JP2574268B2 - Magneto-optical disk controller - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magneto-optical disk control device used as a recording terminal device of a computer.

2. Description of the Related Art Conventionally, a write-once optical disk that can be recorded only once as a mainstream optical disk is known. Recently, an optical disk capable of recording / reproducing any number of times is being developed.

Hereinafter, an erasable magneto-optical disk will be described.
The recording principle of a magneto-optical disk is that a magnetic film with perpendicular magnetic anisotropy is used as the material, and the recording pits can be recorded according to the difference in the direction of the magnetic field. At the time of reflection of laser light, reading is performed by utilizing the fact that the vibration surface of the light rotates according to the direction of the magnetic field.

In data writing, heat is applied to the medium by laser light or the like, and when the medium approaches the Curie temperature, the material loses magnetism. At this time, when a magnetic field is applied from the outside and cooled, the magnetization can be performed in the direction of the applied magnetic field, and data can be written and erased (Erase).

As a method of recording data on the entire track, data is not recorded in the first rotation, a magnetic field is operated in the second rotation, and data is written in the third rotation.
Then, the magnetic field is stopped at the fourth rotation, and a read for verification (Verify Read) is performed at the fifth rotation.

With this operation, the read power of the laser beam (Read Power) is controlled in the second and fourth rotations while operating the magnetic field.
Is applied to the medium, which causes data degradation.

As described above, the number of rotations required for writing is 5
This is a rotation, which also involves data degradation.

Problems to be Solved by the Invention However, the above-described conventional configuration has the following problems.

(1) A magneto-optical disk records data by activating a magnetic field during data recording, but it takes about 1.3 ms after the operation of an electric signal until the magnetic field reaches a steady state. Can not.

(2) Data recording can be performed by applying a magnetic field and irradiating the medium with laser light. But the desired track,
Alternatively, a laser must be irradiated on data already recorded to search for a sector address, and even if a desired sector address is found, it takes time to control the magnetic field. It needs to be launched. Therefore, when a magnetic field is applied when the laser beam is applied with the read power, data on the medium is degraded.

The above (1) and (2) cause a problem at the time of Verify Write of data recording. First, in order to extract a target address, Data Read is required, but no magnetic field must be applied at that time. A magnetic field must be applied 1.3 ms before data recording. In order to perform Verify Read after data recording, a condition that data must be read after the magnetic field is turned off can be extracted.

The present invention adds the time required for a magnetic field operation of a magneto-optical disk to a data recording sequence, enables continuous data recording, and minimizes data deterioration due to laser beam irradiation of a medium during a magnetic field operation transient state. It is an object of the present invention to provide a magneto-optical disk control device capable of performing the above.

Means for Solving the Problems The present invention provides a medium having a spiral groove, a laser pickup capable of changing at least three levels of writing, erasing, and focusing on the medium, and a laser pickup for the medium. A magnetic field generator capable of controlling the direction of the magnetic field, and operation and stop; and a microprocessor for controlling the medium, the laser pickup, and the magnetic field generator. Is a controller that generates a predetermined magnetic field to write data, and then turns off the predetermined magnetic field to read out the recording confirmation, when the recording address is moved to one track before or data is written (Write). At the end, control is performed to set the light quantity of the laser pickup to the focus level of the minimum light quantity level. .

Function The present invention can prevent the magnetic field on / off operation and data deterioration due to Read Power, which have been the conventional problems by the above-described configuration, and optimize the disk format structure and control method for a magneto-optical disk. Can be

Embodiments Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of a magneto-optical disk control device according to an embodiment of the present invention.

In FIG. 1, reference numeral 1 denotes a magneto-optical disk having a spiral groove, 2 denotes a laser pickup capable of varying the amount of light, 3 denotes a magnetic field generator capable of controlling the direction and operation and stop of a magnetic field, and 4 denotes a magnetic field. On / off of the generator 3 is controlled to write / erase (Era) the magneto-optical disk.
5) a laser power control unit for controlling the power of the laser pickup 2, 6 a power switching unit for switching the power at the time of writing, reading (Read) and focus, and 7 a head. Equalizer amplifier, 8 is phase locked loop (PLL)
A circuit, 9 is an encoder for modulating a digital signal,
10 is a decoder for demodulating the modulated signal,
2 is a buffer, 13 is a host computer, 14 is an address extraction unit that extracts track and sector addresses, 15
Is an I / O port, 16 is a CPU, 17 is a RAM, and 18 is a ROM.

