KR20220168817A - Computational holographic imaging apparatus based on volume holographic optical element for color dispersion free holographic virtual display - Google Patents

Abstract

The embodiments of the present invention provide a holographic imaging device, which can be applied to a holographic augmented reality display through a numerical holographic imaging model capable of eliminating color dispersion according to two-step Bragg diffraction by using a combination of multiple volume holographic optical element (VHOE) designed in advance.

Description

VHOE-based computer holographic imaging device for color compensated holographic augmented reality display

The technical field to which the present invention belongs relates to a color compensation method and a holographic imaging device.

The contents described in this part merely provide background information on the present embodiment and do not constitute prior art.

Holographic imaging technology is largely divided into two types. Hologram imaging and holographic optical element area. One of the major problems common to holographic technology is color dispersion.

Existing color dispersion compensation technologies have been variously proposed in the field of holographic lenses or imaging, but as holographic optical elements have received intensive attention in augmented/virtual/mixed reality displays, there are technical limitations in implementing them with existing methods. It is necessary to verify the value of new numerical approaches and optical implementations for new displays.

Korean Registered Patent Publication No. 10-1941063 (2019.01.16)

Embodiments of the present invention are a multi-VHOE (Volume Holographic Optical Element) based transmissive full color holographic imaging device using a combination of two pre-designed VHOEs to develop a numerical holographic imaging model in which color dispersion according to two-step Bragg diffraction can be eliminated. The main purpose of the invention is to apply to various types of augmented reality holographic displays through

Other non-specified objects of the present invention may be additionally considered within the scope that can be easily inferred from the following detailed description and effects thereof.

According to one aspect of the present embodiment, in the holographic imaging device, the control unit for adjusting the incident angle of the reconstructed beam; a panel that emits the reconstructed beam; a first holographic optical element having a first diffraction grating on which a first interference fringe by a first reference beam and a first object beam is recorded, and diffracting the reconstruction beam; and a second holographic optical element having a second diffraction grating on which a second interference fringe by a second reference beam and a second object beam is recorded, and outputting an output beam by diffracting the reconstructed beam. An imaging device is provided.

The panel may cause the reconstructed beam to be incident off-axis.

The second holographic optical element may provide a holographic image in an on-axis direction.

The controller may adjust the incident angle of the reconstructed beam to compensate for the color irrespective of the different wavelengths of the reconstructed beam.

When the reconstructed beam is incident in the direction of the recorded first reference beam, an angle of the beam exiting the first diffraction grating may correspond to an angle of the recorded first object beam.

The control unit may be configured to satisfy a first condition defined as a relationship between an incident angle of the reconstructed beam and a diffraction angle of the output beam.

The control unit may set the incident angle of the reconstructed beam to be the same as the diffraction angle of the output beam.

The control unit may be configured to satisfy a second condition defined as a relationship between an incident angle of the reconstructed beam and a recorded diffraction angle of the first object beam.

The control unit may set the incident angle of the reconstructed beam to have a direction inverted with respect to the side of the recorded diffraction angle of the first object beam.

According to another aspect of the present embodiment, a color compensation method for a holographic imaging device includes adjusting an incident angle of a reconstruction beam; emitting the reconstructed beam; diffracting the reconstructed beam through a first holographic optical element; and outputting an output beam by diffracting the reconstructed beam through a second holographic optical element.

As described above, according to embodiments of the present invention, various forms of augmentation are obtained through a numerical holographic imaging model capable of eliminating color dispersion according to two-step Bragg diffraction using a combination of multiple VHOE (Volume Holographic Optical Element) designed in advance. There is an effect that can be applied to a real holographic display.

Even if the effects are not explicitly mentioned here, the effects described in the following specification expected by the technical features of the present invention and their provisional effects are treated as described in the specification of the present invention.

1 is a block diagram illustrating a holographic imaging device according to an embodiment of the present invention.
2 is a diagram illustrating two-step diffraction of a holographic imaging device according to an embodiment of the present invention.
3 is a diagram illustrating numerical analysis for color compensation of a holographic imaging device according to an embodiment of the present invention.
4 is a flowchart illustrating a color compensation method of a holographic imaging device according to another embodiment of the present invention.
5 and 6 are diagrams illustrating test images simulated in embodiments of the present invention.

Hereinafter, in the description of the present invention, if it is determined that a related known function may unnecessarily obscure the subject matter of the present invention as an obvious matter to those skilled in the art, the detailed description thereof will be omitted, and some embodiments of the present invention will be described. It will be described in detail through exemplary drawings.

The present invention can be applied to a holographic display for augmented/virtual reality, a holographic artificial intelligence avatar display, a holographic artificial intelligence speaker, a holographic projection, and the like.

