KR100579638B1 - Recording device for controlling a reference beam of the holographic rom and method therefor - Google Patents

Abstract

The present invention relates to a recording apparatus of a holographic ROM and a reference light adjusting technology thereof, comprising: a beam splitter separating a signal light and a reference light from a laser light incident from a light source; and a signal light transmitted from the beam splitter according to a bit pattern of holographic data. A data mask that converts the data signal into light and transmits it to the upper surface of the recording medium, a conical mirror that reflects the reference light transmitted from the beam splitter through the mirror inclined surface, and allows the inclining of the inner surface relative to the recording medium. A first annular mirror that adjusts a path of the reference light reflected from the mirror, and a second annular mirror that is made longer than a first annular mirror and reflects the reference light transmitted from the first annular mirror to the lower surface of the recording medium. However, the reference light reflected from the inside of the inclined surface of the conical mirror is the first annular mirror and the second annular The reference light transmitted through the mirror to the inside of the recording medium and reflected from the outside of the inclined surface of the conical mirror is transmitted to the outside of the recording medium. According to the present invention, a system development cost is achieved by adding an annular mirror instead of an expensive conical mirror and adjusting the reference light path transmitted from the conical mirror to the lower surface of the disk, which is a recording medium, to make the reference light intensity irradiated onto the disk uniform. Can be reduced. In addition, the present invention allows multiple overlapping recording by changing the inclination angle of the inner reflection surface of the annular mirror and adjusting the reference light reflection angle without changing the angle of the inclined surface of the conical mirror in comparison with the prior art, thereby overlapping recording of data of different angles. The replacement time is shortened and the replacement is easy.

Conical Mirror, Holographic ROM, Reference Light

Description

RECORDING DEVICE FOR CONTROLLING A REFERENCE BEAM OF THE HOLOGRAPHIC ROM AND METHOD THEREFOR}

1 is a diagram schematically illustrating a recording method of a holographic ROM using a general conical mirror;

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

3 is a view schematically showing a holographic ROM recording method using a reference light control device, a conical mirror and an annular mirror according to the present invention;

4 is a block diagram showing a holographic ROM recording device having a reference light adjusting device according to the present invention;

5A and 5B are diagrams showing that the reference light reflected through the conical mirror is irradiated onto the disc according to the prior art and the present invention, respectively.

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

100: light source 104, 118, 130, 136: mirror

112: beam splitter 122: conical mirror

124: first annular mirror 126: second annular mirror

144: data mask 146: disk as a recording medium

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a holographic memory, and more particularly to a recording apparatus of a holographic ROM suitable for multiple superimposed recording on a disc as a recording medium and a method for adjusting the reference light thereof.

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.

1 is a view schematically showing a holographic ROM recording method using a general conical mirror.

Referring to FIG. 1, a data mask (not shown) is provided on the disk 50, which is a holographic recording medium, and a conical mirror 32 is disposed below the disk 50. When writing data, when a signal beam is incident on the data mask, the signal beam is provided to the disk 50 through a bit pattern (not shown) in the form of a hole in the data mask. At the same time, when a reference beam is incident to the lower portion of the disk 50, the reference light is reflected at a predetermined angle by the inclined surface of the conical mirror 32 to be provided in the radial direction of the disk 50. The signal light and the reference light interfere with each other in the recording material layer in the disc 50, and the holographic data according to the bit pattern of the data mask is recorded.

Such a holographic ROM can superimpose new holographic data on the disc 50 using a conical mirror having a different inclination angle from the data mask.

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

Referring to FIG. 2, a conventional holographic ROM recording apparatus includes a light source 10, mirrors 14, 28, 34, and 40, a beam splitter 22, a conical mirror 32, and a data mask. 48, a disk 50 serving as a recording medium. 12 represents a shutter, 16 represents a half wave plate (HWP), 18 represents a spatial filter, and 20 represents an enlarged lens. 24 and 36 are HWPs, 26 and 38 are polarizers, 30 and 42 are spatial filters, and 44 are magnification lenses.

The laser light of the light source 10 is a type of linear polarization, for example, P-type or S-type polarization characteristics, and the beam splitter 22 through the shutter 12 to the magnification lens 20. Is delivered).

The beam splitter 22 transmits the laser light as it is for the two light paths S1 and S2 as it is to provide the reference light and reflects the laser light to provide the signal light.

