JP2018180198A - Hologram recording device and hologram manufacturing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hologram recording device that can record a hologram in a wider range of vision.SOLUTION: A hologram recording device 1 records an interference pattern of an object light passing through a space filter 20 and a reference light into a hologram recording medium 9, and includes: a laser 10 generating a laser light; an SLM 18 displaying hologram data; the space filter 20 for switching an object light; SF control means 33 for causing the space filter 20 to switch the object light in time division; and SLM control means 35 for causing the SLM 18 to display the hologram data corresponding to the vision range of the object light passed by the space filter 20 in synchronization with the SF control means 33.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a hologram recording apparatus and a hologram manufacturing apparatus.

  The hologram is to realize a desired light wave distribution by utilizing the light diffraction phenomenon. Specifically, in a hologram, light from an object (object light) and reference light are made to interfere with each other to form interference fringes, and the interference fringes are recorded on a hologram recording medium. Conventional holograms have various limitations, such as the need for a real object and a lens with a large aperture, in order to emit light to a real object and generate object light. For example, in the case of producing a holographic optical element (HOE) equivalent to a lens having an aperture of 30 cm, 100 cm, and 200 cm, in the conventional hologram, a lens having an aperture of 30 cm or more, 100 cm, and 200 cm or more is required.

  Recently, DDHOE (Digitally Designed Holographic Optical Element) technology using digital data has been proposed. In this DDHOE technology, hologram data is displayed on a spatial light modulator (SLM: Spatial Light Modulator), and light is emitted to generate object light. Since this hologram data can be calculated by a computer, it is possible to obtain a lightwave distribution of desired object light. As a result, in the DDHOE technology, even if there is no real object or a lens with a large aperture, only wavefront information such as CG (Computer Graphics) data enables the wavefront printer to realize a desired lightwave distribution and easily generate a hologram. .

  In the DDHOE technology, the number of pixels in the SLM is becoming a problem because the size of the hologram and the light emission angle from the hologram are proportional to the number of pixels in the SLM. However, for example, when the number of pixels of the SLM is 1000 pixels, the pixel spacing of the SLM is 2 μm, and the wavelength of the laser light is 533 nm, the size of the hologram can be 2 mm by 2 mm and the light emission angle from the hologram can be only about 7.3 °. It is not enough for practical use.

  For this reason, in the DDHOE technology, "the step of exposing a part of the entire lightwave distribution to the hologram recording medium" and "the step of changing the hologram data to be displayed and moving the hologram recording medium" are sequentially repeated. There is proposed a method of generating a hologram by exposing the whole to light (Non-patent Document 1). For example, in the case of an SLM of 1000 pixels, both steps can be repeated 2500 times while shifting the position of the hologram recording medium to generate a 10 cm by 10 cm hologram.

K. Wakunami et al, “Wavefront printer by using cell overlapping technique”, 3D systems and applications (2015)

  However, the technique described in Non-Patent Document 1 has a problem that the light emission angle from the hologram can not be increased (that is, the viewing area can not be increased). Temporarily, if the exposure area is narrowed once, the light emission angle from the hologram can be increased, but this is equivalent to displaying the object with a small aperture, which causes the object to be blurred, and it is difficult to adopt this method.

  Therefore, an object of the present invention is to provide a hologram recording apparatus and a hologram manufacturing apparatus capable of recording in a wide viewing range.

  In view of the above problems, a hologram recording apparatus according to the present invention includes a light source for generating a laser beam, and a spatial light modulator for reflecting the hologram data generated in advance on the laser beam to generate object light of each order Switching means for switching the object light of each order generated by the spatial light modulator to pass only the object light of any order, the object light having passed through the switching means and the reference light A hologram recording apparatus for recording interference fringes on a hologram recording medium, comprising switching control means and spatial light modulator control means.

  The hologram recording apparatus causes the switching control unit to switch the object light passed by the switching unit to the switching unit in time division. Then, the hologram recording apparatus causes the spatial light modulator to display the hologram data corresponding to the visual field of the object light to be passed by the switching means in synchronization with the switching control means by the spatial light modulator control means. . Thus, the hologram recording apparatus can record in a wide viewing zone by using not only the + 1st order light but also the object light of each order.

  Further, in view of the problems described above, according to the hologram manufacturing method of the present invention, a light source for generating a laser beam and spatial light modulation for generating object light of each order by reflecting previously generated hologram data on the laser beam The switching means using a hologram recording apparatus comprising: a switching device, and switching means for switching the object light of each order generated by the spatial light modulator and passing only the object light of any order It is a hologram manufacturing method for recording the interference fringes of the object light and the reference light on a hologram recording medium, and is a procedure including an object light switching step and a hologram data display step.

