JP2576521B2 - Magneto-optical disk drive - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial application field) The present invention is mainly used as an external storage device such as a computer and comprises a mechanism for recording data by irradiating a magneto-optical disk as a recording medium with a laser beam. More specifically, the present invention relates to a magneto-optical disk device including a control circuit for controlling the output of the recording laser light.

(Prior Art) As is well known, a magneto-optical disk device is an information storage device that rewritably records various types of information (data) replaced by digital signals on a magneto-optical disk.
Recording and reproduction by the device are based on the following principle. That is, the magneto-optical disk is composed of Tb (terbium), Fe
A thin film made of a metallic magnetic material such as (iron) or Co (cobalt) is deposited on the surface of the disk with the magnetization direction aligned. When the temperature is increased by irradiating the laser beam, the magnetization direction of the irradiating local portion is reversed. By providing the irradiating local portion and the non-irradiating local portion of the laser beam, it becomes possible to record a digital signal as a 0-1 signal. When a laser beam is irradiated to the magneto-optical disk during reproduction, the rotation signal of the plane of polarization of the reflected light is different at the portion where the magnetization direction is reversed. The recorded data is read after being identified.

By the way, as the magnetic material on the surface of the magneto-optical disk, Tb-Fe, Tb-Co, Tb-Fe
-Various compositions such as Co are used, but the magnetic properties vary depending on the composition. Therefore, when recording or reproducing data on a magneto-optical disk, various conditions are used according to the composition of the magnetic material. Need to be set. In particular, when recording data, accurate recording cannot be performed unless the output (intensity) of the laser light is appropriate. Therefore, usually, the type of the magneto-optical disk to be used is specified in advance, and the magneto-optical disk is used. The optimal laser light output was set for the disc.

(Problems to be Solved by the Invention) As described above, in the conventional magneto-optical disk device, the type of usable magneto-optical disk is specified,
In many cases, data could not be accurately recorded on magneto-optical disks other than those specified (different types). Therefore, when an unspecified magneto-optical disk is used, it is necessary to readjust the output of the recording laser beam.

A further disadvantage is that when manufacturing a magneto-optical disk,
It is difficult to precisely control the composition of the magnetic thin film, and the composition is slightly different depending on the production lot. In other words, the magnetic thin film applies electrons and ions to the metal material (target),
This is formed by a so-called sputtering method of depositing the protruding metal atoms on the substrate. In this process, the composition changes sensitively depending on the pressure of the argon gas as the atmosphere and the target. Generally, film composition non-uniformity hardly occurs in the same magneto-optical disk, but for the above-mentioned reasons, a magneto-optical disk that is not the same in the production lot due to the use of a different target or a different production time may have different film compositions. There are often differences. As described above, in the conventional magneto-optical disk device, the output of the recording laser beam is preset, so that there are restrictions on the types of magneto-optical disks that can be used, and the composition and production lot of the metal magnetic film are limited. If the same magneto-optical disk is not used, accurate recording cannot be performed.

(Purpose) The present invention has been made in view of the above points, and even for a magneto-optical disk having a different film composition or a different production lot, an optimum laser beam output is automatically set for each disk, and an accurate laser light output is obtained. It is an object of the present invention to provide a magneto-optical disk device capable of performing recording and faithful reproduction.

(Means for Solving the Problems) The gist of the present invention for achieving the above-mentioned object is that each time a magneto-optical disk is replaced, a laser beam is set in a test area set in a part of the disk. A specific signal is recorded by irradiating by appropriately changing the output of the laser signal, and the recorded signal is compared with the digital demodulated signal at the time of their reproduction, and the laser light output with the minimum error rate is selected, or
Alternatively, there is provided an optical output control circuit for automatically setting an optimum output of the laser light by selecting an optical output that minimizes envelope fluctuation among reproduction signals of the recording signal.

