KR100887673B1 - Stereoscopic 3-D Display Apparatus - Google Patents

Abstract

The present invention relates to a stereoscopic image display apparatus, and more particularly, to a stereoscopic image display apparatus which an observer can see without wearing glasses. In particular, the present invention relates to a display device that can display a two-dimensional (2-D) image and a three-dimensional (3-D) image and switch between them. In addition to using two liquid crystal panels in the 2-D and 3-D switchable image displays, one of them is used as a parallax-barrier in 3-D mode. The virtual stereoscopic image can be felt without using ancillary means such as polarized glasses. In addition, there is a feature of the present invention to overcome the disadvantage that the brightness is reduced in the 3-D display using the cholesteric liquid crystal (Cholesteric Liquid Crystal) compared to the 2-D display.

Description

Stereoscopic Display Device {Stereoscopic 3-D Display Apparatus}             

FIG. 1 is a schematic diagram illustrating a parallax barrier method for implementing a 3D stereoscopic image using a liquid crystal display (LCD) panel.

FIG. 2 is a schematic diagram illustrating another example of a parallax barrier method for implementing a 3D stereoscopic image using a liquid crystal display (LCD) panel.

FIG. 3 is a schematic diagram illustrating the implementation of a 3D stereoscopic image in a parallax barrier method using a liquid crystal display (LCD) panel.

FIG. 4 is a schematic diagram illustrating that a 3D stereoscopic image display device using a liquid crystal display (LCD) panel of FIG. 3 implements 2D.

5 is a schematic cross-sectional view of an image display apparatus using a liquid crystal panel according to the present invention;

FIG. 6 is a cross-sectional view schematically illustrating that the second liquid crystal panel of FIG. 5 is driven to display a two-dimensional (2-D) image.

FIG. 7 is a cross-sectional view schematically illustrating that the second liquid crystal panel of FIG. 5 is driven to display a three-dimensional (3-D) image.

FIG. 8 is a plan view schematically illustrating a shape in which a second electrode illustrated in FIGS. 6 and 7 is formed on a substrate.

FIG. 9 is a schematic cross-sectional view showing the progress of light passing through each component constituting the second liquid crystal panel when the image display apparatus according to the present invention displays a two-dimensional (2-D) image.

FIG. 10 is a schematic cross-sectional view showing the progress of light passing through each component constituting the second liquid crystal panel when the image display apparatus according to the present invention displays a three-dimensional (3-D) image.

<Description of the symbols for the main parts of the drawings>

150: first liquid crystal panel 160: second liquid crystal panel

170: backlight unit 161: upper substrate of second liquid crystal panel

162: lower substrate of the second liquid crystal panel 163: liquid crystal layer

164: first electrode 165: second electrode

166: first cholesteric liquid crystal layer 167: second cholesteric liquid crystal layer

169: retardation plate 190: polarizing plate of second liquid crystal panel

The present invention relates to a liquid crystal display device for a three-dimensional (3-D) stereoscopic image display device using a parallax barrier, and in particular, 2-D (2-D) and 3-D ( 3 Dimension) The present invention relates to a stereoscopic image display device capable of a display and a method of manufacturing the same.

The services to be realized for the high speed of information built on the high-speed information communication network today are 'seeing and hearing' multi-centered digital terminals that process text, voice, and video at high speed from simple 'hearing and talking' services such as current telephones. It is expected to develop into a media-type service and ultimately develop into a super-spatial, realistic three-dimensional three-dimensional information and communication service that transcends time and space.

In general, the three-dimensional image representing the three-dimensional is achieved by the principle of stereo vision through two eyes, the parallax of two eyes, that is, binocular disparity that appears because the two eyes are about 65mm apart is the most important of the three-dimensional It can be called a factor. In other words, each of the left and right eyes sees different two-dimensional images, and when these two images are transmitted to the brain through the retina, the brain accurately fuses each other to reproduce the depth and reality of the original three-dimensional image.

