JPH10320924A - Method for recording information - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for recording information, wherein a substitution process can be carried out without increasing an overhead time. SOLUTION: According to this method, an optical card is used which has a data area 7 for recording data, a substitutive area 8 for substituting the data in the data area, and a management area for recording substitution information including an address to be substituted and a substitutive address. When a recording error occurs at the data area, and when the data area becomes full, a substitution process is carried out. If a vacant area is present in the substitutive area, the substitution process is performed to the substitutive area. Without a vacant area in the substitutive area, it is detected whether the data area has a vacant area, and the substitution process is executed to the data area when the data area has the vacant area.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information recording method for recording information on an information recording medium such as an optical card.

[0002]

2. Description of the Related Art Various types of optical information recording media for recording and reproducing information optically, such as a disk, a card, and a tape, are conventionally known. Of these, card-shaped recording media (hereinafter referred to as optical cards)
Is expected to have a great demand as a write-once information recording medium having a large recording capacity which is small, lightweight and portable. FIG.
2 shows an example of an optical card. In FIG. 12, 1
Is an optical card, and 2 is an information recording area. Information recording area 2
In FIG. 1, tracking tracks 3 are arranged in parallel at a predetermined interval, and a data track 4 for actually recording data is provided between the tracking tracks 3. At both ends of each data track 2, a track number 5 for identifying each data track 4 is preformatted. Generally, the data track 4 is divided into one or a plurality of minimum recording units called sectors.

[0003] Further, since an optical card usually has a recording capacity of several megabytes, auxiliary data for managing stored data for each block, a so-called directory, is used to manage recorded data. The directory usually includes file information such as a file name, a file length, and a leading data track number managed by the directory, and the like is written to a part of the recording medium to perform file management of the data part. .

As a file management method for an optical card, for example, a method proposed in Japanese Patent Application Laid-Open No. Hei 5-6299 is known. According to this management method, the recording area is divided into a file data area for recording file data, a directory registration area for registering directory information, and a directory modification information registration area for modifying the registered directory area, and the directory information can be modified. It has a structure.

When a recording error occurs during the recording of file data in the file data area, data cannot be re-recorded on the track or sector where writing has been lost. Is performed on the track or the sector of the data. Also, when a part of the file data is changed, an alternative process is required.

[0006] Next, a description will be given of a process of substituting data of an optical card. FIG. 13 shows the information recording area 2 of the optical card 1. In the figure, 7 is a data area for recording user data, 8 is an alternative area for replacing data in the data area, and 3 is a management area for recording information for managing the data area and the alternative area. Here, the track number 1 to 500 is the management area 3, the track numbers 501 to 1500 are the data area 7, and the track numbers 1501 to 2000 are the replacement area 8. In the data area 7 and the replacement area 8, one track corresponds to one sector.
Addresses 1001 to 1500 are assigned to the sector of the replacement area 8.
Have been granted.

In the data area 7, data is recorded in the direction from address 1 to address 1000, and in the alternative area, data is recorded in the direction from address 1001 to address 1500. Here, if a recording error occurs during the recording of data in the data area 7, the data of that sector is recorded in the sector of the replacement area 8, and the replacement information is recorded in the management area 3. For example, data is recorded in the data area 7 in order from the address 1, and
If an error occurs when data is recorded at 00, data to be recorded at address 200 is recorded at address 1001 of alternative area 8. Also, the replacement information indicating that the data at the address 200 has been replaced with the track number 1501 is recorded in the management area 3, and the replacement process is completed. In this way, data is recorded in the data area 7 while performing the substitution process.

