DE3802693C2 - - Google Patents

Description

The invention relates to a magneto-optical Drawing device according to the preambles of the claims 1 and 5. Such recording devices are known from JP-A-51 1 07 121 and from DE 36 14 411 A1.

It’s in magneto-optical recording devices, where overwriting is possible, a method is known where two points of light are used, as in JP-A-60-35 303. It is also a procedure mentioned, where that on the recording film, i.e. the recording layer, depending on the applied magnetic field is modulated by information to be recorded, as described in JP-A-51-1 07 121, JP-A-59-2 15 008, etc. is.

However, no special attention is paid to any of these methods focused on always the optimal recording erection / erasure requirements, even if the disk changes or fluctuates constantly (e.g. increases and falls) or the position of the recorded information between the inner and outer periphery of the plate changes. There has therefore been the problem of fluctuations in the size or amount of recorded signals or incomplete deletion has occurred.  

DE 36 14 411 A1 describes a device for recording and playing back optical information which is the light intensity in response to a position signal, which is the relative position of the recording medium and indicating the optical head is changed.

Another correction quantity is made according to this device not considered.

The invention has for its object a magneto-optical Create recording device when overwriting is possible and by means of which always the optimal Record / erase conditions regardless of fluctuations of the plate or whether it can be fulfilled the position of the recorded information on the inner Periphery or on the outer periphery of the plate located.

This object is according to the invention in a magnetoopti rule recording device with the features of the An spells 1 and 5 solved. Advantageous further developments the magneto-optical recording according to the invention direction are the subject of the subclaims.

By means of the magneto-optical recording according to the invention equipment, it is possible to record or always carry out deletion under the optimal conditions, while the influences of changes in strength of the applied magnetic field by changing the intensity of the light point can be compensated, even if the Strength of the magnet applied to the recording medium field changes depending on the fluctuations of the opening medium or the position of the light spot the recording medium.

The invention is further preferred in the following based on Execution examples and the drawing described. In the Show drawing:

Fig. 1 is a block diagram light illustrates the structure of a first embodiment of the invention,

FIGS. 2a to 2d waveforms for explaining the first embodiment,

Fig. 3 is a block diagram showing the configuration of a second embodiment of the invention illustrated,

FIGS. 4a to 4d are diagrams for explaining the second embodiment and guide From

Fig. 5 is a block diagram illustrating the construction of a variant of the second embodiment of the invention.

Fig. 1 is a schematic diagram showing the basic structure of a magneto-optical device, which is an embodiment of the invention. A magneto-optical disk 1 contains a magneto-optical recording medium 101 in which the magneto-optical effect is obtained. From a semiconductor laser device 2 emitted light is formed by a collimator lens 3 in a parallel beam and fed through a beam splitter 4 to a focusing lens 5 so that it forms a small dot on the magneto-optical recording medium 101 of the disc 1 . The focusing lens 5 is mounted on a voice coil, which is a device for regulating the focal point so that it can follow vertical deviations of the plate 1 . Light reflected from the plate 1 is supplied by means of a beam splitter 7 to a focusing error detecting optical arrangement 9 and an analyzer 8 after it has passed through the focusing lens 5 and has been divided by the beam splitter 4 . The analyzer 8 has the property that it only transmits light with a specified polarization plane. Accordingly, the angle of rotation of the plane of polarization is converted according to the direction of magnetization on the plate 1 by the analyzer 8 into changes in the amount of light. The light thus obtained is then collected by a lens 10 in a photodetector 11 and converted into an electrical signal.

For recording information, the magneto-optical recording medium 101 on the disc 1 is heated above the Curie temperature by causing the semiconductor laser device 2 to emit light at a high power so that the magneto-optical recording medium 101 loses the magnetization. At this time, a magnetic head 13 serving as a magnetic field applying means applies a magnetic field which is modulated according to information to be recorded on the magneto-optical recording film 101 by means of a driver circuit 15 to record the information. With this method, since the magnetization is lost once during the recording and therefore old recorded information does not remain even if the recording is carried out again in an area where information has already been recorded, it is possible to erase old information by overwriting it, ie by superimposing new information on the old one.

The magnetic head 13 is formed in a housing with an optical head 12 . Due to this fact, the distance between them can be kept constant and at the same time it is controlled so that it is always completely above the light point on the plate. It is not always necessary to form the two heads in one housing, but in this case a device for keeping the distance between the heads constant and a device for adjusting the magnetic head are required in order to locate it completely above the point of light.

