CN211879015U - Holographic optical disk reading device and recording/reproducing device capable of high-speed parallel reproduction - Google Patents

Abstract

The patent of the utility model relates to a holographic CD reading device and record/reappear device that high-speed parallel reappears belongs to light holographic storage technical field. The angle-shift multiplexing method according to the present patent performs multiplex recording by simultaneously changing the reference light incident angle and the moving medium by a fixed angle change amount and a shift amount. In this method, the reference beam is split and incident, and holograms in different cells are simultaneously reproduced. The method disclosed by the patent can also read and write the recorded hologram in real time, and can check the recorded signal under the condition of meeting the response time required by the medium.

Description

Holographic optical disk reading device and recording/reproducing device capable of high-speed parallel reproduction

Technical Field

The utility model belongs to the technical field of the holographic storage of light, concretely relates to holographic CD reading device and record/reappear device that high-speed parallel reappears.

Background

The reference light wave used in the angular multiplexing recording method is a plane wave, and multiplexing/recording is realized by changing the angle at which the reference beam is incident on the recording medium. In the method, the original hologram cannot be reproduced only by changing the incident angle of the reference light by about 0.1 degrees, a new hologram can be recorded at the angle, and the multiplexing recording can be realized for about 100 times by repeating the operation for many times. In this method, the angle selectivity is determined by the bragg condition, and since a thick film medium is used, the intensity of the reproduction light is very sensitive to angle variation, and the reproduction light intensity is greatly reduced in the case where the angle variation is 0.1 °. However, since the incident position of each hologram and the incident angle of the signal light are fixed values, noise is accumulated at the time of multiplex recording, that is, cross-write noise, resulting in a decrease in the signal-to-noise ratio. In addition, the variation range of the incident angle of the reference light is limited. The accumulation of noise and the variation range of the incident angle simultaneously limit the storage capacity of the system, and therefore, a shift multiplexing recording technique that is not constrained by these two conditions is introduced into the angle multiplexing method, thereby increasing the storage capacity of the system. On the other hand, it has been proposed in the application of another patent by the same applicant that the storage capacity can be increased by combining angle multiplexing and shift multiplexing, and it is known from theoretical calculation results that the storage capacity of about 600TB to 1.2PB can be achieved by using an optical disc having a diameter of 120 mm. In view of the fact that high-speed recording/reproduction becomes a big problem as the capacity of optical discs increases, the present patent discloses a holographic optical disc reading method and apparatus for high-speed reproduction.

SUMMERY OF THE UTILITY MODEL

This patent is directed to overcoming at least one of the deficiencies of the prior art mentioned above and providing a holographic disk reading method and apparatus for high speed parallel reconstruction.

A holographic optical disk reading method for high-speed parallel reproduction is characterized in that multiplexing recording of holograms is carried out by linearly moving a medium and changing the incident angle of reference light at each shift position, and the holograms at corresponding positions are subjected to beam splitting incidence of the reference light in the reproduction process to realize high-speed parallel reading of information.

Specifically, the split reference light is incident on the storage medium at the same incident angle.

Specifically, the reading position of the multiplexed recording hologram is adjusted by changing the interval of each beam of reference light.

In particular, parallel reading can be achieved in that the hologram sequences are parallel to each other in a direction perpendicular to the shift direction.

Specifically, when each reference light of the bragg condition needs to be corrected, the incident angle and the wavelength of each light beam can be determined at one time.

Specifically, when the bragg conditions are mismatched, the incident angles of the plurality of beams of reference light can be independently changed to improve the signal-to-noise ratio.

The present patent also provides a hologram recording/reproducing apparatus for implementing high-speed reading of the above method.

In the method for reading the holographic optical disc reproduced in parallel at high speed, aiming at the storage medium at least comprising the shift multiplexing, in the reproduction process, the reference light is split and is respectively incident to a plurality of different positions on the storage medium at the same angle as the shift multiplexing recording, so that the parallel reading of the holograms at the different positions is realized.

In the holographic optical disk reading method for high-speed parallel reproduction, aiming at a storage medium at least comprising angle-shift multiplexing, in the reproduction process, reference light is split and is incident to a plurality of different positions on the storage medium, and the incident angle is the incident angle of the plurality of different positions in the angle multiplexing recording.

