JP2723226B2 - Magnetic recording / reproducing device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention divides a magnetic disk into sectors in a recording area,
Further, the present invention relates to a magnetic recording / reproducing apparatus that divides each sector into an ID area and a data area for recording, and particularly relates to a magnetic recording / reproducing apparatus having an error correction circuit. 2. Description of the Related Art Conventionally, in a magnetic recording / reproducing apparatus having an error correction circuit, an error rate (erroneous reading rate) of data read from the magnetic recording / reproducing apparatus is 10 ⁻⁹ (number of error bits / total number of bits). The level is allowed, and the error correction circuit suppresses the data error rate to the host system to 10 ^-22 or less. Here, it may be considered that the frequency of use of the error correction circuit is extremely rare and the time required for error correction does not affect the average access time. By the way, in consideration of the capability of the error correction circuit, the error rate of the data read from the magnetic disk device can be actually increased more than 10 ^-9 . When the error rate is increased, a bit error can be tolerated by the difference between the error rates, so that the recording density of the magnetic disk can be improved, that is, the storage capacity can be increased by the so-called phase margin. As described above, in the magnetic recording / reproducing apparatus in which the error rate is raised, the phase margin is improved, the density is increased, and the reliability of the information is ensured by the error correction, the frequency of using the error correction circuit increases, and the error correction is required. Time cannot be ignored and access time has been reduced. Therefore, a recording format in which the corresponding ID area and data area are physically located in different sectors as shown in FIG. 3 has been devised. Each divided sector RSN0, PSN1, PSN2 ...
Are divided into ID areas ID0, ID3, ID6... And data areas DATA5, TATA0, DATA3... As shown in FIG. Information for phase synchronization of the synchronous circuit), AM indicating the head of the ID area
T, FLAG indicating a defective sector or an alternative sector, PCNH, PCNL indicating a data cylinder number, PHN indicating a physical head number, ISN indicating a logical ID area sector number, and a data area corresponding to the ID area DSN indicating physical sector number, redundant bit ECC for error detection / correction of ID area information, and ID indicating boundary between ID area and data area
-Consists of PAD. The data area is PLL-SYN
C, AMD indicating the beginning of the data area, recording data DATA, an error correction code ECC for correcting an error occurring in the data area, and DATA-PAD provided between the data area and the next sector area Have been. Recording or reproduction to or from the data area of the magnetic disk having such a recording format is executed after first confirming the information of the ID area of each sector. The detection of an error occurring in the information of the ID area is performed by comparing the error correction code created using the read information of the ID area with the error correction code recorded in excess. This error detection is performed at high speed, but when an error is detected, a certain error correction processing time is required, and information within this time cannot be read. When an error is detected in the data area, information loss occurs in the same manner. More specifically, when recording or reproducing data for one track in the recording format shown in FIG. 3C, the error correction of the information in the ID area is completed before the information in the next ID area is read. The error correction of the information in the data area is to be completed before starting to read the information in the next data area.) In one rotation of the disk, ID0, DATA0, ID1,
Only the information of DATA1, ID2, DATA2 can be processed, and ID at the second rotation
Processing of information of 3, DATA3, ID4, DATA4, ID5 DATA at the third rotation
The information of 5, ID5, DATA6, ID7, and DATA7 was processed. In other words, recording or reproduction of one track required three rotations of the disk. (Problems to be Solved by the Invention) The present invention has improved the problem that the access time is lost when the error rate of the magnetic recording / reproducing apparatus using the error correction circuit is increased as described above. It is an object of the present invention to provide a magnetic recording / reproducing apparatus which prevents an access time from decreasing while improving the magnetic recording / reproducing apparatus. The present invention divides a recording area of a magnetic disk into a plurality of sectors, divides each sector into an ID area and a data area, and In the magnetic recording / reproducing apparatus adopting a magnetic recording method of adding an error correction code to each of the data areas and recording the logically corresponding ID area and the data area in physically different sectors,
The error correction process can be completed before reading the information in the ID area of the sector m (m is an integer of 1 or more) ahead of the sector in which the error has occurred in the ID area, and sequentially switching to the ID area. M error correction circuits for the ID area which can be used in the data area, and before reading the information of the data area of the sector n (n is an integer of 1 or more) ahead of the sector in which the error occurred in the information of the data area. The error correction process can be terminated at the same time, and n
