JP2013097837A - Hologram reproduction device and retrieval method for optimal value of reproduction-time reference light incident angle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hologram reproduction device and a retrieval method for optimal value of reproduction-time reference light incident angle that are capable of compensating for positional deviation of hologram caused at the time of contraction or expansion of a hologram recording medium with page data information recorded in a multiplex manner or installation of an interchangeable recording medium, or that are capable of shortening time required for the compensation.SOLUTION: A hologram reproduction device includes an information reproduction part for reproducing page data information by emitting reproduction-time reference light to a hologram recording medium 11 with page data information recorded in an angle multiplex recording manner, and uses the information reproduction part to make adjustments so as to obtain a light wave holding the page data information. The device comprises operation means 40 that, at the time of reproducing each piece of the page data information, obtains an intended reproduction-time reference light incident angle Φon the basis of an arithmetic expression consisting of a signal light incident angle Θ, a recording-time reference light incident angle Θ, a light wavelength λ, a refractive index n of the recording medium and a contraction coefficient α of the recording medium.

Description

  The present invention relates to a hologram reproducing apparatus that reproduces information multiplexedly recorded on a medium using a hologram and a method for searching for an optimum value of a reference light incident angle during reproduction, and in particular, hologram recording accompanying shrinkage / expansion of a hologram recording medium The present invention relates to a hologram reproducing apparatus that compensates for information distortion and a method for searching for an optimum value of a reference beam incident angle during reproduction.

  In recent years, as a next-generation optical information recording / reproducing system that performs high-speed and large-capacity information recording / reproducing, research and development of a hologram recording / reproducing system has been actively conducted.

  Here, an outline of a conventional hologram recording / reproducing apparatus will be described. That is, the coherent laser beam emitted from the laser light source is split into two beams by the beam splitter, and one beam passes through the beam splitter and is irradiated to the spatial light modulator. Is converted into signal light carrying digital image information called two-dimensionally arrayed white and black binary pixels called page data. The signal light emitted from the spatial light modulation element is optically Fourier-transformed by a lens and applied to a hologram recording medium (hereinafter sometimes simply referred to as “recording medium”). On the other hand, the other light beam from the beam splitter is used as reference light (reference light at the time of recording), and is irradiated at a different angle from the signal light to a place where the signal light in the recording medium passes.

  When the signal light and the reference light are simultaneously irradiated, interference fringes are generated in the volume inside the recording medium, and hologram recording is performed by transferring the fringe distribution to the recording area of the recording medium in the form of a refractive index distribution or the like. In the case of the angle multiplex recording method, different page data is displayed by changing the incident angle (rotation angle) of the reference light to the recording medium little by little while displaying different page data information on the spatial light modulator. It is possible to multiplex-record information on the same area in the recording medium, and to store information at a higher density.

  When reproducing page data information recorded on a hologram recording medium, the same recording is performed by shielding the signal light and irradiating the recording medium with only the reference light (reference light at the time of reproduction) at the same angle as at the time of recording. Even if a plurality of pieces of page data information are recorded in the area, only desired page data information can be selectively taken out and imaged and reproduced by a CCD (imaging device) through a lens.

  By the way, when a replaceable recording medium is installed in the hologram recording apparatus, it is desirable to install it at the same angle as that at the time of recording with respect to the reference light. It is necessary to adjust the incident angle of the reference light according to the tilt angle. For this reason, conventionally, as shown in Patent Document 1 below, the positional deviation (tilt angle) of the recording medium is detected based on the captured reproduction light, and the drive mechanism is controlled so that this positional deviation (tilt angle) is eliminated. A technique for moving a recording medium is known. In addition, as shown in Patent Document 2 below, a technique for controlling a tilt angle by recording a reference tilt angle on a recording medium and detecting an incident angle of the reference reproduction reference light on the recording medium is known. It has been.

