Flat Display Apparatus and Control Circuit and Method for Controlling the same

Abstract

In an exemplary flat display apparatus and control circuit and method for controlling the flat display apparatus, the flat display apparatus includes a plurality of gate driving units, each of which controls the operation of a scan line in the flat display apparatus. The flat display apparatus provides a first gate high level voltage signal and a second gate high level voltage signal to the gate driving units such that the first and second gate high level voltage signals are used as voltage signals transmitted to corresponding scan lines. The first and second gate high level voltage signals respectively include a falling edge with a slope. Duration time of the falling edge of the first gate high level voltage signal is longer than that of the falling edge of the second gate high level voltage signal.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefit of priority from the prior Taiwanese Patent Application No. 097103014, filed Jan. 25, 2008, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates to a flat display apparatus, a control circuit and a control method employed therein, especially a flat display apparatus using different signals to drive horizontal scanning lines of the flat display device, a control circuit and a control method for controlling the flat display apparatus

2. Description of the Related Art

Flat display devices such as liquid crystal displays have been widely used in all kinds of electronic devices. With the extending demands of customers, sizes of display screen of the flat displays have developed from small size originally employed in portable computers to middle size employed in desktop computers, and then to large size employed in family cinema gradually. It is important to maintain a displaying uniformity of a whole screen with the increasing size of the display screen.

Following the increasing size of the display device, amount of display unit defined in the display device for displaying image called as pixel is also increasing. Even a refresh frequency of an image does not increase, a transition of voltage level of scanning signal must be faster to satisfy a displaying demand because of the increasing pixels. However, the faster transition of voltage level results in a feed-though effect of a capacitor generated by a capacitive coupling effect, which causes a stored voltage of the pixel changed. Therefore, the displaying uniformity is challenged in both horizontal and vertical directions.

Referring to FIG. 7, a block diagram of a typical liquid crystal display is shown. The liquid crystal display 10 includes a control circuit 100, a data driving module 110, a gate driving module 120, and a display panel 130. The control circuit 100 receives display data and all kinds of control data needed for displaying. The control circuit 100 transforms the display data and a part of the control data to first signals needed by the data driving module 110, and outputs the first signals to the data driving module 110. The control circuit 100 transforms the other part of the control data to second signals needed by the gate driving module 120 and outputs the second signals to the gate driving module 120. The data driving module 110 drives the data lines 112, 114 according to the received first signals, and the gate driving module 120 drives the scanning lines 122, 124 according to the received second signals. In the display panel 130, each pixel 132 denoted by a dotted frame is formed at the intersections of the data line 112, 114 and the scanning line 122, 124

Referring to FIG. 8A and FIG. 8B, FIG. 8A is an equivalent circuit diagram of a pixel 132 of the liquid crystal display 10 in FIG. 7, and FIG. 8B is a signal wave diagram of a driving signal employed in the gate driving module 120 in FIG. 7 for driving the gate line 122. The pixel 132 includes a thin film transistor 200, a liquid crystal capacitor C_LC, a storage capacitor C_S, and a parasitic capacitor C_GD. The gate electrode 200c of the thin film transistor 200 is electrically coupled to the scanning line 122. The source electrode 200a of the thin film transistor 200 is electrically coupled to the data line 114. The drain electrode 200b of the thin film transistor 200 is electrically coupled to a terminal of the liquid crystal capacitor C_LC, a terminal of the storage capacitor C_S, and a terminal of the parasitic capacitor C_GD. The other terminal of the liquid crystal capacitor C_LC and the other terminal of the storage capacitor C_S are configured for receiving a common voltage V_COM. The other terminal of the parasitic capacitor C_GD is electrically connected to the scanning line 122.

As shown in FIG. 8B, when the scanning signal is provided to the scanning line 122, after a low level voltage Vgl changes to reach a high level voltage Vgh via a rising edge RE, the thin film transistor 200 is turned on due to the high level voltage Vgh been provided to the gate electrode 200c. On the contrary, when the high level voltage Vgh changes to reach a low level voltage Vgl via a falling edge FE, the thin film transistor 200 is turned off due to the decreasing voltage provided to the gate electrode 200c. However, a fast transition of the voltage at the rising edge RE and the falling edge FE results in a capacitive coupling effect of the parasitic capacitor C_GD between the gate 200c and drain electrodes 200b of the thin film transistor 200. Thus, a voltage maintain at the drain electrode 200b is changed to make a potential crossing the liquid crystal capacitor C_LC deviated from a original pre-stored potential. A difference of the actual potential crossing the liquid crystal capacitor C_LC and the original pre-stored potential is call as a feed-though voltage V_f.

