KR20090106062A - Video display device - Google Patents

Abstract

The present invention relates to an image separation display device having a parallax barrier, the invention comprising: an image display panel on which an image is implemented; A backlight for supplying a light source to the image display panel; A parallax barrier disposed between the image display panel and a backlight to block or transmit light; And a light control layer configured on the parallax barrier and having a condensing shape for condensing light to the display panel.

According to the present invention, by changing the path of the light blocked by the blocking portion of the parallax barrier to a transmission slit, by increasing the light efficiency, there is an effect that can provide an image separation display device that can implement a breakthrough brightness.

Description

Display Separator with Image Control

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional stereoscopic image display using a parallax barrier method and an image separation display device applied to a multi-view display. Particularly, in displaying the image information displayed on the liquid crystal panel, the image separation display device which can improve light efficiency by condensing light of the light source passing through the parallax barrier to the transmission slit portion on the parallax barrier. will be.

Briefly describe the principle that people feel a three-dimensional feeling when looking at a particular object as follows. The factors in which a person feels a three-dimensional feeling through vision are very diverse and complicated, but it can be divided into physiological factors and psychological memory factors. As physiological factors, recognition factors such as accommodation, monocular motion parallax, and recognition factors by both eyes such as binocular convergence and binocular parallax There is this. On the other hand, psychological memory factors include geometric stereoscopic vision such as object size, height, superposition, and shape, and optical stereoscopic vision such as contrast, resolution, saturation, and color.

Among the above-mentioned physiological and psychological factors, physiological factors caused by both eyes such as congestion angle of binocular and parallax of both eyes are the biggest factor to make a sense of three-dimensional feeling. The present invention relates to a stereoscopic image display device based on the principle of stereoscopic vision that different stereoscopic feelings are felt.

That is, when a person sees an object using both left and right eyes, the left and right eyes are separated about 6.5 cm from each other, so there is a slight difference in the image of the object coming into the both eyes. In other words, you see a different image for each of the left and right eyes, which is called binocular parallax, and the brain synthesizes two different images received by both eyes by these binocular parallaxes, making the person feel three-dimensional and distance. do. In addition, since the left eye and the right eye are separated, the convergence angle, which is the angle between the eyes between the two eyes when the object is near, is large, and when the object is far away, the convergence angle becomes smaller. Due to the difference in angle, you can feel the three-dimensional feeling and the sense of distance. Here, the stereoscopic image display apparatus using the principle of stereoscopic vision due to binocular parallax will be described in detail as follows.

That is, by using the principle that a person can feel a three-dimensional feeling when viewing different images with both eyes, the left eye image is composed of a left eye image that the left eye feels and a right eye image that the right eye feels. In addition, if only the right eye image is continuously displayed in the right eye, the effect is the same as seeing a three-dimensional image.

As a way of viewing the stereoscopic image, there is a method of wearing glasses and a method of not wearing glasses according to whether the viewer wears glasses. The way of wearing glasses is the anaglyph method, which uses blue and red sunglasses on both eyes, the concentration difference method that feels three-dimensional by attaching filters with different transmittances to the left and right glasses, and the polarization glasses that have different polarization directions. There is a polarization glasses method and a time-division method that uses glasses with a liquid crystal shutter that is periodically repeated and synchronized with the time-divided screen. However, the method of wearing glasses has problems such as inconvenience of wearing glasses and being troubled in observing objects other than stereoscopic images in the state of wearing glasses. Therefore, in recent years, research has been actively conducted on the glasses-free method of not wearing glasses, and research and development have been progressed for various uses.

Representative examples of glasses-free methods that do not wear glasses include a lenticular method in which a lenticular lens plate in which a cylindrical lens array is arranged vertically is installed in front of the image panel, and a parallax barrier method. .

As a representative example of a stereoscopic image implementation technology for realizing a three-dimensional stereoscopic image using such binocular parallax, the parallax barrier type stereoscopic image implementation technology will be described with reference to the drawings.

Referring to FIG. 1, FIG. 1 illustrates a stereoscopic image display apparatus using a conventional parallax barrier method.

