KR101211343B1 - Display device and method of driving the same - Google Patents

Abstract

Disclosed are a display apparatus capable of selecting a 2D image and a 3D image, and a driving method thereof.

The present invention drives one frame of 60 Hz into first and second subframes of 120 Hz, respectively, and alternately transmits and blocks adjacent liquid crystal lenses for each subframe, thereby corresponding to one frame each of the left and right eyes of the observer during one frame. All the pixel data can be viewed, and three-dimensional stereoscopic images can be enjoyed without degrading the resolution.

3D, 120Hz, subframe, liquid crystal lens, stereoscopic image, resolution

Description

Display device and method of driving the same

1 is a view schematically illustrating a parallax barrier method.

2 schematically shows a display device according to the invention;

3 is a flowchart illustrating a method of driving a display device according to the present invention.

4A and 4B are diagrams for explaining different pixels from each other under the control of a liquid crystal lens;

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

10: control unit 20: first drive unit

30: image panel 40: second driver

50: optical switch panel 52: lower substrate

54: liquid crystal array

55a to 55j: liquid crystal lens 56: upper substrate

The present invention relates to a display device, and more particularly, to a display device capable of selecting a 2D image and a 3D image and a driving method thereof.

In a broad sense, three-dimensional image displays displaying three-dimensional images, which include three-dimensional images and three-dimensional images, are classified according to three-dimensional display method, view point, observation conditions, and whether the viewer wears separate glasses. You can do

To see stereoscopic images, different images are entered into the left and right eyes, and the left and right images are synthesized in our heads to feel a three-dimensional effect.

In order to create a stereoscopic image, a device for displaying different images in the left and right eyes is required. Among them, a linear polarization type stereoscopic display device in which a left eye image and a right eye image are separated using stereoscopic glasses and the left and right eyes are separately recognized.

However, the three-dimensional method of the glasses method has the inconvenience that the user must wear the glasses. Therefore, a way of not wearing glasses has been proposed to solve this problem.

These systems mainly combine a flat panel display device such as an LCD or a PDP with a device that separates images for each direction to form a stereoscopic system.

In this case, a lenticular method using a lenticular lense sheet, a parallax method using a slit array sheet, and a microlens array sheet according to a device for separating images for each direction. Various autostereoscopy (autostereoscopy) methods have been proposed, such as integral photography using holography and holography using interference.

1 is a diagram schematically illustrating a parallax barrier method.

As shown in FIG. 1, in the parallax barrier method, a barrier panel 3 formed by repeatedly arranging transparent slits and opaque slits is disposed in front of the image panel 5. The observer 1 sees the image displayed by the image panel 5 through the transparent slit of the barrier panel 3, even though the left eye L and the right eye R of the observer 1 pass through the same transparent slit. Each looks at a different area of the image panel 5. The parallax barrier method uses this principle, and the image corresponding to the pixel of the left and right eyes of each region is seen through the transparent slit, so that a 3D feeling can be felt. That is, in FIG. 1, the left eye L sees the left eye corresponding pixel in the image panel 5, and the right eye R sees the right eye corresponding pixel in the image panel 5.

The parallax barrier method is a method capable of selectively driving two-dimensional and three-dimensional. That is, in the case of driving in two dimensions, both the transparent slit and the opaque slit of the barrier panel 3 are converted into transparent slit without distinction, so that it is a normal image only by the image panel when the barrier panel 3 is absent, that is, 2 The dimensional image is realized. In the case of driving in 3D, the transparent slit and the opaque slit of the barrier panel 3 are divided, so that each pixel of the image panel 5 can be viewed only through the transparent slit, thereby implementing a stereoscopic image, that is, a 2D image.

However, the conventional parallax barrier method only sees half of an image for one frame with respect to one eye. That is, in the left eye, the pixels P1, P3, P5, P7, and P9 correspond to half of the image for one frame. In the right eye, the pixels P2 and P4 corresponding to the other half of the image for one frame. , P6, P8, and P10). Therefore, the left eye does not see P2, P4, P6, P8, and P10 during one frame, and the right eye does not see P1, P3, P5, P7, and P9 during one frame.

