KR20140076881A - Hologram image display device - Google Patents

Abstract

The present invention relates to a hologram image display device realized by using a head mounted display. The hologram image display device according to an embodiment of the present invention includes: a light source for irradiating a first diffusion light; a collimator for converting the first diffusion light into a parallel light; a spatial optical modulator for realizing a hologram interference pattern and outputting a first diffraction parallel light by diffracting the first parallel light; a first optical conversion film for converting the path of the first parallel light output from the collimator so that the first parallel light is incident perpendicularly to a spatial light modulator; and a quarter wave plate interposed between the spatial light modulator and the first optical conversion film. A lower substrate of the spatial light modulator includes a reflective pattern to reflect the first parallel light incident into the spatial light modulator.

Description

[0001] HOLOGRAM IMAGE DISPLAY DEVICE [0002]

The present invention relates to a hologram image display device implemented with a head mounted display.

Recently, three dimensional (3D) image and image reproduction techniques have been actively studied. 3D image related media is expected to lead the next generation imaging device as a realistic image media with a new concept that raises the level of visual information one more level. The conventional 2D image system provides the plane image, but the 3D image system is the ultimate image realization technology in terms of showing the actual image information of the object to the observer.

Methods for reproducing three-dimensional stereoscopic images are largely researched and developed such as stereoscopy, holography, and integral imaging. Among them, the holographic method can reproduce a three-dimensional image of a holography produced by using a laser to realize stereoscopic images without glasses.

The holographic method uses the principle of recording and reproducing an interference signal obtained by superimposing light (object wave) reflected from an object and light (reference wave) having coherence. A hologram is a technique in which an interference fringe formed by causing an object wave scattered by an object to collide with a reference wave incident from another direction using a highly coherent laser beam is recorded on a photographic film. When an object wave and a reference wave meet, an interference fringe due to interference is formed. The amplitude and phase information of the object are also recorded in this fringe pattern. The interference fringe includes the intensity and phase information of the wave of light. The intensity information is recorded in a contrast between the patterns of the interference fringes, the phase information is recorded in the distance between the patterns in the interference fringes, the reference pattern is recorded on the recorded interference fringes, Reconstruction into an image is called holography.

Recently, with the development of the technology, a holographic head mounted display is being developed. The head-mounted display is a virtual screen monitor device that is worn in the form of a pair of glasses or a helmet to form a focus near the wearer's eyes. In recent years, a light and thin head-mounted display is required in order to enhance the usability of the user.

The holographic type head-mounted display includes a spatial light modulator (SLM) for displaying hologram interference fringe images, and implements a hologram stereoscopic image by irradiating a surface light source having linearly polarized light to the SLM. The SLM is generally implemented as a liquid crystal display panel. However, the holographic type head-mounted display has a problem in that it is difficult to reduce the thickness because the size of the beam splitter and the magnifying lens for irradiating the surface light source to the SLM and irradiating the hologram stereoscopic image implemented by the SLM to the magnifying lens is large.

The present invention provides a hologram image display device capable of implementing a thinned head mounted display.

A hologram image display apparatus according to an embodiment of the present invention includes a light source for emitting a first diffusion light; A collimator for converting the first diffused light into a first parallel light; A spatial light modulator that implements a hologram interference fringe pattern and diffracts the first parallel light to output a first diffracted parallel light; A first light conversion film for converting the path of the first parallel light output from the collimator so that the first parallel light is incident on the spatial light modulator vertically; And a quarter wave plate positioned between the spatial light modulator and the first light conversion film, wherein the lower substrate of the spatial light modulator includes a reflection pattern for reflecting the first parallel light incident on the spatial light modulator .

According to another aspect of the present invention, there is provided a hologram image display comprising: a light source for emitting a first diffused light; A collimator for converting the first diffused light into a first parallel light; And a spatial light modulator that implements a hologram interference fringe pattern and diffracts the first parallel light to output a first diffracted parallel light, wherein the first parallel light is incident on the spatial light modulator at a predetermined angle And the lower substrate of the spatial light modulator includes a reflection pattern for reflecting the first parallel light incident on the spatial light modulator.

The present invention implements a beam splitter and a magnifying lens using photo-conversion films. As a result, the present invention can provide a hologram image display device capable of implementing a thinned head-mounted display.

