KR100536686B1 - Holographic rom system - Google Patents

Abstract

The holographic ROM system according to the present invention comprises a light source for generating a laser light required for holographic and a polarizer splitting the laser light generated from the light source into a reference light and a signal light, and transmitting the signal light and reflecting the reference light. A splitter), a second reflection mirror that irradiates the reference light reflected by the polarization splitter through the first and second optical paths, and an optical path of the reference light reflected by the second reflection mirror by the refractive index to the optical recording medium. A second conical mirror to be irradiated, a third reflection mirror reflecting the signal light transmitted through the polarization splitter to the third optical path, and a first conical mirror reflecting the signal light reflected by the third reflection mirror at a predetermined reflectance A mirror and an annular beauty for reflecting the signal light reflected from the first conical mirror to a position corresponding to the area of the optical record carrier on which the reference light Predetermined signal light to be reflected by and in the annular mirror and modulates the data pattern comprises a mask for irradiating the optical recording medium.

As described above, the present invention can reduce the manufacturing cost of the system by changing the path of the signal light with the combination of the conical mirror and the annular mirror instead of the optical expander and injecting the signal light into the optical recording medium to which the reference light is incident.

Description

Holographic ROM System {HOLOGRAPHIC ROM SYSTEM}

The present invention relates to a holographic ROM system, and more particularly, to a holographic ROM system that can reduce the manufacturing cost of the system by changing the path of the signal light.

1 is a block diagram of a typical typical holographic ROM system, which includes a light source 100, a half wave plate (HWP) 102 and 114, a beam expander 104 and 112, and a polarizer beam splitter. ) 106, polarizers 108, 116, reflective mirrors 110, 118, 120, conical mirror 122, mask 124, and optical recording medium 126.

The light source 100 is a laser source having a predetermined wavelength, for example, a wavelength of 532 nm, and generates laser light required for holography.

The laser light generated from the light source 100 is provided to the polarization separator 106 via the HWP 102, the light expander 104, and the like.

The polarization separator 106 is a structure in which two or more kinds of materials having different refractive indices are repeatedly deposited, and transmits signal light and reflects reference light.

The signal light transmitted through the polarization separator 106 is reflected by the reflection mirror 110 via the polarizer 108. In this case, the holographic ROM system needs to change the optical path in order to enter the signal light reflected by the reflective mirror 110 into the recording area (the area where the reference light is incident) of the optical recording medium 120. For this reason, the reflective mirror 110 The optical expander 112 is installed between the mask and the mask 124.

The signal light reflected by the reflection mirror 110 is extended by the optical expander 112, and the expanded signal light is modulated in a predetermined pattern by the mask 124 and irradiated to the optical recording medium 126.

At this time, the optical expander 112 has a ring shape consisting of a plurality of lenses having an arbitrary diameter, and should be able to expand the reflected signal light by about twice the size of the optical recording medium 126. For example, in the holographic ROM system, in order to irradiate the optical recording medium 126 with signal light having a diameter of 120 mm, an optical expander including a combination of a plurality of lenses having a diameter of about 200 mm is required.

The reference light reflected by the polarization separator 106 is reflected by the reflection mirrors 118 and 120 via the HWP 114 and the polarizer 116 and irradiated to the conical mirror 122.

The conical mirror 120 is a means for adjusting the reproduction at the same angle when the holographic ROM system is reproduced, and multiplexes the reproduction angles using conical mirrors having different angles.

In this way, the holographic ROM system is extended by the optical expander 112, and the interference fringe generated by the interference between the signal light modulated by the mask 124 and the reference light incident through the conical mirror 120, the optical recording medium. Record at 126.

However, as described above, the conventional holographic ROM system requires an optical expander composed of a plurality of lenses having a diameter of about 200 mm in order to expand the diameter of the signal light to twice the size of the optical record carrier. There is a problem to increase the manufacturing cost of the system as a whole because of a lot.

Accordingly, the present invention has been made to solve the above-described problem, and by using a conical mirror and an annular mirror that can change the path of the signal light instead of an optical expander that extends the signal light, the manufacturing cost of the system can be lowered alone. Its purpose is to provide a graphical ROM system.

In order to achieve the above object, the present invention, in the holographic ROM system, the light source for generating a laser light required for the holographic and the laser light generated from the light source is separated into a signal light and a reference light, A polarizer beam splitter that transmits the signal light and reflects the reference light, a second reflection mirror that irradiates the reference light reflected through the polarization splitter through first and second optical paths, and the second reflection mirror A second conical mirror that adjusts the optical path of the reference light reflected by the refractive index to the optical record carrier, a third reflective mirror that reflects the signal light transmitted through the polarization splitter to the third optical path, and A first conical mirror for reflecting the signal light reflected by the third reflecting mirror with a predetermined reflectance, and half at the first conical mirror; Annular mirrors for reflecting the signal light to the position corresponding to the optical recording medium region into which the reference light is incident, and a mask for irradiating the optical recording medium by modulating the signal light reflected by the annular mirrors into a predetermined data pattern. Include.

