KR20130021868A - Display apparatus for displaying three dimensional picture - Google Patents

Abstract

PURPOSE: A stereoscopic image display device is provided to emit collimated light using an image panel illumination holographic optical element while maintaining the shape of an existing normal display device and thin vertical thickness. CONSTITUTION: A stereoscopic image display device includes an image panel(100), an image panel lamp holographic optical element(200), a light source(500), an image panel memory holographic optical element(300) and a flat mirror(600). The image panel outputs an image. The image panel lamp holographic optical element supplies backlight on the front surface of the image panel. The light source generates collimated light. The image panel memory holographic optical element reflects the light outputted from the light source while memorizing the shape of the image panel lamp holographic optical element. The flat mirror composed of a mirror having a flat shape reflects the light reflected from the image panel memory holographic optical element using the image panel lamp holographic optical element.

Description

Display Apparatus For Displaying Three Dimensional Picture}

The present invention relates to a stereoscopic image display apparatus, and more particularly, to a stereoscopic image display apparatus capable of stereoscopically displaying an image using a holographic method.

The stereoscopic image display apparatus displays a stereoscopic image by using perspective appearing when different image signals perceived by two eyes are synthesized.

As a method of implementing such a stereoscopic image, a binocular parallax technique, a volumetric technique, a holographic technique, and the like are known.

Among these, the binocular disparity method (stereoscopic method) is a method of causing a three-dimensional image by showing the two-dimensional image having binocular disparity separately and showing the left and right eyes of the user, respectively. A stereoscopic image display apparatus using a binocular disparity method includes a liquid crystal panel in which left eye pixels displaying left eye image information and right eye pixels displaying right eye image information are alternately disposed, and the left eye and right eye images face left and right eyes, respectively. It comprises a separate parallax barrier (parallax barrier).

This binocular parallax method has the advantage that a system can be constructed using a flat panel display panel and simple optical components, so that a three-dimensional image can be realized in a slim structure, but since the left and right images must be configured in one panel, the resolution is less than half It has been reduced to, has a problem that can give a visual fatigue to the user.

On the other hand, holographic (Holographic) is a method that allows you to feel the same stereoscopic image as the real without wearing special glasses using a hologram. Accordingly, the holographic method is known to be the most ideal way to allow the viewer to feel the stereoscopic image without fatigue.

This holographic method utilizes the principle of recording and reproducing an interference signal obtained by superimposing light reflected on an object (object wave) and coherent light (reference wave).

1 is an exemplary view showing the configuration of a stereoscopic image display apparatus using a conventional holographic method, showing a perspective view, a side view, and a state in which light output from a light source is reflected.

A conventional three-dimensional image display device (H-ASD: Holographic-AutoStereoscopic Display) using a holographic method, as described in the patent document of International Publication No. WO 2010/084326, a plurality of light sources (A Plurality of Light Sources or A Plurality of Light Source Array (IPM) is used to investigate Image Panel Memorized (IPM) -HOE.

On the other hand, when the light emitted from the light source 50 is incident to the IPM-HOE 30, the light is diffracted and collimated through a parabola mirror 60 as shown in FIG. Light entering the IPI (Image Panel Illumination) -HOE (20) in the form of light, passing through the IPI-HOE diffraction once again the viewing window (90) area where the user can see the stereoscopic image Is concentrated.

At this time, when the position of the light source 50 to emit light is changed, the direction of the light incident on the IPI-HOE and the IPM-HOE is changed, and thus the viewing window 90 is moved.

In the conventional stereoscopic image display device, the vertical length of the stereoscopic image display device increases according to the curvature of the Parabola mirror 60. Therefore, the conventional stereoscopic image display apparatus cannot maintain the shape of the current stereoscopic image display apparatus, and the upper portion is displayed in a parabolic shape.

That is, in order to irradiate collimated light to the IPI-HOE 20, a parabola mirror 60 is required. On the other hand, the form of light irradiated to the IPI-HOE 20 through the IPM-HOE 30 is the same size as the collimated light of the image panel 10 or the IPI-HOE film 20. Should be In order to generate such parallel light, a collimator is required in the middle, and the parabola mirror 60 plays such a role.

The vertical thickness of the entire stereoscopic image display apparatus increases according to the curvature of the parabola mirror 60 as described above, and the shape of the parabola is different from that of a conventional stereoscopic image display apparatus. Form.

