JPH0636282B2 - Optical information recording / reproducing device - Google Patents

Description

Description: TECHNICAL FIELD The present invention records information on an optical recording disk having an optically detectable guide track, and the guide track is previously divided into a plurality of sectors. The present invention relates to an optical information recording / reproducing device for reproducing.

Configuration of Conventional Example and Its Problems In an optical recording disk memory, which is expected as a high-density and large-capacity memory, an error control technique for overcoming the low error rate of the optical recording disk is very important.

An optical recording disk usually has an optically detectable guide track such as a guide groove in order to increase the track density. The recording layer formed on this guide track has a thickness of 1 μm.
Irradiate a laser beam focused about m to make a hole or change the reflectance for recording.

Since the recording dots and track pitch are about 1 μm, various defects may occur due to the formation of optical recording disc manufacturing process guide tracks, replica disc manufacturing, recording material vapor deposition, formation of a protective layer, or use environment of an unrecorded disc. , Dust and scratches occur, resulting in a dropout of the reproduced signal.

The dropouts are diverse and occur in bursts and random ones. As a result, the raw error rate of the optical recording disk is 10 ⁻⁴ to 10 ^−6.
It is said that the present situation is very bad compared with the raw error rate of 10 ⁻⁹ to 10 ⁻¹² of the magnetic disk which is a typical conventional recording medium.

Therefore, an optical information recording / reproducing apparatus using an optical recording disc usually has strong error control.

FIG. 1 is a diagram showing details of the format of a signal actually recorded on an optical recording disk. Reference numeral 1 is a synchronization signal for urging a clock synchronization pull-in at the time of data reproduction, 2 is a data mark using a fixed code to indicate the beginning of data, and 3 is a redundant bit added based on error correction code logic. , Interleaved encoded data. The recording signal block B consisting of the synchronization signal 1, the data mark 2 and the encoded data 3 is recorded in the information recording area of the sector divided by the address portion 4, as shown in B of FIG. In the address section 4, track addresses and sector addresses are generally recorded.

As described above, it is very effective to record the data by dividing the optical recording disk into sector structures and dividing the data into certain units, when recording digital information in which the length of the data is variable, and to make the recording area efficient. Well available.

The dropout existing on the optical recording disk generally reduces the envelope of the recording / reproducing signal and causes a demodulation error. When this dropout exceeds the capability of the error correction code, the error cannot be completely corrected at the time of demodulation.

In the case of a non-rewritable disc, when data is recorded in a certain sector and then the data is read and it is determined that the demodulation error is uncorrectable, the sector data is processed so that it is not reproduced, and it is recorded in another sector. You need to record the data again.

In addition, when updating a part of the data or erasing a file, it is better not to reproduce the data of the unnecessary sector.

Furthermore, when there is a dropout in the information recording area of an unrecorded sector that is expected to be unable to be reproduced correctly even if data is recorded, that sector is considered as a bad sector and data is not recorded. It is desirable that the optical recording disc be processed, and the same applies to a rewritable optical recording disc in this case.

As shown in the above example, if the sector in which data is to be recorded / reproduced is a defective sector, or if it is not needed for the purpose of updating, etc., make sure to perform processing that can identify it during reproduction. is necessary.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical information recording / reproducing apparatus capable of easily discriminating a defective or unnecessary sector from a sector in which recording / reproducing can be normally performed in an optical recording disk.

According to the present invention, a pulse train having a specific pattern is recorded in a defective sector and an unused sector, and when the pulse train having the specific pattern is detected during reproduction, this sector is determined as a defective or unnecessary sector, and recording / reproduction is not performed. This is the optical information recording / reproducing device.

Description of Embodiments The present invention will be described below with reference to embodiments.

In this embodiment, a plurality of pulse trains of a specific pattern are recorded in the information recording area of the sector in order to identify a defective sector and an unnecessary sector, and a plurality of pulse trains are overwritten in the sector where data has been recorded. Hereinafter, the operation of writing a plurality of pulse trains will be referred to as delete, and the plurality of pulse trains will be referred to as delete pulse.

FIG. 3 is a block diagram of a circuit for writing and deleting data in the sector. At the time of data writing, the target address 6 of the sector in which data is to be written is sent from the CPU 5 to the address detection circuit 7. When the target address is detected from the binarized reproduction signal 8,
The address detection signal 9 is sent to the write sector check circuit 10 to discriminate whether the sector to be written is a recorded sector or an unrecorded sector, whether it is a deleted sector or not, or to check the presence or absence of dropout.
Is returned to the CPU 5. When the sector to be written in this way is unrecorded and there is no dropout, the CPU 5 sends the write command signal 13 to the write gate generation circuit 12 according to the address detection signal 9 to generate the write gate 14. Sector buffer memory 15 according to write gate 14
The data 16 from the data is modulated by the modulation circuit 17, and as a sector recording signal 18 to which a synchronizing signal and a data mark are added, as shown in FIG. Sent. At this time, the output 22 of the multiplexer 21 is operated by the switching signal 20 from the CPU 5 so that the recording signal from the modulation circuit 17 is selected.

