NL8003540A - OPTICAL DATA PRODUCTION DEVICE. - Google Patents

Description

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803221 + / Tx / M / tL

Short designation: Optical data reproduction device

The invention relates to "optical devices and in particular" to an optical device suitable for the optical reproduction of data stored in a recording medium.

A so-called optical disk device for optical reproduction of data is known.

For example, in the optical disk device, a semiconductor laser is used as the light source and, a light beam exiting the laser is projected by an optical system onto an information medium (disk), whereby data stored on the disk is reproduced or information is reproduced on the disc is being recorded. Fig. 1 shows the schematic embodiment of a known optical disc device and shows the main elements of an optical system. According to Fig. 1, a light beam emitted by a semiconductor laser 1 is guided via a prism 20 to a first lens 5. The prism 20 here consists of three prisms 2, 3 and U, which are combined into a single optical component, so that the light beam entering the prism array from the side of the semiconductor laser 1 is passed through the prisms 2 and 3 and towards the lens 5 and inversely a beam passed from the side of the lens 5 within the prism array between the contact surface A 20 the prisms 2 and 3 can be reflected and fed to the prism U. The light beam directed to the first lens 5 is mainly collimated by this lens and is projected as a small spot of light on a disc 8 by a second lens 6, which is carried in a magnetic field placed carrier coil 7. This light beam is reflected by the disc 8 and the reflected beam becomes, after the second lens 6, the first lens 5 and the prisms 3e nb, received by a photodetector 9 · At this time, if data is recorded on the disc 8 (for example, by means of wells corresponding to the data in the surface of the disc), the intensity of the reflected beam modulated in accordance with the data so that the data is obtained in the form of output signals from the photodetector 9. The tuning coil 7 serves to move the second lens 6 over short distances at a high speed and is provided for the control of a light beam, i.e. automatic focusing control or tracking control.

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In such an arrangement, the laser beam emitted by the semiconductor laser used as the light source has a divergence or exhibits an eccentricity ratio of about 3 to 1 and therefore has an anisotropic (elliptical) far field pattern. Therefore, when focused as such on the disc, the beam spot does not form an isotropic (circular) distribution pattern on the disc and the frequency characteristics deteriorate when reading the optical disc.

Therefore, in the known device, in order to bring a beam spot from a semiconductor laser to a circular distribution in case the semiconductor laser is used as the light source, the opening size of a lens is correctly adjusted when a laser beam is passed through the lens. I.e. by using the numerical aperture (called NA, luminosity) of the lens, the elliptical distribution pattern is converted into the circular distribution pattern.

However, such a device has the drawback that a lens with a predetermined brightness must be used. Furthermore, in the case of a small NA, combined lenses (number of lenses 2 to 3) must be used, complicating the implementation.

Moreover, in the device of the type shown in Fig. 1, the output signals from the photodetector must be made large enough to detect the data signals with a good signal-to-noise ratio. To this end, the facets of the prism and the lens, for example a facet 3a of the prism 3 and a facet 5a of the first lens 5j, must be provided with thin films, thereby preventing reflection of the light beam and in strong loss of light beam through the prism and through the lens is reduced. In the known optical disc device as shown in Fig. 1, the resp. however, constituent elements of the optical system, i.e., the prism and lenses, are all separated so that the optical efficiency is low and the number of deposition layers of the anti-reflective films on the prism, lens, etc. becomes large, resulting in high cost. Other drawbacks are that because the prism and lenses are separated, adjustment of the optical axes of the prism and lenses is difficult and the whole device becomes large due to the large number of components required.

The object of the invention is to provide a simple optical device with which a beam spot to be projected on a disc surface is given a circular distribution pattern and which also has the influence of image distortions through a lens. on the stain.

Another object of the invention is to provide an optical device with a high optical efficiency and a small number of components, which can be easily adjusted.

For this purpose the device according to the invention is characterized in that the lens is a plano-convex lens, the flat part of which faces the light source.

The invention is elucidated on the basis of the drawing:

Fig. 1 schematically shows the embodiment of a known optical disc direction device; Fig. 2 shows an embodiment of the invention; Figures 3 (a) and 3 (b) illustrate the operation of the embodiment of Figure 2; Fig. k shows another embodiment of the invention, and Figs. 5 (a) and 5 (b) each show the essential parts of a different embodiment of the invention.

Fig. 2 shows an embodiment of the invention and shows that a light beam L is guided from a semiconductor laser 21 to a polarizing beam splitter 22 and enters a plano-convex lens 23.

