JPH11120708A - Optical disk device and objective sector accessing method for optical disk - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical disk device capable of reducing the time for accessing the objective sector. SOLUTION: This device having the plural sectors to which physical addresses 1-N are imparted in order from the head, and recording/reproducing information to/from the optical disk on which the defective information including the physical address of defective sector is recorded is provided with an address processing part 100 for calculating the physical address (X+a) by obtaining the number (a) of defective secotors included between the physical address 1 through the physical address X based on the defective information when the access is made to the X-th sector counted from the sector of the physical address 1 excluding the defective sectors, and a CPU 50 for accessing to the sector of the physical address calculated from a calculating means when accessing to the X-th sector.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disk apparatus for recording and reproducing information on an optical disk having a plurality of sectors. In particular, it relates to handling of defective sectors existing on an optical disk.

[0002]

2. Description of the Related Art Recently, DVDs have been used as large-capacity information storage media.
(Digital Video Disk)-RAM (random access memo)
Optical disks such as ry) are receiving attention. On such an optical disk, concentric or spiral tracks for recording data are formed. In this track, an area called a sector is formatted. Furthermore, the concept of a block is formed by a plurality of groups of the sectors. Recording of data on the optical disk and reproduction of data recorded on the optical disk are performed in units of this block.

[0003] Some sectors provided on an optical disk include defects for various reasons. A sector including such a defect is called a defective sector. Conversely, a sector containing no defect is called a normal sector. When information is recorded on the optical disk by the optical disk device, such a defective sector is not used. That is, when information is recorded on the optical disk by the optical disk device, the defective sector is skipped (skipped) and the information is recorded only in the normal sector. Such recording of information is referred to as slip replacement processing.

Here, the conventional flip replacement process will be described in more detail. Defect list information is recorded on the optical disc. The defect list information includes a physical address of the defective sector and an identification code in which the type of the defect is coded.

For example, on an optical disc, 1 to 1
It is assumed that there are a plurality of sectors to which N physical addresses are assigned. It is also assumed that, among the sectors at the physical addresses 1 to N, the sector at the physical address X (N ≧ X) is a defective sector. That is, the physical address X is included in the defect list information. Therefore, the actually existing sectors are the sectors at the physical addresses 1 to N, and the sectors actually used (the sectors to be recorded / reproduced) are the sectors at the physical addresses 1 to N excluding the sector at the physical address X. Since the rotation direction of the optical disk is constant, the access order is the sector of the physical address 1, the sector of the physical address 2,..., The sector of the physical address N.

[0006] Under such a premise, it is assumed that the X-th sector counted by excluding the defective sector from the sector at the physical address 1 is requested by the instruction of the optical disk device. That is, it is assumed that the sector of the logical address X is set as the target sector and the target sector must be accessed. In this case, first, the sector at the physical address 1 is accessed, and
It is confirmed whether the sector of the physical address 1 is not a defective sector. This confirmation is performed by referring to the defect list information. In this case, since the sector at the physical address 1 is a normal sector, the count value of the normal sector is “1”. Subsequently, the sector at the physical address 2 is accessed to check whether the sector at the physical address 2 is a defective sector. In this case, since the sector at the physical address 2 is a normal sector, the count value of the normal sector is “2”. In the same manner, counting of normal sectors is continued until the count value of normal sectors becomes “X”. That is, the sector for which the count value of the normal sector is “X” is the target sector.

When the sector of the physical address X is accessed, the sector of the physical address X is a defective sector, so that the count value of the normal sector remains "X-1". Therefore, counting of normal sectors is further continued. When the sector at the physical address (X + 1) is accessed, the sector at the physical address (X + 1) is a normal sector, and the count value of the normal sector is “X”.
That is, the sector of the logical address X requested by the instruction of the optical disk device becomes the sector of the physical address (X + 1).

[0008]

However, the above-described method of accessing the target sector has a problem that the access time is relatively long since the target sector is accessed while accessing the defective sector. Also,
This problem becomes more prominent as the position of the target sector is farther from the head sector.

An object of the present invention is to provide an optical disc apparatus and a method for accessing a target sector of an optical disc, which can shorten the access time to the target sector.

[0010]

In order to solve the above-mentioned problems and achieve the object, an optical disk apparatus according to the present invention is configured as follows. In the method for accessing a target sector of an optical disk according to the present invention, the target sector is accessed as follows.

An optical disk device according to the present invention has an optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top, and recording defect information including a physical address of a defective sector treated as a defect. For
In the optical disk device for recording and reproducing information, when accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector, the X-th sector is included between the physical address 1 and the physical address X based on the defect information. The number a of defective sectors to be obtained is obtained, and the sector at the physical address (X + a) is accessed.

An optical disk apparatus according to the present invention has an optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector treated as a defect. For
In the optical disk device for recording and reproducing information, when accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector, the X-th sector is included between the physical address 1 and the physical address X based on the defect information. The number a1 of defective sectors to be obtained is obtained, the number a2 of defective sectors included between the physical address (X + 1) and the physical address (X + a1) is obtained based on the defect information, and the sector of the physical address (X + a1 + a2) is accessed. .

