KR102601571B1 - Autostereoscopic 3d display device and method for driving the same - Google Patents

Abstract

Embodiments of the present invention relate to a glasses-free 3D display device that can prevent resolution degradation and a driving method thereof. A glasses-free 3D display device according to an embodiment of the present invention includes a display panel including pixels and a backlight unit disposed below the display panel to irradiate light to the display panel. The backlight unit includes a first 3D light guide plate including first 3D light emitting patterns, first 3D light sources that irradiate light to the first 3D light guide plate, and a first light guide disposed below the first 3D light guide plate and including second 3D light emitting patterns. It includes two 3D light guide plates, and second 3D light sources that irradiate light to the second 3D light guide plate.

Description

Glasses-free 3D display device and its driving method {AUTOSTEREOSCOPIC 3D DISPLAY DEVICE AND METHOD FOR DRIVING THE SAME}

Embodiments of the present invention relate to a glasses-free 3D display device and a method of driving the same.

3D display devices are divided into stereoscopic 3d display technique and autostereoscopic 3d display technique, and both methods are being put into practical use recently. The glasses method changes the polarization of left and right parallax images and displays them on a direct-view display device or projector and uses polarized glasses to create 3D images. The polarization glasses method displays left and right parallax images in time division and uses shutter glasses to create 3D images. It is divided into shutter glasses type.

The glasses-free method implements 3D images by appropriately controlling the light from the pixels of the display panel to form a viewing zone at the optimal viewing distance. The viewing area may include x views (x is an integer greater than or equal to 2).

In the glasses-free method, the pixels of the display panel must display x number of views separately. For this reason, when the viewing area includes x views, the resolution of the glasses-free 3D image may be lowered to 1/x that of the 2D image. For example, if the viewing area includes two views, such as a left-eye view that displays the left-eye image and a right-eye view that displays the right-eye image, the resolution of the glasses-free 3D image is 1/2 that of the 2D image. It can be lowered.

Embodiments of the present invention provide a glasses-free 3D display device that can prevent resolution degradation and a driving method thereof.

A glasses-free 3D display device according to an embodiment of the present invention includes a display panel including pixels and a backlight unit disposed below the display panel to irradiate light to the display panel. The backlight unit includes a first 3D light guide plate including first 3D light emitting patterns, first 3D light sources that irradiate light to the first 3D light guide plate, and a first light guide disposed below the first 3D light guide plate and including second 3D light emitting patterns. It includes two 3D light guide plates, and second 3D light sources that irradiate light to the second 3D light guide plate.

A method of driving a glasses-free 3D display device according to an embodiment of the present invention displays a left-eye image on a first group of pixels using first 3D image data during an odd frame period in 3D mode, and displays a left-eye image on a first group of pixels during an odd frame period in 3D mode. displaying a right-eye image, emitting first 3D light sources during the odd frame period to irradiate light to a first 3D light guide plate including first 3D emission patterns, and emitting light to a first 3D light guide plate during the odd frame period in the 3D mode. Displaying the right-eye image in the first group of pixels and the left-eye image in the second group of pixels using image data, and turning on second 3D light sources during the even frame period to 2. It includes the step of irradiating light to a second 3D light guide plate including 3D light output patterns.

An embodiment of the present invention displays the left-eye image and the right-eye image alternately in the first group of pixels and the second group of pixels in odd frame periods and even frame periods, and includes a first 3D light guide plate and a second 3D light guide plate. Use to control the positions of the opening and barrier differently. Therefore, the user can use the left eye to view the left eye image displayed on the first group of pixels during the odd frame period and the left eye image displayed on the second group of pixels during the odd frame period in 3D mode. Additionally, the user can use the right eye to watch the right eye image displayed on the second group of pixels during the odd frame period and the right eye image displayed on the first group of pixels during the odd frame period in 3D mode. That is, in an embodiment of the present invention, a user can watch an image displayed in all pixels with both eyes during one frame period. As a result, embodiments of the present invention can prevent resolution degradation in glasses-free 3D mode.

In addition, in an embodiment of the present invention, when the first 3D light sources emit light during an odd frame period in 3D mode to irradiate light to the first 3D light guide plate, the areas between the first 3D light emission patterns may serve as a first barrier. In addition, when the second 3D light sources emit light during the good frame period to irradiate light to the second 3D light guide plate, the areas between the second 3D light emitting patterns can serve as a barrier. As a result, in the embodiment of the present invention, the backlight unit can play the same role as a 3D optical plate in 3D mode, and the position of the barrier in the odd frame period and the position of the barrier in the even frame period are controlled differently. can do.

Additionally, an embodiment of the present invention can provide uniform surface light to the display panel by emitting 2D light sources in 2D mode and irradiating light to the 2D light guide plate. As a result, embodiments of the present invention can display 2D images in 2D mode.

Additionally, in an embodiment of the present invention, the thickness of the second 3D light guide plate may be formed to be thinner than the thickness of the first 3D light guide plate. As a result, embodiments of the present invention can minimize the thickness of the backlight unit.

Additionally, in an embodiment of the present invention, the first 3D light sources and the second 3D light sources emit light at a predetermined duty ratio. As a result, the embodiment of the present invention can prevent 3D crosstalk, in which the left eye image and the right eye image appear to overlap.

