KR102670718B1 - Holographic Printer For Recording Freeform Holographic Optical Elements - Google Patents

Abstract

The present invention relates to a holographic printer for recording free-form holographic optical elements, comprising: an intermediate plate for fixing a holographic medium; an object light unit that records holographic optical elements on the holographic medium in Hogel units by adjusting the wavenumber vector of object light emitted from a light source; and a reference light unit that controls the wavenumber vector of the reference light emitted from the light source and records holographic optical elements on the holographic medium in units of hogels. As a result, it is possible to record a wavefront with a smooth curved surface by changing the curvature of the wavefront of the reference light and object light in each hosel.

Description

Holographic printer for recording freeform holographic optical elements {Holographic Printer For Recording Freeform Holographic Optical Elements}

The present invention relates to a holographic printer for recording a free-form holographic optical element, and more specifically, to a holographic printer for recording a free-form holographic optical element capable of recording a free-form surface with a continuous wavefront. It's about.

Generally, in order to manufacture a holographic optical element, optical elements corresponding to the original object, such as lenses, mirrors, and aspherical optical elements, are required. When producing a HOE (holographic optical element) using these, the Optical elements can be reproduced using a light source similar to the light source, and by using this, various functions can be performed by replacing the optical elements required for existing immersive displays.

It is not always easy to implement the original object for recording a hologram, and the method of printing a hologram that reproduces the desired wavefront using a hologram printer is a method with high flexibility if the hologram to be output can be calculated. A hologram printed digitally in this way is called DDHOE, and the recording unit of the hologram is defined as a hogel.

Conventionally, arbitrary wavefronts are reproduced in Hogel units, but this inevitably results in distortion as wavefronts are recorded in a flat shape rather than the smooth curved surface of the Hogel unit. In particular, when projecting an image on a curved screen so that the viewer can feel immersed, the projector is placed above the viewer. Since the reference point of the projector and the viewer's viewpoint are not located at the same location, distortion due to the curvature of the screen occurs. This occurs, and such distortion inevitably occurs especially on the left and right sides.

Accordingly, the need for a holographic printer that can record phase information of complex-shaped free-form optical elements is emerging.

Korean Patent Publication No. 10-1423163

The present invention was created to solve the above problems, and the object of the present invention is to provide a free-form holographic optical device that can record a wavefront with a smooth curve by changing the curvature of the wavefront of the reference light and object light in each hogel. To provide a holographic printer for recording.

A holographic printer according to an embodiment of the present invention for achieving the above object includes an intermediate plate for fixing a holographic medium; an object light unit that records holographic optical elements on the holographic medium in Hogel units by adjusting the wavenumber vector of object light emitted from a light source; and a reference light unit that controls the wavenumber vector of the reference light emitted from the light source and records holographic optical elements on the holographic medium in units of hogels.

Here, the object light unit and the reference light unit may be provided to be symmetrical up and down with respect to the middle plate.

And the object light unit includes: a first fixing plate positioned at a certain distance from the middle plate; a first linear stage provided on one surface of the first fixing plate adjacent to the intermediate plate to change a position at which the object light is irradiated; a first goniometer connected to the first linear stage to change a wavenumber vector direction of the object light; and a first collimator coupled to the first goniometer to form light waves of the object light.

In addition, the reference light unit includes a second fixed plate positioned at a certain distance from the intermediate plate; a second linear stage provided on one surface of the second fixing plate adjacent to the intermediate plate to change a position at which the reference light is irradiated; a second goniometer connected to the second linear stage to change the wavenumber vector direction of the reference light; And it may include a second collimator coupled to the second goniometer to form a light wave of the reference light.

And the object light unit further includes a first adjustment member coupled to the first collimator to adjust the curvature of the wavefront of the object light within the hogel, and the reference light unit is coupled to the second collimator and includes the first control member within the hogel. It may further include a second adjustment member that adjusts the curvature of the wavefront of the reference light.

Additionally, the first and second adjustment members may be lenses or mirrors that can adjust the focal length based on electrical signals.

According to one aspect of the present invention described above, by providing a holographic printer for recording a free-form holographic optical element, a wavefront having a smooth curve can be recorded by changing the curvature of the wavefront of the reference light and the object light in each hogel. there is.

In addition, by providing a holographic printer for recording the free-form holographic optical element of the present invention, recording is possible by changing the wave number vector of the reference light, so even when non-parallel reference light is used, the problem of low luminous efficiency of the reproduction light can be solved. .

