KR20140092169A - System for displaying a hologram - Google Patents

Abstract

An embodiment of the present invention relates to a hologram display system using an interference pattern. The hologram display system includes a backlight providing panel which selectively transmits parallel light supplied from a backlight to each divided area; a first optical conversion plate which collects the parallel light supplied from the backlight to a focus point and convert the collected light to reference light in the first direction and reference light in the second direction; a second optical conversion plate which converts the reference light in the first direction supplied from the first optical conversion plate to parallel light in the first direction and converts the reference light in the second direction to parallel light in the second direction; and a display panel which forms a hologram in the first or second direction with the parallel light supplied from the second optical conversion plate.

Description

[0001] System for displaying a hologram [

The present invention relates to a display system that solves a viewing angle problem when viewing a hologram.

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.

As a method for reproducing three-dimensional stereoscopic images, stereoscopic stereoscopic and autostereoscopic methods are widely used. A binocular parallax system uses a parallax image of right and left eyes having a large stereoscopic effect, and a stereoscopic image display apparatus using a spectacles system for realizing a binocular parallax image using glasses has recently been commercialized. The polarizing spectacle method, which realizes a stereoscopic image by using polarization glasses, displays the right and left parallax images in a time-division manner, and displays stereoscopic images by using shutter glasses. It is divided into the shutter glasses method to be implemented. However, the glasses system has a disadvantage that viewers can watch the stereoscopic images only when wearing glasses. To solve this problem, a non-eyeglass system capable of viewing stereoscopic images without wearing glasses has been developed. In particular, the volumetric display method, which is one of the non-glasses type, can provide continuous parallax and color information, thereby providing an advantage that an observer can move the viewpoint relatively freely.

The hologram system, which is a volume expression display system, uses a principle of recording and reproducing an interference signal obtained by superimposing light (object wave) reflected by an object and light (reference wave) having coherence. An interference fringe formed by causing an object wave scattered by colliding with an object using a highly coherent laser light to meet with a reference wave incident from another direction 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. By irradiating reference light to the interference fringes recorded in this manner, the interference information recorded in the hologram is restored, and the three-dimensional stereoscopic effect is felt. A series of processes for implementing a three-dimensional image using such a recording and restoration principle is called a hologram.

A computer generated hologram (CGH) has been developed as a method for computer generated holograms for storage, transmission and image processing. This computer-generated hologram has been developed in various ways so far. Recently, a system for displaying a computer-generated hologram of a moving image without developing a computer-generated hologram of a still image has been developed due to the development of the digital industry.

A computer generated hologram is an interference pattern that is stored directly in a hologram using a computer. The interference fringe image is generated by a computer and then transmitted to a spatial light modulator such as a liquid crystal-spatial light modulator (LC-SLM), and the reference light is irradiated to the SLM to restore / Playback. 1 is a block diagram of a digital hologram image reproducing apparatus embodying a computer generated hologram method according to the related art.

Referring to FIG. 1, an interference fringe image corresponding to a stereoscopic image to be implemented in the computer 100 is generated. The generated interference fringes are transmitted to the SLM 200. The SLM 200 may be formed of a transmissive liquid crystal display panel to display an interference pattern. A laser light source 300 to be used as a reference light is disposed on one side of the SLM 200. The expander 400 and the lens 500 are sequentially arranged in order to uniformly project the reference light 900 irradiated from the laser light source 300 to the front surface of the SLM 200. [ The reference light 900 emitted from the laser light source 300 is irradiated to one side of the SLM 200 through the expander 400 and the lens 500. Accordingly, the three-dimensional stereoscopic image 800 is displayed on the other side of the SLM 200 by the interference fringes of the hologram implemented in the SLM 200.

However, when the hologram is reproduced on an LCD basis, the pixel pitch of one pixel is too large, so that the diffraction angle becomes too small. Therefore, the viewing angle at which the hologram can be viewed is very small, and the viewer has a problem that the viewer can only watch the hologram in a very narrow range.

