KR20060076609A - Stereoscopic 3-d display apparatus - Google Patents

Abstract

The present invention comprises a main liquid crystal panel for displaying a planar image; A backlight emitting light from a rear surface of the main liquid crystal panel; Interposed between the main liquid crystal panel and the backlight to transmit the light of the backlight over the entire surface during 2D image display, and a blocking region for blocking the light of the backlight and a transmission region for transmitting the light of the backlight in 3D image display A parallax barrier liquid crystal panel alternately appearing in a form; A first reflective polarizing film interposed between the backlight and the parallax barrier liquid crystal panel; Provided is a stereoscopic image display device including a second reflective polarizing film interposed between the parallax barrier liquid crystal panel and the main liquid crystal panel.

As a result, it is possible to circulate and reproduce the light reflected by the first and second reflective polarizing films, which greatly increases the luminance.

Description

Stereoscopic 3-D display apparatus             

1 is a cross-sectional view of a conventional parallax barrier type stereoscopic image display device.

2A and 2B are cross-sectional views of operation modes of a typical stereoscopic image display device, respectively.

3 is a cross-sectional view of another general stereoscopic image display device.

4 is a plan view of a 3D implementation image of a typical stereoscopic image display device.

5 is a cross-sectional view of a stereoscopic image display device according to the present invention.

6 is an exploded perspective view of a main liquid crystal panel of a stereoscopic image display device according to the present invention;

Figure 7 is a schematic diagram showing the polarization state of the three-dimensional image display device according to the present invention.

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

100: main liquid crystal panel 110: first substrate

130: first liquid crystal layer 140: second substrate

150: parallax barrier liquid crystal panel 160: third substrate

162: barrier electrode 170: fourth substrate

172: second common electrode 180: second liquid crystal layer

192,194: first and second reflective polarizing film                 

196: polarizer

The present invention relates to a stereoscopic display device (Stereoscopic 3-D Display Apparatus), in more detail, the conversion of the 2D (2Dimension) mode for displaying a planar image and the 3D (3Dimension) mode for displaying a stereoscopic image is free and At the same time, the present invention relates to a stereoscopic image display device having a parallax barrier liquid crystal display panel capable of greatly improving luminance in each of these modes.

Based on the high speed of information built on today's high-speed information network, it has evolved from simply 'listening and talking communication' to the present 'looking and listening multimedia communication' like the telephone of the past. Enjoying 3D stereo communication.

In general, three-dimensional image representing three-dimensional image is based on the principle of stereo vision through two eyes, binocular disparity caused by the parallax of two eyes, that is, the distance between two eyes that are about 65mm apart is the most important It can be called a factor. In other words, when the left and right eyes of the human body each see a 2D image associated with each other, when these two images are delivered to the brain through the retina, the brain fuses them together to reproduce the depth and reality of the original 3D image. It is called grasterography.                         

In this regard, a technology for displaying three-dimensional stereoscopic images on a two-dimensional screen using the above-described capability has been introduced. Specifically, a stereoscopic image display, a glasses-free stereoscopic image display, and a holographic display using special glasses are introduced. Can be mentioned.

At this time, the stereoscopic image display method by special glasses shows the disadvantage that many people can enjoy stereoscopic images but need to wear separate polarized glasses or liquid crystal shutter glasses, and cause inconvenience and unnaturalness because the observer must wear special glasses. do. On the other hand, the autostereoscopic 3D display method is preferred because it has a fixed observation range and is limited to a small number of people, because no extra glasses are required and the device configuration is relatively simple. In addition, the holographic display method without the influence of the viewing position realizes the most perfect 3D stereoscopic image, but there are disadvantages in terms of technical difficulties due to requiring a separate laser reference light and an increase in the charge area of the equipment.

As a result, the parallax barrier type stereoscopic image display device, which is a method of realizing three-dimensional images by separately displaying stereo images for left and right eyes, is mainly used. By superimposing the slit-shaped openings arranged in the vertical or horizontal direction on the planar image on which the information is displayed, a stereoscopic feeling is caused by inducing stereographers of the observer.

To this end, a main display device for displaying a planar image and a separate parallax barrier forming a slit-shaped opening are required. FIG. 1 is a schematic cross-sectional view showing a conventional parallax type stereoscopic image display device. In this case, a liquid crystal panel (liquid crystal display panel) 10 is used.