In addition, the present invention can remove the 0th order diffracted light of the hologram stereoscopic image by using the diffraction light blocking layer. As a result, the present invention can improve the quality of the hologram stereoscopic image.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary view showing a hologram image display apparatus according to a first embodiment of the present invention. FIG.
FIG. 2 is a flowchart illustrating a light conversion process of the hologram image display device according to the first embodiment of the present invention. FIG.
3 is an exemplary view showing in detail the method of manufacturing the first photo-conversion film of FIG.
4 is an exemplary view showing in detail a method of manufacturing the second photo-conversion film of FIG. 1;
FIG. 5 is an exemplary view showing in detail a method of manufacturing the third photo-conversion film of FIG. 1; FIG.
FIG. 6 is an exemplary view showing in detail a method of manufacturing the fourth light conversion film of FIG. 1; FIG.
7 is an exemplary view illustrating a hologram image display apparatus according to a second embodiment of the present invention.
8 is a flowchart illustrating a light conversion process of the hologram image display device according to the second embodiment of the present invention.
9 is an exemplary view showing in detail a method for manufacturing the fifth light conversion film of Fig. 7;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Like reference numerals throughout the specification denote substantially identical components. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The present invention embodies a hologram interference fringe pattern in a spatial light modulator (hereinafter referred to as "SLM") and irradiates light (laser light or the like) to a hologram interference fringe pattern to display a hologram image ≪ / RTI > In the embodiment of the present invention, the SLM has been mainly described as a reflection type liquid crystal display device. In addition, the hologram image display apparatus according to the embodiment of the present invention has been described in the context of a head mounted display. However, the present invention is not limited thereto.

1 is a view illustrating an example of a hologram image display apparatus according to a first embodiment of the present invention. 1, a hologram image display apparatus according to a first embodiment of the present invention includes a light source 10, a collimator 20, a first light conversion film 30, a SLM 40, (50), a diffraction light blocking lens (60), a field lens (70), a mirror (80), and the like.

The light sources 10 may be implemented as red, green, and blue LEDs (light emitting diodes), including a red laser diode, a green laser diode, and a blue laser diode. Also, the light sources 10 may be a combination of red, green, and blue light sources, a combination of light sources of other colors, or a single color light source such as a white laser diode or a white LED. The light sources 10 can output diffused light. Hereinafter, for convenience of description, it should be noted that the diffused light output from the light sources 10 is described as the first diffused light DL1.

The collimator 20 may be disposed on the light sources 10 to convert the first diffused light DL1 output from the light sources 10 into collimated beams. Collimate light is actually parallel light with very little dispersion or concentration. Hereinafter, for convenience of description, it should be noted that the collimated light output from the collimator 20 is described as the first parallel light PL1. Meanwhile, the collimator 20 of the first embodiment of the present invention may be implemented as the fifth light conversion film 90 as shown in FIG. In this case, the hologram image display device can be further thinned.

The first light conversion film (30) converts the path of the first parallel light (PL1) output from the collimator (20). Further, the first light conversion film 30 outputs the first diffracted parallel light DP1 outputted from the SLM 40 without converting it. In particular, the first light conversion film 30 converts the path of the first parallel light PL1 so that the first parallel light PL1 is incident on the SLM 40 vertically. In FIG. 1, it is illustrated that the first light conversion film 30 vertically converts the path of the first parallel light PL1, but it should be noted that the present invention is not limited thereto. The first light conversion film 30 may be implemented to change the path of only the first linearly polarized light (⊙). In FIG. 1, the first linearly polarized light (⊙) is exemplified as a vertical polarized light (⊙) oscillating in the vertical direction (z-axis direction). In this case, the first parallel light PL1 may be implemented to have the polarization component of the first linearly polarized light (⊙), and the first diffraction parallel light DP1 may be implemented to have the polarization component of the second linearly polarized light (↕). In FIG. 1, the second linearly polarized light () is illustrated as a horizontal polarized light () that vibrates in the horizontal direction (x-axis direction). A detailed description of the optical path conversion of the first photoconversion film 30 will be given later with reference to FIGS. 2 and 3. FIG.

A quarter wave plate 50 is disposed between the first light conversion film 30 and the SLM 40. The quarter wave plate 50 delays the phase of incident light by? / 4.

