KR100601951B1 - A holographic data recording/reproducing apparatus, and a holographic data recording method - Google Patents

Abstract

Disclosed are a holographic information recording apparatus capable of simply and inexpensively mass copying a holographic information recording medium and a holographic information reproducing apparatus for reproducing data stored in the holographic information recording apparatus. According to one type of the invention, a holographic information recording apparatus for recording data in the form of a hologram on a holographic information storage medium comprises: a beam splitter for dividing a light beam from a light source into a signal beam and a reference beam; A data mask having a predetermined data pattern formed to contain data to be recorded on the holographic information storage medium in the signal beam, the data mask being spaced apart from a surface of the holographic information storage medium by a predetermined distance; And a mirror reflecting the reference beam such that the reference beam is incident on the entire surface of the holographic information storage medium in parallel with uniform intensity.

Holographic information recording / reproducing apparatus, holographic information recording medium, reference beam, signal beam, wedge prism, lens, photodetector, mirror, beam splitter

Description

A holographic data recording / reproducing apparatus, and a holographic data recording method

1A and 1B illustrate the principle of recording and reproducing data using holograms.

2 schematically shows a holographic information recording apparatus according to the prior art.

3 schematically shows a holographic information reproducing apparatus according to the prior art.

4 schematically shows a holographic information recording apparatus according to the present invention.

5A and 5B illustrate a rotation state of the reference beam according to the rotation of the holographic information storage medium on which information is recorded according to the present invention.

6A and 6B schematically show a holographic information reproducing apparatus according to the present invention.

7A and 7B are perspective views of the wedge prism used in the present invention.

8A and 8B show the change of the refraction angle with the relative rotation angle of the two wedge prisms.

※ Explanation of code about main part of drawing ※

30 ... Holographic information storage media

41 ..... light source 42 ..... reference beam refraction

43 ..... Wedge Prism 44 ..... Lens

45 ..... Transflective mirror 47 ..... Photodetector

The present invention relates to a holographic information recording and reproducing apparatus. More particularly, the present invention relates to a holographic information recording apparatus and a data stored in the holographic information recording apparatus capable of easily and inexpensively mass copying a holographic information recording medium. A holographic information reproducing apparatus for reproducing.

Recently, optical storage technology using holograms has attracted attention. Hologram is a technology that can reproduce an optical signal as it is, and is a technology that can reproduce a signal as a stereoscopic image by recording an interference fringe between a signal beam containing a signal and a reference beam that is straight at a different angle from the signal beam. . According to the storage method using such a hologram, even information stored in a spatially overlapping manner can be read separately from each other by an appropriate multiplexing technique. In addition, since it is possible to implement reading in units of pages in which two-dimensional images are reproduced at once, it is possible to implement a super capacity storage system.

1A shows the principle of recording data using a hologram. As shown, the laser beam 1 is split into a signal beam 5 and a reference beam 6 on which a signal is to be carried by a beam splitter 2. The signal beam 5 is modulated into a two-dimensional signal pattern while passing through a spatial light modulator (SLM) and then incident on the recording medium 7. On the other hand, the reference beam 6 is reflected by the mirror 3 and is incident on the recording medium 7 obliquely at a predetermined angle. At this time, the reference beam 6 and the signal beam 5 interfere with each other, and the resulting interference pattern is recorded on the recording medium 7.

Fig. 1B shows the principle of reproducing the recorded data using the hologram. When the information is reproduced, the recording medium 7 is irradiated using a laser 8 that emits a beam of the same wavelength as the reference beam 6 used when storing the information. At this time, the laser should be irradiated at the same angle as at the time of recording. Then, a two-dimensional signal pattern containing the original information is reproduced, and the signal pattern is read by detecting it with a detector 9 such as a CCD (Charge Coupled Device).

By the way, according to the holographic information storage technology, since the reference beam and the signal beam are sequentially irradiated to the local portions of the recording medium to store the data, the development of the system technology of the WORM method or the RW method has been advanced. Therefore, mass distribution of the same title through a fast data copying technique such as ROM was not possible. To solve this problem, the holographic information storage device shown in FIG.

