JPS6143771B2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention reproduces signals recorded on the optical recording medium by irradiating a laser beam onto the optical recording medium and receiving the reflected light with a light receiving element. The present invention relates to an optical signal reproducing head used in an optical signal reproducing device.

First, a conventional optical signal reproducing head of this type will be explained with reference to FIG. 1 is a laser light source, for example, a He--Ne laser light source. This laser light source 1 generates, for example, a P-polarized (linearly polarized) laser beam. The laser beam from this laser light source 1 is reflected by a mirror 2 and its direction is changed approximately 90 degrees, and then the beam splitter 3
The light is incident on the λ/4 plate 4 through the λ/4 plate 4. Here, the P-polarized laser beam is converted from linearly polarized light to circularly polarized light. This laser beam converted into circularly polarized light is transmitted through the objective lens 5.
The light is focused on the recording surface of the disk-shaped optical recording medium 6 through the optical recording medium 6. On this disc-shaped recording medium 6, information signals such as audio signals and video signals are converted into PCM, and a spiral track consisting of a row of pits is formed. The reflected light from the recording medium 6 enters the λ/4 plate 4 through the objective lens 5 again. Here, the circularly polarized laser beam is converted into an S-polarized (linearly polarized) laser beam, and then enters the beam splitter 3,
Here, the light is reflected laterally in the figure and is incident on a photodiode 7 as a light receiving element. In this way, the light receiving element 7 outputs a reproduced signal.

Incidentally, in the conventional optical signal reproducing head described above, an optical lens consisting of a large number of lens sets is used as the objective lens 5, similar to an objective lens used in a microscope. Although not shown in FIG. 1, focus servo is usually performed by moving the objective lens 5 up and down in the direction of its optical axis using electromagnetic means or a linear motor.
Also, using a galvano mirror as mirror 2,
It is common practice to perform tracking servo by rotating this according to the tracking deviation.

By the way, as mentioned above, the objective lens 5 is quite heavy because it uses an optical lens consisting of many lens sets, and it takes a considerable amount of effort to move it up and down in the optical axis direction for focus servo. It requires mechanical energy and is quite expensive. Furthermore, since the optical system is spatially arranged as described above, there is a possibility that the relative positional relationship between each optical element may change over time. Thus, it cannot be avoided that the optical system as a whole occupies a considerable space factor.

In view of this, the present invention proposes an optical signal reproducing head which completely eliminates the above-mentioned conventional drawbacks.

An embodiment of the present invention will be described below with reference to FIG. The present invention uses a hologram lens as the objective lens 5 in the optical signal reproducing head described above, and also attaches the beam splitter 3, the λ/4 plate 4, and the hologram lens 5 using a light-transmitting adhesive. They are integrated together.

Beam splitter (polarizing beam splitter) 3
For example, a multilayer film 3c is formed on the slopes of prisms 3a and 3b at an angle of 45 degrees, and these are integrated into a cube shape with a side of approximately 5 mm and a weight of approximately 300 mg. The λ/4 plate 4 uses a polymeric stretched film (for example, polypropylene),
Its thickness is 15 μm. This thick taste is
It was selected in accordance with the fact that the wavelength of the He-Ne laser beam is 6328 Å. Its weight is negligible compared to the beam splitter 3.

In this example, the hologram lens 5 is an in-line hologram lens, for example, a photoresist film 5a is formed on a glass substrate 5b having a square shape of 5 mm on a side and a thickness of 1 mm, and a circular lens portion 5 is formed in the center of the photoresist film 5a.
a′ is formed. In this case, the N of lens portion 5a'.
A. (numerical aperture) is about 0.4,
The working distance is about 2.3mm, and the diameter is about 2mm.

Then, a λ/4 plate 4 is attached to the lower surface of the prism 3b of the beam splitter 3 via a light-transmitting adhesive layer 8, and a light-transmitting adhesive layer 8 is further attached to the lower surface of this λ/4 plate 4. Glass substrate 5b of hologram lens 5 via
is pasted, and the photoresist film 5 of the hologram lens 5 is attached.
A cover glass 9 is attached to the lower surface of a with a light-transmitting adhesive layer 8 interposed therebetween. As the light-transmitting adhesive layer 8, an ultraviolet curing adhesive (for example, Canada balsam) is used, and its refractive index is comparable to that of glass.

The cover glass 9 is a square with a side of 5 mm and is thick.
It is a 0.15mm glass plate. Further, the total weight of the hologram lens 5 and cover glass 9 is approximately 70 mg.
In the case of FIG. 2, the weight of the integrated beam splitter 3, λ/4 plate 4, hologram lens 5, and cover glass 9 is about 400 mg or less.

The light receiving element 7 may be a photodiode, for example, and may be attached to the side surface of the prism 3b of the beam splitter 3. In this case as well, a light-transmitting adhesive similar to that described above may be used.