In FIG. 1, a left eye pixel L displaying an image through a pixel arrangement of a combination of R (Red) / G (Green) / B (Blue) and displaying image information for the left eye; A liquid crystal panel (LCD panel 110) having alternating right eye pixels (R) for displaying image information for the right eye, and a left eye pixel (L) and a right eye pixel located at a lower end of the liquid crystal panel (110). A parallax barrier 120 alternately formed with a light-transmitting portion formed by a transparent slit (S) through which light from (R) passes and a light-shielding portion that is a barrier blocking the light (B); Located at the bottom of the parallax barrier 120 is composed of a backlight 130, which is an artificial light source that emits light. At this time, both eyes of the observer, that is, the left eye and the right eye, are located above the liquid crystal panel 110.

In the 3D image display apparatus using the parallax barrier method having the above configuration, the light passing through the right eye pixel R of the light passing through the transparent slit S of the parallax barrier 120 is the right eye of the observer. The light passing through the left eye pixel L reaches the left eye of the observer. In this case, the barrier B of the parallax barrier 120 absorbs and blocks light so that the light formed in the backlight 130 can be distributed to the right eye pixel R and the left eye pixel L. do. As such, light passing through the left eye pixel L is transmitted only to the left eye of the observer, and light passing through the right eye pixel R is transmitted only to the right eye of the observer. Sufficient disparity information is formed between the light and the light reaching the observer's right eye, resulting in the viewer being able to feel the 3D stereoscopic image.

Meanwhile, in the stereoscopic image display system using the conventional parallax barrier method, the liquid crystal panel 110 includes a color filter substrate including a first polarization filter, a first glass substrate, a color filter, a counter electrode, and a first alignment layer; An array substrate including a second alignment layer, a pixel electrode, a thin film transistor (TFT), a second glass substrate, and a second polarizing filter is bonded to each other under a liquid crystal layer including a spacer, wherein the first and the first The second polarization filter is a filter for polarizing the light source supplied from the backlight 130, the counter electrode and the pixel electrode are driving electrodes for changing the molecular arrangement of the liquid crystal, and the first and second alignment layers have a constant molecular arrangement of the liquid crystal. It is an alignment film to arrange in a direction, a spacer is a support stand which prevents the 1st and 2nd glass substrate from bending, etc., and a color filter is an apparatus for displaying the color of RGB.

The image separation display device using the parallax barrier method has been applied to a multi-view display and a 3D stereoscopic image display.

Multi-view display devices have been designed to allow multiple users to view images at the same time, and the characteristics of such display devices may be configured to allow viewers to view the same image from different angles with respect to the display device. It can also be configured to view different images from different angles. For example, the method of displaying the same image at different angles is effective when several users need the same information, such as departure information at airports and railway stations. In addition, a method of displaying different images at different angles may be usefully used in an automobile as an example. In other words, the same display device allows the driver to view satellite navigation data and the passenger to watch a movie. An advantage to multiview displays is that users can be independent of each other's eyes. In addition, as described above, it is well known that the parallax barrier method is actively applied to a stereoscopic image display in addition to the multi-view display.

However, in the stereoscopic display apparatus using the conventional parallax barrier method, since the barrier (B) region that cannot transmit light in the parallax barrier 120 occupies about half of the entire parallax barrier 120 region, the aperture ratio This markedly falls, the light transmittance is lowered, the light efficiency is significantly lowered due to the area of the light shielding portion, and eventually the brightness is lowered.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problem, and an object of the present invention is to transmit a path of light projected onto a barrier to improve a problem of low light transmittance occurring in an image display separation apparatus employing a parallax barrier method. The present invention provides a video separation display device having a light control layer that can be changed into a slit portion and increasing light efficiency to realize a breakthrough luminance.

According to an aspect of the present invention, there is provided an image display panel including an image; a backlight for supplying a light source to the image display panel; A parallax barrier disposed between the image display panel and a backlight to block or transmit light; And a light control layer configured on the parallax barrier and having a condensing shape for condensing light to a display panel. The light control layer may be formed using a lens for condensing or an aspheric lens, thereby increasing light efficiency and improving luminance.

According to the present invention, by changing the path of the light blocked by the blocking portion in the parallax barrier to the transmission slit, and increasing the light efficiency, there is an effect that can provide an image separation display device that can realize a breakthrough brightness.