A holographic imaging device for color compensation of a holographic display has a structure that compensates for color dispersion while generating an obliquely incident beam and a frontally output beam. At least two or more holographic elements are designed and arranged, and since the VHOE element diffracts only the first-order component, it has a great advantage in display applications than thin holographic elements that diffract multiple orders. The VHOE-based color dispersion compensation theory derives a generalized numerical model capable of designing both on-axis and off-axis approaches. This means that under preset conditions, the conditions of the designed model are satisfied regardless of the wavelength, and color compensation is performed under these conditions.

1 is a block diagram illustrating a holographic imaging device according to an embodiment of the present invention.

The holographic imaging device 10 includes a controller 100 , a panel 200 , a first holographic optical element 310 and a second holographic optical element 320 .

The first holographic optical element 310 and the second holographic optical element 320 may be implemented as VHOE.

Panel 200 emits a reconstruction beam. The image for holographic implementation emitted from the panel 200 is converted into a holographic image after passing through the first holographic optical element 310 and the second holographic optical element 320 . The panel 200 may make the reconstruction beam incident on the plane of the first holographic optical device 310 off-axis.

The first holographic optical element 310 has a first diffraction grating on which a first interference pattern by the first reference beam and the first object beam is recorded. The first holographic optical element 310 diffracts the incident reconstruction beam.

The second holographic optical element 320 has a second diffraction grating on which a second interference fringe by the second reference beam and the second object beam is recorded. The second holographic optical element 320 outputs an output beam by diffracting the diffracted reconstruction beam. The second holographic optical element 320 may provide a holographic image on-axis.

The controller 100 adjusts the angle of incidence of the reconstructed beam.

The controller 100 may adjust the incident angle of the reconstructed beam to compensate for the color irrespective of the different wavelengths of the reconstructed beam. When the reconstructed beam is incident in the direction of the recorded first reference beam, the angle of the beam exiting the first diffraction grating may correspond to the angle of the recorded first object beam.

The controller 100 may set the first condition defined as the relationship between the incident angle of the reconstructed beam and the diffraction angle of the output beam to be satisfied. The controller 100 may set the incident angle of the reconstructed beam to be the same as the diffraction angle of the output beam.

The controller 100 may set to satisfy the second condition defined as the relationship between the incident angle of the reconstructed beam and the recorded diffraction angle of the first object beam. The controller 100 may set the incident angle of the reconstructed beam to have an inverted direction relative to the side of the recorded diffraction angle of the first object beam.

2 is a diagram illustrating two-step diffraction of a holographic imaging device according to an embodiment of the present invention.

When the Bragg matching light is incident on the VHOE, object waves are reproduced according to the Bragg diffraction law, and the electric fields of the two waves are expressed as in Equation 1.

E _R is the reference wave, E _O is the object wave, E _R ,E _O are the amplitudes of the reference wave and the object wave, and K _R ,K ₀ are the grid waves of the reference wave and the object wave. r _R ,r _O are the positions of the two point sources for the reference wave and the object wave. The intensity of an interference pattern between two Gaussian waves on a recording medium such as a photopolymer-based VHOE is expressed as Equation 2.

When E _R , E _O are sequentially mixed with E _R , the optical intensity of I is as shown in Equation 2. The grating pattern corresponding to I is recorded on a photopolymer-based VHOE. K _G is the lattice wave vector of the object wave and the reference wave and is expressed as in Equation 3.

K _G is the grid vector normalized to the edge.

The Bragg lattice equation between two Gaussian waves is expressed as Equation 4 and means the Bragg condition.

θ can be defined as half angles outside and inside the recording medium representing the intersection angle of the reference beam and the object beam. N is the diffraction number, and has only the first order in the case of VHOE representing a thick region, and λ and n represent the recording wavelength and refractive index, respectively. When N = 1, the grating period is expressed as Λ = λ/2nsinθ.

When the R, G and B colors are incident on the VHOE at the divergent angle, they are theoretically all diffracted in parallel. In order to apply VHOE without chromatic dispersion, photopolymers must have properties such as high diffraction efficiency, low distortion of diffracted light, and uniformity of intensity of diffracted light.

VHOEs made from photopolymers are affected by the photopolymer's physical and optical properties. Photopolymers are excellent in terms of self-development ability, dry processing, good stability, thick emulsion, high sensitivity, large diffraction efficiency, high resolution and non-volatile storage. Given a reference beam and an object beam in a volume hologram, their fixed interference pattern is formed.

3 is a diagram illustrating numerical analysis for color compensation of a holographic imaging device according to an embodiment of the present invention.

Considering the numerical solution to a multi-VHOE system, the numerical expression for a holographic diffraction grating or lens is described by longitudinal and transverse equations. Longitudinal equations include distances for reference and object beams, configuration and reconstruction, as shown in Equation 5.