In detail, a holographic-autostereoscopic display (H-ASD) using a holographic method is a device for implementing a stereoscopic image using a holographic optical element (HOE). In a stereoscopic image display apparatus using a holographic method, light passing through an IPM-HOE (Image Panel Memorized-HOE) 30 with initial directivity is reflected by a parabola mirror 60 and is parallel ( Collimated) to the IPI-HOE 20.

At this time, the parabola mirror has a vertical thickness according to its curvature, and therefore, a stereoscopic image display device using a conventional holographic method is rounded at the top rather than a shape of a conventional stereoscopic image display device. It is formed in the form.

For this reason, a stereoscopic image display apparatus using a conventional holographic method cannot be manufactured using a case or the like in which a conventional general stereoscopic image display apparatus is used.

The present invention is to solve the above problems, so that the light reflected from the image panel memory holographic optical element (IPM-HOE) can be irradiated to the image panel illumination optical element (IPI-HOE) in a parallel light state, An object of the present invention is to provide a stereoscopic image display device having a flat mirror between an image panel memory holographic optical element (IPM-HOE) and an image panel illumination optical element (IPI-HOE).

According to an aspect of the present invention, there is provided a stereoscopic image display device comprising: an image panel for outputting an image; An image panel illumination holographic optical device (IPI-HOE) for supplying a back light to the front of the image panel; A light source for generating a collimated beam; An image panel memory holographic optical element (IPM-HOE) for storing the form of the IPI-HOE and for reflecting the light output from the light source; And a flat mirror configured to be configured as a flat mirror to reflect light reflected from the IPM-HOE to the IPI-HOE.

In the IPI-HOE, pattern information on a viewing window for displaying a stereoscopic image may be recorded.

The IPI-HOE may be located at the front or the rear of the image panel.

The IPM-HOE can cause the light transmitted from the light source to be incident on the IPI-HOE in a state having an angle of the reference light used when recording the hologram in the IPI-HOE.

The IPM-HOE can function to reflect the light transmitted from the light source and irradiated to a partial region of the IPM-HOE and irradiate the entire area of the flat mirror.

The IPM-HOE or the IPI-HOE may be composed of any one of photoresist, photopolymer, bleached photo plate, and dichromated gelatin (DCG).

The light source may be provided in plurality in order to output light to different positions of the IPM-HOE.

Only one light source may be provided, and the light path control unit for irradiating light to different positions of the IPM-HOE by rotating or moving the one light source; A driving unit for driving the light path adjusting unit; And a control unit for controlling the driving unit.

The flat mirror may include a flat mirror and a Fresnel lens.

There may or may not be a gap between the flat mirror and the Fresnel lens.

The flat mirror may be configured in the form of a Fresnel mirror.

The Fresnel mirror may be formed by coating aluminum on the surface of the Fresnel lens.

According to the above solution, the present invention provides the following effects.

The present invention is to provide an image panel memory holographic optical device so that the light reflected from the image panel memory holographic optical device (IPM-HOE) can be irradiated to the image panel illumination holographic optical device (IPI-HOE) in a parallel light state. By providing a mirror between the (IPM-HOE) and the image panel illumination optical element (IPI-HOE), the shape of the conventional stereoscopic image display device is maintained and the vertical thickness is kept thin. In addition, it provides the effect that the parallel light can be irradiated with the image panel illumination holographic optical element (IPI-HOE).

1 is an exemplary view showing the configuration of a three-dimensional image display device using a conventional holographic method.
Figure 2 is a perspective view showing the configuration of a three-dimensional image display device according to the present invention.
Figure 3 is a side view showing the configuration of a three-dimensional image display device according to the present invention.
4 is an exemplary view illustrating a state in which light output from a light source is reflected in a stereoscopic image display device according to a first embodiment of the present invention.
5 is an exemplary view illustrating a state in which light output from a light source is reflected in a stereoscopic image display device according to a second embodiment of the present invention.

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

2 is a perspective view showing the configuration of a stereoscopic image display device according to the present invention, Figure 3 is a side view showing the configuration of a stereoscopic image display device according to the present invention.