A method of recording data at high speed using the holographic information storage device of FIG. 2 will now be described. First, as shown in FIG. 1A, a beam splitter (not shown) separates a beam emitted from a laser (not shown) into a signal beam 16 and a reference beam 18. The separated signal beam 16 is uniformly incident on the entire transmissive data mask 12, converted into a two-dimensional data pattern, and then incident on the storage medium 10 as a whole. The data pattern 12 to be recorded on the storage medium 10 is formed in the transmissive data mask 12 in advance. At this time, the data pattern, for example, a plurality of pit (pit) having a variety of lengths, such as a general CD or DVD may be made in the form of a spiral arrangement.

On the other hand, the reference beam 18 separated from the beam splitter is uniformly incident on the conical mirror 14. The conical mirror 14 reflects the incident reference beam 18 so that the reflected reference beam 18 is uniform at an angle to the entire holographic storage medium 10 with respect to the center of the holographic storage medium 10. To be incidentally. Then, the signal beam 16 passing through the transmission data mask 12 and the reference beam 18 interfere with each other, and the data contained in the signal beam 16 is recorded in the holographic form in the holographic storage medium 10. do.

At this time, multiple data can be superimposed in the same storage medium 10 using angular multiplexing. That is, data is recorded in the storage medium 10 in the same manner as described above, and then the signal beam 16 is passed through another transmission type data mask in which a new data pattern is formed to enter the storage medium 10. Then, the reference beam 18 is incident on the conical mirror 14 having different inclination angles so that the reference beam 18 is uniformly incident on the storage medium 10 at different angles. Then, as before, the signal beam 16 and the reference beam 18 interfere with each other, and the data contained in the signal beam 16 is recorded in the holographic form in the holographic storage medium 10. Here, when the incident angles of the reference beams 18 incident on the storage medium 10 are different from each other by a predetermined angle or more, new data may be recorded at the position of the same storage medium 10 without first damaging the recorded data. Can be.

Reproduction of data uses the principle of phase conjugate holography. That is, when the phase conjugate reference beam 22 corresponding to the phase conjugate of the reference beam 22 is incident at a predetermined angle in the rotating medium 10 in the opposite direction to the reference beam used at the time of recording, the phase of the signal beam used at the time of recording A conjugate signal beam is generated. When the phase-conjugated signal beam thus generated is detected by the detector 25 through the pickup lens 23, the data recorded in the storage medium 10 can be reproduced. In this case, the phase-conjugated signal beam contains not only one pit or bit signal but all data patterns within the region where the phase-conjugated reference beam 22 is incident. It is necessary to place an aperture (not shown) in front of the detector 25 so as to select only. On the other hand, in the case where data is superimposed through angular multiplexing, when the incident angle of the phase conjugated reference beam 22 is changed, other data superimposed and recorded at the same position of the storage medium 10 can be reproduced.

According to this recording method, data can be recorded on the whole holographic storage medium by only one laser irradiation, and thus, it is possible to replicate at a very high speed. In this method, however, the reference beam needs to be incident on the storage medium with a very uniform angle and intensity. To do this, a conical mirror with a very uniform angle of inclination must be produced, which is technically very difficult and expensive. In addition, since the reference beam must be obliquely incident on the storage medium during reproduction, and the angle of incidence of the reference beam must be changed when angular multiplexing is used, there is a problem that it is not easy to properly configure the shape and arrangement of the pickup.

The present invention is to improve the above conventional problems.

Accordingly, it is an object of the present invention to provide a holographic information recording apparatus and method capable of high speed duplication capable of irradiating a storage medium uniformly with a reference beam when recording data on a holographic storage medium.

In addition, another object of the present invention is to provide a holographic information reproducing apparatus that can adjust the incident angle of the reference beam without moving the optical pickup.

According to one type of the invention, a holographic information recording apparatus for recording data in the form of a hologram on a holographic information storage medium comprises: a beam splitter for dividing a light beam from a light source into a signal beam and a reference beam; A data mask having a predetermined data pattern formed to contain data to be recorded on the holographic information storage medium in the signal beam, the data mask being spaced apart from a surface of the holographic information storage medium by a predetermined distance; And a mirror reflecting the reference beam such that the reference beam is incident on the entire surface of the holographic information storage medium in parallel with uniform intensity.