μ= λ _c /λ _r , where m is the magnification of the hologram, R _I ,R _c ,R _o ,R _r are the reconstruction distance as focus, the distance from the actual incident beam position to the VHOE plane, and the recording distance between the object and the reference point source to be. The focal direction is expressed alternatively in the transverse equation as:

Simplified with a magnification of m=1, Equation 5 represents a paraxial axis lens in the longitudinal direction. Equations 6 and 7 represent off-axis lens equations in the transverse direction.

Since we consider the reconstructed image diffracted from the planar object image in the transverse direction away from the VHOE device, we treat the compensation corresponding to the off-axis angle of incidence of the planar object information. Since correction cannot be performed with only one VHOE, multiple VHOEs with low dispersion and low aberration are adopted as a color correction method.

We derive an analysis of two common multi-holographic optical element geometries for off-axis incidence and fixed-axis holographic imaging.

For a single VHOE, the angular equation is considered a combination of the interference equation and the diffraction equation. The interference grating equation is expressed as Equation 9.

where f is the spatial frequency of the grating. Λ _i and λ _i represent the grating period and each recording wavelength in free space. α _R1 and α _O1 represent the reference wave and the object wave for constructing the interference grating. Since 2π is used when calculating the phase value, it can be omitted. The diffraction equation of the spatial frequency interference grating is expressed as Equation 10.

λ _j represents the incident wavelength in each direction in the free space of the diffraction grating. α _I1 , α _C1 represent the diffraction angle of the output beam and the incidence angle of the reconstructed beam for reconstructing the interference grating. n is the diffraction order, and since the first order appears only in VHOE, it can be expressed as 1.

In order to implement a holographic optical imaging device through Equations 8 and 10, we propose a new mathematical model that compensates for chromatic dispersion regardless of the wavelength of the incident beam in the two VHOE layers. Assume that the recording wavelength is green only. That is, assuming that i = g and j = g, the angle equation is expressed as:

When the reconstruction beam is incident on the diffraction grating in the direction of the recording reference beam, the angle of the output beam exiting the diffraction grating is the same as the angle of the recording target beam. For other wavelength recovery beams such as i = r, b, the angle equation is expressed as:

In Equation 12, the two equations for compensation are expressed as follows.

Summarizing Equation 13 for the (+) sign is expressed as Equation 14.

Regardless of the wavelength, the first condition for color correction is expressed as Equation 15.

Then α _I2 is always equal to α _O2 . That is, the direction of the reconstruction beam incident on the VHOE plane must be the same as that of the recording beam. In this case, the diffraction angle of the output beam must be the same as the diffraction angle of the incident image beam. Although the optical axis of the VHOE device can be tilted, the output holographic imaging must be formed along the optical axis of the input object beam.

Summarizing Equation 13 for the (-) sign, it is expressed as Equation 16.

Regardless of the wavelength, the second condition for color correction is expressed as Equation 17.

This requires that the direction of the reconstruction beam incident on the plane of the VHOE be reversed to the direction and side of the recording beam. A color compensation holographic imaging device to which an off-axis input beam with imaging information and a positive axis (or other axis) output beam having an angle different from the direction of the input beam are applied. Regardless, the lateral color dispersion can be minimized with two multi-single color VHOE planes.

4 is a flowchart illustrating a color compensation method of a holographic imaging device according to another embodiment of the present invention.

A color compensation method of a holographic imaging device includes adjusting an incident angle of a reconstructed beam (S10), emitting a reconstructed beam (S20), diffracting the reconstructed beam through a first holographic optical element (S30), and and outputting an output beam by diffracting the reconstructed beam through a second holographic optical element (S40).

In the step of emitting the reconstructed beam (S20), the reconstructed beam is incident on the reserve axis.

In the step of outputting the output beam (S40), a holographic image is provided in the positive axis.

Adjusting the angle of incidence of the reconstructed beam ( S10 ) adjusts the angle of incidence of the reconstructed beam to compensate for the color irrespective of different wavelengths of the reconstructed beam. When a reconstructed beam is incident in the direction of the written first reference beam, the angle of the beam exiting the first diffraction grating corresponds to the angle of the written first object beam.

Adjusting the incident angle of the reconstructed beam (S10) is set to satisfy a first condition defined as a relationship between the incident angle of the reconstructed beam and the diffraction angle of the output beam.

Adjusting the incident angle of the reconstructed beam ( S10 ) is set to satisfy the second condition defined by the relationship between the incident angle of the reconstructed beam and the recorded diffraction angle of the first object beam.

5 and 6 are diagrams illustrating test images simulated in embodiments of the present invention.

