KR100578207B1 - Recording device of holographic rom using of mirror coating mask - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording apparatus of a holographic ROM using a mirror coating mask, wherein the recording apparatus of a holographic ROM system records hologram data on an optical recording medium, the beam separating a signal light and a reference light from laser light incident from a light source. A splitter, a mirror for injecting the reference light to the lower surface of the optical recording medium at an angle, and transmitting the signal light to the upper surface of the optical recording medium according to the on / off bit pattern of the hologram data, and transmitting the reference light transmitted through the optical recording medium. It includes a data mask having a mirror coating area that transmits as it is. According to the present invention, it is possible to prevent abnormal data from being recorded on the disk due to interference of the reference light and the signal light reflected from the surface of the light blocking film of the data mask, thereby increasing the dynamic range of the recording material layer on the disk and thereby overlapping the data in the holographic ROM system. There is an advantage that the characteristics of the recording can be improved.

Conical Mirror, Holographic ROM, Multi-Layer Mirror Coating Mask

Description

RECORDING DEVICE OF HOLOGRAPHIC ROM USING OF MIRROR COATING MASK}

1 is a view schematically showing a recording method of a holographic ROM to which a general chromium coating is applied;

2 is a block diagram showing a recording apparatus of a holographic ROM according to the prior art;

3 is a diagram schematically illustrating a recording method of a holographic ROM to which a mirror coating mask is applied according to the present invention;

4 is a view showing in more detail the reference light transmission by the mirror-coated mask during recording of the holographic ROM according to the present invention;

5 is a block diagram showing a recording apparatus of a holographic ROM according to the present invention;

6A is a graph showing the relationship between the reference light incident angle versus the transmittance when the mirror coating mask is applied according to the present invention;

6B is a graph showing the relationship between wavelength vs. reflectance when a multi-layer mirror coated mask is applied according to the present invention.

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

122: data mask

123 mirror coating area

124: disk

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to holographic memory, and more particularly, to recording holographic ROM using a mirror coating mask that can prevent abnormal data recording due to reference light reflected on the data mask surface when hologram data is recorded on a disc, an optical recording medium. Relates to a device.

As the information industry develops, a large capacity of a device for storing information and a high speed of processing are required. Currently, research and development of holographic memory (HROM: Holographic ROM), which can store hundreds to hundreds of Gbytes as recording media such as optical disks, for the large capacity and high speed processing of data storage memory There is. The holographic ROM can store a large amount of information in one bit of an optical disc such as a CD or a DVD, and the data input / output speed is high because the stored data is processed in parallel. Because of these advantages, holographic ROMs are in the spotlight as the next generation of mass information storage.

Such a holographic ROM can superimpose and write new holographic data onto a disc using a "conical mirror" having a different inclination angle from the data mask. In order to superimpose recording, a conical mirror is mounted on the reference beam stage of the holographic ROM system. The recording method of the holographic ROM using the conical mirror will be described with reference to FIG. 1.

1 is a view schematically showing a recording method of a general holographic ROM system.

A data mask 52 is disposed on the holographic optical recording medium 50 (hereinafter referred to as a 'disk'), and a conical mirror 54 is disposed below the disk. During recording, if a signal beam S is incident on the data mask 52, the signal light S is transmitted through the bit pattern (not shown) of the data mask 52. Is delivered). At the same time, when a reference beam (R) is incident to the lower portion of the disk 50, it is reflected at a predetermined angle through the inclined mirror surface of the conical mirror 54 is transmitted in the radial direction of the disk 50. The signal light S and the reference light R meet at the recording material layer in the disk 50 and interfere with each other, resulting in the recording of hologram data according to the pattern of the data mask 52.

As described above, the holographic ROM system can use the conical mirror 30 having a different inclination angle from the data mask 32 to superimpose the hologram data on the disc 34.

2 is a block diagram illustrating a recording apparatus of a holographic ROM system according to the related art. Referring to FIG. 2, the recording apparatus of the conventional holographic ROM system includes a light source 10, mirrors 20, 26, 28, a beam splitter 16, a conical mirror 30, It consists of a data mask 32 and a disk 34. Where 12 and 22 are half wave plates (HWP), 14 are magnification lenses, and 18 and 24 are polarizers.