In the method for reading the holographic optical disc reproduced in parallel at high speed, for a storage medium at least comprising unit storage, angle-shift multiplexing storage is adopted in each unit, in the reproduction process, reference light is split, a plurality of beams of split reference light correspond to a plurality of incidence positions with the distance of shift step length on the storage medium, and the incidence angle is the incidence angle when angle multiplexing recording is carried out at different positions in the unit.

Specifically, the incident angles of the plurality of beam-split reference lights differ by an equal angle a.

Specifically, the incident position of the reference light in the unit is changed by moving, and the incident angles of the plurality of beams of reference light after all beams are split are correspondingly changed synchronously according to the corresponding reference light angles at different incident positions during recording.

The recording rule of the holograms in the unit is shift multiplexing along a certain direction x direction and shift multiplexing along a direction y perpendicular to the x direction, the shift step dx of the x direction is different from the shift step dy of the y direction, and during recording, the distance dx is moved, the incident angle of the reference light is changed by delta theta, the distance dy is moved, and the incident angle of the observation light is changed by a.

Furthermore, during the reproduction process, the plurality of beam-split reference lights are distributed along the y direction, and the incident angles are different by an equal angle a.

Further, during reproduction, the incident position of the reference light in the cell is changed by a distance dx while moving in the x direction, and the incident angles of all the reference lights are changed by Δ θ in synchronization.

In the method for reading the holographic optical disc reproduced in parallel at high speed, aiming at the storage media at least comprising unit superposition storage, angle-shift multiplexing storage is adopted in each unit, in the reproduction process, reference light is split, a plurality of beams of reference light are split on the storage media and correspond to the incidence positions of the superposition sizes of a plurality of interval storage units, and the incidence angles are the incidence angles when angle multiplexing recording is carried out at different positions in the units.

Specifically, the incident angles of the plurality of beams of beam-split reference light are the same, and the incident positions are the same in each unit.

Specifically, the incident position of the reference light in the unit is changed by moving, and the incident angles of the plurality of beams of reference light after all beams are split are correspondingly changed synchronously according to the corresponding reference light angles at different incident positions during recording.

The rule of hologram recording in each unit at least includes shift multiplexing along a certain direction x direction, the shift step dx along the x direction, during recording, the moving distance dx, the change of the incident angle of the reference light Δ θ, the dimension width of the hologram information in the x direction is defined as Rx, dx is Rx/n, n is the shift multiplexing number of the hologram in the x direction, the dimension of the unit x direction is 2Rx, the storage medium includes a plurality of units which are mutually overlapped, the overlapping direction at least along the x direction, and the overlapping area dimension of two different units which are mutually overlapped is Rx.

Further, in the reproduction process, the split beam of reference light is distributed along the x direction, and the incident positions are different by Rx or an integral multiple of Rx.

Further, during reproduction, the incident position of the reference light in the cell is changed by a distance dx while moving in the x direction, and the incident angles of all the reference lights are changed by Δ θ in synchronization.

Based on the above principle, this patent further provides a parallel checking method for the recording process of the holographic disk, in the recording process, the reference light is split into at least two beams, one beam is the recording reference light, which interferes with the signal light to record information on the holographic disk, and the other reference lights are the checking reference lights, which are used to read the information recorded on the holographic disk, to form the checking signal, which is used to check whether the recorded information is accurate.

Specifically, the recording is realized by a shift multiplexing method, and the inspection reference light and the recording reference light have the same incident angle and are separated by integral multiple of shift step length.

Specifically, the recording is realized by using an angle-shift multiplexing method, the incident position of the recording reference light is moved by a shift step dx, the incident angle is changed by Δ θ, the change rule of the incident angle of the inspection reference light and the incident angle of the recording reference light is the same, the distance between the inspection reference light and the recording reference light is an integer i times of the shift step L, i is L/dx, and the incident angle lags behind the recording reference light by Δ θ × i.

Based on the above reading method, the present patent provides a high-speed parallel reproduction holographic optical disc reading apparatus, which at least includes a light source, a reference optical path, a reading apparatus and a medium platform, wherein light emitted by the light source forms reference light transmitted along the reference optical path after beam splitting, the reference light generates signal light reproduction on a storage medium supported by the medium platform, and the reading apparatus reads the signal light.