  Further, in the phase conjugate hologram recording apparatus, since the recording medium surface on which the reference light is incident is different between recording and reproduction, there is not much problem if the recording medium surface is extremely flat (horizontal). If it is off to some extent from the flat (horizontal), it is necessary to adjust the incident angle of the reference light. Therefore, conventionally, as shown in Patent Documents 3 and 4, when the angle of the reference light is continuously changed around the assumed incident angle, and the intensity from the photodetector becomes a predetermined level or maximum It is assumed that the target angle is the target angle, and a technique for reproducing with this angle is known.

  Further, a photosensitive resin material (hereinafter referred to as a photopolymer) is used as a write-once recording medium. A medium based on a photopolymer has an advantage that the multiplicity index is high and data can be retained stably for a long period of time. However, in the case of a photopolymer, a hologram (interference fringes) is recorded by generating a refractive index difference inside the recording medium. At this time, medium shrinkage occurs due to photopolymerization. In addition, when a temperature difference occurs between signal recording and signal reproduction, the recording medium may contract or expand due to the influence of the temperature difference. When the recording medium contracts or expands, so-called interference fringe distortion (hologram recording information distortion: hereinafter referred to as hologram distortion) occurs in which the interference fringes recorded in the medium are distorted. Even if reference light similar to that at the time of recording is incident on the distorted interference fringes, it becomes difficult to reproduce the recorded bit data without error, so that the SNR (Signal to Noise Ratio) of the reproduced data is lowered.

  Therefore, in the prior art, there is known one in which reproduction data is obtained by adjusting the incident angle of reference light during reproduction.

Japanese Patent No. 4513543 (Japanese Patent Laid-Open No. 2006-171589) JP 2007-256949 A JP 2006-277873 A JP 2007-240581 A JP 2008-152009 A

  As a technique that can correct the distortion of the recording medium more satisfactorily than the techniques disclosed in Patent Documents 3 and 4, as shown in Patent Document 5, the search range is changed by changing the reference light incident angle during reproduction. There is known a technique for enlarging and reducing the image according to the amount of distortion. However, it takes a lot of time to search for the incident angle of the reference light on the recording medium one by one. In particular, in a multiplexed hologram, it takes an enormous amount of time to obtain the reference light incident angle for compensating hologram distortion for all page data information.

  The present invention has been made in view of such circumstances, such as shrinkage and expansion of a hologram recording medium in which page data information is recorded in multiple recordings, or positional deviation of a recording medium that occurs when a replaceable recording medium is installed. It is an object of the present invention to provide a hologram reproducing apparatus and a method for searching for the optimum value of the reference light incident angle during reproduction, which can reduce the time required for compensation or compensation.

The hologram reproducing apparatus of the present invention is
An information reproducing unit that reproduces the page data information by irradiating a hologram recording medium on which page data information is angle-multiplexed recorded by reproducing the reference data at the time of reproduction provides the light wave carrying the page data information. In the hologram reproducing apparatus adjusted as follows:
When reproducing each page data information of the angle-multiplexed hologram, signal light incident angle Θ _s , recording reference light incident angle Θ _r , light wavelength λ, recording medium refractive index n, and recording medium shrinkage ratio α _Is provided with a calculation means for obtaining a desired reproduction reference light incident angle Φ _read based on an arithmetic expression having the element.

  In the hologram reproducing apparatus, the arithmetic expression is preferably the following conditional expression.

Further, it is preferable that the arithmetic expression is configured so as to obtain the reproduction-time reference light incident angle Φ _read along the signal light axis as the incident angle Θ _s of the signal light.

In addition, the calculation formula is configured to obtain the reproduction reference light incident angle Φ _read based on the minimum value and the maximum value among the incident angles of the light beams of the signal light depending on the NA of the objective lens. Is possible.