1 is a block diagram showing a glasses-free 3D display device according to an embodiment of the present invention.
FIG. 2 is a circuit diagram showing the pixel of FIG. 1.
FIG. 3 is an example diagram showing the backlight unit of FIG. 1.
Figures 4a to 4c are perspective views showing examples of the first 3D light guide plate in detail.
5A to 5C are perspective views showing examples of the second 3D light guide plate in detail.
6A to 6C are exemplary diagrams showing the light output of the backlight unit in odd frame periods and even frame periods in 2D mode and 3D mode.
Figure 7 is a flowchart showing a 2D and 3D implementation method of a glasses-free 3D display device according to an embodiment of the present invention.
Figure 8 is an example diagram showing a 3D implementation method during odd frame periods in 3D mode.
Figure 9 is an example diagram showing a 3D implementation method during a good frame period in 3D mode.
Figure 10 is an example diagram showing backlight lighting timing according to the liquid crystal response curve in 3D mode.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. The present embodiments only serve to ensure that the disclosure of the present invention is complete and that common knowledge in the technical field to which the present invention pertains is not limited. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims.

The shapes, sizes, proportions, angles, numbers, etc. disclosed in the drawings for explaining embodiments of the present invention are illustrative, and the present invention is not limited to the matters shown. Like reference numerals refer to like elements throughout the specification. Additionally, in describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

When 'includes', 'has', 'consists of', etc. mentioned in this specification are used, other parts may be added unless 'only' is used. When a component is expressed in the singular, the plural is included unless specifically stated otherwise.

When interpreting a component, it is interpreted to include the margin of error even if there is no separate explicit description.

In the case of a description of a positional relationship, for example, if the positional relationship of two parts is described as 'on top', 'on the top', 'on the bottom', 'next to', etc., 'immediately' Alternatively, there may be one or more other parts placed between the two parts, unless 'directly' is used.

In the case of a description of a temporal relationship, for example, if a temporal relationship is described as 'after', 'successfully after', 'after', 'before', etc., 'immediately' or 'directly' Unless used, non-consecutive cases may also be included.

Although first, second, etc. are used to describe various components, these components are not limited by these terms. These terms are merely used to distinguish one component from another. Accordingly, the first component mentioned below may also be the second component within the technical spirit of the present invention.

“X-axis direction,” “Y-axis direction,” and “Z-axis direction” should not be interpreted as only geometrical relationships in which the relationship between each other is vertical, and should not be interpreted as a wider range within which the configuration of the present invention can function functionally. It can mean having direction.

The term “at least one” should be understood to include all possible combinations from one or more related items. For example, “at least one of the first, second, and third items” means each of the first, second, or third items, as well as two of the first, second, and third items. It can mean a combination of all items that can be presented from more than one.

Each feature of the various embodiments of the present invention can be combined or combined with each other, partially or entirely, and various technological interconnections and operations are possible, and each embodiment can be implemented independently of each other or together in a related relationship. It may be possible.

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

1 is a block diagram showing a glasses-free 3D display device according to an embodiment of the present invention. Referring to FIG. 1, the glasses-free 3D display device 100 according to an embodiment of the present invention includes a display panel 110, a display panel driver, a display panel control unit 140, a host system 150, and a backlight unit 210. , a backlight driver 220, and a backlight control unit 230.

Since the glasses-free 3D display device 100 according to an embodiment of the present invention implements a barrier for displaying a 3D image using the backlight unit 210, it is preferably implemented as a liquid crystal display (LCD). do.

The display panel 110 displays an image using pixels (P). The display panel 110 includes a lower substrate, an upper substrate, and a liquid crystal layer interposed between the lower substrate and the upper substrate. Data lines (D) and gate lines (G) are formed on the lower substrate of the display panel 110. Data lines (D) may intersect with gate lines (G).

Pixels P may be formed at intersections of data lines D and gate lines G, as shown in FIG. 1 . Each of the pixels (P) may be connected to a data line (D) and a gate line (G). Each of the pixels P may include a transistor T, a pixel electrode 11, a common electrode 12, a liquid crystal layer 13, and a storage capacitor Cst, as shown in FIG. 2 . The transistor (T) is turned on by the gate signal of the gate line (G) and supplies the data voltage of the data line (D) to the pixel electrode 11. The common electrode 12 is connected to a common line and receives a common voltage from the common line. As a result, each of the pixels P drives the liquid crystal of the liquid crystal layer 13 by the electric field generated by the potential difference between the data voltage supplied to the pixel electrode 11 and the common voltage supplied to the common electrode 12. The amount of light transmitted from the backlight unit can be adjusted. As a result, the pixels P can display an image. Additionally, the storage capacitor Cst is provided between the pixel electrode 11 and the common electrode 12 to keep the potential difference between the pixel electrode 11 and the common electrode 12 constant.

The common electrode 12 is formed on the upper substrate in a vertical electric field driving method such as TN (Twisted Nematic) mode and VA (Vertical Alignment) mode, and in a vertical electric field driving method such as IPS (In Plane Switching) mode and FFS (Fringe Field Switching) mode. In the horizontal electric field driving method, it is formed on the lower substrate together with the pixel electrode. The liquid crystal mode of the display panel 110 may be implemented in any liquid crystal mode in addition to the above-described TN mode, VA mode, IPS mode, and FFS mode.

A black matrix and color filters may be formed on the upper substrate of the display panel 110. Color filters may be formed in openings that are not obscured by the black matrix. When the display panel 110 is formed with a color filter on TFT (COT) structure, a black matrix and color filters may be formed on the lower substrate of the display panel 110.

A polarizing plate may be attached to each of the lower and upper substrates of the display panel 110, and an alignment film may be formed to set the pre-tilt angle of the liquid crystal. A column spacer may be formed between the lower substrate and the upper substrate of the display panel 110 to maintain a cell gap in the liquid crystal layer.

