JP2007200400A - Disk unit and its control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent an optical pickup from mistakenly entering an embossed pit section in a lead-in area when seeking a head address of a DMA in the lead-in area of a DVD-RAM disk at start-up of the DVD-RAM disk. <P>SOLUTION: At the start-up of the DVD-RAM disk, the optical pickup is subjected to thread moving to the embossed pit section in the lead-in area being an innermost circumference of the DVD-RAM disk. Then, the optical pickup is moved to an intermediate address of a zone 0 in the data recording area adjacent to an outer circumference side of the DMA in the lead-in area of the DVD-RAM disk by a normal seek so that the optical pickup is moved to the head address of the DMA in the lead-in area of the DVD-RAM disk by repeating interval jumps. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The present invention relates to a disk apparatus for recording / reproducing information data on a DVD-RAM (Digital Versatile Disc-Random Access Memory) disk and a control method thereof, and in particular, to improve the accuracy of address seek at the start-up of the DVD-RAM disk. And a control method thereof.

Conventionally, when the DVD-RAM disk is started up, as shown in FIG. 5, the optical pickup is threaded to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk, and is slightly before the target address. The seek pattern is switched according to the designated number of tracks using the address as the landing address and moved to a DMA (Data Management Area) in the rewritable area of the lead-in area. However, since the DMA 2b in the lead-in area of the DVD-RAM disk 2 is adjacent to the outside of the embossed pit portion 2a in the lead-in area and very close to the embossed pit portion 2a as shown in FIG. When moving to the lead-in area DMA 2b by a normal seek, if the optical pickup accidentally enters the emboss pit portion 2a of the lead-in area adjacent to the inside of the lead-in area DMA 2b, the lead-in area DMA 2b and the lead The tracking error signal generation method for the in-area embossed pit portion 2a is different from the DPD (Differential Phase Detection) method and the DPP (Differential Push-Pull) method, and the servo control of the optical pickup becomes impossible. Click device there is a problem that freezes.
As a background art, at the time of seek and track jump, a header detection signal is generated from a tracking error signal, and tracking is turned on in a data area other than the header area detected by the header detection signal. (For example, see Patent Document 1).
Further, it sequentially detects the light beam spot of the optical pickup passing over the address area of the optical disk toward the target track, and at the start timing at which the light beam spot does not pass over the address area, Some have been drawn onto a nearby track (see, for example, Patent Document 2).
When the optical pickup is moved to a position where the target address and the detection address match, the optical pickup is tracked until the detection address matches the target address or until the detection address is within a preset target range. There was something which made it jump (for example, refer to patent documents 3).
JP-A-11-316957 JP 2002-170253 A JP 2004-22091 A

However, in the first one described in the background art, a header detection signal is generated from a tracking error signal at the time of seek and track jump, and tracking is performed in a data area other than the header area detected by the header detection signal. Can be turned on, but when turning on tracking during seek or track jumping, tracking is normally turned on even if a large shake occurs due to a defect near the target address. However, it was not intended to solve the above problems.
Further, in the following, the light beam spot of the optical pickup is sequentially detected toward the target track, and the light beam spot is detected at the start timing at which the light beam spot does not pass over the address area. Although the spot could be drawn onto the target track or a track in the vicinity of the target track, the timing to start deceleration due to the noise generated near the target address was incorrect, or the light was responded to the noise at the time of tracking pull-in. This is intended to prevent failure of the beam spot pull-in, and not to solve the above-mentioned problems.
Further, in the next one, when the optical pickup is moved to a position where the target address and the detected address match, until the detected address matches the target address, or the target range in which the detected address is set in advance. The optical pickup was able to make a track jump until it was within, but when moving the optical pickup to the target address, the time to acquire the current address, the direction of movement of the optical pickup, the number of moving tracks, the number of brakes, the target The time for copying the address to the optical pickup control device is omitted, and the next track jump of the optical pickup is started while the end notification is received from the optical pickup control device, so that the entire optical disk access time is shortened. It was not intended to solve the above problems It was.
The present invention has been made in view of the above-described problems of the background art, and an object of the present invention is to start the DMA in the lead-in area of the DVD-RAM disk when the DVD-RAM disk is started up. It is an object of the present invention to provide a disk device and a control method therefor that can prevent an optical pickup from accidentally entering an embossed pit portion of a lead-in area when seeking an address.