According to another type of the invention, an information recording method for recording data in the form of a hologram on a holographic information storage medium comprises the steps of: a) dividing a light beam from a light source into a signal beam and a reference beam; b) embedding data to be recorded on the holographic information storage medium in the signal beam using a data mask in which a predetermined data pattern is formed in advance; c) irradiating the signal beam to an entire surface of the holographic information storage medium; And d) irradiating the reference beam in parallel with uniform intensity over the other surface of the holographic information storage medium by using a mirror.

According to another type of the invention, holographic information reproduction comprising a reference beam optical system for locally injecting a reference beam into the holographic information storage medium and a light detector for receiving a signal beam reproduced from the holographic information storage medium. An apparatus, wherein the reference beam optics comprises: a light source for generating a reference beam; A reference beam refracting portion that refracts the reference beam generated by the light source at a predetermined angle and rotates at the same speed as that of the holographic information storage medium; And condensing the reference beam refracted at a predetermined angle by the reference beam refraction unit on the holographic information storage medium, and focusing on the point where the holographic information storage medium and the optical axis meet with the rotation of the reference beam refraction unit. It characterized in that it comprises a; condensing unit to rotate the reference beam in a conical shape.

Hereinafter, with reference to the accompanying drawings, a holographic information recording apparatus and method, and a holographic information reproducing apparatus according to an embodiment of the present invention will be described in detail.

4 is a schematic diagram of a holographic information recording apparatus according to the present invention. The light beam generated from a light source such as a laser (not shown) is separated into a signal beam 36 and a reference beam 38 by a beam splitter (not shown) as in the prior art. The separated signal beam 36 is uniformly incident on the entire transmissive data mask 34 spaced apart from one side of the holographic information storage medium 30 by a predetermined distance. As in the prior art, a predetermined data pattern to be recorded on the holographic information storage medium 30 is formed in the transmissive data mask 34 in advance. Here, the data pattern may be formed in a form in which a plurality of pits having various lengths are spirally arranged, such as a general CD or a DVD. By passing through the transmissive data mask 34, the signal beam 36 includes data information to be recorded in the holographic information storage medium 30. In this way, the signal beam 36 including the data information is incident on the entire area of the holographic information storage medium 30.

On the other hand, the reference beam 38 separated by the beam splitter is reflected by the mirror 32 and is incident on the other side of the holographic information storage medium 30 with uniform intensity. In this case, the mirror 32 is selected such that the reference beam 38 is incident in parallel to the entire area of the holographic information storage medium 30 (that is, the incident direction and the incident angle are constant). For example, the mirror 32 may be a planar mirror. Then, the signal beam 36 passing through the data mask 34 and the parallel reference beam 38 interfere with each other, and the data contained in the signal beam 36 is transferred to the holographic information storage medium 30. Are recorded in the form.

Here, according to the present invention, angle multiplexing can be used for high density recording of information. In other words, when multiple data are to be superimposed on the same position of the holographic information storage medium 30 in the multiple positions, the data mask 34 is replaced with another data pattern, and the mirror 32 is replaced. By changing the incident angle of the reference beam 38, and then repeating the above-described information recording process. To this end, the mirror 32 should be adjustable in angle, and the data mask 34 should be replaceable. For example, the mirror 32 may be configured to rotate by a predetermined angle using a stepping motor or the like. At this time, the angle at which the mirror 32 is rotated at one time should be equal to or greater than the minimum angle (that is, Δθ) that allows angle multiplexing without damaging previously recorded data. In this way, the high density multiplexing is performed by multiplexing the incident angle of the reference beam 38 while changing the data mask 34. That is, each time the data of the new data mask 34 is recorded, the angle of incidence of the reference beam 38 incident on the holographic information storage medium 30 by changing the angle of the mirror 32 as described above is determined. Change.

Next, the holographic information reproducing apparatus according to the present invention will be described with reference to FIGS. 6A and 6B. The holographic information reproducing apparatus for reproducing information from the holographic information storage medium 30 in which data information is recorded according to the above-described method, as shown, localizes a reference beam to the holographic information storage medium 30. And a photodetector 49 for receiving a signal beam reproduced from the holographic information storage medium 30 and a reference beam optical system 48 for incidentally.