Hereinafter, the magneto-optical disk will be described in more detail.
FIG. 2 shows a configuration of an ID portion and a data portion of a sector of the magneto-optical disk 1. As shown in FIG. 2, the magneto-optical disk has an ID portion including a track and a sector, and a data portion for recording data. It is composed of The ID section records uneven ID information on the medium itself, and a magnetic material is used for the data section.

In order to perform data recording, the data length of one sector must be longer than the operation time of the magnetic field, including the relationship between the rotation speed and the clock in the drive. And Writ
e When the magnetic field is turned on, the target ID is detected one sector before, and the output (Power) of the laser beam is performed. Write Power for writing data and Read for reading data are performed.
When the magnetic field is activated to switch to Power and Focus Power of the lowest level that the focus track is applied, Focus
Works with us Power.

The groove of the magneto-optical disk 1 has a spiral structure, and the maximum data processing unit is set to (n-1) sectors at a time for track data having n sectors in one round, and a steel jump is performed in the remaining one sector at the same time. It is configured to perform magnetic field control. When transitioning from the data recording operation to the Verify Read operation, the magnetic field is turned off using the steel jump sector. Also, the laser light is Write Pow
er to Focus Power.

Next, the data length of one sector for a magneto-optical disk as a medium will be described using an example below. A driver that rotates this magneto-optical disk medium at 2400 rpm. The data transfer rate per rotation at a data transfer speed of 8 MHz is 25 Kbytes.
It is. When the operation time of the magnetic field is required to be 1.3 ms, the minimum data amount of one sector is 1300 bytes. The maximum number of sectors in one track is 19 sectors.

From the above calculation results, the medium when using a drive of 8 MHz transfer at 2400 rpm requires one track of 19 sectors or less, or one sector of data amount of 1300 Byte or more.

FIG. 3 shows a track structure of a magneto-optical disk. As shown in FIG. 3, as an example of data processing,
One track is composed of 17 sectors, which will be described below.

When one track has 17 sectors, the data amount of one sector is 1470 bytes, the sector ID portion is 170 bytes, and the data portion is 1 byte.
300 bytes.

Since the medium of the magneto-optical disk has a large bit error rate of 10, data including ECC processing is also included in the data section.

Controls for writing to the medium include: (1) one magnetic field on / off control line, (2)
One magnetic field direction control line (erasing and writing are determined by the magnetic field direction), and (3) two laser power control lines are required in addition to the conventional optical disk control.

Hereinafter, the control operation will be described with reference to FIG. 4, FIG. 5, and FIG.

(1) Continuous Verify Write FIG. 4 shows a control time chart in the processing when the data write amount is continuously performed for 16 sectors or more.

Verify Write operation is a data blank check (Fl
ag Check) (checks that no data is recorded in the sector to be written), Data Write (records data), Verify Read (checks whether the recorded data is normal). finish.
The processing when the data buffer uses 16 sectors will be described. The continuous operation from sector (b) to sector (Q) in FIG. 3 will be described. (The direction of the magnetic field is the Write direction) The ID of the target sector (b) is extracted, the unrecorded data in the target sector is checked, and then the same processing is continued up to the sector (Q).

In order to record data in the target sector (b), a steal jump (JU) is performed from the sector (Q) to the sector (b).
MP). At that time, the recording magnetic field is turned on, and at the same time, the laser power is switched to Focus Power.

Move to the track of target sector (b) and move to sector (a)
The laser power at the end of the data section
And confirm the sector (b).

Write data to the data section of sector (b)
Record with r.

 The above processes 1 to are performed up to the sector (Q).

Target sector (b) for checking recorded data
Then, make a steel jump. At that time, the recording magnetic field is turned off, and at the same time, the laser power is switched to Focus Power.

Move to the track of the target sector (b), and set the laser power to Read Pow at the end of the data section of the sector (a).
er, and checks the recording data from sector (b) to sector (Q).

If data is recorded after sector (R),
At the same time, the target sector is set to (R), and the processing is repeated from the processing.