The present invention is designed to allow a viewer to view a hologram regardless of a viewing position regardless of a narrow viewing angle.

According to an embodiment of the present invention, there is provided a system for displaying a hologram using an interference fringe, comprising: a backlight supply panel for selectively transmitting parallel light supplied from a backlight in each divided region; A first light conversion plate for converting the reference light in the first direction supplied from the first light conversion plate into a parallel light in the first direction and a reference light in the second direction, A second light conversion plate for converting the reference light in the second direction into a parallel light in the second direction and a hologram formed in the first direction or the second direction with the parallel light supplied from the second light conversion plate A hologram display system including a display panel is disclosed.

The backlight supply panel has a structure in which a liquid crystal cell is sandwiched between two substrates, and transmits or blocks the parallel light by the alignment direction of the liquid crystal.

The first photo-conversion plate includes a first recording plate for recording an optical path pattern with the substrate, and the first recording plate is formed corresponding to the divided region, respectively.

The first recording plate includes a 1-1 recording plate for recording an optical path pattern of parallel light and reference light in the first direction and converting the parallel light into reference light in the first direction, And a first-second recording plate for recording an optical path pattern by two-direction reference light and converting the parallel light into reference light in the second direction.

The second photo-conversion plate includes a substrate and a second recording plate sequentially laminated on the substrate, each recording plate recording an optical path pattern.

A second recording plate for recording an optical path pattern of the parallel light and the reference light in the first direction and converting the reference light in the first direction into the parallel light; And a second -2 recording plate for recording an optical path pattern by the reference light in two directions and converting the reference light in the second direction into the parallel light.

In the hologram display system according to the embodiment of the present invention, the light supplied from the backlight to the first light conversion plate 30 is converted into the first through third reference lights and supplied to the second light conversion plate 40 The hologram is displayed on the second position P2 corresponding to the reference point, the first position P1 in the -θ direction, and the third position P3 in the + θ direction. have. Therefore, if the aperture region is formed of n, holograms can be formed at n positions, and the above-described problems can be solved.

1 is a block diagram of a digital hologram image reproducing apparatus embodying a computer generated hologram method according to the related art.
2 shows a schematic configuration of a hologram system according to an embodiment of the present invention.
3 is a view showing a configuration of a backlight supply panel.
4 is a schematic cross-sectional view taken along the line IV-IV in Fig.
Figs. 5 to 7 are views for explaining the formation of light path patterns on the first to third recording plates. Fig.
8 is a cross-sectional view showing a configuration of the second light conversion plate.
9 and 10 are views for explaining the operation of the hologram system according to an embodiment of the present invention.

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 component name used in the following description may be selected in consideration of easiness of specification, and may be different from the actual product name.

2 shows a schematic configuration of a hologram system according to an embodiment of the present invention. 2, the hologram system of this embodiment includes a backlight supply panel 10, a first driving unit 20, a first optical conversion plate 30, a second optical conversion plate 40, a display panel 50 A second driving unit 70, a control unit 80, and a sensing camera 90.

The backlight supply panel 10 selectively supplies the parallel light supplied from the backlight (not shown) to the first light conversion plate 30. In this embodiment, when the panel is divided into the first region, the second region and the third region in the y-axis direction of the drawing, the backlight supply panel 10 passes the parallel light supplied from the backlight only in one region And the transmission of light is blocked in the remaining area. In one example, the backlight supply panel 10 allows light to pass through only the first area and blocks light in the remaining second area and the third area.

In one embodiment, the backlight supply panel 10 may be structured such that a liquid crystal cell is sandwiched between two substrates as illustrated in FIG.