The laser light of the light source 10 has polarization characteristics of P type and S type. The laser light is transformed into P / S polarized light into λ / 2 through the HWP 12, and the light is magnified to a predetermined size through the magnifying lens 14 and transmitted to the beam splitter (PBS) 16.

The beam splitter (PBS) 16 reflects S-polarized light and transmits P-polarized light as it is. Accordingly, the P-polarized light transmitted through the beam splitter (PBS) 16 as it is is transmitted to the polarizer 18 along the signal light path. The polarizer 18 transforms the P-polarized light into parallel light and transmits it to the mirror 20. The mirror 20 vertically reflects the parallel P polarization and transmits it to the entire upper portion of the data mask 32 so that the parallel P polarization is transmitted through the on / off bit pattern of the data mask 32. Incident on the top.

The S-polarized light reflected by the beam splitter (PBS) 16 is transmitted to the HWP 22 along the reference light path. The HWP 22 transforms the S-polarized light into λ / 2 to make P-polarized light, and the polarizer 24 transforms the P-polarized light into parallel light and transmits it to the mirrors 26 and 28. The mirrors 26 and 28 reflect the parallel P polarization vertically and transmit the same to the conical mirror 30 to reflect the parallel P polarization at a predetermined angle through the inclined mirror surface of the conical mirror 30. It enters the lower part of the disk 34.

As a result, the signal light of the P polarization and the reference light of the P polarization meet and interfere with each other in the recording material layer in the disk 34 to record hologram data according to the bit pattern of the data mask 32. At this time, since the signal light and the reference light incident on the disk 34 must be the same polarization type to cause interference, for example, when the signal light polarization incident on the disk 34 is P-type polarized light, the reference light must also be P-type polarized light.

However, a light reflection error may occur due to the pattern of the data mask during recording of the holographic ROM system according to the related art. That is, as shown in FIG. 1, the data mask 52 used in the recording apparatus of the conventional holographic ROM system has a light blocking film on the bit pattern or light transmitting mask 52 in the form of a hole through which the mask penetrates. (Not shown). In the latter case, since the light blocking film of the data mask 52 is usually made of a metal material such as chromium (Cr), the reference light (or light) is formed on the surface of the light blocking film of the mask 52. R) causes reflection (bold solid line reflected downward from mask 52), thereby causing abnormal data recording.

The process of recording abnormal data on the optical recording medium by reference light reflected from the pattern of the data mask during recording of the holographic ROM system will be described in detail as follows.

First, when the reference light R of the P-polarized light is incident to the lower portion of the disk 50 at a predetermined angle, and the signal light S of the P-polarized light is incident on the entire upper portion of the disk 50, the reference light R and the P-polarized light of the P polarized light. Signal signals S interfere with each other and are recorded as normal data in the disk 50.

However, the reference light R of the P-polarized light transmitted through the disk 50 is reflected by the light blocking film of the data mask 52, reincident to the disk 50, and is incident to the upper surface of the disk 50. The reference light R1 of the reflected P-polarized light and the signal light S of the P-polarized light incident on the upper surface of the disk 50 interfere with each other to record abnormal data by the reflected reference light instead of the originally desired hologram data.

Therefore, in the recording apparatus of the holographic ROM system according to the related art, abnormal data is recorded in the disk 50 due to interference of the reference light and the signal light reflected from the light blocking film surface of the data mask 52, so that the recording material layer in the disk 50 is recorded. The problem arises of reducing the dynamic range of the signal and thus degrading the characteristics of data superimposition recording in the holographic ROM system.

The present invention is implemented to solve the problems of the prior art as described above, it is possible to eliminate the interference between the reference light and the signal light reflected from the data mask by applying a mirror coating mask that transmits to the reference light incident in a certain angle range It is an object of the present invention to provide a recording apparatus of a holographic ROM using a mirror coating mask.