The display panel driver includes a data driver 120 and a gate driver 130.

The data driver 120 receives a data control signal (DCS) and 2D data (DATA2D) or 3D data (DATA3D) from the display panel control unit 140. The data driver 120 can receive 2D data (DATA2D) in 2D mode and 3D data (DATA3D) in 3D mode. The data driver 120 converts 2D data (DATA2D) or 3D data (DATA3D) into positive/negative gamma compensation voltages according to the data control signal (DCS) and generates analog data voltages. Analog data voltages output from the source drive ICs are supplied to the data lines D of the display panel 110.

The gate driver 130 receives a gate control signal (GCS) from the display panel control unit 140. The gate driver 130 generates gate signals according to the gate control signal GCS and sequentially supplies the gate signals to the gate lines G of the display panel 110. Accordingly, the data voltage of the data line (D) may be supplied to the pixel (P) to which the gate signals are supplied.

The display panel control unit 140 receives 2D data (DATA2D) in 2D mode and 3D data (DATA3D) in 3D mode from the host system 150. Additionally, the display panel control unit 140 receives timing signals and a mode signal (MODE) from the host system 150. Timing signals may include a horizontal synchronization signal, a vertical synchronization signal, a data enable signal, and a dot clock. The display panel control unit 140 may generate a gate control signal (GCS) and a data control signal (DCS) based on timing signals.

The display panel control unit 140 supplies a gate control signal (GCS) to the gate driver 130, and a data driver control signal (DCS) and 2D data (DATA2D) or 3D data (DATA3D) to the data driver 120. do. The display panel control unit 140 may supply 2D data (DATA2D) to the data driver 120 in 2D mode, and may supply 3D data (DATA3D) to the data driver 120 in 3D mode.

The host system 150 supplies 2D data (DATA2D) or 3D data (DATA3D) to the display panel control unit 140 through an interface such as a Low Voltage Differential Signaling (LVDS) interface or a Transition Minimized Differential Signaling (TMDS) interface. Additionally, the host system 150 supplies a mode signal (MODE) and timing signals to the display panel control unit 140, and supplies the mode signal (MODE) to the backlight control unit 230. The mode signal (MODE) is a signal that indicates whether the current mode is 2D mode or 3D mode. For example, when the mode signal MODE has a first logic level voltage, it may be set to indicate a 2D mode, and when it has a second logic level voltage, it may be set to indicate a 3D mode.

Glasses-free 3D display devices generally display the 2D image displayed on the display panel 110 in 2D mode as is, and display the 3D image displayed on the display panel 110 in 3D mode as a plurality of views in a viewing zone. A 3D optical plate 210 is required to display . However, in an embodiment of the present invention, the backlight unit 210 replaces the role of the 3D optical plate 210, so a separate 3D optical plate 210 is not required.

To this end, the backlight unit 210 includes a first 3D light guide plate 211 including a first 3D light output pattern 211a and a second 3D light guide plate 212 including second 3D light output patterns 212a, as shown in FIG. 3. , a 2D light guide plate 213 including 2D light output patterns 213a, first 3D light sources 216 that irradiate light to the first 3D light guide plate 211, and a second light guide plate 212 that radiates light to the second 3D light guide plate 212. It may include two 3D light sources 217 and 2D light sources 218 that irradiate light to the 2D light guide plate 213. Since the backlight unit 210 includes a plurality of light guide plates 211, 212, and 213 as shown in FIG. 3, each of the plurality of light sources 216, 217, and 218 is connected to a plurality of light guide plates 211, 212, and 213, respectively. It is desirable to implement it as an edge type backlight unit disposed on the side of.

When the backlight unit 210 radiates light to the first 3D light guide plate 211, light is emitted only from the areas where the first 3D light output patterns 211a are formed, and light is not emitted from the remaining areas, so the remaining areas are used as a barrier. Light may be provided to the display panel 10 to play a role. In addition, when the backlight unit 210 irradiates light to the second 3D light guide plate 212, light is emitted only from the areas where the second 3D exit light patterns 212a are formed, and light is not emitted from the remaining areas, so that the remaining areas are Light may be provided to the display panel 10 to serve as a barrier. Additionally, the backlight unit 210 can provide uniform light to the display panel 10 when light is irradiated to the 2D light guide plate 213. A detailed description of the backlight unit 210 will be described later in conjunction with FIG. 3 and FIGS. 6A to 6C.

The backlight driver 220 receives backlight control data (BCD) from the backlight control unit 230. The backlight driver 220 generates a first driving current (DC1) for emitting the first 3D light sources 216 of the backlight unit 210 and a second 3D light source 217 according to the backlight control data (BCD). A second driving current (DC2) and a third driving current (DC3) for causing the 2D light sources 218 to emit light are generated. The backlight driver 220 supplies a first driving current (DC1) to the first 3D light sources 216, a second driving current (DC2) to the second 3D light sources 217, and a third driving current. (DC3) is supplied to the 2D light sources 218.

The backlight control unit 230 receives a mode signal (MODE) from the host system 150. The backlight control unit 230 may control the backlight driver 220 by generating backlight control data (BCD) according to the mode signal (MODE) and supplying it to the backlight driver 220. Backlight control data may be transmitted in SPI (Serial Peripheral Interface) data format.

Specifically, the backlight control unit 230 controls the backlight driver 220 so that the 2D light sources 218 emit light in 2D mode. Accordingly, the backlight driver 220 supplies the third driving current DC3 to the 2D light sources 218 in 2D mode.