Specifically, for reading the shift-multiplexed storage medium, the beam splitter splits the reference light and makes the reference light incident on a plurality of different positions on the storage medium at the same angle as that for shift-multiplexed recording, so as to realize parallel reading of the holograms at the plurality of different positions.

Specifically, for reading the angle-shift multiplexed storage medium, the beam splitter splits the reference light to be incident on a plurality of different positions on the storage medium, and the incident angle is the incident angle of the plurality of different positions during angle multiplexing recording.

Specifically, for the storage medium stored in the reading unit, angle-shift multiplexing storage is adopted in each unit, the beam splitter splits the reference light, a plurality of beams of the reference light after splitting correspond to a plurality of incident positions with a distance of a shift step length on the storage medium, and the incident angle is the incident angle when angle multiplexing recording is performed at different positions in the unit.

Specifically, the rules of hologram recording in the unit are shift multiplexing along a certain direction x direction and shift multiplexing along a direction y perpendicular to the x direction, the shift step dx in the x direction is different from the shift step dy in the y direction, and during recording, the distance dx is moved, the incident angle of the reference light is changed by Δ θ, the distance dy is moved, and the incident angle of the viewing light is changed by a.

Specifically, the beam splitter splits the reference light so that the reference light beams are distributed along the y direction, and the incident angles are different by an equal angle a.

Specifically, the beam splitter splits the reference light, the medium platform supports the storage medium to move along the x direction to change the incident position of the reference light in the unit, the incident position changes by a distance dx, and the beam splitter adjusts the incident angles of all the reference light to change by Δ θ synchronously.

Specifically, for the storage media stacked and stored by the reading unit, each unit adopts angle-shift multiplexing storage, the beam splitter splits the reference light, the split beams of reference light correspond to a plurality of incident positions with the interval of the stacking size of the storage unit on the storage media, and the incident angles are the incident angles of the units in different positions during angle multiplexing recording.

The rule of hologram recording in each unit at least includes shift multiplexing along a certain direction x direction, the shift step dx along the x direction, during recording, the moving distance dx, the change of the incident angle of the reference light Δ θ, the dimension width of the hologram information in the x direction is defined as Rx, dx is Rx/n, n is the shift multiplexing number of the hologram in the x direction, the dimension of the unit x direction is 2Rx, the storage medium includes a plurality of units which are mutually overlapped, the overlapping direction at least along the x direction, and the overlapping area dimension of two different units which are mutually overlapped is Rx.

Furthermore, the beam splitter splits the reference light, the multiple reference lights are distributed along the x direction, and the incident positions are different by Rx or integral multiples of Rx.

Further, the beam splitter splits the reference light, the medium platform supports the storage medium to move along the x direction to change the incident position of the reference light in the unit, the incident position changes by a distance dx, and the beam splitter adjusts the incident angles of all the reference light to change by delta theta synchronously.

Based on the above-mentioned inspection method, the present invention further provides a holographic optical disc recording/reproducing apparatus, including a light source, a reference optical path, a signal optical path, a reading apparatus and a medium platform, where light emitted by the light source is split into a reference light transmitted along the reference optical path and a signal light transmitted along the signal optical path, and the reference light and the signal light interfere with each other on a storage medium supported by the medium platform to form holographic storage image information.

Specifically, for the storage medium of read shift multiplexing, the beam splitter splits the reference light, and the inspection reference light and the recording reference light have the same incident angle and are separated by an integral multiple of shift step length.

Specifically, for the storage medium of read angle-shift multiplexing, the beam splitter splits the reference light, the beam splitter controls the incident position of the recording reference light to move by a shift step dx, the incident angle changes by Δ θ, the change rule of the incident angle of the inspection reference light and the incident angle of the recording reference light is the same, the distance between the inspection reference light and the recording reference light is an integer i times the shift step L, i is L/dx, and the incident angle lags behind the recording reference light by Δ θ × i.

