KR100626957B1 - Pickup device on the holographic digital data system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reproduction apparatus of a holographic digital data system, and more particularly, to a rotation mirror that reflects reference light at a predetermined angle and enters the storage medium, and partially reflects and reflects the reference light transmitted through the storage medium to provide the storage medium. And a second servo system which detects another part of the reference light and converts it into an electrical signal, and is installed at the front of the storage medium and reflects the reproduction light when the data recorded on the storage medium is reproduced by the reference light transmitted from the servo system. An optical separator, a CCD for converting the regenerated light reflected by the second optical separator into electrical data, and installed between the storage medium and the rotation mirror to reflect the reference light transmitted through the storage medium by changing the polarization in the servo system, and rotating A third optical splitter that transmits the reference light reflected by the mirror and a reference light reflected by the third optical splitter A second optical sensing unit converting and outputting a miracle signal, a control unit outputting a control signal for controlling the servo system using the electrical signal values output from the second optical sensing unit and the servo system, and a servo system based on the control signal. It includes a drive system for controlling to reflect the reference light incident on the servo system at the same angle as the reference light at the time of recording.

Description

Playback device of holographic digital data system {PICKUP DEVICE ON THE HOLOGRAPHIC DIGITAL DATA SYSTEM}

1 is a block diagram showing a playback apparatus of a holographic digital data system according to the prior art;

2 is a block diagram showing a reproduction device of a holographic digital data system according to the present invention;

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

100 light source 104 first light separator

108: spatial light modulator (SLM) 110: second optical splitter

114: first mirror 118: rotating mirror

120: third optical separator 122: storage medium

124: servo system 126: second light detecting unit

128: drive system 130: control unit

134: CCD

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a holographic digital data storage system (HDDS), and in particular, facilitates optical pickup and alignment of storage media, as well as reproduction of a holographic digital data system capable of servo control. Relates to a device.

Currently, technologies for storing holographic digital data are being actively researched in various fields, for example, thanks to remarkable developments such as semiconductor lasers, charge coupled devices (CCDs), and liquid crystal displays (LCDs). As a result, fingerprint recognition systems for storing and reproducing fingerprints have been put to practical use, and are being expanded to various fields that can apply the advantages of large storage capacity and ultra-fast data transfer speed. Among them, a holographic digital data system storing a large amount of data is a storage medium, for example, optical refraction, in which an interference fringe generated when the signal light from a target object and a reference light are interfered with each other is sensitive to the amplitude of the interference fringe. By recording to a storage medium such as a photorefractive crystal, it is possible to display a three-dimensional image of an object, and also to display hundreds to thousands of hologram data composed of pages of binary data. Can be stored in place.

1 is a block diagram showing a playback apparatus of a holographic digital data system according to the prior art.

Referring to FIG. 1, a reproducing apparatus of a conventional holographic digital data system divides a light source 10 generating a laser light and a light generated from the light source 10 into a reference beam and a signal beam path. A beam splitter 16, a mirror 22 reflecting the light separated by the light splitter 16, and an angle of the light reflected from the mirror 22 to the storage medium 28 by converting the light splitter 16. Spatial light modulator (SLM) which converts the input data, that is, binary data of a plurality of pixels, configured in units of pages into the light separated by the rotating mirror 26 and the optical separator 16 provided as reference light and converts the signal into a signal light (SLM) The interference fringe generated by the interference of the signal light output from the modulator 18 and the spatial light modulator (SLM) 18 and the reference light reflected from the rotation mirror 26 is recorded and diffracted by the interference fringe recorded by the irradiation of the reference light. Output storage 28, storage And a CCD 32 or the like which irradiates only the reference light to the medium 28 to reproduce a one-page binary pixel data image recorded in the form of an interference fringe, and converts the reproduced data image into electrical data for output. Unexplained reference numeral 12 denotes an optical magnifying lens, 24 a retardation lens, and 20 and 30 denote Fourier lenses.

The holographic digital data system configured as described above performs recording and playback operations as follows.

First, in the recording operation, laser light (for example, 532 nm wavelength laser light) generated by the light source 10 is transmitted to the optical separator 16 through the optical magnifying lens 12, and the optical separator 16 uses two light beams. In order to branch, the horizontally incident P polarized light is transmitted as it is and the vertically incident S polarized light is reflected.