The signal light path of S1 traveling from the beam splitter 22 to the magnifying lens 44 passes through the HWP 36 and the polarizer 38 sequentially through the signal light reflected through the mirror 34 to the other mirror 40. And reflects the signal light from the mirror 40 to the spatial filter 42. The spatial filter 42 removes incomplete polarization components of the signal light and transmits only purely polarization components. The signal light transmitted through the spatial filter 42 is magnified to a predetermined size through the magnifying lens 44 and converted into data signal light through the bit pattern of the data mask 48 and incident on the upper surface of the disk 50 as a recording medium. do.

The reference light path of S2 traveling from the beam splitter 22 to the conical mirror 32 reflects the reference light passing through the HWP 24 and the polarizer 26 sequentially through the mirror 28 and the spatial filter 30. And remove the incomplete polarization component of the reference light in the spatial filter 30 and transmit only the polarization component purely. The reference light transmitted through the spatial filter 30 is irradiated onto the inclined surface of the conical mirror 32 and reflected at a predetermined angle through the inclined surface of the conical mirror 32 and irradiated onto the lower surface of the disk 50.

As a result, the signal light and the reference light interfere with each other in the recording material layer in the disk 50, thereby recording holographic data according to the bit pattern of the data mask. At this time, the signal light and the reference light irradiated onto the disk 50 must be of the same polarization type to cause interference. For example, when the signal light is S type polarized light, the reference light must be S type polarized light.

In such a conventional holographic ROM recording apparatus, when the reference light diameter incident on the conical mirror is 23 mm, the reference light diameter reflected by the inclined surface of the conical mirror and reaching the lower portion of the disc is 120 mm. In terms of area, about 27 times light change occurs.

However, in the recording apparatus of the holographic ROM using such a conical mirror, when the reference light is reflected to the disc by the inclined surface of the conical mirror, the reference light reflected from the inside of the conical mirror is transmitted to the outside of the disc, and the outside of the conical mirror is The reference light reflected from the side is transmitted inside the disk. Therefore, the reference light transmitted to the disk by cross reflection inside and outside the conical mirror is not reflected at the same light intensity magnification.

Furthermore, since the reference light reflected from the inside of the conical mirror is transmitted to the outside of the disc, the farther away from the center of the disc, the more the reference light intensity increases, so that the light intensity of the holographic data recorded on the entire disc is different from the center and the outside. This difference in the reference light intensity causes uneven recording of the holographic data, which causes a problem of deterioration of the superposition characteristics of the holographic data.

As part of the prior art to solve this problem, the holographic data is accurately recorded by adding one more conical mirror and adjusting the reference light path transmitted to the lower surface of the disk as a recording medium to make the reference light intensity irradiated onto the disk uniform. A technique that can be done has been proposed.

Detailed description of this is disclosed in Korean Patent Application No. 2004-0070405 filed on September 3, 2004 by the present applicant with the title of 'The recording device of the holographic ROM having the reference light control device and its reference light control method'. It is disclosed in detail.

However, this technology puts the burden of producing multiple expensive conical mirrors for multiple overlapping recordings. That is, conical mirrors with new angles and sizes must be produced for different angles of overlap recording. For example, if a holographic ROM system requires 20 multiple overlaps, the angle of incidence on the 20 disc faces will be different. You have to make each conical mirror separately. Considering the manufacturing cost of one conical mirror, it is very inefficient.

In addition, each conical mirror must be replaced frequently to record at different angles. In general, conical mirrors are fixed at the center of the disc by attaching screws to clamps that enter the disc holes. You will need to unscrew the conical mirror, remove the used conical mirror, replace it with another conical mirror and fix it with screws.

If you change about 20 conical mirrors for overlapping recordings, it will take a considerable amount of time.

An object of the present invention is implemented to solve the above problems of the prior art, by placing a second annular mirror at the end of the reference beam instead of the second conical mirror and by varying the reflecting surface angle of the first annular mirror Disclosed is a holographic ROM recording apparatus capable of multiple superimposed recording while making uniform the intensity of a reference light and a method of adjusting the reference light.

In order to achieve the above object, the present invention provides a holographic ROM recording apparatus for recording holographic data on a recording medium, comprising: a beam splitter for separating signal light and reference light from laser light incident from a light source, and a signal light transmitted from the beam splitter. A data mask which converts the data signal light according to the bit pattern of the holographic data and transmits it to the upper surface of the recording medium, a conical mirror that reflects the reference light transmitted from the beam splitter through the mirror inclined surface, The first annular mirror which controls the path of the reference light reflected from the conical mirror by allowing the inclination of the side surface, and the reference light transmitted from the first annular mirror to the lower surface of the recording medium, which is made longer than the first annular mirror A second annular mirror that reflects, but is half inward of the slope of the conical mirror; The reference light is transmitted to the inside of the recording medium through the first annular mirror and the second annular mirror, it characterized in that the reference light reflection side of the outer inclined surface of the conical mirror to be delivered to the outside of the recording medium.