In this case, the liquid crystal panel 10 is alternately formed with a left eye pixel L for displaying left eye image information and a right eye pixel R for displaying right eye image information, and a backlight for supplying light to the rear thereof. 20) is provided. In addition, a parallax barrier 30 is disposed between the liquid crystal panel 10 and the observer 40 or between the liquid crystal panel 10 and the backlight 20 to transmit and block light for each position. Slits 32 and barriers 34 that selectively pass and block light from pixels L and R, respectively, are alternately present in the form of stripes.

Therefore, the light L1 passing through the left eye pixel L of the liquid crystal panel 10 among the light emitted from the backlight 20 passes through the slit 32 of the parallax barrier 30 to the left eye of the observer 40. When the light R1 passes through the right eye pixel R of the liquid crystal panel 10, the light R1 reaches the right eye of the observer 40 through the slit 32 of the parallax barrier 30. In addition, there is sufficient disparity information enough to be detected by humans in the image displayed through the pixels for each of the left and right eyes, so that the observer 40 recognizes the 3D stereoscopic image.

On the other hand, the above description is the most basic parallax barrier method, as the slit 32 and the barrier 34 is permanently divided using the parallax barrier 30 is a disadvantage that the use range is limited to 3D only. have. However, if you watch the image converted to 3D for a long time using stereography according to binocular disparity, side effects such as nausea and fatigue may be accompanied, so 2D mode and 3D image display a flat image to cope with this A stereoscopic image display device that can freely switch between 3D modes has been introduced.

This is simply using a separate liquid crystal panel as a parallax barrier. Such a parallax barrier liquid crystal panel does not work in 2D mode but transmits light across the entire surface, but in 3D mode, it acts as a slit. The transmission area and the blocking area that acts as a barrier that blocks light are divided into stripes.

2A and 2B are schematic cross-sectional views of a stereoscopic image display device having a general parallax barrier liquid crystal panel, and show a case of a 2D mode and a 3D mode, respectively.

As can be seen, a stereoscopic image display apparatus using a general parallax barrier liquid crystal panel basically includes a backlight 50 and a main liquid crystal panel 60 displaying a flat image by using light emitted therefrom, and between them. A separate parallax barrier liquid crystal panel 70 is interposed.

In this case, the main liquid crystal panel 60 includes a pair of transparent first and second substrates 64 and 66 bonded to each other with the first liquid crystal layer 62 interposed therebetween, like a general active matrix liquid crystal panel. Although not clearly shown in the figure, a plurality of pixels are vertically and horizontally arranged between both substrates 64 and 66. Each pixel includes a transparent pixel electrode of the first substrate 64 and a transparent first common electrode of the second substrate 66 that face each other with a liquid crystal interposed therebetween. The image signal voltage is selectively applied by a thin film transistor (TFT). As an example corresponding to each pixel, the second substrate 66 includes an RGB color filter and a black matrix that fills a gap therebetween. Located.

Therefore, when the image signal voltage is applied to the pixel electrode of the pixel selected by the switching operation of the thin film transistor, a voltage difference is generated between the pixel electrode and the first common electrode. As a result, liquid crystal molecules having optical anisotropy and polarization are driven to transmit the transmittance. As the light of the backlight 50 passes through the main liquid crystal panel 60, various various planar color images are displayed by the difference in transmittance for each pixel P and the color tone sum of the RGB color filter.

In addition, the parallax barrier liquid crystal panel 70 includes transparent third and fourth substrates 74 and 78 facing each other with the second liquid crystal layer 72 interposed therebetween, but unlike the main liquid crystal panel 60 described above. A transparent stripe electrode 76 having a simple stripe shape is formed on the inner surface of the third substrate 74 without the pixel division, and the transparent second common electrode 80 is provided on the inner surface of the fourth substrate 78. In this case, the liquid crystal driving voltage is applied to the barrier electrode 76 only in the 3D mode under the premise that the second liquid crystal layer 72 is a twisted nematic (TN) aggregate. In addition, such a stereoscopic image display device may include, for example, an outer surface of the second substrate 78 of the main liquid crystal panel 60, between the main liquid crystal panel 60 and the parallax liquid crystal panel 70, and the parallax barrier liquid crystal panel 70. First to third polarizing plates 82, 84, and 86 are attached to the rear surface of the third substrate 74, respectively.

Accordingly, the stereoscopic image display device including the parallax barrier liquid crystal panel 70 having the above-described configuration has a front surface thereof in the 2D mode of FIG. 2A in which no voltage is applied to the barrier electrode 76 of the parallax barrier liquid crystal panel 70. By maintaining the normal white state over the light simply transmitted through the backlight 50, as a result, the viewer can see the planar image of the main liquid crystal panel 60.