The P-polarized light transmitted by the optical separator 16 as it is is input to the spatial light modulator (SLM) 18 and modulated by the signal light Sobj. That is, the signal light Sobj is modulated in units of one page of the binary data of the contrast made by the actual pixels by the data input to the spatial light modulator SLM 18, and then the storage medium 28 is applied through the Fourier lens 20. ) Is incident.

The S-polarized light reflected by the optical separator 16 is reflected by the mirror 22, converted into λ / 2 by a polarization converter (not shown), converted into P-polarized light, and passed through the retardation lens 24. The rotation mirror 26 is incident on the storage medium 28 as a reference light Sref having an angle equal to the preset recording angle. That is, the P-polarized light of the reference light Sref at which the angle of the rotating mirror 26 is changed in correspondence with each stored page is incident on the optical disk which is the storage medium 28.

The P-polarized light of the signal light Sobj and the P-polarized light of the reference light Sobj cause interference inside an optical disk, which is a storage medium 28 for recording holographic digital data, and according to the intensity of the interference fringe generated at this time, the storage medium 28 Light-induced generation of mobile charge is generated in the recording material layer of C1) to record an interference fringe.

On the other hand, the operation for reproducing the data recorded in the storage medium 28 is as follows. A shutter (not shown) positioned in the path of the signal light Sobj blocks P polarization of the signal light transmitted from the optical separator 16.

The S-polarized light reflected by the optical separator 16 is reflected by the mirror 22, converted into λ / 2 by a polarization converter (not shown), converted into P-polarized light, and passed through the retardation lens 24. The rotation mirror 26 is incident on the storage medium 28 as a reference light Sref having an angle equal to the preset recording angle.

When only the P-polarized light of the reference light Sref is irradiated to the storage medium 28 without the signal light Sobj, a one-page binary pixel data image (i.e., composed of original pixel contrast in the storage medium 28 in which interference data is recorded) , Checkerboard pattern) is played.

The binary pixel data image (one page unit) Sread reproduced from the storage medium 28 is transferred through the Fourier lens 30 through the CCD 32, and the CCD 32 reproduces the reproduced data image Sread. Is converted into an electrical data signal, and the converted data is restored to the original data through an image signal processing unit, a decoder, and the like.

However, in the reproducing apparatus of the conventional holographic digital data system, an optical apparatus for reproducing data recorded on the storage medium 28, for example, a Fourier lens 30, a mirror (not shown), and The CCD 32 is located behind the storage medium 28. In other words, the optical device to which the reference light Sref and the signal light Sobj are incident exists in front of the storage medium 28, but the optical devices 30 and 32 that emit the reproduced light Sread from the storage medium 28. Is located behind the storage medium 28, so when moving these devices, the alignment for the optical pickup before and after the storage medium 28 has been problematic.

An object of the present invention is to solve the problems of the prior art, the present invention is to place the position of the Fourier lens and the CCD, which is an optical device for optical reproduction located behind the storage medium in front of the storage medium, and the data storage medium The present invention provides a reproducing apparatus of a holographic digital data system capable of improving data reproduction efficiency by controlling the reference light output from the rear servo system to be incident on the storage medium at the same angle during recording.

According to an aspect of the present invention, there is provided an apparatus for reproducing recorded data by injecting reference light into a storage medium of a holographic digital data system, the apparatus comprising: a rotating mirror reflecting the reference light at an angle and entering the storage medium; A servo system that polarizes and reflects a part of the reference light transmitted through the storage medium to provide the storage medium, and detects and converts another part of the reference light into an electrical signal; A second optical splitter for reflecting the reproduction light when the data recorded on the storage medium is reproduced by the reference light transmitted from the optical signal; a CCD for converting the reproduction light reflected by the second optical splitter into electrical data; Installed between the storage medium and the rotating mirror to change the polarization in the servo system so that the storage medium A third optical splitter which reflects the reference light transmitted through the second optical beam, and transmits the reference light reflected by the rotating mirror, and a second light detector which detects the reference light reflected by the third optical splitter and converts the reference light into an electrical signal; A control unit for outputting a control signal for controlling the servo system by using the electrical signal value output from the second light sensing unit and the servo system, and controlling the servo system based on the control signal to equal the angle of the reference light when recording. And a driving system for controlling the reference light incident on the servo system to be reflected at an angle.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

2 is a block diagram showing a playback apparatus of a holographic digital data system according to the present invention.