Currently, technologies proposed to display three-dimensional stereoscopic images include stereoscopic image display by special glasses, autostereoscopic three-dimensional image display, and holographic display. The three-dimensional image display method using the special glasses is the polarization glasses method using the vibration direction or the rotation direction of the polarization, the time-division glasses method alternately presenting while switching the left and right images and the method of delivering light of different brightness in the left and right. Phosphorus concentration difference can be divided. In addition, the autostereoscopic three-dimensional display method has a parallax method and a semi-cylindrical lens arranged in front of each image corresponding to the left and right eyes through a longitudinal grid-shaped aperture to separate and observe the images. It can be divided into a lenticular method using a lenticular plate and an integral photography method using a lens plate shaped like a fly's eye. In addition, the holographic display method can obtain a three-dimensional stereoscopic image having all factors such as focus adjustment, confinement angle, binocular disparity, and motion parallax that cause three-dimensional effect. With a laser light reproduction hologram and a white light reproduction hologram, Are classified.

The three-dimensional image display method by the special glasses, but many people can enjoy the three-dimensional image, but has the disadvantage of wearing a separate polarized glasses or liquid crystal shutter glasses. That is, the observer must wear special glasses, causing discomfort and unnaturalness.

The autostereoscopic 3D display method has a fixed viewing range and is limited to a small number of people, but there is a feature that does not wear a separate eyeglasses, and thus tends to be preferred. That is, many studies have been conducted in the autostereoscopic 3D display method because the observer directly observes the screen and the above-mentioned disadvantages disappear.

For example, a holographic display method is used to display a perfect 3D stereoscopic image. The 3D coordinate image is displayed directly in space through a laser, a lens, and a mirror. You can get the feel of an object as it is, but it is difficult to access because of the technical difficulties and the space that the equipment takes up.

Thus, there is an increasing tendency to adopt a parallax barrier, which is a method of realizing a three-dimensional image virtually through deception using stereo images.

The parallax barrier is a vertical or horizontal shape (slit) placed in front of an image corresponding to the left and right eyes so as to separate and observe a stereoscopic image synthesized through the slit to feel a three-dimensional effect. .

FIG. 1 is a schematic diagram of a parallax barrier method for implementing a 3D stereoscopic image using a liquid crystal display (LCD) panel.

As shown, a left eye pixel L for displaying image information for the left eye and a right eye for displaying image information for the right eye Pixels R are alternately formed on the LCD panel 10. A backlight 20, which is an artificial light source that emits light, is located under the LCD panel. The backlight 20 emits light toward the liquid crystal panel 10 by using electrical energy. The parallax barrier 30 is positioned between the liquid crystal panel 10 and the observer 40 to pass or block light. That is, the parallax barrier 30 has a slit 32 through which light from the right eye pixel R and the left eye pixel L passes, and a barrier 34 blocking the light. Has the observer 40 to implement a virtual three-dimensional stereoscopic image. As can be seen from the enlarged plan view of the parallax barrier 30, the slit 32 and the barrier 34 are alternately formed vertically alternately.

The parallax barrier-based 3D stereoscopic image implementation method will be described in more detail. First, among the light emitted from the backlight 20, the light toward the left eye of the observer 40 passes through the left eye pixel L of the liquid crystal panel 10 and the slit of the parallax barrier 30. It becomes light L1 passing through 32 and reaching the left eye of the observer 40. However, even though the light emitted from the backlight 20 passes through the left-eye pixel L of the liquid crystal panel 10, the light L2 directed to the right eye of the observer 40 is blocked by the barrier 34 and is observed. It will not be delivered to 40. In this manner, the light emitted from the backlight 20 passes through the right eye pixel R of the observer 40 and passes through the slit 32 of the parallax barrier 30 to the observer 40. There is light R1 that reaches the right eye, and even though it passes through the right eye pixel R of the liquid crystal panel 10, the light R2 toward the viewer's left eye is blocked by the barrier 34.

As a result, the light passing through the left eye pixel L becomes the light L1 transmitted only to the left eye of the observer 40, and the light passing through the right eye pixel R becomes the right eye of the observer 40. Only the light (R1) is transmitted to the viewer 40 can recognize. At this time, sufficient parallax information is formed between the light L1 reaching the left eye and the light R1 reaching the right eye so that a human being as an observer can sufficiently detect the 3D stereoscopic image. 3 dimension images).

However, although the parallax-barrier type 3D stereoscopic image display device has passed through the right eye pixel R and the left eye pixel L, light absorbed by being blocked by the barrier 34 is absorbed. Because of (L2, R2), a large amount of light cannot be reached by the observer. Thus, it has the disadvantage of lowering the brightness and brightness of the three-dimensional stereoscopic image display device.