If the feed-though voltages V_f in all the display panel 130 are same, a problem caused by the feed-though voltage V_f can easily be solved. However, in fact, the feed-though voltages V_f respectively corresponding to each pixel in all the display panel 130 are different. In the horizontal direction, the difference of the feed-though voltages V_f are mainly caused by a signal delay of the scanning lines which make an operation of turning off the thin film transistors 200 arranged in a same scanning line inconsistent. In the vertical direction, the difference of the feed-though voltages V_f are mainly caused by a voltage drop of a current and a resistance. When the gate high level voltage Vgh and the gate low level voltage Vgl are provided to the display panel 130, the wires layout made from different conducting lines, such as metal lines or thin film lines, generate voltage drop thereof. In any case, when signals transmit along the conducting lines (gate lines), a voltage difference (Vgh−Vgl) of the gate lines is gradually decreased with the signals been transmitted downward along the gate lines. The feed-through voltage V_f can be obtained according to following formula:

$V_f=\left(V_{\mathrm{gh}}-V_{\mathrm{gl}}\right)\frac{C_{\mathrm{GD}}}{C_S+C_{\mathrm{LC}}+C_{\mathrm{GD},\mathrm{ON}}}$

wherein C_GD,ON is a parasitic capacitor of the conductive thin film transistor 200. That is, if the voltage difference (Vgh−Vgl) of the gate lines varies in the vertical direction, the feed-through voltage V_f is inevitably changes following the variation of the voltage difference.

To solve the above described problems, many solutions are provided. These solutions are all aimed at solving the uneven display generated by the feed-through effect of the scanning lines arranged in the horizontal direction. In fact, these solutions did achieve some improvement in a manner, such as U.S. Pat. No. 6,359,607, U.S. Pat. No. 6,867,760, U.S. Pat. No. 7,027,024 and US published application No. 2006/0077163, et al. However, after experimental proof, these solutions can only solve a problem of uneven display in the horizontal direction and can not solve the uneven display in the vertical direction. The following chart 1 shows a plurality of voltage differences (Vgh−Vgl) at corresponding areas in a 40 inches LCD panel (it is assumed that the 40 inches LCD panel is divided into sixteen areas arranged as a 4×4 matrix) when normal signals are provided to the 40 inches LCD panel.

	CHART 1
	5.99	6.27	6.31	6.25
	6.00	6.27	6.31	6.25
	6.00	6.26	6.31	6.24
	6.02	6.28	6.33	6.28

After employing the technology provided by the U.S. Pat. No. 6,359,607, the voltage differences (Vgh−Vgl) at corresponding areas of the same LCD panel are shown in Chart 2.

	CHART 2
	6.23	6.29	6.35	6.31
	6.26	6.32	6.37	6.33
	6.26	6.32	6.37	6.33
	6.27	6.33	6.37	6.37

To sum up, after using the technology provided by the U.S. Pat. No. 6,359,607, the voltage differences (Vgh−Vgl) in the horizontal direction may be improved in a manner. However, the voltage differences (Vgh−Vgl) in the vertical direction is not only improved, but also become larger than that using original technology in a manner. In other words, after using the technology, the uniformity of displaying in the vertical direction becomes worse.

SUMMARY OF THE INVENTION

In one aspect, an exemplary control method for a flat display apparatus is provided. The flat display apparatus includes a plurality of gate driving units each of which controls the operation of a scan line. The method comprises providing a first gate high level voltage signal and a second gate high level voltage signal to the gate driving units such that the first and second gate high level voltage signals are used as voltage signals transmitted to corresponding scan lines. The first and second gate high level voltage signals respectively include a falling edge with a slope. A duration time of the falling edge of the first gate high level voltage signal is longer than that of the falling edge of the second gate high level voltage signal.

In the exemplary embodiment, the above described control method firstly generate a original gate high level voltage signal with fixed frequency, a first chamfering control signal, and a second chamfering control signal, then generate the first gate high level voltage signal by gradually decreasing the voltage of the original gate high level voltage signal in an duty cycle of the first chamfering control signal. the second gate high level voltage signal can similarly be generated by gradually decreasing the voltage of the original gate high level voltage signal in another duty cycle of the second chamfering control signal. The duty cycle of the first chamfering control signal is longer than that of the second chamfering control signal.

In another aspect, an exemplary control circuit of a flat display apparatus is provided. The flat display apparatus employs an enable signal to turn on a plurality of scanning lines thereof. The control circuit includes a signal generating module, a first gate driving unit, a second gate driving unit. The signal generating module is configured for generating a first gate high level voltage signal and a second gate high level voltage signal. The first gate driving unit is electrically coupled to the signal generating module and configured for receiving the first gate high level voltage signal as a voltage signal for providing to one of the scanning lines. The second gate driving unit is electrically coupled to the signal generating module and configured for receiving the second gate high level voltage signal as a voltage signal for providing to other one of the scanning lines. The first gate driving unit and the second gate driving unit are electrically coupled to each other so as to sequentially transmit the enable signal. The first gate high level voltage signal and second gate high level voltage signal respectively include a falling edge with a slope. A duration time of the falling edge of the first gate high level voltage signal is longer than that of the falling edge of the second gate high level voltage signal.