The SLM 40 includes a lower substrate 41, an upper substrate 42 and a liquid crystal layer 43 formed between the lower substrate 41 and the upper substrate 42. The SLM 40 reflects incident light on the lower substrate 41 A reflection type liquid crystal display panel in which a reflection pattern is formed. In the lower substrate 41 of the SLM 40, pixels are arranged in a matrix form by the intersection structure of the data lines and the gate lines. Each of the pixels of the SLM 40 is connected to a thin film transistor and supplies a data voltage supplied from the data line through the thin film transistor to the lower electrode of the lower substrate 41. Each of the pixels of the SLM 40 can change the arrangement of the liquid crystal molecules of the liquid crystal layer 43 by the voltage difference between the lower electrode and the upper electrode of the upper substrate 42 to realize the hologram interference fringe pattern. When the first parallel light PL1 is irradiated onto the hologram interference fringe pattern implemented in the SLM 40, the hologram stereoscopic image is realized by the diffraction of the first parallel light PL1 due to the interference fringe. Hereinafter, for convenience of description, it should be noted that the light diffracted by the SLM 40 and embodying the hologram stereoscopic image is described as the first diffractive parallel light DP1.

On the other hand, the lower electrode of the SLM 40 may be embodied as a reflective electrode for reflecting incident light to replace the reflective pattern. In this case, a reflection pattern may not be formed on the lower substrate 41. The SLM 40 may be implemented with LCOS (liquid crystal on silicon). Particularly, in the first embodiment of the present invention, since the first parallel light PL1 is vertically incident on the SLM 40, the SLM 40 is arranged such that the first parallel light PL1 is incident on the SLM 40, And outputs the light DP1.

The SLM driver (not shown) for driving the SLM 40 includes a data driving circuit and a gate driving circuit. The data driving circuit converts the hologram interference fringe data input from the control unit into an analog positive / negative gamma compensation voltage to generate data voltages and supplies the data voltages to the data lines. The gate drive circuit sequentially supplies gate pulses to the gate lines so as to be synchronized with data voltages supplied to the data lines under the control of the control unit.

The diffraction light blocking lens 60 blocks the 0th order diffracted light of the first diffracted parallel light DP1 outputted from the SLM 40. [ When 0th-order diffracted light is present, the stereoscopic effect of the hologram stereoscopic image is deteriorated, so that the diffracted light blocking lens 60 serves to shield the 0th diffracted light. The diffraction light blocking lens 60 includes a second light conversion film 61, a third light conversion film 62, and a blocking layer 63. The second light conversion film 61 converges the first diffracted parallel light DP1 to the first focus f1 and the third light conversion film 62 converges the light diffused from the first focus f1 to the second focus f1, And converted into diffracted parallel light DP2. That is, the second diffracted parallel light DP2 can be defined as the light from which the 0th diffracted light of the first diffracted parallel light DP1 is removed. A detailed description of the second and third photo-conversion films 61 and 62 will be given later with reference to FIGS. 4 and 5. FIG. A blocking layer 63 for shielding 0th-order diffracted light may be located at the focus f.

On the other hand, the diffraction light blocking lens 60 may be embodied as a magnifying lens. In this case, the first focal distance fd1, which is the distance from the second light conversion film 61 to the first focus f1, is the distance from the third light conversion film 62 to the first focus f1, The focal length fd2 may be shorter than the focal length fd2. As a result, the first diffracted parallel light DP1 can be magnified at a predetermined magnification and output as the second diffracted parallel light DP2.

The field lens 70 can converge the second diffracted parallel light beam DP2 to the second focal point f2. The user's eyes can be located at the second focus f2. The field lens 70 may be embodied as a fourth light conversion film 71 functioning similarly to a convex lens. That is, the field lens 70 plays a role similar to a convex lens that enlarges and displays a hologram stereoscopic image. A detailed description of the fourth photoconversion film will be given later with reference to FIG.

The mirror 80 serves to reflect the light output from the field lens 70. The position where the hologram stereoscopic image is visible can be changed by the mirror 80. 1, the mirror 80 reflects the light output from the field lens 70 vertically. However, the present invention is not limited to this.

2 is a flowchart illustrating a light conversion process of the hologram image display device according to the first embodiment of the present invention. Hereinafter, the optical conversion process of the hologram image display device will be described in detail with reference to FIGS. 1 and 2. FIG. Since the light conversion process of the hologram image display device according to the first embodiment of the present invention utilizes the polarization characteristics of light, it will be mainly described.

