NL9301499A - Optical disc and device for playing it. - Google Patents

Description

Title: Optical disc and device for playing it

Background of the invention

Scope of the invention

The invention relates to an optical disc, and in particular to an optical disc that can be played back easily, even if the information having a high density is recorded thereon, and an apparatus for playing the optical disc.

Description of the Related Art

According to the conventional optical plates, known as a CD (Compact Disk) and LD (Laser Disk), information of this type of optical disk is reproduced, corresponding to the presence or absence of pits, by using a photosensor to decrease the amount of reflected light. detecting caused by diffraction, scattering or a change in the optical constant of a portion of a well when the light beam or a reading laser beam is irradiated on the wells. In particular, if the reading laser beam is irradiated on a well as shown in Figure 1A, the amount of reflected light is small due to scattering or the like. If the reading laser beam is irradiated on a portion between wells, as shown in Figure 1B, the amount of reflected light is large. Using such phenomena, information is read from the optical disc.

If the pitch of the track is narrowed to increase the recording capacity by high density, in the above conventional reading method, the beam LB of the laser beam to read a well P on the target track is larger than the pitch of the track, so that pits on two adjacent tracks are also read as shown in figure 2. As the pitch of the track is narrowed, the amount of a leak signal part (crosstalk) of the pits increases correspondingly, making accurate reproduction of information impossible and thus making recording with a high density difficult.

To overcome the above shortcomings, it is common for a V-shaped groove to be provided in an optical disc and signal pits to be formed in the groove, thereby preventing the reflected light from the adjacent tracks from interfering with each other, or signals still containing cross-talk components are read simultaneously from three contiguous tracks with three beams and then the read signals are processed in an adaptive digital filter to obtain the desired signals. The method is proposed, for example, in Japanese Patent Application No. 10012/1989.

However, a conventional method involves new problems which complicate the optical disk manufacturing procedures, making it difficult to obtain the optimum filter coefficient and complicating the circuit arrangement.

Summary of the invention

It is therefore an object of the invention to provide an optical disc which ensures the reproduction of recorded information of a desired track, even if the information is recorded on a high-density optical disc, without crosstalk or the like of the adjacent tracks to be affected, with a simple structure, and a device for playing the optical disc.

To achieve this object, according to an aspect of the invention, there is provided an optical disc having a plurality of adjacent recording tracks, said optical disc comprising a first deflection layer formed on that portion containing the odd-numbered tracks of the plurality of recording tracks, for polarization of incident reading light for emitting the first polarized light having a first polarization plane; and a second deflection layer formed on that portion containing the even-numbered tracks of the plurality of recording tracks, for polarizing incident reading light to emit the second polarized light having a second polarization plane, different from the first polarization plane.

According to the optical disc according to the invention, reading light irradiated as linear polarized light on the first deflection layer becomes the first polarized light with a first polarization plane, and reading light irradiated on the second deflection layer becomes the second polarized light with a second polarization plane, different from the first polarization plane. Therefore, even if signals are read from the recording tracks at the same time, the signals from the recording tracks can easily be separated later in a process due to the differences in the polarization plane.

In accordance with another aspect of the invention, there is provided an optical disc playback device for playing an optical disc having a plurality of contiguous recording tracks, a first deflection layer formed so that portion containing the odd-numbered tracks of the large number of recording tracks, for polarization incident reading light for emitting the first polarized light having a first polarization plane, and a second deflection layer formed on that portion containing the even-numbered traces of the plurality of recording tracks, to polarize incident reading light for emitting the second polarized light a second polarization plane, different from the first polarization plane, which device comprises a light source for generating reading light to the recording tracks of the optical disc; light splitting means for separating the first polarized light and the second polarized light from the optical disc from each other; first light receiving means for receiving and emitting the first polarized light as a first signal; second light receiving means for receiving and emitting the second polarized light as a second signal; reproducing means for reproducing recorded information from the optical disc based on the first signal or the second signal.

According to the optical disc playback device according to the invention, the light source transmits reading light to the optical disc, which produces the first and second polarized light. The first and second polarized light are separated from each other by the light splitting means. The first light receiving means receives the first polarized light and transmits it as a first signal to the reproduction means, while the second light receiving means receives the second polarized light and transmits it as a second signal to the reproduction means. It follows that the reproducing means performs reproducing the recorded information based on the first and second signal. The reproducing means can therefore perform the reproduction without being affected by the tracks adjacent to the target track.

Brief description of the drawings

Fig. 1 (a) and 1 (b) are schematic diagrams to explain the usual principle for reading information from;

Fig. 2 is a schematic diagram to explain the problems of the conventional information reading means;

Fig. 3 is a sectional view showing the basic structure of an optical disk according to the invention;

Fig. 4 is a sectional view showing a detailed structure of the optical disk of FIG. 3;

Fig. 5 is a view showing a detailed structure of the reflection type optical disk indoor section;

Fig. 6 is an explanatory diagram for the magnetization of the optical disk of FIG. 3;

Fig. 7 is a schematic representation showing the structure of the essential part of an optical disc playback device according to the invention;

Figs. 8 and 9 are explanatory diagrams for the reproducing process of the device of FIG. 7;

Fig. 10 is a schematic representation showing the structure of the essential part of an optical disc playback device according to another embodiment of the invention;

Detailed description of the preferred embodiments

Preferred embodiments of the invention are now described in detail with reference to the accompanying drawings.