A stereoscopic image display device (H-ASD (Holographic-AutoStereoscopic Display) using a stereoscopic image display device holographic method according to the present invention), the image panel illumination holographic optical element (Collimated) the light output from the light source ( IPI-HOE: FF (Flat Mirror + Fresnel Lens) mirror consisting of a flat mirror and Fresnel lens instead of a Parabola mirror that is irradiated with Image Panel Illumination-HOE (hereinafter referred to simply as 'IPI-HOE') (Hereinafter, simply referred to as 'flat mirror and Fresnel lens compound mirror') (first embodiment), or by using a Fresnel mirror (Fresnel Mirror), to reduce the vertical thickness of the current general stereoscopic image display device It has the feature of maintaining the shape of.

That is, the stereoscopic image display device according to the present invention reflects the light reflected from the IPM-HOE to the flat mirror and the Fresnel lens composite mirror so that the light reflected from the IPM-HOE can be irradiated to the IPI-HOE in a parallel light state. Or irradiated with Fresnel mirrors and irradiated with IPI-HOE.

To this end, as shown in FIG. 2 and FIG. 3, the stereoscopic display device according to the present invention includes an image panel 100 for outputting an image and an IPI-HOE 200 for supplying a backlight to the front of the image panel. ), A light source 500 for generating a collimated beam, and an IPI-HOE form. The IPM-HOE 300 and a mirror in the form of a flat plate reflect the light output from the light source. It may be configured to include a flat mirror (Mirror) 600 that can reflect the light reflected from the HOE to the IPI-HOE.

First, the IPI-HOE (200) is a function of supplying light to the front surface of the image panel 100, and pattern information about a viewing window is recorded.

That is, the image of the diffuse light source is recorded in the IPI-HOE, so that the user can view the image of the image panel according to the geometric shape or the size of the diffuse light source. It is possible to form a viewing window. An auto-stereoscopic 3D display may be implemented when the viewing window is small enough to deliver different images to the left and right eyes of the user. Here, the viewing window refers to a position in space where a user can view a stereoscopic image.

The IPI-HOE 200 may be located at the front or rear of the image panel 100.

Next, the image panel 100 modulates the light reproduced by the IPI-HOE 200 according to an image signal to form an image. For example, the image panel 100 may be configured as a liquid crystal panel (LCD). In addition, a TFT-LCD, SLM, LCOS, or the like may be applied to the liquid crystal panel LCD forming the image panel 100.

That is, since the IPI-HOE 200 is disposed behind the image panel 100, the image panel 100 modulates the light reproduced by the IPI-HOE according to the video signal. The image panel 100 may alternately implement an image of one frame into a plurality of images in a time multiplexing manner. For example, in a state in which an image of one frame is divided into two sub-frame images, the image panel 100 may modulate light according to an image signal corresponding to each image.

Next, the IPM-HOE 300 stores the shape of the IPI-HOE, and uniformly covers the entire area of the flat mirror 600 when light is irradiated to a part of the IPM-HOE. To distribute the light.

That is, the IPM-HOE 300 may perform a function of converting the optical path such that the light transmitted from the light source 500 has the angle of the reference light used when recording the hologram in the IPI-HOE 200. Here, the IPM-HOE 300 performs a function of uniformly shining the light transmitted from the light source 500 to the entire area of the flat mirror 600, and the IPI-HOE 200 performs the flat mirror 600. It performs a function of forming a different image according to the light transmitted from the IPM-HOE (300) through.

In detail, since the form of the IPI-HOE 200 recorded at the position is recorded at different positions on the IPM-HOE 300, the reproduction light is irradiated to a position of the IPM-HOE 300. FIG. In this case, light is emitted in the direction of the IPI-HOE through the flat mirror 600 at that position, and a viewing window recorded in the IPI-HOE is formed in this direction. When the position where the reproduction light is irradiated on the IPM-HOE is changed, the position of the viewing window is changed.

Meanwhile, the IPM-HOE 300 or the IPI-HOE 200 as described above may be manufactured using a photoresist, a photopolymer, a bleached photo plate, a dichromated gelatin (DCG), and the like. Can be.

In addition, a holographic optical element (HOE) such as the IPM-HOE 300 or the IPI-HOE 200 as described above is a lens or mirrors made by a holographic method. , gratings, prisms and beam splitters. These HOEs are classified as a type of diffraction optical elements (DOEs) and are referred to as DOEs because they use diffraction effects rather than reflection or refraction. In addition, HOE follows geometrical optics rules and can be used for conventional optical elements. In addition, the HOE appears in a wavelength of a narrow operating efficiency (Operate efficiency), but is not a big problem because it is manufactured using a laser (laser).

