KR100536714B1 - Holographic rom system - Google Patents

Abstract

The holographic ROM system according to the present invention separates the reproduction light generated from the light source into the correction light and the reproduction reference light, and detects an incident angle of the recording reference light based on the incident angle of the correction light, and between the recording reference light and the reproduction reference light. By correcting the error incident angle in real time and reproducing the data by providing the reference light for reproduction to the recording medium, the diffraction efficiency of the reproduced signal light can be maximized to improve the signal-to-noise ratio as well as to improve the data reproduction reliability.

Description

Holographic ROM System {HOLOGRAPHIC ROM SYSTEM}

The present invention relates to a holographic ROM system, and more particularly, to a holographic ROM system capable of improving the signal-to-noise ratio of reproduction data.

In general, the reference light for reproduction used in data reproducing in the holographic ROM system should have the same angle of incidence as the reference light used for recording in order to obtain the maximum efficiency of the signal light output from the storage medium, that is, the holographic disc, during reproduction. As a result, the holographic ROM system can obtain a good signal-to-noise ratio.

In addition, the holographic ROM system reproduces by using a phase-conjugated reproduction technique when reproducing a holographic disc in which data is multiplexed and recorded in an angular superposition recording method.

Hereinafter, a holographic ROM system of the related art will be described with reference to FIG. 1. 1 is a structural diagram showing the structure of a holographic ROM system according to the prior art.

Referring to FIG. 1, the holographic ROM system includes a pickup unit 100, a disk 200, a motor 210, a signal processor 300, and a controller 400. Here, the disc 200 is a medium in which data recorded in an angular overlapping manner is stored, and is rotated by a motor 210 driven under the control of the controller 300 during reproduction.

The pickup unit 100 includes a first actuator 102, a light source 104, a light separator 106, a reflector 108, an aperture 110, an objective lens 112, a second actuator 114, and a light receiving unit. It consists of 116. At this time, the pickup unit 100 is connected to the first actuator 102 and moved, and the objective lens 112 is connected to the second actuator 114 and moved.

The light source 104 generates a reference light for reproduction and provides it to the light separator 106, and the light separator 106 reflects a part of the reference light for reproduction to enter the reflector 108. The reproduction reference light reflected by the optical separator 106 is deflected at a predetermined angle by the reflector 108 and is incident on the disk 200. The incident angle of the reproduction reference light incident on the disk 200 is the same as the incident angle of the recording reference light used at the time of recording.

In the disc 200, when the reproduction reference light deflected at a predetermined angle by the reflector 108 is irradiated, the recorded interference fringe diffracts the reproduction reference light to generate the reproduction signal light, and the reproduction signal light is the aperture 110 and It is provided to the optical separator 106 through the objective lens 112. The optical separator 106 reflects the signal signal for reproduction and provides it to the light receiving unit 116.

The reproduction signal light received by the light receiving unit 116 is processed and reproduced in a predetermined manner by the signal processing unit 300.

The holographic ROM system rotates the reflector 108 to reproduce data recorded at another angle from the disc 200 after the data is reproduced using the reference light for reproduction incident at any angle among the angularly superimposed recorded data. The position of the reflector 108 is changed by an actuator (not shown) to be driven to change the incident angle of the reproduction reference light.

By repeating the above process, the holographic ROM system reproduces the data recorded on the disc 200 in an angular overlapping manner.

In this case, in order to obtain the maximum output of the reproduction signal light, that is, the maximum diffraction efficiency, the incident angle of the reproduction reference light incident on the disc 200 should be the same as that of the recording reference light used when recording data on the disc 200.

However, when an incident angle of the reproduction reference light is changed due to external impact and malfunction, there is a problem that there is no corresponding incident angle correction means, so that the diffraction efficiency of the reproduction signal light is lowered and the reproduction diffraction efficiency is worsened.

SUMMARY OF THE INVENTION An object of the present invention is to solve such a problem of the prior art, by detecting an incident angle of a reference light for reproduction during reproduction of data recorded in an angular overlap method, and correcting the error incident angle by comparing it with the reference light for recording, thereby reproducing the reproduction. The present invention aims to provide a holographic ROM system capable of maximizing the diffraction efficiency of signal light to improve the signal-to-noise ratio as well as improving data reproduction reliability.