The first substrate 31 is composed of a plastic substrate or a glass substrate. A first electrode 33 is formed on the first substrate 31. The first electrode 33 may be formed on the first substrate 31 through a transparent conductive material, for example, a transparent conductive oxide such as ITO or IZO through a photolithography process. The first electrode 113 extends in one direction and is spaced apart from a neighboring one by a predetermined distance, and is arranged in parallel with each other to form a stripe arrangement. The first electrode 33 is covered with a transparent protective layer 35 and protected. The transparent protective layer 35 is made of an inorganic material such as silicon oxide (SiOx) or silicon nitride (SiNx).

The second substrate 32 is composed of a glass substrate or a plastic substrate as in the case of the first substrate 31.

A second electrode 34 is formed on the second substrate 32. Unlike the first electrode 33, the second electrode 34 is formed on the second substrate 32 in common. The second electrode 34 may be formed of a transparent conductive oxide such as ITO or IZO to allow light to pass therethrough. This second electrode 34 is covered and protected by a transparent protective layer 36. The transparent protective layer 36 is made of an inorganic material such as silicon oxide (SiOx) or silicon nitride (SiNx).

The liquid crystal cell LC sandwiched between the first substrate 31 and the second substrate 32 may be initially oriented in a TN mode, an IPS mode, an ECB mode, or the like.

A first polarizer PL1 and a second polarizer PL2 having optical axes orthogonal to each other are attached to the first substrate 31 and the second substrate 32, respectively. For example, the first polarizing plate PL1 attached on the first substrate 31 transmits only linearly polarized light in the horizontal direction, and the second polarizing plate PL2 attached on the second substrate 32 transmits the linearly polarized light, . Accordingly, the light supplied to the backlight supply panel 10 is selectively transmitted due to the polarization direction of the polarizers PL1 and PL2. As a result, by adjusting the arrangement direction of the liquid crystal cells arranged in the first to third regions, light is selectively transmitted through the first to third regions or selectively blocked.

The first light conversion plate 30 refracts or transmits the light supplied from the backlight supply panel 10 as it is, and supplies the light to the second light conversion plate 40.

4 is a cross-sectional view taken along the line IV-IV in Fig. 2, and shows a simplified cross-sectional structure of the backlight supply panel 10 and the first photoelectric conversion plate 30. Fig.

In FIG. 4, when the panel is divided into the first region, the second region and the third region in the y-axis direction of the drawing as described above, the backlight supply panel 10 supplies the parallel light supplied from the backlight to the liquid crystal cell The arrangement direction is adjusted to pass only in one area and the light is blocked in the remaining area. In FIG. 4, the first area A1 and the third area A3 are blocked, and light is transmitted through the second area A2. Hereinafter, a state in which the liquid crystal is arrayed such that light can be transmitted as in the second area A2 of the backlight supply panel 10 is referred to as an aperture area.

The first photoconversion plate 30 includes a transparent substrate 301 and a recording plate 302 formed of a photopolymerizable material. The recording plate 302 records an optical path pattern and converts the path of the incident light to transmit the light.

In this embodiment, the recording plate 302 includes a first recording plate LT1, a second recording plate LT2, and a third recording plate LT3. The first recording plate LT1 is formed at a position corresponding to the first area A1 of the backlight supply panel 10 and the second recording plate LT2 is formed at a position corresponding to the second area A2, The third recording plate LT3 is formed at a position corresponding to the third area A3.

Accordingly, the light supplied through the first area A1 is refracted according to the light path pattern recorded on the first recording plate LT1, and the light supplied through the second area A2 is reflected by the second recording plate LT2, and the light supplied through the third area A3 is refracted according to the light path pattern recorded on the third recording plate LT3.

Hereinafter, with reference to Figs. 5 to 7, the formation of the optical path pattern on the first to third recording plates will be described.

First, FIG. 5 exemplarily illustrates the manner in which the light path pattern is recorded on the second recording plate LT2.