Next, the light source 500 performs a function of outputting a collimated beam, and as a light source, a plurality of LEDs may be applied, or a combination of red, green, and blue laser lights may be used. have.

That is, the present invention may include a plurality of light sources 500 for outputting light to different positions of the IPM-HOE 300, but may also include only one light source in which red, green, and blue laser lights are combined. .

When the present invention uses only one light source, the present invention is a light path control unit (not shown) for irradiating light to different positions of the IPM-HOE by rotating or moving the light source, a drive unit for driving the light path control unit ( A control unit (not shown) for controlling the driver and the driving unit may be further included.

Finally, the flat mirror 600 is to reflect the light transmitted from the IPM-HOE (300) to irradiate the front surface of the IPI-HOE (200), it can be configured in two forms.

First, the present invention uses a flat mirror and a Fresnel lens composite mirror (FF) as a flat mirror 600 instead of a conventional Parabola mirror (first embodiment), so that the upper portion of the stereoscopic image display apparatus is used. It is possible to maintain the same shape as that of a conventional stereoscopic image display device rather than a round shape, thereby reducing the vertical thickness of the stereoscopic image display device. Here, the flat mirror and the Fresnel lens composite mirror (FF) refers to a mirror in which a flat mirror and a Fresnel lens are combined. This will be described in detail with reference to FIG. 4 below.

Second, the present invention uses a Fresnel mirror as a flat mirror 600 instead of a conventional Parabola mirror (second embodiment), so that the upper portion of the stereoscopic image display device is not rounded. It can be maintained in the same form as a conventional stereoscopic image display device, thereby reducing the vertical thickness of the stereoscopic image display device.

4 illustrates a state in which light output from a light source is reflected in a stereoscopic image display device according to a first embodiment of the present invention.

The stereoscopic image display device according to the first embodiment of the present invention, as described above, the image panel 100 to output the image, IPI-HOE (200) for supplying a backlight (Back Light) in front of the image panel, parallel It stores the light source 500 to generate the collimated beam, the form of the IPI-HOE, and is composed of an IPM-HOE 300 for reflecting the light output from the light source and a mirror in the form of a flat plate to reflect from the IPM-HOE. It may be configured to include a flat mirror (Mirror) 600 that can reflect the received light to the IPI-HOE, in particular, instead of the conventional Parabola mirror (flat mirror and mirror) with the flat mirror 600 It is characterized by the fact that Nellens compound mirror (FF) is used.

That is, as shown in FIG. 4, the 3D image display device according to the first embodiment of the present invention has a flat mirror and a fryer in which a flat mirror 611 and a fresnel lens 612 are combined. A NEL lens composite mirror (FF) 610 is used as the flat mirror 600, and the flat mirror 600 is characterized in that it is mounted on the top surface direction of the stereoscopic image display device.

Here, there may or may not be a gap between the flat mirror 611 and the Fresnel lens 612.

Therefore, the top surface of the stereoscopic image display device according to the first embodiment of the present invention is not a round shape like the top surface of the conventional stereoscopic image display device, but is a flat shape like the stereoscopic image display device currently used generally. It can be configured as.

Here, the Fresnel lens 612 may be configured using both a glass type (Film type) and a film type (Film type). The Fresnel lens is briefly described as follows. Fresnel Lens refers to a lens whose thickness is reduced instead of having the same effect as a convex lens. In this case, the reason why the thickness can serve as a convex lens is that the Fresnel lens is divided into several bands so that each band has a prism action, thereby reducing the aberration. That is, a Fresnel lens is a type of condenser, and is a lens used not for making an image but for concentrating light in a desired direction and place. Therefore, the reason for reducing the refractive index in the Fresnel lens is not to sharpen the image, but to play a role of collecting the light in one place.

5 is an exemplary view illustrating a state in which light output from a light source is reflected in a stereoscopic image display device according to a second embodiment of the present invention.

As described above, the stereoscopic image display apparatus according to the second embodiment of the present invention has an image panel 100 for outputting an image, an IPI-HOE 200 for supplying a back light to the front of the image panel, and parallelism. It stores the light source 500 to generate the collimated beam, the form of the IPI-HOE, and is composed of an IPM-HOE 300 for reflecting the light output from the light source and a mirror in the form of a flat plate to reflect from the IPM-HOE. It may be configured to include a flat mirror (Mirror) 600 that can reflect the received light to the IPI-HOE, in particular, the flat mirror 600, instead of the conventional Parabola mirror (Parabola Mirror), Fresnel mirror (Fresnel Mirror) is used.