Next, the sequence for deleting will be described. In a non-rewritable disc, an error will occur when the data is read out immediately after recording the data, if the data will be newly written in another sector, if a part of the data will be updated, or a rewritable disc Including a bad sector, such as when there is a dropout that can be predicted to cause an error if the data is recorded.
Write a delete pulse in the unused sector.

In this case, the delete pulse 24 generated by the delete pulse generating circuit 23 is written on the optical recording disk as the output 22 of the multiplexer 21 by the switching signal 20 from the CPU after checking the target sector.

FIG. 4 shows a block diagram of a circuit for reading data. The target address 6 is sent from the CPU 5 to the address detection circuit 7, and the read sector check circuit 33 checks whether the target sector is a recorded sector or whether it is a delete sector. In this case, the CPU 5 sends the read command signal 26 to the read sector gate generation circuit 25, the demodulation circuit 27 demodulates the data from the binarized reproduction signal 8, and the data is taken into the sector buffer memory 15.

FIG. 5 shows the state of the reproduced signal when deleted.

FIG. 5a shows a reproduction signal when data is recorded in the sector, where 28 is an address and 29 is an envelope part of the data. FIG. 5b shows a pulse train signal to be written for delete. In order to distinguish it from data, two sets of pulse trains having a frequency lower than the data recording frequency are provided at intervals.

FIG. 5c is a diagram showing a reproduction signal when the signal indicated by b is written in the unrecorded sector. FIG. 5d is a diagram showing a reproduced signal when the signal of b is overwritten in the sector in which the data has already been recorded, and the laser is set to the recording power at the “H” level of the signal of b to be recorded on the optical recording disk. To write
In that portion, the original data having a high frequency disappears and all are at the "H" level.

FIG. 6 shows an example of a circuit for detecting a delete sector.
The binarized reproduction signal 8 is input to the re-trigger monomulti 29 whose time constant is set to be longer than the maximum pulse interval of the data part, and the inverted output 31 of the monomulti output 30 and the original binarized reproduction signal 8 are input. The logical product is taken as the delete detection signal 32.

The time chart of this delete sector detection circuit
It is shown in FIG. Figure 7 shows the case of recorded sectors
FIG. 8 shows the case of an unrecorded sector.

FIG. 7a shows a binarized reproduced signal when the delete pulse is overwritten, and the shaded portion is the data portion. The output when this signal is input to the retrigger monomulti 29 of FIG. 6 is shown in FIG. 7b. The delete detection signal shown in FIG. 7c is obtained by taking the logical product of the binarized reproduction signal of FIG. 7a and the inverted output of the mono-multi output of FIG. 7b. The time constant of the re-trigger monomulti is set to a value slightly larger than the recording frequency of the data, and the pulse interval of the delete pulse is larger, so the obtained delete detection signal deviates by the monomulti time constant width, but the original delete pulse It has almost the same waveform as.

FIG. 8 shows the case where the unrecorded sector is deleted. 8th
FIG. 10A shows a binarized reproduction signal, which has the same waveform as the delete pulse to be recorded. The logical product of this signal and the inverted output of the mono-multi output of FIG. 8b is shown in FIG. 8c, and the obtained delete detection signal is obtained for both the recorded sector and the unrecorded sector. Is the same.

Next, a method of detecting the delete sector using the serial port of the CPU will be described.

FIG. 9 shows an example of the delete pulse to be recorded and the delete pulse detection signal obtained during reproduction. FIG. 9A shows a delete pulse to be recorded, and two sets of five pulses having a width t ₁ arranged at intervals of t ₁ are provided. This signal is recorded and the inverted output of the delete detection signal obtained during reproduction is
Shown in Figure b. The pulse widths differ by the amount of re-trigger monomulti used at the time of detection, and t ₂ + t ₃ = 2t, (t ₂
> T ₃ ). In FIG. 9, St is a start bit,
Sp is a stop bit.

A serial port of a CPU, which is an example of an asynchronous data serial data receiving unit, detects a start bit at a fall from a high level to a low level, and fetches a plurality of bits of data according to a baud rate determined from that point. That is, if the delete pulse to be recorded is adjusted to the baud rate of the CPU to have a specific pattern and the delete detection signal detected during reproduction is directly sent to the serial port of the CPU, the CPU can immediately detect the delete sector. In the case of this embodiment, 8-bit data is taken in from the bit next to the start bit, and the pattern is set to "10101010". The ninth bit is a stop bit, and in this embodiment, the same pattern is recorded again at intervals of several bits after this. In this way, two sets of delete pulses are provided, and if only one of them is detected, this sector is determined to be a delete sector, thereby improving reliability.

Since the CPU samples and reads data at a frequency clock higher than the baud rate, the delete pulse interval should be as wide as possible. However, if an AC amplifier is used in the reproduction system, the low frequency band is cut. It is decided by the balance of

For example, when the CPU 8051 is operated with a clock of 12 MHz and the baud rate is set to 187.5 Kbps, the frequency of the delete pulse becomes 187.5 KHz, and this value can be set outside the low range to be cut.

