KR200325224Y1 - Reference light incident angle control device of holographic data storage system - Google Patents

Abstract

The present invention relates to a reference light incident angle adjusting device for finely adjusting the angle of incidence of the reference light in the holographic data storage system.

To this end, the present invention provides a mirror 30 for changing the incident angle at which the reference light incident from the light source 10 is incident to the storage medium 60, a substrate 31 for supporting the mirror 30, and the mirror 30. A positive electrode (41) and a negative electrode (42) are formed at a lower end of one side and a fixing device (32) for fixing one side end of the mirror (30), respectively at both ends, and the positive electrode ( A piezoelectric element 43 whose length is changed according to the magnitude of the voltage input between the negative electrode 42 and the negative electrode 42 is formed, and is provided on the other end of the mirror 30 and the other end of the substrate 31. 40, and inputs to the positive electrode 41 and the negative electrode 42 of the moving hole 40 to change the incidence angle of the reference light reflected through the mirror 30 by changing the length of the piezoelectric element 43. It consists of a voltage regulator 50 to adjust the voltage to be.

Therefore, the present invention adjusts the angle of incidence of the reference light according to the intensity of the applied voltage, so that mechanical problems and frequency change characteristics of the AOD do not occur, and since the variation of the voltage of the piezoelectric element is very small, the fine angle of the reference light becomes possible. Simple configuration makes production easy.

Description

REFERENCE BEAM INCIDENCE ANGLE ADJUSTING DEVICE FOR HOLOGRAPHIC DATA STORAGE SYSTEM

The present invention relates to a reference light incident angle adjusting device for finely adjusting the angle of incidence of the reference light in the holographic data storage system.

In general, a holographic data storage system aims to record object light from an object and later reproduce it.

Holographic data recording is achieved by recording the intensity and direction of the object light reflected from the object. The intensity and direction of the light of the object is composed of the interference between the object light and the reference light to form an interference fringe, and the interference fringe is formed in a cube, that is, a storage crystal, made of a material that responds to the intensity of the interference fringe. When the reference light is irradiated to the recorded interference fringe, the hologram, which is a three-dimensional image of the object, is reproduced.

At this time, the hologram data recorded in the storage crystal can only be read by the reference light used in the recording process, and the hologram data recorded in the storage crystal can not be read by the reference light having a different wavelength or phase from the reference light used in the recording process. Done.

By using this volume hologram property, a large amount of hologram data can be stored in a small cube by recording a lot of hologram data in the same place of a storage material cube with different reference light.

The commonly used angular multiplexing technique is to change the angle of the reference light at each recording time to create different reference light, which allows hundreds to thousands of holograms to form binary data in pages. Can be stored in the same place That is, by recording and reproducing a lot of data in the unit of a page in the same place, it is possible to record and reproduce with high storage density and fast data transfer rate.

This general holographic data storage system is installed in a position corresponding to the light source 10 and the light source 10 for generating a coherent beam, that is, a laser beam, required for holography, as schematically shown in FIG. 1. Beam splitter 20 which separates the coherent light generated from the light source 10 into a reference beam and a signal beam, that is, an object beam, and is positioned on an optical path of the reference beam. Rotation mirror 30 for converting a small amount of light, a mirror 40 for changing the direction of the object light, is located on the optical path of the object light reflected from the mirror 40 and composed of input data, i.e. Spatial Light Modulator (SLM) 50, which carries binary data of a plurality of pixels, and light in which an object light output from the SLM 50 and the reference light reflected from the rotating mirror 30 cross each other. A storage medium 60 which is positioned on the recording medium and records the interference fringe generated by the interference of the object light and the reference light and restores and outputs the interference fringe recorded by the irradiation of the reference light, and occurs when the storage medium 60 is irradiated with the reference light. It is located on the optical path of the interference fringe to be made of a charge coupled device (CCD) 70 for converting the interference fringe recorded in the storage medium 60 to the original electrical signal.

The operation of the general holographic data storage system configured as described above will be described.

The coherent light irradiated from the light source 10 is divided into the reference light and the object light in the optical separator 20.

In this case, the object light is inputted to the spatial light modulator 50 and modulated by the mirror 40 in a 90 ° direction. That is, the object light is incident on the storage medium 60 after data input from the spatial light modulator 50 is modulated in units of one page of binary data of light and shade.