Compared with the prior art, the beneficial effect of this patent does:

this patent relates to a hologram recording method that combines the advantages of angle multiplexing and shift multiplexing, which is temporarily referred to as an angle-shift multiplexing recording method. In this method, the hologram is multiplexed and recorded by changing the reference light incident angle and moving the medium at the same time with a fixed angle change and shift amount. Therefore, if the reference light is split into beams and incident, holograms in different cells can be reproduced simultaneously because a plane wave is used as the reference light, whereas this method is difficult if shift multiplexing is performed using a spherical wave as the reference light. When multiplexing recording is carried out by the method, the recording intervals of the holograms in all the hologram sequences are the same in the direction perpendicular to the shifting direction, and the recording tracks of the holograms with the same incident angle of the reference light, which are corresponding positions in different hologram sequences, are parallel to each other, so that the reading speed can be further improved by simultaneously and parallelly reproducing the holograms with different sequences.

The method of the present disclosure may also implement a Read after Write (Write) check function. In general, in the process of recording a hologram, a photopolymer storage medium requires a certain response time to complete a single recording, and it is not possible to perform an inspection at the same time as recording. Usually, laser light of another wavelength, which is not absorbed by the medium material, can be used for irradiation to achieve write-while-read by diffracting the light intensity, but from the viewpoint of the storage system, the input signal is not checked, and the reliability of the method remains questionable. However, the method of the patent can realize the function of reading immediately after writing, and the input signal is checked under the condition of meeting the response time required by the medium.

Drawings

Fig. 1 is a schematic diagram of angle multiplexing recording.

Fig. 2 is a schematic diagram of shift multiplexing recording.

Fig. 3 is a schematic diagram of angle-shift multiplexing recording.

Fig. 4 is a two-dimensional angle-shift multiplexing recording schematic diagram.

Fig. 5 is a block diagram of an angle multiplexing-shift multiplexing recording hologram.

Fig. 6 is a schematic diagram of a two-dimensional angle-shift multiplexing recording method.

FIG. 7 is a schematic diagram of an acousto-optic modulator based angle-shift multiplexing memory.

FIG. 8 is a schematic diagram of parallel reading in different blocks of regions.

FIG. 9 is a system diagram of the simultaneous read and write schematic.

FIG. 10 is a schematic diagram of a holographic multiplexing recording process.

Fig. 11 is a hologram optical recording/reproducing apparatus for high-speed parallel reproduction.

Device description: 10: laser, 20: shutter (AOM), 30: polarizing plate, 40: anamorphic prism set, 50: polarizing beam splitter prism, 51: first polarizing beam splitting prism, 52: second polarizing beam splitter prism, 60: attenuator, 70: half wave plate, 80: mirror, 81: first mirror, 82: second mirror, 90: acousto-optic modulator (AOM), which can be replaced by a galvanometer, 100: beam expanding collimator, 101: first beam expander collimator, 102: second beam expander collimator, 110: spatial light modulator, 120: relay lens group, 130: fourier lens, 131: first fourier lens, 132: second fourier lens, 140: holographic disk, 150: a camera.

Detailed Description

The drawings are only for purposes of illustration and are not to be construed as limiting the patent. For a better understanding of the following embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The conventional angle multiplexing method uses the principle of angle multiplexing recording using a plane wave as reference light, which is a method of repeatedly implementing multiplexing recording by changing the incident angle of reference light at the same position of the medium as shown in fig. 1. When holograms are recorded at the same position a predetermined number of times, a next round of hologram multiplex recording is similarly performed at adjacent positions that do not overlap. During reconstruction of the hologram, the medium is illuminated with reference light only and a filter (polytopic filter) is provided to prevent cross-talk elsewhere.

In contrast, fig. 2 illustrates the shift multiplexing recording principle using a spherical wave as a reference light, and after recording a hologram, if the medium moves a small distance in the axial direction, the hologram cannot be reproduced, and then a new hologram can be recorded to realize shift multiplexing. Specifically, when the medium moves by several micrometers, the bragg condition formed by the signal light, the reference light, and the grating vector is destroyed, so that the hologram cannot be reproduced. The signal beam k can be known from the Bragg principle_sReference beam k_rSum raster vector k_gThe medium only needs to move by several microns, the original triangle is damaged, and the hologram can not be reproduced. However, the amount of displacement for making the reproduction light disappear in the axial direction is very short, but the shift selectivity in the direction perpendicular to the axial direction is weak, and high-density recording cannot be performed. Therefore, shift multiplex recording is first performed in the axial direction, and recording tracks are arranged in parallel in a direction perpendicular to the recording direction and holograms are recorded, forming a hologram array of two-dimensional shift multiplex recording. Then, recording is performed in the plane of the medium by using cross-multiplexingThe method increases the number of multiplexes.