Figure 3 shows an optical disk 1 according to the invention. The optical disk 1 has a substrate 2 in which wells are formed, a deflection layer 3 for rotating the polarization plane of the reading light which is incident light with linear polarization, and a protective layer 4 to protect the deflection layer 3.

The deflection layer 3 consists of a ZnS layer 3A (80 nm) being a dielectric layer, a TbFeCo layer 3B (90 nm) being a photomagnetic layer and a ZnS layer 3C (50 nm) being a dielectric layer applied in the listed order of the substrate layer side to the protective layer side, as shown in figure 4. The values in brackets give examples of the thicknesses of the individual layers. The rotation of the polarization plane in this case is mainly caused by the Kerr effect.

The optical disk 1 shown in Figures 3 and 4 need not have a reflection layer since the TbFeCo layer 3B being a photomagnetic layer has a high reflection. If the photomagnetic layer has too low a reflection to use the optical disk as a reflection type, a reflection layer 4A as shown in figure 5. The rotation of the polarization plane in this case is mainly caused by the Faraday effect.

In more detail, the deflection layer 3 comprises a ZnS layer3D being a dielectric layer, a (BiDy) 3 (FeGa) 5Ο12 layer 3E being a photomagnetic layer based on grit stone and a ZnS layer 3F being a dielectric layer applied in the listed order from the substrate layer side to the protection layer side. Furthermore, an Al layer 4A is provided with a protective layer and a reflection layer. If the Al layer 4A is not used, but instead the same protection layer as shown in Figure 3 is applied, the optical disk can be used as a transmission type disk.

Fig. 6 shows how an optical disc is magnetized. To keep the explanation simple, a description is only given for the four adjacent tracks Ritot R4.

The individual tracks Ri to R4 belong to the respective areas Αχ to A4. Areas Αχ and A3 are previously magnetized, in the schematic downward, by an EMG electric magnet, while areas A2 and A4 are previously magnetized, in the schematic upward.

Accordingly, the rotation direction of the polarization plane of the reading light incident on the areas Αχ and A3 becomes opposite to that of the polarization plane of the reading light incident on the areas A2 and A4.

Figure 7 shows the structure of the essential part of an optical disc playback device according to the invention.

An optical disc playback device 20 includes a laser diode 21 to emit a laser beam as a reading light, a beam splitter 22 to transmit the laser beam from the laser diode 21, and to reflect a laser beam from a mirror described below, a mirror 23 to form a laser beam, an objective lens 24 to focus the laser beam on the surface with the stored information of the optical disk, a first deflection plate 25, passing only a predetermined first polarized light from the laser beam reflected by the beam splitter 22 and reflecting the other light, a first light receiving means 26 for receiving first polarized light passed through the first deflection plate 25 and emitting a first reproduction signal Si (RF signal), a second deflection plate 27, passing only predetermined second polarized light from the laser beam reflected by the first deflection plate 25 and reflects the other light, a second light receiving means 28 for receiving second polarized light passed through the second deflection plate 27 and emitting a second reproduction signal S2 (RF signal), a selector 29 for selectively emitting the first. reproduction signal Si or the second reproduction signal S2 is supplied as a reproduction signal S in response to a control signal C, and a reproduction circuit 30, which comprises a decoder and an amplifier, and transmits the reproduction signal S as a signal Sout

The beam of light LB of the laser beam, which is a linearly polarized light, emitted by the laser diode 21, is focused on surface with the recorded information from the optical disk via the beam splitter 22, mirror 23 and objective lens 24, and is irradiated on pits P on three tracks Ritot R3, as shown in figure 8.

At this time, the areas where the tracks R 1 and R 3 are applied are magnetized facing the rear of the surface in the schematic, while the area where the track R 2 is applied is magnetized facing the surface from the rear. This results, for example, in that the polarization planes of the reflected light rays of the tracks Ri and R3 rotate clockwise when viewed on the drawing sheet, the polarization plane of the reflected light beam of the track R2 rotates counterclockwise when viewed in the same direction.

The reflected light rays from the tracks Ri to R3 are reflected in a mixed form by the beam splitter 22, and are guided to the first deflection plate 25. The first deflection plate 25 is designed to transmit only the first polarized light, the polarization plane of which is clockwise rotated, viewed towards the drawing sheet, only the reflected light rays from the tracks Ri and R3 pass and the other light is reflected and directed to the second deflection plate 27.

Since the second deflection plate 27 similarly transmits only the second polarized light, the polarization of which is rotated counterclockwise, viewed towards the drawing sheet, only the reflected light beam of the track R2 passes and the other light is reflected.

