KR100594945B1 - Data read/Write device for holographic storage medium and method thereof - Google Patents

Abstract

An apparatus for recording / reproducing data on a holographic storage medium is disclosed. The data recording apparatus according to the present invention is a laser beam projection apparatus for projecting a laser beam onto a storage medium capable of recording data in three dimensions by using volume holography, and at the bottom of the storage medium in a state where data to be copied is recorded. When the laser beam is incident through the storage medium, the reflective data mask is arranged so that the interference pattern formed by the first incident laser beam and the signal beam is recorded on the storage medium. It includes. Accordingly, data can be recorded / reproduced with simple hardware and the light efficiency can be improved.

Hologram, ROM, Reflective Data Mask, Laser Beam

Description

Data read / write device for holographic storage medium and method

1 is a schematic diagram showing a conventional configuration of a recording apparatus for recording data on a holographic storage medium;

2 is a schematic diagram showing a conventional configuration of a playback apparatus for reproducing data from a holographic storage medium;

3 is a schematic diagram showing the configuration of a data recording apparatus for recording data on a holographic storage medium according to an embodiment of the present invention;

4 is a schematic diagram showing the configuration of a data reproducing apparatus for reproducing data from a holographic storage medium according to an embodiment of the present invention;

5 is a flowchart for explaining a method of recording data in the data recording apparatus of FIG. 3; and

FIG. 6 is a flowchart for describing a method of reproducing data in the data reproducing apparatus of FIG. 4.

Explanation of symbols on main parts of drawing

110: reflective data mask 120: laser beam projection device

20, 200: holographic storage medium 310: reference beam projection apparatus

311 light source 313 beam splitter

315 objective lens 320 optical signal detector

The present invention relates to a recording / reproducing apparatus and method for a holographic storage medium, and more particularly, to a device capable of quickly recording or reproducing data on a holographic storage medium with a simple hardware configuration by using a reflective data mask. And to a method.

As the spread of computers increases, the development of various peripherals and components to accelerate the use of the computers more efficiently and improve their performance is also accelerating. In particular, various types of storage media have been developed and distributed in the case of auxiliary storage media which store the stored programs or data even when the power supply of the computer is interrupted. Auxiliary storage media generally used include magnetic storage media and optical disk storage media.

A magnetic storage medium is a medium that stores data using magnetic force such as a floppy disk and a hard disk. In particular, a hard disk has a large storage capacity and a high input / output speed of data, which is a major factor in personal computers. It is used as an auxiliary memory device. Floppy disks, on the other hand, have been widely used as an auxiliary storage device for personal computers because they are easy to carry. However, since the storage capacity is small, many dozens of disks are needed to store recent multimedia information.

On the other hand, optical disk devices (or laser disk devices) developed to improve the capacity shortage of removable magnetic disks, such as floppy disks, have relatively large storage capacities and can be searched at high speed. Types include CD-ROMs and digital video discs (DVDs).

However, recent rapid developments in computer technology and information and communication fields require a means of storing massive amounts of information. The massive amount of data of hundreds of billions of bytes goes beyond the storage capacity of CDs, so new storage media are required. Recently, a hologram data storage method using a photorefractive effect in which the refractive index is changed by light has emerged as a new alternative.

Holographic data storage is the storage of information in the form of optical interference fringes in inorganic crystals or polymer materials that are sensitive to light. The optical interference pattern is formed using two coherent laser beams. That is, an interference fringe formed by interference of a reference beam that does not contain any data and an object beam that contains predetermined data may be recorded by causing chemical or physical changes in a photosensitive storage medium. do. As such, a film on which an image of an object is recorded in the form of an interference fringe is called a hologram, and a technique of recording a hologram is called holography.

Meanwhile, volume holography may store information in a three-dimensional space of a storage medium. Accordingly, since the angle, phase, wavelength, and the like of the reference beam are changed and multiplexed to store and restore high-density data, the speed is very fast and the storage capacity is excellent.