Further, the arithmetic expression is the incident angle of each ray of the signal light depending on the NA of the objective lens, based on a plurality of angles from the minimum value up to the maximum value, the reproduction reference beam incident angle [Phi _read It is also possible to configure so that

In addition, a means for reading information relating to the refractive index n and the shrinkage factor α of the recording medium recorded in advance on the hologram recording medium is provided, and based on the information relating to the refractive index n and the shrinkage factor α read by the means. Preferably, the reproduction reference light incident angle Φ _read is obtained.

Furthermore, the optimum value searching method of the reference light incident angle at the time of reproduction of the present invention,
When reproducing the page data information by irradiating the hologram recording medium on which the page data information is angularly multiplexed and reproducing the page data information, adjustment is made so that a light wave carrying the reproduced page data information is obtained. In the method of searching for the optimum value of the reference light incident angle during reproduction,
When reproducing each page data information of the angle-multiplexed hologram, the signal light incident angle Θ _s , the recording reference light incident angle Θ _r , the light wavelength λ, the refractive index n of the recording medium, and the shrinkage of the recording medium It is preferable to obtain a desired reference light incident angle Φ _read during reproduction based on an arithmetic expression having the rate α as an element.

In the above method for searching for the optimum value of the reference light incident angle during reproduction,
In the graph representing the reference light incident angle difference ΔΘ _r during recording and reproduction with respect to the recording reference light incident angle Θ _r , curves are drawn for two different contraction rates α ₁ and α ₂ , 2 It is preferable to obtain the optimum reference light incident angle Φ _read during reproduction from an area located between two curves.

  The information reproducing unit preferably includes a wavefront controller that adjusts the light wave carrying the page data information to have a desired wavefront shape.

  Note that “reproduction” in the hologram reproduction apparatus and the method of searching for the optimum value of the reference light incident angle during reproduction of the present invention means that it has a hologram reproduction function and does not have a hologram recording function. Does not mean. That is, an apparatus having both a hologram recording function and a reproducing function is also included in the concept of the hologram reproducing apparatus of the present invention.

In the hologram reproducing device and the method for searching for the optimum value of the reference beam incident angle during reproduction according to the present invention, recording that occurs when a hologram recording medium on which page data information is multiplexed is contracted or expanded, or when a replaceable recording medium is installed. A correction value of a desired reproduction reference light incident angle Φ _read that can compensate for a positional deviation of the medium is calculated. As a result, the reference light incident angle Φ _read during reproduction can be determined in a shorter time than before, and the data reading speed from the recording medium can be improved. As a result, the SNR of the reproduction data can be improved while shortening the time required to obtain the light wave carrying each page data information.

  In addition, since hardware modification of the apparatus is unnecessary, the hardware configuration of the conventional apparatus can be used as it is, and the operation of the apparatus can be facilitated and the manufacturing cost can be reduced.

1 is a schematic diagram illustrating a configuration of a hologram recording apparatus according to an embodiment of the present invention. It is a conceptual diagram (when signal light is parallel light) which shows the relative position relation of signal light, reference light at the time of recording, and a hologram recording medium, and relation with a recording device of interference fringe to be recorded ((a) is before contraction. (B) after shrinkage). It is the schematic showing the definition of signal light. FIG. 9 is a graph showing the angle relationship of incident light according to Example 1 of the present invention, and is a graph showing the relationship between the reference light incident angle Θ _r during recording and the reference light incident angle difference ΔΘ _r during recording and reproduction. . FIG. 9 is a graph showing the angle relationship of incident light according to Example 2 of the present invention, and is a graph showing the relationship between the reference light incident angle Θ _r during recording and the reference light incident angle difference ΔΘ _r during recording and reproduction. . FIG. 10 is a graph illustrating an angular relationship according to Example 3 of the present invention, and illustrating a relationship between a signal light incident angle Θ _s and a reproduction reference light incident angle Θ _read . FIG. 10 is a graph showing the angular relationship of incident light according to Example 3 of the present invention, and is a graph showing the relationship between the reference light incident angle Θ _r during recording and the reference light incident angle difference ΔΘ _r during recording and reproduction. . In another embodiment of the present invention, a range in which a search time can be shortened in a graph representing a reference light incident angle difference ΔΘ _r during recording and reproduction with respect to a recording reference light incident angle Θ _s is shown. It is.