Data area error correction circuits, and the ID area and the data area corresponding to the ID area are arranged in a sector separated from a distance corresponding to a time corresponding to the time when the error correction processing of the ID area ends. This is characterized in that a recording format is formed so that (Operation) In a magnetic recording / reproducing apparatus in which an error detection code is simply added to the ID area, if a bit error of the ID is detected, the disk has to wait for rotation for retry. In the present invention, since an error correction code is also added to the ID area, even if a bit error is detected in information in the ID area, if error correction is performed, retry is not required. In this case, the ID
When an error occurs in the information of the area, access to the data area is started while the error correction processing is being performed, and the information of the data area is lost. Therefore, according to the present invention, m error correction circuits for information in the ID area and n error correction circuits for information in the data area are provided. The error correction of the information in the data area is completed before reading of the information in the n-th data area is started. Further, the m number of error correction circuits for ID area are sequentially switched and used each time an ID area is detected, and the n error correction circuits for data area are sequentially switched and used each time a data area is detected. As a result, even if error correction is performed in both the ID area and the data area, information is not lost while performing error correction processing.
In addition, information can be read without reducing access time. Next, at the time of recording information, the information in the ID area is read, and when the information is correct, the information is written into the data area corresponding to the ID area. If the data area is adjacent to the data area, access to the data area is started while the error correction processing of the information in the ID area is being performed, and the writing of the information requires waiting for one rotation of the disk. Therefore, in the present invention, the corresponding ID area and the data area are not adjacent to each other and are arranged at a distance slightly longer than the distance corresponding to the time required for the correction processing by the error correction code of the ID area to be completed. . This allows the ID
Even if error correction is performed in the area, the corresponding data area is immediately accessed and information can be recorded without waiting for the rotation of the disk. Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a recording format of a magnetic disk according to an embodiment of the present invention. Here, a magnetic recording / reproducing apparatus including one ID area error correction circuit and two data area error correction circuits is assumed. FIG. 3A shows an index signal, which is a signal having one cycle of one rotation of the disk. The pulse interval of the index corresponds to the track length, and one track length is divided into a plurality of sectors. FIG. 3B shows a sector pulse generated for each sector. FIG. 4C is a diagram showing the recording format of FIG. 4C, and FIG. 4D is an enlarged view of the recording format of each sector. In FIG. 3C, the ID area ID0 and the corresponding data area DATA0 are not arranged adjacent to the same sector but are interleaved with the sectors PSN0 and PSN1, respectively. The distance between them is longer than the distance corresponding to the error correction processing time using the error correction code ECC in the ID area described later, and is arranged at a position as close as possible.
However, the data area DATA0 and the following ID area ID1 do not need to be interleaved and are arranged adjacently. Also,
In FIG. 3D, an error correction code ECC and a data area sector number DSN are added to the ID area. The error correction code ECC is the same as that recorded in the data area. The error correction code enables the error correction, and is generated by the ID area error correction circuit 14. The data area sector number DSN is information indicating the physical sector number of the data area corresponding to the ID area, and is necessary because the ID area and the corresponding data area are not adjacently arranged. According to such a recording format, for example, information in the data area / DATA5 is read out, or the data area / D
When recording information in ATA5, ID5 is searched first and this ID5
It is known that the physical sector number of the corresponding data area DATA5 is PSN6 by referring to the data area sector number DSN. If no error occurs in this ID5, the read timing or write timing of the data area / DATA5 is determined from this DSN. If an error occurs in ID5 and the error can be corrected, an error correction process is performed. At the end of this process, the magnetic head is immediately before ID6 and the information of ID6 is continuously taken in. Here, if an error occurs in this ID6, the error correction circuit 14 for the ID area
When this processing is completed, the magnetic head is located immediately before ID7 and the information of DATA5 cannot be processed by the same error correction circuit. Processed by FIG. 2 is a diagram showing a configuration of a system for realizing the above method. The magnetic disk controller 1 is located between the host system 2 and the magnetic disk device 3, and controls recording or reading of information on the magnetic disk device 3. The magnetic disk controller 1 and the host system 2 are connected via a host interface 11. The microprocessor 12 controls each part. The buffer memory 13 is a RAM for temporarily storing data to be recorded on the disk or data read from the disk.