An optical disk apparatus according to the present invention has an optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top, and recording defect information including a physical address of a defective sector treated as a defect. For
In the optical disk device for recording and reproducing information, when accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector, the X-th sector is included between the physical address 1 and the physical address X based on the defect information. The number a1 of defective sectors to be obtained is obtained, and when a1 = 0, the physical address X is accessed. When a1 ≠ 0, the defective sector included between the physical address (X + 1) and the physical address (X + a1) based on the defect information is obtained. When a2 = 0, the sector of the physical address (X + a1) is accessed. When a2 ≠ 0, the sector is included between the physical address (X + a1 + 1) and the physical address (X + a1 + a2) based on the defect information. Number of defective sectors a
3 and a3 = 0, the physical address (X +
a1 + a2).

An optical disk device according to the present invention has an optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top, and in which defect information including a physical address of a defective sector treated as a defect is recorded. For
In an optical disk apparatus for recording and reproducing information, a reproducing unit for reproducing the defect information recorded on the optical disk, a storage unit for storing the defect information reproduced by the reproducing unit, and a sector of a physical address 1 When accessing the X-th sector counted excluding the defective sector from, the number a of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information, and the physical address (X + a) is obtained. A calculating means for calculating, and an access means for accessing the sector of the physical address calculated by the calculating means when accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector. .

An optical disc apparatus according to the present invention has an optical disc having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top, and recording defect information including a physical address of a defective sector treated as a defect. For
In an optical disk apparatus for recording and reproducing information, a reproducing unit for reproducing the defect information recorded on the optical disk, a storage unit for storing the defect information reproduced by the reproducing unit, and a sector of a physical address 1 When accessing the X-th sector counted excluding the defective sector from, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information, and the physical address is obtained based on the defect information. Calculating means for obtaining the number a2 of defective sectors included between the address (X + 1) and the physical address (X + a1) and calculating the physical address (X + a1 + a2); and a calculating means for counting the sectors of the physical address 1 excluding the defective sectors. When accessing the X-th sector, access is made to the sector of the physical address calculated by the calculation means. And an access means.

An optical disk apparatus according to the present invention has an optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top, and recording defect information including a physical address of a defective sector treated as a defect. For
In an optical disk apparatus for recording and reproducing information, a reproducing unit for reproducing the defect information recorded on the optical disk, a storage unit for storing the defect information reproduced by the reproducing unit, and a sector of a physical address 1 When the X-th sector counted excluding the defective sector is accessed, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information. Calculate the address X, a1
When ≠ 0, the physical address (X
+1) to the physical address (X + a1), the number a2 of defective sectors included is obtained. When a2 = 0, the physical address (X + a1) is calculated. When a2 ≠ 0, the physical address (X + a1 + 1) is obtained based on the defect information. ) To the physical address (X + a1 + a2), and obtains the number a3 of defective sectors included in the physical address (X + a1 + a2). When a3 = 0, the calculating means calculates the physical address (X + a1 + a2). And an access unit for accessing the sector of the physical address calculated by the calculation unit when accessing the X-th sector.

According to the method for accessing a target sector of an optical disk according to the present invention, a defect including a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the head and including a physical address of a defective sector treated as a defect is provided. When accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector on the optical disk on which information is recorded, the defect information recorded on the optical disk is reproduced, and the defect information is stored. Then, the number a of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information, the physical address (X + a) is calculated, and the calculated physical address is accessed.

According to the method for accessing a target sector of an optical disk of the present invention, a defect including a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the head and including a physical address of a defective sector treated as a defect is provided. When accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector on the optical disk on which information is recorded, the defect information recorded on the optical disk is reproduced, and the defect information is stored. Then, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information, and the defect a included between the physical address (X + 1) and the physical address (X + a1) is obtained based on the defect information. The number a2 of sectors is obtained, the physical address (X + a1 + a2) is calculated, and the calculated physical address is accessed.

According to the method of accessing a target sector of an optical disk according to the present invention, a defect having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the head and including a physical address of a defective sector treated as a defect is provided. When accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector on the optical disk on which information is recorded, the defect information recorded on the optical disk is reproduced, and the defect information is stored. Then, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information. When a1 = 0, the physical address X is calculated. When a1 ≠ 0, the physical address X is calculated based on the defect information. From the physical address (X + 1) to the physical address (X
+ A1) to obtain the number a2 of defective sectors included in
When a2 = 0, the physical address (X + a1) is calculated. When a2 ≠ 0, the physical address (X + a1 + 1) is calculated from the physical address (X + a1 + 1) based on the defect information.
The number a3 of defective sectors included during 2) is obtained, and a3
When = 0, the physical address (X + a1 + a2) is calculated, and the calculated physical address is accessed.

[0020]

Embodiments of the present invention will be described below with reference to the drawings. First, an outline of a DVD-RAM as an optical disk will be described with reference to FIGS. FIG. 1 is a diagram for explaining the concept of a zone in a data recording area of an optical disc. FIG. 2 is a diagram for explaining an outline of a data structure of a data recording area of the optical disc. FIG. 3 is a diagram for explaining the rotation speed corresponding to each zone of the optical disc and the number of sectors per track in each zone. FIG. 4 is a diagram for explaining the sector format of the optical disc.

