DE3410589A1 - OPTICAL INFORMATION PROCESSING DEVICE - Google Patents

Description

Optical information processing device

The invention relates to an optical information processing device, which is used to display various types of information by means of a light beam Recording material or on the recording material play back recorded information.

As optical information processing devices are Apparatus with optical disks, magneto-optical disks and the like are known. In the case of devices for magneto-optical Disks are recorded and played back using the following procedure:

The recording material used is a so-called magneto-optical disk with a disk-shaped substrate made of glass, plastic or the like and a depth magnetization film which is attached to the substrate and which usually has a thickness of a few μm. The deep magnetization l ^; The film is made of an amorphous alloy or the like and has the property that it is perpendicular to the film surface.

A / 25

Dresdner Bank (Munich) KIo. 3939 844

Postal check (Munchun) KIo. 6 / 0-43-801

-6- DB 377 8 is netized.

When recording information on such a magneto-optical Storage disk first the directions of magnetization in the deep magnetization film of the storage disk oriented in one direction, after which the film is digitally modulated by means of an information signal Laser beam point is applied to bring the temperature of the film to the Curie point or above. As a result, in the area where the laser beam point strikes, by the influence of the surrounding area Magnetization reversed the direction of magnetization and thus a logical value "1" (or "0") recorded, so that is, therefore, a recording bit is generated.

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To read the data on the magneto-optical disk recorded information is transferred to the deep magnetization film a reading beam spot is directed and the information is generated using the magneto-optical Kerr effect, in which the direction of polarization of the reflected rays changes due to the difference in the direction of magnetization of the film, or the Faraday effect read, in which the polarization direction of the transmitted rays changes.

During this reading of the information, on the other hand, tracking fire or tracking is indispensable. with which it is ensured that a light beam is tracked in an exact manner to an information track that has a result Contains contiguously recorded recording bits. So far, the so-called three-beam method described in US Pat. No. 3,876,842 etc. has often been used for this tracking used because it enables a very precise position detection. Especially when using a magneto-optical Disk as a recording material is the through

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the use of the magneto-optical effect such as the Kerr effect detected signal component very small, so that therefore with tracking is difficult with the so-called far field method applied to an optical disk or the like and the three-beam method is effective. An example for the construction of a conventional optical information processing device, in which this three-beam method is used is shown in Fig. 1 of the drawing.

According to FIG. 1, in a writing system shown on the right half of the figure, a semiconductor laser which can be modulated by a semiconductor laser 1 emitted laser beam by means of a collimator lens 2 aligned parallel and into a Polarization beam splitter 3 initiated. The polarisa-. tion beam splitter 3 is formed so that it is parallel • or P-polarized light passes, and perpendicular or S-polarized light reflects. The direction of polarization of the semiconductor laser 1 is chosen so that it is in relation is horizontal on the plane of the drawing, so that consequently the beam through the polarization beam splitter 3 is transmitted, enters a quarter-wave plate or ρκ / 4 plate, to circularly polarized Light becomes and is deflected by 90 by a deflecting mirror S. The beam then enters an objective 6, after which it is deposited on the surface of a disc-shaped recording material (hereinafter referred to as a disc) 21 and the direction of magnetization of the depth magnetization film on the surface of the plate 21 reverses. The rays reflected by the plate 21 run over the objective 6 and the deflecting mirror 5 formed into S-polarized light by the λ / 4 plate reflected by the beam splitter 3 and fall on a detector 8. The light falling on the detector 8 · becomes converted in a photo-electric way and used as a servo signal SF (for automatic focusing),

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that the focus point of the lens is always on the plate lies. The plate 21 is on a shaft 22 by means of a drive motor 23 with a predetermined Speed set in circulation. On the left half of Fig. 1, a reading system is shown in which the three-beam method is applied. A laser beam emitted from a semiconductor laser 9 is generated by means of a collimator lens 10 aligned parallel, improved with regard to its degree of polarization by means of a polarizing plate 11 and divided into three beams by a grating 12. These bundles of rays pass through a half mirror 13 and are reflected by a tracking mirror 14 and through an objective 15 as three beam points the surface of the plate 21 is shown. These rays of light which have fallen on the plate 21, whereby by the. Kerr effect their polarization directions were rotated, are via the lens 15 on the tracking mirror 14 and the half mirror 13 is reflected, divided into two bundles of rays by a half mirror 16, via polarizing plates 17 and 18 and_in a photoelectric manner by means of Detectors 19a, 19b, 19c and 20 are detected. The polarization azimuth angles the polarizing plates 17 and 18 are offset from each other by a predetermined angle in advance. The light reflected from the center point hits the detectors 19b and 20 and is used as an information signal SR removed. Further, according to a conventional method, a signal, not shown, is also used for focusing recorded. The light rays reflected from points on opposite sides become photoelectric detected by means of the detectors 19a and 19c, subjected to a subtraction and taken out as a tracking signal ST.