In addition, the 3D stereoscopic image display device having the above configuration may have a different structure as shown in FIG. 2. FIG. 2 is a schematic diagram illustrating another example of a parallax barrier method for implementing a 3D stereoscopic image using a liquid crystal display (LCD) panel.

As shown, a 3D stereoscopic image display device of a parallax barrier type has a liquid crystal panel 10 having a left eye pixel L and a right eye pixel R, and a parallax barrier. The parallax barrier 30 is positioned below the liquid crystal panel 10 unlike the above description. In addition, a backlight 20 is positioned below the parallax barrier 30 to emit light toward the parallax barrier 30 and the liquid crystal panel 10. . Unlike the 3D stereoscopic image display described with reference to FIG. 1, in FIG. 2, a parallax barrier 30 is positioned between the backlight 20 and the liquid crystal panel 10, and the liquid crystal panel 10 is It is positioned between the parallax barrier 30 and the observer 40.

As shown in FIG. 2, light passing through the right eye pixel R of the light passing through the slit 32 of the parallax barrier 30 reaches the right eye of the observer 40, and the left eye Light passing through the dragon pixel L reaches the left eye of the observer 40. In addition, the barrier 34 of the parallax barrier 30 absorbs light to distribute the light formed in the backlight 20 to the right eye pixel R and the left eye pixel L. To block.

FIG. 3 is a schematic diagram illustrating implementing a 3D stereoscopic image in a parallax barrier method using a liquid crystal display (LCD) panel.

As shown in FIG. 3, a liquid crystal panel 50 including a left eye pixel L and a right eye pixel R is formed, and a parallax-barrier 62 is implemented under the liquid crystal panel 50. A switching display 60 is formed. The backlight 70, which serves as a light source, is positioned below the switch display 60. The liquid crystal panel 50 has a number of pixels R and L, and displays images in a manner in which a thin film transistor and an electrode are formed in each pixel to apply an electric field to the liquid crystal. When the liquid crystal panel 50 is used as a 3D image display device, the right eye pixel R and the left eye pixel L are alternately formed.

In addition, the switching display 60 formed under the liquid crystal panel 50 has a method of forming a parallax barrier 62 using liquid crystal. That is, when power is applied to the liquid crystal constituting the switching display 60, some pixels serve as a barrier 62 by blocking / absorbing light emitted from the backlight 70. In addition, the remaining pixels that do not receive power serve as a slit of the parallax barrier. Therefore, the light emitted from the backlight 70 is separated by the parallax barrier 62 of the switching display 60 to be formed in the left eye pixel L of the observer 80 respectively. The image and the image formed from the right eye pixel R are transferred. In conclusion, a virtual three-dimensional stereoscopic image can be displayed by forming parallaxes respectively on the left and right eyes of the observer 80.

FIG. 4 is a schematic diagram illustrating that a 3D stereoscopic image display apparatus using a liquid crystal display (LCD) panel of FIG. 3 implements 2D.

As shown in FIG. 4, when power is not applied to the switching display 60 unlike in FIG. 3, a parallax barrier (62 of FIG. 3) is not formed and the switching display 60 is lighted. All pixels are allowed to transmit light without having a pixel that blocks / absorbs them. Therefore, the liquid crystal panel 50 forming the image has the same image in both the right eye and the left eye of the observer without distinguishing between the left eye pixel (L in FIG. 3) and the right eye pixel (R in FIG. 3). Will be delivered. In conclusion, two-dimensional (2-D) images can be displayed.

As described above, 2D and 3D may be implemented by one image display apparatus using two panels. However, the conventional image display apparatus as described above has a disadvantage in that the brightness of the display is reduced by 20 to 30% compared to the 2D implementation since the conversion display 60 forms a barrier to absorb light when implementing the 3D. Have In other words, a parallax barrier is formed in the switching display, and the pixels serving as a barrier of the parallax barrier absorb and block some of the light formed in the backlight, thereby making it three-dimensional. (3D) When displaying a stereoscopic image, the brightness of the video display device is lowered.

As described above, it is an object of the present invention to improve the disadvantage that the brightness of the image display device is reduced when implementing the 3D stereoscopic image. The light emitted from the backlight, which is a light source, can be recycled without being absorbed by a barrier, so that even if the 2-D / 3-D switchable image display device displays a 3D stereoscopic image, 2-D This is to prevent the luminance from decreasing as compared to when implementing.