1 is a cross-sectional view illustrating the holographic printer of the present invention;
Figure 2 is a perspective cross-sectional view for explaining the holographic printer of the present invention;
Figure 3 is a diagram for explaining the wavenumber vector directions of reference light and object light in a conventional holographic printer;
Figure 4 is a diagram for explaining the wavenumber vector directions of reference light and object light in the holographic printer of the present invention, and
Figure 5 is a diagram comparing the curvature of the wavefront recorded in each hosel in the holographic printer of the present invention and the conventional holographic printer.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in one embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

Figure 1 is a cross-sectional view for explaining the holographic printer 10 of the present invention, Figure 2 is a perspective cross-sectional view for explaining the holographic printer 10 of the present invention, and Figure 3 is a diagram of reference light and object light in a conventional holographic printer. Figure 4 is a diagram for explaining the wavenumber vector direction of the reference light and object light in the holographic printer 10 of the present invention, and Figure 5 is a diagram for explaining the wavenumber vector direction of the holographic printer 10 of the present invention. This is a diagram comparing the curvature of the wavefront recorded on each hosel in a conventional holographic printer.

The holographic printer 10 of the present invention is a holographic printer for recording free-form holographic optical elements. More specifically, in order to solve the problem of conventional holographic printers that cause distortion by recording fragmented wavefronts in a flat form, the reference light and object light in each hogel change the wavefront curvature to record a wavefront with a smooth curved surface. You can. And through this, the problem that the luminous efficiency of the reproduction light is lowered even when non-parallel reference light is used can be solved.

To this end, the holographic printer 10 according to this embodiment may include an intermediate plate 100, an object light unit 200, and a reference light unit 300.

As shown in FIGS. 1 and 2, the intermediate plate 100 is provided between the object light unit 200 and the reference light unit 300. This intermediate plate 100 contains a hologram medium 110 for recording a hologram. This can be fixed. And the object light unit 200 and the reference light unit 300 are provided vertically symmetrically based on the middle plate 100, so that the object light emitted from the object light unit 200 and the reference light emitted from the reference light unit 300 are transmitted through the hologram medium 110. ) so that the hogel can be recorded.

Meanwhile, the object light unit 200 may be provided to record a holographic optical element in a hogel unit on the holographic medium 110 by adjusting the wavenumber vector of the object light emitted from the light source, and as shown in the figure, the intermediate plate 100 ) may be located at the lower or upper part of the middle plate 100. Hereinafter, for convenience of explanation, the description will be based on the case where the object light unit 200 is located below the middle plate 100 as shown in the drawing.

This object light unit 200 includes a first fixing plate 210, a first linear stage 220, a first goniometer 230, a first collimator 240, and a first adjustment member 250. can do.

The first fixing plate 210 is located at a certain distance from the middle plate 100 and is provided to fix a part of the first linear stage 220. Here, the distance between the first fixing plate 210 and the middle plate 100 refers to the components located between the middle plate 100 and the first fixing plate 210, that is, the first linear stage 220, the first gonier It is greater than the height formed by combining the meter 230, the first collimator 240, and the first adjustment member 250, and refers to a distance appropriate for recording the hogel on the hologram medium 110, which is determined in advance by the designer. It may be a set distance.

Meanwhile, the first linear stage 220 may be provided on one side of the first fixing plate 210 adjacent to the intermediate plate 100 to change the position at which the object light is irradiated. And, as shown, this first linear stage 220 may be provided to include rails that allow it to move in two axes including the X-axis and Y-axis. Additionally, the position at which the object light is irradiated can be changed by allowing the first goniometer 230, which is partially fixed to the first linear stage 220, to change its position along the X-axis and Y-axis. Therefore, the first linear stage 220 can have an x-axis and a y-axis, enabling Hogel recording in a 2D array form on the hologram medium 110.

The first goniometer 230 is connected to the first linear stage 220 and may be provided to change the wavenumber vector direction of object light. While the first goniometer 230 is fixed to the first linear stage 220, the position at which the object light is irradiated can be changed according to the movement of the first linear stage 220.

In addition, the first goniometer 230 is provided to be rotatable about two axes as shown by the arrows in FIG. 2, so that object light is transmitted simultaneously with movement along the X- and Y-axes through the first linear stage 220. The direction of irradiation can be changed. Through this first goniometer 230, the holographic printer 10 of the present invention allows the light wave of the object light emitted from the first collimator 240 via the first adjustment member 250 to enter the hosel at a designed angle. You can do it.