In Fig. 5, the first parallel light AS1 is incident parallel to the second recording plate LT2. At the same time, the first reference beam AT1 is incident parallel to the second recording plate LT2. The first reference beam AT1 forms a focus f at a position separated by the first distance d1 It can be realized as light converging and diffusing using the first convex lens CR1. That is, the first reference beam AT1 may be implemented as light converging while passing through the focus f and diffusing through the focus f.

When the first parallel light AS1 and the first reference light AT1 are simultaneously incident on the second recording plate LT2 as described above, the light path pattern of the first parallel light AS1 and the first reference light AT1 And is recorded in the second recording plate LT2. Accordingly, when the parallel light is incident on the second recording plate LT2, the light converges to the focus f which is separated by the second distance d2, and is converted into the first reference light to be diffused thereafter and outputted.

Accordingly, when the second region A2 of the backlight supply panel 10 is implemented as an opening region, the parallel light supplied from the backlight (not shown) is supplied to the first light conversion plate 30 through the opening region Since the second recording plate LT2 is formed corresponding to the second area A2, the parallel light is converted into the first reference light AT1 while being transmitted through the second recording plate LT2 and output. Therefore, even if the backlight is supplied only to a partial area of the backlight supply panel 10, the light is converted into light converging and diffusing while transmitting through the first light conversion 30, .

FIG. 6 exemplarily illustrates the manner in which the light path pattern is recorded on the third recording plate LT3.

In Fig. 6, the second parallel light AS2 is incident in a state parallel to the third recording plate LT3. At the same time, the second reference beam AT2 is incident on the third recording plate LT3 inclined by +?. The second reference beam AT2 is incident on the third recording layer LT3 at a position And can be realized as light converging and diffusing using a biconvex lens CR2. The second convex lens CR2 is inclined by +? So that the second reference beam can be incident on the third recording plate LT3 while being inclined by +?. The second reference beam AT2 transmitted through the second convex lens CR2 is supplied to the third recording plate LT3 while being inclined by +? And converges to the focus f and diffuses beyond the focus f .

When the second parallel light AS2 and the second reference light AT2 are incident on the first recording plate LT1 at the same time, the optical path pattern of the second parallel light AS2 and the second reference light AT2, 3 recording plate LT3. Accordingly, when parallel light is incident on the third recording plate LT3, the light is converted into the second reference light AT2 in the +? Direction and output.

Accordingly, when the first area A1 of the backlight supply panel 10 is implemented as an opening area, the parallel light supplied from the backlight (not shown) is supplied to the first light conversion plate 30 through the opening area Since the third recording plate LT3 is formed corresponding to the first area A2, the parallel light is converted into the second reference light AT2 in the + θ direction while being transmitted through the third recording plate LT3, do.

FIG. 7 exemplarily illustrates the manner in which the light path pattern is recorded on the first recording plate LT1.

In Fig. 7, the third parallel light AS3 is incident parallel to the first recording plate LT1. At the same time, the third reference beam AT3 is incident on the first recording plate LT1 in a state inclined by -?. The third reference beam AT3 is focused at a position distant by a third distance And can be realized as light converging and diffusing using the third convex lens CR3. The second convex lens CR3 is inclined by -θ so that the third reference beam can be incident on the first recording plate LT1 in a tilted state by -θ. The third reference light AT3 transmitted through the third convex lens CR3 is supplied to the first recording plate LT1 while being inclined by -θ and converges to the focus f and diffuses beyond the focus f .

When the third parallel light AS3 and the third reference light AT3 are simultaneously incident on the first recording plate LT1 as described above, the light path pattern of the third parallel light AS3 and the third reference light AT3 And is recorded in the first recording plate LT1. Accordingly, when parallel light is incident on the first recording plate LT1, the light is converted into third reference light AT3 in the -θ direction and output

Accordingly, when the third region A3 of the backlight supply panel 10 is realized as the opening region, the parallel light supplied from the backlight (not shown) is supplied to the first light conversion plate 30 through the opening region Since the first recording plate LT1 is formed corresponding to the third area A3, the parallel light is converted into the third reference light AT3 in the -θ direction while being transmitted through the first recording plate LT1, do.

