JPH09102173A - Cd-r drive - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a CD-R drive capable of managing and recording defect information on the disk by detecting defects of an unrecorded disk by a command from a host computer and providing a means to record the defect information. SOLUTION: ATIP-DEC (defect detector) 18 detects defect information from wobble signal from a reproducing amplifier 11, and also extracts a clock for a spindle control. When an unrecorded disk has a defect thereon, a controller 2 can find the presence or absence and the position (time) of the defect by detecting the ATIP reproduction error. Receiving a defect inspection execution command from a host computer 1, the controller reads the defect information on a prescribed area on disk 16, and writes the defect information when a defect exceeding a prescribed level exists. This makes it possible to manage and write the defect information on the disk.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention uses a CD-R disc as a medium which is an information recording medium,
The present invention relates to a device for writing information on a CD-R disc, and mainly relates to a CD-R disc drive device capable of managing defect information of the disc.

[0002]

2. Description of the Related Art Recently, as an information recording medium, CD-
R disk is used. Such CD-R discs are in relatively small lots (eg less than about 50 discs)
It is effective for the production of CDs and the like, and is used for recording image data, music data, computer information and the like. CD-R discs are write once (Wri
Since it is te once), the sector once written cannot be overwritten. For example, when recording a certain track by the track burst writing method, if an error occurs for some reason and recording of information fails,
The track can no longer be added or played.

[0003]

By the way, the CD-R drive is usually used for writing data. However, since verification is not performed after writing the data, and the presence or absence of defects and dust on the disc is not checked, there is a problem that a data error may occur when the disc is reproduced after writing the information. .

The present invention has been made to solve the above problems, and an object of the present invention is to provide a CD-R drive device capable of managing and recording defect information of a disc.

[0005]

According to the present invention, in order to achieve the above object, a CD-R drive which receives information from a host computer and irradiates an unrecorded optical disk with a semiconductor laser to record predetermined information. A CD-R drive device, characterized in that the device comprises defect detection means for detecting a defect of an unrecorded disc by a command from the host computer, and recording means for recording the detected defect information on the disc. is there. A CD-R that irradiates an unrecorded disc with a semiconductor laser to record predetermined information.
In a drive device, defect detection means for detecting a defect in an unrecorded disc, switch means for turning on or off this defect detection means, and defect information detected by the defect detection means when this switch means is in an on state. Is a CD-R drive device having a recording means for recording the data on the optical disc. As defect information detected by the defect detecting means, a defect start time is recorded in a PMA area on a disc as a skip start time, and a defect end time is recorded as a skip end time in a PMA area on the disc. It is characterized in that the information is divided into blocks so that the number of times and information about the skip end time are within a predetermined number. Then, in a host computer and a CD-R drive device which receives information from the host computer and irradiates a semiconductor laser on an unrecorded optical disc to record predetermined information, a defect of the unrecorded disc is caused by a command from the host computer. A CD-R drive device characterized by transmitting defect information to a defect detecting means for detecting and a host computer and recording data while avoiding a defective track. In a host computer and a CD-R drive device which receives information from the host computer and irradiates a semiconductor laser on an unrecorded optical disc to record predetermined information, a defect of the unrecorded disc is detected by a command from the host computer. A CD-R drive device having defect detection means, wherein when a track is reserved, the defective track is avoided and the track is reserved.

[0006]

According to the apparatus of the present invention, when recording on an unrecorded disc, the defect detecting means detects a defect of the disc and the detected defect information is written on this optical disc. Further, according to the apparatus of the second aspect, when the switch means is turned on, the above-described operation is performed.
The defect information is recorded in the PMA area on the optical disc with the defect start time as the skip start time and the defect end time as the skip end time. Further, the defect information is detected and recorded so that the number of times of the defect information is within a predetermined number. Further, at the time of track reserve, the track reserve is made to avoid the defective track.

[0007]

The present invention will be specifically described below with reference to examples. A CD-R drive device according to an embodiment of the present invention is shown in FIG.
As shown in FIG. 3, the host computer 1 is connected by a SCSI bus and is configured to receive a command from the host computer 1 and operate.

The CD-R drive device according to this embodiment is
It has a controller 2 for controlling the overall functions of the apparatus, a ROM 3 for storing a control program, and a RAM 4 for storing control data and the like.
It is connected to the SCSI controller 5 for controlling the connection with. The SCSI controller 5 has a buffer RAM 6 for temporarily storing the data sent from the host computer 1 and the data obtained from the reflected light from the optical disk, and error correction for the data sent from the host computer 1. A CIRC 7 which is added with a code or which is error-corrected for the data obtained from the reflected light of the optical disk is connected.