(Operation) According to the magneto-optical disk device of the present invention, when data is recorded by exchanging the magneto-optical disk, a specific signal for testing is appropriately changed at a specific portion (test area) of the disk by changing the laser beam output. The optical output control circuit, which self-learns and selects the laser light output to obtain the optimum reproduction signal by recording and reproducing, and compares the recording signal with the digital demodulation signal at the time of their reproduction, to minimize the error rate The laser light output at the time of data recording is set by selecting the laser light output that is to be selected, or by selecting the light output that minimizes the envelope fluctuation among the reproduced signals of the recording signal, and setting the set light output. Since the data is recorded on the disk by using the optical disk, accurate recording can be performed even on different types of magneto-optical disks.

(Embodiment) Hereinafter, an embodiment of a magneto-optical disk drive according to the present invention will be described with reference to the drawings.

FIG. 1 is a flowchart showing a data recording process of the magneto-optical disk device according to the first embodiment of the present invention. As shown in the figure, in the apparatus of this embodiment, the laser beam output control in the apparatus is performed for the magneto-optical disk 1 which has been formatted (A) and mounted (B) on a magneto-optical disk apparatus (not shown). The circuit preliminarily self-learns (C) the optimum laser light output, and then records (D) data in response to a command from the controller. At the stage of the format setting (A), the data area 1a in which the user can freely write and delete data on the magneto-optical disk 1 used in the present apparatus and the characteristics of the disk are determined (optimization of the recording laser light). The test area 1b for determining the output is set as shown in FIG.

In the self-learning (C) process, as shown in FIG. 1, first, several types of tests are performed by appropriately changing the optical output on the test area 1b of the magneto-optical disk 1 mounted in the apparatus. A laser light signal is transmitted (a) and recorded (b). Then, each recorded signal is reproduced and digitally demodulated (c), and the retransmitted (d) test signal (recorded signal) and the digital demodulated signal are compared (e). As a result, the output of the test signal recorded most accurately is selected (f), and the output of the selected signal is set as the optimal laser light output (g). The data recording (D) is performed on the data area 1a in the disk 1 by the laser light output set in the self-learning (C) process.

Here, as an example of the test laser light signal, EFM modulated signals P ₁ , P ₂ , P _3, ... Of a specific pattern having slightly different outputs as shown in the left column of FIG. ₃ are used.
These modulated signals are sequentially transmitted (a) and recorded (b),
When reproduction and digital demodulation (c) are performed, an error occurs in the digital demodulated signal, for example, as shown in the right column of FIG. And
As the output of the laser light signal during the recording is inappropriate,
Since the frequency of this error (error rate) increases,
The error rate difference is measured by comparing the modulated signal (recording signal) with the demodulated signal (e), and the signal output (here, P ₂ ) that minimizes the error rate is selected (f).

By the way, when recording data on the magneto-optical disk 1,
The phenomenon in which the laser light output is inappropriate and accurate recording cannot be performed, and an error occurs during reproduction is explained as follows.

For example, in a magneto-optical disk in which the film composition of the magnetic material on the surface is Tb _x Fe _1-x , the relationship between coercive force and temperature is represented by a curve 11 shown in FIG. Then, in order to reverse the magnetization direction of a local portion of the disk 1, a magnetic field having a strength of, for example, _Hth is applied in a direction opposite to the magnetic field held by the magnetic film, and a focused laser beam having a predetermined output is applied. by irradiating, the temperature of the portion is raised to a temperature above room temperature T _r T _w. At this temperature _Tw , the strength H _th of the magnetic field exceeds the coercive force of the magnetic film, so that the magnetization direction of the local area irradiated with the laser light is reversed. In this way, data is recorded by providing the laser beam irradiating portion and the non-irradiating portion on the magneto-optical disk 1 based on the recording signal. However, the output of the irradiated laser light is weak, and the temperature of the irradiated part is _Tw
Otherwise, magnetization reversal does not occur, so that information different from data is recorded on the disk 1. The output of the laser beam on the contrary too strong, when the temperature of the irradiated portion is much greater than T _w, the magnetization reversal temperature of the surrounding well irradiation localized laser light even when the above T _w is As a result, a so-called bit is expanded, and information different from data is recorded. Therefore, if the recorded signal recorded in the former or the latter state is reproduced, an error naturally occurs. In addition, if the signal is digitally demodulated, a signal may be missing or an extra signal may enter.

