KR20050099826A - Hdds worm system for using two laser beams different in wave length for recording/reproducing and method thereof - Google Patents

Abstract

In the present invention, the HDDS worm system and the holographic data reproduction to prevent errors due to the interference of the same beam and to increase the storage density of the holographic data in the storage medium by using beams having different wavelengths during recording / playback in the HDDS worm system It is about a method. That is, in the present invention, by using a laser beam of different wavelengths when recording and reproducing holographic data in the HDDS worm system, by preventing the formation of a new interference pattern in the storage medium by using the same reproduction beam, the storage medium due to the interference pattern Increase the storage density of the storage medium by preventing a decrease in dynamic range. In addition, it is possible to prevent errors from occurring in the holographic data recorded by the interference fringes caused by the same beam, thereby increasing the reliability of the system.

Description

HDDS WORM SYSTEM FOR USING TWO LASER BEAMS DIFFERENT IN WAVE LENGTH FOR RECORDING / REPRODUCING AND METHOD THEREOF}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a holographic digital data storage system (HDDS) system. In particular, the HDDS worm system uses beams having different wavelengths when recording / playback to prevent errors due to interference of the same beam and in the storage medium. The present invention relates to a HDDS worm system and a holographic data reproducing method for increasing holographic data storage density.

Figure 1 shows a block configuration of a conventional HDDS worm system using the same laser beam during recording and playback. Hereinafter, referring to FIG. 1, an operation of performing recording and reproduction using the same laser beam in a conventional HDDS worm system will be described.

First, the beam splitter 102 splits a laser beam incident from a light source 100 into a reference beam and a signal beam, where the vertical branching is performed. The polarized reference light is provided to the reference light processing path s1 and the branched signal light is provided to the signal light processing path s2. At this time, the reference light branched to the reference light path s1 is reflected at a predetermined deflection angle necessary for recording or reproducing the hologram data through the optical paths formed by the mirrors 104 and 106, thereby causing the lens 108 to be rotated. Through the media 114.

On the other hand, the signal light branched into the signal light path s2 is a binary in contrast of the pixels formed according to input data provided from a data coding unit (not shown) through a spatial light modulator (SLM) 110. After being modulated by one page of data, the data is incident on the storage medium 114 in synchronization with the reference light incident from the mirror 106 of the reference light processing path s1. Therefore, in the storage medium 114, the signal light modulated in units of pages of binary data provided from the spatial light modulator 110 in the recording mode, and the recording reference light incident from the mirror 106 with a predetermined deflection angle corresponding thereto. The interference fringe generated through the interference of is recorded. That is, the light induced phenomenon of the kinetic charge occurs in the storage medium according to the intensity of the interference fringe obtained by the interference between the modulated signal light and the reference light. Through this process, the three-dimensional image holographic data is stored in the storage medium 114. Interference fringes are recorded.

Subsequently, when the holographic data recorded on the storage medium 114 is reproduced, the reference light branched from the optical separator 102 is reflected by the mirror 106 and irradiated to the storage medium 114, and as a result, the storage medium ( In 114), the interference pattern recorded by the reproduction reference light diffracts the incident reference light, and is demodulated into one page of binary data composed of original pixel contrast. The demodulated reproduction signal is a charge-coupled device (CCD). Is investigated at 118. Accordingly, the CCD 118 detects the reproduced image irradiated from the storage medium 114 and restores the original data, that is, the electric signal.

However, in the conventional HDDS worm system, both recording and reproducing are performed with the same laser beam during recording / reproducing of hologram data. In the case of reproducing with the same laser beam, the storage medium is caused by the interference of the same laser beam during reproducing. There is a problem that a new interference fringe is formed in the to act as a noise (noise) factor.

That is, when the reproduction is performed by the same laser beam, the recording reaction occurs by the reproduction beam, which causes the problem of limiting the recording capacity by exhausting the dynamic range of the storage medium. There were inconveniences such as having to complete the recording and use it after exhausting the dynamic range completely.

Accordingly, an object of the present invention is to provide an HDDS worm system for preventing errors due to interference of the same beam and increasing holographic data storage density in a storage medium by using beams having different wavelengths when recording / reproducing in an HDDS worm system. It is to provide a holographic data reproduction method.

The present invention for achieving the above object is an HDDS worm system using a laser beam of different wavelengths during recording / playback, the first light source for emitting a laser beam for recording holographic data, and from the first light source during recording An optical splitter for optically separating the laser beam of the laser beam, an SLM for spatially modulating and outputting the signal light from the first light source in units of one page of binary data, and an interference pattern diffracted by the signal light and the reference light modulated by the SLM The incident angle to the storage medium for storing the holographic data, the second light source for emitting the reference laser beam for reproduction of the holographic data stored in the storage medium, and the angle of incidence to the storage medium for the reproduction of the reference light emitted from the second light source are recorded. Adjusting the beam width of the reference light of the second light source to be equal to the incident angle of the storage medium of the reference light of the first light source It comprises an iris.