As shown in FIG. 1 and FIG.
Can be divided into a lead-in area 2, a data area 3, and a lead-out area 4. Each area is composed of a plurality of zones, and each zone is composed of a plurality of tracks.

The lead-in area 2 includes an emboss data zone 5 and a rewritable data zone 6. A reference signal and control data are recorded in the emboss data zone 5 during manufacturing. The rewritable data zone 6 further includes a guard track zone, a disk test zone, a drive test zone, a disk identification data zone, a replacement management zone, and the like. Defect list information is recorded in this replacement management zone.

The data area 3 is composed of a plurality of zones, for example, zones 3a,. The lead-out area 4 is a rewritable data zone similar to the rewritable data zone 6 formed in the lead-in area 2. In the lead-out area 4, data having the same recording content as the data zone 6 is recorded.

The optical disc 1 has a different number of sectors per track between the inner circumference and the outer circumference. That is, the number of sectors included in one track on the outer peripheral side is larger than the number of sectors included in one track on the inner peripheral side.
Therefore, as shown in FIG. 3, the number of rotations (rotational speed) of the optical disc 1 changes for each zone. Therefore, in each zone in the lead-in area 2, each zone in the data area 3, and each zone in the lead-out area 4, the rotation speed decreases from the inner circumference to the outer circumference of the optical disc 1.
The relationship between the rotation speed data and the number of sectors included in one track (FIG. 3) for each zone is recorded in a table 10a of the memory 10 described later.

The zones 3a,... 3x of the data area 3
As shown in FIG. 1 and FIG. 2, each track has an ECC (error correction code) block data unit (for example, 38688 bytes) as a data recording unit.
The data is recorded.

Next, the sector format will be described with reference to FIG. As shown in FIG. 4, one sector is composed of approximately 2697 bytes. In this sector, data modulated by 8-16 modulation is recorded. The 8-16 modulation converts an 8-bit input code sequence into 1
This is a modulation method for modulating a 6-bit output code sequence. The input code sequence is called an input bit, and the output code sequence is called a channel bit. By the way, 1 byte is 16
It has the same meaning as the channel bit.

Here, the details of one sector will be described. One sector has a 128-byte header field,
It consists of a byte mirror field and a 2567 byte recording field.

In the header field, predetermined data is recorded (pre-formatted) as a concave / convex shape in the optical disk manufacturing process. In this header field, a sector address of 4 is set in order to improve the detection accuracy of the header.
Overwritten. That is, this header field is composed of a header 1 field, a header 2 field, a header 3 field, and a header 4 field.
The header 1 field and the header 3 field are composed of 46 bytes. Header 2 field and header 4
The field is composed of 18 bytes.

The header 1 field has a 36-byte synchronization code VFO (Variable Frequency Oscillator) 1 field and a 3-byte address mark AM (Address Matrix).
rk) field, 4-byte address PID (Physical
ID) 1 field, 2 byte error detection code IED
(ID Error Detection Code) 1 field, 1 byte postamble PA (Post Ambles) 1 field.

The header 2 field includes an 8-byte synchronization code VFO2 field and a 3-byte address mark A.
M field, 4-byte address PID2 field, 2-byte error detection code IED2 field, 1 byte
It consists of a byte postamble PA2 field.

The header 3 field includes an 8-byte synchronization code VFO2 field and a 3-byte address mark A.
M field, 4-byte address PID3 field, 2-byte error detection code IED3 field, 1 byte
It is composed of a byte postamble PA1 field.

The header 4 field includes an 8-byte synchronization code VFO2 field and a 3-byte address mark A.
M field, 4-byte address PID4 field, 2-byte error detection code IED4 field, 1
It consists of a byte postamble PA2 field.

[0033] Physical address information is recorded in the PID field. Specifically, sector information (including a PID number) of 1 byte and a sector number of 3 bytes are recorded.

In the VFO field, a PLL (Phase Lo
A continuous repetition pattern (100010001000...) for drawing in the cked Loop) is recorded.
Specifically, the pattern recorded in the VFO field is used to synchronize the frequency for reproducing the address information recorded in the PID field.

An address mark is recorded in the AM field, and this address mark plays a role of detecting a block boundary when demodulating a fixed-length block code. Specifically, the address mark recorded in the AM field indicates the position of the address information recorded in the PID field. A special pattern (a pattern violating the run-length restriction) that does not appear elsewhere is used for the address mark recorded in the AM field.

The error detection code IED field contains an error (error) for the sector address (including the ID number).
The detection code is recorded, and the presence or absence of an error in the PID read by the error detection code is detected.

State information necessary for demodulation is recorded in the postamble PA field, and also has a role of polarity adjustment so that the header field ends with a space.
The mirror field is a mirror surface field, and this field is used for, for example, gain adjustment of a photodetector described later.

The recording field is a field mainly for recording user data. The recording fields are a (10 + J / 16) byte gap field, a (20 + K) byte guard 1 field, a 35 byte VFO3 field, and a 3 byte PS.
(Pre-synchronous code) field, 2418-byte data field (user data field), 1-byte postamble PA3 field, (55-K)
Guard 2 field of bytes, and (25-J / 1
6) Consists of a byte buffer field. Incidentally, J takes an integer of 0 to 15 and K takes an integer of 0 to 7 and takes a random value. As a result, the start position of the data writing is randomly shifted. As a result, deterioration of the recording film due to overwriting can be reduced.