On the other hand, another disk with a slightly different film composition TB _x
In the case of _1-x ', the coercive force characteristic is as shown by a curve 12 in FIG. 4, for example, which is different from that of the disk. In this case, by irradiating a laser beam having the same output and a disk having a film composition of the Tb _x Fe _1-x, raising the temperature of the irradiated local to T _w, expanded bit to ambient illumination local, You will not be able to keep accurate records.

FIG. 5 is a flowchart showing a data recording process of the magneto-optical disk device according to the second embodiment of the present invention. Parts common to those in the first embodiment are denoted by the same reference numerals as in FIG. In the second embodiment, when the optimum laser light output is selected by self-learning (C), a high-frequency signal having a slightly different output is transmitted as a test signal (n).
Then, this is recorded (o). When the recorded signal is reproduced (p), the fluctuation of the envelope (envelope) of the reproduced signal becomes larger as the laser light output becomes inappropriate, so that the envelope fluctuation is extracted by a peak hold circuit or the like (q), and the minimum fluctuation is obtained. Is selected (r), and this is set as the optimal laser light signal (s). That is, for example, a signal as shown in the left column of FIG.
When P ₁ ′, P ₂ ′, P ₃ ′... Are transmitted (n), and recorded (o) and reproduced (p), a reproduced signal as shown in the right column of FIG. The optical output of the signal P ₂ ′ with the smallest fluctuation is selected (r).

In the above two embodiments, the test signals P ₁ ,
P ₂ , P ₃ … or several kinds of signals P ₁ ′, P ₂ ′, P ₃ ′… are successively transmitted, recorded, reproduced and compared, and the optimum optical output is selected and set. However, the optimum optical output may be selected while transmitting, recording, reproducing, and comparing and examining each signal. Further, the self-learning (C) is performed immediately after the magneto-optical disk 1 is mounted in the apparatus (B), instead of immediately after the data recording command is issued, that is, immediately before the recording (D). You may do so.

(Effects of the Invention) Since the magneto-optical disk drive of the present invention has the above-described configuration, the following effects can be obtained.

(1) Since the recording laser light output is set to the optimum output for each individual magneto-optical disk and recording is performed, accurate recording is stably performed, and a good reproduction signal faithfully in accordance with the recording signal is obtained.

(2) Even when a magneto-optical disk having a different composition of a magnetic film or a different production lot is used, the output of the recording laser light is automatically set to the optimum output value, so that the operator does not need to perform any troublesome adjustment work. It is convenient.

(3) Due to the effect of the above (1), the apparatus of the present invention can record even on a magneto-optical disk having a different composition for each manufacturer with an optimum optical output, so that the types of magneto-optical disks that can be used And manufacturers are not restricted.

(4) Since the best performance can be obtained for each magneto-optical disk, the allowable range of the quality is widened, and the manufacturing cost of the magneto-optical disk can be reduced.

[Brief description of the drawings]

FIG. 1 is a flowchart showing a recording process of the magneto-optical disk device according to the first embodiment of the present invention, FIG. 2 is an explanatory diagram showing a format set on the magneto-optical disk, and FIG. FIG. 4 is a graph showing the relationship between the coercive force of the magnetic film of the magneto-optical disk and the temperature, and FIG. 5 is a diagram showing the recording process in the second embodiment. FIG. 6 is a waveform diagram illustrating a test recording signal used in the second embodiment and its reproduction signal. 1 ... magneto-optical disk, 1a ... data area, 1b ... test area, (C) ... self-learning process.

Claims (1)

(57) [Claims] Each time a magneto-optical disk is replaced, a test signal set in a part of the disk is irradiated with a laser beam output with an appropriate change, and a specific signal is recorded. By comparing the digital demodulated signal at the time of reproduction, and selecting a laser light output that minimizes the error rate, or by selecting an optical output that minimizes envelope fluctuation among the reproduction signals of the recording signal, A magneto-optical disk drive comprising an optical output control circuit for automatically setting an optimal output of light.