To this end, it is an object of the present invention to form a cholesteric liquid crystal layer on the liquid crystal panel used as a conversion display and to configure the recycling of light to enable the recycling of light. In the present invention, in forming a liquid crystal panel displaying an image and another switching LCD panel implementing a parallax barrier, a cholesteric liquid crystal is formed in the switching liquid crystal panel. By forming a liquid crystal layer it is possible to recycle the light (recycling).

The image display device of the present invention for achieving the above object includes a first liquid crystal panel and a second liquid crystal panel and a backlight unit below. Here, the second liquid crystal panel includes an upper substrate; A lower substrate spaced apart from the upper substrate by a predetermined distance; A first electrode formed on an upper portion of the lower substrate; A first cholesteric liquid crystal layer formed under the lower substrate; A second electrode formed under the upper substrate; A second cholesteric liquid crystal layer formed on the upper substrate; A retardation plate formed on the second cholesteric liquid crystal layer; A flat plate formed on the retardation plate; And a liquid crystal layer disposed between the upper and lower substrates, wherein the backlight unit includes a reflective plate.

The backlight unit may further include a light source that emits light, and the second liquid crystal panel enables the image display device of the present invention to implement 2D and 3D. The first liquid crystal display includes two substrates, a liquid crystal filled therebetween, and a polarizing plate at an outer portion of the two substrates.                     

The first cholesteric liquid crystal layer reflects only right circular polarization covering the left circularly polarized light, and the second cholesteric liquid crystal layer reflects only right circularly polarized light or left circularly polarized light.

The second electrode is patterned on the substrate to have a stripe shape, and if no power is supplied to the first and second electrodes, the image display device displays a two-dimensional image. In this case, the liquid crystal layer has a phase difference of 275 nm, and serves to emit incident right circularly polarized light into left circularly polarized light.

When power is supplied to the first and second electrodes, the image display device displays a 3D stereoscopic image, and the second liquid crystal panel serves as a parallax barrier. In this case, a portion of the liquid crystal layer corresponding to the second electrode transmits the incident light without any phase difference change, and a portion of the liquid crystal layer that does not correspond to the second electrode transmits the phase difference of the incident light by 180 degrees. Perform. In addition, a portion corresponding to the second electrode serves as a barrier of a parallax barrier, and a portion corresponding to the second electrode does not correspond to a slit of a parallax barrier. The image display apparatus displays a three-dimensional stereoscopic image by performing a role of slit.

In addition, the retardation plate has a phase difference of λ / 4 to convert the incident circularly polarized light into linearly polarized light, and the light reflected by the first and second cholesteric liquid crystal layers is recycled by interaction with the reflecting plate. And enter the first liquid crystal panel.                     

The present invention has the configuration as described above, with reference to the drawings will be described a preferred embodiment according to the present invention.

The present invention provides a liquid crystal display device that enables two-dimensional and three-dimensional image display, wherein the first liquid crystal panel (image LCD panel) for implementing an image and the switchable to enable two-dimensional and three-dimensional image display A second liquid crystal panel is formed and a cholesteric liquid crystal layer is formed in the second liquid crystal panel. Hereinafter, a configuration of an image display apparatus using a liquid crystal panel according to the present invention will be described with reference to FIG. 5.

5 is a schematic cross-sectional view of an image display apparatus using a liquid crystal panel according to the present invention. As shown, the 2-D / 3-D convertible image display apparatus according to the present invention includes a first image LCD panel 150 and 2-D / 3-D which largely implement an image. And a second switching LCD panel 160 to convert the light into a backlight unit 170 and a backlight unit 170 to emit light. The first liquid crystal panel implements an image using a substrate composed of a top and bottom plates and a liquid crystal filled therebetween, and implements the left eye and the right eye of the observer 180 when the image is implemented in 3-D, respectively. It has a pixel for pixels and a right eye. The first polarizing plate P1 and the second polarizing plate P2 are positioned outside the upper and lower substrates of the first liquid crystal panel, respectively.

The second liquid crystal panel 160 is positioned below the second polarizing plate P2, and the third polarizing plate P3 is positioned above the second liquid crystal panel 160. The second liquid crystal panel converts the image display device of FIG. 5 to display two-dimensional (2-D) and three-dimensional (3-D) images. That is, in 3-D display, a parallax barrier is formed to allow different images to be delivered to the left and right sides of the observer 180 so that a virtual three-dimensional stereoscopic image is realized. When the display is performed, all the light from the backlight unit 170 is passed without forming a parallax barrier so that the same image image is transmitted to the left and right sides of the observer to implement a 2D image.

