KR100601275B1 - Apparatus for detecting intensity of signal beam for reproduce in a hdds worm system and method thereof - Google Patents

Abstract

The present invention relates to an apparatus and method for detecting optimal signal light intensity for playback in an HDDS worm system which detects the intensity of signal light during playback in the HDDS worm system and performs optimal playback. That is, the present invention detects the intensity of the signal light by splitting the signal light diffracted from the storage medium when the holographic data is reproduced in the holographic worm system, and detecting the intensity of the signal light through the CCD when the intensity of the signal light is higher than a predetermined reference value. By reproducing, it is possible to fix the signal light intensity detector for measuring the signal light intensity regardless of the incident angle of the reference light even if the reference light is incident at various angles.

Description

Apparatus and Method for Optimal Signal Light Intensity Detection for Reproducing in HDDS Worm System {APPARATUS FOR DETECTING INTENSITY OF SIGNAL BEAM FOR REPRODUCE IN A HDDS WORM SYSTEM AND METHOD THEREOF}

1 is a schematic block diagram of a conventional HDDS worm system;

2 is a block diagram of an apparatus for detecting signal light intensity in a conventional HDDS worm system;

3 is a block diagram of a signal light intensity detection device in the HDDS worm system according to an embodiment of the present invention.

<Brief description of the major symbols in the drawings>

316: storage medium 317: beam splitter

318: CCD 320: decoding unit

322: signal light intensity detection unit 324: microcomputer

The present invention relates to a holographic digital data storage (HDDS) worm system, and in particular, an apparatus for detecting optimal signal light intensity for playback in an HDDS worm system for detecting an intensity of signal light during playback in an HDDS worm system and performing optimal playback. It is about a method.

In general, HDDS system is a page-oriented memory that uses the principle of volume hologram on the principle of data recording / reproducing, and can use the parallel data processing method as the input / output method to make the input / output speed higher than 1Gbps. In addition, it is possible to configure the system without the mechanical driving part, so that the data access time can be implemented very quickly with less than 100 ms.

FIG. 1 illustrates a block diagram of a conventional HDDS worm system. Referring to FIG. 1, the operation of a conventional HDDS system will be described. First, in the optical separator 102, the laser light incident from the light source 100 is converted into a reference light and an object light. In the branching, the reference light of vertically polarized branching is provided to the reference light processing path S1 and the branched object light is provided to the object light processing path S2. In addition, the shutter 104 and the reflector 106 are provided in the emission direction of the reference light on the reference light processing path S1, and the reference light necessary for recording or reproducing hologram data in the reference light processing path S1 through the light transmission path. The light is reflected at a predetermined deflection angle and provided to the storage medium 116.

Accordingly, the vertically polarized reference light branched from the light separator 102 and incident through the opening of the shutter 104 is adjusted through an optical lens (not shown) or the like and expanded to an arbitrary size (ie, an object described below). Extends to a size sufficient to cover the size of the object light extending through the beam expander in the light processing path S2, and a predetermined angle, for example, a recording angle or reproduction at the time of recording, is reflected through the reflector 106; It is deflected to a preset reproduction angle for the incident to the storage medium 116. Here, the reference light used during recording or reproduction is controlled by rotating the reflector 106 whenever the binary data for each page is recorded on the storage medium 116 to change the deflection angle θ. Through such a reference optical deflection technique, hundreds to thousands of hologram data may be stored in the storage medium 116 or the stored hologram data may be reproduced.

On the other hand, on the object light processing path S2, the shutter 110, the reflector 112, and the spatial light modulator 114 are sequentially provided in the emission direction of the object light, but the shutter 110 is kept open in the recording mode. In the regeneration mode, the cutoff state is maintained. The object light branched from the optical separator 102 and incident through the opening of the shutter 110 is reflected at a predetermined deflection angle through the reflector 112 and then transmitted to the spatial light modulator 114.

