KR102494764B1 - Hologram printing system based on microlens array - Google Patents

Abstract

A hologram printing system based on a micro lens array is provided. A hologram printing system according to an embodiment of the present invention includes a beam splitter; and a reflective Spatial Light Modulator (SLM) that displays a hologram pattern composed of unit holograms and, when light separated by the beam splitter is incident, is reflected to emit a hologram pattern. Accordingly, as the physical size of unit holograms decreases in the hologram printing system, it is possible to reproduce hologram contents having a high viewing angle. In addition, since a number of unit holograms are simultaneously recorded compared to the existing hologram printing system, the hologram printing time can be greatly reduced.

Description

Hologram printing system based on microlens array}

The present invention relates to a hologram printing system, and more particularly to a hologram printing system based on a micro lens array.

As described in Korean Patent Registration No. 10-1826741, the conventional hologram printing technology transmits light of a predetermined color from a light source 10 to a reference light 11 and a material light 21 by an optical separator 40. ), and when the reference light 11 is incident on a predetermined position of the hologram recording medium 50 at a predetermined angle via the reflection mirror 12, the object light 21 is transmitted through the reflection mirror 22 and the lens. After being incident on the spatial light modulator (SLM, 30) on which information of a predetermined color is displayed via the fields (23, 24), the modulated object light (21) passing through the spatial light modulator (30) is an object lens ( 25) to be incident on the hologram recording medium 50.

At this time, an interference pattern of the reference light 11 and the object light 21 is printed at a predetermined location of the hologram recording medium 50 where the reference light 11 and the object light 21 are incident.

Hologram recording can be performed by printing the interference patterns corresponding to all positions of an actual 3D image while moving the hologram recording medium 50 in the x direction or the y direction.

However, since the hologram patterns corresponding to R, G, and B are sequentially recorded in this conventional hologram printing technology to restore a color hologram, there is a disadvantage that three times more recording time is required compared to the existing recording time. .

In addition, problems such as chromatic dispersion distortion in a hologram reconstruction image may occur due to a difference in diffraction efficiency for R, G, and B colors according to a recording medium.

Korean Patent Registration No. 10-1826741 (Title of Invention: Holographic 3D Image Printing Method)

The present invention has been made to solve the above problems, and an object of the present invention is to create a hologram printing system composed of a spatial light modulator, a micro lens array and optical elements and a hologram pattern composed of a plurality of unit holograms, It is an object of the present invention to provide a hologram printing system based on a micro lens array capable of reducing the recording time of the existing hologram printing time by a factor of the total number of micro lenses and providing a hologram reconstruction image with a greatly expanded viewing angle.

According to an embodiment of the present invention for achieving the above object, a hologram printing system includes a beam splitter; and a reflective Spatial Light Modulator (SLM) that displays a hologram pattern composed of unit holograms and, when light separated by the beam splitter is incident, is reflected to emit a hologram pattern.

And, according to an embodiment of the present invention, the hologram printing system includes a microlens array into which the hologram pattern emitted by the reflective spatial light modulator is incident; and a relay optic to which the hologram pattern passing through the micro lens array is incident.

In addition, the hologram pattern passing through the microlens array is recorded on the hologram film after the size of the plenoptic is reduced by the relay optic, and the actual size of the individual hologram is formed to be the same as the size of the individual lens in the microlens array, A distance between the micro lens array and the relay optic may be twice the focal length of an element lens in the micro lens array.

And, according to an embodiment of the present invention, the hologram printing system includes a relay optic into which the hologram pattern emitted by the reflective spatial light modulator is incident; and a microlens array into which the hologram pattern passing through the relay optic is incident.

In addition, the hologram pattern passing through the micro lens array is recorded on the hologram film, the individual hologram patterns in the spatial light modulator are reduced in size by relay optics, and the distance between the micro lens array and the hologram film is an element in the micro lens array It can be twice the focal length of the lens.

Also, when the hologram pattern passes through the relay optic before the micro lens array, the physical size of the unit hologram displayed on the spatial light modulator may be greater than the size of the micro lens by the reciprocal of the demagnification ratio.

On the other hand, in the hologram printing system according to another embodiment of the present invention, a hologram pattern composed of unit holograms is displayed, and when light is incident, it is transmitted and the hologram pattern is emitted. ); a microlens array into which the hologram pattern emitted by the transmissive spatial light modulator is incident; and a relay optic into which the hologram pattern passing through the micro lens array is incident.