A backlight unit 170 is formed below the second liquid crystal panel to form artificial light. The light emitted from the backlight unit 170 is directed toward the first and second liquid crystal panels. In this case, the polarization directions of the second polarizing plate P2 and the third polarizing plate P3 coincide with each other, and one of the second and third polarizing plates P2 and P3 may be omitted.

In the image display apparatus using the liquid crystal panel illustrated in FIG. 5, it is a second liquid crystal display apparatus (or a switching LCD panel) that enables 2-D / 3-D conversion. The configuration is described in detail in FIGS. 6 and 7.

FIG. 6 is a cross-sectional view schematically illustrating that the second liquid crystal panel of FIG. 5 is driven to display a two-dimensional (2-D) image.

As shown in FIG. 6, the switching liquid crystal panel 160 includes an upper substrate 161 and a lower substrate 162, and includes a liquid crystal layer 163 including liquid crystal therebetween. A backlight unit 170 is disposed below the lower substrate 162 including a light source 170a for emitting light and a reflecting plate 170b for reflecting light toward the substrate.                     

The first electrode 164 made of a transparent conductive material is formed on the upper portion of the lower substrate 162 facing the liquid crystal layer 163, and only the left circularly polarized light is reflected on the lower portion of the lower substrate 162 opposite to the right side of the lower substrate 162. The first cholesteric liquid crystal layer 166 is formed to pass through. Here, the phase difference Δnd of the liquid crystal layer 163 has 275 nm, and serves to convert right circularly polarized light transmitted by the first cholesteric liquid crystal layer 166 into left circularly polarized light.

A second electrode 165 formed of a transparent conductive material is formed below the upper substrate 161. As shown in FIG. 8, the second electrode 165 is formed under the upper substrate in the form of a stripe, so that a barrier-shaped barrier and a slits can be formed when a 3D image is realized. It plays a role. A second cholesteric liquid crystal layer 167 is formed on the upper substrate 161 to reflect right circularly polarized light and transmit left circularly polarized light. In addition, a phase difference plate 169 is formed on the first cholesteric liquid crystal layer to convert left circularly polarized light transmitted by the first cholesteric liquid crystal layer 167 into linearly polarized light. The retardation plate 169 has a phase difference Δnd equal to λ / 4 and serves to convert circularly polarized light into linearly polarized light.

In addition, a polarizing plate 190 that transmits linearly polarized light converted by the retardation plate 169 is formed on the retardation plate 169.

In the liquid crystal display device 160 shown in FIG. 6, no liquid field is applied to the liquid crystal layer 163, and the liquid crystal converts the right circularly polarized light to the left circularly polarized light as described above. Therefore, the switching liquid crystal display 160 does not form any barrier or slit, and the light emitted from the backlight unit 170 is passed through the polarizer 190 as it is and the first liquid crystal panel 150 (see FIG. 5). ), The viewer can see a two-dimensional (2-D) image.

In addition, in the switching liquid crystal display device 160 having the above structure, the first cholesteric liquid crystal layer 166 may be formed to reflect right circularly polarized light instead of left circularly polarized light, in which case the second cholesteric liquid crystal layer 167 is designed to reflect left circularly polarized light. Therefore, the same result as described above can be obtained.

FIG. 7 is a cross-sectional view schematically illustrating that the second liquid crystal panel of FIG. 5 is driven to display a three-dimensional (3-D) image.

Since the liquid crystal panel shown in FIG. 7 is the same as the liquid crystal panel shown in FIG. 6, detailed description thereof will be omitted. In order to display a three-dimensional (3-D) stereoscopic image, a voltage is applied to the first and second electrodes 164 and 165 and an ON-state is applied to the liquid crystal. In this case, the phase difference of the liquid crystal 163a positioned between the first electrode 164 and the second electrode 165 is changed, and passes right circularly polarized light transmitted by the first cholesteric liquid crystal layer 166 without any phase change. Let's go. The right circularly polarized light thus passed is reflected by the second cholesteric liquid crystal layer 167 and reaches the reflecting plate 170b of the backlight unit 170 to be recycled.