Therefore, since each eye sees only half of the image of one frame by each eye, there is a problem that the resolution is reduced by half compared to viewing of a conventional two-dimensional image.

The present invention provides a display apparatus and a driving method thereof, by which an entire image is visible to each eye for one frame, so that there is no electrolytic resolution loss compared to a conventional 2D image and that the resolution can be significantly improved as compared to a conventional 3D image. The purpose is to provide.

According to a first exemplary embodiment of the present invention for achieving the above object, a method of driving a display apparatus includes: dividing one frame of 60 Hz into first and second subframes of 120 Hz, respectively; Arranging first and second pixel data corresponding to the first and second subframes by using a first image and a second image; Displaying the first pixel data during the first subframe, and driving a plurality of liquid crystal lenses such that the odd and even pixels of the first pixel data are selectively visible to an observer's first and second eyes. ; And a plurality of liquid crystals to display the second pixel data during the second subframe, and to selectively display odd-numbered pixels and even-numbered pixels of the second pixel data, which are alternately changed in the first and second eyes of the observer. Driving the lens.

According to the second exemplary embodiment of the present invention, the display apparatus divides one frame of 60 Hz into first and second subframes of 120 Hz, respectively, and uses the first and second images to display the first and second subframes. A controller for arranging the first and second pixel data corresponding to the frame; A first panel displaying the first pixel data during the first subframe and displaying the second pixel data during the second subframe; And a second panel configured to alternately change and select the odd-numbered pixel and even-numbered pixel of the first pixel data, and the odd-numbered pixel and even-numbered pixel of the second pixel data.

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

2 is a view schematically showing a display device according to the present invention.

Referring to FIG. 2, the display apparatus of the present invention includes a controller 10, first and second drivers 20 and 40, an image panel 30, and an optical switch panel 50.

The controller 10 controls the L image and the R image to be driven at 120 Hz. For this purpose, one frame (16.67 ms) is composed of first and second subframes (8.84 ms each). The L image is aligned such that the odd pixel is displayed in the first subframe and the even pixel is displayed in the second subframe. The R image is aligned such that even-numbered pixels are displayed in a first subframe and odd-numbered pixels are displayed in a second subframe. Accordingly, the L image having the odd-numbered pixel and the R image having the even-numbered pixel is displayed during the first subframe, and the L image having the even-numbered pixel and the R image having the odd-numbered pixel are displayed during the second subframe. . In contrast, it can be displayed. That is, the L image having the even-numbered pixel and the R image having the odd-numbered pixel during the first subframe may be displayed, and the L image having the odd-numbered pixel and the R image having the even-numbered pixel during the second subframe may be displayed. have.

The controller 10 classifies the L image and the R image and arranges the first and second pixel data for the first subframe and the second subframe. The first pixel data refers to an L image having an odd-numbered pixel and an R image having even-numbered pixels during a first subframe, and the second pixel data is an L image having an even-numbered pixel and an R image having an odd-numbered pixel. It means the image.

In any case, half of the L image and half of the R image are displayed during the first frame, and the other half of the L image and the other half of the R image are displayed during the second frame.

Therefore, all L images are displayed and all R images are displayed during one frame including the first subframe and the second subframe. Thus, the user can see both the L image and the R image for one frame.

This can solve the problem of remarkably lowering the resolution by allowing only half of the L image and half of the R image to be seen in one frame.

The controller 10 generates an image control signal for driving at 120 Hz and an optical control signal for controlling the optical switch according to the 120 Hz driving. The image control signal is supplied to the first driver 20, and the light control signal is supplied to the second driver 40.

The image control signal is a control signal for performing 120 Hz driving with a normal 60 Hz driving, and is a control signal for enabling two scanning of the first subframe and the second subframe during one frame.

The first driver 20 drives the image panel 30 to a first subframe and a second subframe for one frame according to the image control signal.

The image panel 30 may be a liquid crystal display device, a plasma display panel, an electroluminescence display, or the like.