2, the second light conversion plate 40 is disposed at a predetermined distance from the first light conversion plate 30. The second light conversion plate 40 selectively converts the first to third reference light supplied from the first light conversion plate to supply the light to the display panel 50 as parallel light as illustrated in FIG.

The second optical conversion plate 40 has a structure in which the fourth to sixth recording plates 402, 403 and 404 are sequentially stacked on the substrate 401. The fourth recording plate 402 converts the third reference light AT3 in the -θ direction into the parallel light to the optical path by the first recording plate LT1 described above and the fifth recording plate 403 The first reference beam AT1 which is converged and diffused while maintaining the optical path by the above-mentioned second recording plate is converted into the optical beam by the parallel light, and the sixth recording plate 404 is rotated by the third recording plate LT3 And converts the second reference beam (AT2) in the + θ direction into the optical path into parallel light.

Since the light is converted into a light in each of the recording plates (1) through (3), the detailed description thereof will be omitted.

Accordingly, all the light transmitted through the second optical conversion plate 40 is converted into parallel light and supplied to the display panel 50.

In this embodiment, the display panel 10 for displaying an interference pattern is constructed in the same manner as the above-described structure through Fig. That is, the display panel 10 is composed of a transmissive LCD. The display panel 10 receives and displays the interference fringe pattern, and thus the hologram can be displayed on the other side of the display panel 10 while the parallel light is transmitted through the display panel 10.

On the other hand, the display panel 50 displays the holograms at the first position P1, the second position P2, and the third position P3, respectively. Here, the second position P2 is a position corresponding to the front face of the substrate, and the hologram is displayed at the second position () by the first reference light. The first position P1 is a position refracted by -θ in the second position (), and the hologram is displayed by the third reference light in the -θ direction. The third position P3 is a position that is refracted by +? In the second position P2, and the hologram is displayed by the second reference light in the +? Direction.

Then, the first driving unit 20 supplies the driving voltage to the backlight supply panel 10 to operate the backlight supply panel 10. Here, the driving voltage adjusts the molecular arrangement of the liquid crystal molecules constituting the liquid crystal cell to form an opening region, so that light can be transmitted through the backlight supply panel 10 only through the opening region.

The second driver 50 includes a gate driver and a data driver. The data driver receives the hologram data DATA from the controller 80 and receives the hologram data DATA from the positive / negative polarity gamma compensation voltage supplied from a gamma voltage generator circuit (not shown) To an analog data voltage. The data driver supplies the positive / negative polarity analog data voltages to the data lines of the display panel 10. The gate driver sequentially supplies a gate pulse (or a scan pulse) synchronized with the data voltage to the gate lines of the display panel 10 under the control of the controller 80. [

The control unit 80 controls the first and second driving units 70 to drive the backlight supply panel and the display panel 10, respectively. The control unit 80 supplies the gate driver control signal GCS to the gate driver and the hologram data DATA and the data driver control signal DCS to the data driver. The gate driver control signal GCS may include a gate start pulse, a gate shift clock, and a gate output enable signal. The data driver control signal DCS may include a source start pulse, a source sampling clock, a source output enable signal, a polarity control signal, and the like.

The detection camera 90 captures an image of a viewer and transmits the captured image to the control unit 80. [ The control unit 80 analyzes the photographed image so that the viewer can see the first position P1, the second position P2, and so on. And the third position P3.

The controller 80 controls the backlight supply panel 10 according to the viewer position information to form one of the first to third areas A1 to A3 as an opening area. The light transmitted through the aperture area is converted into parallel light in the +? Or? Direction through the first and second light conversion plates 30 and 40 and supplied to the display panel 50.

A driving method of the hologram system constructed as above will be described with reference to FIGS. 9 and 10. FIG.