Another object of the present invention is to eliminate the interference between the reference light and the signal light reflected from the data mask by applying a multi-layer mirror coating mask that transmits for the reference light incident at the remaining angle except the reference light incident perpendicular to the coating surface The present invention provides a recording apparatus of a holographic ROM using a mirror coating mask.

According to a preferred embodiment of the present invention for achieving this object, a recording apparatus of a holographic ROM system for recording hologram data on an optical recording medium, comprising: a beam splitter for separating signal light and reference light from laser light incident from a light source; A mirror for injecting the reference light to the lower surface of the optical recording medium at a predetermined angle, and transmitting the signal light to the upper surface of the optical recording medium according to an on / off bit pattern of the hologram data and transmitting through the optical recording medium. The present invention provides a recording apparatus of a holographic ROM system including a data mask having a mirror coating area for transmitting the reference light as it is.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

3 is a diagram schematically illustrating a recording method of a holographic ROM to which a mirror coating mask is applied according to the present invention.

Referring to FIG. 3, since the data mask 52 according to the present invention has a mirror coating technique applied thereto, the reference light R reflected from the conical mirror 54 and passing through the disk 50 is transferred from the data mask 52. It can be seen that the light is transmitted without being reflected. That is, in the holographic ROM recording apparatus according to the present invention, the data mask using the mirror coating material as the light blocking film is used instead of the data mask using the metal material such as chromium as the light blocking film, so that it is reflected from the conical mirror 54. It is characterized in that the reference light passing through the disk 50 is transmitted as it is without being reflected from the light blocking film.

This is shown in more detail in FIG. 4.

As shown in FIG. 4, when the reference light R of the P-polarized light is incident to the lower portion of the disk 124 at a predetermined angle, and the signal light S of the P-polarized light is incident on the entire upper portion of the disk 124, the reference light R of the P-polarized light. And the P-polarized signal light S interfere with each other and are recorded as normal hologram data in the recording material layer in the disk 124.

In addition, even though the reference light R of the P-polarized light passed through the disk 124 reaches the data mask 122, the reference light R of the P-polarized light is transmitted as it is by the mirror coating area 123 of the data mask 122. R '). Accordingly, hologram data is not recorded in the recording material layer in the disk 124 because it does not interfere with the signal light S of P polarized light incident on the upper surface of the disk 124.

5 is a block diagram illustrating a recording apparatus of a holographic ROM system using a data mask to which the mirror coating technique as described above is applied.

Referring to FIG. 5, the recording apparatus of the holographic ROM system according to the present invention includes a light source 100, mirrors 110, 116, and 118, a beam splitter (PBS) 106, a conical mirror 120, and a mirror. And a disk 124, which is an optical record carrier. Where 102 and 112 are HWPs, 104 are magnifying lenses, and 108 and 114 are polarizers.

The laser light of the light source 100 has polarization characteristics of P type and S type. The laser light is transformed to P-type and S-type polarized light into λ / 2 through the HWP 102, and the light is magnified to a predetermined size through the magnifying lens 104 and transmitted to the beam splitter (PBS) 106.

The beam splitter (PBS) 106 reflects S-polarized light and transmits P-polarized light as it is. Accordingly, the P-polarized light transmitted through the beam splitter (PBS) 106 as it is is transmitted to the polarizer 108 along the signal light path. The polarizer 108 transforms the P-polarized light into parallel light and transmits it to the mirror 110. The mirror 110 reflects the parallel P polarization vertically and transmits it to the entire upper portion of the data mask 112 so that the parallel P polarization is incident on the mirror coated data mask 122.

The S-polarized light reflected by the beam splitter (PBS) 106 is transmitted to the HWP 112 along the reference light path. The HWP 112 transforms the S-polarized light into λ / 2 to make P-polarized light, and the polarizer 114 transforms the P-polarized light into parallel light and transmits it to the mirrors 116 and 118. The mirrors 116 and 118 reflect the parallel P polarization vertically and transmit the same to the conical mirror 120 to reflect the parallel P polarization at a predetermined angle through the inclined mirror surface of the conical mirror 120. It enters the lower part of the disk 124.