On the other hand, in the 3D mode of FIG. 2B in which the liquid crystal driving voltage is applied to the barrier electrode 76, only the liquid crystal between the barrier electrode 76 and the second common electrode 80 is driven to block the light by displaying the black portion. Barrier-zone (hereinafter referred to as B-zone (B)), and a portion between them is a transparent zone for transmitting light by displaying white (hereinafter, simply T-zone (T)) Is called). As a result, the B-zone B and the T-zone T act as barriers and slits, respectively, so that an observer can recognize an image of the main liquid crystal panel 60 in three dimensions.

Accordingly, the 2D and 3D modes can be switched by the on / off operation of the parallax barrier liquid crystal panel 70 and strictly the barrier electrode 76.

Meanwhile, another type of parallax barrier liquid crystal panel having similar but differentiation in detail has been introduced. The cross-sectional structure thereof is shown in FIG. 3, and has the same role as that described in FIGS. 2A and 2B. The same reference numerals are given to the same elements.

As can be seen, another general three-dimensional image display device having the main liquid crystal panel 60 and the backlight 50 is the same, and the parallax barrier liquid crystal panel 70 is interposed therebetween. However, in this case, a partition wall made of a transparent polymer material, for example, photo acryl, is formed between the third and fourth substrates 74 and 78 of the parallax barrier liquid crystal panel 70 so as to correspond to the T-zone T. Since 90 is located, the liquid crystal is not present in the T-zone (T), and the liquid crystal is formed only in the B-zone (B) which is a space between the partitions 90.

And as before, the barrier electrode 76 is positioned on the inner surface of the third substrate 74 corresponding to the B-zone B, and the second common electrode 80 is provided on the inner surface of the fourth substrate 78 facing the barrier electrode 76. have. Accordingly, the 2D and 3D modes can be selectively displayed by turning the barrier electrode 76 on and off, and the boundary between the T-zone T and the B-zone B is clearly distinguished.

However, the above-described stereoscopic image display apparatus using the parallax barrier liquid crystal panel exhibits some disadvantages, one of which is a phenomenon in which the luminance suddenly decreases particularly in the 3D mode.

That is, in the 3D mode, the light of the backlight 50 passes through the parallax barrier liquid crystal panel 70 in which the T-zone T and the B-zone B are formed in a stripe shape, and the luminance is substantially reduced. Subsequently, secondary luminance decreases while passing through the main liquid crystal panel 60. In general, the light transmittance of the main liquid crystal panel 60 except for the parallax barrier liquid crystal panel 70 stays at only 2 to 8%. In view of the fact that the parallax barrier liquid crystal panel 70 is included, the lowering of the luminance appears even more. As an example, referring to FIG. 4 which shows a part of an image implemented from the main liquid crystal panel 60 in the 3D mode, it can be seen that the area of the T-zone T where the actual image is externally expressed is very narrow compared to the total area. Therefore, the stereoscopic image display device using the general parallax barrier liquid crystal panel 70 exhibits a very low overall luminance characteristic.

In addition, the width of the T-zone (T) and B-zone (B) of the parallax barrier liquid crystal panel 70 depends on the viewing distance of the observer according to each use, but the space in which the observer can recognize stereoscopic images. In order to enlarge the area, a method of reflecting the left and right eye images multiplely at a distance of at least two or more in the main liquid crystal panel 60 is used. In this case, the width of the T-zone (T) tends to be further reduced. There is a disadvantage in that the decrease in luminance is intensified.

Accordingly, the present invention has been made to solve the above problems, in the stereoscopic image display apparatus using a free parallax barrier liquid crystal panel of 2D mode for displaying planar images and 3D mode for displaying stereoscopic images, in particular, 3D mode The purpose of the present invention is to provide a more improved stereoscopic image display device by presenting a concrete way to greatly improve the brightness.

In order to achieve the above object, the present invention includes a main liquid crystal panel for displaying a flat image; A backlight emitting light from a rear surface of the main liquid crystal panel; Interposed between the main liquid crystal panel and the backlight to transmit the light of the backlight over the entire surface during 2D image display, and a blocking region for blocking the light of the backlight and a transmission region for transmitting the light of the backlight in 3D image display A parallax barrier liquid crystal panel alternately appearing in a form; A first reflective polarizing film interposed between the backlight and the parallax barrier liquid crystal panel; Provided is a stereoscopic image display device including a second reflective polarizing film interposed between the parallax barrier liquid crystal panel and the main liquid crystal panel.