In addition, the reference light is incident on the storage medium 60 by changing the angle by the rotating mirror 30. That is, the reference light which slightly changes the angle of the rotating mirror 30 corresponding to each page is incident on the storage crystal which is the storage medium 60.

The object light and the reference light cause interference inside the storage medium 60 for recording the hologram, and light-induced generation of mobile charge of the internal kinetic charge of the storage medium 60 according to the intensity of the interference fringes generated at this time. ) And the interference fringe is recorded through this process.

In order to read the data recorded in the storage medium 60, only the reference light needs to be irradiated to the storage medium 60. That is, when the reference light is irradiated, the interference fringe is diffracted by the reference light to restore the checkered pattern composed of the contrast of the original pixel, and then the read image is reflected on the CCD 70 to restore the original data.

In this way, after recording one page, a reference light having a slightly different angle of the rotating mirror 30 is applied to the next page. That is, the reference light is applied to each page according to the change of the angle of the rotating mirror 30. After recording the first page of data in the storage medium, the angle of the reference light is increased until the reproduction restoration image of the first hologram disappears completely. In this case, a new data page is inputted to the reference light of a different angle and recorded in the storage medium 60.

In other words, the process of changing the angle of the reference light every time each page is recorded by using the angular overlap technique is repeated to overwrite the data in the storage medium.

As described above, when the angle of the reference light is changed and recorded using the angle superposition technique, the same pattern of reference light at the same angle must be irradiated to the storage medium 60 to reproduce the checkered pattern consisting of the original pixel contrast. The image is restored to the original data by the CCD 70.

In order to overlap such angles, a conventional step motor is used. That is, the mirror 30 was attached to the step motor, and the step motor was rotated to change the optical path of the reference light. Conventional reference light incident angle adjusting device using such a step motor has a simple configuration and implementation, but must be mechanically rotated, so the adjustment speed is slow due to the response speed and the change angle cannot be finely adjusted, resulting in poor reliability.

In addition, conventionally, AOD (Acoust0-Optic Device) was used for angular overlap. In other words, the sound path was used to change the optical path of the reference light. In the conventional reference light incident angle adjusting device using the AOD, since the mechanical adjustment does not occur, a quick and accurate angle adjustment is possible, but a Doppler effect occurs to change the frequency of the reference light. Therefore, in the conventional reference light incident angle adjusting device using AOD, the AOD is also applied to the object light to correct the frequency change with the reference so that the same Doppler contour is generated so that the frequencies of the reference light and the object light are kept the same. As a result, the same apparatus must be provided for the object light to change the path of the reference light, thereby complicating the system. In addition, AOD does not exhibit ideal characteristics and has a problem of greatly reducing the light intensity and increasing the price of a system having a high price.

Accordingly, an object of the present invention is to provide a reference and incident angle adjusting device for changing a light path of a reference light by changing the angle of a mirror using a piezoelectric element whose length varies according to voltage intensity in a holographic data storage system. There is this.

In order to achieve the above object, the present invention provides a mirror for changing an incident angle at which a reference light incident from a light source is incident to a storage medium, a substrate supporting the mirror, a bottom of one side of the mirror, and a top of one side of the substrate, A fixture for fixing one end of the mirror and a positive electrode and a negative electrode are formed at both ends, respectively, and a piezoelectric element whose length is changed between the positive electrode and the negative electrode is formed to form a lower end of the mirror and the other side of the substrate. Hologram characterized in that it comprises a mobile device installed on the top, and a voltage regulator for controlling the voltage input to the positive electrode and the negative electrode of the mobile device to change the incident angle of the reference light reflected through the mirror by changing the length of the piezoelectric element A reference light incident angle adjusting device of a data storage system is provided.

1 is a configuration diagram of a holographic data storage system

2 is a structural diagram of a reference light incident angle adjusting device according to the present invention

3 is a state diagram using the reference light incident angle adjusting device according to the present invention

Explanation of symbols on the main parts of the drawings

10: light source 20: optical separator

30, 40: mirror 50: SLM

60: storage medium 70: CCD

31: substrate 32: fixture

40: moving port 41, 42: electrode

43: piezoelectric element 50: voltage regulator

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

The reference light incident angle adjusting device of the hologram data storage system according to the present invention includes a mirror 30, a substrate 31, a fixture 32, a moving tool 40, and a voltage regulator 50. do.