  Hereinafter, embodiments of a hologram reproducing device and a method for searching for an optimum value of the reference light incident angle during reproduction according to the present invention will be described in detail with reference to the drawings.

  First, a hologram reproducing apparatus according to an embodiment of the present invention will be described with reference to FIG. This hologram reproducing apparatus is configured as a recording / reproducing apparatus having a hologram recording function and a reproducing function, and the hologram recording medium 11 is composed of a photopolymer and adopts an angle multiplex recording system. The mechanism (flow of recording / reproducing operation) will be described below.

  The coherent laser beam emitted from the laser light source 1 is expanded in beam diameter by a beam expander composed of a diverging lens 2 and a collimating lens 3, passes through a half-wave plate 4, is deflected by a mirror 5, and then is a polarized beam. The light is branched into two light beams by the splitter 6.

  A light beam traveling from the polarization beam splitter (PBS) 6 toward the left in the figure passes through the polarization beam splitter (PBS) 7 and is irradiated to the spatial light modulation element (SLM) 8. The signal light is modulated to carry page data information composed of a digital image in which white and black binary pixels are two-dimensionally arranged. The polarization direction of the signal light emitted (reflected) from the spatial light modulator 8 is changed from that of the incident light, and is reflected downward in the drawing by the polarization beam splitter (PBS) 7 and optically reflected by the lens 10. The hologram recording medium 11 is irradiated with the Fourier transform.

  On the other hand, the light beam traveling downward in the figure from the polarizing beam splitter (PBS) 6 is used as reference light (recording reference light), passes through the half-wave plate 14 and the mirror 15, and is reflected by the polarizing beam splitter (PBS) 16 in the figure. Reflected downward, the angle is controlled by the galvanometer mirror 17, and the place where the signal light in the recording medium 11 passes through the relay lenses 18 a and b is irradiated at an angle different from that of the signal light. Interference fringes are recorded inside. The half-wave plate 14 is set so as not to change the polarization direction (longitudinal polarization). In the apparatus of the present embodiment, since angle multiplex recording is possible, the incident angle (rotation angle) of the reference light to the recording medium is gradually changed while displaying different page data on the spatial light modulator 8. By changing, it becomes possible to multiplex-record different page data in the same area in the recording medium, and to store information with higher density.

  On the other hand, when reproducing the page data information recorded on the hologram recording medium 11, the polarization direction of the reference light is changed (vertically polarized light to horizontally polarized light) by the half-wave plate 14 and reflected by the mirror 15. The reference light passes through the polarization beam splitter (PBS) 16, passes through the galvanometer mirror 17 and the lenses 18 a and b, and is irradiated onto the hologram recording medium surface opposite to the recording reference light irradiation side. Thus, the apparatus according to the present embodiment is a phase conjugate type.

  Further, in order to cope with angle multiplex recording, by changing the incident angle of the reference light at the time of reproduction to the recording medium 11 at a predetermined timing, desired information can be obtained from a plurality of pieces of page data information multiplexedly recorded in the same recording area. The page data information is sequentially read, and the read information of the reproduction light is sequentially picked up by a CCD (imaging device) 13 through the lens 12.

  As described above, in angle multiplexing recording and reproduction, the angle of the galvanometer mirror 22 is changed little by little. Specifically, for example, the incident angle is in the range of 60 to 80 °. The page data information is recorded or reproduced in the area every time it is changed by 0.2 degrees.

  Hereinafter, a method for searching for the optimum value of the reference light incident angle during reproduction according to the embodiment of the present invention, specifically, a method for correcting the reference light incident angle during reproduction according to the shrinkage after recording of the hologram recording medium 11 will be described.