Here, the reference beam optical system 48 includes: a light source 41 for generating a reference beam such as a laser; A reference beam refracting portion (42) for refracting the reference beam generated by the light source (41) at a predetermined angle and rotating at the same speed as the rotational speed of the holographic information storage medium (30); And condensing the reference beam refracted at a predetermined angle by the reference beam refraction unit 42 on the holographic information storage medium 30, thereby storing the holographic information according to the rotation of the reference beam refraction unit 42. And a light collecting portion 44 for rotating the reference beam in a conical shape about the point where the medium 30 and the optical axis meet.

In this case, the reference beam refraction portion 42, as shown in Figure 7a and 7b, includes at least two wedge prism (43a, 43b) having a form in which one side of the cylindrical glass is cut obliquely, The refractive angle of the reference beam can be adjusted by changing the relative rotation angles of the at least two wedge prisms 43a and 43b. The light collecting unit 44 may focus at least two lenses 44a on the holographic information storage medium 30 to collect the reference beam refracted by the reference beam refraction unit 42 at a predetermined angle. , 44b). In this case, although the at least two lenses 44a and 44b are shown as convex lenses, the present disclosure is not limited thereto, and the same effect may be obtained by properly arranging different types of optical elements.

Meanwhile, the light detector 49 receives the transflective mirror 45 for reflecting the signal beam reproduced from the holographic information storage medium 30, the condenser lens 46 for condensing the signal beam, and the signal beam. And a photodetector 47 for converting to an electrical signal. At this time, as in the prior art, since the reproduced signal beam does not contain only one pit or bit signal, but includes all data patterns in the region where the reference beam is incident, only the desired pit or bit signal among them. An aperture (not shown) may be additionally placed in front of the photodetector 47 for selection.

The operation of the holographic information reproducing apparatus according to the present invention having such a configuration will now be described.

As in the prior art, the data recorded on the holographic information storage medium 30 is reproduced using the principle of phase conjugate holography. That is, the phase-conjugated reference beam corresponding to the phase conjugate of the reference beam is incident on the rotating storage medium 30 in the opposite direction of the reference beam used for recording (that is, the direction in which the signal beam is incident). Therefore, the reference beam generated by the light source 41 is a beam corresponding to the phase conjugate of the reference beam at the time of recording.

The reference beam generated by the light source 41 is incident on the reference beam refracting portion 42. As described above, the reference beam refracting portion 42 includes at least two wedge prisms 43a and 43b. The reason for using the two wedge prisms 43a and 43b is to change the relative rotation angle of the two wedge prisms so that the angle of incidence of the reference beam incident on the holographic information storage medium 30 can be adjusted. . The relative rotation angle between the wedge prisms 43a and 43b may vary from 0 ° to 180 °. 8A shows a case where the relative rotation angles of the two wedge prisms 43a and 43b are 0 degrees. As shown, the angle of refraction is maximum in this case. On the other hand, Figure 8b is a case where the relative rotation angle of the two wedge prism is 180 °. As shown, the angle of refraction is minimal in this case. In this way, by adjusting the angle of incidence of the reference beam by changing the relative rotation angle between the two wedge prisms, the superimposed information can be reproduced by using the angle multiplexing method. Therefore, when the incidence angle of the reference beam required to reproduce the specific data recorded on the holographic information storage medium 30 is determined, the reference beam is appropriately selected by appropriately selecting the relative rotation angle between the two wedge prisms 43a and 43b. This is done by adjusting the refraction angle of.

The reference beam refracted at a specific angle in the reference beam refraction portion 42 is incident on the light collecting portion 44. The condenser 44 is for condensing the reference beam locally at a specific point on the holographic information storage medium 30. More specifically, the condenser 44 allows the reference beam to enter the point where the optical axis indicated by the dotted line and the holographic information storage medium 30 meet. To this end, the light collecting part 44 is composed of at least two lenses 44a and 44b. The two lenses 44a and 44b cause the reference beam refracted by the reference beam refraction unit 42 to deviate from the optical axis again to converge toward the optical axis.

On the other hand, when recording data on the holographic information storage medium 30 in the present invention, since the reference beam is incident in parallel and uniformly throughout the holographic information storage medium 30, the holographic data is reproduced when the data is reproduced. As the information storage medium 30 rotates, the reference beam also needs to rotate. The reason can be understood with reference to FIGS. 5A and 5B. In the conventional case using a conical mirror, a reference beam is incident to be radially symmetric about the center of the storage medium. However, in the present invention, as shown in FIG. 5A, the reference beam is incident in parallel to the entirety of the storage medium 30. When the holographic information storage medium 30 in which data is recorded is rotated at a predetermined angle, as shown in FIG. 5B, the direction of incidence of the reference beam must also be rotated by the same angle to reproduce the desired information.