  In the hologram manufacturing method, in the object light switching step, the switching control means causes the switching means to switch the object light to be passed through in a time division manner. Then, in the hologram manufacturing method, in the hologram data display step, the spatial light modulator control means synchronizes with the switching control means, and the hologram data corresponding to the visual field of the object light to be passed in the object light switching step is Display on the spatial light modulator. As described above, according to the hologram manufacturing method, recording can be performed in a wide viewing range by using not only + 1-order light but also object light of each order.

  According to the hologram recording apparatus and the hologram manufacturing method according to the present invention, recording can be performed in a wide viewing range by using not only + 1-order light but also object light of each order.

It is a block diagram which shows the structure of the hologram recording device concerning 1st, 2nd embodiment of this invention. In 1st Embodiment, it is explanatory drawing explaining the visual field of object light. It is a conceptual diagram of the spatial filter of FIG. It is a timing chart which shows operation | movement of the hologram recording device of FIG. FIG. 8 is a conceptual diagram for explaining switching of the SLM and the spatial filter in the first embodiment, in which (a) is a state in which + first order light is allowed to pass, (b) is a state in which − first order light is allowed to pass, In the state in which the next light is allowed to pass, (d) is the state in which the −secondary light is allowed to pass. In 2nd Embodiment, it is explanatory drawing explaining shielding of an interference light. It is a conceptual diagram of the spatial filter in 2nd Embodiment. It is a timing chart which shows operation of a hologram recording device concerning a 2nd embodiment. It is a block diagram showing composition of a hologram recording device concerning a 3rd embodiment of the present invention. It is a timing chart which shows operation | movement of the hologram recording device of FIG.

  Hereinafter, each embodiment of the present invention will be described in detail with reference to the drawings as appropriate. In each embodiment, the same means and the same members are denoted by the same reference numerals, and the description thereof is omitted.

First Embodiment
[Configuration of Hologram Recording Device]
The configuration of the hologram recording apparatus 1 according to the first embodiment of the present invention will be described with reference to FIG.

The hologram recording apparatus 1 records interference fringes between object light and reference light on a hologram recording medium 9.
The hologram recording medium 9 is a medium for recording the interference fringes of the object light and the reference light. For example, as the hologram recording medium 9, one in which a photopolymer and a photosensitive material are laminated on a glass or plastic substrate can be mentioned.

  As shown in FIG. 1, the hologram recording apparatus 1 includes a laser (light source) 10, a polarizing plate 11, a half wave plate 12, lenses 13 and 14, a polarization beam splitter 15, and a half wave plate 16, a polarizing beam splitter 17, an SLM (spatial light modulator) 18, a lens 19, a spatial filter (switching means) 20, lenses 21 to 23, mirrors 24 and 25, a spatial filter 26, and a stage 27 and a control device 30.

In FIG. 1, the horizontal direction is illustrated as the X-axis direction, and the vertical direction is illustrated as the Y-axis direction.
In the present embodiment, the switching direction of the object light is assumed to be the horizontal direction. That is, the spatial filter 20 described later switches the object light in the horizontal direction.

  The laser 10 is a laser light source that generates a laser beam. In the laser 10, the wavelength of the laser beam to be generated is not particularly limited. In the present embodiment, it is assumed that the laser 10 is a monochromatic laser device that oscillates a green laser with a wavelength of 532 nm.

The polarizing plate 11 adjusts the polarization direction of the laser beam generated by the laser 10.
The half-wave plate 12 changes the polarization direction of the laser light that has passed through the polarizing plate 11 in order to adjust the balance of the object light and the reference light branched by the polarization beam splitter 15 described later. The laser light that has passed through the half-wave plate 12 is emitted to the lens 13.

The lens 13 is a convex lens that enlarges the beam diameter of the laser beam from the half-wave plate 12. The lens 13 may be a single lens or a compound lens as long as the function satisfies the function (the same applies to the lenses 14, 19 and 21 to 23 described later).
The lens 14 is a convex lens that converts the laser light from the lens 13 into parallel light. The laser light converted into parallel light by the lens 14 is emitted to the polarization beam splitter 15.

  The polarization beam splitter 15 splits the laser light from the lens 14 into object light and reference light. That is, the polarization beam splitter 15 splits the laser beam from the lens 14 into P polarized light and S polarized light which are orthogonal to each other. In this embodiment, the laser beam transmitted through the polarization beam splitter 15 is used as a reference beam, and the laser beam reflected by the polarization beam splitter 15 is used as an object beam.

In FIG. 1, the center of the optical axis of the laser beam is illustrated by a broken line, and both ends of the laser beam are illustrated by a solid line.
Further, in FIG. 1, the reference light is illustrated by a block arrow R, and the object light is illustrated by a block arrow O.