At this time, the liquid crystal 163b where the second electrode 165 is not positioned has a phase difference Δnd of 275 nm as described with reference to FIG. 6.                     

Therefore, in the driving state illustrated in FIG. 7, the portion Dark corresponding to the second electrode does not pass light and acts as a barrier in the form of a stripe. In addition, the portion where the second electrode is not formed serves as a slit for transmitting light, thereby forming a parallax barrier having a shape as shown in FIG. 8.

As described above, when the switching liquid crystal panel 160 forms a parallax barrier, the image display device of FIG. 5 may display a 3D virtual stereoscopic image.

The recycling of light by the second liquid crystal panel of the image display apparatus shown in FIGS. 6 and 7 will be described in detail with reference to FIGS. 9 and 10.

FIG. 9 is a schematic cross-sectional view showing the progress of light passing through each component constituting the second liquid crystal panel when the image display apparatus according to the present invention displays a two-dimensional (2-D) image.

As shown, the light 200 emitted from the backlight unit 170 of FIG. 6 transmits only the light 210R circularly polarized by the first cholesteric liquid crystal layer 166 and the left circularly polarized light 200L It is reflected toward the reflecting plate 170b of the backlight unit. The left circularly polarized light 210L reflected by the first cholesteric liquid crystal layer 166 is reflected by the reflecting plate 170b and directed to the upper first cholesteric liquid crystal layer 166, whereby the reflecting plate 170b The reflected light is converted into the right circularly polarized light 200R by the mirror effect. The reflected right circularly polarized light 200R passes through the first cholesteric liquid crystal layer 166 and is directed toward the lower substrate 162. The right circularly polarized light 210R passing through the first cholesteric liquid crystal layer 166 passes through the lower substrate 162 and the first electrode 164 without any phase change and enters the liquid crystal layer 163. In the 2-D mode, since no electric field is applied to the liquid crystal layer 163, the liquid crystal changes the phase difference of incident light by 180 degrees.

As described above, since the phase difference Δnd of the liquid crystal layer 163 is 275 nm, the incident right circularly polarized light 210R is turned into the left circularly polarized light 230L and is emitted, and the second electrode 165 and the upper substrate are transparent without any phase change. Pass 161. In addition, since the second cholesteric liquid crystal layer 167 reflects the right circularly polarized light and passes the left circularly polarized light, the incident left circularly polarized light 230L passes through the second cholesteric liquid crystal layer 167 without any phase change. . The left circularly polarized light 230L passing through the second cholesteric liquid crystal layer 167 passes through the retardation plate 169 having a phase difference of λ / 4, and is changed into linearly polarized light 240LP, and the linearly polarized light 240LP finally becomes a polarizing plate ( 190).

The light passing through the above path is incident on the first liquid crystal panel 150 of FIG. 5 and enables the image display device according to the present invention to implement 2-D image. The second liquid crystal panel 160 according to the present invention is capable of recycling light by utilizing a cholesteric liquid crystal layer, and has an advantage of obtaining high luminance even in a 2-D mode.

FIG. 10 is a schematic cross-sectional view showing the progress of light passing through each component constituting the second liquid crystal panel when the image display apparatus according to the present invention displays a three-dimensional (3-D) image. As shown in FIG. 10, the light emitted from the backlight unit 170 in FIG. 7 passes through two paths, and the polarization state of the light in these two paths and the path thereof will be described.

When an electric field is applied to the liquid crystal layer 163 by using the first electrode 164 and the second electrode 165, the liquid crystal 163a positioned at the portion corresponding to the second electrode 165 may have a phase difference. Will change. That is, the liquid crystal layer 163 is divided into a first region 163a having a changed phase difference and a second region 163b having a phase difference as it is. In the first region 163a of the liquid crystal layer 163, incident light is transmitted as it is without any phase change, and light incident on the second region 163b is changed in phase by 180 degrees. Changes to left circularly polarized light and exits. As described above, the light incident on the second region 163b is indicated by reference numeral 200 as in the 2-D mode of FIG. 9, and the light incident on the first region 163a is indicated by reference numeral 300. Each phase change and progress path will be described. First, light incident on the second region 163b showing a progress path as in the 2-D mode of FIG. 9 will be described first.