On the other hand, when reproducing data, before reproducing the data area 7, the management area 3 is reproduced in advance and alternative information is stored in the memory. Then, when reproducing the data in the data area 7, the sector replaced by the substitute information reproduces the data from the substitute area 8. For example, it is determined that the data at the address 200 is replaced with the address 1001 from the substitute information, and the address 20 is determined.
The address 1001 is reproduced instead of reproducing the data of 0. Thus, the information recording area is divided into the data area, the substitute area,
By dividing the data into management areas and performing the data area substitution processing, the recording capacity of the data area can be guaranteed, and the reliability of data can be improved. The allocation of the data area 7, the replacement area 8, and the management area 3 is appropriately determined by the application. However, in order to guarantee the capacity of the set data area, the replacement area should be set with a margin. General.

[0009]

However, in the prior art, the data area and the substitute area are fixedly set,
Since the amount of data that can be recorded is determined by the size of the preset data area, even if the substitute area is not used at all, once the data area is full, user data can no longer be recorded, and the substitute area cannot be used. There was a problem of wasting. As a method for solving such a problem, for example, Japanese Patent Laid-Open No. 4-170765 proposes a data recording method for recording data while dynamically managing the boundary between the data area 7 and the alternative area. In that publication,
When one of the data area and the alternative area is full, the boundary between the data area and the alternative area is changed so that data can be recorded thereafter.

Specifically, as shown in FIG. 14, first, the data area 7 of the optical card 1 is changed from the 1H track to the 8FFH track, and from the 1H track to the 8FFH track.
It is assumed that data is recorded in the direction of the track.
It is assumed that data is recorded in the direction from the 00H track to the 900H track. Also, the 0H track is assigned to the management area 3
The boundary address between the data area 7 and the replacement area 8 is recorded. For example, the 0H track is divided into 16 sectors of 16 bytes per sector and used, and 900H of the boundary address between the data area and the alternative area is recorded in the initial state.

Here, data is recorded in the data area 7,
If other data to be recorded remains when data is recorded on the last 8FFH track, an area necessary for recording the data is obtained in the alternative area 8 and recording is performed. For example, when 10H tracks are required to record the remaining data at the time of recording 8FFH tracks,
The data is recorded in the replacement area 8, and a new boundary address 910H is recorded in the management area 3. That is, the substitute area 8
Is used as a data area, and the data area 7 and the substitute area 8 are used.
Is shifted, the boundary address is updated to a new address. Conversely, if the replacement area 8 is full and the data area 7 is empty, a replacement area is obtained in the data area and a new boundary address is recorded in the management area 3. As described above, when the data area 7 is full and there is a free space in the alternative area 8, user data can be recorded thereafter.

However, in such a recording method,
Since the recording direction is opposite in the data area and the alternative area, when recording data in the alternative area, the data must be recorded from the opposite side of the boundary address. Here, a SCSI interface is generally used as an interface between the host computer and the optical card recording / reproducing apparatus. SCSI is, as is well known, ANSI X
3T9 / 89-042 SMALL COMPUTER
It is specified in SYSTEM INTERFACE (SCSI-2) and is widely used as an interface between a host computer and peripheral devices.

One of the commands defined by the SCSI standard is a write command. This write command can record data in a plurality of consecutive sectors in the direction in which the address increases from the designated address by designating the address at which data recording is started and the number of sectors. As with the write command, the read command can reproduce data of a plurality of sectors that are continuous in the direction in which the address increases from the designated address. However, when such a SCSI interface is used, in the information recording method as described above, data is recorded in a direction in which the address decreases in the alternative area, so that it is difficult to record and reproduce a plurality of continuous sectors. Therefore, when replacing data of a plurality of continuous sectors by using the SCSI interface, since only one sector can be processed, there is a problem that the overhead time of the SCSI command increases.

An object of the present invention is to provide an information recording method capable of performing an alternative process without increasing the overhead time in view of the above-mentioned conventional problems.

[0015]

SUMMARY OF THE INVENTION An object of the present invention is to provide a data area for recording data, a replacement area for replacing data in the data area, and a management area for recording replacement information including a replacement source address and a replacement destination address. When a recording error occurs in the data area using an information recording medium having
And an information recording method for performing an alternative process when the data area is full, and in the alternative process, if there is a free area in the alternative area, record data in the alternative area and store the alternative information. The replacement processing is performed by recording the data in the management area, and if there is no free area in the replacement area, it is determined whether or not there is a free area in the data area. An information recording method is characterized in that data is recorded in an area, and alternative information is recorded in the management area to perform an alternative process.