The half-wave plate 16 rotates the polarization direction of the laser beam reflected by the polarization beam splitter 15 by π / 2.
The polarization beam splitter 17 transmits the object light from the half wave plate 16 to the SLM 18 and reflects the object light from the SLM 18 toward the lens 19. That is, the polarization beam splitter 17 reflects the object light modulated by the SLM 18 toward the lens 19.

  The SLM 18 reflects the hologram data generated in advance on the laser light (object light) from the polarization beam splitter 17 in accordance with a command from the control device 30 described later. Specifically, the SLM 18 reads out and displays the hologram data stored in the control device 30, modulates the object light from the polarization beam splitter 17 according to the hologram data, and polarizes the object light on which the hologram data is reflected It reflects to the splitter 17. For example, as a modulation method of the SLM 18, an amplitude modulation type, a phase modulation type, an amplitude / phase modulation type can be mentioned.

  Here, since the SLM 18 has a structure in which pixels are regularly arranged, high-order light such as 0th-order light, ± 1st-order light, ± 2nd-order light is generated. As shown in FIG. 2, zero-order light illustrated by a thick line is emitted to the front. Here, the 0th-order light does not spread in a certain range like ± 1st-order light or ± 2nd-order light, and becomes a light beam in one direction. In addition, + first-order light is emitted to a certain range slightly leftward from the front. In addition, +2 order light is emitted to a fixed range on the left outside of the +1 order light. Then, the -1st order light is emitted from the front into a certain range slightly to the right. Furthermore, the −secondary light is emitted to a certain range on the right outside of the −1st light. Therefore, if hologram data corresponding to the viewing area (emission range) of the ± 1st order light and ± 2nd order light to be emitted is reflected in the object light, the ± 1st order light and ± 2nd order light will be viewed when the hologram is reproduced. The area can be continuous.

In each figure, numerical values such as 0, +1, -1, +2, and -2 represent the order of the object light.
Further, in the present embodiment, ± first-order light and ± second-order light are used, and zero-order light, which is simply reflected light, and third-order light or more are not used.

  The lens 19 is a convex lens that condenses the object light reflected by the polarization beam splitter 17 on the spatial filter 20. The light passing through the lens 19 is emitted to the spatial filter 20.

  A spatial filter (SF: Spatial Filter) 20 switches object light of each order generated by the SLM 18 according to a command from the control device 30, and passes only object light of any order. For example, as the spatial filter 20, an optical shutter such as a liquid crystal panel or a mechanical shutter such as a rotary disk provided with slits at different positions in the radial direction can be mentioned.

Here, the spatial filter 20, as shown in FIG. 3 has a shutter ₂₀ A to 20 _D in the switching direction of the object beam (X axis direction). Shutter 20 _A corresponds to the passage region of the +1 order light, the shutter 20 _B corresponds to the passage region of the -1 order light. The shutter 20 _C corresponds to the passage region of the + 2nd order light, shutter 20 _D corresponds to the passage region -2 order light. Then, the spatial filter 20 according to the instruction from the controller 30 to open and close the shutter ₂₀ A to 20 _D.

Incidentally, the zero-order light is incident on one point of the shutter ₂₀ A, 20 _B on the boundary (shown by thick lines). Therefore, the spatial filter 20, and to always shield the zero-order light on the boundary of the shutter ₂₀ A, 20 _B.

The lens 21 is a convex lens that converts object light that has passed through the spatial filter 20 into parallel light.
The lens 22 is a convex lens that condenses the object light from the lens 21 on the lens 23.
The lens 23 is a convex lens that emits the object light from the lens 22 to the hologram recording medium 9.

The mirror 24 reflects the reference light transmitted through the polarization beam splitter 15 to the mirror 25.
The mirror 25 reflects the reference light from the mirror 24 to the spatial filter 26.
The spatial filter 26 is a filter that blocks the outer peripheral portion of the reference light transmitted through the polarization beam splitter 15.

  The stage 27 mounts the hologram recording medium 9 and moves it to an arbitrary position. For example, when recording is performed in element cell units, the stage 27 may move the mounted hologram recording medium 9 in two axial directions. At this time, the stage 27 may move the hologram recording medium 9 so that element cells do not overlap (tiling). In addition, the stage 27 may move the hologram recording medium 9 so that element cells overlap (overlap).

  With the above configuration, the polarization direction of the laser beam emitted from the laser 10 is adjusted by the half-wave plate 12. Then, the laser beam is branched by the polarization beam splitter 15 into object light and reference light.

  The object light passes through the half wave plate 16 and enters the SLM 18. The object light incident on the SLM 18 reflects the hologram data displayed on the SLM 18 and is incident on the spatial filter 20. Further, the object light incident on the spatial filter 20 is emitted to the hologram recording medium 9.