In this case, it is the track R2 that carries the desired propagation signal S, so that the controller (not shown) emits a control signal C causing the selector 29 to select the second light receiving means 28. This control signal C can be obtained from the reproduction signal S, or it can be calculated from the rotational speed of the optical disk 1.

Since the second reproduction signal S2, which is a reproduction signal of the second light receiving means 28, does not contain crosstalk components of the tracks R1 and R3, the information can be accurately reproduced from only the desired track R2, even if the recording on the optical disc was made high intensity.

Similarly, if, as shown in Figure 9, the center of the laser beam LB is shifted to track R3, the polarization planes of the reflected light beams of tracks R2 and R4 are rotated counterclockwise, looking at the drawing sheet , relative to the polarization plane of the incident light, and the polarization plane of the reflected light of the track R3 rotated counterclockwise when viewed from the drawing sheet relative to the polarization plane of the incident light.

The reflected light from the tracks R 1 to R 3 is reflected by the striker 22 in a mixed form, and is guided to the first deflection plate 25. Only reflected light from the track R3 passes the deflection plate 25 and other light is reflected and directed to the second deflection plate 27.

Since the second deflection plate 27 similarly transmits only the second polarized light, the polarization of which is rotated counterclockwise, viewed from the drawing sheet, only the reflected light beam from the track R2 and R4 passes and the other light is reflected .

In this case, it is the track R3 that carries the desired reductance signal S, so that the controller (not shown) emits a control signal C causing the selector 29 to select the first light receiving means 26.

Since the first reproduction signal Si, which is a reproduction signal from the first light receiving means 26, does not contain cross-talk components of the tracks R2 and R4, the information can be accurately reproduced from only the desired track R3, even if the recording on the optical disc was made high intensity.

Although the laser beam emitted from the laser diode 21 is irradiated unchanged on surface with the recording information of the optical disc through the beam splitter 22, mirror 23 and objective lens 24 according to the above-described embodiment, a deflection plate may be provided in the optical path between the laser diode 21 and the beam splitter 22, whereby the laser beam on the optical disk 1 can be beamed via the deflection plate.

Two types of polarized light different by directions of rotation of the polarized plane are received by the two light receiving means, respectively, and one of the reproduction signals, or the emitted signals from the light receiving means, is selectively emitted by the embodiment described above. If an improvement is made so that a single deflection plate 30 is applied and the deflection plate 30 is rotated by a drive 31 at the same time as the switching moment of the control signal C in the above-described embodiment, as shown in Figure 10, there is only one light receiving means 32 is needed, making it possible to design a device of small dimensions.

Although two types of magnetic optical disks have been described in the above description of the individual embodiments, the invention can also be applied to a magnetic optical disk with a different structure.

Briefly, deflection layers according to the optical disc according to the invention are provided in such a way that the direction of rotation of the polarization planes for one track differs from that of the polarization planes for the adjacent tracks. Therefore, even if the optical disc playback device reads information from pits of the adjacent tracks, the signal of the desired track can be easily separated in a process afterwards by the difference in the polarization plane, thereby producing a high density recording insured.

The optical disc playback device according to the invention can only reproduce information of the desired track without any interference from the adjacent tracks by using the phenomenon that the direction of rotation of the polarization is different from that of the polarization surfaces for the adjacent surfaces. Although the device has a simple structure, it can effectively reduce the influence of crosstalk.

Claims (4)

An optical disc having a plurality of adjacent recording tracks, the optical disc comprising: - a first deflection layer formed on that portion containing the odd-numbered tracks of the plurality of recording tracks, for polarizing incident reading light to emit the first polarized light with a first polarization flat; and - a second deflection layer, formed on that portion containing the numbered tracks of the plurality of recording tracks, to polarize incident reading light to emit the second polarized light with a second polarization plane, different from the first polarization plane. An optical disc according to claim 1, characterized in that the first deflection layer and the second deflection layer each have a photomagnetic layer and a direction of the magnetization of the first deflection layer is opposite to that of the second deflection layer. 3. An optical disc playback device for playing an optical disc having a plurality of adjacent recording tracks, a first deflection layer formed on that portion containing the odd-numbered tracks of the plurality of recording tracks, for polarizing incident reading light to emit the first polarized light having a first polarization plane, and a second deflection layer formed on that portion containing the even-numbered tracks of the plurality of recording tracks, to polarize incident reading light to emit the second polarized light with a second polarization plane, different from the first polarization plane, which device comprises: - a light source for generating reading light to the recording tracks of the optical disc; light splitting means for separating the first polarized light and the second polarized light from the optical disc from each other; first light receiving means for receiving and emitting the first polarized light as a first signal; second light receiving means for receiving and emitting the second polarized light as a second signal; reproducing means for reproducing recorded information from the optical disc on the basis of the first signal or the second signal. 4. An optical disc playback device according to claim 3, characterized in that it further comprises selection means for receiving the first signal and the second signal, selectively broadcasting the first signal when reproducing recorded information from said recording track. the first deflection layer is formed, and selectively transmitting the second signal when reproducing recorded information from that recording track where the second deflection layer is formed.