To this end, in the holographic information reproducing apparatus according to the present invention, the reference beam refracting portion 42 rotates at the same rotational speed as the holographic information storage medium 30. As the reference beam refraction 42 rotates, as can be seen by comparing FIGS. 6A and 6B, the reference beam generated from the light source 41 meets the holographic information storage medium 30 and the optical axis indicated by the dotted line. Rotate conically around the point. Therefore, by changing the incident direction while making the incident angle of the reference beam constant, it is possible to reproduce the information recorded according to the recording method of the present invention.

In this way, when the reference beam is incident on the holographic information storage medium 30, a phase conjugate signal beam is generated from the holographic information storage medium 30. The signal beam is reflected toward the condenser lens 46 by the transflective mirror 45 and finally received by the photodetector 47. The photodetector 47 is a photosensitive element such as a CCD as in the related art, and converts a signal pattern of a signal beam into an electrical signal. In this case, as described above, the reproduced signal beam does not contain only one pit or bit signal, but includes all data patterns within the region where the reference beam is incident. An aperture (not shown) may be additionally placed in front of the photodetector 47 so that the user can select only the desired pit or bit signal.

According to the present invention, since the wedge prism, the lens, the mirror, etc. used in the present invention can be manufactured relatively precisely and easily compared to the conical mirror, the holographic information recording apparatus can be provided in a relatively inexpensive and simple manner as compared with the prior art. have. Furthermore, according to the present invention, there is an advantage in that angle multiplexing can be achieved by simply adjusting the angle of the mirror without having to use several conical mirrors having different angles.

In addition, according to the holographic information reproducing apparatus according to the present invention, since the incident angle of the reference beam can be adjusted using two wedge prisms, the pickup can be simply configured in the related art.

Claims (11)

A holographic information recording apparatus for recording data in the form of a hologram on a holographic information storage medium, A beam splitter for dividing the light beam from the light source into a signal beam and a reference beam; A data mask having a data pattern formed to contain data to be recorded on the holographic information storage medium in the signal beam, the data mask being spaced apart from one surface of the holographic information storage medium; And And a mirror reflecting the reference beam such that the reference beam is incident on the entire area of the other surface of the holographic information storage medium in parallel with uniform intensity. The mirror is a holographic information recording device, characterized in that the angle can be adjusted through rotation. delete The method of claim 1, And the mirror is a planar mirror. delete The method of claim 3, wherein And the data mask is replaceable. An information recording method for recording data in the form of a hologram on a holographic information storage medium, a) dividing the light beam from the light source into a signal beam and a reference beam; b) embedding data to be recorded on the holographic information storage medium in the signal beam using a data mask in which a data pattern is formed in advance; c) irradiating the signal beam to an entire surface of the holographic information storage medium; d) irradiating the reference beam in parallel to the entire area of the other surface of the holographic information storage medium with uniform intensity using a mirror; e) replacing the data mask with another data mask having a different data pattern formed when recording of the data on the holographic information storage medium is completed; And and f) changing the angle of the mirror by rotating the mirror, and repeating the steps a) to d). delete A holographic information reproducing apparatus comprising a reference beam optical system for locally injecting a reference beam into a holographic information storage medium and a light detector for receiving a signal beam reproduced from the holographic information storage medium. : A light source generating a reference beam; A reference beam refracting portion that refracts the reference beam generated by the light source to deviate from the optical axis and rotates at the same speed as that of the holographic information storage medium; And By condensing the reference beam refracted by the reference beam refracting portion on the holographic information storage medium, the reference beam is conical about the point where the optical axis meets the holographic information storage medium according to the rotation of the reference beam refracting portion. Holographic information reproduction apparatus comprising a; condensing unit to rotate. The method of claim 8, And the reference beam refracting portion includes two wedge prisms. The method of claim 9, And adjusting the refractive angle of the reference beam by changing the relative rotation angles of the two wedge prisms. The method according to any one of claims 8 to 10, And the condenser comprises two lenses.

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