A combination of the above-described methods of angle multiplexing and shift multiplexing has been proposed in previously filed patents to achieve higher density storage, as shown in fig. 3. In FIG. 3, the holograms are indicated by circles having a diameter of 500 μm, and the medium is moved to the left while recording the holograms using a short pulse laser from a light source. Theoretically the system is capable of 800 reuses. In fig. 3, a first hologram is recorded by reference light at an initial incident angle, and then the change Δ θ of the incident angle of the reference light is 0.1 ° every time dx is moved to the right by 5 μm, while recording one hologram, resulting in a sequence of 100 holograms aligned. Since the incident angle of the reference light is different when each hologram is recorded, crosstalk does not occur even if a plane wave is used as the reference light. In the sequence of holograms, the reference light incidence angle ranges from 0 ° to 9.9 °. After recording 100 holograms, the next hologram has been disjoint from the first hologram, so the next sequence of holograms can be re-recorded to the right, again with a shift of 5 μm each and a change of 0.1 ° in the angle of incidence of the reference light each. That is, the shift step dx in the x direction is 5 μm, the number of times of shift multiplexing the hologram image information in the x direction is 100, and the angle d θ of the reference beam changes to 0.1 ° for each multiplexing.

As shown in fig. 5. In the present embodiment, the total multiplexing number is 800, and the multiplexing number of each sequence shift is 100, so that 8 hologram sequences can be recorded in the same direction on the same line. In order to increase the number of multiplexes, the method of recording using two-dimensional shift multiplexing is shown in fig. 4, and after moving by 62.5 μm in the direction perpendicular to the shift multiplexing, the above-described steps are repeated to record a new line of holograms to the right. Since the hologram diameter is 500 μm and the shift pitch is 62.5 μm, after 8 lines of holograms are thus recorded, the next line of holograms will be completely separated from the first line of holograms. As shown in fig. 6, the reference light angle for the first recording of holograms is 0 ° to 0.9 °, the reference light angle for the second recording of holograms is 10 ° to 19.9 °, the third row of holograms records 100 holograms with a reference beam angle in the range of 20 ° to 29.9 °, and so on. Therefore, the reference light incident angles of the holograms recorded in the vertical direction are also different, so that crosstalk does not occur and the holograms can be reproduced individually. That is, the shift step dy in the y direction is 62.5 μm, the number of shift multiplexes of the hologram information in the y direction is 8, the angle Δ θ of the reference light is changed to 0.1 ° every time the shift multiplexes in the lateral direction, and the difference between the reference light start angles of the hologram sequences in two adjacent rows is 10 °.

As can be seen from the figure, the hologram information is a circular hologram, that is, Rx is 500 μm, dx is 5 μm, Δ θ is 0.1 °, and a is 10 °

Fig. 7 is an example of a reference light angle changing method that can perform high-speed conversion of reference light angles that can meet system requirements. Here, a method using an ultrasonic deflector is recommended. An acousto-optic modulator (AOD) generates a spectrum consisting of a carrier and sidebands by amplitude modulation, thereby obtaining diffracted light corresponding to the sidebands. In this method, the incident angle of the reference light can be realized by changing the frequency of the amplitude modulation signal. The frequency band of the sidebands is determined by the numerical aperture determination (NA) of the lens L1, and a bandwidth of several tens MHz can be achieved.

Galvanometers may be used instead of AODs.