  The reference light is reflected by the mirrors 24 and 25 and is narrowed by the spatial filter 26 to the same beam diameter as the object light. Then, the reference light is emitted to the hologram recording medium 9. Thus, both the object light and the reference light are irradiated to the hologram recording medium 9, and the interference fringes of the object light and the reference light are recorded.

[Configuration of control unit]
Next, the configuration of the control device 30 will be described.
The control device 30 controls the SLM 18 and the spatial filter 20, and includes storage means 31, SF control means (switching control means) 33, and SLM control means (spatial light modulator control means) 35.

  The storage unit 31 is a storage device such as a memory for storing hologram data generated in advance, a hard disk drive (HDD), a solid state drive (SSD) or the like. The hologram data stored by the storage means 31 is referred to by the SLM 18.

Here, the hologram data is data obtained by calculating in advance interference fringes between complex amplitude data representing a light wave distribution of an object and laser light incident on the SLM 18.
In the present embodiment, the hologram data corresponds to four viewing areas of ± 1st order light and ± 2nd order light generated by the SLM 18. Therefore, a total of four hologram data are generated for each of the ± first-order light and ± second-order light viewing zones, and stored in the storage unit 31 in advance.

  For example, the hologram data can be obtained by a general computer generated hologram (CGH) such as calculation from a point light source or calculation from an integral stereoscopic image (element image group). When calculating from a point light source, the object is treated as a set of point light sources, the light generated by each point light source is propagated, the light wave distribution on the hologram surface is individually determined, and all the calculated light wave distributions are added. , Generate complex amplitude data. Then, in the computer-generated hologram, the result (interference fringe) of calculating the interference phenomenon with the complex amplitude data and the reference light data is generated as hologram data.

The SF control means 33 switches object light which the spatial filter 20 passes through to the spatial filter 20 by time division.
The SLM control means 35 causes the SLM 18 to display, in synchronization with the SF control means 33, the hologram data corresponding to the viewing area of the object light which the spatial filter 20 passes.

<Synchronous control of SLM and spatial filter>
Synchronous control of the SLM 18 and the spatial filter 20 will be described with reference to FIGS. 3 to 5 (see FIG. 1 as needed).
As shown in FIG. 4, this synchronization control is configured by an object light switching step S1 performed by the SF control unit 33 and a hologram data display step S2 performed by the SLM control unit 35.

"Timing signal _T +1 _{through T -2} of FIG. 4 shows the timing of shutter ₂₀ A to 20 _D is opened and closed. Here, the timing signal _T +1 _{through T -2} in the time interval of the Low (L), the shutter ₂₀ a to 20 _D is opened. On the other hand, the timing signal _T +1 _{through T -2} in the time interval of Hi (H), the shutter ₂₀ a to 20 _D is closed.
Further, “hologram data” in FIG. 4 represents the order of the object light corresponding to the hologram data displayed by the SLM 18. For example, “+1” represents + 1st order light, and “−1” represents −1st order light.
Further, in FIG. 5, the object light passing through the spatial filter 20 is shown by a solid line, and the object light blocked by the spatial filter 20 is shown by a broken line.

First, SF control means 33, as shown in FIG. 4, the timing signal _{T +1} in the time interval of the Low (L), to command the opening of the shutter 20 _A to the spatial filter 20. Further, the SLM control means 35 instructs the SLM 18 to display the hologram data corresponding to the visual area of the + 1st order light in the time interval in which the timing signal T _{+ 1} is Low (L).

Then, as shown in FIG. 5A, the SLM 18 displays hologram data corresponding to the visual field of the + 1st order light. Further, the spatial filter 20 opens the shutter 20 _A corresponding to the +1 order light. Although the hologram data corresponding to the viewing area of the + 1st order light is reflected also on the 0th order light, the -1st order light, and the ± 2nd order light, it is blocked by the spatial filter 20.
Thereby, the hologram recording device 1 can emit the + 1st order light on which the hologram data is reflected to the hologram recording medium 9.

Next, SF control means 33, as shown in FIG. 4, the timing signal _{T -1} at time intervals of Low (L), to command the opening of the shutter 20 _B to the spatial filter 20. Further, the SLM control means 35 instructs the SLM 18 to display the hologram data corresponding to the visual area of the −1st order light in the time interval in which the timing signal T ₋₁ is Low (L).

Then, as shown in FIG. 5B, the SLM 18 displays the hologram data corresponding to the viewing area of the -1st order light. Further, the spatial filter 20 opens the shutter 20 _B corresponding to the -1 order light.
Thereby, the hologram recording device 1 can emit the −1st order light on which the hologram data is reflected to the hologram recording medium 9.

Next, SF control means 33, as shown in FIG. 4, the timing signal _{T +2} in the time interval of the Low (L), to command the opening of the shutter 20 _C to the spatial filter 20. Further, the SLM control means 35 instructs the SLM 18 to display the hologram data corresponding to the viewing area of the ₊₂ order light in the time interval in which the timing signal T _{+ 2} is Low (L).