It is another object of the present invention to provide an information recording apparatus having a data area for recording data, a substitution area for substituting data in the data area, and a management area for recording substitution information including a substitution source address and a substitution destination address. An information recording method for performing a substitution process when a recording error occurs in the data area and when the data area is full, using a medium, wherein data is recorded in the same direction in the data area and the substitution area. In addition, at the time of the substitution processing, the data in which a recording error has occurred in the data area and the substitution data exceeding the capacity of the data area are held, and if there is a free area in the substitution area, the substitution data is stored in the substitution area. Record, substitute information is recorded in the management area to perform the substitution process, and if there is no free area in the substitution area,
Determining whether there is a free area in the data area, and if there is a free area, substitute data is recorded in the data area, substitute information is recorded in a management area, and substitute processing is performed. Achieved by recording methods.

[0017]

Embodiments of the present invention will be described below in detail with reference to the drawings. First, the first of the present invention
An embodiment will be described. FIG. 1 shows a configuration example of an information recording / reproducing system including a host computer and an information recording / reproducing device according to the first embodiment of the present invention. In FIG. 1, reference numeral 31 denotes an information recording / reproducing apparatus (hereinafter referred to as a drive) for recording and reproducing information on / from an optical card 1 as an information recording medium. The drive 31 is connected to a host computer 32 of the host controller, and the host computer 32
Recording and reproduction of information are performed based on the control of. Drive 3
As an interface between the host computer 1 and the host computer 32, the above-described SCSI interface is used.

The drive 31 has a partition function for dividing the recording area of the optical card 1 into a plurality of parts and managing them. Recording and reproduction of information on the optical card 1 are performed in sector units. 37 drives a transport mechanism (not shown) to introduce the optical card 1 into a predetermined position in the drive 31, reciprocates the optical card 1 in the R direction at the predetermined position, and further moves the optical card 1 out of the machine. This is a card feed motor for discharging paper to the printer.
Reference numeral 38 denotes a light beam irradiation optical system including a semiconductor laser as a light source, and irradiates the optical card 1 with a light beam of the light source focused on a minute light spot when recording and reproducing information. Reference numeral 39 denotes a photodetector for detecting light reflected from the optical card 1, and reference numeral 40 denotes a part of the light beam irradiation optical system 38 which drives a part of the light spot on the surface of the optical card 1 in the Z direction, that is, the optical card. An AF actuator 41 for performing auto-focus control by moving in the direction perpendicular to the plane is a light beam irradiation optical system 38.
Is an AT actuator for driving a part of the optical card 1 to move a light spot on the surface of the optical card 1 in the Y direction, that is, a direction orthogonal to the information track of the optical card, to perform auto tracking control.

The optical head 50 includes the light beam irradiation optical system 38, the photodetector 39, the AF actuator 40, and the AT actuator 41. Numeral 36 denotes a head feed motor for moving the optical head 50 in the Y direction to access the light spot to a desired track.
The MPU 33 is a processor circuit for controlling each unit in the drive 31, and has a built-in ROM and RAM. MP
U33 is a head feed motor 36, a card feed motor 37
And the like, and transmit and receive data to and from the host computer 32. The AT / AF control circuit 34 includes the photodetector 3
9 and the AF actuator 40 based on the output signal from
By driving the T actuator 41, the light beam irradiation optical system 3
Auto-focus control and auto-tracking control are performed so that the light spot from 8 focuses on the card surface and the light spot scans following the information track.