In addition, the present invention is a method for reproducing holographic data with a laser beam of a different wavelength in the HDDS worm system using a laser beam of a different wavelength during recording / playback, (a) recording by the reference light from the first light source Emitting a reference light from a second light source having a wavelength different from that of the first light source as a reproducing reference light when there is a regeneration request for the storage medium, and (b) a reference emitted from the second light source. Adjusting the beamwidth of the second light source reference light through the iris such that the angle of incidence of the storage medium is equal to the angle of incidence of the storage medium of the first light source reference light used for recording; and (c) the reproducing agent whose beamwidth is adjusted through the iris. The reference light of the two light sources is incident to the storage medium through the mirror, and the holographic data recorded by the reference light of the first light source is Regenerating.

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

2 is a block diagram of an HDDS worm system using different laser beams during recording and playback according to an embodiment of the present invention. Hereinafter, a recording and reproducing operation using laser beams having different wavelengths in the HDDS worm system of the present invention will be described in detail with reference to FIG. 2.

First, the optical splitter 202 branches the laser beam incident from the first light source 200 into the reference light and the signal light, wherein the branched vertical polarized reference light is provided to the reference light processing path s1 and the branched signal light. Is provided in the signal light processing path s2. At this time, the reference light branched to the reference light path s1 is reflected at a predetermined deflection angle required for recording or reproducing the holographic data through the optical paths formed by the mirrors 204 and 208, and then through the storage medium 216 through the lens 210. Incident).

Subsequently, the signal light branched into the signal light path s2 is modulated in units of one page of binary data of light and dark in pixels according to input data provided from the data coding unit through a spatial light modulator (SLM) 212. The light incident on the storage medium 216 is synchronized with the reference light incident on the mirror 208 of the reference light processing path s1. Accordingly, in the storage medium 216, in the recording mode, the signal light modulated in units of pages of binary data provided from the spatial light modulator 212 and the recording reference light incident from the mirror 210 having a predetermined deflection angle corresponding thereto. The interference fringe generated through the interference of is recorded. That is, the light induced phenomenon of the kinetic charge occurs in the storage medium according to the intensity of the interference fringe obtained by the interference between the modulated signal light and the reference light. Through this process, the interference fringe of the three-dimensional holographic data is generated on the storage medium. Is recorded.

On the other hand, when reproducing holographic data recorded on the storage medium, unlike the conventional method, the holographic data recorded on the storage medium is reproduced by using reference light having a wavelength different from that of the laser beam used during recording. do. This is to solve the problem that when the holographic data reproducing operation is performed on the storage medium using the same reproducing laser beam, new interference fringes are formed on the storage medium due to the interference of the same laser beam, thereby acting as a noise factor. To this end, in the present invention, as shown in FIG. 2, a separate second light source 220 which emits a reference light for reproduction during holographic data reproduction is provided.

That is, in the present invention, instead of using the reference light of the first light source 200 used for recording branched from the optical separator 202 during reproduction, the first light source 200 emitted from the second light source 220 is used. The reference light having a different wavelength from the reference light is reflected through the mirrors 206 and 208 to be irradiated onto the storage medium 216.

In this case, in order to use the reference light having different wavelengths as the reproducing laser beam as described above, the reference of the first light source 200 used when the incident angle of the reference light emitted from the second light source 220 to the storage medium is used for recording. The beam width of the reference light of the second light source 220 should be adjusted to be equal to the incident angle of the storage medium. This is because the Bragg condition is out of the case of reproducing with a different laser beam.

3 shows a state immediately before the reference light is incident on the storage medium. In this case, the beam width of the reference light from the first light source 200 is X1. After passing through the lens, the storage medium 216 is -a to + Assuming that the incident light has an angle of a, for example, when the reference light of the second light source 220 uses a laser beam having a wavelength larger than that of the first light source 200, the second light source 220 may be used. The beam width of the reference light is formed as X2 larger than X1, so that the angle of incidence into the storage medium is also increased from -b to + b. When the angle of incidence incident on the storage medium is changed, the reference light of the first light source 200 is changed. This is because the grating formed by it cannot be read properly.

To this end, in the present invention, the iris 222 is installed on the reference light path of the second light source 220 to form the same angle of incidence as that of the storage medium of the reference light of the first light source 200. The beam width of the reference light is adjusted.

Hereinafter, an operation of adjusting the reference light beam width of the second light source 220 using the iris 222 will be described in detail. In the description of the present invention, the reference light of the first light source 200 is a green laser beam and the reference light of the second light source 220 is a red laser beam. Will be explained.

First, as shown in FIG. 4, the incident angle at which the green laser beam, which is the reference light of the first light source, is incident on the storage medium 216 is a1, and the incident laser beam is incident on the storage medium 216. Assuming that the angle is a2, a relationship as shown in Equation 1 below is established between the incident angle a1 and the refraction angle a2 by Snell's law.

sin a1 = n sin a2

Here, since the grating formed by the green laser beam is a grating reproduced by the angle of a2, the wavelength λ1 of the green laser beam may be expressed as shown in Equation 2 below.