Fig. 11 shows a high-speed parallel-reproducing holographic optical recording/reproducing apparatus proposed in this patent, which can be implemented in a conventional optical system for angle-multiplexed recording. As shown in the drawing, a high-speed parallel reproduction holographic optical disk reading apparatus may be a reproduction section of a recording/reproducing apparatus, and light emitted as light including a laser 10 passes through a shutter 20, a polarizing plate 30 and a anamorphic prism set 40 in this order, and is divided into a reference optical path and a signal optical path by a first polarization beam splitter prism 51. The signal light passes through the second beam expanding collimator 102, is reflected to the spatial light modulator 110 by the second polarization beam splitting prism 52 to load the signal, passes through the relay lens group 120 and the first fourier lens 131 in sequence by the second polarization beam splitting prism 52 again, and reaches the holographic disk 140. The reference light is reflected by the first mirror 81 after passing through the attenuator 60 and the half-wave plate 70 in sequence, and then enters an Acoustic Optical Modulator (AOM)90 or a galvanometer for angle modulation, the specific modulation principle is shown in fig. 7, and then reaches the holographic disk 140 after being expanded and collimated by the collimating structure formed by the second mirror 82 and the first beam expanding collimator 101. The reference light and the signal light interfere with each other on the holographic disk 140 supported by the medium platform to form holographic storage image information, and the acousto-optic modulator (AOM)90 or the galvanometer is used to control the incident angle of the reference light, so that the incident angle of the reference light and the writing position of the reference light on the storage medium are in one-to-one correspondence.

When the above system is used as a holographic optical disk reading apparatus for high-speed parallel reproduction, a beam splitter is further provided for splitting the reference light and respectively incident on a plurality of different positions on the holographic optical disk 140 at the same angle as the angle at which the holographic optical disk 140 records, thereby forming a plurality of signal lights, and the reading apparatus includes a plurality of cameras 150 respectively reading the different signal lights, as shown in fig. 8.

The above is a description of the recording/reproducing method of this patent, which has been proposed in another patent, called an angle-shift multiplexing method, and discloses a parallel reproducing method and apparatus based on this system. The plane wave light source is adopted as the reference light, the beam splitting of the reference light can be easily realized, and the reference light can be incident to the storage medium at the same angle by adjusting the beam splitter. In the parallel reproduction method and apparatus, the hologram recording is performed using the previously proposed angle-shift multiplexing method. During reproduction, the holograms of the same row and the sequences can be reproduced by the split reference beams respectively. In particular, in the case of multiplex recording, the optical system can adjust the incident angle of the reference light by a fixed value every time of shift, as shown in fig. 8, there are 100 holograms in each sequence, 8 sequences in each row, and the holograms in each sequence are independently reproduced by the split reference light, so that parallel reproduction and high-speed transmission can be realized.

As described above, the rule of recording the hologram in each cell at least includes shift multiplexing in the x direction, a shift step dx in the x direction, a shift distance dx during recording, a change Δ θ in the incident angle of the reference light, a dimension width in the x direction of the hologram information Rx, dx ═ Rx/n, n ═ 100 is the number of times of shift multiplexing of the hologram in the x direction, a dimension in the x direction of the cell is 2Rx, a storage medium includes a plurality of cells stacked on one another, the stacking direction is at least in the x direction, and a stacking area dimension of two different cells stacked on one another is Rx.

The multiple reference beams are distributed along the x direction, the incident positions have the difference Rx of 500 mu m, and the incident angles are the same. The medium platform supports the storage medium to move along the x direction to change the incidence position of the reference light in the unit, the incidence position change distance dx is 5 mu m, and the beam splitter adjusts the incidence angle of all the reference light to synchronously change delta theta by 0.1 deg.

A second parallel reproduction method of the present patent disclosure is shown in fig. 10. The AODs corresponding to the respective beams of reference light have independent driving frequencies in a direction perpendicular to the shift, and the respective columns of holograms arranged in parallel can be simultaneously reproduced.

The recording rule of the holograms in the unit is shift multiplexing along a certain direction x direction and shift multiplexing along a direction y perpendicular to the x direction, the shift step dx of the x direction is different from the shift step dy of the y direction, and during recording, the distance dx is moved, the incident angle of the reference light is changed by delta theta, the distance dy is moved, and the incident angle of the observation light is changed by a.

The beam splitter splits the reference light and distributes the reference light in the y direction, wherein the incident position difference dy is 62.5 mu m, and the incident angle difference a is 10 degrees. The medium platform supports the storage medium to move along the x direction to change the incidence position of the reference light in the unit, the incidence position change distance dx is 5 mu m, and the beam splitter adjusts the incidence angle of all the reference light to synchronously change delta theta by 0.1 deg.

This patent also discloses a parallel reconstruction hologram inspection method, as shown in fig. 9. Both holographic recording and optical disc drives require a "read-after-write check" function for the entire system, which is easily achieved using the method proposed in this patent.