The detection camera 90 captures an image of a viewer and transmits the captured image to the control unit 80. [ The control unit 80 analyzes the photographed image to calculate coordinates at which the viewer is located, and determines which position among the first position to the third position is located.

When the viewer moves to the third position P3 in the + θ direction with respect to the reference point, the controller 80 supplies the drive voltage according to the position of the viewer to the backlight supply panel 10, And is formed as an opening region so that light supplied from the backlight is transmitted only in the first region A1 and the remaining region is blocked. Thus, since the parallel light is supplied only to the third recording plate LT3 of the first light conversion plate 30, the parallel light is transmitted through the third recording plate LT3 while the second reference light AT2 in the + And is supplied to the second optical conversion plate 40. [ The second reference light AT2 is converted into parallel light by the second light conversion plate 40 and is supplied to the display panel 50 so that the hologram is displayed at the third position P3 in the + ).

If the viewer moves in the -θ direction relative to the reference point, the controller 80 supplies the driving voltage corresponding to the position of the viewer to the backlight supply panel 10 to form the third area A3 as an opening area The light supplied from the backlight is transmitted only in the third area A3 and the remaining area is blocked. Thus, since the parallel light is supplied only to the first recording plate LT1 of the first light conversion plate 30, the parallel light is transmitted through the first recording plate LT1, and the third reference light AT3 in the - And is supplied to the second optical conversion plate 40. [ The third reference light AT3 is converted into parallel light by the second light conversion plate 40 and is supplied to the display panel 50 so that the hologram is displayed at the first position P1 in the -θ direction ).

As described above, in the hologram display system according to the embodiment of the present invention, the light supplied from the backlight to the first light conversion plate 30 is converted into the first through third reference lights, The second position P2 corresponding to the reference point, the first position P1 in the -θ direction, the third position P3 in the +? Direction, and the second position P2 corresponding to the reference point. A hologram can be displayed. On the other hand, in the above-described embodiment, only the case where the aperture region corresponds to the first to third regions has been described. However, if the aperture region is formed of n, holograms can be formed at n positions, .

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.

Claims (6)

A backlight supply panel for selectively transmitting parallel light supplied from the backlight,
A first light conversion plate for converting the reference light in the first direction and the reference light in the second direction, which converge the parallel light supplied from the supply panel to the focal point,
A second light conversion plate for converting the reference light in the first direction supplied from the first light conversion plate into parallel light in the first direction and converting the reference light in the second direction into parallel light in the second direction,
A display panel for forming a hologram in a first direction or a second direction by the parallel light supplied from the second light conversion plate,
And the hologram display system.
The method according to claim 1,
Wherein the backlight supply panel has a structure in which a liquid crystal cell is sandwiched between two substrates, and transmits or blocks the parallel light by an alignment direction of the liquid crystal.
The method according to claim 1,
Wherein the first light conversion plate comprises:
And a first recording plate for recording the substrate and the light path pattern,
Wherein the first recording plate is formed corresponding to the divided area.
The method of claim 3,
Wherein the first recording plate comprises:
A 1-1 recording plate for recording an optical path pattern of parallel light and reference light in the first direction and converting the parallel light into reference light in the first direction,
A first-second recording plate for recording an optical path pattern of parallel light and reference light in the second direction and converting the parallel light into reference light in the second direction,
And the hologram display system.
The method according to claim 1,
Wherein the second light conversion plate comprises:
And a second recording plate which is sequentially laminated on the substrate and the substrate, and records the optical path patterns, respectively.
6. The method of claim 5,
Wherein the second recording plate comprises:
A second-1 recording plate for recording an optical path pattern of the parallel light and the reference light in the first direction and converting the reference light in the first direction into the parallel light,
2-2 recording plate for recording an optical path pattern of parallel light and reference light in the second direction and converting the reference light in the second direction into the parallel light,
And the hologram display system.

Images