In the optical information processing device shown in FIG can because of the use of the three-beam method, the reading system and the writing system

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cannot be summarized, which led to the disadvantage has that the device has become bulky.

In JP-OS No. 17546/1983 a device is proposed in which two light sources with different wavelengths are used and in which the reading system and the Writing system are summarized or common. Even with this device, however, only parts of the optical paths are Recording beams and playback beams, incl.

a lens and so on in common, so that this device is not significantly different from the device of FIG differs as a recording beam from the one light source and three reproduction beams can be obtained from the other light source. As a result, are in this device the optical system and the detection system complicated structure, so that it was not possible to make the device sufficiently compact.

As one of the apparatus of Fig. 1 and the apparatus of JP-OS No. 17546/1983 common problem is to be mentioned, that because of the division of the light rays from a light source into three bundles of rays using one Grating, the output power of the light source must be chosen to be large so that each of the partial beams is sufficient Has intensity, and that in this way the light source is heavily loaded. In contrast, in of JP-OS No. 94842/1976 proposed a semiconductor laser arrangement as a light source, which has three or more luminous areas which are formed on a substrate.

In this case, however, the positional relationship between the Beam points on the plate determined by the points at which the respective luminous areas of the semiconductor laser arrangement are trained; this has led to the disadvantage that, due to the inaccuracies in the manufacture, it is 1-ment semiconductor laser arrangements is difficult to always reproduce with different devices under predetermined

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-10- DE 3778 th conditions to bring about.

The invention is based on the object of providing an optical information processing device in which highly accurate tracking can be accomplished using a low output light source and differences in performance between facilities are small.

The invention is also intended to provide an optical information processing device be created in which an extremely precise tracking is possible and the enables recording and reproduction by means of a compact structure.

The object is achieved according to the invention with an optical information processing device solved, in which a first beam of a first radiation is directed onto an information track on a recording material in order to obtain information to reproduce, and at least two second beams of a second radiation directed at points which are different from one another with respect to the width of the information track onto which the first beam of rays hits is directed, and in which the rays from the recording material are detected from the second bundle of rays to thereby obtain a tracking signal for accurately directing the first beam onto the information track, the first beam and the second bundles of rays have different wavelengths and these bundles of rays emitted by separate light sources are combined via a common optical path and directed onto the recording material.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the drawing. 35

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Fig. 1 is a schematic view showing an example of the construction of an optical information processing device shows according to the prior art.

Fig. 2 is a schematic view showing an embodiment of the optical information of the present invention processing se points towards.

Fig. 3 is a graph showing the spectral transmission and reflection characteristics of a ray. divider of the device shown in Fig. 2 shows.

FIG. 4 shows the arrangement of beam spots on a recording material similar to that shown in FIG Establishment to be formed.

Fig. 2 is a schematic view showing an example of the construction of an optical device according to the present invention Information recording and reproduction shows.

Fig. 2 shows a semiconductor laser 31 with a wavelength ^ ₁ , a semiconductor laser 32 with a wavelength ^ -:, collimator lenses 33 and 34 for parallel alignment of the light beams from the semiconductor lasers 31 and 32, respectively, an optical wedge 35 for splitting the light from the Semiconductor laser 31 in two parallel beams of different inclination angles and a beam _{splitter 36 which transmits light of wavelength λ 1} and reflects light of wavelength '\ 2 and whose characteristics are shown in FIG.

