KR100262336B1 - Gate driving method of field emission display device - Google Patents

Abstract

PURPOSE: A gate driving method for a field emission display is provided to increase brightness level by adjusting scanning operation of a gate line. CONSTITUTION: The gate driver is coupled with a plurality of gate lines, receives a gate line selection control signal from a controller and performs scanning on the corresponding gate line with response to a clock signal. At first, a plurality of line selection control signals are applied on the gate driver from the controller with a time delay of half period during one period of the first clock signal. When the first gate line is scanned, the second gate line is scanned after the time delay of half period. Data suitable for the panel(that is, image signal) is applied on the selected gate line by way of a data driver. The steps above are performed on following gate lines. Altogether, plurality of gate lines are multiple-scanned with a predetermined time difference.

Description

Gate driving method of field emission indicator

The present invention relates to a field emission indicator, and more particularly, to a gate driving method of a field emission indicator configured to overscan a plurality of gate lines of a field emission indicator.

Field Emission Display (FED), which is emerging as a new flat panel display, displays the screen in a similar way to the cathode ray tube (CRT), which displays the screen using emitted electrons. It is different from the cathode ray tube (CRT) using the thermal electron emission (thermal electron emission) in that it is used.

Such conventional field emission indicators install hundreds to thousands of field emission elements for emitting electrons per pixel, and impinge electrons from the developed emission elements on an electrode coated with a fluorescent film to display an image.

The field emission device constituting the pixel of the field emission indicator is provided with a cathode 12 connected to the cathode electrode 10 and a predetermined distance above the cathode 12, as shown in FIG. A gate 14 and an anode 18 having a phosphor film 16 coated thereon is provided on the rear surface thereof.

Here, the fluorescent film 16 generates light corresponding to the amount of electrons colliding to display an image.

In addition, the positive electrode plate 18 plays a role of attracting electrons emitted from the cathode 12, and also has transparency to transmit light by the fluorescent film 16.

In addition, the cathode 12 has the shape of a horn forming the upper part of the tactile part and emits electrons from its tactile part by a driving power source from the cathode electrode 10.

In addition, the gate 14 induces the emission of electrons from the cathode 12 to the hole by a high voltage lower than the voltage applied to the positive electrode plate 18, the emitted electrons are applied with a higher voltage It is directed toward the positive electrode plate 18.

FIG. 2 is a block diagram illustrating a panel driving operation of a general field emission indicator. The panel 20 is an image display area in which the field emission elements in pixel units shown in FIG. 1 are formed in a matrix form, and the control means 22 ) Receives a video signal from the outside and outputs a control signal and a video signal according to the characteristics of the panel 20, the gate driver 24 is connected to a plurality of gate lines to receive a control signal input from the control means 22 A signal for scanning the corresponding gate line is generated, and the data driver 26 is connected to a plurality of data lines to transmit an image signal input from the control means 22 to each pixel of the panel 20.

According to the same figure, the gate driver 24 switches to a high voltage capable of emitting electrons whenever the corresponding gate line is selected by the control signal (gate line selection control signal) of the control means 22. The data driver 26 outputs an image signal corresponding to the characteristics of the panel 20 to the selected gate line. Therefore, a desired image is displayed on the panel 20.

In addition, the normal scanning operation of the gate driver 24 will be described. As shown in FIG. 1, n + 2) are sequentially scanned. Here, each of the gate lines n, n + 1 and n + 2 is sequentially scanned at a _high voltage V _high (for example, 100 V) at a rising edge of the clock signal.

In a general field emission indicator employing a gate driver for performing such a scanning operation, the internal circuit structure such as a gate driver or a data driver is changed to improve luminance.

Accordingly, an object of the present invention is to provide a gate driving method of a field emission indicator which improves luminance by adjusting a scanning operation of a gate line.

According to a preferred embodiment of the present invention, a gate driver connected to a plurality of gate lines, receiving a control signal for selecting a gate line input from a control means, and scanning a corresponding gate line based on a clock signal. In the equipped field emission indicator, a plurality of gate line selection control signals are input from the control means to the gate driver during a period of the first clock signal by a half cycle difference, and the second gate line is also scanned when the first gate line is scanned. After half a period of scanning, data corresponding to the characteristics of the panel (i.e., image signal) is applied to the selected gate line through a data driver, and the same operation is performed on subsequent gate lines. Multiple gate lines are staggered every cycle The gate driving method of overlapping the scanning field emission display is provided.

1 is a diagram for explaining a structure of a general field emission device.

2 is a block diagram for explaining a panel driving operation of a general field emission indicator.

3 is a drive timing diagram of the gate driver shown in FIG.

4 is a driving timing diagram according to a gate driving method of a field emission indicator according to an exemplary embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10 cathode electrode 12 cathode

14 gate 16 fluorescent film

18: bipolar plate (anode) 20: panel

22: control means 24: gate driver

26: data driver

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

The driving method according to the embodiment of the present invention can be realized by the block configuration shown in FIG.

However, the control operation in the control means only differs. That is, while the control means in the conventional configuration controls one gate line to be scanned every one cycle of the clock signal, the control means to which the embodiment of the present invention is applied controls such that a plurality of gate lines are scanned every one cycle of the clock signal. Is different.

4 is a driving timing diagram of a gate driving method of a field emission indicator according to an exemplary embodiment of the present invention. As the start control signal from the control unit 22 is input, the gate driver 24 is synchronized with a clock signal. The gate lines (two in the embodiment of the present invention) are scanned repeatedly one cycle.

That is, a plurality of gate line selection control signals (Gate_Control (1) and Gate_Control (2)) are input from the control means 22 to the gate driver 24 with a half cycle difference during one period of the first clock signal. When scanning the gate line Gate_Line (1), the second gate line Gate_Line (2) is also scanned after a half cycle.

Accordingly, the data (ie, the video signal) provided from the data driver 26 is applied to the two gate lines Gate_Line (1) and Gate_Line (2).

During the next one period of the clock signal, the gate line selection control signal Gate_Control (3) becomes the "high" level, and the gate line selection control signal Gate_Control (2) maintains the "high" level only for half a period. Since the data is supplied from the data driver 26 (that is, the video signal), the data is applied to two gate lines Gate_Line (2) and Gate_Line (3).

This operation is also performed on subsequent gate lines Gate_Line (4) to Gate_Line (n).

According to the present invention as described above, the brightness is improved by duplex scanning the two gate lines for each cycle of the clock signal.

On the other hand, the present invention is not limited only to the above-described embodiments, but may be modified and modified within the scope of the present invention.

Claims (1)

A field emission indicator having a gate driver connected to a plurality of gate lines and receiving a gate line selection control signal input from a control means and scanning the gate line based on a clock signal, During a period of the first clock signal, a plurality of gate line selection control signals are input from the control means to the gate driver with a half cycle difference, and when the first gate line is scanned, the second gate line is also scanned after a half cycle, and Data corresponding to the characteristics of the panel (i.e., image signal) is applied to the selected gate line through a data driver, and the same operation is performed on subsequent gate lines, and a plurality of gate lines are provided for each cycle of the clock signal. The parallax overlapping scanning method of the field emission indicator characterized by the above-mentioned.

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