5(a), (b), and (c) are outputs obtained by passing a three-color source image through a single VHOE, and (d), (e), and (f) of FIG. is the output passed to

(a), (b), (c), and (d) of FIG. 6 are outputs obtained by passing a white K image through a single VHOE, and (e), (f), (g), and (h) of FIG. This is the output of passing the white K image through multiple VHOEs.

As shown in the computational simulation test results according to FIGS. 5 and 6, an augmented reality display in which the output beam is on-axis and the input beam is off-axis according to the condition that color compensation is possible regardless of the wavelength. can be implemented.

Components included in the holographic imaging device are shown separately in FIG. 1 , but a plurality of components may be combined with each other to be implemented as at least one module.

The holographic imaging apparatus may be installed in a computing device equipped with hardware elements in the form of software, hardware, or a combination thereof. A computing device includes a variety of devices including all or part of a communication device such as a communication modem for communicating with various devices or wired/wireless communication networks, a memory for storing data for executing a program, and a microprocessor for executing calculations and commands by executing a program. can mean a device.

In FIG. 4, it is described that each process is sequentially executed, but this is merely an example, and a person skilled in the art changes and executes the sequence described in FIG. 4 within the range not departing from the essential characteristics of the embodiment of the present invention. Alternatively, it will be possible to apply various modifications and variations by executing one or more processes in parallel or adding another process.

These embodiments are for explaining the technical idea of this embodiment, and the scope of the technical idea of this embodiment is not limited by these embodiments. The scope of protection of this embodiment should be construed according to the claims below, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of rights of this embodiment.

10: holographic imaging device
100: control unit
200: panel
310: first holographic optical element
320: second holographic optical element

Claims (15)

In the holographic imaging device,
a control unit for adjusting the angle of incidence of the reconstructed beam;
a panel that emits the reconstructed beam;
a first holographic optical element having a first diffraction grating on which a first interference fringe by a first reference beam and a first object beam is recorded, and diffracting the reconstruction beam; and
Holographic imaging including a second holographic optical element having a second diffraction grating on which a second interference fringe by a second reference beam and a second object beam is recorded, and outputting an output beam by diffracting the reconstructed beam. Device. According to claim 1,
The panel is a holographic imaging device, characterized in that for incident the reconstruction beam off-axis. According to claim 1,
The holographic imaging device, characterized in that the second holographic optical element provides a holographic image on-axis. According to claim 1,
The holographic imaging device according to claim 1 , wherein the control unit adjusts an incident angle of the reconstructed beam to compensate for color irrespective of different wavelengths of the reconstructed beam. According to claim 1,
When the reconstructed beam is incident in the direction of the recorded first reference beam, an angle of the beam emitted from the first diffraction grating corresponds to an angle of the recorded first object beam. According to claim 1,
The holographic imaging device of claim 1 , wherein the control unit sets a first condition defined as a relationship between an incident angle of the reconstruction beam and a diffraction angle of the output beam to be satisfied. According to claim 1,
The control unit sets an incident angle of the reconstructed beam equal to a diffraction angle of the output beam. According to claim 1,
The holographic imaging device according to claim 1 , wherein the control unit sets a second condition defined by a relationship between an incident angle of the reconstructed beam and a diffraction angle of the recorded first object beam to be satisfied. According to claim 1,
The control unit sets the incident angle of the reconstructed beam to have an inverted direction with respect to the side of the recorded diffraction angle of the first object beam. In the color compensation method of a holographic imaging device,
adjusting the angle of incidence of the reconstruction beam;
emitting the reconstructed beam;
diffracting the reconstructed beam through a first holographic optical element; and
and outputting an output beam by diffracting the reconstructed beam through a second holographic optical element. According to claim 10,
In the step of emitting the reconstructed beam, the reconstructed beam is incident on a reserve axis;
The color compensation method of the holographic imaging device, characterized in that the step of outputting the output beam provides a holographic image in a positive axis. According to claim 10,
The step of adjusting the angle of incidence of the reconstructed beam comprises adjusting the angle of incidence of the reconstructed beam to compensate for color regardless of different wavelengths of the reconstructed beam. According to claim 10,
When the reconstructed beam is incident in the direction of the recorded first reference beam, an angle of the beam emitted from the first diffraction grating corresponds to an angle of the recorded first object beam. Color compensation of the holographic imaging device, characterized in that method. According to claim 10,
The step of adjusting the incident angle of the reconstruction beam is set to satisfy a first condition defined by a relationship between the incident angle of the reconstruction beam and the diffraction angle of the output beam Color compensation method of a holographic imaging device. According to claim 10,
Adjusting the incident angle of the reconstruction beam is set to satisfy a second condition defined by a relationship between the incident angle of the reconstruction beam and the recorded diffraction angle of the first object beam, color compensation of the holographic imaging device, characterized in that method.

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