The CIRC 7 has an ENC 8 for EFM modulating the data to be recorded, and an EFM-DEC (E) for demodulating the data reproduced from the optical disk.
The FM decoder 12 and the audio circuit 17 are connected.

The ENC 8 is connected to the optical head 10 via an LD driver 9, while the EFM-DEC is connected.
Reference numeral 12 is connected to the optical head 10 via a reproduction amplifier 11. A head servo 13 for controlling the operation of the optical head 10 is connected to the optical head 10. The head servo 13 is connected to an ATIP-DEC (defect detector) 18 via a reproduction amplifier 11 and further to the ATIP- The DEC (defect detector) 18 is connected to the controller 2.

A spindle motor 15 for rotating the optical disk 16 and the spindle motor 1 are also provided.
It has a spindle motor servo 14 for controlling 5 to a predetermined number of revolutions, and the spindle motor servo 14 is selectively connected to the EFM-DEC 12 or ATIP-DEC 18 by a switch.

The SCSI controller 5 has a function of transmitting / receiving data to / from the host computer 1 and controlling an internal data bus. The LD driver is for supplying a semiconductor laser (not shown) current in the optical head 10 so that the optical head 16 irradiates the optical disk 16 with semiconductor laser light. The optical head 10 includes a semiconductor laser, an objective lens for condensing the light collected from the semiconductor laser on the optical disc 16, a light receiving element for detecting the reflected light from the optical disc, and the like. The head servo 13 is detected by a light receiving element in the optical head 10 and focuses a spot irradiated on the optical disc 16 on a predetermined track based on a focus error signal and a track error signal obtained through the reproduction amplifier 11. It has the function of following.

Next, the operation of the present apparatus will be described. At the time of writing, the CD-R drive device receives a command from the host computer 1 via the SCSI bus,
Based on this command, the controller 2 executes a predetermined program in the ROM 3.

That is, from the host computer 1 to the SC
The data to be written, which has been sent via the SI bus, is temporarily stored in the buffer RAM from the SCSI controller 5.
6 and is interleaved by the CIRC 7 and at the same time an error correction code is added. The data to which the error correction code is added is EFM-modulated by the ENC 8 and, at the same time, a subcode is added and is output to the LD driver 9 as write data. The LD driver 9 causes a semiconductor laser (not shown) in the optical head to emit light based on the transmitted write data. The light emitted from this semiconductor laser is condensed on an optical disc by a predetermined optical system to record data.

On the other hand, when reproducing data, the light reflected by the optical disk passes through the optical system and enters the light receiving element in the optical head, is converted into an electric signal, and is reproduced by the reproducing amplifier 11.
Is output to This electric signal is amplified by the reproduction amplifier 11, EFM demodulated by the EFM-DEC 12, and then C
Error correction is performed by IRC7. This error-corrected reproduction data is stored in the buffer RAM 6 and then
It is transferred to the host computer 1 via the SCSI controller 5. When the reproduced data is audio data, it is output from the CIRC 7 to the audio circuit 17.

When a CD-R disc which is an unrecorded disc is used, the AT is detected from the wobble signal from the reproduction amplifier 11.
The IP-DEC 18 detects defect information and extracts a spindle control clock. here,
Not only the time on the disc can be known from the ATIP information, but also if there is a defect on the disc, an ATIP reproduction error (CRC error) is detected. Therefore, the controller 2 can know the presence / absence of a defect and the position (time) of the defect from the ATIP information. Although the ATIP-DEC is shared with the defect detector in FIG. 1, a defect detector may be provided separately.

The processing operation of the CD-R drive device according to claim 1 will be described with reference to FIG. When the defect inspection execution command is received from the host computer 1, the defect information of a predetermined area on the disk, that is, the ATIP information is read out, and if there is a defect of a predetermined level or higher, the information indicating the defect information is written on the disk. The process ends.

The processing operation of the CD-R drive according to claim 2 will be described with reference to FIG. When the cartridge is installed,
It is checked whether or not the switch equipped in the drive is ON, and if it is ON, an unrecorded area of the disk is searched and a defect inspection of the unrecorded area is performed. It is judged whether or not there is a defect of a predetermined level or higher. If there is a defect of a predetermined level or higher, the information indicating the defect is written to the disc and the process ends. On the other hand, if the defect is a predetermined level or lower, the process ends as it is. .

When a defect of a predetermined level or higher is detected, the start time and end time of the defect can be written in the PMA area as skip start time and end time, respectively. FIG. 4 is an explanatory diagram showing the format of the ATIP signal. By detecting this signal with the ATIP-DEC signal, the time on the track can be detected. In FIG. 1, ATIP-DEC also serves as a defect detector. This is because the presence or absence of a defect can be detected by performing a CRC check on the ATIP signal. When a defect having a predetermined level is detected, for example, a defect which continues for several EMF frames or more, the start time and the end time of the defect are registered in the PMA area.

