JPS5891512A - Data recording system - Google Patents

Abstract

PURPOSE:To elevate utilization efficiency of a track for recording a data, by collecting a data field of prearranged length by plural areas, and displaying it by a sector block address in one address field. CONSTITUTION:2 data fields of DATA1 and DATA2 are blocked as one sector block 201. As for the sector block 201, the address is displayed by one ID part. The ID part consists of an address mark AM showing the start of address information, a sector block address SBA, a head address HA, a cylinder address CA, and an error detecting check byte CB of AM through CA. Among them, SBA is a number for representing the data fields DATA1, DATA2.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a data recording system, and particularly to a data recording system that performs sector blocking in a magnetic disk device.

As shown in FIG. 1, a magnetic disk device uses a head 3 attached to a head arm 2 to read and write data on a rotating recording medium disk 1 in sectors 102 obtained by dividing a track 101 by n. It is something. An arrow R indicates the direction of rotation of the recording medium disk 1.

FIG. 2 shows details of the track 101 and sector 102. What is actually read and written is the data field (DATA), the ID part is information indicating the position of the sector, and Gl, G2 and G3 are used to verify the ID part or read and write the data field. This field is required due to the performance specific to the magnetic disk device, and is a redundant byte that is not included in the actual data recording capacity.

In particular, the G1 and G3 fields are gaps necessary for the state transition for reading to move on to verifying the ID part of the next sector after writing of the data field is completed, and are required depending on the performance of the magnetic disk device. The length will vary.

The amount of data that can be stored in one track of a magnetic disk drive is determined by the data capacity per sector and the number of sectors per track. There is a problem in that the efficiency of using the track for data recording decreases.

The present invention has been made in view of the above circumstances, and its purpose is to solve the above-mentioned problems of the data distribution method in conventional magnetic disk devices and to improve the efficiency of track usage for data recording. The purpose of the present invention is to provide a data distribution method that enables the following.

The gist of the present invention is a data distribution method in a fixed data length sector type magnetic disk device.

The feature is that data fields of a predetermined length are grouped into a plurality of areas and are displayed as a sector block address in one address field. In other words, reading and writing data to a magnetic disk device that generally uses a fixed data length sector method is performed in sector units or in units of multiple sectors, and commands are also divided into read commands and write commands, and some commands are read and written across sectors. There is no writing from successive data or reading from writing. Therefore.

By collecting multiple data fields and addressing them as one sector block, we reduce the number of state transition gaps required from writing a data field to verifying the ID portion of the next sector block. ,
It becomes possible to increase the amount of data that can be stored in one track. In this case, the state transition from writing to reading or from continuation to writing does not occur between data fields in a sector block, so the data field on the previous edge when reading or writing starts or ends. It would be good if there was a short gap to recognize the boundary between the two.

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 3 shows a data allocation system according to an embodiment of the present invention, and is an example in which two data fields, DATAI and DATA2, are blocked as one sector block 201. Sector block 201 has one I
The address is displayed by section D.

As shown in the figure, the ID section includes an address mark (AM) indicating the start of address information, a sector block address (SBA), a head address (HA), a cylinder address (CA), and information from the AM to the CA. It consists of a check-by (CB) for error detection up to CB.

Among these, 5IIA is the data field DATAI,
This number represents DATmu2. Also, in Figure 1,
S indicates sector pulse.

FIG. 4 shows the correspondence between data field numbers and sector block numbers when the sector blocking method shown in FIG. 3 is followed. FIG. 4 (4) shows that when the track is divided into n equal parts and numbered OM-n from the starting point of the track (indicated by BT), the numbers 0, 2, 4, . ...n-1 is DATAI shown in Figure 3
Corresponds to number 1゜3.5. . . . n indicates that it corresponds to DATA2. Here, each DATAI and D
ATA2 is blocked and the sector block number is set to 0°1.2. ...Let it be m.

Further, FIG. 4(B) shows the case where the data field number and sector block number are expressed in binary numbers - (data field number) 1. (sector block number). In this case, the value of 21 bits or more of the data field number can be used as the sector block number. Also, when the 2° bit of the data field number is “0”, DATAI, “l”
In this case, the position within the sector block is known as DATA2.

When reading/writing is started by a command, 1 byte of data given at the same time as the start or in advance.
From the field number, sector, sector, sector, etc. according to the above correspondence relationship.
A block number can be generated and the position within the sector block can be determined at the same time.

The sector pulse for field division is present between DATAI and DATA2, and is used to determine the position when reading or writing ends at DATA1 or when reading or writing starts from DATA2.

Now, when data transfer is activated for data field numbers 3 to 3 shown in FIG. 4(A), the control procedure is as follows.

(1) Calculating the sector block number In this case, the data field number is 3 (00000
011)t, the sector block number is (00000001)z by taking these 21 or more bits.

(2) Determination of data transfer start data field Data field number 3 (00000011) Since the 2° bit of t is "1", it is DATA2 in this case.

((3) Ya □, 2゜7. Incense, go. A, Yani sector I
D information is read and addresses are compared to find the target sector/block position.

(4) When the target sector block is found, a detection operation is performed for the sector pulse signal indicating the previously determined position of DATA2.

(5) Detection wave of sector pulse D of sector block 1
Start data transfer using ATA2.

(6) After the above data transfer is completed, the ID information of the next sector block number is read, and the data is transferred using DATA1 of sector block 2 after comparing the addresses.

) After the data transfer is completed, the first sector pulse signal is detected and the command operation is completed.

In the above embodiment, as shown in FIG.
After the completion of the data transfer in step 2, the gap G5 necessary for the state transition to read the ID of the next sector block is
It is clear that one per block is sufficient, and the efficiency of track usage for data recording is improved.

Further, in the above embodiment, an example was shown in which 1.2 data fields were blocked as one sector block, but it goes without saying that the number of data fields to be blocked is not limited to two.

As described above, according to one aspect of the present invention, in a data recording method in a fixed data length sector type magnetic disk device, data fields of a predetermined length are grouped together in a plurality of areas, and a sector block address is stored in one address field. By displaying the data field, the gap required for state transition between data fields can be reduced, and the efficiency of track data recording can be improved. This has the following effects.

[Brief explanation of drawings]

FIG. 1 is a diagram showing an overview of magnetic disk recording, FIG. 2 is a diagram showing a sector format in a conventional data recording system, FIG. 3 is a diagram showing sector blocking as an embodiment of the present invention, and FIG. 41! ! ! Q(A). (B) is a diagram showing the correspondence between data field numbers and sector block numbers. 1: Disc, 2: Head arm, 3: Head °. 101:) Rack, 102: Sector, 201: Sector
block. Figure 1 Figure 2 02

Claims (1)

[Claims] In a data recording method in a magnetic disk drive using a fixed data length sector method in which one track is divided into equal parts according to information indicating boundaries, data of a predetermined length and
The fields are grouped into multiple areas and one address/field/sector/block address is displayed, converting the data field number specified by the program to the corresponding sector/block number, and A data recording method characterized in that a data field is accessed by calculating which data field corresponds to the data field.