However, when data is copied by the hologram information storage method, unlike the conventional optical record storage media, since fast copying is not easily performed, until recently, WORM (Write-Once, Read-Many) or RW (Read and Write) methods are used. Technological development has been progressed limited to the system. In other words, compared to a WORM or RW holographic storage medium that does not require fast copying because data is copied by a user, a fast copying method is essential in a ROM method in which a producer produces a large amount of media. Therefore, the holographic technology could not be utilized by the ROM method while the development of a technology for rapidly copying the holographic information storage method was not known.

FIG. 1 is a schematic diagram showing a configuration of an apparatus for copying data to a holographic ROM as a technique conventionally proposed to solve such a problem. According to FIG. 1, light emitted from a laser light source (not shown) is split into two beams 40a and 40b in a beam splitter, so that a transmissive data mask 10 and a conical cone Incident on a conical mirror (30).

The transmissive data mask 10 records data in the form of pits of various lengths, such as CD or DVD, and transmits light 40a to the storage medium 20 through each pit. The included signal beam 50a is incident on the storage medium 20.

Meanwhile, the beam 40b incident to the conical mirror 30 is reflected from the surface of the conical mirror 30 and is incident on the storage medium 20 at various angles. The beam 50b reflected through the conical mirror 30 does not include any data and thus becomes a reference beam.

Accordingly, the signal beam 50a and the reference beam 50b are incident on the upper and lower surfaces of the storage medium 20 at various angles, causing interference with each other, and recorded in the hologram form on the storage medium 20.

Meanwhile, the conical mirror 30 is replaced with another conical mirror having various inclination angles, and the data mask 10 is also replaced with other data, and then the reference beam 50b and the signal beam 50a in the same manner. ), The reference beam 50b is incident on the same region of the storage medium 20 at different angles, and at the same time, data is recorded while causing interference with the signal beam 50a containing different data. That is, since multiplexing of angles is performed, data multiplexing is performed. As a result, data can be quickly replicated using holographic technology.

FIG. 2 is a schematic diagram illustrating a process of reproducing data from a storage medium 20 in which data is stored in the manner of FIG. 1. Referring to FIG. 2, when a phase conjugate wave 60 is scanned with respect to the reference beam 50b on a surface opposite to the direction in which the reference beam 50b is incident on the storage medium 20, the storage medium 20 is scanned. The phase conjugate wave of the incident signal beam 50a is reproduced as it is, and the data recorded in the transmission data mask 10 is reproduced as it is.

The reproduced data is focused through a pickup lens 70 and then detected by the optical signal detector 80. On the other hand, when the phase conjugate wave 60 is scanned at various angles, all the data recorded at the multiplexed angles can be reproduced.

Meanwhile, when data is recorded / reproduced using the techniques shown in FIGS. 1 and 2, since a relatively fast data copy is possible, a holographic ROM may be implemented. However, in FIG. 1, the reference beam is stored at a uniform angle of incidence. In order to scan at), the reflective surface of the conical mirror 30 should have a uniform inclination angle. However, it is difficult to manufacture the conical mirror 30 having such a uniform reflective surface.

In addition, as shown in FIG. 2, in order to reproduce the data, the phase conjugate wave 60 with respect to the reference beam 50b should be scanned at an oblique angle to the storage medium 20. In order to reproduce the multiplexed data, It should be changed to a constant scanning angle, this technique also has a problem that it is difficult to implement.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to record data using a reflective data mask and to enter a reference beam in a direction perpendicular to the storage medium. It is an object of the present invention to provide a data recording / reproducing apparatus and a method for recording / reproducing data on a holographic storage medium with hardware simpler than the prior art by reproducing recorded data.

A holographic data recording apparatus according to the present invention for achieving the above object, a laser beam projection apparatus for projecting a laser beam to a storage medium capable of recording data in three dimensions using volume holography, and the storage Align the data under the storage medium with the data to be copied to the recording medium. If the laser beam is incident through the storage medium, the laser beam is diffracted into a signal beam corresponding to the data and projected onto the storage medium. And a reflective data mask for recording an interference fringe formed by the first incident laser beam and the signal beam onto the storage medium.