The modulation / demodulation circuit 35 is a circuit for modulating recording information under the control of the MPU 33 and demodulating reproduction information. When recording information, the host computer 32
Is modulated by the modulation / demodulation circuit 33, the light source in the light beam irradiation optical system 38 is driven in accordance with the modulation signal, and the intensity-modulated light beam is scanned on the information track, so that the optical card 1 Record information in When reproducing information, the light beam irradiation optical system 38 scans an information track of the optical card 1 with a light beam for reproduction, and the light detector 39 detects reflected light from the optical card 1. Then, the modulation / demodulation circuit 35 performs predetermined signal processing such as binarization and demodulation based on the signal of the photodetector 39 to reproduce the recorded information. Since the optical card 1 generally has a high error rate due to the nature of the medium, an error correction means is required when highly reliable information recording is required.

FIG. 2 shows an optical card used in this embodiment. In FIG. 2, the information recording area 2 of the optical card 1 has a format information area 3 for recording format information, a change information area 4 for recording change information of directory information and sector alternative information, and directory information for recording directory information. It is divided into four partitions, an area 5 and a file data area 6. In the format information area 3, format information indicating the size and the like of the change information area 4, the directory information area 5, and the file data area 6, information on card issuance, and the like are recorded. If necessary, a plurality of change information areas 4, directory information areas 5, and file data areas 6 may be set as one unit. In the directory information area 5, information necessary for file management such as a file name, a file size, and a head address of file data, that is, directory information is recorded. The change information area 4 records change information of directory information such as a change of a file name or a file size, sector substitution information, substitution area information, and the like.

FIG. 3 shows an example of information recorded in the change information area 4. First, FIG. 3A shows alternative area information for setting an alternative area in the file data area 6.
Reference numeral 201 denotes a change attribute indicating the type of change information. 01h (hexadecimal notation) is used as the change attribute indicating the alternative area information. 202 is the first sector address of the alternative area, 20
3 is the number of sectors in the replacement area. The substitute area 8 is set in the file data area 6 based on the substitute area information. FIG. 3B shows sector replacement information recorded in the replacement process. Reference numeral 201 denotes a change attribute indicating the type of change information, and 0 as a change attribute indicating sector replacement information.
2h (hexadecimal notation) is used, 204 is a starting source sector address of the replacement source, 205 is a starting destination sector address of the replacement destination, and 206 is the number of replaced sectors. The substitution information can represent the substitution of a plurality of continuous sectors.

FIG. 4 shows the structure of the file data area 6. The file data area 6 includes a data area 7 for recording user data, and an alternative area 8 for replacing a defective sector in the data area 6. In this case, there are 1500 sectors in the file data area 6, the sectors from addresses 1001 to 1500 are set as the replacement area 8, and the remaining sectors from addresses 1 to 1000 are set as the data area 7. In this case, the change information area 4
FIG. 3A shows the change attribute 201 as the substitute area information in FIG.
Indicates the replacement area information, 01h (in hexadecimal notation), change information in which the replacement area start sector address 202 is 1001, and the replacement area sector number 203 is 500.

In this embodiment, recording and reproduction of information are managed by the host computer 32. When the optical card 1 is detected to be inserted into the drive 31, the drive 31 is controlled to format the optical card 1 from the optical card 1. Read information. Next, the partition is appropriately set based on the read format information, and the change information area 4, the directory information area 5, and the file data area 6 are set.
Set. When the areas are set, the change information area 4 and the directory information area 5 are read out on the memory, and the recorded files are managed. Also, a data area 7 and an alternative area 8 are set in the file data area 6, and at this time,
It is possible to recognize the last recording sector address of each area and the alternative information of the data area. When newly recording file data, data is recorded from the next of the last recording sector address of the data area 7. When changing existing file data, it is re-recorded at an address that needs to be changed.

Next, the information recording method according to the present embodiment will be explained. FIG. 5 shows a data recording processing procedure. In FIG. 5, first, it is determined whether a target sector address to which data is to be recorded at the time of data recording is already recorded (step 1). In this case, the destination address is
If the address is equal to or lower than the last recording position of the data area 7, it is determined that data is already recorded in the sector address. Here, if the destination address has been recorded, an alternative process is performed (step 5). That is, data to be recorded at the destination address is recorded in the substitution area 8, and substitution information is recorded in the management area to perform substitution processing. The alternative processing will be described later in detail.