In order to achieve the above object, the method of the present invention provides a holographic ROM for irradiating a recording medium with data signal light and a reference light transmitted through a bit pattern of holographic data of a data mask and recording the holographic data by interference between these lights. A method of adjusting a reference light path in a recording apparatus of claim 1, comprising: irradiating a reference light to a conical mirror positioned below a recording medium and reflecting the reflected light through a mirror inclined surface; and a first annular mirror having a predetermined inclined surface reflected from the conical mirror. Reflecting back at an angle through the light source, reflecting the reflected reference light to the inner reflective surface of the second annular mirror positioned below the recording medium, and the inside of the inclined surface of the conical mirror through the inner reflective surface of the second annular mirror. Reflected from the outside of the inclined plane of the conical mirror And forwarding the received reference light straight out of the recording medium.

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

3 is a view schematically showing a holographic ROM recording method using a reference light adjusting device and a conical mirror according to the present invention.

Referring to FIG. 3, a reference light adjusting device in a holographic ROM recording apparatus according to the present invention adjusts a reference light path reflected by a second annular mirror 126 and irradiated onto a disk 146 which is a recording medium. By making the intensity of the reference light irradiated to 146 uniform, holographic data can be accurately recorded both inside and outside the disk 146. Here, the inside of the disc represents a portion close to the center of the disc and the outside represents a portion far from the center of the disc.

More specifically, the reference light control device according to the present invention, between the second annular mirror 126 provided on the lower surface of the disk 146, and the conical mirror 122 installed at a position away from and aligned with each other It consists of a first annular mirror (124) provided in.

The first annular mirror 124 is disposed around the conical mirror 122 and reflects the reference light reflected by the conical mirror 122 to provide the reflective surface of the second annular mirror 126.

That is, in the reference light adjusting device of the present invention, when the reference light diameter is r ₂ -r ₁ , the reference light r ₂ (solid line) reflected from the inside of the conical mirror 122 is reflected by the first annular mirror 124. Reflected from the reflective surface of the first annular mirror 124 is transmitted to the reflective surface of the second annular mirror 126 on top. Accordingly, the reference light r ₂ (solid line) reflected from the inside of the second annular mirror 126 is transmitted to the inside of the disk 146. The inner side of the conical mirror 122 is far from the disk 146 and has a small circumferential size, and the outer side of the conical mirror 122 is close to the disk 146 and has a large circumferential size.

At the same time, the reference light r ₁ (dotted line) reflected from the outer inclined surface of the conical mirror 122 is reflected by the first annular mirror 124. In this case, the reference light r ₁ (dashed line) is reflected at a high point of the first annular mirror 124, for example, while the reference light r ₂ (solid line) reflected from the inside of the conical mirror 122 is the first annular mirror ( 124 can be reflected at the middle height. The reference light r ₁ (dotted line) reflected from the reflecting surface of the first annular mirror 124 is transmitted to the upper reflecting surface of the second annular mirror 126 on the upper side. Accordingly, the reference light r ₁ (dotted line) reflected from the upper end of the second annular mirror 126 is transmitted to the outside of the disk.

Accordingly, the reference light adjusting device according to the present invention adjusts the reference light path between the conical mirror 122 and the first and second annular mirrors 124 and 126 so that the reference light r ₂ reflected from the inside of the conical mirror 122 is adjusted. Is transmitted through the lower end of the second annular mirror 126 to the inside of the disk 146, and the reference light r ₁ reflected from the outside of the conical mirror 122 is transmitted through the upper end of the second annular mirror 126. By passing out of 146, the reference lights r ₁ , r ₂ of the conical mirror 122 are increased to the disk 146 at the same light intensity magnification. That is, since the reference light reflected from the inside and the outside of the inclined surface of the conical mirror 122 is increased at the same magnification inside and outside the disc 146, the holographic data is accurately recorded as the uniform reference light is irradiated on the entire disc 146. can do.

At this time, the inner surface of the first annular mirror 124 is characterized in that the inclined angle (θ) relative to the disk 146.

That is, in the present embodiment, the inclination of the inner reflective surface of the first annular mirror 124 is not overwritten without changing the conical mirror by changing the angle of meeting the signal light by changing the side inclination angle of the conical mirror as in the prior art. Implemented multiple overlapping recording by changing the angle.