At this time, the main liquid crystal panel, the first transparent substrate on the backlight side; Gate and data lines arranged on one surface of the first transparent substrate to define pixels; A thin film transistor provided at an intersection point of the gate and the data line; A transparent pixel electrode mounted on the pixel and connected one-to-one with the thin film transistor; A second transparent substrate facing the one surface of the first transparent substrate; A black matrix defining an opening corresponding to the pixel electrode on an inner surface of the second transparent substrate; An RGB color filter filled in the opening; A transparent first common electrode covering the black matrix and the RGB color filter; And a first liquid crystal layer interposed between the first and second transparent substrates.

In addition, the parallax barrier liquid crystal panel, the third transparent substrate; A transparent barrier electrode arranged in a stripe shape on one surface of the third transparent substrate to correspond to the blocking region; A fourth transparent substrate facing the one surface of the third transparent substrate; A transparent second common electrode formed on an inner surface of the fourth transparent substrate; And a second liquid crystal layer interposed between the third and fourth transparent substrates.

The first and second liquid crystal layers are twisted nematic assemblies, and the first and second reflective polarizing films have polarization axes perpendicular to each other. In this case, the polarizing plate interposed on the outer surface of the main liquid crystal panel is used. The first reflective polarizing film and the polarizing plate may further include polarization axes parallel to each other.

In this case, the first and second reflective polarizing films transmit light parallel to each polarization direction and reflect the rest except for the above, and the backlight includes a plurality of optical sheets. The light reflected by the polarizing film is re-reflected by the plurality of optical sheets, and the light parallel to the polarization direction of the first reflective polarizing film is reproduced to transmit the first reflective polarizing film, and the second The light reflected by the reflective polarizing film is re-reflected by the first reflective polarizing film and the plurality of optical sheets, so that light parallel to the polarization direction of the second reflective polarizing film is reproduced so that the second reflective type It is characterized by transmitting the polarizing film.

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

5 is a cross-sectional view of a stereoscopic image display device according to an embodiment of the present invention, which includes a main liquid crystal panel 100 displaying a planar image, a parallax barrier liquid crystal panel 150 provided at a rear thereof, and the parallax barrier liquid crystal panel. And a backlight 200 for supplying light from the back of 150. In this case, the parallax barrier liquid crystal panel 150 may be located between the user and the main liquid crystal panel 100, that is, in front of the main liquid crystal panel 100 as necessary.

In this case, the main liquid crystal panel 100 may have the same structure as a general active matrix liquid crystal panel used in a notebook computer, a TV, or various display devices, and a detailed exploded perspective view of the example is illustrated in FIG. 6.

As can be seen, the main liquid crystal panel of the stereoscopic image display device according to the present invention includes first and second substrates 110 and 140 bonded to each other with the first liquid crystal layer 130 interposed therebetween.

The first substrate 110 is also commonly referred to as a lower substrate or an array substrate. A plurality of gate wirings 114 and data wirings 116 intersect with the inner surface of the first substrate 110, such as glass, and have a matrix shape. The pixel P is repeatedly defined vertically and horizontally, and the thin film transistor 120 is provided at the intersection point of the gate line 114 and the data line 116 with the transparent pixel electrode 122 mounted on each pixel P. One-to-one correspondence is connected.

The second substrate 140 facing the same is commonly referred to as an upper substrate or a color filter substrate, and has gates and data wirings 114 and 116 of the first substrate 110 to the inner surface of the transparent second substrate 140 such as glass. In addition, the black matrix 146 defining the openings which are repeated in a lattice shape so as to expose only the pixel electrodes 122 by covering portions not directly related to the liquid crystal driving such as the thin film transistor 120 and the like, filled in the openings. As an example, R, G, and B color filters 144a, 144b, and 144c, and transparent first common electrodes 148 covering them are provided. Although not clearly shown in the drawings, an alignment layer for determining the alignment direction of the liquid crystal molecules is interposed on the inner surfaces of the first and second substrates 110 and 140 in contact with the first liquid crystal layer 130.

Therefore, the main liquid crystal panel 100 having the above-described structure controls the arrangement direction of the liquid crystal molecules by the vertical electric field generated by the artificial voltage difference between the pixel electrode 122 and the first common electrode 148, and thus the transmittance difference. The light emitted from the backlight 200 of FIG. 5 reflects the difference in transmittance for each pixel P and the color combination of the R, G, and B color filters 144a, 144b, and 144c. Displays a color plane image.