Next, an example in which an off-axis hologram lens is used as the objective lens 5 will be described with reference to FIG. In FIG. 3, parts corresponding to those in FIG. 2 are designated by the same reference numerals, and redundant explanation will be omitted.
When using an off-axis hologram lens 5, the incident angle is set to 45, for example, to the hologram lens 5.
It is necessary to input a laser beam of °. Therefore, as the beam splitter 3, we use a prism 3a whose left side surface has an angle of 90 degrees with respect to the bottom surface, and whose right side surface has an angle of 65 degrees with respect to the bottom surface.
The multilayer film 3c is pasted on the slope of °. Then, a laser beam from a laser light source is made incident on the multilayer film 3c, where the laser beam is refracted and made incident on the hologram lens 5 at an incident angle of 45°, and then the reflected light is directed onto the multilayer film 3c. The light receiving element 7 attached to the left side surface of the prism 3a
Make it incident on .

An example of a method for manufacturing an in-line hologram lens as the objective lens 5 will be described below with reference to FIG. The diffraction efficiency is
Less than 100% off-axis hologram lens OX−
L is used as a mother lens (objective lens). This off-axis hologram lens OX-L
The manufacturing method, especially the recording method, will be described later with reference to FIG. This off-axis hologram lens OX
-L is a hologram recording medium HR ₂ consisting of a glass substrate BS and a photoresist film (recording layer) K thereon, in which a circular off-axis hologram lens portion HL' is recorded in the center of the photoresist layer K, and further developed as described below. It is formed through processing. In this case, the off-axis hologram lens OX-L directs the reproduced reference wave beam (a plane wave or a spherical wave beam, in this example, a plane wave beam) from the substrate BS side at an angle of approximately 45 degrees to the normal to the photosensitive layer K. When the lens part HL' is irradiated, the optical axis is on the normal line from the photosensitive layer K side,
It is made to reproduce a regenerated object wave beam that is focused at a point P.

HR ₁ is a hologram recording medium on which an in-line hologram lens IN-L is to be recorded, and is made of a glass substrate.
It consists of BS and a photosensitive layer K thereon.

And for this hologram recording medium HR ₁ ,
The off-axis hologram lens OX-L, which serves as a mother lens, is made to face the lens. That is, in this case, hologram recording is performed on the off-axis hologram lens OX-L at a predetermined interval so that the photosensitive layer K of the hologram recording medium HR ₁ faces parallel to the photosensitive layer K of the off-axis hologram lens OX-L. Place medium HR ₁ .

Then, a part of the laser beam (parallel plane wave beam) from the laser light source LS is sent to the beam splitter.
Reflected by BS, and the reflected beam is further reflected by mirror M.
The reflected beam (parallel plane wave beam) is made incident on the photosensitive layer K from the glass substrate B' side of the off-axis hologram lens OX-L as a reproduced reference wave beam B'. In this way, the off-axis hologram lens OX-L reproduces the reproduced object wave beam A' which is focused at the point P and then diverges, and this is incident on the photosensitive layer K of the hologram recording medium HR ₁ as the recording object wave beam A. do.

On the other hand, a part of the laser beam from the laser light source LS passes through the beam splitter BS, further passes through the off-axis hologram lens OX-L, and is in an in-line relationship with the recording object wave beam A (that is, each optical axis coincides with each other). The recording reference wave beam B is incident on the photosensitive layer K of the hologram recording medium HR ₁ . Thus, a circular in-line hologram lens portion HL is formed at the center of this photosensitive layer K, and an in-line hologram lens IN-L is produced by performing a development process to be described later.

Next, how to make the off-axis hologram lens OX-L used as the objective lens 5 in FIG. 3 and the mother lens in FIG. 4 will be explained with reference to FIG. A recording object wave beam (spherical wave) is irradiated onto the photosensitive layer K of the hologram recording medium HR ₂ consisting of a photosensitive layer K and a glass substrate BS so that the optical axis coincides with the normal line, and at the same time, the optical axis is aligned with the normal line. A circular off-axis hologram lens portion HL' is recorded in the center of the photosensitive layer K by irradiating the recording reference wave beam (parallel plane wave beam) B with an incident angle of about 45°, and then this photosensitive layer K is processed to obtain an off-axis hologram lens OX-L.

In this case, the recording object wave beam A is created as follows. A part of the laser beam (parallel plane wave beam) from the laser light source LS is sent to the beam splitter BS.
is passed through the auxiliary lens (optical lens) L ₂ to create a spherical wave beam that is focused at point Q (rear focal point of lens L ₂ ) and then diverges, and this beam is sent to the mother lens (objective lens) ( A spherical wave beam is created which is made incident on an optical lens (optical lens (optical lens) _L1 consisting of a large number of lens sets), converges at a point P, and then diverges, and this beam is designated as a recording object wave beam A.

Further, the recording reference wave beam B is created as follows. A part of the laser beam from the laser light source LS is reflected by the beam splitter BS, the reflected beam is reflected by the mirror M, and the reflected beam is used as the recording reference wave beam B.

As the mother lens _L1 , for example, a microscope objective lens with NA of 0.4 or 0.5 is used. Also, the aperture of the off-axis hologram lens portion HL' is, for example, 2 mm in diameter, and its working distance is, for example, 2.3 mm.
It is. Therefore, in this case, the aperture and working distance of the inline hologram lens portion HL of the inline hologram lens IN-L obtained in FIG. 4 are also 2 mm and 2.3 mm, respectively.

