KR19990005336A - Space Overlaying Method for Volume Holographic Digital Data Storage Systems - Google Patents

Abstract

The present invention relates to a volume holographic digital data storage system, and in storing a holographic data page in a storage material by a spatial superposition method, the storage medium is moved a predetermined distance and at the same time. It is to provide a spatial superimposition method of the VHDDSS characterized by tilting a predetermined angle.

According to the present invention, it is possible to maximize the area that can overlap the space, it is possible to bring about the effect of constituting a system with good diffraction efficiency while maintaining the storage capacity equal.

Description

Space Overlaying Method for Volume Holographic Digital Data Storage Systems

The present invention relates to a storage material of a volume holographic digital data storage system. More particularly, the present invention relates to a storage material of a volume holographic digital data storage system. The present invention relates to a spatial superposition method that can maximize density.

Recently, the field of technology using volume holographic digital data storage has been actively researched by the remarkable development of components such as semiconductor laser, CCD, LCD, etc., and it has already been put into practical use as a fingerprint recognition system that stores and plays fingerprints. In addition, it is expanding to be able to apply the advantages of large storage capacity and ultra-fast data transfer rate.

FIG. 1 is a schematic diagram showing a digital data storage system (hereinafter abbreviated as VHDDSS) using general volume holography.

As shown, a typical VHDDSS includes a light source 1, a light splitter 2, a rotating mirror 3, a spatial light modulator 4, a storage medium 5, and a charge coupled device CCD. And 6) an optical system consisting of a single device.

The light source 1 is composed of a laser light source capable of generating coherent beams required for holography.

A beam splitter 2 for separating the aggregated light into a reference beam and an object beam is configured at a position corresponding to the laser light source.

A spatial light modulator 4 is configured on the optical path of the object light to modulate by one page unit of the binary data of the contrast made by the pixel according to the input data.

On the other hand, a rotating mirror 3 is provided on the optical path of the reference light for converting the angle of the reference light little by little.

The storage medium 5 is provided on an optical path where the reference light and the object light cross each other so that the storage medium 5 can be recorded according to the intensity of the interference fringe formed by the interference of the object light and the reference light.

The CCD 6 is for restoring the data recorded on the storage medium 5, and is installed on the optical path of the interference fringe generated when the storage medium 5 is irradiated with the reference light.

The operation of the general VHDDSS configured as described above is as follows.

The condensed light irradiated from the light source 1 is divided into the reference light and the object light by the optical splitter 2, and the object light is a spatial light modulator 4 in units of one page of the binary data of the intensity which the pixels form according to the input data. Is modulated by

Thereafter, the object light and the reference light cause interference in the storage medium 5 for recording the hologram, and light-induced generation of mobile kinetic charges in the storage medium 5 according to the intensity of the interference fringes generated at this time. charge) occurs and an interference fringe is recorded through this process.

On the other hand, each page is applied with a reference light that slightly changes the angle of the rotating mirror (3). After recording the first page of data on the storage medium, the angle of the reference light is increased until the reproduction restoration image of the first hologram disappears completely. At this time, a new data page is inputted to the reference light of a different angle and recorded in the storage medium 5. The data is stored in the storage medium by repeating the angle multiplexing process of changing the angle of the reference light at each recording time. Overlap will be recorded.

In addition, in addition to the above-described angle multiplexing, the data is superimposed by a spatial multiplexing method in which the storage medium 5 is shifted in the longitudinal direction. That is, after the first page of data is recorded at the front end of the storage medium 5, the storage medium 5 is sufficiently moved so that there is no interference between the storage areas, and then a new data page is input and recorded on the storage medium.

As such, hundreds to thousands of holograms composed of pages of binary data can be recorded and stored in the same place inside a small cube, resulting in high storage density and fast data transfer rate.

On the other hand, in order to read the data recorded on the storage medium (5), when the reference medium applied to each page at the time of recording is irradiated to the storage medium (5), the interference pattern diffracts the reference light and consists of the pattern of the original pixel intensity. Is restored to the original data by illuminating the image read afterwards onto the CCD (6).

Here, the total data storage capacity (M) of the VHDDSS is a hologram data obtained by superimposing the number of data bits included in a hologram of one page by Nb and the number of holographic data pages superimposed by an angular overlap. Supposing the number of pages is Ns:

The relationship of M = Nb × Na × Ns holds.

As described above, when hologram data configured in units of pages is overlaid on the same storage medium 5, finite dynamic ranges of materials in which interference fringes recorded in the storage medium 5 constitute the storage medium 5 are defined. There is a limit to storage capacity because

On the other hand, when the degree of overlap of the hologram is increased by the angle overlap method to increase the storage density, the reproduction hologram image becomes darker, and as a result, the reproduction noise increases.

That is, the proportion of light diffracted by each hologram is inversely proportional to the square of the number of superimposed holograms. This reduction in diffraction efficiency ultimately weakens the reconstruction image, and this weak signal is caused by the variation in laser brightness, the scattering of light from the storage medium and the heat in the CCD. Since the electronics are easily affected by the noise inevitably present in the system, the bit error ratio increases, making it impossible to detect reliable data.