  FIG. 2 is a diagram for explaining the incident angle of the signal light and the incident angle of the recording reference light with respect to the recording medium 11 in the state (a) before the contraction of the recording medium 11 and the state (b) after the contraction. .

That is, as shown in FIG. 2 (a), the signal light incident angle θ _{s in} the recording medium and the recording reference light incident angle θ _r in the recording medium are respectively those when entering the recording medium 11 during recording. The incident angle is shown. Θ _k is the angle of the interference fringe with respect to the recording medium 11, and θ _h is the incident angle of the recording reference light in the recording medium with respect to the interference fringe.

Further, in FIG. 2 (b), phi _K angle of the interference fringes on the recording medium 11 after shrinkage, M is the interference fringe spacing after shrinkage, alpha is the shrinkage.

Also, when reproducing interference fringes recorded using plane wave signal light and plane wave reference light, the incident angle Θ _read of reproduction reference light satisfying the Bragg condition is incident from the outside on the recording medium 11. (Incident incident angle) is expressed by the following equation (1).

Θ _{read in the} above equation (1) matches the incident angle of the reference light during recording. However, when the recording medium 11 contracts and the recorded interference fringes are distorted, the incident angle of the reference light during reproduction for satisfying the Bragg condition (incident angle when entering the recording medium 11 from the outside) is Is represented by the following formula (2).

In the above equation (2), θ _K is an angle of interference fringes with respect to the recording medium ((signal light incident angle θ _{s in the} recording medium + reference light incident angle θ _r during recording in the recording medium) / 2). Since the signal light incident angle Θ _s and the recording reference light incident angle Θ _r can be replaced, the description of this embodiment does not contradict the description of claim 1. Further, Λ is an interference fringe interval, and this can also be replaced with wavelength / 2sin (reference light incident angle θ _h during recording with respect to the interference fringe angle).

Therefore, in order to improve the reproduction wavefront when the recording medium 11 contracts, it is necessary to provide an incident angle difference ΔΘ _r (= Φ _read −Θ _read ) between the reference light during recording and reproduction.

In hologram recording, since signal light reaches the recording medium 11 in a condensed manner, the condensed light is a plane wave incident on the recording medium 11 at various angles as shown in FIG. It can be regarded as a set. The incident angle of the signal light depends on the NA of the lens, and the angle range is from -arcsin (NA) to arcsin (NA). The incident angle of the signal light is calculated reproduction time reference beam incident angle theta _read over the entire range from -arcsin (NA) to arcsin (NA), it is sufficient to perform the correction based on this.

  The present embodiment can be applied not only when the recording medium formed of a photopolymer or the like contracts but also when it expands, and can provide the same effects.

  Hereinafter, examples using specific numerical values will be described.

<Example 1>
As a first embodiment, a case where the reference light incident angle Θ _read during reproduction is corrected using interference fringes generated by the plane wave element of the axial ray of the signal light and the reference light will be described below.

The angle of the on-axis beam of signal light is 0 °, and the reference light incident angle during recording is 70 °. Assuming that the wavelength of light is 532 nm, the refractive index n of the recording medium is 1.4, and the contraction rate α is 0.2%, and the contraction occurs only in the normal direction with respect to the surface of the recording medium 11, the reference light incident angle Θ _read during reproduction is 70.135 °, which can be corrected by shifting the recording angle to increase by 0.135 °.

When angle multiplexing is performed, the reference light incident angle Θ _r during recording is shifted by a predetermined angle and different page data is sequentially recorded. The reference light incident angle Θ _r during recording is changed in the range of 60 ° to 80 °. The recording reference light incident angle Θ _r can be multiplexed over 100 pages when the angle interval between recorded page data is 0.2 °.

FIG. 4 shows the relationship between the reference light incident angle Θ _r during recording and the reference light incident angle difference ΔΘ _r during recording and reproduction.