When the image panel 30 is a liquid crystal display, the first driver 20 may drive a driving signal (eg, a scan signal) for driving the first subframe and the second subframe in units of 120 Hz for one frame. The image panel 30 is supplied to the image panel 30.

During the first subframe, the lines of the image panel 30 (gate lines in the case of a liquid crystal display device and address lines in the case of a plasma display panel) are scanned by the scan signal, and the controller controls the scanned pixels. Pixel data (including half of the L image and half of the R image) corresponding to the first subframe supplied in (10) is supplied to display a predetermined stereoscopic image.

Subsequently, lines of the image panel 30 are scanned by a scan signal during the second subframe, and pixel data corresponding to the second subframe supplied from the controller 10 to the scanned pixels (the rest of the L image). Half and the other half of the R image) are supplied to display a predetermined stereoscopic image.

When the image panel 30 is a liquid crystal display, the liquid crystal display includes a plurality of gate lines and data lines arranged in a matrix form, a thin film transistor is disposed at an intersection point of each line, and a pixel electrode is connected to the thin film transistor. do. In addition, the common electrode is disposed to face the pixel electrode. Liquid crystal is disposed between the pixel electrode and the common electrode. Accordingly, a pixel on each line is selected by the gate line, and a liquid crystal is displaced by a predetermined voltage supplied between the pixel electrode and the common electrode to control transmission and blocking of light to display a predetermined image.

When the image panel 30 is a plasma display panel, in the plasma display panel, address electrodes are arranged in a stripe shape on the lower substrate 52, partition walls are disposed between the address electrodes, and phosphors are coated on an inner surface of the partition walls. The first and second sustain electrode pairs are disposed at regular intervals on the upper substrate 56 at right angles to the address electrodes. Accordingly, a unit discharge cell is defined by the address electrode and the first and second sustain electrode pairs. Accordingly, the discharge cell is selected by the address electrode, and plasma discharge is generated by the sustain voltage supplied to the first and second sustain electrode pairs for the selected discharge cell, and the ultraviolet rays generated at this time are coated with the phosphor. In response to conversion into visible light, a predetermined image is displayed.

On the other hand, the second driver 40 alternates the transmission amount of the liquid crystal lenses 55a to 55j adjacent to each of the first subframe and the second subframe by 12 Hz, that is, by the light control signal supplied by the controller 10. The driving signal for inverting the signal is supplied to the optical switch panel 50. As a result, the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, and 55i are transmitted through the first subframe, and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, and 55j are blocked. On the contrary, during the second subframe, the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, and 55i are blocked, and the even-numbered liquid crystal lens is transmitted.

Accordingly, the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, and 55i may be driven in the same manner, and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, and 55j may be driven in the same manner.

The optical switch panel 50 includes a liquid crystal array 54 including a lower substrate 52, an upper substrate 56, and a plurality of liquid crystal lenses 55a to 55j.

A plurality of lower electrodes are disposed on the lower substrate 52 corresponding to each of the liquid crystal lenses 55a to 55j. Similarly, a plurality of upper electrodes are disposed on the upper substrate 56 corresponding to the liquid crystal lenses 55a to 55j. Since the lower electrode and the upper electrode should not block the progress of light, indium tin oxide (ITO) or indium zinc oxide (IZO), which are transparent materials, may be used.

In this case, the same first voltage must be supplied to the lower electrode and the upper electrode opposite to the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, 55i, and the even-numbered liquid crystal lenses 55b, 55d, 55f, The same second voltage must be supplied to the lower electrode and the upper electrode opposite to 55h, 55j). A first voltage supplied to the lower electrode and the upper electrode opposed to the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, and 55i and opposite to the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, 55j. The second voltages supplied to the lower electrode and the upper electrode have inverted phases. That is, when the first voltage has a high level, the second voltage has a low level, and when the first voltage has a low level, the second voltage has a high level.

When the first voltage is at a low level, light is blocked by the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, and 55i, and when the second voltage is at a high level, the even-numbered liquid crystal lens 55b. , 55d, 55f, 55h, 55j) allow light to pass through.

Therefore, the first voltage and the second voltage are phase-inverted alternately every subframe.