FIG. 5 shows a diagram relating to claim 4. When the disc is dusted or scratched, a defect occurs across a plurality of tracks. Therefore, in order to prevent the number of defects from being unnecessarily increased, as shown in FIG. 5, the leading time of a defect (A1 minute B1 second C1
Frame) and end time (A2 minutes B2 seconds C2 frame) are registered in the PMA area.

FIG. 6 shows a flow diagram relating to claim 5. The host computer 1 issues a command to reproduce the PMA area before recording data. This command causes the drive to transfer the subcode data to the host computer 1. The host computer 1 obtains the defect information from the subcode and checks whether the track to be recorded has a defect. If there is a defect, do not record on that track and check the next track. In this way, the data is recorded on the defect-free track.

FIG. 7 is a diagram related to the invention according to claim 6, and is an explanatory diagram showing the processing flow of the drive device when a reserve command is received from the host computer 1, and when the drive reserves a track, PMA If there is a defect in the area you are trying to reserve in the area,
After the defect end position, it is checked whether or not there is a defect in a predetermined area, it is confirmed that there is no defect in that area, and the reserved area is reserved.

[0023]

According to the present invention, since the defect inspection of the disc is performed and the defect information is recorded on the disc, it becomes possible to manage the defect management information. Further, as defect information, the defect start time is set as a skip start time, and the defect end time is set as a skip end time.
Since it is recorded as a subcode in the MA area and complies with the CD standard, compatibility between drives can be maintained. Further, since the skip information is set to the number of predetermined positions or less, it is possible to comply with the CD standard. Then, in order to record the data while avoiding the defective track,
The reliability of the written data is improved, and since there is no defect in the reserved track, the reliability of the written data is improved.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing the operation flow thereof.

FIG. 3 is an explanatory diagram showing an operation flow of another embodiment.

FIG. 4 is an explanatory diagram showing a format of an ATIP signal.

FIG. 5 is an explanatory diagram showing a state where a defect has occurred on the disc.

FIG. 6 is an explanatory diagram showing an operation flow of another embodiment.

FIG. 7 is an explanatory diagram showing an operation flow of another embodiment.

[Explanation of symbols]

 1 ... Host computer 2 ... Controller 3 ... ROM 4 ... RAM 5 ... SCSI controller 6 ... Buffer RAM 7 ... CIRC 8 ... ENC 9 ... LD driver 10 ... Optical head 11 ... Reproducing amplifier 12 ... EFM-DEC 13 ... Head servo 14 ... Spindle motor servo 15 ... Spindle motor 15 16 ... Optical disk 17 ... Audio circuit 18 ... ATIP-DEC

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Reference number within the agency FI Technical display location G11B 20/18 574 9558-5D G11B 20/18 574E 7/00 9464-5D 7/00 H

Claims (6)

[Claims] 1. A CD-R drive device which receives information from a host computer and irradiates an unrecorded optical disk with a semiconductor laser to record predetermined information, and detects a defect in the unrecorded disk by a command from the host computer. A CD-R drive device, comprising: a defect detecting unit for recording the detected defect information; and a recording unit for recording the detected defect information on a disc. 2. A defect detecting means for detecting a defect of an unrecorded disc in a CD-R drive device for irradiating an unrecorded disc with a semiconductor laser to record predetermined information,
A CD having switch means for turning on or off the defect detecting means, and recording means for recording defect information detected by the defect detecting means on the optical disk when the switch means is in an on state. -R drive device. 3. The PMA on the disk with the defect start time as the defect start time and the defect end time as the skip end time as the defect information detected by the defect detecting means.
The CD-R drive device according to claim 1, wherein the CD-R drive device records in a region. 4. The CD-ROM according to claim 3, wherein the information is divided into blocks so that the number of times of the skip start time and the skip end time as defect information is within a predetermined number of times.
R drive device. 5. A host computer and a CD-R drive device which receives information from the host computer and irradiates a semiconductor laser on an unrecorded optical disc to record predetermined information in the unrecorded disc by a command from the host computer. Defect detecting means for detecting defects of
CD-characterized by transmitting this defect information to a host computer and recording data while avoiding defective tracks
R drive device. 6. A host computer and a CD-R drive device which receives information from the host computer and irradiates a semiconductor laser on the unrecorded optical disc to record predetermined information, wherein an unrecorded disc is issued by a command from the host computer. CD having a defect detecting means for detecting the defect of the CD, and when the track is reserved, the track is reserved while avoiding the defective track.
-R drive device.