In 3D mode, the backlight control unit 230 causes the first 3D light sources 216 to emit light during the odd frame period (or even frame period) and the second 3D light sources 217 to emit light during the even frame period (or odd frame period). Controls the backlight driver 220. Accordingly, the backlight driver 220 supplies the first driving current DC1 to the first 3D light sources 216 during the odd frame period (or even frame period) in 3D mode, and the even frame period (or odd frame period) During this time, the second driving current DC2 is supplied to the second 3D light sources 217.

The backlight control unit 230 controls the 2D light sources 218, the first 3D light sources 216, and the second 3D light sources 217 at a predetermined duty ratio in 2D mode and 3D mode in consideration of the response characteristics of the liquid crystal. You can. A detailed description of this will be provided later in conjunction with FIGS. 10 and 11.

The backlight control unit 230 may be included in the display panel control unit 140. That is, the display panel control unit 140 and the backlight control unit 230 can be formed as one IC.

FIG. 3 is an example diagram showing the backlight unit of FIG. 1. Figure 3 shows a side cross-sectional view of the backlight unit.

Referring to FIG. 3, the backlight unit 210 according to an embodiment of the present invention includes a first 3D light guide plate 211, a second 3D light guide plate 212, a 2D light guide plate 213, optical sheets 214, and a reflective sheet. (215), including first 3D light sources 216, second 3D light sources 217, 2D light sources 218, and first to third circuit boards 219a, 219b, and 219c.

The first 3D light guide plate 211 is disposed at the top of the backlight unit 210 and may include first 3D light exit patterns 211a. When the first 3D light emission patterns 211a are disposed on the lower part of the first 3D light guide plate 211 as shown in FIG. 3, the light incident on the first 3D light guide plate 211 from the first 3D light sources 216 is the first light guide plate 211. In order to output the light to the upper part of the first 3D light guide plate 211 by the 3D light output patterns 211a, it is preferably formed in a concave shape.

The first 3D light emitting patterns 211a are preferably formed to output most of the light only in the areas where the first 3D light emitting patterns 211a are arranged, as shown in FIG. 6B. To this end, the first 3D light output patterns 211a may be formed as line patterns including a plurality of triangular prism mountains formed in the y-axis direction as shown in FIG. 4A. As the distance from the first 3D light sources 216 increases, the amount of light reaching the plurality of triangular prism mountains may decrease, so the plurality of triangular prism mountains may be formed thicker as the distance from the first 3D light sources 216 increases. You can.

Alternatively, the first 3D light output patterns 211a may be formed as hemispherical dot patterns formed in the y-axis direction as shown in FIG. 4B. As the distance from the first 3D light sources 216 increases, the amount of light reaching the hemispherical dot patterns may decrease, so the distance between the hemispherical dot patterns increases as the distance between the first 3D light sources 216 increases. The longer it gets, the shorter it can be formed. That is, hemispherical dot patterns can be formed more densely as the distance from the first 3D light sources 216 increases.

Alternatively, the first 3D light emission patterns 211a may be formed as triangular pyramid-shaped dot patterns formed in the y-axis direction as shown in FIG. 4C. As the distance from the first 3D light sources 216 increases, the amount of light reaching the triangular pyramid-shaped dot patterns may decrease, so the spacing between the triangular pyramid-shaped dot patterns is farther away from the first 3D light sources 216. The longer it gets, the shorter it can be formed. That is, the dot patterns in the shape of a triangular pyramid can be formed more densely as the distance from the first 3D light sources 216 increases. 4A to 4C, the x-axis direction is the direction in which light from the first 3D light sources 216 is incident, the y-axis direction is a direction intersecting the x-axis direction, and the z-axis direction is the direction of the first 3D light guide plate 211. ) is the thickness direction.

The second 3D light guide plate 212 is disposed below the first 3D light guide plate 211 and may include second 3D light emission patterns 212a. When the second 3D light emission patterns 212a are disposed on the upper part of the second 3D light guide plate 212 as shown in FIG. 3, the light incident on the second 3D light guide plate 212 from the second 3D light sources 217 is the second light guide plate 212. In order to output the light to the upper part of the second 3D light guide plate 212 by the 3D light output patterns 212a, it is preferably formed in a relief.

The second 3D light emitting patterns 212a are preferably formed to output most of the light only in the areas where the second 3D light emitting patterns 212a are arranged, as shown in FIG. 6C. For example, the second 3D light output patterns 212a may be formed as triangular prism-shaped line patterns formed in the y-axis direction as shown in FIG. 5A. Alternatively, the second 3D light output patterns 212a may be formed as hemispherical dot patterns formed in the y-axis direction as shown in FIG. 5B. Alternatively, the first 3D light output patterns 212a may be formed as triangular pyramid-shaped dot patterns formed in the y-axis direction as shown in FIG. 5C. 5A to 5C, the x-axis direction is the direction in which light from the second 3D light sources 217 is incident, the y-axis direction is a direction intersecting the x-axis direction, and the z-axis direction is the direction of the second 3D light guide plate 212. ) is the thickness direction.

Meanwhile, the first 3D light emitting patterns 211a may be formed to be spaced apart from each other at a first interval d1, and the second 3D light emitting patterns 212a may be formed to be spaced apart from a second interval d2. The first interval d1 and the second interval d2 may be the same. In addition, the second 3D light output pattern 212a is disposed between adjacent first 3D light output patterns 211a, and the first 3D light output pattern 211a is disposed between adjacent second 3D light output patterns 212a. It can be. Because of this, the positions of the light output by the first 3D light emitting patterns 211a and the positions of the light output by the second 3D light emitting patterns 212a may be different. A detailed description of this will be provided later in conjunction with FIGS. 6B and 6C.