The first collimator 240 may be coupled to the first goniometer 230 to form light waves of object light.

The first adjustment member 250 may be coupled to the first collimator 240 to adjust the curvature of the wavefront of the object light within the hogel. In this embodiment, a liquid lens is used as a variable focus lens, but it is not limited to this, and the first adjustment member 250 may be provided as a lens or mirror as long as the focal length can be adjusted based on an electrical signal. The holographic printer 10 of the present invention records the fragmented planar wavefront of each hogel as a wavefront of optimal curvature through the first adjustment member 250, so that only the fragments are free from distortion caused by the plane wavefront. You can.

Meanwhile, the reference light unit 300 may be provided to record a holographic optical element in a hogel unit on the holographic medium 110 by adjusting the wavenumber vector of the reference light emitted from the light source, and as shown in the figure, the middle plate ( It may be located at the upper or lower part of the middle plate 100 based on 100). That is, since the object light unit 200 and the reference light unit 300 are provided so that they are vertically symmetrical with respect to the middle plate 100, the positions of the object light unit 200 or the reference light unit 300 may be mutually changeable. Hereinafter, for convenience of explanation, the description will be based on the case where the reference light unit 300 is located on the upper part of the intermediate plate 100 as shown in the drawing.

This reference light unit 300 includes a second fixing plate 310, a second linear stage 320, a second goniometer 330, a second collimator 340, and a second adjustment member 350. can do.

The second fixing plate 310 is positioned at a certain distance from the middle plate 100 and may be provided to fix a portion of the second linear stage 320. Here, the distance between the second fixing plate 310 and the middle plate 100 is the component located between the middle plate 100 and the second fixing plate 310, that is, the second linear stage 320, the second gonier It is greater than the height formed by combining the meter 330, the second collimator 340, and the second adjustment member 350, and refers to a distance appropriate for recording the hogel on the hologram medium 110, which is determined in advance by the designer. It may be a set distance.

The second linear stage 320 may be provided on one side of the second fixing plate 310 adjacent to the intermediate plate 100 to change the position at which the reference light is irradiated. In addition, the second linear stage 320 may be provided to include rails that allow it to move in two axes including the X and Y axes, in the same way as the above-described first linear stage 220. Additionally, a portion of the second goniometer 330 is fixed to the second linear stage 320, and the fixed position of the second goniometer 330 can be moved along the X-axis and Y-axis. Accordingly, the second linear stage 320 has an

The second goniometer 330 may be connected to the second linear stage 320 and may be provided to change the direction of the wavenumber vector of the reference light. While the second goniometer 330 is fixed to the second linear stage 320, the position at which the reference light is emitted can be changed according to the movement of the second linear stage 320.

In addition, the second goniometer 330 is provided to be rotatable about two axes like the first goniometer 230, as indicated by the arrow shown in FIG. 2, and can be rotated around the X and Y axes through the second linear stage 320. The direction in which the reference light is irradiated can be changed simultaneously with movement on the ship. Through this second goniometer 330, the holographic printer 10 of the present invention allows the light wave of the reference light emitted from the second collimator 340 via the second adjustment member 350 to enter the hogel at a designed angle. You can do it.

In particular, the holographic printer 10 of the present invention, unlike a conventional holographic printer that has a structure in which only the parallel reference light is recorded by adjusting only the wave number vector of the object light, adjusts the wave number of the reference light through the second goniometer 330. Since hogel recording is possible by adjusting the vector, the problem of low luminous efficiency of the reproduction light can be solved even when non-parallel reference light is used.

More specifically, FIG. 3(a) is a diagram for a case where the reference light is a plane wave and the object light diverges, and FIG. 3(b) is a diagram for a case where the reference light is still a plane wave and the object light is converging. That is, as shown in FIG. 3, the conventional holographic printer records holographic optical elements by adjusting the direction of the wave number vector of the object light while the direction of the wave number vector of the reference light is fixed. Therefore, there is a problem that the reference light has no choice but to record Hogel with a fixed wavenumber vector.

However, the holographic printer 10 of the present invention can adjust the wavenumber vector direction of the reference light by providing the reference light unit 300 with a second goniometer 330, and the holographic optical elements recorded in this way can be used in various types. It is possible to improve the diffraction light efficiency with respect to the reference light.