The reason for changing the reference light reflection angle of the inner reflective surface of the first annular mirror 124 rather than the inclined surface of the conical mirror is that replacing the annular mirror rather than replacing the conical mirror for multiple overlapping recordings is the replacement time. Because it is also faster and much easier.

On the other hand, the second annular mirror 126 to be applied to the present embodiment is characterized in that it is formed longer than a predetermined length than the first annular mirror 124. The length of this second annular mirror 126 is preferably such that it can sufficiently cover the reflection angle which is changed through the first annular mirror 124.

In addition, the second annular mirror 126 applied to the present embodiment may be implemented to be able to move up and down while having the same length as the first annular mirror 124. The up / down moving range of the second annular mirror 126 is preferably a moving range sufficient to cover the reflection angle which is changed through the first annular mirror 124.

4 is a block diagram illustrating a holographic ROM recording apparatus having a reference light adjusting device according to the present invention.

Referring to FIG. 4, a holographic ROM recording apparatus according to the present invention includes a light source 100, mirrors 104, 118, 130, and 136, a beam splitter 112, a first conical mirror 122, and an annular shape. And a reference light adjusting device having a mirror 124 and a prism 126, a second conical mirror 128, a data mask 144, a disk 146 as a recording medium, and the like. 102 denotes a shutter, and 106, 114, and 132 denote HWP. 108, 120 and 138 represent spatial filters, 110 and 140 represent magnification lenses, and 116 and 134 represent polarizers.

The laser light of the light source 100 is a type of linear polarized light, for example, P-type or S-type polarized light and is transmitted to the mirror 104 through the opening of the shutter 102.

The laser light reflected by the mirror 104 is transmitted to the beam splitter 112 through the HWP 106 to the magnifying lens 110.

The beam splitter 112 transmits and reflects the laser light of the magnifying lens 110 as it is and splits into two light paths S1 and S2.

The signal light path of S1 traveling from the beam splitter 112 to the magnifying lens 110 passes through the signal light reflected through the mirror 130 through the HWP 132 and the polarizer 134 to the other mirror 136. And reflects the signal light from the mirror 136 to the spatial filter 138.

The spatial filter 138 removes incomplete polarization components of the signal light and transmits only purely polarized light components, and the signal light transmitted through the spatial filter 138 is enlarged to a predetermined size through the magnifying lens 140 and then the data mask 144. Is converted into data signal light and irradiated to the upper surface of the disk 146 which is a recording medium.

The reference light path of S2 traveling from the beam splitter 112 to the second annular mirror 126 is a reference light path sequentially passed through the HWP 114 and the polarizer 116 to the spatial filter 120 through the mirror 118. Reflecting and removing the incomplete polarization component of the reference light in the spatial filter 120 to transmit only the pure polarization component.

The reference light transmitted through the spatial filter 120 is irradiated onto the inclined surface of the conical mirror 122, is reflected at a predetermined angle through the inclined surface of the conical mirror 122, and is transmitted to the first annular mirror 124 of the reference light adjusting device. .

The inner reflective surface of the first annular mirror 124 in the reference light adjusting device is formed to be inclined at an angle with respect to the disk 146 as described above, and the reference light reflected through the inclined surface is second annular mirror 126. Is reflected to the reflective surface.

The reflective surface of the second annular mirror 126 reflects the reference light r ₂ reflected inside the inclined surface of the conical mirror 122 at the lower reflective surface, and the reference light r ₁ reflected from the outside of the inclined surface of the conical mirror 122 is obtained. Reflect from the top reflective surface.

The reflected reference lights r ₁ and r ₂ are irradiated to the lower surface of the disk 146.

The disk 146 has a holographic image in which the data signal light passing through the data mask 144 on the upper surface and the reference light reflected by the second annular mirror 126 on the lower surface of the disk 146 interfere with each other in the internal recording material layer. The data is recorded.

The recording apparatus of the present invention configured as described above has a reference light path controlled by a reference light control device having one conical mirror 122 and two annular mirrors 124 and 126, thereby making the entire reference light intensity of the disk 146 conical. The same magnification is increased for the entire inclined surface of the curl mirror 122. Therefore, the holographic data can be accurately recorded by the reference light intensity uniformly irradiated on the entire disk 146.

Further, by adjusting the inclination angle of the inner reflective surface of the first annular mirror 124 to adjust the reference light reflection angle, multiple superimposition recording is possible without changing the angle of the inclined surface of the conical mirror.

5A and 5B are diagrams showing that the reference light reflected through the conical mirror is irradiated onto the disc according to the prior art and the present invention, respectively.