Then, as shown in FIG. 5C, the SLM 18 displays hologram data corresponding to the viewing area of + second-order light. Further, the spatial filter 20 opens the shutter 20 _C corresponding to the + second order light.
Thereby, the hologram recording apparatus 1 can emit the +2 secondary light on which the hologram data is reflected to the hologram recording medium 9.

Finally, SF control means 33, as shown in FIG. 4, the timing signal _{T -2} in the time interval of the Low (L), to command the opening of the shutter 20 _D to the spatial filter 20. Further, the SLM control means 35 instructs the SLM 18 to display hologram data corresponding to the viewing area of the −secondary light in the time interval in which the timing signal T− ₂ is Low (L).

Then, as shown in FIG. 5D, the SLM 18 displays hologram data corresponding to the viewing area of the −secondary light. Further, the spatial filter 20 opens the shutter 20 _D corresponding to -2 order light.
Thereby, the hologram recording device 1 can emit the −secondary light on which the hologram data is reflected to the hologram recording medium 9.

  As described above, in the hologram recording apparatus 1, the SF control means 33 executes the object light switching step S1, and the SLM control means 35 executes the hologram data display step S2, and + 1st order light, -1st order light, + 2th order It switches by time division in order of light and -2nd light. Thus, the hologram recording apparatus 1 sequentially emits ± first-order light and ± second-order light to the hologram recording medium 9 as object light. Then, the hologram recording apparatus 1 records the interference fringes of the object light and the reference light on the hologram recording medium 9.

<Adjustment of exposure>
Since the light intensity of the object light decreases as the order becomes higher, the exposure amount per unit time also decreases with ± second-order light than ± first-order light. In addition, since it becomes difficult to see a three-dimensional image if the brightness of the three-dimensional image differs between viewing zones, it is preferable that the exposure amounts of ± first-order light and ± second-order light be uniform.

Therefore, the SF control unit 33 sets the exposure time in advance for each order of the object light so that the exposure amount of the object light of each order becomes uniform. In Figure 5, as the exposure time, the time interval in which the timing signal T _{± 2} becomes Low (L), is set to be longer than the time interval in which the timing signal T _{± 1} becomes Low (L). Then, the SF control means 33 instructs the spatial filter 20 based on these timing signals T _{± 1} and T _{± 2} to make the exposure amounts of ± 1st-order light and ± 2nd-order light uniform.

[Operation / effect]
As described above, the hologram recording apparatus 1 can record interference fringes between the object light (± first light and ± second light) and the reference light on the hologram recording medium 9. Therefore, when the hologram recorded by the hologram recording apparatus 1 is reproduced, the visual areas of ± 1st-order light and ± 2nd-order light are continuous, so the visual area can be widened.

  Further, the hologram recording apparatus 1 can record the hologram data on the hologram recording medium 9 so that the exposure amounts of ± 1st light and ± 2nd light become uniform. Therefore, when the hologram recorded by the hologram recording device 1 is reproduced, the brightness of the three-dimensional image becomes uniform between the viewing areas, so that the three-dimensional image can be easily viewed, and the quality of the three-dimensional image can be improved.

Second Embodiment
[Configuration of Hologram Recording Device]
With respect to a hologram recording device 1B according to a second embodiment of the present invention, points different from the first embodiment will be described with reference to FIG.
The hologram recording apparatus 1B is different from the first embodiment in that the SLM 18B is an amplitude modulation type.

First, the configuration of the hologram recording device 1B will be described.
As shown in FIG. 1, the hologram recording apparatus 1 B includes a laser 10, a polarizing plate 11, a half wave plate 12, lenses 13 and 14, a polarization beam splitter 15, and a half wave plate 16. A polarization beam splitter 17, an SLM (spatial light modulator) 18B, a lens 19, a spatial filter (switching means) 20B, lenses 21 to 23, mirrors 24 and 25, a spatial filter 26, and a stage 27; And a control device 30B.
The respective units other than the SLM 18B, the spatial filter 20B, and the control device 30B are the same as those in the first embodiment, and thus the description thereof is omitted.

  Since the SLM 18B is of the amplitude modulation type, as shown in FIG. 6, the disturbance light (transmitted light .beta., Conjugated light .gamma.) Is generated in the vertical direction orthogonal to the switching direction of the object light .alpha. It will

  Therefore, the hologram recording device 1B shields the disturbance light with the spatial filter 20B in order to remove the image due to the complex conjugate. In this case, since the hologram recording apparatus 1B halves the incident angle of the object light to the hologram recording medium 9 (that is, the viewing area), it reduces the viewing area by half.