λ1 = 2d sin a2

In the above, d represents a grating space, and when it is read as a red laser beam as a reference light of the second light source, the wavelength λ 2 of the red laser beam may be expressed as in Equation 3 below.

λ2 = 2d sin b2

Here, b2 is an internal angle of the storage medium of the red laser beam. Like the green laser beam of the first light source, b2 is an incidence angle at which the red laser beam is incident on the storage medium. Assuming that the internal angle of the storage medium of the laser beam is b2, a relation as shown in Equation 4 below is established between the incident angle b1 and the refraction angle b2 by Snell's law, similarly to the green laser beam.

sin b1 = n sin b2

Therefore, when the above equations are combined, the relationship between the green laser beam as the reference light of the first light source and the red laser beam as the reference light of the second light source may be expressed as shown in Equation 5 below.

At this time, the angle correction in FIG. 3 corrects -a1 to + a1 to -b1 to + b1. This can be obtained by adjusting the beam width of the laser beam through the iris as shown in FIG. 3, and the beam width of the red laser beam as a reference light of the second light source is obtained as shown in Equation 6 below.

F is the focal length of the lens, and when it is solved for X2, the beam width X2 of the red laser beam, the reference light of the second light source, and green, the reference light of the first light source, as shown in Equation 7 below. The relationship between the beam widths X1 of the laser beams can be seen.

Therefore, as described above, in the present invention, since the laser beams having different wavelengths are used for recording and reproducing holographic data in the HDDS worm system, the interference pattern is prevented by forming new interference patterns in the storage medium due to the use of the same reproduction beam. It is possible to increase the reliability of the system by preventing the reduction of dynamic range in the storage medium, thereby increasing the storage density of the storage medium, and preventing errors in the holographic data recorded by interference fringes caused by the same beam. do.

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, by using the laser beams of different wavelengths when recording and reproducing holographic data in the HDDS worm system, the interference pattern is prevented by forming new interference patterns in the storage medium due to the use of the same reproduction beam. There is an advantage of increasing the storage density of the storage medium by preventing a reduction in the dynamic range in the storage medium. In addition, there is an advantage that the reliability of the system can be increased by preventing an error from occurring in the holographic data recorded by the interference fringe due to the same beam.

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

2 is a block diagram of a HDDS worm system according to an embodiment of the present invention;

3 is an exemplary view of beamwidth between laser beams of different wavelengths according to an embodiment of the present invention;

4 is a view illustrating an incident angle in a storage medium of a ray point beam according to an exemplary embodiment of the present invention.

Claims (5)

HDDS worm system that uses laser beams of different wavelengths in recording / playback. A first light source for emitting a laser beam for recording holographic data, An optical splitter for optically separating the laser beam from the first light source during recording; An SLM for spatially modulating and outputting the signal light from the first light source in units of one page of binary data; A storage medium for storing the interference pattern diffracted by the signal light and the reference light modulated by the SLM as holographic data; A second light source for emitting a reference light for reproducing holographic data stored in the storage medium; An iris that adjusts the beam width of the reference light of the second light source so that the angle of incidence to the storage medium for reproducing the reference light emitted from the second light source is equal to the angle of incidence of the storage medium of the reference light of the first light source used for recording. HDDS worm system using a laser beam having a different wavelength during recording / playback comprising a. The method of claim 1, The reference light beamwidth of the second light source is controlled by the iris to reproduce hologram data in the storage medium recorded by the first light source as in the following equation. HDDS worm system using beams. [Equation] x2 = x1 tan b / tan a x1: beam width of the first light source b1: incident angle of the storage medium of the second light source a1: incident angle of the storage medium of the first light source The method of claim 1, And the first and second light sources are green light having a wavelength of 532n and red light having a wavelength of 632n, respectively. As a method of reproducing holographic data with laser beams of different wavelengths in HDDS worm systems using laser beams of different wavelengths in recording / reproducing, (a) when there is a regeneration request for a storage medium on which recording is performed by the reference light from the first light source, the reference light from the second light source having a wavelength different from that of the first light source is emitted as the reproducing reference light. Making a step, (b) adjusting the beam width of the second light source reference light through the iris such that the angle of incidence of the storage medium of the reference light emitted from the second light source is the same as the angle of incidence of the storage medium of the first light source reference light used for recording; (c) reproducing the holographic data recorded by the reference light of the first light source by injecting the reference light of the second light source for reproduction with the beam width controlled through the iris into the storage medium through the mirror; Hologram data reproduction method using a laser beam of a different wavelength comprising a. The method of claim 4, wherein In the step (b), the reference light beamwidth of the second light source is adjusted by the iris to reproduce hologram data in the storage medium recorded by the first light source as in the following equation. Holographic data reproduction method using laser beams of different wavelengths. [Equation] x2 = x1 tan b / tan a x1: beam width of the first light source b1: incident angle of the storage medium of the second light source a1: incident angle of the storage medium of the first light source