Referring to FIG. 2, a reproducing apparatus of a holographic digital data system according to the present invention includes a light source 100, a first light separator 104, a spatial light modulator (SLM) 108, a second light separator 110, The first mirror 114, the rotating mirror 118, the third optical splitter 120, the storage medium 122, the servo system 124, the second optical sensor 126, the drive system 128, the controller 130 ) And the CCD 134 or the like. Unexplained reference numeral 102 denotes an optical magnification lens, 106 denotes a shutter, 116 denotes a retardation lens, and 112 and 132 denote Fourier lenses.

The first light separator 104 splits the laser light generated from the light source 100 (for example, a laser light having a wavelength of 532 nm) into two lights when the light is incident through the light magnifying lens 102. It transmits as it is and reflects the S-polarized light incident vertically.

The second light separator 110 reflects the S-polarized light of the reproduction light Sread reproduced in the storage medium 122 by the reference light output from the servo system 124 and sends it to the CCD 134.

The first mirror 114 reflects the S-polarized light separated by the first light splitter 104 and converts it into λ / 2 by a polarization converter (not shown) to rotate the mirror through the delay lens 116 to P-polarized light ( 118).

The rotation mirror 118 adjusts the angle for injecting the P-polarized light transmitted through the retardation lens 116 into the storage medium 122 and provides it to the storage medium 122 through the third optical separator 120 as reference light. . The rotation mirror 118 rotates the mirror surface at the same angle as a preset recording angle corresponding to each page data stored in the storage medium 122.

The storage medium 122 transmits the P-polarized light of the reference light Sref transmitted from the rotation mirror 118 to the servo system 124 as it is, and provides the S-polarized light of the reference light Sref incident from the servo system 124. The reproduced light Sread is transmitted to the second optical splitter 110 after diffracting and reproducing the interference fringe recorded by the second optical splitter 110. At this time, the storage medium 122 outputs the regenerated light reproduced by the reference light Sref provided through the third optical splitter 120 to the opposite direction of the second optical splitter 110, that is, to the outside.

The servo system 124 polarizes the reference light Sref transmitted through the storage medium 122 and the reference light Sref reflected by the servo system 124 and outputs the polarized light by the polarization converter 124a and the polarization converter 124a. A part of the converted reference light is reflected back to the polarization converting unit 124a, and the half mirror 124b for transmitting the other part and the other part of the reference light passing through the half mirror 124b are detected and converted into an electrical signal. The first light sensing unit 124c is configured.

The polarization converter 124a is composed of a λ / 4 plate and converts the P polarization of the reference light Sref transmitted through the storage medium 122 into λ / 4 to convert it to circular polarization, and converts the converted circular polarization to the half mirror 124b. To pass). In addition, the circularly polarized light of some reference light Sref transmitted from the half mirror 124b is converted into λ / 4 to be converted into S-polarized light, and the converted S-polarized light is transmitted to the storage medium 122.

Here, the servo system 124 should reflect the reference light Sref to be provided to the storage medium 122 so as to match the path of the reference light Sref passing through the storage medium 122. When the 124 is twisted due to an external impact, that is, when the half mirror 124b is twisted, it is provided to the storage medium 122 differently from the path of the incident reference light. When the half mirror 124b is reflected and provided to the storage medium 122 differently from the path of the incident reference light, the storage medium 122 does not generate reproduction light or decrease the reproduction efficiency. For this reason, the angle and position adjustment of the half mirror 124b is necessary.

To this end, the servo system 124 is connected to the drive system 128, and the controller 130 controls the drive system 128 to move or rotate the half mirror 124b to the left and right.

The first light detecting unit 124c is composed of two divided photodiodes. The first light detecting unit 124c detects reference light in each divided area, converts the reference light into an electrical signal, and outputs it to the control unit 130. The control unit 130 is output from each photodiode. A control signal for controlling the drive system 128 is output by using the difference of the electrical signal values.