First, the first diffused light DL1 output from the light sources 10 is mainly described as having a polarization component of the first linearly polarized light (⊙). In FIG. 1, the first linearly polarized light (⊙) is exemplified as a vertical polarized light (⊙) oscillating in the vertical direction (z-axis direction). The first diffused light DL1 is output by the collimator 20 as the first parallel light PL1. The first parallel light PL1 has a polarization component of the first linearly polarized light (⊙). (S101)

Second, the first parallel light PL1 is converted by the first light conversion film 30 so as to be incident on the SLM 40 vertically. The first light conversion film 30 may be implemented to change the path of only the first linearly polarized light (⊙). Since the first parallel light PL1 has the polarization component of the first linearly polarized light ⊙, the first parallel light PL1 whose path is changed by the first light conversion film 30 is changed in path, (50). (S102)

Third, since the first parallel light PL1 is delayed by? / 4 by the quarter wave plate 50, the polarization component of the first parallel light PL1 is converted into the first circularly polarized light. In FIG. 1, the first circularly polarized light is exemplified as the right circularly polarized light. The first parallel light PL1 having the polarization component of the first circularly polarized light is incident on the SLM 40. [ (S103)

Fourth, the first parallel light PL1 is vertically incident on the SLM 40, diffracted by the hologram interference fringe pattern implemented in the liquid crystal layer 43, and output as the first diffracted parallel light DP1. Particularly, since the first parallel light PL1 is reflected by the reflection pattern formed on the lower substrate 41 of the SLM 40, the first parallel light PL1 is reflected from the upper substrate 42 of the SLM 40 Diffracted by the hologram interference fringe pattern embodied in the liquid crystal layer 43 up to the substrate 41 and further diffracted by the hologram interference fringe pattern from the lower substrate 41 of the SLM 40 to the upper substrate 42 , And is output as the first diffracted parallel light DP1. Particularly, since the first parallel light PL1 is vertically incident on the SLM 40 and is reflected by the reflection pattern, the incident path of the first parallel light PL1 is the same as the output path of the first parallel light DP1 . In addition, the SLM 40 may embody a hologram interference fringe pattern in the liquid crystal layer 43 in consideration of the fact that the first parallel light PL1 is diffracted twice. In other words, the hologram interference fringe pattern must be realized in consideration of the fact that the first parallel light PL1 moves twice as much as the thickness T of the liquid crystal layer 43. [ The first diffracted parallel light DP1 having the polarization component of the first circularly polarized light is incident on the quarter wave plate 50. (S104)

Fifthly, since the phase of the first diffracted parallel light DP1 is delayed by? / 4 by the quarter wave plate 50, the polarization component of the first diffracted parallel light DP1 is converted into the second linear polarized light do. In FIG. 1, the second linearly polarized light () is illustrated as a horizontal polarized light () that vibrates in the horizontal direction (x-axis direction). (S105)

Sixth, the first diffraction parallel light DP1 outputted from the quarter wave plate 50 is not changed in path by the first light conversion film 30. [ That is, since the first photoconversion film 30 is configured to change the path of only the first linearly polarized light (⊙), the first diffracted parallel light DP1 having the polarization component of the second linearly polarized light (↕) And passes through the film 30 as it is. (S106)

Seventh, the 0th-order diffracted light of the first diffracted parallel light DP1 is blocked by the diffracted light blocking lens 60. [ Specifically, the first diffracted parallel light DP1 converges to the first focal point f1 by the second light conversion film 61, so that the first diffracted light DP1 is converged by the blocking layer 63 located at the first focus f1, Order diffracted light of the parallel light DP1 is cut off. The light diffused from the first focus f1 is the light from which the 0th order diffracted light is removed. The light diffused from the first focus f1 is converted into the second diffracted parallel light DP2 by the third light conversion film 62. [ That is, the second diffracted parallel light DP2 can be defined as the light from which the 0th diffracted light of the first diffracted parallel light DP1 is removed.

