KR100627496B1 - Apparatus and method for reproducing recording medium - Google Patents

Abstract

A reproducing apparatus of a recording medium in which a recording layer and a guide layer form a multi-layer structure, the reproducing apparatus comprising: an aperture having a predetermined window for passing light diffracted according to a data pattern recorded in the recording layer; And an image sensor for detecting recorded data by detecting light passing through the window formed in the aperture, wherein the aperture is in the form of a bar.

Holographic, data storage

Description

Playback apparatus and method {Apparatus and method for reproducing recording medium}

1 illustrates a holographic data storage system.

2 is a view for explaining the shape of a conventional LCD aperture.

3 illustrates a holographic data storage system in accordance with the present invention.

4 and 5 illustrate the aperture window of the present invention.

<Explanation of symbols for main parts of drawing>

10; Lens 20; Storage media

21; Core layer 22; Cladding Layer

24; Image sensor 25; LC Aperture

30; Holographic data storage medium 31; Core layer

32; A cladding layer 34; Image sensor

35; Aperture

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to holographic data storage systems, and more particularly to a holographic data storage system having an aperture window of a scanning method for aperture multiplexing of a holographic data storage medium.

Currently, optical storage technology is widely used in general life, and typical examples thereof include CD (COMPACT DISC) and DVD (DIGITAL VERSATILE DISC).

The development direction of the optical storage technology is focused on high integration, miniaturization and light weight.

In particular, the miniaturization of the optical storage device is to increase the utilization by attaching the storage device to a mobile device, and to compensate for the disadvantages of the conventional disc type optical storage device.

In order to be used in mobile environments, optical storage devices must be able to withstand external shocks, have a minimum mechanical operating range, and have the robustness of the system itself.

This object cannot be achieved by a method of reducing the size of a conventional disc type optical storage device, and a structural change of the optical storage device is required.

Holographic optical information storage devices using holograms are being studied as one of researches to develop new storage devices.

The holographic data storage system illustrated in FIG. 1 includes a lens 10 for linearly focusing light emitted from a light source, a holographic data storage medium 20, and an LCD that is changed into various shapes according to a control signal. An LCD 25 includes an image sensor 24 that senses light passing through the LCD aperture 25 and reads out data.

The lens 10 is a pre-condensing means for pre-condensing the incident light to be incident on the selected layer of the holographic data storage medium 20, the cross-section is cylindrical or semi-circular Can be formed.

A collimation lens may be additionally provided between the lens 10 and the light source to convert light incident on the lens 10 into parallel light.

The holographic data storage medium 20 has a multilayer thin film structure in which a plurality of core layers 21 and a cladding layer 22 are alternately formed.

The core layer 21 is designed to have a high optical refractive index and the cladding layer 22 is designed to have a low optical refractive index. The incident light is guided so that it can

Thus, the pre-condensed light incident from the lens 10 is vertically diffracted by a pre-stored pit pattern of the core layer 21, and the diffracted light is of the holographic data storage medium 20. It passes through the LCD Aperture 25 provided on the upper side and detects it through the image sensor 24. CMOS may be used as the image sensor 24.

As shown in FIG. 2, the opening shape of the LCD aperture 25 may be variously changed by a control signal, and the light may be diffracted by the same core layer 21. Different data are shown depending on the shape of the opening.

That is, the LCD aperture 25 is for improving the information integration degree of the holographic data storage medium 20, and the same core layer (according to the change in the arrangement of the apertures of the LCD aperture 25) The light diffracted in 21) shows different information.

Therefore, increasing the number of vertically disposed core layers 21 and the cladding layers 22 of the holographic data storage medium 20 and diversifying the arrangement of the openings of the CD aperture 25 stores more data. This is possible.

In this way, it is called aperture multiplexing to improve the density of information by diversifying the opening arrangement of the CD aperture 25.

For example, if the aperture arrangement of the CD aperture 25 is changed ten times with respect to the light diffracted in the specific core layer 21, five times the information integration degree can be obtained as compared with the case where the change is made twice.

Of course, the data pattern recorded in the core layer 21 should be previously recorded in consideration of the change in the opening of the CD aperture 25.

Such a holographic data storage device has an advantage that the mechanical driving unit of the operation unit is very small and can be configured robustly compared to an optical storage device such as a conventional CD or DVD.

In particular, since the image storage method is used, the data integration degree is very high.

However, the opening arrangement in the form of a square mosaic shown in FIG. 2 requires that the diffraction of the core layer 21 be well correlated overall so that the accuracy of the reproduced detected information is maintained. (21) There is a problem that an error occurs in the entire information.

In addition, even when error correction (error correction), there is a lot of difficulties because the opening arrangement of all the CD aperture must be considered.

In addition, there is a problem that it is impossible to mechanically modify the aperture arrangement of the aperture.

An object of the present invention is to provide a holographic data storage system in which a window of an aperture for aperture multiplexing is configured in a mechanically or electrically movable bar form.