In this case, the reflective data mask may record the data in the form of pits and, when the laser beam is projected, diffractive reflection to correspond to the pit form to generate the signal beam and project it onto a storage medium. This eliminates the need for additional hardware, such as a beam splitter, that separates the laser beam into a reference beam and a signal beam.

On the other hand, in order to multiplely copy separate data in the same area of the storage medium, the reflective data mask should be replaced with a second reflective data mask having predetermined second data written in a pit shape.

In this case, according to an embodiment of the present invention, the laser beam projection apparatus can record data multiplexed by multiplexing the wavelength of the laser beam. That is, by changing the wavelength of the laser beam within the range that can be multiplexed, and projecting onto the storage medium it is possible to record the data in the same area of the storage medium multiplely.

As described above, the reproducing apparatus according to the present invention for reproducing holographic data from a storage medium on which holographic data, which is an interference fringe between a reference beam and a signal beam, is recorded, projects the reference beam perpendicularly to the storage medium to perform the reference. And a reference beam projection device for restoring a signal beam corresponding to the beam, and an optical signal detector for detecting the restored signal beam and confirming data displayed by the signal beam.

In this case, the reference beam projection apparatus, a light source for outputting a laser beam in the form of a parallel beam, a beam splitter for changing the path of the laser beam output from the light source to be projected perpendicular to a predetermined area of the storage medium, and the beam It may include an objective lens for focusing the laser beam whose path is changed by the splitter to a predetermined region of the storage medium.

On the other hand, preferably, further comprising an aperture in front of the optical signal detector for adjusting the reproduction area of the signal beam to selectively pass only the signal beam reproduced from a predetermined pit to read data of the storage medium; can do.

More preferably, the present holographic data reproducing apparatus further includes a focusing lens for adjusting the focus position of the signal beam reconstructed from the storage medium, so that more accurate data can be detected.

On the other hand, in order to detect data recorded in the same area in multiple times, the reference beam projection apparatus may change the wavelength of the reference beam and project it on the same area of the storage medium. That is, when each signal beam corresponding to the wavelength of each reference beam is restored, multiplexed data can be confirmed by detecting data from the signal beam.

A data recording method in a holographic data recording apparatus according to the present invention comprises the steps of: (a) projecting a predetermined laser beam onto a storage medium capable of recording hologram data; (b) the laser beam penetrating the storage medium. (C) the reflective data mask reflecting the laser beam in the form of a signal beam corresponding to the data, and entering the reflective data mask onto the storage medium. Projecting, and (d) recording interference patterns formed by the laser beam and the signal beam in the predetermined region of the storage medium as holographic data.

On the other hand, in the step (c), it is preferable that the reflective data mask generates the signal beam by diffractive reflection so that the data corresponds to the pit shape when the data is recorded in the form of pits. Do.

More preferably, the data recording method according to the present invention may further comprise (e) multiplexing the data recorded in a predetermined region of the storage medium by multiplexing the wavelength of the laser beam.

In this case, the step (e) may include replacing the reflective data mask with a second reflective data mask on which predetermined second data is recorded, and changing the wavelength of the laser beam within a predetermined range capable of multiplexing. And then projecting onto the storage medium.

In addition, according to the present invention, a holographic data reproduction method for reproducing the data from a storage medium on which holographic data, which is an interference fringe between a reference beam and a signal beam, is recorded, (a) the reference beam is the data of the storage medium. (B) restoring the signal beam corresponding to the reference beam by the storage medium, and (c) detecting the restored signal beam to display the signal beam. Verifying the data.

In this case, preferably, the step (a) comprises: transforming the light emitted from the light source into a parallel beam, changing the path of the parallel beam in a direction perpendicular to the storage medium, and to the storage medium. The method may include focusing the parallel beam incident on the storage medium on a predetermined area.

On the other hand, more preferably, the step (c) further comprises the step of adjusting the restoration area of the signal beam to selectively pass only the signal beam reproduced from a predetermined pit to read data of the storage medium; can do.