Since the first focal length f1 is shorter than the second focal length f2, the first diffracted parallel light DP1 is magnified at a predetermined magnification by the diffracted light blocking lens 60, (DP2). (S107)

Eighth, the second diffracted parallel light DP2 is converged by the field lens 70 to the second focus f2. The user's eyes can be located at the second focus f2. (S108)

Ninth, the light output from the field lens 70 is reflected by the mirror 80. The position where the hologram stereoscopic image is visible can be changed by the mirror 80. When the user's eyes are located at the first position P1, the mirror 80 can be omitted. (S109)

As described above, according to the present invention, a planar light source is irradiated to a SLM using a photo-conversion film, and a hologram stereoscopic image implemented from the SLM is irradiated to the diffraction light blocking layer, And the diffraction light blocking layer may be implemented as an enlarged lens. As a result, the present invention can provide a hologram image display device capable of implementing a thinned head-mounted display. In addition, the present invention can remove the 0th order diffracted light of the hologram stereoscopic image by using the diffraction light blocking layer. As a result, the present invention can improve the quality of the hologram stereoscopic image.

FIG. 3 is an exemplary view showing a method of manufacturing the first photo-conversion film of FIG. 1 in detail. Referring to FIG. 3, the first photo-conversion film 30 includes a first transparent substrate T 1 and a first recording medium R 1 formed on the first transparent substrate T 1. The first light conversion film 30 can convert the path of incident light by forming an optical path pattern in the first recording medium Rl. The first recording medium R1 may be embodied as a photopolymer.

The second parallel light PL2 is incident on the first recording medium R1 of the first light conversion film 30 at a predetermined first angle? 1 and the third parallel light PL3 is incident on the first recording medium R1 at a predetermined second angle? (? 2). The first angle? 1, which is the incident angle of the second parallel light PL2, is an angle measured with reference to the vertical normal P. The second angle? 2, which is the incident angle of the third parallel light PL3, is an angle measured based on the vertical normal P. The first angle? 1 and the second angle? 2 may be implemented in the same manner. For example, the first angle [theta] 1 and the second angle [theta] 2 may be implemented at 45 [deg.].

As a result, the second parallel light PL2 incident at the first angle? 1 and the third parallel light PL2 incident at the second angle? 2 are incident on the first recording medium R1 of the first light conversion film 30, PL3 are recorded. Therefore, when the second parallel light PL2 is incident on the first recording medium R1 by the interference pattern recorded in the first recording medium R1 of the first light conversion film 30, the third parallel light PL2 PL3.

On the other hand, the second parallel light PL2 and the third parallel light PL3 recorded in the first recording medium R1 of the first light conversion film 30 are implemented to have a polarization component of the first linearly polarized light (⊙) . In this case, since the first photo-conversion film 30 has the polarization characteristic, it has the polarization characteristic realized so as to convert the path of the first linearly polarized light (⊙).

4 is an exemplary view showing a method of manufacturing the second light conversion film of FIG. 1 in detail. Referring to FIG. 4, the second photo-conversion film 61 includes a second transparent substrate T2 and a second recording medium R2 formed on the second transparent substrate T2. The second light conversion film 61 can converge the parallel light to the first focus f1 by forming an optical path pattern in the second recording medium R2. The second recording medium R2 may be embodied as a photopolymer.

The fourth parallel light PL4 is vertically incident on the second recording medium R2 of the second light conversion film 61 and the light DP1 diffused from the first focus f1 is incident vertically. The interference pattern of the fourth parallel light PL4 and the light DP1 diffused from the first focus f1 is recorded in the second recording medium R2 of the second light conversion film 61. [ When the fourth parallel light PL4 is incident on the second recording medium R2 by the interference pattern recorded in the second recording medium R2 of the second light conversion film 61, Converging light CF1 is output.

On the other hand, the fourth parallel light PL4 recorded in the second recording medium R2 of the second light conversion film 61 and the light DP1 diffused from the first focus f1 are reflected by the second linearly polarized light And can be implemented to have a polarization component. In this case, the second light conversion film 61 outputs the light CF1 converging to the first focus f1 only when the fourth parallel light PL4 having the polarized light component of the second linearly polarized light is incident. Polarized light.

FIG. 5 is an exemplary view showing a method of manufacturing the third photo-conversion film of FIG. 1 in detail. Referring to FIG. 5, the third photo-conversion film 62 includes a third transparent substrate T3 and a third recording medium R3 formed on the third transparent substrate T3. The third light conversion film 62 can convert the light DP1 diffused from the first focus f1 into parallel light by forming an optical path pattern on the third recording medium R3. The third recording medium R3 may be embodied as a photopolymer.

The third photo-conversion film 62 is substantially the same as the method of manufacturing the second photo-conversion film 61 shown in Fig. The third photoconversion film 62 has a second focal length fd2 that is a distance from the third recording medium R3 to the first focal point f1 in the second recording medium 61 of the second photoconversion film 61, May be longer than the first focal length fd1, which is the distance from the first focus point R2 to the first focus point f1.