Next, a case of a recording operation of a specific sector will be described with reference to FIGS. (The magnetic field direction is the Write direction) The number of sectors to be recorded is 1 to 15.

The recording target sector will be described by taking the case of (Q) one sector recording as an example.

Laser power to check target sector (Q)
Extract as Read Power and check for unrecorded data content.

A steal jump is made from sector (Q) to sector (b).

When the sector (P) one sector before the sector (Q) is extracted, the recording magnetic field is turned on, and at the same time, the laser power is reduced.
Focus Power.

At the end of the data part of sector (P), the laser power is
Set to Read Power and extract the sector (Q). Data is recorded in the data portion of the sector (Q) by Write Power.

When the data recording is completed, a still jump is made to the sector (b). At the same time, the recording magnetic field is turned off, and the laser power is set to Focus Power.

When entering the track of the sector (b), the laser power is set to Read Power, and the target sector (Q) is extracted.

Verify Read the data in the sector (Q) and perform data check. Thus, the data recording ends.

FIG. 6 shows a case of data recording accompanied by an erasing process. The erasing operation is performed by reversing the direction of the magnetic field. Since no external data transfer is required, erasing is performed for the entire target sector.

Extract the sector one sector before the sector to be erased,
Turn on the erasing magnetic field and simultaneously focus the laser power
Power.

After erasing all the target sectors, a track jump is performed to the write target sector. Then the laser power is Fo
Set to cus Power and turn off the magnetic field.

After the end of the jump, the magnetic field direction is changed to the write magnetic field, and the same processing as in FIGS. 4 and 5 is performed.

According to the present invention, the medium format configuration including the sector length and the number of tracks in consideration of the magnetic field control of the magneto-optical disk and the laser light control during the magnetic field operation have an effect of minimizing the deterioration to the recording data. .

Further, by minimizing the number of waiting rotations by magnetic field control, high-speed data writing becomes possible.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a magneto-optical disk control device according to an embodiment of the present invention, and FIG.
FIG. 3 is a block diagram showing the configuration of the ID part and data part of the sector, FIG. 3 is a plan view showing the configuration of the magneto-optical disk track and sector, and FIG.
FIG. 5 is a time chart of a Verify Write operation of less than 16 sectors, and FIG. 6 is a time chart of a Verify Write including an erase process. 1 ... Magneto-optical disk, 2 ... Laser pickup, 3
... magnetic field generator, 4 ... magnetic field control unit, 5 ... laser power control unit, 6 ... power switching unit, 7 ... head equalizer amplifier, 8 ... PLL circuit, 9 ... encoder, 10
... Decoders, 11, 12 ... Buffers, 13 ... Host computers, 14 ... Address extraction units, 15 ... I / O ports, 16 ... CPU, 17 ... RAM, 18 ... ROM.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Akira Muto 1006 Kadoma, Kadoma City Matsushita Electric Industrial Co., Ltd. (72) Inventor Fujio Ito 4-3-1 Tsunashima Higashi, Kohoku-ku, Yokohama Matsushita Communication Industrial Co., Ltd. Inside the company (72) Inventor Akinori Watanabe 3-9-1, Midoricho, Musashino-shi Nippon Telegraph and Telephone Corporation Electronic Technology Research Laboratory (56) References JP-A-61-184744 (JP, A) JP-A-61-260439 (JP, A) JP-A-57-162137 (JP, A)

Claims (2)

(57) [Claims] 1. A medium having a spiral groove, a laser pickup capable of changing at least three levels of writing, reading, and focusing on the medium, a direction of a magnetic field to the medium, an operation, A magnetic field generator capable of controlling the stop, the medium, a laser pickup, comprising a microprocessor for controlling the magnetic field generator, after at least data unrecorded check, by the magnetic field generator under the control of the microprocessor A control device for generating a predetermined magnetic field and writing data, and then turning off the predetermined magnetic field and reading out a recording confirmation, when a recording address is moved forward by one track or data writing (Write) is completed. Sometimes, control is performed to set the light amount of the laser pickup to a focus level of a minimum light amount level. Optical magnetic disk controller according to claim and. 2. The magneto-optical disk control device according to claim 1, wherein the control for setting the light amount of the laser pickup to a focus level is performed immediately before the data non-recording check is performed.