The present invention provides an image display panel on which an image is implemented; A backlight for supplying a light source to the image display panel; A parallax barrier disposed between the image display panel and a backlight to block or transmit light; And a light control layer formed on the parallax barrier and having a condensing shape for condensing light to a display panel. It is possible to maximize the light efficiency by changing the path of the light traveling to the barrier that blocks the light to the transmission slit part.

In addition, the parallax barrier can provide an image separation display device comprising a transmission slit for transmitting light and a barrier for blocking light.

In another aspect, the present invention provides an image separation display device characterized in that the light converging shape of the light control layer has a condensing shape having a curvature so as to focus the path of light blocked by the barrier to the transmission slit. It is possible to increase the brightness of the image display device.

In addition, the present invention is to provide a separate image display device, characterized in that the condensing shape is made of a lens.

In addition, the present invention can provide an image separation display device characterized in that the condensing shape is an aspherical lens, it is possible to implement the efficiency of the condensing structure.

In addition, the present invention provides an image separation display device characterized in that the condensing shape is made of a structure in which the spherical or aspherical lens is arranged uniformly or non-uniformly, so that the light control layer can be formed in various compositions, the versatility of the manufacturing method To be able to implement

In addition, the present invention is to provide a separate image display device, characterized in that the central axis of the light collecting shape is arranged to match the central axis of the transmission slit.

In addition, the present invention is to provide a video display device, characterized in that the barrier is made of a black resin.

In addition, the black resin constituting the barrier of the present invention is any one of the black component material selected from carbon black, organic pigment mixed light-shielding colorant, or hybrid color material mixed with carbon black and organic pigment mixed light-shielding colorant. It is possible to provide an image separation display device, characterized in that formed.

In addition, the black component material constituting the above-described black resin of the present invention is to provide an image separation display device characterized in that 20 to 50wt% of the total ratio of the black resin.

In addition, the barrier in the present invention is to provide an image separation display device characterized in that the inorganic material is formed by mixing the metal (oxide) -based (oxide).

Hereinafter, with reference to the accompanying drawings will be described the configuration and operation of the present invention.

Figure 2 is a schematic diagram showing a structure for condensing light through the light control layer on the parallax barrier according to the present invention.

FIG. 2A shows a barrier 22 in which the light projected from the light source L serves as a light shielding portion for blocking the light and the transmission slit 21 of the parallax barrier 20, in which the light is emitted straight from the light source. The light projected with the light passing through the light control layer 30, the light path is shown to be changed to the transmission slit 21. 2B illustrates a detailed configuration of the light control layer 30. Reference numerals in the drawings are the same as in (a), and reference numerals X1, X2, and X3 are lines passing through the central axis of the transmission slit. As will be described later, the condensing shape 34 for changing the light path is preferably aligned to coincide with this central axis. The overall schematic diagram of the parallax barrier combined with the backlight unit and the light control layer will be described with reference to FIG. 3.

As shown in FIG. 3, the present invention includes an image display panel 10 in which an image is implemented, and a backlight 40 unit for supplying a light source to the image display panel. A parallax barrier 30 is provided between the image display panel and the backlight unit to block or transmit light, and a light control layer 30 is provided below the barrier beam to condense light.

The parallax barrier is arranged to cross the transmission slit 22 and the barrier 22, the transmission slit is a portion through which light is transmitted, and the barrier acts as a portion through which light is blocked, thereby implementing the above-described stereoscopic image. This is the part that makes it possible.

In particular, the barrier may be formed of a black resin. The black resin is basically composed of a base material, a surface active material, and a black component material. Among these, the black powder material is formed by using carbon black or an organic pigment mixed light-shielding colorant, or carbon black and an organic pigment. It can form using the hybrid type coloring material which mixed the mixed light-shielding colorant. In this case, it is preferable to form the carbon black, the organic pigment, or the hybrid type coloring material mixed with both containing 20 to 50 wt% of the total barrier. In addition, the base material may be a UV resin (polymer resin), and a surfactant may be a silicon-based or fluorene (fluorine-based) material.

In addition, the barrier may be formed by mixing an inorganic material with a metal or oxide based metal as another example.

The light control layer 30 is formed under the parallax barrier, and has a structure in which a predetermined condensing shape 34 is implemented on a transparent substrate. The condensing shape may be basically formed directly on the transparent substrate, but is preferably implemented on the basic base films 32 and 33. The base film may be any film having a structure that does not inhibit the transmission of light.