3 are shown. In Fig. 3, the spectral transmission factor is shown with the solid line, during the spectral reflection factor shown with the dashed line is. 39 with a magneto-optical disk is referred to, which via a shaft 40 by means of a drive motor 41 can be put into circulation. Three bundles of rays combined by the beam splitter 36

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enter a polarization beam splitter 37, which has a transmission factor of 952 for P-polarized light and a reflection factor of 98 for S-polarized light! Has; the beams are almost completely transmitted through the polarization beam splitter 37, since the light emerging from the beam splitter 36 is P-polarized light; the bundles of rays are imaged as points on the magneto-optical disk 39 by means of an objective 38. The points shown on the magneto-optical disk 39 are shown in FIG. 4 shown. In FIG. 4, ¹ 45 denotes a recording bit, while 46a and 46c denote the points from the light beams with the wavelength ν., And 46b denotes the point from the light beams with the wavelength Λ ₂ . Due to the direction of magnetization, the direction of polarization of the light reflected from the magneto-optical disk 39 is rotated by + _ 0k; the reflected light passes through the objective 38 and is reflected by the polarization beam splitter 37, whereby its Kerr twist angle is apparently increased. This light passes through a converging lens 42 and a polarizing plate 43 and is incident on detectors 44a, 44b and 44c. As a result, the light from the light beam spot 46a of FIG Detector 44c detected. By forming the difference between the signals from the detectors 44a and 44c, a tracking signal ST is obtained, with which the tracking is brought about. The light from the disk surface at the light beam spot 46b is detected by the detector 44b, and focusing control, not shown, is effected in a conventional manner. During writing, the beam forming the point 46b becomes a writing beam by the power of the semiconductor laser

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32 is amplified, whereas it becomes a reading beam during reading by the fact that the power of the semiconductor laser 32 is reduced. As a result, a read signal SR is also obtained from the detector 44b. .

In the embodiment described above, the light from the semiconductor laser 31 is split into two beams by the optical wedge 35. The optical one Wedge 35 is designed so that its two reflective surfaces are arranged at a predetermined angle, and can be made by a glass material to a wedge shape is processed. Compared to other beam splitter devices such as gratings, the optical Wedge 35 various advantages. For example, by arranging the optical wedge shown in FIG. 35 in such a way that the chief ray of each of the two split bundles of rays goes to the center of the pupil of the Objective 38 runs, with a simple structure of the objective diameter can be used effectively.

In the embodiment described, the semiconductor laser 31 can be switched off during writing, if no tracking is required. If a guide track such as a Groove is formed, it is also possible to write or record information with tracking. Farther In the magneto-optical disk, it is possible to erase recorded information by doing during applying a magnetic field in one direction, directing a beam of light onto the disk; with the one described Embodiment is it by switching the output. power of the semiconductor laser 32 on the output power For erasing, it is possible to erase the recording bits in a precise manner with tracking.

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The embodiment described above is designed so that the beams from two light sources for different Wavelengths are used while they are with each other be combined; the output of one of the light sources is changed so that during writing a recording beam and during reading Reproducing beam is formed; the rays from the other light source are split into two bundles of rays, with which the tracking is carried out.

By using this structure, the writing system and the reading system can be made compact; because the can be split into two bundles of rays from one of the light sources, the output power for the tracking beams can be increased without unduly stressing the light sources. When a . magneto-optical recording material is used, is to improve the signal-to-noise ratio or signal-to-noise ratio, a high output power for the tracking beams desirable because of the magneto-optical effect Signal component is very small. As a result, the design according to the invention is special in this case effective. The invention is for the same reason Design also suitable for the use of an erasable recording material in which a phase change a substance is used.

In the embodiment described above, an example has been shown in which the recording on the Recording material and reproducing from the recording material be made by means of a common optical system; however, the inventive design is also with regard to the weakening of the requirements also useful for the high output power of the light source when the device is used in a device where information is only recorded or can only be played back. In addition, is in comparison

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in the event that a semiconductor laser as the light source. Arrangement is used, the adjustment of the beam arrangement easy, so that power deviations between Facilities can be reduced to a minimum.

The invention allows various modifications without departing from the basic concept of the invention. For example the recording material is not limited to the magneto-optical disk; much more Any recording material can be used which can transmit information by applying a light beam can be recorded and reproduced, such as a recording material having bumps a recording layer or changes in the. Reflection factor can be used. The recording material is not limited to the shape of the round plate in terms of shape, but can also be the shape of a card, a belt, drum or the like. Forner The recording material can be made translucent and the design can be made so that the through rays passing through the material are detected. It is also possible to make the design so that the rays coming from the recording material be divided into two bundles of rays by means of a half mirror or the like, the respective bundles of rays are recorded with detectors and the playback signal, the tracking signal and so on detected with superposition will.