Another object of the present invention is to provide a holographic data storage system capable of partially detecting data recorded in a core layer and minimizing possible errors and enabling partial error correction.

Another object of the present invention is to provide a holographic data storage system in which a plurality of bar-shaped aperture windows are arranged to improve data detection speed.

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A reproducing apparatus of a recording medium in which a recording layer and a guide layer form a multi-layer structure, the reproducing apparatus comprising: an aperture having a predetermined window for passing light diffracted according to a data pattern recorded in the recording layer; And an image sensor for detecting recorded data by detecting light passing through the window formed in the aperture, wherein the aperture is in the form of a bar.
Hereinafter, a holographic data storage system according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a diagram illustrating a holographic data storage system according to the present invention, and FIGS. 4 and 5 are views illustrating an aperture window in the present invention.

The holographic data storage system according to the present invention includes a lens 10 for line focusing of light emitted from a light source, a holographic data storage medium 30, and a window for aperture multiplexing. Aperture 35 having a window formed therein, and an image sensor 34 for detecting the light passing through the aperture 35 to read the data.

The lens 10 is a pre-condensing means for pre-condensing the incident light to be incident on the selected layer of the holographic data storage medium 20, the cross-section is cylindrical or semi-circular Can be formed.

A collimation lens may be additionally provided between the lens 10 and the light source to convert light incident on the lens 10 into parallel light.

The holographic data storage medium 30 has a multilayer thin film structure in which a plurality of core layers 31 and a cladding layer 32 are alternately formed.

The core layer 31 is designed to have a high optical refractive index and the cladding layer 32 is designed to have a low optical refractive index. The cladding layer 32 may be diffracted from the core layer 31 while the incident light satisfies the total reflection condition. The incident light is guided so that it can

That is, the holographic data storage medium 30 is a first medium in which data is recorded and forms a multi-layered structure with the core layer 31 having a high refractive index, and the incident light is diffracted and detects data. The cladding layer 32 is included as a second medium having a low refractive index to enable it.

Here, the core layer 31 is used as a recording layer in which data is recorded, and the cladding layer 32 is used as a guide layer for detecting recorded data.

Thus, the pre-condensed light incident from the lens 10 is vertically diffracted by a pre-stored data pit pattern of the core layer 31, and the diffracted light is of the holographic data storage medium 30. Passes through the aperture 35 provided on the upper side and detects it through the image sensor 34. CMOS may be used as the image sensor 34.

As shown in FIG. 4, the window shape of the aperture 35 is formed in a bar shape, and the window of the aperture 35 moves in a directional manner with time.

Preferably the window of the aperture 35 is continuously moved in a scanning manner.

As described above, the bar-shaped window may be electrically implemented as in the conventional LCD aperture.

In particular, the scanning opening of the present invention can minimize the error of data since an error occurs only in a part of the detected data when there is an error in the light diffracted in the data pattern of the core layer 31. .

Meanwhile, as illustrated in FIG. 5, the window shape of the aperture 35 may be formed in two bars or two or more bars to increase the data detection speed.

That is, since data is detected in two areas of the image sensor 34, the detection speed of the data may be doubled.

Additionally, the shape of the aperture 35, the image sensor 34, and the holographic data storage medium 30 can be rectangular because of the use of a bar-shaped window, which is a design freedom or This can lead to an increase in data storage capacity.

The present invention can provide a holographic data storage system capable of partially detecting data recorded in the core layer to minimize possible errors and partially correcting the errors.

The present invention can provide a holographic data storage system that can improve the detection speed of data recorded on a holographic data storage medium.

Claims (9)

A recording medium reproducing apparatus in which a recording layer and a guide layer form a multilayer structure, An aperture having a predetermined window through which light diffracted in accordance with a data pattern recorded in the recording layer passes; And And an image sensor for detecting recorded data by detecting light passing through the window formed in the aperture. And the window of the aperture has a bar shape. The method of claim 1, The bar-shaped window may be arranged at various positions within the aperture. The method of claim 1, And the window of the aperture has two or more bars. A reproducing apparatus in which incident light is diffracted by a recorded data pattern and processes data by sensing the diffracted light, A storage medium in which a recording layer in which a data pattern is recorded and a guide layer for guiding light to the recording layer form a multilayer structure; An aperture through which light diffracted in the recording layer passes, and having a bar-shaped window; And And an image sensor for detecting data from light incident through the aperture. The method of claim 4, wherein The bar-shaped window may be arranged at various positions within the aperture. The method of claim 4, wherein And the window of the aperture has at least one bar shape. Irradiating light onto the recording medium; The irradiated light is reflected or diffracted by a data pattern recorded on a recording medium; Passing light reflected or diffracted by the data pattern through a window formed in an aperture; And Detecting the data passing through the window, thereby detecting recorded data; And the window of the aperture has a bar shape. The method of claim 7, wherein The bar-shaped window may be arranged at various positions within the aperture. The method of claim 7, wherein And the window of the aperture is formed in two or more bars, and the two or more bars may be disposed at various positions in the aperture, respectively.

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