In particular, the condensing shape 34 preferably has a curvature capable of condensing light of a convex structure, and the curvature may be adjusted to change the path of light to the transmission slit. In particular, such a condensing shape may be arranged regularly or irregularly using a lens, more specifically, a spherical or aspherical lens, so that the light blocked by the barrier 22 portion may be changed into the transmission slit 21. .

The condensing shape may be formed by an arrangement consisting of only spherical lenses, or may be formed of an arrangement consisting only of aspherical lenses, or may be arranged in a crosswise manner by appropriately combining spherical lenses and aspherical lenses. In addition, it is also possible to irregularly arrange the spherical lens or aspherical lens rather than such a regular arrangement.

In addition, in the arrangement of the shape, the condensing shape is basically aligned so that the central axis (X1, X2, X3) of the transmissive slit coincides with the central axis of the condensing shape, basically having any of spherical or aspherical shapes. It is preferable to align.

The enhancement effect of the light efficiency according to the present invention having such a condensing shape will be described in more detail.

Basically, the parallax barrier type shows optical efficiency proportional to the area ratio. Here, the area ratio means a ratio obtained by dividing the area of the transmission slit (transmission part) by the total area (sum of the transmission part and the light shielding part). In other words,

Area ratio = area / total area of the light transmitting part

(The total area here is the sum of the area of the light transmitting part and the light blocking part.)

Differentiating the area is a function of the length of the two axes, so partial derivatives of one axis result in a ratio of lengths. therefore,

Light efficiency = length / total length of the light emitting part

(Where the total length is the sum of the length of the light-transmitting part + the length of the light-shielding part)

Becomes

In the case of calculating the light efficiency by measuring luminance using a conventional Parallax barrier sample using the BM-7A device, the area ratio of the transmission slit (transmitter) and the barrier (shield) is 1: 3 or 1: Corresponding to 4, when the area ratio is calculated by using the arithmetic calculation formula, an area ratio value of about 0.25 or 0.2 is obtained. In this case, the center luminance in the backlight only is 9,888 nit, and for the film type with parallax barrier, the center luminance of 2,428 nit is calculated. That is, the ratio of the area between the barrier and the transmission slit has an approximate relationship with the light efficiency. As the area of the barrier increases, the light efficiency decreases.

That is, the present invention adds a light control layer having a condensing shape for condensing the light according to the present invention to a display panel in a parallax barrier system in order to increase the light efficiency at a given constant ratio. To increase.

The effect of the light efficiency according to the structure of the present invention is that the final center luminance passing through the light control layer when the 9888nit in the backlight state is 8009nit can obtain about 80% light efficiency. This effect varies depending on the shape of the lens, and the optimum shape can be designed to obtain a light efficiency of at least 50% or more according to the variation of the height ratio of the lens to the length of the light blocking portion.

An example of obtaining an optimum light efficiency considering the variation of the ratio of the height of the lens to the length of the light blocking portion will be described with reference to FIG. 4A.

Figure 4a is basically set the number (A) of the light (R) incident from the backlight unit, the number (B) of the light (R) emitted after passing through the light control layer, before entering the light control layer according to the present invention Represents the light efficiency (%; B / A) of only the light control layer calculated as the number of rays (i.e., before entering the liquid crystal panel) immediately after passing through the light control layer to the number of rays (light emitted from the backlight unit). Table. (However, the number of lights shown in the table and the measurement of light efficiency accordingly are light efficiency measured by simulating the number of rays passing through the light control layer by injecting 111 light rays into the number of lights.)

As shown in the table, the portion R, which shows a significant increase in light efficiency relative to the number of constant rays passing through the backlight unit, has a low light efficiency depending on the lens shape of the light control layer having the curvature of the aspherical lens according to the present invention. It can be seen that it is increased by 50 ~ 90%.

This effect varies depending on the shape of the lens, and a higher efficiency can be realized according to the variation of the height ratio C of the lens with respect to the length of the light blocking portion.