In conjunction with fig. 11, the reference light and the signal light interfere with each other on the storage medium supported by the medium platform to form holographic storage image information, the beam splitter splits the reference light into two beams, one beam is recording reference light and interferes with the signal light to record information on the holographic optical disc, the other beam is inspection reference light, signal light reproduction is generated on the storage medium supported by the medium platform, and the reading device reads the signal light to check whether the recorded information is accurate. As shown in fig. 9, for the storage medium of the read angle-shift multiplexing, the beam splitter splits the reference light, the beam splitter controls the recording reference light incidence position to move by a shift step dx of 5 μm, the incidence angle change Δ θ is 0.1 °, the inspection reference light and the recording reference light have the same incidence angle change law, i is an integer of the shift step L, i is L/dx apart, and the incidence angle lags behind the recording reference light by Δ θ × i.

Obviously, the above embodiments of the present patent are only examples for clearly illustrating the technical solutions of the present patent, and are not intended to limit the specific embodiments of the present patent. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present patent claims should be included in the protection scope of the present patent claims.

Claims (10)

1. A holographic optical disk reading device for high-speed parallel reproduction at least comprises a light source, a reference light path, a reading device and a medium platform, wherein light emitted by the light source forms reference light transmitted along the reference light path after passing through beams, the reference light generates signal light reproduction on a storage medium supported by the medium platform, the reading device reads the signal light, the holographic optical disk reading device is characterized by further comprising a beam splitter which is used for splitting the reference light and enabling the reference light to be incident to a plurality of different positions on the storage medium at the same angle as the angle of the storage medium during recording to form a plurality of signal lights, and the reading device comprises a plurality of reading devices which are used for reading different signal lights respectively.

2. The apparatus of claim 1, wherein for reading the shift-multiplexed storage medium, the beam splitter splits the reference light and makes the reference light incident on a plurality of different locations on the storage medium at the same angle as in shift-multiplexed recording, respectively, to achieve parallel reading of the holograms at the plurality of different locations.

3. The apparatus of claim 1, wherein the beam splitter splits the reference light for reading the angle-shift multiplexed storage medium to be incident on a plurality of different locations on the storage medium, the incident angle being an incident angle at which the plurality of different locations are angle-multiplexed for recording.

4. The apparatus according to claim 1, wherein the storage medium stored in the reading unit is stored in each unit by using angle-shift multiplexing, and the beam splitter splits the reference light into a plurality of beams corresponding to a plurality of incident positions on the storage medium with a shift step distance therebetween, wherein the incident angles are incident angles at different positions in the unit during angle multiplexing recording.

5. The apparatus according to claim 4, wherein the rules of hologram recording in the cell are shift multiplexing in the x direction and shift multiplexing in the y direction perpendicular to the x direction, the shift step dx in the x direction is different from the shift step dy in the y direction, and the distance dx, the reference light incident angle change Δ θ, the distance dy, and the viewing light incident angle change a are moved during recording.

6. The apparatus of claim 5, wherein the beam splitter splits the reference light such that the reference light beams are distributed along the y-direction with the incident angles being different by an equal angle a.

7. The apparatus of claim 6, wherein the beam splitter splits the reference light, the media platform supports the storage media to move along the x-direction to change the incident position of the reference light in the cell, the incident position changes by a distance dx, and the beam splitter adjusts the incident angles of all the reference light to change by Δ θ synchronously.

8. A holographic optical disk recording/reproducing device comprises a light source, a reference light path, a signal light path, a reading device and a medium platform, wherein light emitted by the light source is split into reference light transmitted along the reference light path and signal light transmitted along the signal light path, the reference light and the signal light generate interference on a storage medium supported by the medium platform to form holographic storage image information.

9. The apparatus of claim 8, wherein the beam splitter splits the reference light for reading the shift multiplexed storage medium, the inspection reference light being at the same angle of incidence as the recording reference light by an integer multiple of a shift step.

10. The apparatus according to claim 8, wherein the beam splitter splits the reference light for reading the angle-shift multiplexed storage medium, the beam splitter controls the recording reference light incident position to move by a shift step dx and the incident angle to change by Δ θ, the inspection reference light and the recording reference light are identical in incident angle change law by an integer i times of the shift step L, i ═ L/dx, and the incident angle lags behind the recording reference light by Δ θ × i.

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