The gap field is a field in which nothing is recorded. The guard 1 field is a discard data area for absorbing the deterioration of the starting end of the repeated overwriting peculiar to the phase change recording film.

The VFO3 field is also a field for PLL lock, but is also intended to synchronize a byte boundary by inserting a synchronization code in the same pattern.

The PS field is a field where a synchronization code is recorded, and is provided for detecting a block boundary. The data field includes a data ID, a data ID error correction code IED (Data ID Error Detecti
on Code), synchronization code, ECC (Error Collection Co)
de), EDC (Error Detection Code), 2048 bytes of user data, and the like. The data ID is a sector ID 1 to ID 16 of 4 bytes (32 channel bits) of each sector. The data ID error correction code IED is a 2-byte (16-bit) error correction code for data ID.

The postamble PA3 field contains state information necessary for demodulation and is a field indicating the end of the last byte of the previous data field. The guard 2 field is a field provided to prevent the end deterioration at the time of repetitive recording peculiar to the phase change recording medium from reaching the data field.

The buffer field is a field provided to absorb rotation fluctuation of the motor for rotating the optical disk 1 so that the data field does not overlap the next header field.

Next, an optical disk device will be described with reference to FIG. FIG. 5 is a diagram showing a schematic configuration of the optical disk device. The optical disk device irradiates the optical disk 1 with a converging light beam, receives the reflected light of the light beam from the optical disk 1, and reflects the data recorded on the optical disk 1 reflected on the received reflected light. Is to be reproduced. The optical disk device irradiates the optical disk 1 with a light beam and records data on the light beam 1.

As shown in FIG. 5, the optical disk 1 is loaded on a spindle motor 23 while being held by a cartridge 21. The optical disc 1 is rotated by the spindle motor 23, for example, at a different rotation speed for each zone. This spindle motor 23
Are controlled by the motor control circuit 24.

The reproduction of data recorded on the optical disk 1 is performed by the optical head 25. The spindle motor 23 and the optical head 25 are provided on a fixed base as described later.

The optical head 25 includes a linear motor 26
Is fixed to a drive coil 27 which constitutes a movable portion of the motor, and the drive coil 27 is connected to a linear motor control circuit 28.

On the other hand, a speed detector 29 is connected to a linear motor control circuit 28 for driving the linear motor 26. The speed signal of the optical head 25 detected by the speed detector 29 is transmitted to the linear motor control circuit 28. And the moving speed of the optical head 25 is controlled.

The objective lens 30 is provided on the carriage 70 of the optical head 25, and is supported by a wire or a leaf spring (not shown). This objective lens 3
0 is moved in the focusing direction (the direction of the optical axis of the lens) by the drive coil 31 and the drive coil 3
2 moves in the tracking direction (the direction orthogonal to the optical axis of the lens).

A semiconductor laser 39 as an irradiating means for irradiating a light beam is driven by a laser driving circuit 35 to generate a laser beam. Laser drive circuit 35
Is a photodiode P for monitoring the semiconductor laser 39.
The light amount of the laser beam generated by the semiconductor laser 39 is corrected according to the monitor current from D.

The laser drive circuit 35 includes a PLL (not shown).
It operates in synchronization with a clock signal for data recording or data reproduction from a circuit. This PLL circuit divides the frequency of a basic clock signal from an oscillator (not shown) to generate a clock signal for data recording or data reproduction. In the laser drive circuit 35, the semiconductor laser 3
When a laser beam for data recording is generated from step 9, control is performed so as to generate a high-output laser beam higher than the laser beam for data reproduction by a predetermined level.

The laser beam generated by the semiconductor laser 39 driven by the laser drive circuit 35 is collimated by a collimator lens 40, and the optical path is bent at a substantially right angle by a half prism 41.
That is, the semiconductor laser 39 is formed by the half prism 41.
Is emitted toward the optical disc 1 in a collimated state. This laser beam is focused on the data recording surface of the optical disc 1 by the objective lens 30.

The light beam reflected from the data recording surface of the optical disk 1 passes through the objective lens 30 and the half prism 41, passes through the condenser lens 42 and the cylindrical lens 43, and detects light as a light receiving means. Vessel 4
It is led to 4.

The photodetector 44 comprises, for example, four-divided photodetection cells 44a, 44b, 44c and 44d. The light detection cell 44 included in the light detector 44
The output signal a is supplied to one end of an adder 46a via an amplifier 45a, and the output signal of the photodetector cell 44b is supplied to one end of the adder 46b via an amplifier 45b. The output signal of the light detection cell 44c is supplied to the other end of the adder 46a via the amplifier 45c.
Is supplied to the other end of the adder 46b via the amplifier 45d.

The output signal of the photodetector cell 44a included in the photodetector 44 is supplied to one end of an adder 46c via an amplifier 45a, and the output signal of the photodetector cell 44b is supplied via an amplifier 45b. It is supplied to one end of the adder 46d. The output signal of the light detection cell 44c is
The output signal of the photodetector cell 44d is supplied to the other end of the adder 46d via the amplifier 45d via the amplifier 45d.
6c is supplied to the other end.