In addition, the data reproducing method according to the present invention further includes adjusting the focal position of the signal beam restored from the storage medium, so that more accurate data can be detected.

On the other hand, in order to detect the multiplexed recorded data, the method further comprises the step of (e) changing the wavelength of the reference beam and projecting the same region of the storage medium, thereby reproducing the data recorded in the region multiplely. It is also preferred.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention.

3 is a schematic diagram showing a holographic data recording apparatus according to an embodiment of the present invention. According to FIG. 3, the holographic data recording apparatus 100 includes a reflective data mask 110 and a laser beam projection apparatus 120, and the data is stored in the holographic storage medium 200 using the reflective data mask 110. Will be recorded.

As a medium of the holographic storage medium 200, it is preferable to use a relatively inexpensive photoreactive polymer material, that is, a photopolymer, among organic and polymer materials, which have recently been highlighted.

In order to record data, the laser beam projection apparatus 120 is driven to emit a laser beam 121 having a uniform large area in the direction of the holographic storage medium 200. In this case, the laser beam 121 becomes a reference beam that does not contain any data. The emitted reference beam 121 is partially transmitted through the holographic storage medium 200 to be projected onto the reflective data mask 110 on the lower side.

The reflective data mask 110 may be formed of a pit coded in the same or similar manner as a conventional bit CD or DVD. That is, the reflective data mask 110 records the data to be recorded in a pit shape, and when the reference beam 121 is projected, generates the signal beam 123 by diffracting and reflecting light to correspond to the recorded data. Projected onto the holographic storage medium 200. Accordingly, the reference beam 121 projected from the laser beam projection apparatus 120 and the signal beam 123 reflected from the reflective data mask 110 cause mutual interference to generate a predetermined interference fringe. The pattern is recorded as holographic data on the holographic storage medium 200.

On the other hand, on the surface of the opposite holographic storage medium 200 to which the reference beam 121 is incident, the optical intensity of the transmittance is changed to adjust the light intensity of the signal beam and the reference beam. Such optical coating can be achieved by forming a multilayer film using a dielectric.

Meanwhile, according to an embodiment of the present invention, the wavelength of the reference beam 121 projected from the laser beam projection apparatus 120 is multiplexed for recording multiplexing. That is, after replacing the reflective data mask 110 with a new one, the wavelength of the reference beam 121 is changed by a certain amount within a range capable of wavelength multiplexing by controlling a light source (not shown) in the laser beam projection apparatus 120. In this case, data is recorded multiplely.

FIG. 4 is a schematic diagram showing the configuration of a playback apparatus for reproducing data from the holographic storage medium 200 recorded in the manner of FIG. According to FIG. 4, the present playback apparatus 300 includes a reference beam projector 310 and an optical signal detector 320.

The reference beam projector 310 refers to a device for reproducing a signal beam corresponding thereto by projecting a laser beam as a reference to the holographic storage medium 200 in which data is recorded in the form of an interference fringe.

According to an embodiment of the present invention, the reference beam projector 310 includes a light source 311, a beam splitter 313, and an objective lens 315. The light source 311 serves to output a laser beam in the form of a parallel beam. In this case, the light source 311 refers to a laser beam source having a broad meaning including a collimator for transforming a laser beam radiated at various angles into a parallel beam shape. Accordingly, the path of the laser beam output from the light source 311 in the form of a parallel beam is changed by the beam splitter 313 to enter the objective lens 330. The beam at this time becomes a reference beam which does not contain any data. On the other hand, the objective lens 315 serves to focus the reference beam on the focal point. In order to reproduce data, the position of the objective lens 315 is adjusted to focus on the holographic storage medium 200.

When the waist of the reference beam is focused at the position where the hologram is recorded, in the Rayleigh range, the recorded signal beam is reproduced as it is because it has the same properties as a parallel beam. In this case, a signal having less noise can be reproduced only when the size of the rail array area is larger than the thickness of the holographic storage medium 200.