3 is a flowchart illustrating a method of driving a display apparatus according to the present invention.

2 and 3, first, the controller 10 divides one frame of 60 Hz into first and second subframes of 120 Hz (S 61). That is, the sum of the first and second frames is one frame.

The control unit 10 is supplied with an L image and an R image from the outside. The L image is an image for the viewer's left eye and the R image is an image for the viewer's right eye.

The L and R images are classified into odd and even pixels, respectively. The pixel data of the first subframe is sorted by the odd-numbered pixel of the L image and the even-numbered pixel of the R image from the pixels classified as described above, and the second sub-number is arranged by the even-numbered pixel of the L image and the odd-numbered pixel of the R image. The pixel data of the frame is aligned (S65).

The first pixel data and the second pixel data are displayed, and a predetermined control signal is generated to control the optical switch panel 50 accordingly. That is, since the first pixel data and the second pixel data are respectively driven at 120 Hz, the image panel 30 should also be driven at 120 Hz. Thus, first and second image control signals for supplying the first and second pixel data at 120 Hz are generated.

In addition, a first light control signal is generated for driving the optical switch panel 50 to first and second subframes of 120 Hz.

During a first subframe, a predetermined driving signal (eg, a scan signal) is supplied to the image panel 30 by the first image control signal, and thus the first pixel data is supplied to the image panel 30. It is displayed (S 65).

At the same time, a predetermined lens driving signal is supplied to the optical switch panel 50 by the first optical control signal. The lens driving signal is supplied at a low level to the lower electrode and the upper electrode opposite to the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, 55i, and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, 55j. The lower electrode and the upper electrode opposite to are supplied at a high level. Accordingly, the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, and 55i are blocked, and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, 55j are transmitted (S 67).

In this case, as shown in Fig. 4A, the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, 55i are blocked, and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, 55j are transmitted. The left eye L and the right eye R of (15) pass through the same liquid crystal lens to see different pixels even when the image panel 30 is viewed. For example, the left eye L of the observer 15 sees the odd pixel and the right eye R sees the even pixel.

Subsequently, during the second subframe, a predetermined driving signal is supplied to the image panel 30 by the second image control signal, and thus the second pixel data is displayed on the image panel 30 (S). 69).

At the same time, a predetermined lens driving signal is supplied to the optical switch panel 50 by the second optical control signal. The lens driving signal is supplied at a high level to the lower electrode and the upper electrode opposite to the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, 55i, and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, 55j. The lower electrode and the upper electrode opposite to are supplied at a low level. Accordingly, the odd-numbered liquid crystal lens is transmitted and the even-numbered liquid crystal lens is blocked (S 71).

In this case, as shown in Fig. 4B, the odd-numbered liquid crystal lenses 55a, 55c, 55e, 55g, 55i are transmitted and the even-numbered liquid crystal lenses 55b, 55d, 55f, 55h, 55j are blocked, so that the observer ( The left eye L and the right eye R of 15) pass through the same liquid crystal lens to see different pixels even when the liquid crystal panel is viewed. For example, the left eye L of the observer 15 sees the even-numbered pixel, and the right eye R sees the odd-numbered pixel.

Therefore, the left eye L of the observer 15 can see both even-numbered and odd-numbered pixels during one frame in which the first subframe and the second subframe are combined, and the right eye R also displays the even-numbered and odd-numbered pixels. All can be seen.

Although not shown in the drawing, the next frame and the next frame may be performed through the same process as described above.