In order to achieve the above object, according to the present invention, there is provided a disk device for recording / reproducing information data on a DVD-RAM disk. When the DVD-RAM disk is started up, an optical pickup is connected to the innermost lead of the DVD-RAM disk. First moving means for moving the thread to the embossed pit portion in the in-area, and when the optical pickup moves to the embossed pit portion in the innermost lead-in area of the DVD-RAM disc, the optical pickup is read from the DVD-RAM disc. The second moving means for moving by a normal seek to the intermediate address of the zone 0 of the data recording area adjacent to the outer peripheral side of the in-area DMA, and the optical pickup to the intermediate address of the zone 0 of the data recording area of the DVD-RAM disc When moved, remove the optical pickup from the DVD-RAM disc. Until the DMA start address of Doin'eria and a third moving means for moving Repeat track jump.
The second moving means may move the optical pickup to the intermediate address of zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disk by a normal seek.
The third moving means may move the optical pickup by repeatedly performing an interval jump to the start address of the DMA in the lead-in area of the DVD-RAM disk.
By these means, when the DVD-RAM disk is started up, the optical pickup does not accidentally enter the embossed pit portion of the lead-in area when seeking the start address of the DMA in the lead-in area of the DVD-RAM disk. can do.

According to the disk device of the first aspect of the present invention, when the DVD-RAM disk is started up, the optical pickup is thread-moved to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk so that the optical pickup is When moved to the embossed pit portion of the innermost lead-in area of the DVD-RAM disc, the optical pickup is moved to the intermediate address of zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disc. When the optical pickup is moved to the intermediate address of the zone 0 of the data recording area of the DVD-RAM disc, the interval pickup is repeated until the start address of the DMA in the lead-in area of the DVD-RAM disc. Because I am trying to move When starting the DVD-RAM disk, when seeking the start address of the DMA in the lead-in area of the DVD-RAM disk, after moving the optical pickup to zone 0 of the data recording area, an interval jump with high seek accuracy is performed. Since the optical pickup is repeatedly moved to the DMA in the lead-in area, the optical pickup can be prevented from accidentally entering the embossed pit portion of the lead-in area.
According to the disk device of the second aspect of the invention, when the DVD-RAM disk is started up, the optical pickup is thread-moved to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk so that the optical pickup is When moved to the embossed pit portion of the innermost lead-in area of the DVD-RAM disc, the optical pickup is moved to the intermediate address of zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disc. When the optical pickup is moved to the intermediate address of the zone 0 of the data recording area of the DVD-RAM disk by moving normally, the track jump is repeated until the start address of the DMA in the lead-in area of the DVD-RAM disk. D because it is moved When the D-RAM disk is started up, when seeking the start address of the DMA in the lead-in area of the DVD-RAM disk, the optical pickup is moved to zone 0 of the data recording area, and then the track jump is repeated to repeat the optical pickup. Since the optical pickup is moved to the DMA in the lead-in area, the optical pickup can be prevented from accidentally entering the embossed pit portion of the lead-in area.
According to the disk device of the third aspect of the invention, the optical pickup is moved to the intermediate address of the zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disk by a normal seek. Therefore, the optical pickup can be reliably moved to the intermediate address of zone 0 of the data recording area of the DVD-RAM disk.
According to the disk device of the invention described in claim 4, since the optical pickup is moved repeatedly by the interval jump to the start address of the DMA in the lead-in area of the DVD-RAM disk. When seeking, when the head address of the DMA in the lead-in area of the DVD-RAM disc is sought, the optical pickup is moved to the DMA in the lead-in area by repeating an interval jump with high seek accuracy. Can be prevented from accidentally entering the embossed pit portion of the lead-in area.
According to the disk device control method of the fifth aspect of the present invention, when the DVD-RAM is started up, the optical pickup is thread-moved to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk to When the pickup moves to the embossed pit portion of the innermost lead-in area of the DVD-RAM disc, the optical pickup is moved to the intermediate address of zone 0 of the data recording area of the DVD-RAM disc by a normal seek. When the optical pickup is moved to the intermediate address of zone 0 of the data recording area of the DVD-RAM disc, the optical pickup is repeatedly moved to the first address of the DMA in the lead-in area of the DVD-RAM disc. -When starting the RAM disk, DV -When seeking the start address of the DMA in the lead-in area of the RAM disk, after moving the optical pickup to the zone 0 of the data recording area, the optical pickup is moved to the zone 0 of the data recording area by repeating an interval jump with high seek accuracy. Therefore, the optical pickup can be prevented from accidentally entering the embossed pit portion of the lead-in area.

Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings as appropriate. FIG. 1 is a block diagram showing the configuration of a disk apparatus according to an embodiment of the present invention. FIG. 2 is an explanatory diagram showing the operation of the disk apparatus according to an embodiment of the present invention. FIG. FIG. 4 is a schematic diagram showing an embossed pit portion, DMA, and zone 0 of a DVD-RAM disc, and FIG. 5 is an explanatory diagram showing the operation of the conventional disc device.
First, a description will be given based on the block diagram showing the configuration of the disk device of one embodiment of the present invention shown in FIG.
The disk device 1 irradiates a DVD-RAM disk 2 with laser light, detects the reflected light, reads information data recorded on the DVD-RAM disk 2, and irradiates the DVD-RAM disk 2 with laser light. The optical pickup 3 for recording information data on the DVD-RAM disk 2, the spindle motor 4 for rotating the DVD-RAM disk 2, the spindle servo circuit 5 for servo-controlling the rotation speed of the spindle motor 4, and the optical pickup 3 Based on the tracking error signal detected by the optical pickup 3, the sled motor 6 that moves the disk in the radial direction of the DVD-RAM disk 2, the sled servo circuit 7 that servo-controls the rotational direction and rotational speed of the sled motor 6. A track that servo-controls the tracking of the optical pickup 3. Servo circuit 8, focus servo circuit 9 that servo-controls the focus of the optical pickup 3 based on the focus error signal detected by the optical pickup 3, and information data read from the DVD-RAM disk 2 by the optical pickup 3 An RF amplification circuit 10 for amplifying an RF (Radio Frequency) signal, an RF signal of information data recorded on the DVD-RAM disk 2, and an RF signal of the information data amplified by the RF amplification circuit 10 as a reference clock Based on the detection and demodulation, the error of the demodulated information data is corrected, the compressed information data is decompressed based on a predetermined compression method, and the decompressed information data is decoded to reproduce the information data. In addition, the information data is encoded and compressed based on a predetermined compression method. A signal processing circuit 11 which is constituted by a microcomputer 12 for controlling the entire system of the disk drive 1.
The operation of the disk device configured as described above will be described below.
When starting up the DVD-RAM disk 2, the microcomputer 12 sends a control signal to the spindle servo circuit 5, drives the spindle motor 4 to rotate the DVD-RAM disk 2, and sends a control signal to the thread servo circuit 7. Then, the thread motor 6 is driven to move the optical pickup 3 to the embossed pit portion 2a in the innermost lead-in area of the DVD-RAM disk 2 (see FIG. 4), and the tracking servo circuit 8 and the focus servo. A control signal is sent to the circuit 9 to servo-control the tracking and focus of the optical pickup 3.
When the optical pickup 3 moves to the embossed pit portion 2a in the innermost lead-in area of the DVD-RAM disk 2 (see FIG. 4), the microcomputer 12 sends a control signal to the sled servo circuit 7, and the optical pickup 3 Is subtracted by a predetermined amount, for example, 4%, from the intermediate address of zone 0 to the hexadecimal intermediate address 3548FH of zones 0 and 2c of the data recording area adjacent to the outer periphery of the DMA 2b of the lead-in area of the DVD-RAM disk 2 The address is moved as a landing address by a normal seek according to the designated number of tracks (see FIGS. 2 and 4).
When the optical pickup 3 moves to the intermediate address of zones 0 and 2c of the data recording area of the DVD-RAM disk 2 (see FIGS. 2 and 4), the microcomputer 12 sends a control signal to the thread servo circuit 7 to The pick-up 3 is repeatedly moved to the start address of the DMA in the lead-in area of the DVD-RAM disk 2 by repeating an interval jump with a small number of jump tracks and high seek accuracy (see FIG. 2). This prevents the optical pickup from accidentally entering the embossed pit portion of the lead-in area when seeking the start address of the DMA in the lead-in area of the DVD-RAM disk when the DVD-RAM disk is started up. Can do.
The operation will be described with reference to the flowchart of FIG. 3 showing the operation of the disk apparatus according to the embodiment of the present invention.
When the DVD-RAM disk is started up, the process proceeds from step S1 to step S2. In step S2, the optical pickup is thread-moved to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk, and the process proceeds to step S3. .
In step S3, the optical pickup is moved to the intermediate address of zone 0 of the data recording area of the DVD-RAM disk by a normal seek, and the process proceeds to step S4.
In step S4, it is determined whether or not the optical pickup has moved to the intermediate address of zone 0 of the data recording area of the DVD-RAM disc. If the optical pickup has moved to the intermediate address of zone 0 of the data recording area, step S5 is performed. If the optical pickup has not moved to the intermediate address of zone 0 of the data recording area, the process returns to step S3 and the steps from step S3 are repeated.
In step S5, the optical pickup is moved to the start address of the DMA in the lead-in area of the DVD-RAM disc by an interval jump, and the process proceeds to step S6.
In step S6, it is determined whether or not the optical pickup has moved to the start address of the DMA in the lead-in area of the DVD-RAM disk. If the optical pickup has moved to the start address of the DMA, the process proceeds to step S7 and the process is terminated. If the optical pickup has not moved to the start address of the DMA, the process returns to step S5 and the steps from step S5 are repeated.
Although the best mode for carrying out the present invention has been described in detail above, the present invention is not limited to this, and modifications and improvements can be made within the ordinary knowledge of those skilled in the art. Needless to say.