The 2D light guide plate 213 is disposed below the second 3D light guide plate 212. Light incident from the 2D light sources 218 to the 2D light guide plate 213 may be output as surface light to the top of the 2D light guide plate 212, as shown in FIG. 6A. As long as the 2D light guide plate 213 can output light from the 2D light sources 218 as surface light, any known light guide plate can be used.

The 2D light guide plate 213 may include 2D light emission patterns 213a for outputting surface light to the top of the 2D light guide plate 212. 2D light emission patterns 213a may be formed on the lower part of the 2D light guide plate 213 as shown in FIG. 3 .

In order to irradiate the light from the 2D light guide plate 213 to the display panel 10 as a more uniform surface light, optical sheets 241 are placed between the second 3D light guide plate 212 and the 2D light guide plate 213. ) can be placed. The optical sheets 214 may include at least one diffusion sheet and at least one prism sheet. For example, the optical sheets 214 may include a diffusion sheet 214a, a prism sheet 214b, and a dual brightness enhancement film 214c, as shown in FIG. 3 .

A reflective sheet 215 may be placed below the 2D light guide plate 213. The reflective sheet 215 can reduce light loss by reflecting light directed downward from the 2D light guide plate 213 to the 2D light guide plate 213.

The first 3D light sources 216 are disposed on the side of the first 3D light guide plate 211 and irradiate light to the first 3D light guide plate 211. The second 3D light sources 217 are disposed on the side of the second 3D light guide plate 212 and irradiate light to the second 3D light guide plate 212. The 2D light sources 218 are disposed on the side of the 2D light guide plate 213 and irradiate light to the 2D light guide plate 213. The first and second 3D light sources 216, 217 and 2D light sources 218 include Hot Cathode Fluorescent Lamp (HCFL), Cold Cathode Fluorescent Lamp (CCFL), External Electrode Fluorescent Lamp (EEFL), and Light Emitting Diode (LED) ), OLED (Organic Light Emitting Diode), or two or more types of light sources.

Each of the first 3D light sources 216 is mounted on the first light source circuit board 219a, and can emit light by receiving a first driving current DC1 from the first light source circuit board 219a. Each of the second 3D light sources 217 is mounted on the second light source circuit board 219b, and can emit light by receiving a second driving current (DC2) from the second light source circuit board 219b. Each of the 2D light sources 218 is mounted on the third light source circuit board 219c, and can emit light by receiving a third driving current (DC3) from the third light source circuit board 219c. Each of the first to third light source circuit boards 219a, 219b, and 219c is connected to the backlight driver 220 and receives first to third drive currents DC1, DC2, and DC3 from the backlight driver circuit 220. Each is supplied.

Hereinafter, light output of the backlight unit during odd frame periods and even frame periods in 2D mode and 3D mode will be described in conjunction with FIGS. 6A to 6C.

FIGS. 6A to 6C are exemplary diagrams showing the light output of the backlight unit in odd frame periods and even frame periods in 2D mode and 3D mode.

First, in the 2D mode, the 2D light sources 218 emit light as shown in FIG. 6A, which causes light to enter the 2D light guide plate 213. In 2D mode, light from the 2D light sources 218 is output as surface light (SL) to the top of the 2D light guide plate 213 by the 2D exit light patterns 213a of the 2D light guide plate 213.

Second, during odd frame periods in 3D mode, the first 3D light sources 216 emit light as shown in FIG. 6B, and thus light is incident on the first 3D light guide plate 211. Light from the first 3D light sources 216 is output to the upper part of the first 3D light guide plate 211 by the first 3D exit patterns 211a of the first 3D light guide plate 211. In particular, the first 3D light emitting patterns 211a may be designed to output most of the light only in areas where the first 3D light emitting patterns 211a are arranged, as shown in FIG. 6B.

That is, the first 3D light guide plate 211 outputs light L only in the areas where the first 3D light output patterns 211a are arranged, and almost no light is output in the areas between the first 3D light output patterns 211a. No. Accordingly, the areas where the first 3D light emitting patterns 211a are arranged serve as the first opening OA1 in 3D implementation, and the areas between the first 3D light emitting patterns 211a serve as a first barrier (barrier) in 3D implementation. It plays the role of B1).

Third, during the good frame period in 3D mode, the second 3D light sources 217 emit light as shown in FIG. 6C, which causes light to enter the second 3D light guide plate 212. Light from the second 3D light sources 217 is output to the upper part of the second 3D light guide plate 212 by the second 3D exit patterns 212a of the second 3D light guide plate 212. In particular, the second 3D light emitting patterns 212a may be designed to output most of the light only in areas where the second 3D light emitting patterns 212a are arranged, as shown in FIG. 6C.