The above and other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. 2 is a block diagram of a holographic ROM system according to a preferred embodiment of the present invention.

2 is a block diagram of a holographic ROM system according to a preferred embodiment of the present invention, which includes a light source 200, a HWP 202 and 216, an optical expander 204, a polarization splitter 206, and a polarizer 208 and 218. , The first reflection mirror 220, the second reflection mirror 222, the third reflection mirror 210, the first conical mirror 212, the annular mirrors 214a and 214b, and the second conical mirror 224 And an optical record carrier 226 and a mask 228.

The light source 200 is a laser source having a wavelength of 532 nm, which is a predetermined wavelength, and generates laser light required for holography, and the laser light is passed through the HWP 202, the light expander 204, and the like to the polarization separator 206. Is provided.

The polarization separator 206 separates the laser light into two lights, that is, the signal light and the reference light, wherein the reference light is reflected and provided to the second reflection mirror 222 through the first and second optical paths, and the signal light is transmitted to the third light source. It is provided to the third reflection mirror 210 via the optical path.

The reference light reflected by the polarization separator 206 is irradiated to the second conical mirror 224 through the first and second optical paths. In this case, the HWP 216, the polarizer 218, and the first reflection mirror 220 are installed on the first optical path, and the first reflection mirror 220 receives the reference light reflected by the polarization separator 206 in a predetermined direction. Deflection to provide the second optical path. A second reflection mirror 220 is provided in the second optical path, and the second reflection mirror 222 reflects the reference light incident by being deflected by the first reflection mirror 220 to the second conical mirror 224. Investigate.

The second conical mirror 224 reflects the reference light reflected by the second reflection mirror 222 to be parallel to each other at the same angle and enters the optical recording medium 226. That is, the reference light, which is spread in parallel at the same angle, is incident on the optical recording medium 226 through the second conical mirror 224.

The signal light transmitted through the polarization separator 206 is reflected by the third reflection mirror 210 through the polarizer 208 provided on the third optical path and irradiated to the first conical mirror 212. In this case, the surface of the first conical mirror 212 has a reflectance capable of reflecting all incident light to the annular mirrors 214a and 214b, so that the first conical mirror 212 is the third reflection mirror 210. Reflects the signal light reflected by the annular mirror (214a, 214b). The annular mirrors 214a and 214b reflect the signal light reflected by the first conical mirror 212, and the reflected signal light is modulated through the mask 228 and is incident on the optical recording medium 226. That is, the optical path of the signal light is changed by the first conical mirror 212 and the annular mirrors 214a and 214b, so that the signal light is incident at the same position as the position of the optical recording medium 226 to which the reference light is incident.

On the optical recording medium 226, an interference fringe generated by the interference between the signal light and the reference light provided through the optical path is recorded.

Therefore, the present invention can reduce the manufacturing cost of the system by changing the path of the signal light by a combination of the conical mirror and the annular mirror instead of the optical expander and injecting the signal light into the optical recording medium to which the reference light is incident.

As mentioned above, although this invention was demonstrated concretely based on the Example, this invention is not limited to this Example, Of course, various changes are possible within the range which does not deviate from the summary of the claim described below. .

1 is a block diagram of a typical holographic ROM system according to the related art,

2 is a block diagram of a holographic ROM system according to a preferred embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

200: light source 202, 216: HWP

204: optical expander 206: polarization separator

208, 218: polarizer 210: third reflection mirror

212: first conical mirror 214a and 214b: annular mirror

220: first reflection mirror 222: second reflection mirror

224 second conical mirror 226 optical recording medium

228: mask

Claims (1)

In holographic ROM system, A light source for generating laser light required for holographic, A polarizer beam splitter for separating the laser light generated from the light source into a signal light and a reference light, transmitting the signal light and reflecting the reference light; A second reflection mirror that irradiates the reference light reflected through the polarization separator through the first and second optical paths; A second conical mirror configured to irradiate the optical recording medium by adjusting the optical path of the reference light reflected by the second reflective mirror by a refractive index; A third reflecting mirror reflecting the signal light transmitted through the polarization splitter in a third optical path; A first conical mirror for reflecting the signal light reflected by the third reflecting mirror at a predetermined reflectance; Annular mirrors for reflecting the signal light reflected from the first conical mirror to a position corresponding to an area of the optical recording medium on which the reference light is incident; A mask that modulates the signal light reflected by the annular mirrors into a predetermined data pattern and irradiates the optical recording medium Holographic ROM system having a.