KR19980085421A - Storage angle multiplexing device for hologram data storage. - Google Patents

Abstract

Disclosed is a storage angle multiplexing device for hologram data storage having an angular multiplexing device having a high response speed instead of a precision rotating device constituting a storage device for storing hologram data. A reflector reflecting the laser beam applied from the laser beam generator at a predetermined angle is installed on the upper surface of the rotating plate, and the rotating plate rotates at a constant speed by the rotating motor so that the reflecting mirror rotates at the constant speed with the rotation of the rotating motor. do. The rotating plate is detected by the rotation angle sensor and applied to the microcomputer, and the microcomputer controls the operation of the laser beam generator according to a signal applied from the rotation angle sensor to intercept the irradiation of the laser beam according to the rotational position of the reflector. Done. Therefore, since the irradiation of the laser beam is interrupted by the control of the microcomputer according to the rotational position of the reflecting mirror fixed to the upper surface of the rotating plate, the laser beam can be precisely irradiated to the desired position of the hologram recording element.

Description

Storage Angle Multiplexing Device for Hologram Data Storage

The present invention relates to a device for storing hologram data, and more particularly to an angular multiplexing device having a fast response speed instead of a precision rotating device constituting a storage device for storing hologram data. The storage angle of hologram data storage relates to a multiplexing device.

Recently, with the development of microprocessors and software, excellent personal computers can be processed by 3D CG, and a main line network having a gigabit transfer speed connects the world in real time. And with the advent of the multimedia society, it is progressing to a new highly information society.

In the next few years, a 4-gigahertz microprocessor with one gigabit transistor will be realized, and a terabit backbone network will be realized. Memory technologies are being developed to store information that can process and transfer them in large quantities.

By the way, although the superiority of optical memory is claimed in the recording density which is an index of memory technology, optical memory has a limitation. That is, the current optical disk uses the wave characteristics of the light forming the optical spot in the lens. Therefore, unless X-Ray or the like is used as a theoretical limit for spots of the wavelength of light, the recording density has an upper limit of 5 gigabit (Gbit / cm 2). This will lag behind magnetic memory or semiconductor memory in the near future. This is because there is no wavelength limitation in the magnetic memory because the head gap defines the recording density. The same applies to the semiconductor memory. Therefore, in order for an optical memory to take an advantage, it is to discard the wave characteristics of light or to use multiple recording.

A photon memory using instantaneous wavelengths has been proposed as a method of discarding the wave characteristics, and its recording limit reaches 100 to 200 (Gbit / cm 2). This method is not suitable for application because the Probe must be able to access the recording medium up to several 10 nm, such as the Photon STM, which uses unspread light.

Therefore, a volume hologram recording method has been studied as a method of multi-recording. The volumetric hologram recording method has a recording density of 1 terabit, can be read at a speed of several gigabits or more, and can satisfy the entire non-contact as a high-speed random access of several tens or less.

Holograms can be said to record the complex amplitude distribution of light waves by modulating the carrier spatial frequency, but multiple recordings are possible by using the carrier spatial frequency varying from the change of the angle θ.

That is, when recording hologram data, another object can be recorded continuously by attaching an angle index while changing the incident angle of the reference light little by little, and when reading, the reference light can be irradiated from the angle at the time of recording.

1 is a diagram schematically illustrating a configuration of a general hologram memory device.

Referring to FIG. 1, a beam splitter 12 which separates a laser applied from the laser beam generator 10 into two lights (reference light and object light); A first rotating reflector 14 reflecting a reference light applied through the beam splitter 12 at a predetermined angle; A second rotating reflector 16 which reflects the object light applied through the beam splitter 12 at a predetermined angle; A spatial light modulator (18) for modulating the data applied from the data generator (24) by the object light reflected from the second rotating reflector (16); An imaging lens 20 for converging object light including data applied from the spatial light modulator 18; A hologram recording element (22) for storing hologram data generated by interference between an object light applied through the imaging lens (20) and a reference light applied through the first rotating reflector (14); And an imaging unit (CCD) 26 for imaging the hologram data applied through the hologram recording element 22.

In the conventional hologram memory device configured as described above, the laser beam applied from the laser beam generator 10 is separated into two beams, the object light 40 and the reference light 30, by the beam splitter 12 and is generated in two directions. do. The reference light 30 is applied to the first rotating reflector 14 and reflected at a predetermined angle, and the object light 40 is also reflected at a predetermined angle by the second rotating reflector 16.

The object light reflected by the second rotation reflector 16 is applied to the spatial light modulator 18, and the data is applied from the data generator 24 to the spatial light modulator 18, so the object light passes the data. While being modulated and applied to the imaging lens 20. The imaging lens 20 focuses an object light on which data applied through the spatial light modulator 18 is applied to the hologram recording element 22.