Spatial filter 20B, as shown in FIG. 7, has a shutter ₂₀ AU _{to 20 DD} was bisected quarters horizontally, vertically.
Here, the shutter 20 _AU corresponds to the upper passage region of +1 order light (upper half), corresponding to the lower side of the passage region of the shutter 20 _AD +1 order light (lower half). Also, the shutter 20 _BU corresponds to the upper side of the passage area of the -1st order light, and the shutter 20 _BD corresponds to the lower side of the passage area of the -1st order light. The shutter 20 _CU corresponds to the upper side of the +2 secondary light passage area, and the shutter 20 _CD corresponds to the lower side of the +2 secondary light passage area. In addition, the shutter 20 _DU corresponds to the upper side of the passing area of −secondary light, and the shutter 20 _DD corresponds to the lower side of the passing area of −secondary light.

For example, consider the case where the spatial filter 20B passes the object light α (+ 1st order light) of FIG. In this case, the spatial filter 20B is, + 1-order light shutter ₁₁₅ corresponding to the passage region of the U, 115 out and _D, open the upper shutter 115 _U, transmitted light β and conjugate light γ closes the shutter 115 _D of the lower Shield
Also, the spatial filter 20B, the shutter _{20 AU, 20 AD, 20 BU} , with _{20 BD} borderline (shown by a thick line) always shield the zero-order light.

[Configuration of control unit]
Returning to FIG. 1, the configuration of the control device 30B will be described.
The control device 30B controls the SLM 18B and the spatial filter 20B, and includes a storage unit 31B, an SF control unit (switching control unit) 33B, and an SLM control unit (spatial light modulator control unit) 35B.

The storage unit 31B stores in advance eight hologram data corresponding to the upper side and the lower side of the ± 1st light and ± 2nd light. The hologram data is generated for each shielding area of the object light and the interference light of each order, and is stored in advance in the storage unit 31B.
In addition, since the production | generation method of hologram data is the same as that of 1st Embodiment, description is abbreviate | omitted.

The SF control means 33B further switches the shielding region of the interference light to the spatial filter 20B by time division.
The SLM control means 35B displays the hologram data in synchronization with the SF control means 33B.

<Synchronous control of SLM and spatial filter>
Synchronous control of the SLM 18B and the spatial filter 20B will be described with reference to FIG.
As shown in FIG. 8, this synchronization control is configured by an object light switching step S1B performed by the SF control unit 33B and a hologram data display step S2B performed by the SLM control unit 35B.

"Timing signal _T + _{1U through T -2 D"} in FIG. 8 shows the timing of shutter ₂₀ AU _{to 20 DD} is opened and closed. Further, “hologram data” in FIG. 8 represents the order of the object light corresponding to the hologram data displayed by the SLM 18B and the shielding region (upper side, lower side) of the interference light. For example, “+1 U” indicates the + first order light upper side, and “+1 D” indicates the + first order light lower side.

First, as shown in FIG. 8, the SF control means 33B instructs the spatial filter 20B to open the shutter _20AU in a time interval in which the timing signal T _{+ 1U} is Low (L). Further, the SLM control means 35B instructs the SLM 18B to display the hologram data corresponding to the visual field above the + 1st order light in the time interval in which the timing signal T _{+ 1U} is Low (L).

Then, the SLM 18B displays hologram data corresponding to the visual field above the + 1st order light. Furthermore, the spatial filter 20B opens the shutter 20 _AU corresponding to the + primary light upper side.
Thus, the hologram recording device 1B can emit the upper side of the + first-order light on which the hologram data is reflected to the hologram recording medium 9.

Next, SF control unit 33B, as shown in FIG. 8, the timing signal _{T + 1D} in the time interval of the Low (L), to command the opening of the shutter _{20 AD} to the spatial filter 20B. Further, the SLM control means 35B instructs the SLM 18B to display the hologram data corresponding to the visual area under the + 1st order light in the time interval in which the timing signal T _{+ 1D} is Low (L).

Then, the SLM 18B displays the hologram data corresponding to the viewing area under the + 1st order light. Further, the spatial filter 20B opens the shutter _{20 AD} corresponding to + 1-order light lower.
Thus, the hologram recording device 1B can emit the lower side of the + first-order light on which the hologram data is reflected to the hologram recording medium 9.
In addition, about -1st-order light and +/- 2nd-order light, since it is the process similar to + 1st order light, description is abbreviate | omitted.

  As described above, in the hologram recording apparatus 1B, the SF control unit 33B executes the object light switching step S1B, and the SLM control unit 35 executes the hologram data display step S2B. The first-order light upper side, the -first-order light lower side, the + second-order light upper side, the + second-order light lower side, the -secondary light upper side, and the -secondary light lower side are switched in order of time division. Thus, the hologram recording apparatus 1B sequentially emits upper and lower sides of the ± 1st light and ± 2nd light as object light to the hologram recording medium 9. Then, the hologram recording apparatus 1 records the interference fringes of the object light and the reference light on the hologram recording medium 9.