Subsequently, the spatial light modulator 114 modulates the object light transmitted from the reflector 112 in units of one page of binary data of light and shade binary data formed by pixels according to input data provided from the data coding unit 124. For example, when the input data is image data in one frame unit of the image, the object light incident on the spatial light modulator 114 is modulated into signal light in one frame unit, and then the reflector 106 of the reference light processing path S1 is used. ) Is incident on the storage medium 116 in synchronization with the reference light incident on the side. Accordingly, in the storage medium 116, in the recording mode, the reflector 106 has a signal light modulated in units of pages of binary data provided from the spatial light modulator 114 and a deflection angle θ corresponding thereto. An interference fringe obtained through interference between incident reference light for reference is recorded. That is, the light induced phenomenon of the kinetic charge is generated in the storage medium 116 according to the intensity of the interference fringe obtained by the interference between the modulated object light and the reference light. Interference fringes of the holographic data are recorded in dimensions.

Subsequently, when reproducing the holographic data recorded in the storage medium 116, the shutter 110 on the object light processing path S2 is blocked and the shutter 104 on the reference light processing path S1 is opened. It is in a state. The reference light (reproducing reference light) branched from the optical separator 102 is then reflected through the reflector 106 and irradiated to the storage medium 116, whereby the storage medium 116 writes by the reference light for reading. The interfering interference fringe diffracts the incident reference reading light, and is demodulated into one page of binary data composed of original pixel contrast, and the demodulated reproduction signal is irradiated to the CCD 118. Accordingly, the CCD 118 restores the reproduction output irradiated from the storage medium 116 to the original data, that is, the electrical signal, and the reproduction signal reproduced here is reproduced and output through the data decoding unit 120.

Meanwhile, in the conventional HDDS worm system as described above, in order to obtain an image having the highest intensity among signal lights input to the CCD 118 in real time as shown in FIG. 2 in continuous rotation according to reproduction of holographic data. When the reference light projected onto the medium 116 is received through the storage medium, the intensity of the received reference light passing through the storage medium 116 is detected by the detector 200 and the signal light when the intensity of the received reference light is the lowest. 118) to decode the playback image.

This is because the energy of the reference light incident to the first storage medium is the sum of the energy of the reference light detected through the storage medium and the energy of the signal light emitted from the storage medium by the incidence of the reference light. This is because the signal light has the highest intensity when the light intensity is the lowest. However, when detecting the intensity value of the reference light passing through the storage medium as in the prior art, when the incident angle of the reference light is changed when the holographic data stored in each multiplexing method is changed, the detection unit 200 detects the reference light passing through the storage medium. There was a problem that the position had to be adjusted each time.

Accordingly, it is an object of the present invention to provide an apparatus and method for detecting optimal signal light intensity for playback in an HDDS worm system which detects the intensity of signal light during playback in an HDDS worm system and performs optimal playback.

According to an aspect of the present invention, there is provided an apparatus for detecting an optimal signal light intensity for reproduction in a holographic worm system, the storage medium outputting signal light diffracted by the reference light when the reference light is incident for holographic data reproduction, and A beam splitter for splitting and splitting the signal light emitted from the storage medium, a signal light intensity detector for detecting the intensity of the signal light incident from the beam splitter, and a strength of the reproduction signal light detected from the signal light intensity detector at a predetermined reference value or more; And a microcomputer for controlling the decoding of the image of the corresponding signal light incident from the beam splitter and incident on the CCD.

In another aspect, the present invention is a method for detecting the optimal signal light intensity for reproduction in a holographic worm system, (a) injecting a reference light for holographic data reproduction to the storage medium, and (b) a signal light diffracted by the incident reference light (C) beam splitting and splitting the signal light emitted from the storage medium; and (d) detecting the intensity of the branched signal light and checking whether the signal is detected to be above a predetermined reference value. And (e) controlling the decoding of the image of the corresponding signal light incident to the CCD when the intensity of the signal light is greater than or equal to a predetermined reference value.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation of the preferred embodiment according to the present invention.