The actual size of each individual hologram may be the same as that of each individual lens in the microlens array, and the distance between the microlens array and the relay optic may be twice the focal length of the element lens in the microlens array.

In addition, in the hologram printing system according to another embodiment of the present invention, a hologram pattern composed of unit holograms is displayed, and when light is incident, it is transmitted and the hologram pattern is emitted. ); a relay optic into which the hologram pattern emitted by the transmissive spatial light modulator is incident; and a microlens array into which the hologram pattern passing through the relay optic is incident.

Further, the distance between the micro lens array and the hologram film is twice the focal length of the element lens in the micro lens array, and the actual size of each hologram may be the same as the size of each individual lens in the micro lens array.

As described above, according to embodiments of the present invention, as the physical size of a unit hologram decreases in a hologram printing system, it is possible to reproduce hologram content having a high viewing angle.

In addition, since a number of unit holograms are simultaneously recorded compared to the existing hologram printing system, the hologram printing time can be greatly reduced.

1 is a view provided for explanation of a hologram printing system based on a micro lens array according to a first embodiment of the present invention;
2 is a diagram provided for explanation of a micro-lens array-based hologram printing system according to a second embodiment of the present invention;
3 is a diagram provided for explanation of a hologram printing system based on a micro lens array according to a third embodiment of the present invention;
4 is a diagram provided for explanation of a micro-lens array-based hologram printing system according to a fourth embodiment of the present invention, and
FIG. 5 is a diagram illustrating a hologram pattern displayed by the spatial light modulator shown in FIGS. 1 to 4 .

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

This micro-lens array 130-based hologram printing system (hereinafter collectively referred to as a 'hologram printing system') generates a hologram pattern composed of a plurality of unit holograms, reducing the recording time to the existing hologram printing time by using a micro lens array. It is provided to reduce by a factor of the total number of , and to provide a hologram reconstruction image with a greatly expanded viewing angle.

1 is a diagram provided for explanation of a hologram printing system according to a first embodiment of the present invention.

Referring to FIG. 1 , the hologram printing system according to the first embodiment may include a beam splitter 110, a reflective spatial light modulator 120, a micro lens array 130, and a relay optic 140. .

The reflective spatial light modulator 120 displays a hologram pattern composed of unit holograms, and when light (laser) separated by the beam splitter 110 is incident, it is reflected so that the hologram pattern is emitted.

The micro lens array 130 is provided at the rear end of the reflective spatial light modulator 120, the hologram pattern emitted by the reflective spatial light modulator 120 is incident, and the relay optic 140 is a myco lens array Provided at the rear end of 130, the hologram pattern passing through the micro lens array 130 may be incident.

Here, the reflective spatial light modulator 120 emits a hologram pattern composed of multiple unit holograms to record a plurality of element holograms on the hologram film 20 after displaying them, and the hologram passing through the micro lens array 130 The pattern may be recorded on the hologram film 20 by reducing the size of the plenoptic by the relay optic 140 .

At this time, the hologram film 20 is positioned on the moving stage 10, and a unit hologram (hogel or element hologram) having a small size can be recorded.

In addition, the actual size of individual holograms recorded on the hologram film 20 may be formed to be the same as the size of individual lenses in the microlens array 130 .

And the distance between the micro lens array 130 and the relay optic 140 should be twice the focal length of the element lens in the micro lens array 130, and the distance between the micro lens array 130 and the relay optic 140 is The hologram pattern is corrected when the focal length of the lens is not doubled.

Through this, since the size of the recorded unit hologram is reduced by several tens to hundreds of times compared to the size of the existing hologram, it is possible to reproduce hologram content with an improved viewing angle.

In addition, compared to the method of recording a single unit hologram in the spatial light modulator 120, which is a single object, one spatial light modulator 120 can simultaneously record as many holograms as the number of lenses in the micro lens array 130, The hologram writing speed can be greatly reduced.

2 is a diagram provided for explanation of a hologram printing system according to a second embodiment of the present invention.