In addition, in the conventional space overlapping method, as shown in FIG. 2, an interval of Δh is required to prevent cross talk due to interference between data storage regions, so that the space for the total length h of the storage medium is spaced. There was a problem that the overlapping area is reduced.

Accordingly, the present invention is to solve such a conventional problem, it is possible to maximize the area that can overlap the space without having to maintain a separate gap for the prevention of crosstalk due to interference between the storage areas during space overlap recording. The purpose is to provide a spatial overlapping method of VHDDSS.

In addition, the present invention provides a method of overlapping the space of the VHDDSS that can maximize the storage density inexpensively compared to the method of developing a new storage material to increase the storage density of the recording medium, or to shorten the data wavelength and increase the intensity Has a different purpose.

In addition, another object of the present invention is to provide a spatial superimposition method of the VHDDSS, which makes it possible to construct a system having a good diffraction efficiency while maintaining an equal storage capacity.

In order to achieve the above object, the present invention provides a method of storing a holographic data page on a recording medium of a VHDDSS in a spatial superposition method, wherein the storage medium is moved at a predetermined distance and simultaneously tilted at a predetermined angle. It is to provide a method of spatial nesting.

According to the present invention, even when a storage area of the storage medium overlaps with a preceding storage area or a subsequent storage area during spatial overlap recording, each storage area is independently recorded and reproduced without interference by angle seletivity. It becomes possible. That is, the storage density of the holographic data page that can be stored for the entire length h of the recording medium by eliminating the need for a constant interval to be maintained so as to avoid the problem of overlapping or crosstalk with a conventional preceding or subsequent storage area. Can be maximized.

1 is a schematic diagram showing a typical VHDDSS,

2 is a schematic diagram showing a conventional space superposition method,

Figure 3 is a schematic diagram showing a spatial overlap method according to the present invention.

* Explanation of symbols on the main parts of the drawings

1: light source 2: optical separator

3: rotating mirror 4: spatial light modulator (SLM)

5: storage medium 6: CCD (charge coupled device)

7: first area 8: second area

Hereinafter, the spatial overlapping method of the VHDDSS according to the present invention will be described with reference to the accompanying drawings.

3 is a schematic diagram showing a spatial superimposition method of the VHDDSS according to the present invention.

The recording material of the storage medium 5 is a photorefractive crystal, and the shape is hexahedral or cylindrical.

The aggregated light irradiated from the light source is divided into the reference light and the object light by the optical splitter, and the object light is modulated by the spatial light modulator in units of one page of the binary data of the contrast made by the pixels according to the input data. 5), the reference light is irradiated to the storage medium 5 with the angle slightly different for each hologram data page to be stored.

In this case, an interference fringe is generated by the interference of the reference light and the object light in the storage medium 5, and a light-induced generation of mobile charge in the storage medium 5 is generated according to the intensity of the interference fringe. Through this, interference fringes are recorded.

After recording the first page of the hologram data in the storage medium 5, the angle of the reference light is increased until the reconstructed image of the first hologram disappears completely, and again a new data page is inputted with the reference light of a different angle to the storage medium (5). The so-called Angle Multiplexing process of changing the angle of the reference light for each hologram data page recording is repeated.

In addition, while moving the storage medium 5 in one of the reference light or the object light (the z-axis direction in which the reference light is irradiated in the drawing) at a predetermined interval while tilting in the x-axis direction by Δθ by spatial overlap ( spatial multiplexing).

[Delta] [theta] is set to such an extent that interference does not occur even when there are overlapping portions between neighboring storage areas on the basis of the angle selectivity in the spatial overlap recording of the hologram data page.

Therefore, the range of the interval H where cross talk does not appear between neighboring storage areas during spatial overlap recording is reduced.

That is, even if the first region 7 and the second region 8 overlap some portions, recording / reproducing is independently performed without interference by the angle selectivity.

As described above, when tilting in the x-axis direction by Δθ while moving a predetermined interval in the z-axis direction during space overlapping, the first area 7 is not only required between the storage areas due to the space overlapping. Even if the and second regions 8 overlap to some extent, it becomes possible to store data independently without interfering with each other. That is, the number of spatial overlaps can be secured more with respect to the total length h of the storage medium 5, thereby increasing the data storage density.

In particular, as mentioned earlier, the diffraction efficiency is inversely proportional to Na ² when the hologram data pages are superimposed on one storage area with angular overlap to increase the overall data storage capacity (M) in the relation M = Nb × Na × Ns. As Na decreases as much as possible, instead of maintaining the diffraction efficiency above a certain level, Na increases the number of spatial overlaps for the total length h of the storage medium (5) during space overlapping, thereby increasing the Ns. M) can be configured to increase the diffraction efficiency while maintaining the same.

The foregoing is merely illustrative of a preferred embodiment of the present invention and those skilled in the art to which the present invention pertains may make modifications and changes to the present invention without changing the subject matter of the present invention.

Therefore, according to the present invention, it is possible to maximize the area that can overlap the space, it is possible to bring the effect of constructing a system having a good diffraction efficiency while maintaining the storage capacity equal.

Claims (1)

A spatial superimposition method of a VHDDSS characterized in that a holographic data page is stored in a recording medium of a VHDDSS in a spatial superposition method, wherein the storage medium is moved a predetermined distance and at the same time tilted at a predetermined angle.