As described above, the present invention drives one frame of 60 Hz to the first and second subframes of 120 Hz, respectively, and transmits and blocks adjacent liquid crystal lenses alternately for each subframe, thereby allowing the observer's left eye to All the pixel data corresponding to one frame of the right eye can be viewed, and three-dimensional stereoscopic images can be enjoyed without degrading the resolution.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

Claims (14)

Dividing one frame of 60 Hz into first and second subframes of 120 Hz, respectively; Arranging first and second pixel data corresponding to the first and second subframes by using a first image and a second image; Displaying the first pixel data during the first subframe, and driving a plurality of liquid crystal lenses such that the odd and even pixels of the first pixel data are selectively visible to an observer's first and second eyes. ; And A plurality of liquid crystal lenses to display the second pixel data during the second subframe, and to selectively display odd-numbered pixels and even-numbered pixels of the second pixel data that are alternately altered to first and second eyes of the observer; And driving the odd-numbered liquid crystal lens and the even-numbered liquid crystal lens mutually exclusively in a blocking and transmitting state, respectively. The liquid crystal lens of claim 1, wherein an odd-numbered liquid crystal lens of the plurality of liquid crystal lenses is blocked and an even-numbered liquid crystal lens is driven to be transmitted during the first subframe, and an odd-numbered liquid crystal of the plurality of liquid crystal lenses is transmitted during the second subframe. And a lens is transmitted so that the even-numbered liquid crystal lens is blocked. The liquid crystal lens of claim 1, wherein an odd-numbered liquid crystal lens of the plurality of liquid crystal lenses is transmitted and a even-numbered liquid crystal lens is blocked during the first subframe, and an odd-numbered liquid crystal of the plurality of liquid crystal lenses is driven during the second subframe. The lens is blocked and the even-numbered liquid crystal lens is driven so as to be transmitted. The image display device of claim 1, wherein during the first and second subframes, an image of any one of the first or second image is divided by an odd pixel of the first pixel data and an even pixel of the second pixel data. The driving method of the display device, characterized in that. The image of claim 1, wherein, during the first and second subframes, an image of any one of the first or second image is divided by an even-numbered pixel of the first pixel data and an odd-numbered pixel of the second pixel data. The driving method of the display device, characterized in that. A frame of 60 Hz is divided into first and second subframes of 120 Hz, respectively, and aligned with first and second pixel data corresponding to the first and second subframes using the first and second images. Control unit; A first panel displaying the first pixel data during the first subframe and displaying the second pixel data during the second subframe; And And a second panel configured to alternately change the odd-numbered pixel and the even-numbered pixel of the first pixel data and the odd-numbered pixel and the even-numbered pixel of the second pixel data to be alternately selected. The second panel, It includes; a lens array having a plurality of liquid crystal lenses for transmission or blocking; And an inverted voltage level is supplied to an odd-numbered liquid crystal lens and an even-numbered liquid crystal lens among the plurality of liquid crystal lenses. The display apparatus of claim 6, wherein the first panel is any one of a liquid crystal display, a plasma display panel, and an electroluminescent element. The method of claim 6, wherein the second panel, A first substrate having a plurality of first electrodes corresponding to the liquid crystal lenses; And And a second substrate having a plurality of second electrodes corresponding to the liquid crystal lens. The display device according to claim 8, wherein the same voltage is supplied to the odd-numbered liquid crystal lens and the same voltage is supplied to the even-numbered liquid crystal lens. delete 7. The liquid crystal display of claim 6, wherein an odd-numbered liquid crystal lens of the plurality of liquid crystal lenses is blocked and a even-numbered liquid crystal lens is driven to be transmitted during the first subframe, and an odd-numbered liquid crystal of the plurality of liquid crystal lenses is transmitted during the second subframe. And the lens is transmitted so that the even-numbered liquid crystal lens is blocked. The liquid crystal lens of claim 6, wherein an odd-numbered liquid crystal lens of the plurality of liquid crystal lenses is transmitted and the even-numbered liquid crystal lens is blocked during the first subframe, and an odd-numbered liquid crystal of the plurality of liquid crystal lenses is provided during the second subframe. And the lens is blocked and the even-numbered liquid crystal lens is driven to transmit. The image display device of claim 6, wherein during the first and second subframes, an image of any one of the first or second image is divided by an even-numbered pixel of the first pixel data and an even-numbered pixel of the second pixel data. Display device, characterized in that visible. The image display device of claim 6, wherein, during the first and second subframes, an image of any one of the first or second image is divided by an even-numbered pixel of the first pixel data and an odd-numbered pixel of the second pixel data. Display device, characterized in that visible.

Images