Referring to FIG. 2 , the hologram printing system in the second embodiment includes a beam splitter 110, a reflective spatial light modulator 120, a micro lens array 130, and a relay optic 140 in the same manner as in the first embodiment. ), but the arrangement order of the micro lens array 130 and the relay optic 140 is changed, so that the laser separated by the beam splitter 110 displays a hologram pattern composed of unit holograms. A spatial light modulator ( After being incident on 120, it may be reflected and incident on the micro lens array 130 through the relay optic 140.

That is, the hologram pattern emitted by the reflective spatial light modulator 120 is incident on the relay optic 140 in the second embodiment, and the micro lens array 130 in the second embodiment is the relay optic 140 ), the hologram pattern passing through may be incident.

At this time, the hologram pattern passing through the micro lens array 130 may be recorded on the hologram film 20 .

In the second embodiment, since the hologram pattern passes through the relay optic 140 before the micro lens array 130, the individual hologram patterns in the spatial light modulator 120 are reduced in size by the relay optic 140. can

Therefore, when the hologram pattern passes through the relay optic 140 before the micro lens array 130 as in the second embodiment, the actual size of each hologram recorded on the hologram film 20 is Although it is formed to have the same size as the individual lenses, the physical size of the unit hologram displayed on the spatial light modulator 120 may be larger than the size of the microlenses by the reciprocal of the demagnification ratio.

Also, at this time, the distance between the micro lens array 130 and the hologram film 20 should be twice the focal length of the element lens in the micro lens array 130, and the distance between the micro lens array 130 and the hologram film 20 The hologram pattern is corrected when the distance is not twice the focal length of the micro lens.

3 is a diagram provided for explanation of a hologram printing system according to a third embodiment of the present invention.

Referring to FIG. 3 , the hologram printing system according to the third embodiment may include a transmissive spatial light modulator 120 , a micro lens array 130 and a relay optic 140 .

The transmissive spatial light modulator 120 displays a hologram pattern composed of unit holograms, and when light is incident, it is transmitted so that the hologram pattern is emitted.

The micro lens array 130 is provided at the rear end of the transmissive spatial light modulator 120, so that the hologram pattern emitted by the transmissive spatial light modulator 120 can be incident.

The relay optic 140 is provided at the rear end of the micro lens array 130 so that a hologram pattern passing through the micro lens array 130 can be incident.

Here, the actual size of the individual hologram is formed to be the same as the size of the individual lens in the microlens array 130, and at this time, the distance between the microlens array 130 and the relay optic 140 is within the microlens array 130 It should be twice the focal length of the element lens, and the hologram pattern is corrected for the case where the distance between the micro lens array 130 and the relay optic 140 is not twice the focal length of the micro lens.

4 is a diagram provided for explanation of a hologram printing system according to a fourth embodiment of the present invention.

Referring to FIG. 4, the hologram printing system in the fourth embodiment is composed of a transmission type spatial light modulator 120, a micro lens array 130, and a relay optic 140 as in the third embodiment, but the micro lens The arrangement order of the array 130 and the relay optics 140 is changed, and after being incident on the spatial light modulator 120 displaying a hologram pattern composed of unit holograms, it is transmitted and passes through the relay optics 140 to the micro lens array. (130).

That is, the hologram pattern emitted by the transmissive spatial light modulator 120 is incident on the relay optic 140 in the fourth embodiment, and the micro lens array 130 in the fourth embodiment is the relay optic 140 A hologram pattern passing through may be incident.

At this time, the hologram pattern passing through the micro lens array 130 may be recorded on the hologram film 20 .

And, in the fourth embodiment, since the hologram pattern passes through the relay optic 140 before the micro lens array 130, the individual hologram patterns in the spatial light modulator 120, as in the second embodiment, relay optic 140 ) can be reduced in size.

Therefore, when the hologram pattern passes through the relay optic 140 before the micro lens array 130 as in the fourth embodiment, the actual size of each hologram recorded on the hologram film 20 is Although it is formed to have the same size as the individual lenses, the physical size of the unit hologram displayed on the spatial light modulator 120 may be larger than the size of the microlenses by the reciprocal of the demagnification ratio.

Also, at this time, the distance between the micro lens array 130 and the hologram film 20 should be twice the focal length of the element lens in the micro lens array 130, and the distance between the micro lens array 130 and the hologram film 20 The hologram pattern is corrected when the distance is not twice the focal length of the micro lens.