The sector data is recorded / reproduced after the address of the target sector is detected. However, if the address cannot be detected due to a defect in the address section, the device will be in a waiting state. Therefore, if the unrecorded sector having a defective address section is deleted, the defective sector can be detected immediately from the addresses of the preceding and succeeding sectors and the deleted sector detection position, and the waiting state can be eliminated. The delete pulse writing is performed by converting from the time when the address of the sector before the defective sector is detected. The same applies to a non-rewritable optical recording disk and a rewritable optical recording disk.

EFFECTS OF THE INVENTION As described above, in a non-rewritable optical recording disk, when there is an error in the recorded data or when it is desired to update the data, a reproduction error is predicted in unrecorded sectors including the rewritable optical recording disk. When the target sector is defective, such as when there is a defect or when the sector address cannot be detected, or when it becomes unnecessary, by forcibly writing a pulse train of a certain specific pattern to this sector, The unnecessary sector can be easily detected, and the serial circuit of the CPU is used to detect the sector, so that a simple circuit configuration can be obtained.

[Brief description of drawings]

FIG. 1 is a sector format diagram of a recording signal, FIG. 2 is a diagram showing addresses and recording signal blocks of a sector of an optical recording disk, FIG. 3 is a block diagram of a sector data recording and delete circuit, and FIG. 4 is a sector. FIG. 5 is a block diagram of data reproduction, FIG. 5 is a state diagram of a delete pulse and a reproduction signal at the time of delete, and FIG. 6 is a block diagram showing a delete detection circuit.
FIG. 7 shows a time chart of the delete detection circuit in the recorded sector, FIG. 8 shows a time chart of the delete detection circuit in the unrecorded sector, and FIG. 9 shows the delete pulse and the input to the serial port of the CPU. It is a figure which shows the delete detection signal which does. 5 ... CPU, 7 ... Address detection circuit, 10 ... Write sector check circuit, 12 ... Write gate generation circuit, 15 ... Sector buffer memory, 17 ... Modulation circuit, 19 ... Semiconductor laser drive circuit, 21 ... multiplexer, 23 ... delete pulse generation circuit, 25 ... read sector gate generation circuit, 27 ... demodulation circuit, 29 ...
Re-trigger mono-multi, 33 ... Read sector check circuit.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Tatsuo Sugimura 1006 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (56) Reference JP-A-49-44725 (JP, A) JP-A-58-35733 (JP, A)

Claims (13)

[Claims] 1. A guide track which is optically detectable,
Means for recording / reproducing information on a sector-by-sector basis on the optical recording disk in which the guide track is divided into a plurality of sectors; and means for writing a pulse train having a width wider than the maximum data inversion interval in the information recording area of the sector, An optical information recording / reproducing apparatus comprising: means for detecting the pulse train during reproduction. 2. The optical information recording / reproducing apparatus according to claim 1, wherein the pulse train to be written is a pulse train consisting of repetitions of "1" and "0". 3. The optical information recording / reproducing apparatus according to claim 1, wherein the pulse train to be written is a pulse train in which the first bit is "1" and the last bit is "0". . 4. The optical information recording / reproducing apparatus according to claim 1, wherein the pulse train to be written is a pulse train capable of detecting that the first bit is "1" and the last bit is "0" during reproduction. apparatus. 5. The pulse train to be written is a pulse train capable of detecting the first bit as a start bit and the last bit as a stop bit in serial communication data reception of an asynchronous system. The optical information recording / reproducing apparatus described. 6. A pulse train is written in a sector in which information recorded sector is reproduced and when a demodulation error occurs, the pulse train is written in the sector. The optical information recording / reproducing apparatus described. 7. The light according to claim 1, wherein the pulse train is written in the sector before updating when updating the data of the sector in which information is recorded. Information recording / reproducing apparatus. 8. A pulse train is written in a sector where there is a defect such that a demodulation error is expected to occur when data is recorded and reproduced in a sector in which information is not recorded. An optical information recording / reproducing apparatus according to any one of claims 1 to 5. 9. The optical information recording according to any one of claims 1 to 5, wherein the pulse train is written in a sector in which information is not recorded when the address of the sector cannot be detected. Playback device. 10. The reproducing apparatus according to claim 1, wherein the sector in which the pulse train is detected is determined to be a defective sector during reproduction, and recording / reproduction is not performed on this sector. The optical information recording / reproducing apparatus described. 11. A sector according to claim 10, wherein at least two sets of pulse trains are recorded in one sector, and at the time of reproduction, if any one of the sets of pulse trains is detected, this sector is determined to be a defective sector. An optical information recording / reproducing apparatus according to the item. 12. A means for detecting a pulse train inputs a binarized reproduction signal to a re-trigger mono-multi, and a logical product of an output of the re-trigger mono-multi and an inversion signal of the binarized reproduction signal. A pulse train is configured to be detected by an output, and the pulse train is detected.
An optical information recording / reproducing apparatus according to any one of items. 13. The logical product output is input to a serial communication data receiving unit of an asynchronous method, and a plurality of bits are read in parallel from the first bit of the input bit string, whereby the corresponding sector is a defective or unnecessary sector. 13. The optical information recording / reproducing apparatus according to claim 12, characterized in that