On the other hand, if the target address has not been recorded in step 1, it is determined whether or not the target sector address is an address in the data area 7 (step 2). In this case, if the target address is larger than the maximum address of the data area 7, it is determined that the sector is outside the data area. That is, it is determined that the data area has exceeded the set data area and the data area has been used up. Here, if the destination address is outside the data area, the substitution process is performed on the substitution area 8 in step 5. If the target address is an address in the data area 7 in step 2, data is recorded at the target address in the data area 7 (step 3). Next, it is determined whether or not the data has been recorded normally (step 4). If the data has been recorded normally, the recording process is terminated. If a recording error occurs, the substitution process is similarly performed at step 5.

FIG. 6 shows an alternative processing procedure of step 5 in FIG. In FIG. 6, first, in the substitution process, it is determined whether or not the substitution region 8 has no free space and is full (step 1). That is, it is determined whether or not the last recording address of the alternative area 8 is smaller than the maximum address 1500 of the alternative area in FIG. 4, and if the final recording address is smaller than the maximum address and there is a free area in the alternative area 8,
Data is recorded in the alternative area 8 (step 2). Thereafter, it is determined whether or not the data has been normally recorded (step 3).
As shown in FIG. 2B, the sector replacement information including the address of the replacement source sector in the data area 7 and the address of the replacement destination sector in the replacement area 8 is recorded in the change information area 4 of FIG. finish.

If a recording error occurs in step 3, the process returns to step 1 again to determine whether or not the alternative area 8 is full.
The data is recorded in the next sector, and it is determined whether or not the data was recorded normally. The processes of steps 1 to 3 are repeated until data can be normally recorded in this way, and if the data can be normally recorded, the substitution information is recorded in step 4 and the substitution process ends. On the other hand, if the last recording address of the substitute area 8 is larger than the maximum address in step 1 and the substitute area 8 is full, it is determined whether or not there is a free area in the data area 7 in FIG. 4 (step 5). .

If there is a free area in the data area 7, the data is recorded in the data area 7 (step 6).
It is determined whether the data has been recorded normally (step 3). When the data can be normally recorded, the substitute information is similarly recorded in the change information area 4 (step 4), and the substitute process is terminated. If a recording error occurs in step 3, the same processing is performed from step 1, and if there is a free area in the data area 7, data is recorded in the next sector.
It is determined whether or not the recording was successful. In this way, the same processing is repeatedly performed, and when the data can be normally recorded, the alternative information is recorded, and the alternative processing ends. On the other hand, in step 5, when the free area of the data area 7 is exhausted and the data area 7 is full, it means that the data area 7 and the alternative area 8 have all been used up. Cannot be recorded and terminates with an error.

Next, the information recording method of this embodiment will be described in more detail with reference to FIG. FIGS. 7A and 7B each show the configuration of the file data area 6 as in FIG. 7 is a data area, and 8 is an alternative area. First, FIG.
In (a), data area 7 is from address 1 to address 1
000, the alternative area 8 is from address 1001 to address 1500. The hatched portion indicates a recorded sector. That is, in FIG. 7A, the data area 7 is completely used up, and a free area remains in the alternative area 8 after the address 1201. In the present embodiment, when data is further recorded in this state, recording is performed at the address 1001 next to the last recording position of the data area 7. However, in this case, since this address is outside the data area as described with reference to FIG. 5, data is recorded at the address 1201 of the alternative area 8 to perform the alternative processing. Also,
Since the free area remains in the alternative area 8 thereafter, even when the data area 7 is used up, it is possible to record data by performing the alternative processing in the alternative area 8.