3 is a block diagram of a holographic worm system for performing a reproducing operation by detecting signal light intensity according to an exemplary embodiment of the present invention. Hereinafter, an operation of detecting optimal signal light intensity in the holographic worm system will be described in detail with reference to FIG. 3.

First, the reproducing operation in the holographic worm system will be described once again. In the case of reproducing the holographic data recorded in the storage medium 316, the shutter 310 on the object light processing path S2 is in a blocked state and a reference is made. The shutter 304 on the light processing path S1 side is in an open state. The reference light (reproducing reference light) branched from the optical separator 302 is then reflected through the reflector 306 and irradiated to the storage medium 316, whereby the storage medium 316 is recorded by the reading reference light. The interfering fringe is subjected to diffraction to read out the incident reference reference light and demodulated into one page of binary data composed of original pixel contrast, and the demodulated reproduction signal is irradiated to the CCD 318. Accordingly, the CCD 318 restores the reproduction output irradiated from the storage medium 316 to the original data, that is, the electrical signal, and the reproduction signal reproduced here is reproduced and output through the data decoding unit 320.

At this time, during reproduction in the holographic worm system as described above, the signal light is diffracted from the storage medium by the reference light incident to the storage medium and incident to the CCD 318. In the present invention, as shown in FIG. A beam splitter 317 is provided between the 316 and the CCD 318 to separate the signal light so that the signal light emitted from the storage medium 316 is branched through the beam splitter 317 to be input to the signal light intensity detector 322. do.

Then, the signal light intensity detector 322 detects the intensity of the reproduced signal light which is branched through the beam splitter 317 and inputs it to the microcomputer 326. Accordingly, the microcomputer 326 receives the signal light intensity detector 322 from the signal light intensity detector 322. When the detected intensity of the reproduced signal light is greater than or equal to a predetermined reference value, and when the intensity of the optimal signal light for reproducing holographic data is examined, the image of the corresponding signal light branched from the beam splitter 317 and incident on the CCD 318 Is controlled to be decoded by the decoding unit 320.

As described above, in the present invention, when the holographic data is reproduced in the holographic worm system, the signal light diffracted from the storage medium is beam split to detect the intensity of the signal light, and when the intensity of the signal light is detected to be higher than a predetermined reference value, the CCD is detected. By reproducing the image through, the signal light intensity detector for measuring the signal light intensity can be fixed even if the reference light is incident at various angles regardless of the incident angle of the reference light.

Meanwhile, in the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the invention should be determined by the claims rather than by the described embodiments.

As described above, in the present invention, in the holographic worm system, when the holographic data is reproduced, the signal light diffracted from the storage medium is beam split to detect the intensity of the signal light, and the intensity of the signal light is detected to be higher than a predetermined reference value. In this case, by reproducing the image through the CCD, even if the reference light is incident at various angles, the signal light intensity detector for measuring the signal light intensity may be fixed regardless of the incident angle of the reference light.

Claims (2)

Optimal signal light intensity detection device for reproduction in holographic worm system, A storage medium for emitting the signal light diffracted by the reference light when the reference light is incident for reproducing holographic data; A beam splitter for splitting and splitting the signal light emitted from the storage medium; A signal light intensity detector for detecting an intensity of signal light incident from the beam splitter; If the intensity of the reproduction signal light detected by the signal light intensity detection unit is greater than or equal to a predetermined reference value, the microcomputer for controlling to decode the image of the corresponding signal light branched from the beam splitter incident to the CCD Signal light intensity detection device of the holographic worm system comprising a. Optimum Signal Light Intensity Detection Method for Playback in Holographic Worm System (a) injecting reference light for holographic data reproduction into a storage medium; (b) emitting signal light diffracted by the incident reference light, (c) beam splitting and splitting the signal light emitted from the storage medium; (d) detecting whether the signal intensity of the branched signal is detected to be detected by a predetermined reference value or more, and (e) controlling the decoding of the image of the corresponding signal light incident to the CCD when the intensity of the signal light is greater than or equal to a predetermined reference value; Optimal signal light intensity detection method for reproduction in a holographic worm system comprising a.

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