KR101022653B1 - Field emission display apparatus wherein white balancing is efficiently performed - Google Patents

Abstract

The field emission display device according to the present invention performs gradation display by the width of data pulses applied to the data electrode lines while the scan pulses are sequentially applied to the scan electrode lines. Here, the maximum width of the data pulses is set differently according to the colors corresponding to the respective gradation data of the data pulses.

Description

Field emission display apparatus wherein white balancing is efficiently performed

1 is a block diagram showing the configuration of a field emission display device according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view illustrating the field emission display panel of FIG. 1.

3 is a cross-sectional view viewed from the X-axis direction when the field emission display panel of FIG. 2 is cut in the Y-axis direction.

4 is a timing diagram illustrating scan pulses applied to one cathode electrode line of FIG. 1 and data pulses applied to three gate electrode lines when the end points of the data pulses are identically set.

FIG. 5 is a timing diagram illustrating scan pulses applied to one cathode electrode line of FIG. 1 and data pulses applied to three gate electrode lines when the start points of the data pulses are set identically.

<Explanation of symbols for main parts of the drawings>

1 ... field emission display panel, 2 ... front panel,

214 ... front substrate, 216 ... anode plate,

218 ... fluorescent display cells, 3 ... rear panel,                 

34 ... rear substrate, 36 ... gate electrode line,

38 ... insulating layer, 310 ... cathode electrode line,

314 electron emission source, 320 space bar,

322 ... major penetrations, 324 ... secondary penetrations,

326 ... counter electrode.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a field emission display device, and more particularly, to a field emission for performing gradation display by a width of data pulses applied to data electrode lines while scan pulses are sequentially applied to scan electrode lines. It relates to a display device.

Such a conventional field emission display device basically includes cathode electrode lines, gate electrode lines, fluorescent display cells, and a bipolar plate. The cathode electrode lines are electrically connected with the electron emitters. The gate electrode lines are formed to intersect the cathode electrode lines in front of or behind the cathode electrode lines. When the gate electrode lines are formed in front of the cathode electrode lines, through holes corresponding to the electron emission sources are formed in the region of the gate electrode lines that cross the cathode electrode lines. Fluorescent display cells are formed corresponding to electron emission sources. A positive potential is applied to the positive electrode plate to transfer electrons from the electron emission sources to the fluorescent display cells.

On the other hand, in the conventional field emission display device as described above, even when driving the red, green, and blue display cells with the same grayscale data, different luminance is generated according to each color, so white balancing is not performed.

In order to improve such a white balancing problem, a technique for correcting grayscale data itself for each color is disclosed in Japanese Unexamined Patent Publication No. 242,214 (name of invention: field emission type image display device). However, since the gray scale data itself must be corrected for each color, the driving device and the algorithm are complicated, and the reproducibility of the image is likely to decrease.

It is an object of the present invention to provide a field emission display device in which white balancing is efficiently performed so that the driving device and the algorithm are simple and the image reproducibility is maintained.

The field emission display device of the present invention for achieving the above object performs gradation display by the width of the data pulses applied to the data electrode lines while the scan pulse is sequentially applied to the scan electrode lines. Here, the maximum width of the data pulses is set differently according to the colors corresponding to the respective gradation data of the data pulses.                     

According to the field emission display device of the present invention, the maximum width of the data pulses is set differently according to the colors. Accordingly, white balancing may be performed without correcting the grayscale data itself. Accordingly, white balancing can be efficiently performed so that the driving device and the algorithm are simple and the image reproducibility is maintained.

Hereinafter, preferred embodiments according to the present invention will be described in detail.

Referring to FIG. 1, a field emission display device according to an embodiment of the present invention includes a field emission display panel 1 and a driving device thereof. The driving device of the field emission display panel 1 includes an image controller 4, a set-top box 5, a panel controller 6, a scan driver 7, a data driver 8, and a power supply 9. .

Image control section 4 includes an image signal from a computer (S _PC), DVD (digital versatile disk) video signal (S _DVD), and processes the video signal from the set-top box 5, the panel control unit 6 from the player To enter. The set top box 5 converts the video signal STV from the _television and inputs it to the video control unit 4.

The panel controller 6 processes the image signal from the image controller 4 to generate scan-drive control signals and data-drive control signals. The scan driver 7 drives the cathode electrode lines C ₁ ,... C _n of the field emission display panel 1 in accordance with the scan-drive control signals from the panel controller 6. The data driver 8 drives the gate electrode lines G _1R ,..., G _mB of the field emission display panel 1 in accordance with data-driven control signals from the panel controller 6.

To the gate electrode lines G _1R , ..., G _mB as the data electrode lines while the scan pulse is sequentially applied to the cathode electrode lines C ₁ , ..., C _n as the scan electrode lines. The gray scale display is performed by the width of the data pulses applied. Here, for white balancing, the maximum width of the data pulses is set differently according to the colors corresponding to the respective gray level data of the data pulses. Related contents will be described in more detail with reference to FIGS. 4 and 5.

The power supply unit 9 is an anode plate of the image control unit 4, the set-top box 5, the panel control unit 6, the scan driver 7, the data driver 8, and the field emission display panel 1 (see FIG. 2). 216 are applied. Here, a high potential of 1 to 4 kilovolts (KV) is applied to the positive electrode plate (216 in Fig. 2).

2 and 3, in the field emission display panel 1 of FIG. 1, the front panel 2 and the rear panel 3 are supported by space bars 320.