The error correction circuit consists of 14 for the ID area and 15 and 16 for the data area.
Each of them has a function of generating an error correction code ECC corresponding to information to be recorded on a disk, and performing a correction when an error occurs in data read from the disk. The control circuit 17 controls each block in response to an instruction from the microprocessor 12 or independently. The recording / reproducing circuit 18 converts a parallel signal sent from the buffer memory 13 into a serial signal and outputs it to the magnetic disk device 3 as a write signal, or converts a serial signal read from the magnetic disk device 3 into a parallel signal. Has a function of transmitting the data to the buffer memory 13 and the error correction circuits 14, 15, and 16 via the format generator 19 and the control circuit 17. The format generator 19 generates a recording format as shown in FIG. The sequencer 20 controls the sequence of formatting, recording, and reading. Further, the sector counter 21 is provided in the magnetic disk drive 3 shown in FIGS.
A physical sector number is generated from the index pulse and the sector pulse. [Effects of the Invention] According to the present invention, even if an error occurs in any of the ID area and the data area, the disk does not wait for one rotation, so that the access time is reduced even if the bit error rate is increased. Nothing. This can contribute to improvement of the storage capacity of the magnetic disk.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing an embodiment of a recording format of a magnetic disk according to the present invention, FIG. 2 is a block diagram showing a configuration example of a system for realizing the embodiment, FIG. FIG. 1 shows a recording format of a conventional magnetic disk. 1: magnetic disk controller, 2: host system,
3 magnetic disk device 11 host interface, 12 microprocessor, 13 buffer memory, 14 ID area error correction circuit,
15 ... Error correction circuit for data area (a), 16 ... Error correction circuit for data area (b), 17 ... Control circuit, 18 ... Recording /
Playback circuit, 19 ... format generator, 20 ... sequence,
21 ... Sector counter.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification number Agency reference number FI Technical display location G11B 20/18 572 G11B 20/18 572F

Claims (1)

(57) [Claims] Dividing the recording area of the magnetic disk into multiple sectors,
Each sector is divided into an ID area and a data area, and an error correction code is added to each of the ID area and the data area to logically correspond the ID area and the data area to physically different sectors. In the magnetic recording / reproducing apparatus adopting the magnetic recording method for recording, the information in the ID area of the sector m (m is an integer of 1 or more) ahead of the sector in which the error occurred in the information of the ID area before reading is started. The error correction process can be terminated,
M ID area error correction circuits that can be sequentially switched and used for each ID area; and n from the sector where an error has occurred in the information of the data area.
The error correction process can be completed before starting to read the information of the data area of the next (n is an integer of 1 or more) sectors, and the n data area errors that can be sequentially switched and used for each data area A correction circuit, wherein the ID area and a data area corresponding to the ID area are
A magnetic recording / reproducing apparatus characterized in that a recording format is formed so as to be arranged in a sector which is longer than a distance corresponding to a time corresponding to a time when an error correction process of an area is completed. 2. The ID area and a data area corresponding to the ID area
2. The magnetic recording / reproducing apparatus according to claim 1, wherein the ID area is disposed in a sector which is longer than a distance corresponding to a time when the error correction processing of the ID area is completed and is close to the sector. 3. 2. The magnetic recording / reproducing apparatus according to claim 1, wherein a data area corresponding to the ID area and an ID area following the data area are arranged in adjacent sectors.