In order to achieve the above object, the present invention provides a holographic ROM system for reproducing a recording medium on which recording reference light provided at different incidence angles and interference fringes by signal light are recorded in an angular overlapping manner. A light source to be generated, a memory in which the incident angle information of the recording reference light is stored, a first optical splitter that transmits a part of the reproduction light to generate a reproduction reference light, and reflects another portion to generate correction light, and the correction A control provided between the reflector for deflecting the light at a predetermined angle, the second optical splitter for reflecting the reproduction reference light and the reproduction signal light provided from the recording medium in different directions, and the first and second optical splitters. A shutter that opens in accordance with a signal to provide the reproduction reference light to a second optical splitter, and the deflected correction light A double-sided reflector provided to the recording medium by deflecting the reference light for reproduction provided from the second optical splitter at the same incidence angle as the corrected light and provided to the recording medium; An actuator for changing the incident angle by moving the double-sided reflector according to a control signal, a position detector for detecting and providing position data of the correction light provided by the double-sided reflector, the positional data provided by the detector and the double-sided reflector and detector A control unit configured to calculate an incident angle of the correction light using a distance between the controllers and provide the driving control signal to the actuator or provide the control signal to the shutter based on a comparison between the calculated incident angle and the incident angle stored in the memory. Include.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 2 is a structural diagram illustrating a holographic ROM system according to the present invention, and FIG. 3 is a view for explaining a process of correcting an incident angle of a reference light for regenerative reference according to the present invention.

Referring to FIG. 2, the holographic ROM system includes first, second and third actuators 502, 512 and 522, a light source 504, first and second light splitters 506 and 516, a shutter 507 and a reflector ( 508, a pickup module, a recording medium 524, a motor 528, comprising a double-sided reflector 510, a position detector 514, an optical system 518, an aperture 520, an optical detector 526, The controller 530, the memory 532, and the signal processor 534 are included. The pickup module is moved by the first actuator 502, and the recording medium 524 stores interference fringes generated by the recording reference light and the signal light in an angular overlapping manner of the recording reference light, and the recording medium 524 during reproduction. ) Is rotated by the motor 528 under the control of the controller 530.

The light source 504 generates the light for reproduction and provides it to the first light separator 506. The first light separator 506 separates the light for reproduction into two lights, that is, the reference light for correction and the correction light, for the second light. To separator 516 and reflector 508. That is, the first optical separator 506 reflects a part of the reproduction light to generate correction light, and transmits the other part to generate the reproduction reference light.

The shutter 507 provided between the first and second light splitters 506 and 516 is opened or closed based on an on or off control signal provided from the control unit 530 to supply the reproduction reference light to the second light splitter 516. Provide or block.

The correction light provided by the first optical separator 506 is deflected by the reflector 508 at a predetermined angle and provided to the double-sided reflector 510. The double-sided reflector 510 has first and second reflecting surfaces 510a and 510b, and the second reflecting surface 510b deflects the correction light provided from the reflecting mirror 508 at a predetermined incident angle to provide it to the position detecting unit 514. The first reflective surface 510a receives the reference light for reproduction and reflects the same at an incident angle θ equal to that of the corrected light and provides the reflected light to the recording medium 524.

The double-sided reflector 510 is connected to the second actuator 512, and the second actuator 512 linearly and rotationally reciprocates the double-sided reflector 510 to change the incident angle of the correction light and the reference light for reproduction.

The second actuator 512 straightens and rotates the double-sided reflector 510 based on the driving control signal provided from the controller 530. Accordingly, the incident angle of the correction light and the reference light for reproducing the double-sided reflector 510 is Is changed.

When the correction light provided on the second reflecting surface 510b is reflected at a predetermined incident angle and is incident on the position detecting unit 514, the position detecting unit 514 detects the position data to which the correction light is incident and provides it to the controller 530. .

The controller 530 calculates and calculates the incident angle of the corrected light by using the distance from the position data provided by the position detector 514 and the corrected light to the second reflective surface 510b to the position detector 514. The incident angle of the recorded reference light stored in the memory 532 is supplied to the second actuator 512. That is, when the calculated incident angle and the incident angle of the recording reference light stored in the memory 532 are not the same, the controller 530 provides a driving control signal to the second actuator 512 to straighten and rotate the double-sided reflector 510. The incident angle of the correction light is changed to the same incident angle as the recording reference light. As the incident angle of the correction light is changed, the incident angle of the reproduction reference light incident on the first reflection surface 510a of the double-sided reflector 510 is deflected to the same incident angle as the recording reference light and is incident on the recording medium 524. In addition, when the calculated incident angle is the same as the incident angle of the recording reference light stored in the memory 532, the controller 530 may provide an on control signal to the shutter 507 to open the shutter 507 to open the first optical separator 506. In addition to providing the reproducing reference light provided by the second optical separator 516, the driving of the second actuator 512 is stopped. When the second actuator 512 is driving, the shutter 507 always keeps the closed state.