That is, the second 3D light guide plate 212 outputs light L only in the areas where the second 3D light output patterns 212a are arranged, and almost no light is output in the areas between the second 3D light output patterns 212a. No. Accordingly, the areas where the second 3D light emitting patterns 212a are arranged serve as the second openings OA2 when implemented in 3D, and the areas between the second 3D light emitting patterns 212a serve as the second barrier B2 when implemented in 3D. plays the role of

As discussed above, the embodiment of the present invention can provide uniform surface light to the display panel 10 when the 2D light sources 217 emit light in a 2D mode and irradiate light to the 2D light guide plate 213. In addition, in an embodiment of the present invention, when the first 3D light sources 216 emit light during an odd frame period in 3D mode to irradiate light to the first 3D light guide plate 212, the areas between the first 3D light emission patterns 211a It can serve as a first barrier (B1), and when the second 3D light sources 217 emit light during the good frame period to irradiate light to the second 3D light guide plate 213, the second 3D light emission patterns 212a are generated. The areas in between can serve as a barrier (B2). That is, in an embodiment of the present invention, the backlight unit 210 can function like a 3D optical plate in 3D mode, and the position of the barrier in odd frame periods and the position of the barrier in even frame periods can be controlled differently. As a result, embodiments of the present invention can implement 2D images in 2D mode and display 3D images in 3D mode.

In addition, the second 3D light output pattern 212a is disposed between adjacent first 3D light output patterns 211a, and the first 3D light output pattern 211a is disposed between adjacent second 3D light output patterns 212a. It can be. For this reason, in 3D mode, the positions of the first opening OA1 and the first barrier B1 may be different during odd frame periods, and the positions of the second opening OA2 and the second barrier B2 may be different during odd frame periods. For example, in 3D mode, the position of the first opening OA1 during the odd frame period may correspond to the position of the second barrier B2 during the even frame period, and the position of the first barrier B1 during the odd frame period may correspond to the position of the second barrier B2 during the odd frame period. may correspond to the position of the second opening OA2 during the even frame period.

Specifically, by forming the positions of the first opening (OA1) and the first barrier (B1) during the odd frame period to be different from the positions of the second opening (OA2) and the second barrier (B2) during the even frame period, The pixels viewed by the left eye and the pixels viewed by the right eye during the best frame period may be differentiated from the pixels viewed by the left eye and the pixels viewed by the right eye during the best frame period. For example, during the odd frame period, as shown in FIG. 8, the left eye views the first group of pixels (PG1) and the right eye views the second group of pixels (PG2), while the even frame period Meanwhile, as shown in FIG. 9 , the left eye may view the second group of pixels PG2 and the right eye may view the first group of pixels PG1.

Below, we will look in detail at the 2D and 3D implementation method of the glasses-free 3D display device according to an embodiment of the present invention in conjunction with FIGS. 1 and 7 to 9.

Figure 7 is a flowchart showing a 2D and 3D implementation method of a glasses-free 3D display device according to an embodiment of the present invention.

First, the display panel control unit 140 receives a mode signal (MODE) and 2D data (DATA2D) or 3D data (DATA3D) from the host system 150. Additionally, the backlight control unit 230 receives a mode signal (MODE) from the host system 150. The display panel control unit 140 and the backlight control unit 230 can determine whether the mode is 2D mode or 3D mode according to the mode signal MODE. (S101 in FIG. 7)

Second, the display panel control unit 140 supplies 2D data (DATA2D) and a data control signal (DCS) to the data driver 120 and a gate control signal (GCS) to the gate driver 130 in 2D mode. do. The data driver 120 supplies data voltages to the data lines D according to the 2D data (DATA2D) and the data control signal (DCS). The gate driver 130 supplies gate signals to the gate lines (G) according to the gate control signal (GCS). Because of this, the pixels P of the display panel 110 display a 2D image.

The backlight control unit 230 supplies backlight control data (BCD) to the backlight driver 220 so that the 2D light sources 218 emit light in 2D mode. The backlight driver 220 supplies third driving currents (DC) to the 2D light sources 218 according to the backlight control data (BCD), which causes the 2D light sources 218 to emit light.

The 2D light guide plate 213 provides surface light to the display panel 110 by the emission of the 2D light sources 218, so the display panel 110 displays a 2D image. Therefore, the user can view 2D images. (S102 in FIG. 7)

Third, the display panel control unit 140 increases the frame frequency in 3D mode and divides one frame period into an odd frame period and an even frame period. The display panel control unit 140 supplies first 3D image data (DATA3D(1)) and a data control signal (DCS) to the data driver 120 during an odd frame period in 3D mode, and provides a gate control signal (GCS) to the data driver 120. It is supplied to the driving unit 130. The data driver 120 supplies data voltages to the data lines D according to the first 3D image data DATA3D(1) and the data control signal DCS. The gate driver 130 supplies gate signals to the gate lines (G) according to the gate control signal (GCS). When the first 3D image data (DATA3D(1)) is supplied to the display panel 110, the first group of pixels PG1 of the display panel 110 displays the left eye image, and the remaining pixels of the second group display the left eye image. PG2 indicates the right eye image.

The backlight control unit 230 supplies backlight control data (BCD) to the backlight driver 220 so that the first 3D light sources 216 emit light during odd frame periods in 3D mode. The backlight driver 220 supplies the first driving currents DC1 to the first 3D light sources 216 according to the backlight control data BCD, so that the first 3D light sources 216 emit light.

By the emission of the first 3D light sources 216, the first 3D light guide plate 211 outputs light to form first openings OA1 and first barriers B1 as shown in FIG. 8. As a result, in 3D mode, the left eye image is incident on the user's left eye (LE) during the odd frame period, and the right eye image is incident on the user's right eye (RE) during the odd frame period. Therefore, the user can view 3D images. (S103 in FIG. 7)

Fourth, the display panel control unit 140 supplies the second 3D image data (DATA3D(2)) and the data control signal (DCS) to the data driver 120 during the good frame period in 3D mode, and provides a gate control signal ( GCS) is supplied to the gate driver 130. The data driver 120 supplies data voltages to the data lines D according to the second 3D image data DATA3D(2) and the data control signal DCS. The gate driver 130 supplies gate signals to the gate lines (G) according to the gate control signal (GCS). When the second 3D image data (DATA3D(2)) is supplied to the display panel 110, the first group of pixels PG1 of the display panel 110 displays the right eye image, and the remaining second group of pixels display the right eye image. Fields (PG2) indicate the left eye image.