In a part of a holder 25 which supports the polarizing beam splitter 22, a circular opening 2h is arranged such that an optical path is formed. The viewing angle α from the opening to the semiconductor laser 21 is adjusted so that α <Θn <is satisfied. Here, Q ^ and 9 ^ indicate half divergence angles of the semiconductor laser beam in a direction perpendicular to the node of the semiconductor laser, respectively. in a direction parallel to it.

This embodiment practically gives the NA of the lens 23 the value sin α and avoids the complicated application of a lens with a predetermined NA for the lens 23. Furthermore, instead of combined lenses such as 30 in the known lens device, various planar use a convex lens 23, with its flat side facing the semiconductor laser 2.1 and image drawing sufficiently inhibited.

The reasons are the following:

Since the semiconductor laser used as the light source has a single oscillation wavelength (e.g. 8300 lb), a correction lens for the correction of a chromatic aberration is not necessary. Secondly, because the NA is small relative to the half-divergent angle (e.g., 9 ^ 8 °) of 800 35 40 -4- & e semiconductor laser 21, a correlation lens to correct a beam deviating from the axis is not necessary . Third, the wavefront of the semiconductor laser beam is a fairly good spherical wave and does not need correction. For these reasons, even a single lens can be used well. However, even in the manufacture of a single lens, if provided with a curved surface, a mold must be used corresponding to the curvature. Furthermore, the step of polishing a lens to a spot is unavoidable as a machining step prior to accurately shaping the curvature. The plan con 10. vexe lens is therefore advantageous from a manufacturing standpoint for the single lens with the convergence property.

The setting of the plano-convex lens in Fig. 2 will now be explained, considering the cases where the curvature directions as shown in Figs. 3 (a) and 3 (b) with respect to the semiconductor laser 21 originating bundle are different. In the case of Fig. 3 (a), the beam enters the lens at an angle ten to the normal of the incident facet. In the case of Fig. 3 (b), the angle becomes 3 and the beam exits at an angle X from the normal of the output facet. As a result, * 1> 3, ƒ.

To reduce lens deviations, the angle of the incident beam from the normal of the incident facet should be minimized. This mainly affects the spherical deviation. It will therefore be appreciated that the arrangement of Fig. 3 (b) is better. In other words, the plano-convex lens must be of the embodiment with the flat part thereof facing the light source.

As mentioned, the lens entered by the beam from the semiconductor laser consists of the single plano-convex lens, the flat part of which faces the light source and the effective aperture is positioned in the center of the optical path and the -30 tic head with simple construction.

Fig. k shows the construction of another embodiment of the invention in which the optical system is further simplified. According to this figure, a light beam emitted by a semiconductor 41 passes through the prisms k2 and ^ 3 and a first lens U5 to be substantially collimated, and the collimated light beam is projected as a small spot of light on a disk 8 through a second lens b6 is supported by a carrier reel (not shown). A beam reflected by the optical disc 8 8003540 -5- passes through the second lens k6, the first lens U5 and the prism b3, is reflected by the interface A between the prisms b2 and ^ -3, traverses a lens ^ and falls on a photo detector 9.

In this embodiment, a facet 5a of the first lens k5 has a flat shape and is mounted against a facet 3a of the prism Ij-3, so that the first lens and the prism form a single structure. By bringing the first lens b $ and the prism ^ 3 together according to this embodiment, it is not necessary to vaporize anti-reflection films on the facet 5a of the lens h5 and the facet 3a of the prism ij-3, and the loss of light is likewise less. Furthermore, with readily adjusted optical system, it is insensitive to vibrations and can be miniaturized.

Figures 5 (a) and 5 (¾) each show important parts of another embodiment of the invention. A component 30, Fig. 5 (a), is obtained such that the first lens b-5, the prism i + 3 and the lens in Fig. B are formed as a single piece during manufacture, while a component ^ 0 FIG. 5 (b) is obtained such that the first lens U5 and the prism ^ 3 are formed as a single piece during manufacture. Such a unit can be realized with a known technique, such as for instance molding of plastics. By forming into a single component as in the invention the first lens 1 -5 and the prism U3 during manufacture, the number of components of an optical system can be greatly reduced.

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Claims (3)

An optical system for the reproduction of data, comprising a semiconductor laser light source and a lens placed between the light source and a disc, wherein a laser beam is projected from the light source onto the disc, characterized in that the lens is a plan-convex lens 5 , the flat part of which faces the light source. An optical data reproduction system according to claim 1, characterized by a transmission aperture smaller than a divergence of the beam from the light source and placed in an optical path between the light source and the lens. 10 3. Optical system for the reproduction of data, equipped with a light source provided with a semiconductor laser, a plan-convex lens that projects a light beam emitted by the light source onto a disk, and a prism that deflects a beam reflected by the disk, with the characterized in that the lens and the prism form one whole. 15 800 35 40