In this case, the reference light Sref provided from the polarization converting unit 124a of the servo system 124 passes through the storage medium 122 and is provided to the third optical separator 120, and is provided to the third optical separator 120. Since the reference light Sref has P polarized light, the reference light Sref is reflected by the third light separator 120 and provided to the second light detector 126.

The second light detector 126 is composed of a two-divided photodiode, and detects the reference light provided through the third optical splitter 120 in each divided region, converts the reference light into an electrical signal, and outputs it to the controller 130. 130 outputs a control signal for controlling the drive system 128 by using a difference between electrical signal values output from each photodiode.

The drive system 128 is connected to the half mirror 124b and rotates the half mirror 124b in response to a control signal provided based on an electrical signal output from the second light sensing unit 126 to the half mirror 124b. The second actuator 128b for adjusting the angle of the reflected reference light Sref and the half mirror 124b of the servo system 124 are provided based on an electrical signal output from the first light detector 124c. The first actuator 128a adjusts an incidence position of the reference light Sref reflected by the half mirror 124b by moving the position of the half mirror 124b from side to side in response to the control signal.

The CCD 134 irradiates only the reference light to the storage medium 122, and when the one-page binary pixel data image recorded in the form of an interference fringe is reproduced, the CCD 134 is transmitted through the storage medium 122 and the second light separator 110. The reproduced light Sread is converted into electrical data and output.

The reproduction apparatus of the holographic digital data system configured as described above operates as follows.

First, laser light (for example, laser light of 532 nm wavelength) generated in the light source 100 is transmitted to the first light separator 104 through the light magnifying lens 102, and the two light beams are provided in the first light separator 104. The light beam is branched into the light beam, and the horizontally incident P polarized light is transmitted as it is and the vertically incident S polarized light is reflected.

The P-polarized light transmitted by the first light separator 104 as it is is blocked by the shutter 106, and the S polarized light reflected by the first light separator 104 is reflected by the first mirror 114. The S-polarized light reflected by the first mirror 114 is converted into [lambda] / 2 by a polarization converter (not shown) and passed through the retardation lens 116 with P-polarized light, and then the recording preset by the rotating mirror 118. The reference light Sref having an angle equal to the viewing angle is incident on the storage medium 122 through the third light separator 120.

When only the P polarization of the reference light Sref is irradiated to the storage medium 122 while the signal light Sobj is blocked by the shutter 106, the P polarization of the reference light Sref irradiated to the storage medium 122 is transmitted as it is. Is transmitted to the polarization converter 124a of the servo system 124.

In the polarization converter 124a, P polarized light of the reference light Sref is converted by? / 4 to circularly polarized light. The half mirror 124b reflects a part of the circularly polarized light of the polarization converter 124a and transmits it to the polarization converter 124a, and transmits the other part to the first light detector 124c.

The polarization converter 124a converts the circularly polarized light reflected by the half mirror 124b by λ / 4 to convert it to S-polarized light and transmits the converted S-polarized light to the storage medium 122.

The storage medium 122 is a one-page binary pixel data image composed of original pixel contrast in the storage medium 122 in which interference data is recorded when S polarization of the reference light Sref transmitted from the polarization converter 124a is incident. The reproduction light Sread having the checkerboard pattern (that is, the checkerboard pattern) is output and transmitted to the second optical separator 110.

On the other hand, the S polarization of the reference light Sref transmitted to the storage medium 122 is transmitted to the storage medium 122 and provided to the third optical separator 120, where the S polarization of the reference light Sref is the third light. The light is reflected by the light separator 120 and transmitted to the second light detector 126. The second light detector 126 detects the reference light Sref reflected by the third light splitter 120, converts the reference light into an electrical signal, and provides the converted light to the controller 132.

Here, when the reference light Sref transmitted from the polarization converter 124a is not incident on the storage medium 122 at an angle that is 180 degrees different from the recording time, that is, when the half mirror 124b is distorted, the storage medium 122 ) Does not output reproduced light. In this case, the half mirror 124 of the servo system 124 needs to be corrected.