<Adjustment of exposure>
Further, the hologram recording apparatus 1B can adjust the exposure amount as in the first embodiment. That is, in FIG. 8, the timing signal T _± 2U, the time interval T _{± 2D} becomes Low (L), the timing signal T _± 1U, set to be longer than the time interval T _{± 1D} becomes Low (L) There is. Then, the SF control means 33B instructs the spatial filter 20B in accordance with these timing signals T _{+ 1U to} T- _2D to _allow the upper and lower sides of the ± 1st order light and the upper and lower sides of the ± 2nd order light. The exposure amount is made uniform.

[Operation / effect]
As described above, even when the SLM 18B is of the amplitude modulation type, as in the first embodiment, the hologram recording device 1B can widen the viewing area and improve the quality of the three-dimensional image.
Furthermore, the hologram recording device 1B can prevent the visual field from being halved by the amplitude modulation type SLM 18B.

Third Embodiment
The differences between the first embodiment and the hologram recording device 1C according to the third embodiment of the present invention will be described with reference to FIG.
The hologram recording apparatus 1C is different from the first embodiment in that three color lasers are used.

[Configuration of Hologram Recording Device]
First, the configuration of the hologram recording device 1C will be described.
As shown in FIG. 9, the hologram recording device 1C, the light source unit ₁₀₀ and (100 _R, 100 G, 100 _B), a polarization beam splitter 15, a 1/2-wavelength plate 16, a polarization beam splitter 17, and SLM18 The lens 19, the spatial filter 20, the lenses 21 to 23, the mirrors 24, 25, the spatial filter 26, the stage 27, the mirrors 29, 40, the optical path changing means 41, and the control device 30C.

The green light source unit 100 _G is a light source unit that generates green laser light, and includes a laser (light source) 10 _G , a polarizing plate 11 _G , a half wavelength plate 12 _G , lenses 13 _G and 14 _G , And a shutter 28 _G.

The optical shutter 28 _G according to the instruction from the later-described control apparatus 30C, is to pass or shield the laser beam green light source unit 100 _G is caused. For example, as the optical shutter 28 _G, it may be mentioned an optical shutter or a mechanical shutter.
The respective _units other than the light shutter 28G are the same as those in the first embodiment, and thus the description thereof will be omitted.

The red light source unit 100 _R is a light source unit that generates red laser light, and includes a laser (light source) 10 _R , a polarizing plate 11 _R , a half wavelength plate 12 _R , lenses 13 _R and 14 _R , light And a shutter 28 _R.
The laser 10 _R is a laser light source that generates red laser light. For example, the laser 10 _R generates red laser light with a wavelength of 660 nm.
In addition, since each means other than laser 10 _R is the same as that of the green light source unit 100 _G , the further description is abbreviate | omitted.

Blue light source unit 100 _B is a light source unit for generating a blue laser beam, and the laser (light source) 10 _B, and the polarizing plate 11 _B, and 1/2-wavelength plate 12 _B, and a lens ₁₃ B, 14 _B, light and a shutter 28 _B.
The laser 10 _B is a laser light source that generates blue laser light. For example, the laser 10 _B generates blue laser light with a wavelength of 475 nm.
Each means other than the laser 10 _B is the same as that green light source unit 100 _G, further explanation is omitted here.

The mirror 29 reflects the red laser light from the red light source unit 100 _R toward the light path changing means 41.
The mirror 40 reflects the blue laser light from the blue light source unit 100 _B toward the optical path changing means 41.

The optical path changing means 41 emits the green laser light from the green light source unit 100 _G , the red laser light from the red light source unit 100 _R , and the blue laser light from the blue light source unit 100 _B to the polarization beam splitter 15. It is. For example, as the optical path changing means 41, a combination of a diffraction grating and a prism may be mentioned.

[Configuration of control unit]
Next, the configuration of the control device 30C will be described.
The controller 30C controls the light source unit 100, the SLM 18, and the spatial filter 20, and includes a storage unit 31, an SF control unit 33, an SLM control unit 35, and a light source control unit 37.
In addition, since each means other than the light source control means 37 is the same as that of the first embodiment, the description will be omitted.

  The light source control means 37 instructs the light source unit 100 to switch between red laser light, green laser light and blue laser light in synchronization with the SF control means 33 and the SLM control means 35.

<Synchronous control of light source unit, SLM and spatial filter>
Synchronous control of the light source unit 100, the SLM 18, and the spatial filter 20 will be described with reference to FIG. 10 (see FIG. 9 as needed).
In FIG. 10, the laser light represents the timing at which the light shutters 28 _R , 28 _G and 28 _B are opened and the red laser light (R), the green laser light (G) and the blue laser light (B) are emitted. .