When the reference beam is projected onto the holographic storage medium 200 by the reference beam projector 310, the signal beam is restored as if it is output from the reflective data mask 110. The reconstructed signal beam is converted back into a parallel beam by the objective lens 315 to be focused on the optical signal detector 320, and the optical signal detector 320 checks the data included in the signal beam.

In this case, as described above, since the reproduced signal beam appears to be emitted from the reflective data mask 110 at the time of recording, it does not become an accurate parallel beam after passing through the same objective lens 315 as the reference beam. Therefore, a focusing lens for adjusting the focus of the signal beam in front of the optical signal detector 320 may be additionally provided to compensate for the difference in the focal plane.

Meanwhile, since all data recorded in the area where the reference beam is projected onto the holographic storage medium 200 is reproduced, a type of aperture may be used to reproduce only desired data. That is, by adjusting the projection area of the signal beam restored and projected to the optical signal detector 320 using an aperture, it is possible to detect only the signal beam restored from a predetermined pit of the holographic storage medium 200.

FIG. 5 is a flowchart for describing a method of recording data on the holographic storage medium 200 using the holographic data recording apparatus 100 shown in FIG. 3. According to FIG. 5, the reference beam is projected onto the holographic storage medium 200 while the reflective data mask 110 having the data to be copied once recorded in a pit shape is placed under the holographic storage medium 200. (S510). In this case, a medium of the holographic storage medium 200 may use an optical polymer.

On the other hand, the projected reference beam is partially transmitted through the holographic storage medium 200 to be diffracted by the reflective data mask 110 at the bottom to be projected onto the holographic storage medium 200 in the form of a signal beam (S520). . That is, the pit recorded in the reflective data mask 110 is reflected as it is and is projected to the lower portion of the holographic storage medium 200.

Since the laser beam projected from the laser beam projection apparatus 120, that is, the reference beam 121 causes interference with the diffracted and reflected signal beam 123, such an interference pattern is recorded on the storage medium 200 as it is. (S530). A manufacturer who wants to manufacture a ROM-type hologram storage medium can copy data in a fast manner accordingly.

On the other hand, the manufacturer replaces the reflective data mask 110 with other data recorded therein, and then changes the wavelength of the reference beam 121 and then projects the same area of the holographic storage medium 200 to thereby multiplex the recording. It may also be (S540). Accordingly, the producer can increase the capacity of the data stored in the holographic storage medium 200 even more than the conventional optical recording medium.

6 is a flowchart for explaining a method of reproducing holographic data recorded in the manner of FIG. Referring to FIG. 6, first, a reference beam having the same wavelength as the reference beam 121 projected at the time of recording data is projected onto the holographic storage medium 200 (S610).

In this case, according to the reproduction apparatus of FIG. 4, which is an embodiment of the present invention, the holographic storage medium 200 uses the laser beam emitted from the light source 311 using the beam splitter 313, the objective lens 315, or the like. Projected perpendicularly to (S620).

Meanwhile, when the reference beam is projected onto the holographic storage medium 200, the signal beam corresponding to the projected reference beam is reproduced as it is (S630). In this case, since the reproduced signal beam is projected directly from the lower reflective data mask 110, a separate lens for focusing an image may be additionally required. In addition, it may further include an aperture for adjusting the area projected by the optical signal detector 320 to reproduce the signal beam to read only the desired data.

The reproduced signal beam is detected by the optical signal detector 320 opposite to the reflective data mask 110 with respect to the holographic storage medium 200, and the optical signal detector 320 of the detected signal beam By identifying the bit form it is possible to check the data (S640).

On the other hand, if there is multiplexed data, it is possible to detect all such data by projecting by varying the wavelength of the reference beam.

Accordingly, the user can utilize data recorded in the holographic ROM even with simple hardware.