The output signal of the adder 46a is a differential amplifier O
The output signal of the adder 46b is supplied to a non-inverting input terminal of the differential amplifier OP2. Thus, the differential amplifier OP2 includes the adder 46a,
A signal relating to the focus point, that is, a focus error signal is supplied to the focusing control circuit 47 in accordance with the difference 46b. The output signal from the focusing control circuit 47 is supplied to the drive coil 31, and is controlled so that the laser beam is always just focused on the data recording surface of the optical disc 1.

The output signal of the adder 46c is a differential amplifier O
The output signal of the adder 46d is supplied to the non-inverting input terminal of the differential amplifier OP1. As a result, the differential amplifier OP1 includes the adder 46c,
A tracking error signal is supplied to the tracking control circuit 48 according to the difference of 46d. Tracking control circuit 48
Creates a track drive signal according to the tracking error signal supplied from the differential amplifier OP1.

The track drive signal output from the tracking control circuit 48 is supplied to the drive coil 32 in the tracking direction. The tracking error signal used in the tracking control circuit 48 is also supplied to the linear motor control circuit 28.

The sum signal of the outputs of the photodetection cells 44a to 44d of the photodetector 44 in the state where the focusing control and the tracking control are performed, that is, the adder 4
The signal obtained by adding the output signals from 6c and 46d by the adder 46e reflects a pit formed on the track, that is, a change in reflectance from the recording data. This signal is supplied to a data reproducing circuit 38 as reproducing means.
In the data reproducing circuit 38, data recorded on the data recording surface of the optical disk is reproduced.

The reproduced data reproduced by the data reproducing circuit 38 is subjected to error correction by an error correcting circuit 52 as an error correcting means using an error correction code ECC added to the reproduced data, and then the interface circuit 55 Optical disk control device 56 as an external device through
Is output to

A data generation circuit 34 is provided at a stage preceding the laser drive circuit 35. The data generation circuit 34 receives the format data of the ECC block as the recording data supplied from the error correction circuit 52,
Recording EC with synchronization code for ECC block
An ECC block data generation circuit 34a for converting the data into C block format data, and a modulation circuit 34b for modulating the recording data from the ECC block data generation circuit 34a by the 8-16 modulation method are provided.

The data generation circuit 34 is supplied with the recording data to which the error correction code is added by the error correction circuit 52 and the dummy data for error check read from the memory 10. To the error correction circuit 52, recording data from an optical disk control device 56 as an external device is supplied via an interface circuit 55 and a bus 49.

The error correction circuit 52 converts the 32 Kbytes of recording data supplied from the optical disk control unit 56 into 4K bytes.
The horizontal and vertical error correction codes are added to the recording data in the unit of sector for each byte, the sector ID (logical address number) is added, and the ECC is added.
Generate block format data.

The optical disk device is provided with a D / A converter 51. This D / A converter 51
It is used to exchange data between the CPU 50 and other units. The other units are a focusing control circuit 47, a tracking control circuit 48, a linear motor control circuit 28, and the like.

The motor control circuit 24, the linear motor control circuit 28, the laser drive circuit 35, the data reproduction circuit 38, the focusing control circuit 47, and the tracking control circuit 4
8, the error correction circuit 53, the address processing unit 100, etc.
Controlled by the CPU 50 via the bus 49. The CPU 50 performs a predetermined operation according to a control program recorded in the memory 10. The address processing unit 10
0 will be described in detail later.

The memory 10 stores a control program and is used for data recording. This memory 10
Is a table 10 in which the relationship between speed data (number of revolutions) and the number of sectors in one track is recorded for each zone.
a.

Next, the relationship between physical addresses and logical addresses will be described with reference to FIG. FIG. 6 is a diagram illustrating a relationship between a physical address and a logical address. The physical address is an address assigned to an actually existing sector. The logical address is an address assigned to a sector actually used.

For example, 1 to 1
It is assumed that there are a plurality of sectors to which N physical addresses are assigned. It is also assumed that, among the sectors having the physical addresses 1 to N, the sectors having the physical addresses 2, 3, 6, 9, and 11 are defective sectors. That is, the defect list information includes the physical addresses 2, 3, 6, 9, and 11.

The X-th sector counted from the sector at the physical address 1 excluding the defective sector is the sector at the logical address X. That is, the physical address 1 is replaced with the logical address 1
Corresponds to the physical address 4 and the logical address 2 corresponds to
The logical address 3 corresponds to the physical address 5.

Next, a case will be described in which the X-th sector counted from the sector at the physical address 1 excluding the defective sector, that is, the logical address X is accessed. In the optical disk device of the present invention, the physical address Y is accessed in response to a request to access the logical address X. Less than,
A method of calculating the physical address Y will be described.

First, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect list information. When a1 = 0, the physical address Y = the physical address X.

When a1 ≠ 0, the physical address (X +
The number a2 of defective sectors included between 1) and the physical address (X + a1) is obtained. When a2 = 0, physical address Y = physical address (X + a1).

When a2 ≠ 0, the physical address (X +
The number a3 of defective sectors included between (a1 + 1) and the physical address (X + a1 + a2) is obtained. When a3 = 0, physical address Y = physical address (X + a1 +
a2).