As illustrated in FIG. 10, the light 200 that exits the backlight unit and travels toward the second region 163b of the liquid crystal layer 163 passes through the first cholesteric liquid crystal only in the portion in which the right circularly polarized light 210R is passed. The left circularly polarized light 200L is reflected to be incident on the reflector plate 170b of the backlight unit 170 of FIG. 7. The left circularly polarized light 200L incident on the reflector plate 170b is changed into the right circularly polarized light 200R by a mirror effect, and finally passes through the first cholesteric liquid crystal layer 166. The right circularly polarized light 210R passing through the first cholesteric liquid crystal layer 166 enters the second region 163b of the liquid crystal layer 163 through the lower substrate 162 and the transparent first electrode 164. The light emitted through the second region 163b is changed in phase by the phase difference Δnd of the liquid crystal to become the left circularly polarized light 230L.

The left circularly polarized light 230L may pass through the second cholesteric liquid crystal layer 167 that passes the upper substrate 161 without any phase change and passes only the left circularly polarized light. The left circularly polarized light 230L passing through the second cholesteric liquid crystal layer 167 is incident on the retardation plate 169 and is converted into linearly polarized light 240LP. The linearly polarized light passing through the retardation plate 169 enters the first liquid crystal panel 150 of FIG. 5 after passing through the polarizer 190. Here, the second region 163b of the liquid crystal layer 163 serves as a slit in the parallax barrier, and the image display device of FIG. 5 can display a 3D stereoscopic image. Let's do it.

In addition, the light 300 which exits the backlight unit 170 of FIG. 7 and moves toward the first region 163a of the liquid crystal layer 163 may walk the following path. Among the lights 300 emitted from the backlight unit, the right circularly polarized light 310R passes through the first cholesteric liquid crystal layer 166 and passes through the lower substrate 166 and the transparent first electrode 164 to form the first liquid crystal layer 1630. The left circularly polarized light 300L of the light exiting the backlight unit is reflected by the first cholesteric liquid crystal layer 166 and again reflected by the reflector plate 170b to reflect the mirror effect. (mirror effect) changes to the right circularly polarized light 300R, passes through the first colgesteric liquid crystal layer 166 and passes through the lower substrate 162 and the second electrode 164 to form the first region of the liquid crystal layer 163. It enters 163a.

In this case, the first region 163a of the liquid crystal layer 163 is changed in phase difference by an electric field applied by the first and second electrodes 164 and 165, and thus the second polarized light 310R is incident. Unlike the region 163b, it passes without any phase change. The right circularly polarized light 310R having passed through the first region 163a of the liquid crystal layer 163 passes through the second electrode 165 and the upper substrate 161 and reaches the second cholesteric liquid crystal layer 167. do.

Since the second cholesteric liquid crystal layer 167 passes the left circularly polarized light and reflects the right circularly polarized light, the arrived right circularly polarized light 310R is reflected. The right circularly polarized light 320R reflected by the second cholesteric liquid crystal layer 167 passes through the lower components of the second cholesteric liquid crystal layer 167 and reaches the reflecting plate 170b.

The right circularly polarized light 320R reaching the reflecting plate 170b is reflected to become the left circularly polarized light 320L, and is reflected by the first cholesteric liquid crystal layer 166 again. The left circularly polarized light 330L reflected by the first cholesteric liquid crystal layer 166 is reflected back by the reflecting plate 170b to be turned into the right circularly polarized light 330R, and the right circularly polarized light 330R is the first cholesteric. The liquid crystal layer 166 passes through the lower substrate 162 and the first electrode 164 to reach the second region 163b of the liquid crystal layer 163. Since no electric field is applied to the second region 163b of the liquid crystal layer 163, it serves to change the incident right circularly polarized light 330R into the left circularly polarized light 340L. The left circularly polarized light 340L passing through the second region 163b of the liquid crystal layer 163 passes through the upper substrate 161 as in the left circularly polarized light 230L described above, and passes only the left circularly polarized light. The retarder plate 169 passes through the liquid crystal layer 167.

The left circularly polarized light 340L reaching the retardation plate 169 is changed into the linearly polarized light 350LP after the retardation plate 169 and passes through the polarizing plate 190 to display the first liquid crystal panel of the image display device according to the present invention. 5, 150). That is, the light reflected by the second cholesteric liquid crystal layer 167 is recycled, and the light reflected by the first cholesteric liquid crystal layer 166 is also recycled.