On the other hand, in FIG. 7B, the data area 7 includes addresses 1 to 1000,
Are from address 1001 to address 1500. Similarly, the shaded area is a recorded sector, the data area 7 is recorded from address 1 to address 800, and the alternative area 8 is completely used. In this embodiment, when data is recorded in this state, the data is recorded at the address 801 of the data area 7.
When a recording error occurs in 01, the substitution process is performed on the substitution area 8 as described with reference to FIG. However, in this case, FIG.
Since the alternative area 8 has already been used up as in (b),
As described with reference to FIG. 6, the substitution process is performed on the data area 7.

Specifically, address 8 of data area 7
The replacement process is performed on the address 802 next to the address 01, and the replacement information indicating that the address 801 has been replaced with the address 802 is recorded. When data is recorded at the next address, the address 802 has already been recorded. Therefore, the address 802 is replaced with the address 803 by a substitution process. Similarly, when data is recorded after the next address, the data is recorded by the substitute processing. As described above, in the present embodiment, when the replacement area 8 is used up and the data area 7 is replaced, the replacement information indicating that the sector has been replaced in the data area 7 is recorded. Thus, there is no problem in managing the data.

FIG. 8 shows a data reproduction processing procedure. First, when reproducing data from the optical card 1, format information, change information, directory information, and the like of the optical card 1 are read into the memory of the host computer 32 as described above. In FIG. 8, when reproducing data, first, change information in a memory is searched to determine whether there is alternative information of a target sector address to be reproduced (step 1). If there is no alternative information of the target address, the data of the target address in the data area 7 is reproduced (step 2), and thereafter, it is determined whether or not the data has been normally reproduced (step 3). Then, if the data can be reproduced normally, the reproduction processing is normally terminated. If the data cannot be reproduced normally, the reproduction processing is terminated with an error.

On the other hand, if there is alternative information of the target address in step 1, the alternative destination sector address which is an alternative destination of the alternative source sector address included in the alternative information is reproduced (step 4). When the data is reproduced, it is similarly determined whether or not the data has been normally reproduced (step 3). If the data has been reproduced normally, the process ends normally. If the data cannot be reproduced normally, the process ends with an error. As described above, by reproducing the replacement destination sector address based on the replacement information, the recorded data can be reproduced without contradiction.

As described above, according to the present embodiment, when a recording error occurs in the data area or when the data area is full, the replacement processing is performed. Since the alternative processing is performed first, data can be recorded until the data area and the alternative area are used up, regardless of which of the data area and the alternative area becomes full first. In addition, the replacement processing can be easily performed without recording any complicated processing by simply recording the replacement information while keeping the setting of the data area and the replacement area fixed.

Next, a second embodiment of the present invention will be described. In the first embodiment, the case where the processing is performed one sector at a time has been described. In the present embodiment, a case where a plurality of continuous sectors are recorded will be described. FIG. 9 shows a data recording processing procedure according to the present embodiment. In FIG. 9, first, when recording data, an area for recording data is checked (step 1). This is because, when recording a plurality of sectors, if the number of empty sectors in the data area 7 is small and the data more than the empty sectors in the data area is to be recorded, all the data cannot be recorded in the data area 7. This is a process of dividing into data to be recorded in the empty sector 7 and data that cannot be recorded in the data area 7. Data that cannot be recorded in the data area 7 is recorded in the alternative area 8. As described above, in Step 1, the data to be recorded in the data area 7 and the data to be recorded in the alternative area 8 are sorted.

Next, as a result of the data distribution in step 1, it is determined whether there is data to be recorded in the data area 7 (step 2). If there is data to be recorded in the data area 7, the data is transferred to the data area 7. (Step 3). In this case, since recording is performed in a plurality of continuous sectors, the SCSI write command only needs to be issued once. When a recording error occurs during recording, the data of the sector in which the error occurred is held as substitute data. Then, the remaining data is recorded from the next sector in which the error has occurred. Next, it is determined whether there is data to be recorded in the alternative area 8 (step 4). This data includes the data allocated to the alternative area 8 in step 1 and the data that has been recorded as an alternative data due to the occurrence of a recording error in step 3. If so, an alternative process is performed in step 5. Note that this substitute data is data of a plurality of continuous sectors.
One data block. On the other hand, if there is no data to be recorded in the alternative area 8 in step 4, the recording process ends.