Returning to FIG. 5 again, the Parallax barrier liquid crystal panel 150 converts the planar image of the main liquid crystal panel 100 into 2D or 3D mode according to a user's selection. In the 3D mode, the T-zone (T) transmitting light and the B-zone (B) blocking light alternately appear in the form of stripes.

To this end, the parallax barrier liquid crystal panel 150 includes third and fourth transparent substrates 160 and 170 bonded to each other with the second liquid crystal layer 180 interposed therebetween. The transparent barrier electrode 162 of the stripe shape is located in the B-zone (B) region, and the transparent second common electrode 172 is provided on the entire surface of the fourth transparent substrate 170 facing the B-zone (B). have. In this case, the barrier electrode 162 and the common electrode 172 are made of indium tin oxide (ITO) material which is a transparent conductive material.

Therefore, under the premise that such a parallax barrier liquid crystal panel 150 is normal white, the plane image of the main liquid crystal panel 100 is transmitted through the entire surface of the main liquid crystal panel 100 by simply transmitting the light emitted from the backlight 200 without any action in the 2D mode. To appear outside. In 3D mode, the liquid crystal driving voltage is applied to the barrier electrode 162 to drive the liquid crystal therebetween, and black is displayed in the B-zone (B), and white is displayed in the T-zone (T) therebetween. A planar image of the liquid crystal panel 100 is displayed as a stereoscopic image.

In addition, the backlight 200 employs at least one fluorescent lamp or LED emitting light as the light source 202, and the light emitted from the diffuser sheet and the prism are incident to high quality over the entire surface of the parallax barrier liquid crystal panel 150. A plurality of optical sheets 204, including sheets, and light guide plates are included depending on the purpose.

In this case, the three-dimensional image display apparatus using the parallax barrier liquid crystal panel 150 according to the present invention has a plurality of polarizing members, specifically, between the backlight 200 and the parallax barrier liquid crystal panel 150. The first reflective polarization film 192 interposed therebetween, the second reflective polarization film 194 interposed between the parallax barrier liquid crystal panel 150 and the main liquid crystal panel 100, and the main liquid crystal panel 100 interposed therebetween. Polarized plate 196 is included. In this case, when the first and second liquid crystal layers 130 and 180 are, for example, an aggregate of twisted nematic LCs having positive anisotropy in which the long axes of the liquid crystal molecules are perpendicular to the vertical electric field direction, the first reflection type polarized light The polarization axes of the film 192 and the second reflective polarizing film 194 are perpendicular to each other, and the polarization axes of the first reflective polarizing film 192 and the polarizing plate 196 are parallel to each other, resulting in the second reflective polarizing film 194. And the polarization axes of the polarizing plate 196 are perpendicular to each other.

Meanwhile, the first and second reflective polarizing films 192 and 194 are based on general technical ideas, and stretch polyvinyl alcohl (PVA) films having different refractive indices in one direction to form a multilayer thin film structure using Brewster's law. After laminating, the films are laminated so that the stretching directions coincide with each other to transmit only specific polarized light and reflect other light.

Accordingly, in the stereoscopic image display device according to the present invention, the parallax barrier liquid crystal panel 150 having the first and second reflective polarization films 192 and 194 interposed therebetween is used to improve the luminance through the reproduction cycle of light. 5 and FIG. 7 showing the polarization state of the stereoscopic image display device according to the present invention.

In this case, FIG. 7 is shown under the assumption that the first and second liquid crystal layers 130 and 180 are twisted nematic aggregates. For example, the 2D mode is not shown separately, but may be easily understood when referring to the following description of 3D. .

In this case, the light emitted from the backlight 200 in the 3D mode is not polarized and mixed in each direction polarization, and the polarization direction of the first reflective polarizing film 192 and Only an arbitrary first polarized light L1 in parallel may pass through the first reflective polarization film 192 and enter the parallax barrier liquid crystal panel 150. On the other hand, the polarization other than the first polarization L1 including the second polarization L2 in the direction perpendicular to the first polarization L1 is reflected by the first reflective polarizing film 192 and then the backlight 200. It is reflected and scattered by each of the components, and the polarization state is reorganized to include the first polarization L1 according to the property of light whose polarization state is changed when the refractive index passes through the interface of different media. The first polarized light L1 passes through the first reflective polarizing film 192.

At this time, the above-described circulation of light and realignment of polarization are repeated, and as a result, the first polarized light L1 is continuously reproduced and transmitted through the first reflective polarizing film 192 to enter the parallax barrier liquid crystal panel 150. do.