It is a block diagram which shows the structure of the disk apparatus of one Example of this invention. It is explanatory drawing which shows operation | movement of the disc apparatus of one Example of this invention. It is a flowchart which shows operation | movement of the disc apparatus of one Example of this invention. It is a schematic diagram which shows the emboss pit part, DMA, and zone 0 of a DVD-RAM disc. It is explanatory drawing which shows operation | movement of the conventional disc apparatus.

Explanation of symbols

1 Disc device 2 DVD-RAM disc 2a Embossed pit part 2b DMA
2c Zone 0
3 optical pickup 4 spindle motor 5 spindle servo circuit 6 tracking servo circuit 7 thread servo circuit 8 tracking servo circuit 9 focus servo circuit 10 RF amplification circuit 11 signal processing circuit 12 microcomputer

Claims (5)

A disk device for recording and reproducing information data on a DVD-RAM disk,
A first moving means for threading the optical pickup to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk when the DVD-RAM disk is started up; and the optical pickup is the innermost circumference of the DVD-RAM disk When the optical pickup is moved to the embossed pit portion of the lead-in area, the second optical disk is moved to the intermediate address of the zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disc by a normal seek. When the moving means and the optical pickup are moved to the intermediate address of zone 0 of the data recording area of the DVD-RAM disk, the optical pickup is moved repeatedly by repeating an interval jump to the head address of the DMA in the lead-in area of the DVD-RAM disk. Having a third moving means Disk apparatus according to claim. A disk device for recording and reproducing information data on a DVD-RAM disk,
A first moving means for threading the optical pickup to the embossed pit portion of the innermost lead-in area of the DVD-RAM disk when the DVD-RAM disk is started up; and the optical pickup is the innermost circumference of the DVD-RAM disk Second moving means for moving the optical pickup to an intermediate address in zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disc when moved to the embossed pit portion of the lead-in area of When the optical pickup moves to the intermediate address of zone 0 of the data recording area of the DVD-RAM disc, the optical pickup is moved repeatedly by repeating the track jump to the start address of the DMA of the lead-in area of the DVD-RAM disc. And a moving means. Click device. The second moving means is a moving means for moving the optical pickup to the intermediate address of zone 0 of the data recording area adjacent to the outer peripheral side of the DMA of the lead-in area of the DVD-RAM disc by a normal seek. The disk device according to claim 2. 3. The disk apparatus according to claim 2, wherein the third moving means is a moving means for repeatedly moving the optical pickup to the leading address of the DMA in the lead-in area of the DVD-RAM disk. A method of controlling a disk device for recording / reproducing information data on a DVD-RAM disk,
When starting up the DVD-RAM, the optical pickup is thread-moved to the emboss pit portion of the innermost lead-in area of the DVD-RAM disc, and the optical pickup is moved to the innermost lead-in area of the DVD-RAM disc. When moving to the embossed pit, the optical pickup is moved to the intermediate address of the zone 0 of the data recording area of the DVD-RAM disc by a normal seek, and the middle of the zone 0 of the data recording area of the DVD-RAM disc is moved. And a step of repeatedly moving the optical pickup to the start address of the DMA in the lead-in area of the DVD-RAM disk when moving to the address.

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