FIG. 10 shows an alternative processing procedure of step 5 in FIG. In FIG. 10, first, it is determined whether or not the substitute area 8 is full (step 1). If there is a free area in the substitute area 8, the substitute data is recorded in the substitute area 8 (step 2). Next, it is determined whether or not a recording error has occurred (step 3). If no recording error has occurred and normal recording has been performed, the sector replacement information shown in FIG. It is recorded in the change information area 4 (step 4). Further, it is determined whether or not all the alternative data has been recorded (step 5),
If data that has not been recorded remains, the processing from step 1 is performed. On the other hand, when a recording error has occurred in step 3, alternative information of data that could be normally recorded among the data recorded in step 2 is recorded (step 6).
Thereafter, the process returns to step 1 to perform processing for recording the remaining alternative data.

That is, it is determined whether or not the alternative area 8 is full (step 1), if there is a free area, the remaining alternative data is recorded from the next sector (step 2), and whether or not a recording error has occurred. (Step 3). Here, when no recording error occurs and the recording is performed normally, the substitute information is recorded (step 4), and thereafter, it is determined whether or not all the substitute data are recorded (step 5). If has been recorded, the substitution process ends. On the other hand, in step 1, there is no free area in the alternative area 8, and
If the data area 7 is full, it is determined whether or not the data area 7 is full (step 7). If there is a free area in the data area 7, alternative data is recorded in the data area 7 (step 8). Here, in Steps 2 and 8, since the replacement data of a plurality of continuous sectors is recorded, the SCSI write command may be issued once similarly.
It is possible to reduce the overhead time of the SCSI command.

Next, it is determined whether or not a recording error has occurred (step 3). If the recording has been normally performed, the alternative information is recorded (step 4). Thereafter, it is determined whether or not all the alternative data has been recorded (step 5). If there is any unrecorded alternative data, the same processing is performed from step 7 and the remaining alternative data is stored in the data area 7. Record. If a recording error occurs in step 3, substitute information is recorded for the substitute data that could be normally recorded in step 6, and then the same processing is performed from step 7, and the data in which the recording error occurred is stored in the data area. Record in 7. In this way, the replacement data is recorded, and when all the replacement data have been normally recorded, the substitution process ends.

Next, the information recording method of this embodiment will be described with reference to FIG.
This will be described in more detail with reference to FIG. FIG. 11 shows the configuration of the file data area 6. In FIG. 11, the data area 7 covers the area from address 1 to address 1000,
01 to address 1500 are set in the substitute area 8. The hatched portions indicate recorded sectors, and the crosses indicate defective sectors in which data cannot be normally recorded. In this state, when recording data of, for example, continuous 10 sectors, first, data to be recorded is sorted in step 1 of FIG. In this case, since the data area 7 is vacant from the address 996 to the address 1000, the data of 5 sectors is allocated to the addresses 996 to 1000, and the data of the remaining 5 sectors is allocated to the addresses 1001 to 1005 of the alternative area 8. Address 1001
Since the data of ~ 1005 is a continuous sector, it is held as one alternative data.

Next, the process proceeds to step 3 via step 2 in FIG.
Record the substitute data in 0. However, in this case, since the addresses 996 to 998 are defective sectors, a recording error occurs.
998 data and the address 1001 of the alternative area 8
It holds data of ~ 1005. Next, step 4
Then, the process proceeds to step 5 to perform the alternative processing of FIG. At the time of the substitution process, first, the process proceeds to step 2 via step 1 and the data allocated to the addresses 1001 to 1005 is already recorded in this area.
Free addresses 1201 to 12 as indicated by 9 in 1
Record at 05. If the data can be normally recorded, the alternative information is recorded in step 4 according to the format shown in FIG.