That is, in the stereoscopic image display apparatus according to the second embodiment of the present invention, as shown in FIG. 5, a Fresnel mirror 620 is used as the flat mirror 600, and such a flat mirror 600 is mounted on the top surface of the stereoscopic image display device.

Here, the Fresnel mirror 620 may be made similar to the principle of the Fresnel lens to flatten the convex portion of the convex lens.

Therefore, the top surface of the stereoscopic image display device according to the second embodiment of the present invention is not round like the top surface of the conventional stereoscopic image display device, but in the same flat shape as the flat panel display device currently used. Can be configured.

That is, the three-dimensional image display device according to the present invention as described above, replacing the conventional parabolar mirror (Parabolar Mirror) in the form of a flat plate in order to reflect the incident light in the form of parallel light 600 As such, the flat mirror 600 may be configured in the form of a flat mirror and a Fresnel lens composite mirror 610 as in the first embodiment, or may be configured as a Fresnel mirror 620 as in the second embodiment. .

The flat mirror 600 performs the same function as the conventional Parabolar mirror in the functional part, but has a feature of being made in a flat form.

Here, the method of making a parabolar mirror in the form of a flat mirror and a fresnel lens composite mirror 610 or a fresnel mirror 620, in principle, a convex lens (Fresnel Lens) The same method as in the form of) can be applied.

In other words, the parabolic parabolic mirror is divided horizontally, and the same method as the method of manufacturing the Fresnel lens is used to vertically move the flat portion having the upper curvature to make it flat. Thus, a flat mirror and a Fresnel lens composite mirror 610 or a Fresnel mirror 620 can be manufactured.

However, since the flat mirror 600 applied to the present invention functions as a mirror, a form in which a Fresnel lens and a mirror are combined with each other (first embodiment), or Fresnel The surface of the aluminum coating may be produced in the form (second embodiment).

That is, the flat mirror 610 applied to the first embodiment is a Fresnel lens 612 manufactured by applying the method as described above is combined with the flat mirror 611, the second embodiment The flat mirror 620 to be applied is manufactured by coating aluminum on the surface of the Fresnel lens 612 manufactured by applying the method as described above.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Image panel 200: IPI-HOE
300: IPM-HOE 500: light source
600: flat mirror

Claims (13)

An image panel on which an image is output;
An image panel illumination holographic optical device (IPI-HOE) for supplying a back light to the front of the image panel;
A light source for generating a collimated beam;
An image panel memory holographic optical element (IPM-HOE) for storing the form of the IPI-HOE and for reflecting the light output from the light source; And
And a flat mirror configured to be configured as a flat mirror to reflect light reflected from the IPM-HOE to the IPI-HOE. The method of claim 1,
And the pattern information of a viewing window for displaying a stereoscopic image is recorded in the IPI-HOE. The method of claim 1,
And the IPI-HOE is located at the front or the rear of the image panel. The method of claim 1,
The IPM-HOE is,
And the light transmitted from the light source is incident on the IPI-HOE with the angle of the reference light used when recording the hologram on the IPI-HOE. The method of claim 1,
The IPM-HOE is,
And reflecting the light transmitted from the light source and irradiated to a part of the IPM-HOE to the entire area of the flat mirror. The method of claim 1,
The IPM-HOE or the IPI-HOE,
A stereoscopic image display device comprising one of a photoresist, a photopolymer, a bleached photo plate, and a dichromated gelatin (DCG). The method of claim 1,
The light source is
A plurality of stereoscopic image display device is provided for outputting light to different positions of the IPM-HOE. The method of claim 1,
Only one light source is provided,
An optical path adjusting unit for irradiating light to different positions of the IPM-HOE by rotating or moving the one light source;
A driving unit for driving the light path adjusting unit; And
And a control unit for controlling the driving unit. The method of claim 1,
The flat mirror,
And a flat mirror and a Fresnel lens. The method of claim 9,
And a gap between the flat mirror and the Fresnel lens. The method of claim 9,
And a gap between the flat mirror and the Fresnel lens. The method of claim 1,
The flat mirror,
A stereoscopic image display device characterized in that it is configured in the form of a Fresnel Mirror (Fresnel Mirror). 13. The method of claim 12,
The Fresnel mirror,
A stereoscopic image display device characterized in that the aluminum is coated on the surface of the Fresnel lens.

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