As the reference light incident angle Θ _r at the time of recording increases, the correction angle required for reproduction (reference light incident angle difference ΔΘ _r at the time of recording and reproduction) increases. Further, this curve can be approximated by a hyperbolic function represented by the following equation (3).

  In FIG. 4, the values of the coefficients a, b, and c are −2.5, 89, and 0, respectively.

Using the hyperbolic function expressed by the above equation (3), the correction value (Φ _read −Θ _read ) of the reproduction reference light incident angle can be obtained from the recording reference light incident angle Θ _r . Reproduced data is obtained by reproducing the recorded information at the reference light incident angle corrected by such a correction value.

  In this embodiment, the approximate expression is a hyperbolic function, but other functions such as a linear function (the number of required page data is 2), a quadratic function, a cubic function, or a higher order function, an exponential function, a logarithmic function, or the like. May be an approximate expression (fitting function) (the same applies to Examples 2 and 3 below).

<Example 2>
The second embodiment uses the interference fringes generated by the incident light plane wave element and the reference light at the minimum value (-arcsin (NA)) and the maximum value (arcsin (NA)) of the signal light incident angle, and the reference light during reproduction. The incident angle Θ _r is corrected. Hereinafter, Example 2 will be described in detail.

  Since the signal light is collected by the lens, it can be regarded as a set of plane waves incident from various angles. The maximum value and minimum value of the incident angle at this time depend on the NA of the lens. For example, if the NA of the condenser lens is 0.65, a plane wave having a minimum signal light incident angle of −40.54 ° and a maximum value of 40.54 ° is obtained.

The recording reference light incident angle Θ _r is 70 °, the light wavelength λ is 532 nm, the refractive index n of the recording medium is 1.4, and the shrinkage rate α is 0.2%, and the shrinkage is in the direction normal to the surface of the recording medium 11. If this occurs only, the reference light incident angle Θ _r during reproduction is 70.048 ° and 70.179 °. The intermediate value between these two angles is 70.113 °, and can be corrected by shifting the angle so that it is increased by 0.113 ° from the angle at the time of recording.

FIG. 5 is a graph showing the relationship between the reference light incident angle Θ _r during recording and the reference light incident angle difference ΔΘ _r during recording and reproduction for Example 2 with NA of 0.4, 0.65, and 0.85.

The reference light incident angle Θ _r during recording is changed in the range of 60 ° to 80 °. As the reference light incident angle Θ _r during recording increases in each NA, the correction angle required during reproduction (reference light incident angle difference ΔΘ _r during recording and reproduction) increases. Further, this curve can be approximated by a hyperbolic function represented by the above equation (3), and a correction value (Φ _read −Θ _read ) of the reference light incident angle during reproduction can be obtained from the reference light incident angle Θ _r during recording. Reproduced data is obtained by reproducing the recorded information at the reference light incident angle corrected by such a correction value.

<Example 3>
In the third embodiment, the incident light plane wave element for a plurality of angles in the range from the minimum value (−arcsin (NA)) to the maximum value (arcsin (NA)) of the signal light incident angle and the reference light are generated. The reference light incident angle Θ _read during reproduction is corrected using the interference fringes. Hereinafter, Example 3 will be described in detail.

  As described in the first and second embodiments, since the signal light is collected by the lens, it can be regarded as a set of plane waves incident from various angles. The maximum and minimum values of the incident angle at this time depend on the NA of the lens. For example, if the lens NA is 0.85, the signal light is a set of plane waves having a minimum incident angle of −58.21 ° and a maximum value of 58.21 °.

FIG. 6 is a graph showing the relationship between the signal light incident angle Θ _s and the reproduction reference light incident angle Θ _read . The reference light incident angle Θ _r during recording is 70 °, the light wavelength λ is 532 nm, the refractive index n of the recording medium is 1.4, and the shrinkage rate α is 0.2%. The shrinkage occurs only in the normal direction to the surface of the recording medium 11. Assuming that the reference light incident angle Θ _read during reproduction is 70.015 °, the maximum value is 70.179 °. The intermediate value between these two angles is 70.097 °, and can be corrected by shifting the angle so as to increase by 0.097 ° from the angle at the time of recording.