More specifically, the change information 201 is recorded in the change information area 4 as 02h, the replacement source sector address 204 as 1001, the replacement destination sector address 205 as 1201, and the number of sectors 206 as five. Next, in step 5, it is determined whether or not all the alternative data has been recorded. At this time, since the data of addresses 996 to 998 remains, the process proceeds to step 2 again via step 1, and the remaining addresses 996 to 998 are stored. The 998 data is recorded at addresses 1206-1208 indicated by 10 in FIG. If the data can be recorded normally, the alternative information is recorded for this data in step 4, and the recording process for all data is completed. In the present embodiment, continuous processing of a continuous sector is possible, and the drive 3
1, the number of SCSI commands issued to the
The overhead time of the SI command can be reduced.

[0044]

As described above, according to the present invention, data can be recorded until both the data area and the replacement area are used up, even if the data area or the replacement area becomes full first. The replacement process can be easily performed simply by recording the replacement information without requiring any process. Further, the substitution process for a plurality of continuous sectors can be performed only by issuing the SCSI command once,
Command overhead time can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration example of an information recording / reproducing system according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a format of an optical card used in the first embodiment of the present invention.

FIG. 3 is a diagram for explaining a format of change information.

FIG. 4 is a diagram showing the file data area of FIG. 2 in detail.

FIG. 5 is a flowchart showing a data recording process according to the first embodiment of the present invention.

FIG. 6 is a flowchart illustrating a data substitution process according to the first embodiment of this invention.

FIG. 7 is a diagram for explaining in detail an information recording method according to the first embodiment of the present invention.

FIG. 8 is a flowchart showing a data reproduction process according to the first embodiment of the present invention.

FIG. 9 is a flowchart showing a data recording process according to the second embodiment of the present invention.

FIG. 10 is a flowchart illustrating a data replacement process according to the second embodiment of this invention.

FIG. 11 is a diagram for explaining in detail an information recording method according to a second embodiment of the present invention.

FIG. 12 is a plan view showing a recording surface of the optical card.

FIG. 13 is a diagram for explaining a data replacement process of a conventional example.

FIG. 14 is a diagram for explaining an information recording method of the prior application.

[Explanation of symbols]

 1 optical card 4 change information area 6 file data area 7 data area 8 alternative area 31 drive 32 host computer 33 MPU

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Claims (5)

[Claims] 1. An information recording medium comprising: a data area for recording data; a replacement area for replacing data in the data area; and a management area for recording replacement information including a replacement source address and a replacement destination address. An information recording method for performing a substitution process when a recording error occurs in an area and when the data area is full, and in the substitution processing, when there is a free area in the substitution area, Data, and substitute information is recorded in the management area to perform substitution processing.If there is no free area in the substitute area, it is determined whether there is a free area in the data area. When there is an area, data is recorded in the data area, alternative information is recorded in the management area, and an alternative process is performed. 2. The information recording method according to claim 1, wherein the recording directions of the data area and the replacement area are the same. 3. An information recording medium comprising: a data area for recording data; a replacement area for replacing data in the data area; and a management area for recording replacement information including a replacement source address and a replacement destination address. An information recording method for performing a substitution process when a recording error occurs in an area and when the data area is full, wherein data is recorded in the same direction in the data area and the substitution area, Holding data in which a recording error has occurred in the data area and alternative data exceeding the capacity of the data area, and if there is a free area in the alternative area,
The replacement data is recorded in the replacement area, the replacement information is recorded in the management area, and the replacement process is performed. If there is no free area in the replacement area, it is determined whether the data area has a free area. An information recording method, wherein when there is a free area, substitute data is recorded in the data area, substitute information is recorded in a management area, and substitute processing is performed. 4. The information recording method according to claim 3, wherein said replacement information includes the number of continuous sectors to be replaced. 5. The information recording method according to claim 1, wherein the recording medium is an optical card.