Accordingly, P-polarized signal light is incident on the disk 124, which is the entire optical recording medium, through the on / off bit pattern of the data mask 122, and the inclined mirror surface of the conical mirror 120 is incident. The reference light of the P-polarized light incident on the lower portion of the disk 124 is interfered with each other in the recording material layer in the disk 124 so that hologram data according to the bit pattern of the data mask 122 is recorded. At this time, since the data mask 122 includes a mirror pattern region (not shown), the reference light passing through the disk 124 is transmitted as it is without being reflected back to the disk 124. This prevents signal light and rewriting.

6A is a graph showing the relationship between the reference light incident angle and the transmittance when a mask having such a mirror coating area is applied.

As can be seen in the graph of Fig. 6A, the mirror coating mask applied to this embodiment has an incident angle of 0 ㅀ -20 ㅀ, and 70 ㅀ assuming that the beam angle perpendicular to the mirror coating area is 0 ㅀ. In the above, when the light is reflected by 90% or more and enters between 35 kHz and 50 kHz, 90% or more passes. That is, when the incident angle of the reference light reflected by the conical mirror 54 and passed through the disk 50 is in the range of 0 to 20 kHz, or when the reference light is incident to 70 ㅀ or more, the reflection is reflected at the mirror coating area 123. However, it can be seen that when the reference light is incident in the range of 35 kV to 50 kV, the light transmits 90% or more in the mirror coating area 123.

According to the mirror coating mask as shown in FIG. 6A, it has been described as transmitting the reference light incident in a predetermined angle range, that is, in the range of 35 ° to 50 °, but this range of incidence angle is not necessarily limited, and other types of mirror coatings. In the case of using the material, it may be realized to transmit the reference light in another angular range.

On the other hand, the angular range of the reference light may cover the angular range of the reference light reflected by the conical mirror 54 to some extent, but when the mirror coating mask is applied once, the angular range capable of transmitting the reference light Because of its limitation, it does not provide a satisfactory transmission range.

Thus, the present invention is characterized by applying a multi-layer mirror coating mask employing a multilayer coating material.

FIG. 6B is a graph of wavelength vs. reflectance when a multi-layer mirror coating mask having transparency for most incident angles is used to further emphasize the features of the present invention.

As can be seen in FIG. 6B, the reference light is reflected only at 0 되는 which is incident almost perpendicularly to the mirror coating surface, and all are transmitted when the reference light is incident at the other angle. That is, the mirror coating area was formed in the data mask by the multi-layer technique so that it can be transmitted for most incident angles. At this time, the thick dotted line in Figure 6b shows the reflectance at 532nm wavelength.

As described above, preferred embodiments of the present invention have been described, but the present invention is not limited to these embodiments, but various modifications, for example, angles of reference light, are made by those skilled in the art within the spirit and scope of the present invention described in the following claims. Of course, it is possible to apply the mirror coating material so that the reference light is transmitted between 50 kHz to 70 kHz which is widely used.

According to the present invention, it is possible to prevent abnormal data from being recorded on the disk due to interference of the reference light and the signal light reflected from the surface of the light blocking film of the data mask, thereby increasing the dynamic range of the recording material layer on the disk and thereby overlapping the data in the holographic ROM system. There is an advantage that the characteristics of the recording can be improved.

Claims (5)

A recording apparatus of a holographic ROM system for recording hologram data on an optical recording medium, A beam splitter separating the signal light and the reference light from the laser light incident from the light source; A mirror for injecting the reference light into the lower surface of the optical recording medium at an angle; A data mask having a mirror coating region that transmits the signal light to the optical recording medium on an upper surface according to an on / off bit pattern of the hologram data and transmits the reference light transmitted through the optical recording medium as it is The recording device of the holographic ROM system comprising a. The method of claim 1, And the mirror is a conical mirror. The method of claim 1, And the mirror coating area is transmitted to a reference light incident in a predetermined angle range. The method of claim 1, And the mirror coating area is transmitted to the reference light incident in a second angular range except for the reference light incident perpendicularly to the mirror coating area. The method according to claim 1 or 4, And the mirror coating area is a multi-layer mirror coating area.

Images