Referring to FIGS. 4A and 4B (reference numerals are the same as those of FIG. 4), wherein the height ratio C of the lens to the length of the light blocking portion is the central axis of the barrier (light blocking portion) and the light condensing according to the present invention. Given the convex shape that is aligned to coincide with the central axis of the lens, the convex shape that extends from the end of the lens a1 through the central axis and back to the opposite end of the lens b1 is equal to the length of the light blocking portion l. ) Shows the ratio of the lens height (h1, h2 ..) to. In consideration of such a ratio, it is preferable to form the ratio C of the height of the lens to the length of the light shielding portion to have a curvature at a ratio of 12 to 22%. (In this case, it may be considered to have a lens shape, but in the case of a region coinciding with the transmissive part, to form a flat curve of the lens.)

Although it is possible to set such an arbitrary curvature, the curvature according to the ratio of the height of the lens along the length of the light shielding part can be set, but of course it is also possible to set the curvature by numerical calculation of forming the aspherical lens. For example, in constructing a lens having a condensing shape, when the lens is formed through an aspherical shape, a curve represented by an aspherical equation and aspherical coefficients may be used, and in particular, a bezier curve representing a free curve. It is also possible to form an aspheric curvature using a curve). For example, it may be considered to provide a shape having a specific aspherical curvature based on the start point a1 and the end point b1 of the lens.

A process of manufacturing a parallax barrier with a light control layer according to the present invention will be described with reference to FIG. 5.

First, a master mold is manufactured to pattern the condensing shape of the light control layer using this (S 1). In this case, the master mold is provided with a pattern to form the condensing shape, the pattern can be produced by a method such as machining or laser processing or photolithography.

Next, a condensing shape is molded on a transparent substrate or a base film. This can be formed through a stamp method, thermal transfer, UV transfer method (S 2). Subsequently, the base film on which the light-forming formation is formed is blanked to a required standard (S3), and then laminated with the substrate of the film material to form the parallax barrier (S4). Forming a pattern of a transmission slit (transmitter) and a barrier (shield) by using a lithography, screen print, stamp method on the substrate of the film material that is the layer to form the parallax barrier (S 5, S 6).

Such a parallax barrier with a light control layer according to the present invention has a high degree of freedom for SAG, Fill factor, Pitch, shape control, etc., which enables flexible response according to the formation and demand of lenses according to various requests, thereby improving light efficiency. Will be.

In the detailed description of the invention as described above, specific embodiments have been described. However, many modifications are possible without departing from the scope of the invention. The technical spirit of the present invention should not be limited to the described embodiments of the present invention, but should be determined not only by the claims, but also by those equivalent to the claims.

1 is a conceptual diagram illustrating the operation of a conventional parallax barrier.

2 and 3 are conceptual views illustrating a structure of an image separation display device having a light control layer according to the present invention.

4A and 4B illustrate the results of a simulation comparing the efficiency according to the shape of the lens with the light efficiency in the parallax barrier system having the light control layer according to the present invention and the curvature structure of the lens.

Figure 5 shows a process for manufacturing a parallax barrier with a light control layer according to the present invention.

Claims (11)

An image display panel on which an image is implemented; A backlight for supplying a light source to the image display panel; A parallax barrier disposed between the image display panel and a backlight to block or transmit light; And a light control layer formed on the parallax barrier and having a condensing shape for condensing light to a display panel. The method according to claim 1, The parallax barrier is an image separation display device comprising a transmission slit for transmitting light and a barrier for blocking light. The method according to claim 2, And the condensing shape of the light control layer is a condensing shape having a curvature so that the path of light blocked by the barrier is condensed into the transmission slit. The method according to claim 3, And the condensing shape is formed of a lens. The method according to claim 4, And the condensing shape is an aspherical lens. The method according to claim 3, And said condensing shape has a structure in which spherical or aspherical lenses are arranged uniformly or non-uniformly. The method according to any one of claims 4 to 6, And the central axis of the condensing shape is arranged to coincide with the central axis of the transmission slit. The method according to claim 2, And said barrier is made of a black resin. The method according to claim 8, The black resin is formed of any one of black component materials selected from carbon black, organic pigment mixed light-shielding colorant, or hybrid color material mixed with carbon black and organic pigment mixed light-shielding colorant. Device. The method according to claim 8, The black component material is an image separation display device, characterized in that 20 to 50wt% of the total ratio of the black resin. The method according to claim 2, The barrier is an image separation display device characterized in that the inorganic material is formed by mixing the metal (oxide) (oxide) system (metal).

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