The relative position of the plate 1 and the focusing lens 5 is detected by a focusing error detecting optical arrangement 9 . Various known arrangements can be used for this (see, for example, US patent application, application no. 8 28 354). The output signal is input to an actuator driver circuit 14 , and the relative position of the plate and the focusing lens is kept constant by driving a focusing lens actuator 6 . Since the relative position of the focusing lens with respect to the optical head can be known by using the actuator drive signal, by using this signal it is possible to know the relative position of the disk with respect to the optical head. For the reason described above, considering the fact that the distance between the optical head 12 and the magnetic head 13 is constant, it is possible, by using the actuator drive signal, to use the distance between the magneto-optical recording medium 101 on the disk and the magnetic head 13 to know.

When the distance between the magneto-optical recording medium and the magnetic head changes, the strength of the magnetic field applied to the recording medium changes. If the intensity of the light spot focused on the recording medium is kept constant, fluctuations in the amplitude of the signal to be recorded are generated during this time. Therefore, the actuator drive signal is input to a semiconductor laser drive circuit 16 so that the laser drive current is changed depending on the distance between the recording medium and the magnetic head and the intensity of the focused light spot is changed so that the conditions for optimum recording / Delete are met.

In Fig. 2 changes in the strength of the magnetic field and changes in the focused light spot are illustrated light. Fig. 2a shows changes in the strength of the magnetic field generated by the magnetic head, and in Fig. 2b changes in the effective magnetic field applied to the recording medium due to vertical back and forth movements of the disk are shown. When the distance between the magnetic head and the recording medium is small, they are large, and when the distance is large, they are small. At this time, the actuator drive signal changes as shown in Fig. 2c. For example, in the case where the optimal recording / erasing conditions are met by decreasing the intensity of the light spot when the applied magnetic field is strong, and increasing the intensity of the light spot when the applied magnetic field is weak, that becomes shown in Fig. 2c actuator signal entered into the laser driver circuit 16 so that the intensity of the light spot changes, as shown in Fig. 2d. In this way it is possible to always meet the optimal recording / erasing conditions.

The second exemplary embodiment of the invention will now be explained with reference to FIG. 3. The feature of this embodiment is that the intensity of the focused light spot is changed depending on the position of the light spot focused on the plate in the radial direction. In this embodiment, the position of the light spot is detected using an ex ternal scale. The external scale consists of a light source 18 , a photodetector 19 and a moir 'scale 17 arranged between them, and either the light source or the photodetector 19 is moved or the moir' scale 17 , connected to the optical head 12 . The light source 18 and the photo detector 19 are moved together with the movement of the optical head 12 and the Moir 'scale 17 is fixed. The techniques for detecting the position of the light point using the external scale are known (cf., for example, US Pat. No. 4,650,332). Since the amount of light captured by the photodetector 19 changes depending on the movement of the optical head 12 , the position of the optical head 12 in the radial direction can be detected by pulsing the output signal from the photodetector 19 and the number of pulses by means of a counting circuit 20 is counted. In this way it is possible to know the position of the light point at this time. The output signal of the counter circuit 20 is input via a D / A converter 21 into the laser driver circuit 16 and changes the intensity of the emission of the semiconductor laser device so that optimal recording / erasing conditions can be met, depending on the position of the light spot in the radial Direction on the plate. In FIG. 4b, an example of the semiconductor laser drive current is shown. This shows what can be observed in the case where a recording is continued from the inner periphery to the outer, that is, in the case where it is required that the intensity of the light spot at the inner periphery is small and with decreasing distance to the outer periphery increases. In Fig. 4a the strength of the magnetic field generated by the magnetic head is shown, in Fig. 4b the semiconductor laser driver current and in Fig. 4c the intensity of the light spot.

Although the case explained above that the intensity of the light spot is continued or changed continuously, it may be possible that the plate is divided into different areas in the radial direction of the plate and the intensity of the light point is changed step by step, such as is shown in Fig. 4d. It is also possible to further adjust the intensity of the light spot so that it is high on the inner periphery and low on the outer periphery.

In Fig. 5 a variant of the second game Ausführungsbei the invention is shown. Here is the case where the position of the light spot is detected using light reflected from the plate. This embodiment is useful in the case where a recording medium is used in which the track address, for example the track address by means of pits, has been recorded in advance for each track. The position of the light spot is detected by inputting the output signal of the photodetector 11 into a signal processing circuit 22 and reading out the track address recorded on the disk. The track address signal detected by the signal processing circuit 22 is input to the laser driver circuit 16 through the D / A converter 21 and changes the intensity of the light output signal of the semiconductor laser 2 so that the optimum recording / erasing conditions are satisfied depending on the position of the light spot in the radial direction of the plate. Since the shape of the semiconductor laser driver is the same as that described for the second embodiment, an explanation in this regard is omitted. Although no optical arrangement for detecting defocusing is shown in FIGS . 3 and 5, this is of course necessary.