The backlight control unit 230 supplies backlight control data (BCD) to the backlight driver 220 so that the second 3D light sources 217 emit light during the good frame period in 3D mode. The backlight driver 220 supplies the second driving currents DC2 to the second 3D light sources 217 according to the backlight control data BCD, which causes the second 3D light sources 217 to emit light.

By the emission of the second 3D light sources 217, the second 3D light guide plate 212 outputs light to form second openings OA2 and second barriers B2 as shown in FIG. 9. As a result, in 3D mode, the left eye image is incident on the user's left eye (LE) during the good frame period, and the right eye image is incident on the user's right eye (RE) during the good frame period. Therefore, the user can view 3D images. (S104 in FIG. 7)

As seen above, the embodiment of the present invention alternately displays the left-eye image and the right-eye image to the first group of pixels (PG1) and the second group of pixels (PG2) in odd frame periods and even frame periods. and the positions of the opening and the barrier are formed differently using the first 3D light guide plate 211 and the second 3D light guide plate 212. Therefore, the user uses the left eye to view the left eye image displayed on the first group of pixels PG1 during the odd frame period in 3D mode, and the left eye image displayed on the second group of pixels PG2 during the odd frame period. You can watch the video. Additionally, the user uses the right eye to view the right eye image displayed on the second group of pixels PG2 during the odd frame period in 3D mode, and the right eye image displayed on the first group of pixels PG1 during the odd frame period. You can watch the video. That is, in an embodiment of the present invention, a user can view images displayed in all pixels P with both eyes during one frame period. As a result, embodiments of the present invention can prevent resolution degradation in glasses-free 3D mode.

Meanwhile, in FIGS. 8 and 9, S is the back distance and represents the distance from the liquid crystal layer of the display panel 110 to the first 3D light output patterns 211a of the first 3D light guide plate 211, and OD is the optimal 3D image. It represents the viewing distance, and E is the distance between both eyes, which can be 65mm.

The optimal viewing distance (OD) for 3D images is designed based on the width of the pixel (P), the back distance (S), and the distance between both eyes (E). The thickness of the first 3D light guide plate 211 must be designed to be more than a predetermined thickness in order to maintain the back distance (S). However, the thickness of the second 3D light guide plate 212 is not related to the back distance (S). In addition, since the embodiment of the present invention includes three light guide plates 211, 212, and 213, in order to minimize the thickness of the backlight unit 210, the thickness of the second 3D light guide plate 212 is reduced to that of the first 3D light guide plate ( 211) can be formed thinner than the thickness. Even so, it is preferable that the second 3D light guide plate 212 has a thickness that can guide light from the second 3D light sources 217 without loss.

Additionally, the reason the second 3D light emitting patterns 212a are formed on the upper part of the second 3D light guide plate 212 is to minimize the distance from the first 3D light emitting patterns 211a. The distance between the second 3D light emitting patterns 212a and the first 3D light emitting patterns 211a should be minimized so that the distance from the second 3D light emitting patterns 212a to the liquid crystal layer of the display panel 110 and the back distance ( This is because the difference between S) is minimized.

Figure 10 is an example diagram showing backlight lighting timing according to the liquid crystal response curve in 3D mode. In FIG. 10 , for convenience of explanation, the left eye image displayed in the first group of pixels PG1 displays peak white gradation during the odd frame period, and the right eye image displayed in the second group of pixels PG2 displays peak black. The gray scale is displayed, and during the good frame period, the right eye image displayed on the first group of pixels (PG1) displays a peak black gray scale, and the left eye image displayed on the second group of pixels (PG2) displays a peak white gray scale. This is an example of displaying. Based on 8 bits of digital data, 255 gray level data displays a peak white gray level, and 0 gray level data displays a peak black gray level.

Since liquid crystal has a response delay as shown in FIG. 10, if the duty ratios of the first 3D light sources 216 and the second 3D light sources 217 are not adjusted, the left eye image and the right eye image This overlapping 3D crosstalk may occur. The duty ratio indicates the lighting period compared to the total period of the lighting period and the lighting-off period. However, if the duty ratios of the first 3D light sources 216 and the second 3D light sources 217 are too low, there may be a problem of lowering 3D luminance. Therefore, it is desirable that the duty ratios of the first 3D light sources 216 and the second 3D light sources 217 are appropriately set in consideration of 3D crosstalk and 3D luminance due to response delay of the liquid crystal.

Although embodiments of the present invention have been described in more detail with reference to the accompanying drawings, the present invention is not necessarily limited to these embodiments, and various modifications may be made without departing from the technical spirit of the present invention. . Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of protection of the present invention should be interpreted in accordance with the claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of the present invention.