Meanwhile, since the T-zone T and the B-zone B are implemented in a stripe form in the parallax barrier liquid crystal panel 150 in the 3D mode, the first polarized light L1 passing through the double B-zone B is ) Is blocked and reflected by the second reflective polarizing film 194 having a polarization axis opposite to the polarization direction because there is no change in the polarization direction, but the first polarized light L1 passing through the T-zone T is a liquid crystal. The first polarized light L1 and the second polarized light L2 are perpendicular to the second polarized light L2 along the arrangement direction of the molecules, and are transmitted through the second reflective polarizing film 194 parallel to the polarized light. In this case, the first polarized light L1 blocked and reflected by the second reflective flat polarizing film 194 is reflected and scattered by each component of the first reflective polarizing film 192 or the backlight 200, and the polarization state is reorganized. As a result, the circulation and reproduction are repeated. As a result, the second polarized light is continuously generated and transmitted through the second reflective polarizing film 194.

As described above, the second polarized light L2 transmitted through the T-zone T and the second reflective polarizing film 194 of the parallax barrier liquid crystal panel 150 is incident to the main liquid crystal panel 100. Here, the luminance is increased because a part of the polarized light is partially reflected after being reflected and scattered by the backlight 200 including the first and second reflective polarizing films 192 and 194.

As a result, the user can enjoy stereoscopic images with greatly increased luminance.

As described above, the stereoscopic image display device according to the present invention is free to switch between the 2D (2Dimension) mode for displaying a planar image and the 3D (3Dimension) mode for displaying a stereoscopic image, and at the same time, the luminance significantly in each of these modes There is an advantage that can be improved.

Accordingly, the user can observe a three-dimensional and realistic three-dimensional image.

Claims (9)

A main liquid crystal panel displaying a planar image; A backlight emitting light from a rear surface of the main liquid crystal panel; Interposed between the main liquid crystal panel and the backlight to transmit the light of the backlight over the entire surface during 2D image display, and a blocking region for blocking the light of the backlight and a transmission region for transmitting the light of the backlight in 3D image display A parallax barrier liquid crystal panel alternately appearing in a form; A first reflective polarizing film interposed between the backlight and the parallax barrier liquid crystal panel; A second reflective polarizing film interposed between the parallax barrier liquid crystal panel and the main liquid crystal panel Stereoscopic image display device comprising a. The method of claim 1, The main liquid crystal panel includes a first transparent substrate on the backlight side; Gate and data lines arranged on one surface of the first transparent substrate to define pixels; A thin film transistor provided at an intersection point of the gate and the data line; A transparent pixel electrode mounted on the pixel and connected one-to-one with the thin film transistor; A second transparent substrate facing the one surface of the first transparent substrate; A black matrix defining an opening corresponding to the pixel electrode on an inner surface of the second transparent substrate; An RGB color filter filled in the opening; A transparent first common electrode covering the black matrix and the RGB color filter; And a first liquid crystal layer interposed between the first and second transparent substrates. The method of claim 1, The parallax barrier liquid crystal panel comprises: a third transparent substrate; A transparent barrier electrode arranged in a stripe shape on one surface of the third transparent substrate to correspond to the blocking region; A fourth transparent substrate facing the one surface of the third transparent substrate; A transparent second common electrode formed on an inner surface of the fourth transparent substrate; And a second liquid crystal layer interposed between the third and fourth transparent substrates. The method of claim 1, The first and second liquid crystal layers are twisted nematic aggregates, And the first and second reflective polarizing films have polarization axes perpendicular to each other. The method of claim 4, wherein And a polarizing plate interposed on an outer surface of the main liquid crystal panel. The method of claim 5, And a polarizing axis of the first reflective polarizing film and the polarizing plate in parallel with each other. The method of claim 4, wherein And the first and second reflective polarizing films transmit light parallel to each polarization direction and reflect the rest except for the same. The method of claim 7, wherein And the backlight includes a plurality of optical sheets. The method of claim 8, The light reflected by the first reflective polarizing film is re-reflected by the plurality of optical sheets while the light parallel to the polarization direction of the first reflective polarizing film is regenerated to pass through the first reflective polarizing film. , The light reflected by the second reflective polarizing film is re-reflected by the first reflective polarizing film and the plurality of optical sheets, so that light parallel to the polarization direction of the second reflective polarizing film is reproduced to generate the second reflective polarizing film. 2 Stereoscopic image display device that penetrates the reflective polarizing film.

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