FIG. 5 is a diagram illustrating a hologram pattern displayed by the spatial light modulator 120 shown in FIGS. 1 to 4 .

Referring to FIG. 5 , the hologram pattern displayed by the spatial light modulator 120 described above with reference to FIGS. 1 to 4 is composed of unit holograms.

Specifically, the number of unit holograms displayed in the spatial light modulator 120 is the same as the number of micro lens arrays 130 , and the resolution of the unit holograms may vary depending on the resolution of the spatial light modulator 120 .

The unit hologram displayed on the spatial light modulator 120 has the same resolution and physical size as the size of the micro lens, but the unit hologram is relayed like the second and fourth embodiments described above with reference to FIGS. 2 and 4 . If it passes through the optic 140 first, it may be formed as large as the reciprocal of the demagnification ratio.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is common in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those who have knowledge of, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

10 : Moving Stage
20: hologram film
21: unit hologram recorded on hologram film
110: beam splitter
120: Spatial Light Modulator (SLM)
130: microlens array
140: relay optic

Claims (10)

a beam splitter; and
A hologram pattern composed of unit holograms is displayed, and when the light separated by the beam splitter is incident, it is reflected to emit a hologram pattern (SLM: Spatial Light Modulator); includes,
a microlens array into which the hologram pattern emitted by the reflective spatial light modulator is incident; and
It further includes; a relay optic into which the hologram pattern passing through the micro lens array is incident;
The hologram pattern passing through the micro lens array,
The size of the plenoptic is reduced by the relay optic and recorded on the hologram film,
The actual size of individual holograms is
It is formed to have the same size as the individual lenses in the microlens array,
The distance between the micro lens array and the relay optic is
To make it twice the focal length of the element lens in the micro lens array, but if the distance between the micro lens array and the relay optic is not twice the focal length of the element lens in the micro lens array, the correction for the hologram pattern is performed Characteristic hologram printing system.
delete delete a beam splitter; and
A hologram pattern composed of unit holograms is displayed, and when the light separated by the beam splitter is incident, it is reflected to emit a hologram pattern (SLM: Spatial Light Modulator); includes,
a relay optic into which the hologram pattern emitted by the reflective spatial light modulator is incident; and
It further includes; a microlens array into which the hologram pattern passing through the relay optic is incident;
The hologram pattern passing through the micro lens array,
recorded on a holographic film,
The individual hologram patterns in the spatial light modulator,
The size is reduced by relay optics,
The distance between the micro lens array and the hologram film,
It is made to be twice the focal length of the element lens in the micro lens array, but when the distance between the micro lens array and the hologram film is not twice the focal length of the element lens in the micro lens array, the hologram pattern is corrected,
The physical size of the unit hologram displayed on the spatial light modulator is
When the hologram pattern passes through the relay optic before the micro lens array, the hologram printing system is formed larger than the size of the micro lens by the reciprocal of a demagnification rate.
delete delete a transmissive spatial light modulator (SLM) that displays a hologram pattern composed of unit holograms, and when light is incident, transmits and emits a hologram pattern;
a microlens array into which the hologram pattern emitted by the transmissive spatial light modulator is incident; and
A relay optic into which the hologram pattern passing through the micro lens array is incident,
The actual size of individual holograms is
It is formed to have the same size as the individual lenses in the microlens array,
The distance between the micro lens array and the relay optic is
To make it twice the focal length of the element lens in the micro lens array, but if the distance between the micro lens array and the relay optic is not twice the focal length of the element lens in the micro lens array, the correction for the hologram pattern is performed Characteristic hologram printing system.
delete a transmissive spatial light modulator (SLM) that displays a hologram pattern composed of unit holograms, and when light is incident, transmits and emits a hologram pattern;
a relay optic into which the hologram pattern emitted by the transmissive spatial light modulator is incident; and
Including; a microlens array into which the hologram pattern passing through the relay optic is incident;
The distance between the micro lens array and the hologram film,
It is made to be twice the focal length of the element lens in the micro lens array, but when the distance between the micro lens array and the hologram film is not twice the focal length of the element lens in the micro lens array, the hologram pattern is corrected,
The physical size of the unit hologram displayed on the spatial light modulator is
When the hologram pattern passes through the relay optic before the micro lens array, the hologram printing system is formed larger than the size of the micro lens by the reciprocal of a demagnification rate. delete

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