As can be seen from the light path as described above, when power is supplied to the first electrode 164 and the second electrode 165, the liquid crystal layer 163 passes through the light without any phase difference and the first region 163a and the light. It is divided into a second region 163b that applies a 180 degree phase difference to the. When the image display device of the present invention is driven in the 3-D mode, the first region 163a serves as a barrier of the parallax barrier and the second region 163b. Will play the role of a slit. Further, in the present invention, even though light passing through the first region 163a serving as a barrier is blocked by the cholesteric liquid crystal layer, the properties of the cholesteric liquid crystal and the backlight unit By recycling by using a reflector, the image display device can display an image without deterioration of luminance even in a 3-D mode.

In addition, as described above, in the switching liquid crystal display device 160 having the above structure, the first cholesteric liquid crystal layer 166 may be formed to reflect right circularly polarized light instead of left circularly polarized light. The steric liquid crystal layer 167 is designed to reflect left circularly polarized light. Therefore, the same result as described above can be obtained.

In other words, while a barrier of a conventional parallax barrier blocks light by absorbing light, in the present invention, a barrier is formed by utilizing a cholesteric liquid crystal. Not only can the light incident on the barrier be recycled, so there is little difference in luminance in 2-D and 3-D. According to the present invention, the light emitted from the backlight unit is ideally available 100%.

As described above, the image display apparatus according to the present invention includes a first liquid crystal panel for implementing an image and a second liquid crystal panel for switching to 2-D / 3-D. Although the second liquid crystal panel serves as a parallax barrier, the second liquid crystal panel includes first and second cholesteric liquid crystal layers and is blocked by a barrier of the parallax barrier. It is possible to recycle the light.

Therefore, the image display device according to the present invention can display an image without decreasing the luminance not only in the 2-D mode but also in the 3-D mode. That is, the 2-D / 3-D switchable image display device can display a 3D image without reducing the luminance.

Claims (15)

In an image display device including a first liquid crystal panel and a second liquid crystal panel and a backlight unit below the first liquid crystal panel, the second liquid crystal panel includes: An upper substrate; A lower substrate spaced apart from the upper substrate by a predetermined distance; A first electrode formed on an upper portion of the lower substrate; A first cholesteric liquid crystal layer formed under the lower substrate; A second electrode formed under the upper substrate; A second cholesteric liquid crystal layer formed on the upper substrate; A retardation plate formed on the second cholesteric liquid crystal layer; A polarizing plate formed on the retardation plate; It includes a liquid crystal layer configured between the upper and lower substrates, The backlight unit has a reflector Video display device comprising. The method of claim 1, The backlight unit further comprises a light source for emitting light. The method of claim 1, An image display device that enables the implementation of two-dimensional and three-dimensional displays by switching the second liquid crystal panel. The method of claim 1, The first liquid crystal display device includes two substrates, a liquid crystal filled between them, and an image display device including polarizing plates at outer portions of the two substrates, respectively. The method of claim 1, And the first cholesteric liquid crystal layer reflects only the first circularly polarized light. The method of claim 5, wherein And the second cholesteric liquid crystal layer reflects only the second circularly polarized light orthogonal to the first circularly polarized light. The method of claim 1, And the second electrode is patterned on the substrate to have a stripe shape. According to claim 7, And a two-dimensional image display when no power is supplied to the first and second electrodes. The method of claim 8, And the liquid crystal layer has a phase difference of 275 nm, and converts the incident first circularly polarized light into a second circularly polarized light which is orthogonal to the first circularly polarized light. The method of claim 7, wherein And a 3D stereoscopic image when power is supplied to the first and second electrodes. The method of claim 10, And a second liquid crystal panel acting as a parallax barrier when power is supplied to the first and second electrodes. The method of claim 11, And a portion of the liquid crystal layer corresponding to the second electrode transmits the incident light without any phase difference change, and a portion of the liquid crystal layer that does not correspond to the second electrode changes the phase difference of the incident light by 180 degrees. The method of claim 12, The portion corresponding to the second electrode serves as a barrier of a parallax barrier, and the portion not corresponding to the second electrode has a slit of a parallax barrier. Image display device for displaying a three-dimensional stereoscopic image by performing the role of. The method of claim 1, And the phase difference plate has a phase difference of? / 4, and converts incident circularly polarized light into linearly polarized light. The method of claim 1, And the light reflected by the first and second cholesteric liquid crystal layers is recycled by interaction with the reflecting plate and reenters the first liquid crystal panel.

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