The hologram recording element 22 stores the hologram data generated when the object light carrying the data and the reference light interfere with each other. When the hologram data stored in the hologram recording element 22 is reproduced, the reference light reflected from the first rotation reflector 14 is applied to the hologram data recorded in the hologram recording element 22. When reference light is applied to the hologram data stored in the hologram recording element 22, the object light is reproduced and applied to the imaging unit 26 to read the stored data.

The first rotating reflector 14 applying the reference light to the hologram recording element 22 rotates the reference light to the desired position of the hologram element 22 to rotate left and right so that the data carried in the object light can be superimposed. . When the first rotating reflector 14 is rotated, the laser beam as the reference light is not accurately irradiated, so that a separate acoustic light modulator 28 or a plurality of lenses 32 are installed in the middle to adjust the reference light to be irradiated accurately. Further, in order to rotate the first rotating reflector 14, the reflecting mirror is installed on a constant rotating plate and then rotates the rotating plate using a rotating motor (not shown).

Since the rotating plate is rotated left and right by the motor, the rotation operation is slow, and the rotation function is not smooth due to the inertia when repeating the stop operation and the rotation operation.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to replace the precision rotating device constituting the storage device for storing the hologram data with a fast response speed and a storage angle of the hologram data storage that can be overwritten. It is to provide a multiplexing device.

1 is a diagram schematically illustrating a configuration of a general hologram memory device.

2 is a diagram schematically illustrating an apparatus for multiplexing a storage angle of hologram data storage according to an exemplary embodiment of the present invention.

Explanation of symbols on the main parts of the drawing

50 laser beam generator 52 beam splitter

54: rotation reflector 56: spatial light modulator

58: data generator 60: imaging lens

62: rotating plate 64: reflector

66 hologram recording element 68 rotation motor

70: rotation angle detection sensor 72: imaging unit

80: micom 82: reference light

84: object light

In order to achieve the above object of the present invention, the present invention comprises a beam splitter for separating the laser applied from the laser beam generating unit into two lights (reference light and object light) of the same ratio; A rotation reflector reflecting the object light applied through the beam splitter at a predetermined angle; A spatial light modulator for modulating the data applied from the data generator by the object light reflected from the rotating reflector; An imaging lens that focuses an object light including data applied from the spatial light modulator; A rotating plate on which a reflector reflecting a laser beam is mounted and fixed on an upper surface thereof; A rotating motor for rotating the rotating plate at a constant speed; A rotation angle sensor for detecting a rotation angle of the rotation plate; A hologram recording element for storing hologram data generated by interference between an object light applied through the imaging lens and a reference light applied through a reflecting mirror of a rotating plate; An imaging unit (CCD) for capturing hologram data applied through the hologram recording element, and connected to the rotation angle sensor and the laser generation unit, and controlling the operation of the laser generation unit according to a signal applied from the rotation angle detection sensor. A storage angle multiplexing device for hologram data storage made of a microcomputer is provided.

According to the present invention, a reflector reflecting a laser beam applied from a laser beam generator at a predetermined angle is provided on the upper surface of the rotating plate, and the rotating plate is rotated at a constant speed by the rotating motor so that the reflecting mirror is rotated with the rotation of the rotating motor. Let's do constant rotation together. The rotating plate is detected by the rotation angle sensor and applied to the microcomputer, and the microcomputer controls the operation of the laser beam generator according to a signal applied from the rotation angle sensor to intercept the irradiation of the laser beam according to the rotational position of the reflector. Done. Therefore, since the irradiation of the laser beam is interrupted by the control of the microcomputer according to the rotational position of the reflecting mirror fixed to the upper surface of the rotating plate, the laser beam can be precisely irradiated to the desired position of the hologram recording element.

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

2 is a diagram schematically illustrating an apparatus for multiplexing a storage angle of hologram data storage according to an exemplary embodiment of the present invention.

Referring to FIG. 2, a storage angle multiplexing apparatus for hologram data storage is described. The laser applied from the laser beam generator 50 is configured by the beam splitter 52 to have two reference lights 82 and object light 84 having the same ratio. Separated by). The object light 84 applied through the beam splitter 52 is reflected at a predetermined angle by the rotation reflector 54, and the object light 84 reflected by the rotation reflector 54 is applied to a spatial light modulator ( The data applied to 56 and applied from the data generator 58 is loaded on the object light 84. The object light 84 on which data is carried by the spatial light modulator 56 is focused by the imaging lens 60 and applied to the hologram recording element 66 that stores the hologram data.

In addition, a mirror 64 reflecting a laser beam is mounted on the upper surface of the rotating plate 62 having a flat upper surface, and fixed to the upper surface. The rotating plate 62 is rotated at a constant speed in a predetermined direction by the rotation of the rotary motor 68 about the central axis (not shown).