FIG. 7 is a graph showing the relationship between the reference light incident angle Θ _r during recording and the reference light incident angle difference ΔΘ _r during recording and reproduction for Example 3.

The reference light incident angle Θ _r during recording is changed in the range of 60 ° to 80 °. As the reference light incident angle Θ _r during recording increases in each NA, the correction angle required during reproduction (reference light incident angle difference ΔΘ _r during recording and reproduction) increases. Further, this curve can be approximated by a hyperbolic function represented by the above equation (3), and a correction value (Φ _read −Θ _read ) of the reproduction reference light incident angle can be obtained from the recording reference light incident angle. Reproduced data is obtained by reproducing the recorded information at the reference light incident angle corrected by such a correction value.

  In the above-described first to third embodiments, a method for correcting the reproduction reference beam angle in the case where hologram distortion has occurred has been described. Instead of this, or in addition to this, for example, as described above, Even when a commutative recording medium is installed, or when a tilt (tilt) occurs in the recording medium installation in a phase conjugate hologram recording apparatus, the angle correction is necessary due to other factors. Considering the reference light incident angle obtained by any of the above embodiments, for example, if the reference light incident angle is searched by any of the methods described in Patent Documents 3 to 5, the search time is significantly reduced. can do.

Also, if it is known that the shrinkage rate α is included in a range between 0.1 and 0.2%, for example, the range of the reference light incident angle difference ΔΘ _r during recording and reproduction as shown by the oblique lines in FIG. Is required. If the reference light incident angle is searched in this range, the search time can be greatly shortened.

  Although one embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment.

  Further, in the reference light path at the time of reproduction, for example, at the position of the mirror 21 shown in FIG. 1, a wavefront controller is provided in place of the mirror 21, and the application was filed on the same date as the present application, for example. The wavefront may be controlled by a technique as described in detail in the patent application (Title of Invention: Multiple Record Hologram Reproduction Measure and Hologram Distortion Compensation Method). Thereby, the distortion of the hologram can be controlled in more detail.

  The wavefront controller 21 is arranged to compensate for hologram distortion (interference fringe distortion) caused by shrinkage (including expansion) of the hologram recording medium, and a thin film mirror serving as a reflecting mirror surface is a mirror. A deformable mirror that is supported from the back side by a plurality of pin members that can advance and retreat in the front and back direction, and the thin film supported by each pin member by adjusting the amount of protrusion from the substrate for each pin member Each region of the mirror is moved in the front and back directions so that the shape of the entire thin film mirror is changed.

  The movement amount of this thin film mirror (the protruding amount of each pin member) is controlled by the measurement control device 40 by a control method using a genetic algorithm. That is, the measurement control device 40 evaluates the reproduction data captured by the CCD 13 and outputs a control signal corresponding to the evaluation result to the wavefront controller 21 to change the operation amount of the thin film mirror. It is performed repeatedly using a genetic algorithm to optimize the wavefront of the reference light during playback.

  In the genetic algorithm, a group (individual group) consisting of a plurality of individuals is assumed, a gene as an element that defines the trait of each individual is defined, and gene duplication, crossover, mutation, etc. are repeatedly executed. . Based on the fitness, individuals that are most suitable for the environment will form the next generation. Specifically, the state of the thin film mirror is an individual, and the protrusion amount of each pin member (protrusion position with respect to the substrate) is a gene. As the fitness, the brightness of reproduction data, SNR, and the like are used.

  The wavefront controller is not limited to a deformable mirror, but a liquid crystal panel (for example, LCOS-SLM X10468 series manufactured by Hamamatsu Photonics), a liquid crystal lens that corrects a specific Zernike coefficient, or an acoustooptic modulator, It is also possible to configure the optical system by combining a plurality of elements such as an electro-optic modulation element.