The back panel 3 includes a back substrate 34, gate electrode lines 36, an insulating layer 38, cathode electrode lines 310, and electron emitters 314. Data signals are applied to the gate electrode lines 36. The cathode electrode lines 310 to which scan pulses are applied are electrically connected to the electron emission sources E _R11 ,..., E _Bnm .

In the cathode electrode lines 310, auxiliary through portions 324 are formed at one sides of the electron emission sources 314. The auxiliary through portions 324 are those in which the conductive material constituting the cathode electrode lines 310 is removed, exposing the insulating layer 8. Accordingly, the electric field from the gate electrode lines 36 to the electron emission sources E _R11 ,..., E _Bnm acts more strongly through the exposed insulating layer 8. Accordingly, the light emission start voltage can be lowered.

On the other hand, main through portions 322 are formed on the other sides of the electron emission sources 314, and through holes 38a are formed between the central portion of the main through portions 322 and the gate electrode lines 36. As the conductive materials are filled in the through holes 38a, counter electrodes 326 electrically connected to the gate electrode lines 36 are formed. Accordingly, since the counter electrodes 326 further form an electric field toward the electron emission sources E _R11 ,..., E _Bnm , the emission start voltage can be lowered.

The front panel 2 includes a front transparent substrate 214, a bipolar plate 216, and fluorescent display cells 218. Fluorescent display cells 218 are formed corresponding to electron emission sources 314. A high positive potential of 1-4 kilovolts (KV) is applied to the positive electrode plate 216 so that electrons from the electron emitters 314 move to the fluorescent display cells 218.

4 is a timing diagram illustrating scan pulses applied to one cathode electrode line of FIG. 1 and data pulses applied to three gate electrode lines when the end points t4 of the data pulses are set to be the same. In FIG. 4, S _Cn denotes the scan pulse applied to the nth cathode electrode line (C _n of FIG. 1), and S _{G (m-2) R} denotes the highest applied to the (m-2) th gate electrode line. The red data pulse of gray level, S _{G (m-1) G} is the green data pulse of highest gray level applied to the (m-1) th gate electrode line, and S _GmB is the mth gate electrode line ( The data pulses for blue of highest gradation applied to G _mB ) of FIG. 1 are indicated respectively.

2 and 4, data applied to the gate electrode lines 36 as the data electrode lines during a t1 to t4 time when the scan pulse of the -V _S potential is applied to the cathode electrode line 310 as the scan electrode line. The gray scale display is performed by the width of the pulses. Here, the maximum width of the data pulse of the + V _D potential corresponding to red is t2 to t4 hours, and the maximum width of the data pulse of the + V _D potential corresponding to green is t1 to t4 time equal to the width of the scan pulse. , The maximum width of the data pulse of the + V _D potential corresponding to blue is t3 to t4 time.

Here, the end time t4 of the data pulses is set the same, and the best start time of the data pulses is set differently according to the colors corresponding to the respective gradation data of the data pulses. That is, the best starting time of the data pulse of the + V _D potential corresponding to red is time t2, the best starting time of the data pulse of the + V _D potential corresponding to green is time t1, and the + V _D potential corresponding to blue color. The best starting point of the data pulse is at time t3.

As described above, the maximum width of the data pulses is set differently according to the colors corresponding to the grayscale data of the data pulses. Accordingly, white balancing may be performed without correcting the grayscale data itself. Accordingly, white balancing can be efficiently performed so that the driving device and the algorithm are simple and the image reproducibility is maintained.

FIG. 5 shows scan pulses applied to one cathode electrode line of FIG. 1 and data pulses applied to three gate electrode lines when the start points of the data pulses are set identically. In FIG. 5, the same reference numerals as used in FIG. 4 indicate objects of the same function.

2 and 5, data applied to the gate electrode lines 36 as the data electrode lines during a t1 to t4 time when the scan pulse of the -V _S potential is applied to the cathode electrode line 310 as the scan electrode line. The gray scale display is performed by the width of the pulses. Here, the maximum width of the data pulse of the + V _D potential corresponding to red is t1 to t3 time, and the maximum width of the data pulse of the + V _D potential corresponding to green is t1 to t4 time equal to the width of the scan pulse. , The maximum width of the data pulse of the + V _D potential corresponding to blue is t1 to t2 time.

Here, the start time t1 of the data pulses is set the same, and the last end time of the data pulses is set differently depending on the colors corresponding to the respective gradation data of the data pulses. That is, the last end point of the data pulse of the + V _D potential corresponding to red is time t3, the last end point of the data pulse of the + V _D potential corresponding to green is time t4, and the + V _D potential corresponding to blue color. The last end time of the data pulse at is t2.

As described above, according to the field emission display device according to the present invention, the maximum width of the data pulses is set differently according to the colors. Accordingly, white balancing may be performed without correcting the grayscale data itself. Accordingly, white balancing can be efficiently performed so that the driving device and the algorithm are simple and the image reproducibility is maintained.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (3)

A field emission display device for performing gradation display by a width of data pulses applied to data electrode lines while scanning pulses are sequentially applied to scan electrode lines. The maximum width of the data pulses is set differently according to the colors corresponding to the respective gray level data of the data pulses, An end point of the data pulses is set to be the same, and the best start point of the data pulses is set differently according to the colors corresponding to the grayscale data of the data pulses. delete delete

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