As described above, according to the present invention, it is possible to implement a recording device and a storage device applied to a holographic storage medium. In particular, by using a reflective data mask, data can be quickly replicated, and data can be recorded and disseminated using a holographic ROM method. In particular, data can be recorded / reproduced using only relatively simple hardware compared to the prior art. Will also increase.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (18)

A laser beam projection apparatus for projecting a laser beam onto a storage medium capable of recording holographic data; And Align the data under the storage medium with the data to be recorded, and when the laser beam passes through the storage medium, the laser beam is reflected in the form of a signal beam corresponding to the data and is projected onto the storage medium. And a reflective data mask which allows the interference fringe formed by the beam and the signal beam to be recorded on the storage medium. The method of claim 1, And the reflective data mask records the data in the form of a pit so that the signal beam is diffracted to reflect the pit shape when the laser beam is projected to generate the signal beam. The method of claim 2, And recording the data in one area of the storage medium by replacing the reflective data mask with a second reflective data mask having predetermined second data written in a pit shape. The method of claim 3, The laser beam projection device, And changing the wavelength of the laser beam and projecting the data onto the storage medium to record data in the same area of the storage medium multiplely. A holographic data reproducing apparatus for reproducing data from a storage medium on which holographic data is recorded in the form of an interference fringe between a reference beam and a signal beam, A reference beam projection device for projecting the reference beam perpendicular to the storage medium to restore a signal beam corresponding to the reference beam; and And an optical signal detector which detects the restored signal beam and confirms the data displayed by the signal beam. The method of claim 5, The reference beam projection apparatus, A light source for outputting a laser beam in the form of a parallel beam; A beam splitter for changing a path of a laser beam output from the light source so as to be projected perpendicular to a predetermined area of the storage medium; and And an objective lens for focusing the laser beam whose path is changed by the beamsplitter to a predetermined area of the storage medium. The method of claim 6, The reference beam projection apparatus, And changing the wavelength of the reference beam to project on the same area of the storage medium, thereby reproducing data recorded in the area multiplely. The method of claim 7, wherein And an aperture for adjusting a projection area at which the signal beam restored from the storage medium is projected to the optical signal detector so as to selectively read data. The method of claim 8, And a focusing lens for adjusting a focus position of the signal beam reconstructed from the storage medium. (a) projecting a predetermined laser beam onto a storage medium capable of recording hologram data; (b) the laser beam penetrating the storage medium, and entering the reflective data mask in which data to be copied is recorded on the storage medium; (c) the reflective data mask reflecting the laser beam in the form of a signal beam corresponding to the data and projecting the laser beam onto the storage medium; and and (d) recording interference patterns formed by the laser beam and the signal beam as holographic data in a predetermined region of the storage medium. The method of claim 10, Step (c) is, And the reflective data mask generates the signal beam by diffractive reflection so that the data is recorded in the form of a pit so that the laser beam is projected to correspond to the pit form. The method of claim 11, and (e) multiplexing data recorded in a predetermined area of the storage medium by multiplexing the wavelength of the laser beam. The method of claim 12, In step (e), Replacing the reflective data mask with a second reflective data mask on which predetermined second data is recorded; and And changing the wavelength of the laser beam within a predetermined range capable of multiplexing and projecting the laser beam onto the storage medium. A holographic data reproduction method for reproducing the data from a storage medium on which holographic data as an interference fringe between a reference beam and a signal beam is recorded, (a) projecting the reference beam perpendicular to a predetermined area of the storage medium to which the data is to be reproduced; (b) restoring, by the storage medium, a signal beam corresponding to the reference beam; and (c) detecting the reconstructed signal beam and confirming data displayed by the signal beam. The method of claim 14, In step (a), Outputting a laser beam in the form of a parallel beam; Changing a path of the laser beam in a direction perpendicular to the storage medium; and And focusing the laser beam vertically incident on the storage medium to a predetermined area of the storage medium. The method of claim 15, and (d) reproducing the data recorded in the region by changing the wavelength of the reference beam to project on the same region of the storage medium. The method of claim 16, In step (a), And adjusting a restoration area of the signal beam restored from the storage medium so as to selectively read data. The method of claim 17, And adjusting a focus position of the signal beam reconstructed from the storage medium.

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