6 is an exemplary view showing in detail a method of manufacturing the fourth photoconversion film of FIG. Referring to FIG. 6, the fourth light conversion film 71 includes a fourth recording medium R4 formed on a fourth transparent substrate T4 and a fourth transparent substrate T4. The fourth light conversion film 71 can converge the parallel light to the second focus f2 by forming an optical path pattern in the fourth recording medium R4. The fourth recording medium R4 may be embodied as a photopolymer.

The fifth parallel light PL5 is vertically incident on the fourth recording medium R4 of the fourth light conversion film 71 and the light DF2 diffused from the second focus f2 is incident vertically. The interference pattern of the light DF2 diffused from the fifth parallel light PL5 and the second focus f2 is recorded in the fourth recording medium R4 of the fourth light conversion film 71. [ When the fifth parallel light PL5 is incident on the fourth recording medium R4 by the interference pattern recorded in the fourth recording medium R4 of the fourth light conversion film 71, Converging light CF2 is output.

On the other hand, the fifth parallel light PL5 recorded in the fourth recording medium R4 of the fourth light conversion film 71 and the light DF2 diffused from the second focal point f2 are reflected by the second linearly polarized light And can be implemented to have a polarization component. In this case, the fourth light conversion film 71 outputs the light CF2 that converges to the second focus f2 only when the fifth parallel light PL5 having the polarization component of the second linearly polarized light is incident. Polarized light.

7 is a view illustrating an example of a hologram image display apparatus according to a second embodiment of the present invention. 7, the hologram image display apparatus according to the second embodiment of the present invention includes a light source 10, a collimator, an SLM 40, a diffraction light blocking lens 60, a field lens 70, a mirror 80 , A fifth light conversion film 90, and the like.

The SLM 40, the diffraction light blocking lens 60, the field lens 70 and the mirror 80 of the hologram image display device according to the second embodiment of the present invention are the same as those of the first embodiment Is substantially the same as the bar. A detailed description of the light sources 10, the SLM 40, the diffraction light blocking lens 60, the field lens 70, and the mirror 80 of the hologram image display device according to the second embodiment of the present invention will be described in detail It will be omitted.

The collimator may be implemented as a fifth light conversion film 90 as shown in FIG. That is, the fifth light conversion film 90 converts the first diffusion light DL1 output from the light sources 10 into a collimated beam. Hereinafter, for convenience of description, it should be noted that the collimated light output from the fifth light conversion film 90 is referred to as a first parallel light PL1. A detailed description of the fifth light conversion film 90 will be given later with reference to Fig.

In particular, the first parallel light PL1 output from the fifth light conversion film 90 is incident on the SLM 40 at the third angle? 3. The third angle? 3 at which the first parallel light PL1 is incident is an angle measured with respect to the vertical normal line P as a reference. The third angle [theta] 3 may be an acute angle or an obtuse angle, not an angle of 90 [deg.]. For example, as shown in FIG. 7, the third angle? 3 may be 45 degrees. In this case, since the first parallel light PL1 is reflected by the reflection pattern formed on the lower substrate 41 of the SLM 40, the first parallel light PL1 is reflected from the upper substrate 42 of the SLM 40 Diffracted by the hologram interference fringe pattern embodied in the liquid crystal layer 43 up to the lower substrate 41 and further diffracted by the hologram interference fringe pattern from the lower substrate 41 of the SLM 40 to the upper substrate 42 And is output as the first diffracted parallel light DP1. Accordingly, the SLM 40 may implement the hologram interference fringe pattern in the liquid crystal layer 43 in consideration of the diffraction of the first parallel light PL1 twice. The first parallel light PL1 is moved longer than twice the thickness T of the liquid crystal layer 43 because the first parallel light PL1 is incident on the SLM 40 at the third angle? . That is, in the second embodiment of the present invention, the liquid crystal layer 43 of the SLM 40 must implement the hologram interference fringe pattern in consideration of the movement path of the first parallel light PL1.

8 is a flowchart illustrating a light conversion process of the hologram image display device according to the second embodiment of the present invention. Hereinafter, the optical conversion process of the hologram image display device will be described in detail with reference to FIGS. 7 and 8. FIG. In the light conversion process of the hologram image display device according to the second embodiment of the present invention, the description has been made mainly on the fact that the polarization component of the light is the first linearly polarized light (⊙). However, it should be noted that the present invention is not limited to this, and the polarized light component of the light can be realized by the second linearly polarized light ().