The mirror 30 changes the incident angle at which the reference light incident from the light source 10 is incident to the storage medium 60.

The substrate 31 supports the mirror 30.

The fastener 32 is installed at one lower end of the mirror 30 and one upper end of the substrate 31 to fix one end of the mirror 30.

The moving part 40 has a positive electrode 41 and a negative electrode 42 formed at both ends thereof, and the piezoelectric element 43 whose length is changed according to the magnitude of the voltage input between the positive electrode 41 and the negative electrode 42. Is formed is to be installed on the other bottom of the mirror 30 and the other top of the substrate 31.

The voltage regulator 50 changes the length of the piezoelectric element 43 to change the incident angle of the reference light reflected through the mirror 30, so that the positive electrode 41 and the negative electrode 42 of the moving hole 40 are changed. To adjust the voltage input to

The operation of the reference light incident angle adjusting device of the hologram data storage system constructed as described above will be described with reference to FIGS. 2 and 3.

As shown in FIG. 2, a substrate 31 is installed below the left and right sides of the mirror 30 to fix the mirror 30. In this case, a fixing tool 32 is installed at the lower left side of the mirror 30 and attached to the substrate 31, and a moving tool 40 is installed at the lower right side of the mirror 30 and attached to the substrate 31.

On the other hand, the moving port 40 is formed from a piezoelectric element (Piezoelectric) 43 and the positive electrode 41 and the negative electrode 42 are formed at both ends of the piezoelectric element 43, respectively, set from the voltage regulator 50. A voltage, that is, an angle adjusting voltage for adjusting the reference light incident angle is applied.

At this time, the piezoelectric element 43 has a property that its length is changed in proportion to the applied power supply voltage when power is applied at both ends.

Accordingly, when the voltage regulator 50 applies the power of a specific voltage, the applied power is applied to the positive electrode 41 and the negative electrode 42, so that the piezoelectric element 43 increases in length in proportion to the applied power voltage. do. At this time, the movable tool 40 is lengthened as a whole to lift one side, that is, the right side of the mirror (30). Therefore, the mirror 30 is inclined and the incident light of the reference light incident on the mirror 30 is changed.

In particular, since the length of the piezoelectric element is minutely increased according to the voltage, fine adjustment of the reference light incident angle is easy.

That is, in the case of piezoelectric ceramics, since 10 ^-12 m is increased per 1V, fine angle adjustment is possible according to the voltage applied from the voltage regulator 50.

Accordingly, angular overlap of the hologram data storage system can be smoothly performed.

As described above, the reference light incident angle adjusting device of the hologram data storage system according to the present invention has the following effects.

First, since the incident angle of the reference light is adjusted according to the intensity of the applied voltage, mechanical problems and frequency change characteristics of the AOD do not occur.

Second, since the variation with respect to the voltage of the piezoelectric element is very small, it is possible to finely adjust the angle of the reference light.

Third, the configuration is simple and easy to manufacture.

Fourth, the angular superposition of the hologram data storage system can be performed smoothly, and high capacity can be realized.

Fifth, it can be applied to optical storage media such as DVD, CD and most other systems using light.

Claims (1)

A mirror 30 for changing the incident angle at which the reference light incident from the light source 10 is incident to the storage medium 60; A substrate 31 supporting the mirror 30; A fixture (32) installed at one lower end of the mirror (30) and one upper end of the substrate (31) to fix one end of the mirror (30); A positive electrode 41 and a negative electrode 42 are formed at both ends, respectively, and a piezoelectric element 43 whose length is changed according to the magnitude of the voltage input between the positive electrode 41 and the negative electrode 42 is formed to form the mirror 30. A moving hole 40 installed at the lower end of the other side and the upper end of the other side of the substrate 31; And The voltage input to the positive electrode 41 and the negative electrode 42 of the moving tool 40 is changed to change the incident angle of the reference light reflected through the mirror 30 by changing the length of the piezoelectric element 43. Reference light incident angle adjusting device of the hologram data storage system, characterized in that consisting of a voltage regulator (50).