  Further, in the hologram recording apparatus, medium information such as the refractive index n and the contraction rate α of the hologram recording medium 11 is recorded in advance on the recording medium 11, and the medium information is read to obtain the medium information during reproduction. In addition, the information used in the correction methods shown in the first to third embodiments can be used.

DESCRIPTION OF SYMBOLS 1 Laser light source 2 Divergent lens 3 Collimating lens 4, 14 Half wave plate 5, 15, 21 Mirror 6, 7, 16 Polarization beam splitter (PBS)
8 Spatial light modulator (SLM)
17, 22 Galvanometer mirror 10, 18a, 18b, 23a, 23b Lens 11 Hologram recording medium 13 CCD
40 Measurement control device

Claims (9)

A hologram recording medium on which page data information is angle-multiplexed is provided with an information reproducing unit that reproduces the page data information by irradiating a reference light at the time of reproduction. In the information reproducing unit, a light wave carrying the page data information In a hologram reproducing apparatus that adjusts so as to be obtained,
In reproducing each page data information of the angle-multiplexed hologram, signal light incident angle Θ _s , recording reference light incident angle Θ _r , light wavelength λ, recording medium refractive index n, and recording medium shrinkage ratio α A hologram reproducing apparatus comprising: a calculating means for obtaining a desired reproduction reference light incident angle Φ _read based on an arithmetic expression having an element as an element. The hologram reproducing apparatus according to claim 1, wherein the arithmetic expression is the following conditional expression.
Wherein the mathematical expression, wherein the incident angle theta _s of the signal light, to claim 1 or 2, characterized in that configured to determine the reproduction reference beam incident angle [Phi _read along the axis of the signal light Hologram reproducing device. The calculation formula is configured to obtain the incident angle Φ _read of the reference light during reproduction based on the minimum value and the maximum value among the incident angles of the light beams of the signal light depending on the NA of the objective lens. The hologram reproducing device according to claim 1, wherein the hologram reproducing device is a hologram reproducing device. The calculation formula obtains the reference light incident angle Φ _read during reproduction based on a plurality of angles from the minimum value to the maximum value among the incident angles of each ray of the signal light depending on the NA of the objective lens. 4. The hologram reproducing apparatus according to claim 1, wherein the hologram reproducing apparatus is configured as described above. Means for reading information relating to the refractive index n and shrinkage factor α of the recording medium recorded in advance on the hologram recording medium, and based on the information relating to the refractive index n and shrinkage factor α read by the means, 6. The hologram reproducing apparatus according to claim 1, wherein the hologram reproducing apparatus is configured to obtain a reference light incident angle [Phi] _read during reproduction. When reproducing the page data information by irradiating the hologram recording medium on which the page data information is angle-multiplexed and reproducing the page data information, the light wave carrying the reproduced page data information is adjusted to a desired wavefront shape. In the method for searching for the optimum value of the reference light incident angle during reproduction,
When reproducing each page data information of the angle-multiplexed hologram, the signal light incident angle Θ _s , the recording reference light incident angle Θ _r , the light wavelength λ, the refractive index n of the recording medium, and the shrinkage of the recording medium A method for searching for an optimum value of the reference light incident angle at the time of reproduction, wherein a desired reference light incident angle Φ _read at the time of reproduction is obtained based on an arithmetic expression having the rate α as an element. In the graph representing the reference light incident angle difference ΔΘ _r during recording and reproduction with respect to the recording reference light incident angle Θ _r , curves are drawn for two different contraction rates α ₁ and α ₂ , 2 8. The method for searching for an optimum value of the reference light incident angle during reproduction according to claim 7, wherein the optimum reference light incident angle Φ _read during reproduction is obtained from an area located between the two curves. 9. The hologram reproduction apparatus according to claim 1, wherein the information reproduction unit includes a wavefront controller that adjusts a light wave carrying the page data information to a desired wavefront shape.