As shown in FIG. 10, the light source control means 37, during the irradiation time set in advance, to command opening of the light shutter 28 _R to the red light source unit 100 _R. Then, the red light source unit 100 _R emits a red laser beam.
While being irradiated with the red laser light, the control device 30C switches the light emission in the order of +1 order light, -1 order light, +2 order light and -2 order light in the same manner as the first embodiment. Record with.

Next, the light source control means 37, during the time of illumination, directing the opening of the light shutter 28 _G to the green light source unit 100 _G. Then, the green light source unit 100 _G emits green laser light.
While the green laser light is being emitted, the control device 30C switches the light in the order of + first-order light, -first-order light, + second-order light and -secondary light in the same manner as in the first embodiment. Record with.

Next, the light source control means 37, during the time of illumination, directing the opening of the light shutter 28 _B to the blue light source unit 100 _B. Then, the blue light source unit 100 _B emits blue laser light.
While the blue laser light is being emitted, the control device 30C switches the light in the order of +1 order light, -1 order light, +2 order light and -2 order light in the same manner as in the first embodiment. Record with.
In the present embodiment, the irradiation time of each laser beam is set to be the same, but different irradiation times may be set.

[Operation / effect]
As described above, even in the case of using a color laser, the hologram recording apparatus 1C can widen the viewing area and improve the quality of the three-dimensional image as in the first embodiment.

(Modification)
As mentioned above, although each embodiment of the present invention has been described in detail, the present invention is not limited to the above-described embodiment, and design changes and the like within the scope of the present invention are also included.

In the first embodiment described above, switching is performed in the order of + 1st order light, -1st order light, + 2nd order light, and -2nd order light. However, in the present invention, the switching order is not particularly limited. For example, in the present invention, switching may be performed in the order of +2 light, +1 order light, -1 order light, and -2 order light.
In the third embodiment described above, it has been described that the irradiation order of the laser light is switched in the order of red, green and blue, but in the present invention, the irradiation order of the laser light is not particularly limited. For example, in the present invention, laser light may be emitted in the order of green, blue and red.

In each of the embodiments described above, the configuration example of the optical system in the hologram recording apparatus has been described, but the present invention is not limited to the configuration example.
Although each embodiment described above is described as switching ± first-order light and ± second-order light, the present invention is not limited to this. For example, in the present invention, only ± first-order light may be switched, or ± third-order light or more may be switched.

1, 1 B, 1 C Hologram recording device 10, 10 _R , 10 _G , 10 _B laser (light source)
18, 18 B SLM (Spatial Light Modulator)
20, 20B Spatial filter (switching means)
30, 30B, 30C Control device 31, 31B Storage means 33, 33B SF control means (switching control means)
35, 35 B SLM control means (spatial light modulator control means)
37 Light source control means

Claims (4)

A light source for generating a laser beam, a spatial light modulator for generating object light of each order by reflecting hologram data generated in advance on the laser light, object light of each order generated by the spatial light modulator A hologram recording apparatus comprising: switching means for switching to pass only the object light of any order, and recording interference fringes of the object light passing through the switching means and the reference light on a hologram recording medium,
Switching control means for switching the object light passed by the switching means to the switching means in time division;
Spatial light modulator control means for causing the spatial light modulator to display, in synchronization with the switching control means, the hologram data corresponding to the visual field of the object light to be passed by the switching means;
A hologram recording apparatus comprising:   The switching control means sets the exposure time in advance for each order of the object light so that the exposure amount of the object light of each order becomes uniform, and causes the object to pass based on the set exposure time. 2. The hologram recording apparatus according to claim 1, wherein light is switched to said switching means in time division. The spatial light modulator is an amplitude modulation type that generates interference light in a direction orthogonal to the switching direction of the object light, together with the object light of each order,
The switching means has a predetermined range in the orthogonal direction in the region for passing the object light as the shielding region of the interference light,
3. The hologram recording apparatus according to claim 1, wherein the switching control unit causes the switching unit to switch the shielding area of the interference light in a time division manner. A light source for generating a laser beam, a spatial light modulator for generating object light of each order by reflecting hologram data generated in advance on the laser light, object light of each order generated by the spatial light modulator A hologram recording apparatus comprising: switching means for switching, and passing only the object light of any order, and using the hologram recording device to record on the hologram recording medium the interference fringes of the object light passing through the switching means and the reference light A manufacturing method,
An object light switching step of causing the switching control means to switch the passing object light to the switching means in time division;
A hologram data display step of causing the spatial light modulator to display, in synchronization with the switching control means, the hologram data corresponding to the visual field of the object light to be passed in the object light switching step; ,
A hologram manufacturing method comprising:

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