First, the first diffused light DL1 output from the light sources 10 is mainly described as having a polarization component of the first linearly polarized light (⊙). In FIG. 1, the first linearly polarized light (⊙) is exemplified as a vertical polarized light (⊙) oscillating in the vertical direction (z-axis direction). The first diffused light DL1 is output as the first parallel light PL1 by the fifth light conversion film 90. [ The first parallel light PL1 has a polarization component of the first linearly polarized light (⊙). (S201)

Second, the first parallel light PL1 is diffracted by the hologram interference fringe pattern embodied in the SLM 40 and output as the first diffracted parallel light DP1. Particularly, since the first parallel light PL1 is reflected by the reflection pattern formed on the lower substrate 41 of the SLM 40, the first parallel light PL1 is reflected from the upper substrate 42 of the SLM 40 Diffracted by the hologram interference fringe pattern embodied in the liquid crystal layer 43 up to the substrate 41 and further diffracted by the hologram interference fringe pattern from the lower substrate 41 of the SLM 40 to the upper substrate 42 , And is output as the first diffracted parallel light DP1. Accordingly, the SLM 40 may implement the hologram interference fringe pattern in the liquid crystal layer 43 in consideration of the diffraction of the first parallel light PL1 twice. The first parallel light PL1 is moved longer than twice the thickness T of the liquid crystal layer 43 because the first parallel light PL1 is incident on the SLM 40 at the third angle? . That is, in the second embodiment of the present invention, the liquid crystal layer 43 of the SLM 40 must implement the hologram interference fringe pattern in consideration of the movement path of the first parallel light PL1. The first diffracted parallel light beam DP1 is incident on the diffracted light blocking lens 60. (S202)

Third, the 0th-order diffracted light of the first diffracted parallel light DP1 is blocked by the diffracted light blocking lens 60. [ Specifically, since the first diffracted parallel light DP1 converges to the first focal point f1 by the second light conversion film 61, the zero-order diffracted light DP1 of the first diffracted parallel light DP1 is converged by the blocking layer 63, The diffracted light is blocked. Therefore, the first diffracted light DD1 which is the light diffused from the first focal point f1 is light in which the 0th-order diffracted light is almost eliminated. The first diffracted light DD1 is converted into the second diffracted parallel light DP2 by the third light conversion film 62. [ The first diffracted parallel light DP1 can be magnified at a predetermined magnification by the diffracted light blocking lens 60 and output as the second diffracted parallel light DP2. (S203)

Fourth, the second diffracted parallel light beam DP2 passes through the field lens 70,

Converges to the second focus f2. The user's eyes can be located at the second focus f2. (S204)

Fifth, the light output from the field lens 70 is reflected by the mirror 80. [ The position where the hologram stereoscopic image is visible can be changed by the mirror 80. Therefore, when the user's eyes are located at the first position P1, the mirror 80 can be omitted. (S205)

As described above, according to the present invention, a planar light source is irradiated to a SLM using a photo-conversion film, and a hologram stereoscopic image implemented from the SLM is irradiated to the diffraction light blocking layer, And the diffraction light blocking layer can be realized as an enlarged lens. As a result, the present invention can provide a hologram image display device capable of implementing a thinned head-mounted display. In addition, the present invention can remove the 0th order diffracted light of the hologram stereoscopic image by using the diffraction light blocking layer. As a result, the present invention can improve the quality of the hologram stereoscopic image.

FIG. 9 is an exemplary view showing a method of manufacturing the fifth light conversion film of FIG. 7 in detail. Referring to FIG. 9, the fifth light conversion film 90 includes a fifth recording medium R5 formed on a fifth transparent substrate T5 and a fifth transparent substrate T5. The fifth light conversion film 90 can convert the first diffused light DL1 into the first parallel light PL1 by forming an optical path pattern in the fifth recording medium R5. The fifth recording medium R5 may be embodied as a photopolymer.

The second diffused light DL2 diffused from the third focus f3 is vertically incident on the fifth recording medium R5 of the fifth light conversion film 90 and the sixth parallel light PL6 is incident vertically do. The interference pattern of the first diffused light DL1 and the sixth parallel light PL6 is recorded in the fifth recording medium R5 of the fifth light conversion film 90. [ When the first diffused light DL1 is incident on the fifth recording medium R5 by the interference pattern recorded in the fifth recording medium R5 of the fifth light conversion film 90, Is output.