Specifically referring to FIG. 4, FIG. 4(a) is a diagram showing a case where reference light diverges and object light converges, and FIG. 4(b) is a diagram showing a case where reference light converges and object light also converges. That is, the holographic printer 10 of the present invention can adjust the wavenumber vector direction of the reference light by the second goniometer 330 as well as the parallel reference light, so that the holographic optical element is recorded with the diverging reference light or the converging reference light. can do. The holographic optical element recorded in this way can improve diffraction light efficiency even when reproduced with non-parallel reference light.

The second collimator 340 may be coupled to the second goniometer 330 to form light waves of reference light.

Additionally, the second adjustment member 350 may be coupled to the second collimator 340 to adjust the curvature of the wavefront of the reference light within the hogel. In this embodiment, a liquid lens is used as a variable focus lens, but it is not limited to this, and the second adjustment member 350 may be provided as a lens or mirror as long as the focal length can be adjusted based on an electrical signal. The holographic printer 10 of the present invention records the fragmented planar wavefront of each hogel as a wavefront of optimal curvature through the second adjustment member 350, so that only the fragments are free from distortion caused by the plane wavefront. You can.

Conventional holographic printers record by adjusting only the wavenumber vectors of reference light and object light for each hogel. In this conventional recording method, a flat wavefront with a curvature of 0 in a fragmented form is recorded, as shown in the dotted line shown in FIG. 5. When the wavefront recorded in this form is reproduced, distortion is bound to occur because each hogel cannot be smoothly connected.

On the other hand, the holographic printer 10 of the present invention, unlike a conventional holographic printer that reproduces an arbitrary wavefront on a hogel basis through the above-described configuration, can change the curvature of the wavefront of the reference light and object light recorded in each hogel. there is. Therefore, as shown in the solid line shown in FIG. 5, the size of the reproduced beam can be compensated by adjusting the curvature of the wavefront of each recorded Hogel.

Therefore, the holographic printer 10 of the present invention can record a free-form holographic optical element with a continuous wave front, and thus can record phase information of a free-form optical element of a complex shape.

The components according to the present invention are components defined by functional division rather than physical division, and can be defined by the functions each performs. Each component may be implemented as hardware or program code and processing units that perform each function, and the functions of two or more components may be included and implemented in one component. Therefore, the names given to the components in the following embodiments are not intended to physically distinguish each component, but are given to suggest the representative function performed by each component, and the names of the components are used to describe the present invention. It should be noted that the technical idea is not limited.

Although various embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and may be used in the technical field to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

10: Holographic printer
100: middle plate 110: hologram medium
200: Object Miner
210: first fixing plate 220: first linear stage
230: first goniometer 240: first collimator
250: first adjustment member
300: Reference miner
310: second fixing plate 320: second linear stage
330: second goniometer 340: second collimator
350: second adjustment member

Claims (6)

A middle plate that holds the holographic medium in place;
an object light unit that records holographic optical elements on the holographic medium in Hogel units by adjusting the wavenumber vector of object light emitted from a light source; and
A reference light unit that adjusts the wavenumber vector of the reference light emitted from the light source to record holographic optical elements in the holographic medium in units of Hogel,
The object miner,
a first fixing plate positioned at a certain distance from the middle plate;
a first linear stage provided on one surface of the first fixing plate adjacent to the intermediate plate to change a position at which the object light is irradiated;
a first goniometer connected to the first linear stage to change the wavenumber vector direction of the object light; and
A holographic printer comprising a first collimator coupled to the first goniometer to form light waves of the object light. According to paragraph 1,
A holographic printer, wherein the object light unit and the reference light unit are provided symmetrically up and down with respect to the middle plate. delete According to paragraph 1,
The reference miner is,
a second fixing plate positioned at a certain distance apart from the middle plate;
a second linear stage provided on one surface of the second fixing plate adjacent to the intermediate plate to change a position at which the reference light is irradiated;
a second goniometer connected to the second linear stage to change the wavenumber vector direction of the reference light; and
A holographic printer comprising a second collimator coupled to the second goniometer to form a light wave of the reference light. According to clause 4,
The object miner,
It further includes a first adjustment member coupled to the first collimator to adjust the curvature of the wavefront of the object light within the hogel,
The reference miner is,
The holographic printer further comprises a second adjustment member coupled to the second collimator to adjust the curvature of the wavefront of the reference light within the hogel. According to clause 5,
The first and second adjustment members are,
A holographic printer characterized by a lens or mirror whose focal length can be adjusted based on electrical signals.