Although the first and second embodiments have been explained separately above, they can of course be carried out simultaneously. As shown by the broken lines in Fig. 1, for example, a signal processing circuit 22 and a D / A converter are provided, and the semiconductor laser drive current is controlled by both the actuator drive signal and the light point position signal. Of course, an ex ternal scale as shown in Fig. 3 can be provided to detect the position of the light spot.

Since recording / deleting is always under optimal conditions can be performed even if there are fluctuations the plate occur or the position of the light spot tes changes, it is according to the above by the invention possible fluctuations in the quantity or size of recorded Suppress signals and at the same time incomplete To prevent deletion.

The invention can be summarized as follows: magneto-optical recording device has an opti head to project a beam of light onto a mag netooptical recording medium to on this one Light point to form a magnetic head in a front certain distance from the optical head is arranged and corresponding to that on the magneto-optical record Information medium to be recorded is a modulated Magnetic field, and a light intensity controlling Set up to adjust the intensity of the light spot speaking on a focusing error signal that deviations of the light spot from the magneto-optical recording medium indicates, and / or a position signal indicating the relative Position of the magneto-optical recording medium and the optical head indicates, even if the In intensity of the mag applied to the recording medium netfeldes changes depending on vertical back and forth movements or vibrations of the recording medium or the position of the point of light, influences of changes in compensated for the strength of the applied magnetic field that the intensity of the light point is changed, so that fluctuations in the size of recorded signals and suppress incomplete deletion.

Claims (10)

1. Magneto-optical recording device with

• - A focusing lens ( 3 ) for focusing a light beam such that a light spot is formed on a magneto-optical recording medium ( 101 ),
• - A focusing error detecting optical arrangement ( 9 ) for detecting the relative position of the recording medium and the focusing lens,
• - an optical head ( 12 ) having a focus regulating means for maintaining the distance between the magneto-optical recording medium and the focusing lens in response to a focusing error signal detected by the optical error detecting optical arrangement, and
• a device ( 15 ) applying a magnetic field for applying a modulated magnetic field to the magneto-optical recording medium in accordance with information to be recorded,

marked by

• - A means ( 16 ) for changing the intensity of the light spot focused on the recording medium in response to the focusing error signal.

2. Magneto-optical recording device according to claim 1, characterized by a device ( 17 ) for detecting the position of the light spot focused on the recording medium and a device for changing the intensity of the light spot depending on the position of the light spot. 3. Magneto-optical recording device according to claim 2, characterized in that the device for detecting the position of the light spot from an external scale ( 17 ) which outputs a pulse each time the optical head ( 12 ) moves over a predetermined distance , and consists of a device ( 19 ) for counting the pulses thus output. 4. Magneto-optical recording device according to An saying 2 or 3, characterized in that the device for detecting the position of the light spot is a device for reading out the address of the track at which is the point of light.   5. Magneto-optical recording device with

• - An optical head ( 12 ) for projecting a light beam onto a magneto-optical recording medium ( 101 ) to form a light spot on this, and
• - A magnetic head ( 13 ), which was arranged in a predetermined position from the optical head and applies a modulated magnetic field to the magneto-optical recording medium in accordance with information to be recorded, and
• light intensity control means ( 16 ) for changing the intensity of the light spot in response to a position signal indicative of the relative position of the magneto-optical recording medium and the optical head,

characterized in that the device ( 16 ) controlling the light intensity additionally responds to a focusing error signal which indicates deviations of the light spot from the magneto-optical recording medium. 6. Magneto-optical recording device according to claim 5, characterized in that the the light quality control device a laser driver circuit for controlling electricity, the one is the light beam emitting laser light source drives. 7. Magneto-optical recording device according to claim 5 or 6, characterized in that the optical head ( 12 ) an external scale ( 17 ) which outputs a pulse each time the optical head moves over a predetermined distance, and a device ( 20 ) for counting the pulses thus output, the output signal of the device for counting pulses being used as the position signal. 8. Magneto-optical recording device according to An saying 6 or 7, characterized in that the address of the track where the light spot is located is used as a position signal.