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An optical information processing device is specified in which a first beam of rays is directed onto an information track is directed to a recording material to reproduce information, and at least two second bundles of rays are directed at points which are separated from each other in the direction of the width of the information

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track on which the first bundle of rays is directed, and in the case of which through the second bundle of rays caused rays are detected by the recording material to generate a tracking signal for precise alignment of the first bundle of rays to reverberate on the information track, the first bundle of rays and the second bundle of rays different from each other wavelengths and these bundles of rays emitted by separate radiation sources, via a common optical Combined way with each other and directed to the recording material.

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Claims (13)

Claims (\ j Optical information processing device in which a first bundle of rays is directed onto an information track on a recording material in order to reproduce information, and at least two second bundles of rays are directed onto locations which are different from one another in the direction of the width of the information track to which the first beam was directed, whereby from the second beam coming from the recording material beams are detected in order to thereby obtain a tracking signal for the precise guidance of the first beam onto the information track, characterized in that the first beam and the second beam have different wavelengths (λ- or Tu) and the bundles of rays emitted by separate radiation sources (32 and 31) are combined via a common optical path (37, 38) and directed onto the recording material (39). 2. InformationsverarbeItungseinrichtung according to claim I, characterized in that the information track (4S) is on the recording material (39) is recorded by that the first beam is modulated in accordance with the information and directed onto the recording material. A / 25 Dresdner Bank (Munich) KIo. 3939 844 Bayer. Verclnsbank (Munich) KIn 5OB 941 PoslschC'Ck (Munich) KlO left / O 43-} 104 -Z- DE 37 7 8 3. Information processing device according to claim 2, characterized in that in the information recording no second bundle of rays by means of the first bundle of rays be directed at the recording material (39). 4. Information processing device according to one of the Claims 1 to 3, characterized in that the second beam using a radiation source (31) and an optical wedge element (35) are generated, which the beam emitted by the radiation source splits into two bundles of rays and has two reflective surfaces, between which a predetermined angle is formed is. . 5. information processing device according to claim 4, characterized in that the first beam and the second beam via an objective (38) on the Recording material (39) are directed and the optisehe Keilelemont (35) is arranged so that the. Principal rays of the reflected on the respective reflective surfaces second sirahlen bundle to the center of the pupil of the objective run forward. 6. Information processing device according to one of claims 1 to 5, characterized in that the first beam, and the second bundles of rays are combined by means of a beam splitter (36), the transmission factor of which and reflection factor as a function of the wavelength are different. 7. Information processing device according to one of claims 1 to 6, characterized in that the recording material (39) is an erasable recording material. 35 -3- DE 3778 8. Information processing device according to claim 7, characterized in that the on the recording material (39) recorded information can be erased by applying the first beam to it. . 9. Informationsververarbeitungeinrichturig according to claim or 8, characterized in that the recording material (39) is a magneto-optical recording material. 10. Optical information processing device, characterized by a first radiation source (32) for delivery an information correspondingly modulated first beam, a second radiation source (31) for output a second beam which is different in terms of wavelength from the first beam, a splitter device (35) for splitting the second beam into two second beams, an optical system (37, 38), which combines the first bundle of rays with the split second bundles of rays and the bundles of rays via a common optical path to a recording material (39), the optical system directing the first beam onto one in the recording material im Aligns the pre-formed guide track and directs the two split second bundles of rays to locations that are different from each other with respect to the width direction of the guide track on which the first beam is directed is directed, and a detection device (44a, 44c), which receives the rays caused by the second bundle of rays from the recording material and a ' Emits tracking signal (S-) for the precise alignment of the first beam on the guide track. 11. Information processing device according to claim 10, characterized in that the splitter device (35) has an optical wedge element with two reflective surfaces, between which a predetermined angle is formed. -4- DE 3778 12. Information processing device according to claim 11, characterized in that the first beam and the second beam via an objective (38) the recording material (39) are directed and the 5 optical wedge element (35) is arranged so that the main rays that of the respective reflection surfaces of the same reflected second bundle of rays towards the center of the pupil of the lens. 13. Information processing device according to one of claims 10 to 12, characterized in that the first The bundle of rays and the second bundle of rays are combined by means of a beam splitter (36) whose transmission factor and reflection factor depending on the length are different. . . .