The process of calculating the incident angle of the correction light by the controller 530 will be described with reference to FIG. 3.

Referring to FIG. 3, the controller 530 is configured such that the correction light is incident on the second reflection surface 510b when the correction light is incident on the position detector 514 at an incident angle of 90 ° by the second reflection surface 510b. At the point of incidence when the distance L from the point to the position detection unit 514 and the correction light are incident on the position detection unit 514 at an incidence angle of 90 ° by the second reflecting surface 510b. The incident angle θ of the corrected light is calculated by the following equation (1) from the distance Y to the position where the light is reflected by θ).

The second optical splitter 516 reflects a portion of the reproduction reference light provided from the first optical splitter 506 to provide it to the first reflective surface 510a of the double-sided reflector 510, and the first reflective surface 510a. Is reflected at the same incident angle as that of the correction light and provided to the recording medium 524.

The diffraction pattern recorded on the recording medium 524 is diffracted by the reproduction reference light provided by being reflected by the first reflection surface 510a to generate the reproduction signal light, and the reproduction signal light is transmitted through the optical system 518 to the second optical separator. 516 is provided. The second optical splitter 516 reflects the reproduction signal light and provides it to the light detector 526.

The light detector 526 converts the reproduction signal light into an electrical signal and provides the signal to the signal processor 534, and the signal processor 534 processes and reproduces the electrical signal provided from the light detector 526.

As described above, the present invention detects the incident angle of the reproduction reference light when reproducing the recorded data in the angular superposition method and compares it with the recording reference light to correct the error incident angle, thereby maximizing the diffraction efficiency of the reproduced signal light to maximize the signal to noise ratio. In addition to improving the performance, data reproduction reliability can be improved.

1 is a structural diagram showing the overall structure of a holographic ROM system according to the prior art,

2 is a structural diagram showing a holographic ROM system according to the present invention;

3 is a view for explaining a process for correcting the incident angle of the reference reference light for the present invention.

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

502, 512, 522: 1st, 2nd, 3rd actuator 504: light source

506: first optical separator 508: reflector

510: double-sided reflector 514: position detection unit

516: second optical separator 518: optical system

524: recording medium 526: optical detector

528: motor 530: control unit

532: Memory 534: Signal Processing Unit

Claims (2)

A holographic ROM system for reproducing a recording medium in which recording reference light provided at different incidence angles and interference fringes by signal light are recorded in an angular superposition method. A light source for generating reproduction light; A memory in which incidence angle information of the recording reference light is stored; A first optical splitter configured to transmit a portion of the reproduction light to generate a reproduction reference light, and reflect another portion to generate correction light; A reflector for deflecting the correction light at a predetermined angle; A second optical splitter for reflecting the reproduction reference light and the reproduction signal light provided from the recording medium in different directions; A shutter open according to a control signal provided between the first and second optical separators to provide the reproduction reference light to the second optical separator; A double-sided reflector provided with the deflected correction light on one side and deflected at a predetermined angle of incidence; An actuator connected to the double-sided reflector to change the incident angle by moving the double-sided reflector according to a driving control signal; A position detector for detecting and providing position data of correction light provided by the double-sided reflector; The incident angle of the correction light is calculated by using the position data provided by the detector and the distance between the double-sided reflector and the detector, and the driving control signal is provided to the actuator based on a comparison between the calculated incident angle and the incident angle stored in the memory. Or providing a control signal to the shutter. Holographic ROM system comprising a. The method of claim 1, The control unit, When the correction light is incident on the position detection unit at an angle of incidence of 90 ° by the double-sided reflector, the distance L from the point at which the correction light is incident on the double-sided reflector and the angle of correction is 90 ° by the double-sided reflector. The distance (Y) from the incidence point when the incident light is incident on the position detector to the position at which the correction light is reflected at a predetermined incidence angle (θ) is incident θ = tan ^-1 (Y / L) Holographic ROM system, characterized in that the calculation.