device according to claim 1, further comprising a transmission unit configured to transmit a count value of the C1 error or information obtained from the count value to an external device. 6. A reproducing capability or recording of the optical disk device based on a count value of a C1 error obtained when reproducing or recording / reproducing a reference disk with the optical disk device according to claim 1. An inspection method of an optical disk device, which is characterized by determining a reproduction capability.