Referring to the correction process of the half mirror 124b, the control unit 130 provides and drives the control signal to the first actuator 128a based on the electrical signal value transmitted from the first light sensing unit 124c. The position of the half mirror 124b is corrected. On the other hand, the controller 132 supplies and drives a control signal to the second actuator 128b based on the electrical signal value transmitted from the second light sensing unit 126, so that the angle of the half mirror 124b is adjusted. Calibrated.

By performing this correction, the reference light Sref reflected by the half mirror 124b is incident on the storage medium 122 at the same angle as the incident angle at the time of recording.

The second light separator 110 reflects the P-polarized light of the reproduced light Sread transmitted through the storage medium 122 and transmits the P-polarized light to the CCD 134 through the Fourier lens 132.

The CCD 134 converts a read light having a one-page binary pixel data image of the storage medium 122 transferred through the second optical splitter 110 into electrical data, and the converted data is not present. The original data is restored through the illustrated video signal processor and decoder.

As described above, according to the present invention, the position of the Fourier lens and the CCD, which are optical reproducing optical devices located behind the storage medium, is positioned in front of the storage medium, and the reference light output from the servo system behind the storage medium is recorded at the recording time. By controlling the incident to the storage medium so that the difference is always 180 degrees, not only can the data reproduction efficiency be improved, but also the real-time servo control effect can be obtained.

In addition, the present invention eliminates the need for adjusting the positions of the optical devices located in front of the optical disk as the storage medium and the Fourier lens and CCD located in the rear by installing a second optical separator in front of the storage medium. Can make phosphorus easier.

In addition, the present invention has the advantage that it is easy to move the system can be configured as a set of a new optical device installed in the front end of the storage medium.

On the other hand, the present invention is not limited to the above-described embodiment, various modifications are possible by those skilled in the art within the spirit and scope of the present invention described in the claims to be described later.

Claims (10)

An apparatus for reproducing recorded data by injecting reference light into a storage medium of a holographic digital data system, A rotation mirror which reflects the reference light at a predetermined angle and enters the storage medium; A servo system that polarizes and reflects a part of the reference light transmitted through the storage medium to provide it to the storage medium, and detects and converts another part of the reference light into an electrical signal; A second optical separator installed at the front end of the storage medium and reflecting the reproduction light when the data recorded on the storage medium is reproduced by the reference light transmitted from the servo system; A CCD for converting the reproduced light reflected by the second optical separator into electrical data; A third optical splitter disposed between the storage medium and the rotation mirror to reflect the reference light transmitted through the storage medium by changing polarization in the servo system, and transmitting the reference light reflected by the rotation mirror; A second light detector which detects the reference light reflected by the third light separator and converts the reference light into an electrical signal; A control unit for outputting a control signal for controlling the servo system by using the electrical signal value output from the second light sensing unit and the servo system; The drive system controls the servo system based on the control signal to control the reference light incident on the servo system to be reflected at an angle equal to the angle of the reference light during recording. Playback device of the holographic digital data system comprising a. The method of claim 1, The servo system, A polarization converting unit configured to polarize the reference light transmitted through the storage medium and some reference light reflected from the servo system; A half mirror which reflects a part of the reference light converted by the polarization converting part to the polarization converting part again and transmits another part; A first light detector configured to detect and convert the other part of the reference light into an electrical signal Playback device of the holographic digital data system comprising a. The method of claim 2, And the polarization converting unit comprises a λ / 4 plate. The method of claim 2, The first light detector is a two-part photodiode, and each of the photodiodes senses the reference light and converts it into an electrical signal and outputs the holographic digital data system. The method of claim 4, wherein And the controller is configured to adjust the position of the half mirror by providing a control signal to the driving system based on the electrical signal output from the first light sensor. The method of claim 2, The drive system, A first actuator for moving the half mirror from side to side to adjust an incident position of the reference light; And a second actuator for rotating the half mirror to adjust a reflection angle of the reference light. The method of claim 2, The second light detector is a two-part photodiode, and each photodiode detects the reference light reflected by the third optical splitter and converts the reference light into an electrical signal and outputs the converted electrical signal. . The method of claim 7, wherein And the control unit adjusts an angle of the half mirror by providing a control signal to the driving system based on the electrical signal output from the second light sensing unit. The method of claim 1. And a Fourier lens between the second optical splitter and the storage medium. The method of claim 1, And a Fourier lens between the second optical splitter and the CCD.

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