On the other hand, the first diffused light DL1 and the sixth parallel light PL6 recorded in the fifth recording medium R5 of the fifth light conversion film 90 are implemented to have a polarization component of the first linearly polarized light (⊙) . In this case, the fifth light conversion film 90 has a polarization characteristic of outputting the sixth parallel light PL6 only when the first diffused light DL1 having the polarization component of the first linearly polarized light (⊙) is incident .

As described above, the present invention implements a beam splitter and a magnifying lens using photo-conversion films. As a result, the present invention can provide a hologram image display device capable of implementing a thinned head-mounted display. In addition, the present invention can remove the 0th order diffracted light of the hologram stereoscopic image by using the diffraction light blocking layer. As a result, the present invention can improve the quality of the hologram stereoscopic image.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

10: light source 20: collimator
30: first photo-conversion film 40: SLM
41: upper substrate 42: lower substrate
43: liquid crystal layer 50: quarter wave plate
60: diffraction light blocking lens 61: second light conversion film
62: third light conversion film 64: blocking layer
70: field lens 71: fourth light conversion film
80: mirror 90: fifth light conversion film

Claims (11)

A light source for irradiating the first diffused light;
A collimator for converting the first diffused light into a first parallel light;
A spatial light modulator that implements a hologram interference fringe pattern and diffracts the first parallel light to output a first diffracted parallel light;
A first light conversion film for converting the path of the first parallel light output from the collimator so that the first parallel light is incident on the spatial light modulator vertically; And
And a quarter wave plate positioned between the spatial light modulator and the first light conversion film,
Wherein the lower substrate of the spatial light modulator includes a reflection pattern for reflecting the first parallel light incident on the spatial light modulator. The method according to claim 1,
Wherein the first diffused light and the first parallel light output from the collimator have a polarization component of a first linearly polarized light,
The first parallel light having passed through the quarter wave plate and the first diffracted parallel light outputted from the spatial light modulator have a polarization component of the first circularly polarized light,
And the first diffraction parallel light having passed through the quarter wave plate has a polarization component of a second linearly polarized light. 3. The method of claim 2,
Wherein the first light conversion film converts the optical path only when the first linearly polarized light is incident. The method of claim 3,
And a diffraction light blocking lens for blocking the 0th order diffracted light of the first diffracted parallel light that has passed through the first light conversion film. A light source for irradiating the first diffused light;
A collimator for converting the first diffused light into a first parallel light; And
And a spatial light modulator that implements a hologram interference fringe pattern and diffracts the first parallel light to output a first diffracted parallel light,
Wherein the first parallel light is incident at a predetermined angle instead of an angle perpendicular to the spatial light modulator,
Wherein the lower substrate of the spatial light modulator includes a reflection pattern for reflecting the first parallel light incident on the spatial light modulator. 6. The method of claim 5,
And a diffraction light blocking lens for blocking the 0th order diffracted light of the first diffracted parallel light output from the spatial light modulator. 6. The method according to claim 1 or 5,
Wherein the first parallel light incident on the spatial light modulator comprises:
The hologram interference pattern is diffracted by the hologram interference fringe pattern embodied in the liquid crystal layer of the spatial light modulator from the upper substrate to the lower substrate of the spatial light modulator, Diffracted by the first diffracted light, and diffracted by the pattern one more time, thereby outputting as the first diffracted parallel light. The method according to claim 4 or 6,
The diffraction light blocking lens is a diffraction-
A second light conversion film for converging the first diffraction parallel light to a first focus;
A blocking layer for shielding 0th-order diffracted light of the first diffracted parallel light converged at the first focal point; And
And a third light conversion film for converting the light diffused from the first focal point into a second diffracted parallel light which is parallel light. 9. The method of claim 8,
Wherein a first focal distance, which is a distance from the second photo-conversion film to the first focal point, is shorter than a second focal distance that is a distance from the third photo-conversion film to the first focal point. The method according to claim 4 or 6,
And a field lens for converging the second diffracted parallel light output from the diffraction light blocking layer to a second focal point. 11. The method of claim 10,
And a mirror for reflecting the light converged at the second focus by the field lens.

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