100: Glasses-free 3D display device 110: Display panel
120: data driver 130: gate driver
140: display panel control unit 150: host system
210: backlight unit 211: first 3D light guide plate
211a: first 3D light emission pattern 212: second 3D light guide plate
212a: Second 3D light emission pattern 213: 2D light guide plate
213a: 2D light output pattern 214: Optical sheets
215: reflective sheet 216: first 3D light source
217: second 3D light source 218: third 3D light source
220: backlight driving unit 230: backlight control unit

Claims (13)

A display panel including pixels; and
a backlight unit disposed below the display panel and emitting light to the display panel;
The backlight unit is,
A first 3D light guide plate including a plurality of first 3D light emission patterns on its lower surface;
first 3D light sources disposed on one side of the first 3D light guide plate and emitting first light;
a second 3D light guide plate disposed below the first 3D light guide plate and including a plurality of second 3D light emission patterns on an upper surface; and
second 3D light sources that irradiate second light to one side of the second 3D light guide plate corresponding to one side of the first 3D light guide plate;
a 2D light guide plate disposed below the second 3D light guide plate and including a plurality of 2D light emission patterns on a lower surface; and
It includes 2D light sources disposed on one side of the 2D light guide plate and irradiating third light to the 2D light guide plate,
In 3D mode, which displays 3D images,
The first 3D light sources emit the first light during an odd frame period, and the first light is emitted through an area of the first 3D light guide plate where the first 3D light emission patterns are formed, and the remaining area of the first 3D light guide plate. It is blocked in
The second 3D light sources emit the second light during the good frame period, and the second light is emitted through the areas of the second 3D light guide plate where the second 3D emission patterns are formed and in the remaining area of the second 3D light guide plate. is blocked,
In a 2D mode displaying a 2D image, the plurality of 2D light emission patterns output third light emitted from the 2D light sources as surface light toward the upper part of the 2D light guide plate,
The plurality of first 3D light emission patterns are gradually arranged more densely as the distance from the first 3D light sources increases over the entire lower surface area of the first 3D light guide plate,
The plurality of second 3D light emission patterns are arranged gradually more densely as the distance from the second 3D light sources increases in the entire upper surface area of the second 3D light guide plate,
Each of the plurality of second 3D light emitting patterns and each of the plurality of first 3D light emitting patterns are arranged alternately with each other when viewed in a plan view,
The plurality of first 3D light emitting patterns and the plurality of 2D light emitting patterns are formed in a concave shape,
A glasses-free 3D display device in which the plurality of second 3D light emitting patterns are formed in relief. delete delete delete According to claim 1,
A glasses-free 3D display device in which the thickness of the second 3D light guide plate is thinner than the thickness of the first 3D light guide plate. delete According to claim 1,
The backlight unit is,
optical sheets disposed between the 2D light guide plate and the second 3D light guide plate; and
A glasses-free 3D display device further comprising a reflective sheet disposed below the 2D light guide plate. delete According to claim 1,
The pixels include a first group of pixels and a second group of pixels,
During the odd frame period, the first group of pixels display a left-eye image, the second group of pixels display a right-eye image, and during the even frame period, the first group of pixels display the right-eye image, The second group of pixels displays the left eye image. According to claim 1,
The first 3D light sources and the second 3D light sources emit light at a predetermined duty ratio. delete A backlight unit disposed below the display panel and emitting light to the display panel,
A first 3D light guide plate including a plurality of first 3D light emission patterns on its lower surface;
first 3D light sources disposed on one side of the first 3D light guide plate and emitting first light;
a second 3D light guide plate disposed below the first 3D light guide plate and including a plurality of second 3D light emission patterns on an upper surface;
second 3D light sources that irradiate second light to one side of the second 3D light guide plate corresponding to one side of the first 3D light guide plate;
a 2D light guide plate disposed below the second 3D light guide plate and including a plurality of 2D light emission patterns on a lower surface; and
It includes 2D light sources disposed on one side of the 2D light guide plate and irradiating third light to the 2D light guide plate,
In 3D mode, which displays 3D images,
Displaying a left eye image on a first group of pixels using the first 3D image data during an odd frame period,
displaying a right eye image on a second group of pixels;
The first 3D light sources emit light during the odd frame period, so that the first light is emitted through an area of the first 3D light guide plate where the first 3D emission patterns are formed and is blocked from the remaining area of the first 3D light guide plate. irradiating light to the first 3D light guide plate including a plurality of first 3D light exit patterns;
Displaying the right eye image in the first group of pixels and displaying the left eye image in the second group of pixels using second 3D image data during an even frame period in the 3D mode; and
Turning on the second 3D light sources during the even frame period so that the second light is emitted through the areas of the second 3D light guide plate where the second 3D emission patterns are formed and is blocked from the remaining areas of the second 3D light guide plate. A step of irradiating light to the second 3D light guide plate including a plurality of second 3D light output patterns,
The first 3D light sources are disposed on one side of the first 3D light guide plate,
The second 3D light sources are disposed on one side of the second 3D light guide plate corresponding to one side of the first 3D light guide plate,
The plurality of first 3D light emission patterns are gradually arranged more densely as the distance from the first 3D light sources increases over the entire lower surface area of the first 3D light guide plate,
The plurality of second 3D light emission patterns are arranged gradually more densely as the distance from the second 3D light sources increases in the entire upper surface area of the second 3D light guide plate,
Each of the plurality of second 3D light emitting patterns and each of the plurality of first 3D light emitting patterns are arranged alternately with each other when viewed in a plan view,
The plurality of first 3D light emitting patterns and the plurality of 2D light emitting patterns are formed in a concave shape,
A method of driving a glasses-free 3D display device in which the plurality of second 3D light emission patterns are formed in relief. According to claim 12,
In a 2D mode for displaying a 2D image, displaying a 2D image on the first and second groups of pixels using 2D image data; and
A method of driving a glasses-free 3D display device further comprising turning on the 2D light sources in the 2D mode to irradiate light to the 2D light guide plate.

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