That is, the number of defective sectors ai (i = 1,
When (2, 3,...) = 0, the physical address Y = the physical address (X + a1 + a2 +... A (i-1)). Also,
If the physical address Y does not exist in the sectors of the physical addresses 1 to N, it is determined that an error has occurred.

Next, a method for calculating the physical address Y from the logical address X will be specifically described with reference to FIG. First, when X = 3, that is, the physical address Y when an access request to the logical address 3 is made
The calculation of will be described.

First, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect list information. That is, the number a1 of defective sectors included between the physical addresses 1 to 3 is obtained. In this case, a1 = 2. Further, from the physical address (X + 1) to the physical address (X + a
The number a2 of defective sectors included during 1) is obtained.
In this case, a2 = 0.

Therefore, physical address Y = physical address (X + a1) = physical address (3 + 2) = physical address 5. That is, when an access request to the logical address 3 is made, the access to the physical address 5 is executed.

Next, the calculation of the physical address Y when X = 4, that is, when an access request to the logical address 4 is made will be described. First, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect list information.
That is, the number a1 of defective sectors included between the physical addresses 1 to 4 is obtained. In this case, a1
= 2. Further, the number a of defective sectors included between the physical address (X + 1) and the physical address (X + a1)
2 is obtained. In this case, a2 = 1. further,
From physical address (X + a1 + 1) to physical address (X +
The number a3 of defective sectors included between a1 + a2) is obtained. In this case, a3 = 0.

Therefore, physical address Y = physical address (X + a1 + a2) = physical address (4 + 2 + 1) = physical address 7 That is, when a request for access to the logical address 4 is made, access to the physical address 7 is executed.

Next, the calculation of the physical address Y when X = 5, that is, when an access request to the logical address 5 is made will be described. First, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect list information.
That is, the number a1 of defective sectors included between the physical addresses 1 to 5 is obtained. In this case, a1
= 2. Further, the number a of defective sectors included between the physical address (X + 1) and the physical address (X + a1)
2 is obtained. In this case, a2 = 1. further,
From physical address (X + a1 + 1) to physical address (X +
The number a3 of defective sectors included between a1 + a2) is obtained. In this case, a3 = 0.

Therefore, physical address Y = physical address (X + a1 + a2) = physical address (5 + 2 + 1) = physical address 8 That is, when a request for access to the logical address 5 is made, access to the physical address 8 is executed.

Next, referring to FIG.
The schematic configuration of 00 will be described. The address processor 100 calculates the physical address Y from the logical address X. That is, the address processing unit 100 functions as a calculating unit.

The address processing unit 100 includes an address register 102, an address data adding unit 104, an identification code register 106, an identification code comparing unit 108, an address data comparing unit 110, a reaching flag adding unit 112, and an address data confirming unit 114. Is provided.

Next, the calculation of the physical address Y from the logical address X by the address processing unit 100 will be described. First, defect list information is read from the optical disc. The reading of the defect list information is performed by the optical head 25 as the reproducing means and the data reproducing circuit 38 also as the reproducing means. As shown in FIG. 8, the defect list information A read from the optical disc is rearranged and stored as defect list information B in the memory 10 as a storage unit. The rearrangement is performed so that the magnitude relationship of the sector address values is in ascending order. Then, they are provided as a defect list read address and an identification code, which will be described later, in ascending order of the sector address value.

Further, the requested address as the logical address X is output from the CPU 50. The request address output from the CPU 50 is input to the address register 102. The address register 102 holds the requested address and outputs the value of the requested address to the address data adder 104 as address data (AD). Further, adding section 104 outputs the address data to address data comparing section 110.

The request identification code is output from the CPU 50. The request identification code output from the CPU 50 is input to the identification code register 106. As described above, the defect list information includes the physical address of the defective sector and the identification code in which the type of the defect is coded. In this embodiment, the slip replacement process is performed regardless of the type of the defect. Therefore, all the identification codes are input to the identification code register 106 as request identification codes. The identification code register 106 holds the request identification code and outputs the request identification code to the identification code comparison unit 108.

Further, all the identification codes included in the defect list information stored in the memory 10 are read. The identification code read from the defect list information, that is, the defect list read identification code is output to the identification code comparison unit 108. The identification code comparison unit 108 outputs a match flag F1 to the address data comparison unit 110 when a defect list read identification code that matches the request identification code is input. In the case of this embodiment, since all the identification codes have been input to the identification code register 106 as request identification codes,
All defect list read identification codes match the request identification code.

Further, all physical addresses (physical addresses of defective sectors) included in the defect list information stored in the memory 10 are read. The physical address read from the defect list information, that is, the defect list read address, is
Output to 0. When the match flag provided from the identification code comparing unit 108 is input, the address data comparing unit 110 compares the defect list read address with the arrival address provided from the address data adding unit 104. In this embodiment, since the match flag is always provided, all the defect list read addresses are compared with the arrival addresses. When the defect list read address is smaller than the destination address or when the defect list read address is equal to the destination address, the address data comparing unit 110 outputs the addition flag F2 to the address data adding unit 104. When the defect list read address is larger than the arrival address, the arrival flag F3 is output from the address data comparison unit 110 to the arrival flag addition unit 112.