Referring to Fig. 5A, in the recording apparatus of the conventional holographic ROM, the reference light reflected from the inside of the inclined surface R1 of the conical mirror is outside the disk R4, and from the outside of the inclined surface R2 of the conical mirror. The reflected reference light is irradiated to the inside R3 of the disc.

However, referring to FIG. 5B, in the holographic ROM recording apparatus according to the present invention, the inside of the inclined surface R10 of the conical mirror 122 directly under the disk 146 by the first and second annular mirrors 124 and 126. It can be seen that the reference light reflected at is irradiated to the inner side R12 of the disc, and the reference light reflected at the outer side R11 of the conical mirror 122 is irradiated to the outer side R13 of the disc.

Accordingly, in the holographic ROM recording apparatus according to the present invention, since the reference light reflected from the inside and the outside of the inclined surface of the conical mirror is transmitted to the inside and the outside of the disk as it is, the reference light reflected from the conical mirror is It is increased at the same magnification with respect to the whole disc and becomes uniform with reference light intensity in the whole disc area. Further, by adjusting the inclination angle of the inner reflection surface of the annular mirror to adjust the reference light reflection angle, multiple superimposition recording is possible without changing the angle of the inclination surface of the conical mirror.

Meanwhile, the present invention is not limited to the above-described embodiments, and various modifications may be made by those skilled in the art within the spirit and scope of the present invention described in the claims below.

As described above, the present invention adds an annular mirror instead of an expensive conical mirror and adjusts the reference light path transmitted from the conical mirror to the lower surface of the disk as a recording medium to make the reference light intensity irradiated onto the disk uniform. Reduce system development costs. In addition, the present invention allows multiple overlapping recording by changing the inclination angle of the inner reflection surface of the annular mirror and adjusting the reference light reflection angle without changing the angle of the inclined surface of the conical mirror in comparison with the prior art, thereby overlapping recording of data of different angles. The replacement time is shortened and the replacement is easy.

Claims (9)

A holographic ROM recording apparatus for recording holographic data on a recording medium, A beam splitter separating the signal light and the reference light from the laser light incident from the light source; A data mask for converting the signal light transmitted from the beam splitter into data signal light according to the bit pattern of the holographic data and transmitting it to the upper surface of the recording medium; A conical mirror that reflects the reference light transmitted from the beam splitter through a mirror slope; A first annular mirror for adjusting the path of the reference light reflected from the conical mirror by allowing the inclination of the inner surface relative to the recording medium; A second annular mirror fabricated longer than the first annular mirror and reflecting the reference light transmitted from the first annular mirror to the lower surface of the recording medium; The reference light reflected from the inside of the inclined surface of the conical mirror is transmitted to the inside of the recording medium through the first annular mirror and the second annular mirror, and the reference light reflected from the outside of the inclined surface of the conical mirror is Holographic ROM recorder transmitted outward. The method of claim 1, And the first and second annular mirrors are disposed at a predetermined distance and aligned with each other. The method according to claim 1 or 2, And the first and second annular mirrors are reference light adjusting means. A method of adjusting a reference light path in a recording device of a holographic ROM which irradiates data signals and reference light transmitted through a bit pattern of holographic data of a data mask to record holographic data by interference between these lights. , Irradiating the reference light to a conical mirror positioned below the recording medium and reflecting it through a mirror inclined surface; Reflecting the reference light reflected by the conical mirror back at a predetermined angle through the first annular mirror having a predetermined slope; Reflecting the reflected reference light to a reflecting surface of a second annular mirror positioned below the recording medium; The reference light reflected from the inside of the inclined surface of the conical mirror through the reflective surface of the second annular mirror is given to the inside of the recording medium, and the reference light reflected from the outside of the inclined surface of the conical mirror is given straight outward of the recording medium. Passing step Method of adjusting the reference light in the recording device of the holographic ROM comprising a. The method of claim 4, wherein The reflective surface of the second annular mirror reflects the reference light reflected from the inside of the inclined surface of the conical mirror at the bottom reflective surface, and reflects the reference light reflected from the outside of the inclined surface of the conical mirror at the upper reflective surface. Method for adjusting reference light in recording device of holographic ROM. The method of claim 4, wherein And the second annular mirror is formed to be longer than a predetermined length compared to the first annular mirror. The method of claim 6, And said predetermined length is a length that can accommodate a reflection angle that is changed through said first annular mirror. The method of claim 4, wherein And the second annular mirror is movable up and down while having the same length as that of the first annular mirror. The method of claim 8, The up / down moving range of the second annular mirror is a moving range capable of covering a reflection angle which is changed through the first annular mirror.

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