The rotation angle sensor 70 is installed in the vicinity of the rotation plate 62, the rotation angle sensor 70 detects the rotation angle of the rotation plate 62. The reference light 82 applied through the beam splitter 52 is applied to the reflecting mirror 64 of the rotating plate 62. The reference light 82 reflected through the reflecting mirror 64 of the rotating plate 62 and the object light 84 reflected through the rotating reflecting mirror 54 and applied through the imaging lens 60 are hologram recording elements 66. Is irradiated to and recorded on the imaging unit 72

The microcomputer 80 is connected to the rotation angle sensor 70 and the laser beam generator 50, and the microcomputer 80 is located at a rotational position of the rotation plate 62 applied from the rotation angle sensor 70. The laser beam is irradiated to the reflector 64 by controlling the operation of the laser beam generator 50 according to the corresponding signal.

In the present invention made as described above, the laser beam generated by the laser beam generator 50 is irradiated by being split into two reference lights 82 and object light 84 through the beam splitter 52, and the reference light 82 is It is applied to the reflector 64 provided on the upper surface of the rotating plate 62.

The reference light 82 applied to the reflector 64 is irradiated to the hologram recording element 66, and the object light 84 is reflected by the rotation reflector 54 and applied to the spatial light modulator 56. Since the data irradiated from the data generator 58 is applied to the spatial light modulator 56, the object light 84 is modulated by the data while passing the data applied to the spatial light modulator 56, and the data generator The object light 84, which is an optical signal on which data applied from 58 is loaded, is applied to the imaging lens 60. The imaging lens 60 focuses the object light on which data applied through the spatial light modulator 56 is applied to the hologram recording element 66.

The object light 84 applied to the hologram recording element 66 is stored in the hologram recording element 66 while causing mutual interference with the reference light 82 reflected by the reflecting mirror 64 of the rotating plate 62. Becomes

At this time, since the rotating plate 62 continuously rotates in a constant direction by the rotating motor 68, the reflecting mirror 64 installed on the upper surface of the rotating plate 62 also rotates along with the rotating plate 62. . Accordingly, the reference light 82 irradiated through the beam splitter 52 stops irradiating when the rotating plate 62 rotates to be out of a predetermined angle.

When the rotating plate 62 rotates forward at a constant speed, the rotation angle sensor 70 detects this and applies it to the microcomputer 80. The microcomputer 80 compares the rotational position applied from the rotational angle sensor 70 to determine a deviation from the set angle and immediately applies a signal to the laser beam generator 50 so that the laser beam is not generated.

The laser beam generator 50 prevents unnecessary laser beam consumption because the operation of generating the laser beam is interrupted by the control of the microcomputer 80 and the rotating plate 62 is out of the set angle. In addition, the microcomputer 80 detects the rotational position of the rotating plate 62 applied from the rotation angle sensor 70 and operates the laser beam generator 50 when the reflector is positioned at the set angle. Reflected through the reflecting mirror 64 to be applied to the hologram recording element (66). When the reflector 64 of the rotating plate 62 is out of a predetermined angle is detected by the rotation angle sensor 66 and applied to the microcomputer 80, the microcomputer 80 is a laser beam generating unit 50 is a laser beam Should not occur.

The hologram recording element 66 while continuously modifying the irradiation angle of the reference light 82 applied through the reflecting mirror 64 of the rotating plate 62 and the object light 84 on which data is carried under the control of the microcomputer 80. The hologram can be multi-recorded by being irradiated to.

As can be seen from the above description, the present invention is installed on the upper surface of the rotating plate reflector for reflecting the laser beam applied from the laser beam generating unit at a constant angle, and the rotating plate is rotated at a constant speed by the rotating motor Let the reflector rotate at constant speed with the rotation of the rotating motor. The rotating plate is detected by the rotation angle sensor and applied to the microcomputer, and the microcomputer controls the operation of the laser beam generator according to a signal applied from the rotation angle sensor to intercept the irradiation of the laser beam according to the rotational position of the reflector. Done. Therefore, since the irradiation of the laser beam is interrupted by the control of the microcomputer according to the rotational position of the reflecting mirror fixed to the upper surface of the rotating plate, the laser beam can be irradiated to the desired position of the hologram recording element at high speed accurately.

Claims (1)

A beam splitter 52 for separating the laser applied from the laser beam generator 50 into two reference lights 82 and object light 84 having the same ratio; A rotation reflector 54 reflecting the object light applied through the beam splitter at a predetermined angle; A spatial light modulator (56) for modulating the data applied from the data generator (58) by the object light reflected from the rotating reflector; An imaging lens for focusing object light including data applied from the spatial light modulator; A rotating plate 62 having a reflector reflecting a laser beam mounted on and fixed to an upper surface thereof; A rotating motor 68 for rotating the rotating plate at a constant speed; A rotation angle sensor 70 for detecting a rotation angle of the rotation plate; A hologram recording element (66) for storing hologram data generated by interference between an object light carrying the data and a reference light applied through a reflecting mirror of a rotating plate; An imaging unit (CCD) 72 for imaging hologram data applied through the hologram recording element 66; The storage angle multiplexing of hologram data storage connected to the rotation angle sensor 70 and the laser generator 50 and composed of a microcomputer 80 controlling the operation of the laser generator according to a signal applied from the rotation angle sensor. Device.