The address data adding section 104 generates a reaching address by adding the number of occurrences of the addition flag to the address data. Further, the address data adder 104
Outputs the reaching address to the address data comparing unit 110 and the address data checking unit 114. The address data comparing unit 110 and the address data adding unit 104
Starts operation according to the search start output from the CPU 50. At the start of this operation, the addition of the address data adder 104 is reset, and the address data is output as the arrival address. Therefore, when the operation of the address data comparison unit 110 starts, the arrival address to be compared with the defect list read address is the address data output from the address register 102.

The address data confirmation section 114 is
The operation starts in accordance with the search start output from 0. Further, the address data checking unit 114 checks whether or not the arrival address exists in the sectors of the physical addresses 1 to N. If the destination address does not exist in the sectors of the physical addresses 1 to N, the address data check unit 114 outputs an NG flag F4 to the CPU 50. Conversely, if the arrival address exists in the sectors of the physical addresses 1 to N, the address data 114
Outputs the reaching flag F5 to the reaching flag adding unit 112.

The arrival flag F3 is transmitted to the arrival flag adding section 112.
Alternatively, when F5 is input, reaching flag addition section 112 outputs reaching flag F6. The arrival address output from the address data addition unit 104 when the arrival flag F6 is output from the arrival flag addition unit 112 corresponds to the physical address Y.

Next, referring to the flowchart of FIG.
The process of calculating the physical address Y from the logical address X will be described. First, the request address is stored in the address register 102 (ST10). Further, the request identification code is stored in the identification code register 106 (ST1).
2). Further, a search start signal is output to address data comparing section 110 and address data confirming section 114. Thereby, the defect list read address is taken into address data comparing section 110 (ST1).
4). Further, the defect list read identification code is taken into the identification code comparison unit 108 (ST14).

If the physical address of the defective sector does not exist in the defect list information, that is, if the defect list read address does not exist, a fixed address is taken into the address data comparing section 110 instead of the defect list read address. (ST16,
YES). This fixed address is an address that does not exist. Then, the arrival address having the same value as the address data is output from address data adding section 104 (ST2).
8). Further, at this time, arrival flag F6 is output from arrival flag adding section 112 (ST28).

When the physical address of the defective sector exists in the defect list information, that is, when the defect list read address exists and the address data is smaller than the defect list read address (ST18, YES), The destination address having the same value as the address data is output from address data adding section 104 (ST28). Further, at this time, arrival flag F6 is output from arrival flag adding section 112 (ST2).
8).

This is a case where the address data is larger than the defect list read address (ST18, N
O), if the request identification code and the defect list read identification code match (ST20, YES), the address data adding section 104 outputs "address data =
Address data + 1 "is calculated (ST22). Further, the address data calculated by the address data adding unit 104 is input to the address data comparing unit 110 as a reaching address. Further, thereafter, the comparison between the next defect list read address and the address data is continued (ST24 → ST14). Each time the comparison is performed, 1 is added to the value of the destination address. Until the arrival address becomes smaller than the defect list read address, the comparison between the arrival address and the defect list read address is continued.

When the calculated arrival address is included in the physical address, the arrival flag F5 is output from the address data checking unit 114 to the arrival flag adding unit 112. Further, at this time, the arrival flag F6 is output from the arrival flag adding unit 112 to the CPU 50.

If the calculated arrival address is not included in the physical address, NG flag F4 is output from address data checking section 114 to CPU 50 (ST30).

The optical disk device of the present invention calculates the physical address Y from the logical address X to be accessed and the defect list information, and accesses the physical address Y. Thus, the target sector can be accessed at high speed.

[0099]

According to the present invention, it is possible to provide an optical disk apparatus and a method for accessing the target sector of the optical disk, which can shorten the access time to the target sector.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining a concept of a zone of a data recording area of an optical disc.

FIG. 2 is a diagram for explaining an outline of a data structure of a data recording area of the optical disc.

FIG. 3 is a diagram for explaining a rotation speed corresponding to each zone of the optical disc and the number of sectors per track in each zone.

FIG. 4 is a diagram for explaining a sector format of an optical disc.

FIG. 5 is a diagram showing a schematic configuration of an optical disk device.

FIG. 6 is a diagram illustrating a relationship between a physical address and a logical address.

FIG. 7 is a diagram illustrating a schematic configuration of an address processing unit.

FIG. 8 is a diagram for explaining rearrangement of defect list information.

FIG. 9 is a flowchart illustrating a process of calculating a physical address Y from a logical address X.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Optical disk 10 ... Memory 25 ... Optical head 38 ... Data reproduction circuit 50 ... CPU 100 ... Address processing part

Claims (10)