The laser light sources LS in Figures 4 and 5 include, for example, argon laser beam (λ = 4880 Å), krypton laser beam (λ = 6471 Å), dye laser beam (λ = 6330 Å), He-Ne laser beam ( λ = 6328 Å), etc. can be used. Furthermore, the photosensitive layers K of the hologram recording media HR ₁ and HR ₂ shown in FIGS. 4 and 5 are selected depending on the type of laser beam.

Next, the hologram recording medium shown in Figures 4 and 5
HR ₁ , HR ₂ and hologram lens IN-L, OX-
An example of how to make L will be explained. An aqueous gelatin solution containing an appropriate amount of a hardening agent, such as formaldehyde or glyoxal, is maintained at around 40°C, and a 1 mm thick glass substrate and a spinner are similarly maintained at around 40°C. A gelatin aqueous solution is applied onto a glass substrate using this spinner.
The coating thickness of this aqueous gelatin solution is selected so that the thickness after drying is 5 μm for a hologram recording medium for an off-axis hologram lens, and 15 μm for an inline hologram lens. The aqueous gelatin solution coated on the glass substrate is dried to form a gelatin film that is the base material of the photosensitive layer. Next, a processing step for imparting photosensitivity to this gelatin film will be explained.

To impart photosensitivity to a blue or green beam on a gelatin film, soak the gelatin film in a 2 to 10% by weight aqueous solution of ammonium dichromate for about 10 minutes, then gently pull it up, stand it vertically, and dry it in a dark place. .

To impart photosensitivity to the red beam to the gelatin film, an aqueous ammonium solution containing 2% by weight of ammonium dichromate and 1×10 ^-3 mol/l of methylene blue dye is added to the gelatin film so that its pH becomes about 10. Thereafter, the gelatin membrane is immersed in this aqueous solution for about 10 minutes, and then dried in a stream of ammonia and dry nitrogen.

In this way, a hologram recording medium having a photosensitive layer K formed on a glass substrate is obtained. The photosensitive layer of the hologram recording medium is exposed to light as shown in FIGS. 4 and 5, and the irradiation energy density of the laser beam is about 100 to 1000 mJ/cm ² .

A hologram recording medium having an exposed photosensitive layer is immersed in water. If the photosensitive layer has photosensitivity to blue or green beams, it is immersed in running water at about 20°C for about an hour to reduce its photosensitivity to red beams. If you have it, soak it in warm water of about 40℃ for about 30 minutes.
Thereafter, this hologram recording medium is immersed in a 50% isopropanol aqueous solution for about 10 minutes, in a 90% isopropanol aqueous solution for several seconds, then in a 100% isopropanol solution for about 10 minutes, and then quickly dried with hot air. This completes the development process.

Note that the photosensitive layer, whose base material is gelatin film, is hygroscopic, and there is a risk that the hologram lens will disappear if left in this state. A cover glass 9 having a certain thickness is pasted onto the photosensitive layers 5a, K using an ultraviolet curing resin 8. Thus, hologram lenses 5, OX-L, and IN-L are obtained.

According to the above-mentioned optical signal reproducing head of the present invention, a hologram lens is used as the objective lens, and the beam splitter, the λ/4 plate, and the hologram lens are bonded together using a light-transmitting adhesive and integrated. Therefore, the weight of these integrated objects is extremely small, and therefore, when moving this integrated object up and down in the optical axis direction to perform focusing servo, the mechanical energy required for this purpose is small. The servo device becomes simple. Furthermore, since an optical lens consisting of a large number of lens sets is not used as the objective lens, and a hologram lens is used instead, the cost is reduced. Furthermore, a beam splitter,
Since the spatial arrangement between the λ/4 plate and the objective lens is fixed, there is no risk that the arrangement relationship will change over time.
Also, these parts are smaller and the space factor is smaller.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing a conventional optical signal reproducing head, FIG. 2 is a sectional view showing a main part of an optical signal reproducing head according to the present invention, and FIG. 3 is a main part of another embodiment of the present invention. FIGS. 4 and 5 are layout diagrams showing an example of a method for producing a hologram lens used in the present invention. 1 is a laser light source, 3 is a beam splitter (polarizing beam splitter), 4 is a λ/4 plate, 5 is an objective lens consisting of a hologram lens, 6 is a disc-shaped optical recording medium, 7 is a light receiving element, and 8 is a light-transparent adhesive layer,
9 is a cover glass.

Claims (1)

[Scope of Claims] 1. A laser light source, a beam splitter, a λ/4 plate, an objective lens, and a light receiving element, and a laser beam from the laser light source is transmitted to the beam splitter, the λ/4 plate, and the objective lens. an optical recording medium, the reflected light is incident on the light receiving element through the objective lens, the λ/4 plate, and the beam splitter, and the light receiving element outputs a reproduced signal. In the signal reproducing head, a hologram lens is used as the objective lens, and the beam splitter, the λ/4 plate, and the hologram lens are bonded and integrated using a light-transmitting adhesive. Optical signal regeneration head.