[Claims] An optical disc having a plurality of sectors to which physical addresses of 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector to be treated as a defect is provided. When accessing the X-th sector counted by excluding the defective sector from the sector at the physical address 1 in the optical disk device that performs recording and reproduction of data, it is included between the physical address 1 and the physical address X based on the defect information. Obtain the number a of defective sectors and obtain the physical address (X + a)
An optical disk device characterized by accessing sectors. 2. An optical disc having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector to be treated as a defect is recorded on an optical disk. When accessing the X-th sector counted by excluding the defective sector from the sector at the physical address 1 in the optical disk device that performs recording and reproduction of data, it is included between the physical address 1 and the physical address X based on the defect information. The number a1 of defective sectors is obtained, and a physical address (X + 1) to a physical address (X + a1) are obtained based on the defect information.
An optical disk device that obtains the number a2 of defective sectors included in the sector and accesses the sector at the physical address (X + a1 + a2). 3. An optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector to be treated as a defect. When accessing the X-th sector counted by excluding the defective sector from the sector at the physical address 1 in the optical disk device that performs recording and reproduction of data, it is included between the physical address 1 and the physical address X based on the defect information. The number a1 of defective sectors is obtained. When a1 = 0, the physical address X is accessed. When a1 ≠ 0, the defective sector included between the physical address (X + 1) and the physical address (X + a1) is determined based on the defect information. When the number a2 is obtained and a2 = 0, the physical address (X + a1)
When a2 ≠ 0, the number a3 of defective sectors included between the physical address (X + a1 + 1) and the physical address (X + a1 + a2) is acquired based on the defect information. When a3 = 0, the physical address ( X
+ A1 + a2). 4. An optical disc having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector to be treated as a defect is provided. An optical disk device for performing recording and reproduction of the information; reproducing means for reproducing the defect information recorded on the optical disk; storage means for storing the defect information reproduced by the reproducing means; When accessing the X-th sector counted excluding the defective sector, the number a of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information, and the physical address (X + a) is obtained.
And an access unit for accessing the sector of the physical address calculated by the calculating unit when accessing the X-th sector counted by removing the defective sector from the sector of the physical address 1. An optical disk device characterized by the above-mentioned. 5. An optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector to be treated as a defect is provided. An optical disk device for performing recording and reproduction of the information; reproducing means for reproducing the defect information recorded on the optical disk; storage means for storing the defect information reproduced by the reproducing means; When accessing the X-th sector counted excluding the defective sector, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information, and the physical address is obtained based on the defect information. (X + 1) to physical address (X + a1)
Calculating means for calculating the physical address (X + a1 + a2) by acquiring the number a2 of defective sectors included between the two, and accessing the X-th sector counted by removing the defective sector from the sector of the physical address 1. An optical disk device comprising: an access unit that accesses a sector of a physical address calculated by a calculation unit. 6. An optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector to be treated as a defect. An optical disk device for performing recording and reproduction of the information; reproducing means for reproducing the defect information recorded on the optical disk; storage means for storing the defect information reproduced by the reproducing means; When accessing the X-th sector counted excluding the defective sector, the number a1 of defective sectors included between the physical address 1 and the physical address X is obtained based on the defect information. When a1 = 0, the physical address is obtained. X is calculated, and when a1 ≠ 0, the value is included between the physical address (X + 1) and the physical address (X + a1) based on the defect information. Acquiring the number a2 of defective sectors, and calculates the physical address (X + a1) is at a2 = 0, the physical address based on the defect information when the a2 ≠ 0 (X + a1 + 1) from the physical address (X + a1 +
The number a3 of defective sectors included during a2) is obtained, and a
When 3 = 0, calculating means for calculating the physical address (X + a1 + a2); and when accessing the X-th sector counted from the sector of the physical address 1 excluding the defective sector, the physical address of the physical address calculated by the calculating means is calculated. An optical disk device comprising: an access unit for accessing a sector. 7. The first to N-th sectors include:
7. The optical disk device according to claim 4, further comprising a determination unit configured to determine an error when a sector of the physical address calculated by the calculation unit does not exist. 8. A physical address 1 in an optical disc having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector treated as a defect. When accessing the X-th sector counted from the sectors excluding the defective sector, the defect information recorded on the optical disk is reproduced, the defect information is stored, and the physical address 1 is used based on the defect information. A method for accessing a target sector of an optical disc, comprising: obtaining a number a of defective sectors included between physical addresses X; calculating a physical address (X + a); and accessing the calculated physical address. 9. An optical disk having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector treated as a defect. When accessing the X-th sector counted from the sectors excluding the defective sector, the defect information recorded on the optical disk is reproduced, the defect information is stored, and the physical address 1 is used based on the defect information. The number a1 of defective sectors included between the physical addresses X is obtained, and the number a2 of defective sectors included between the physical addresses (X + 1) and (X + a1) is obtained based on the defect information. X + a1 + a2), and accessing the calculated physical address. Scan method. 10. An optical disc having a plurality of sectors to which physical addresses 1 to N are sequentially assigned from the top and recording defect information including a physical address of a defective sector treated as a defect. When accessing the X-th sector counted from the sectors excluding the defective sector, the defect information recorded on the optical disk is reproduced, the defect information is stored, and the physical address 1 is used based on the defect information. The number a1 of defective sectors included between the physical addresses X is obtained, and a1 =
When 0, the physical address X is calculated. When a1 ≠ 0, the number a2 of defective sectors included between the physical address (X + 1) and the physical address (X + a1) is obtained based on the defect information, and when a2 = 0, Physical address (X
+ A1), and when a2 ≠ 0, the number a3 of defective sectors included between the physical address (X + a1 + 1) and the physical address (X + a1 + a2) based on the defect information
And when a3 = 0, the physical address (X + a1
+ A2), and accessing the calculated physical address.