In the exemplary embodiment, the above described signal generating module includes the chamfering control signal generating unit and gate high level voltage signal generating unit. The chamfering control signal generating unit is used for generating the first chamfering control signal and the second chamfering control signal with different duty cycles. The gate high level voltage signal generating unit is electrically coupled to the chamfering control signal generating unit so as to receive the first chamfering control signal and the second chamfering control signal and respectively change a falling edge of the original gate high level voltage signal to generate the first and second gate high level voltages according to the first and second chamfering control signal.

Still in another aspect, an exemplary flat display apparatus is provided. The flat display apparatus includes a display panel, a plurality of data driving units, and a control circuit. The display panel includes a plurality of data lines, a plurality of scanning lines, and a plurality of pixel units. The data lines are paralleled extended on the display panel along a first direction for transmitting image data used for display image. The scanning lines are paralleled extended on the display panel along a second direction. The pixel units are positioned adjacent the intersections of the data lines and the scanning lines. The scanning lines are configured for turning on/off the pixel units. The data driving units are respectively electrically coupled to the data lines for providing the image data used for displaying image. The control circuit includes a signal generating module, a first gate driving unit, and a second gate driving unit. The signal generating module is configured for generating a first gate high level voltage signal and a second gate high level voltage signal. The first gate driving unit is electrically coupled to the signal generating module and configured for receiving the first gate high level voltage signal as a voltage signal for providing to one of the scanning lines. The second gate driving unit is electrically coupled to the signal generating module and configured for receiving the second gate high level voltage signal as a voltage signal for providing to other one of the scanning lines. The first gate driving unit and the second gate driving unit are electrically coupled to each other so as to sequentially transmit the enable signal. The first gate high level voltage signal and second gate high level voltage signal respectively include a falling edge with a slope. A duration time of the falling edge of the first gate high level voltage signal is longer than that of the falling edge of the second gate high level voltage signal.

Aforementioned embodiments of the present invention provide different driving signals to different gate driving units, and the falling edges have a same slope and a different duration time. Thus different compensations for different feed-through voltages are provided according to different position of the display panel. An experiment proves that this method can provides a uniform display in the vertical direction.

Other objectives, features and advantages of the touch panel device will be further understood from the further technological features disclosed by the embodiments of display system wherein there are shown and described preferred embodiments of this flat display apparatus, simply by way of illustration of modes best suited to carry out the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the various embodiments disclosed herein will be better understood with respect to the following description and drawings, in which like numbers refer to like parts throughout, and in which:

FIG. 1 is circuit block diagram of a flat display apparatus according to a first embodiment.

FIG. 2 is a signal wave diagram showing two different gate high level voltages signals.

FIG. 3 is a flow chart of generating gate high level voltage signals with different duration time according to an exemplary embodiment.

FIG. 4 is a schematic diagram illustrating generating gate high level voltage signals having falling edges with different duration time.

FIG. 5 is a circuit block of a signal generating module according to an exemplary embodiment.

FIG. 6 is a circuit block of a control circuit according to an alternative embodiment.

FIG. 7 is a circuit block diagram of a conventional liquid crystal display.

FIG. 8A is an equivalent circuit diagram of a pixel of the liquid crystal display of FIG. 7.

FIG. 8B is a signal wave diagram of a driving signal employed in a gate driving module of FIG. 7 for driving a scanning line.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made in detail to the present preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.

Referring to FIG. 1, a block diagram of a flat display apparatus 30 according to a first embodiment is shown. In the exemplary embodiment, the flat display apparatus 30 includes a display panel 300, a data driving module 31, and a control circuit 32. A plurality of data lines 340, 342, 344, a plurality of scanning lines 350, 352, 354 and a plurality of pixel units 360, 362, 364 positioned adjacent the intersections of the data lines 340, 342, 344 and the scanning lines 250, 352, 354 are all arranged in the display panel 300.

The data driving module 31 includes a plurality of data driving unit 310, 312 and 314. The control circuit 32 includes a plurality of gate driving units 320, 322, 324 and a signal generating module 330. An equivalent circuit of each pixel unit of the pixel units 360, 362, 364 is shown in FIG. 8A. The number of the above described data lines, scanning lines, pixel units, data driving units, gate driving units and signal generating module is illustrated to conveniently describe this embodiment but not limited.

As showing in the FIG. 1, the data lines 340, 342, and 344 are paralleled extended on the display panel 300 along a special direction, hereafter call as a first direction. The scanning lines 350, 352 and 354 are paralleled extended on the display panel 300 along another special direction, hereafter call as a second direction. The data lines 340, 342, 344 are used to transmit image data configured for displaying image. The scanning lines 350, 352, 354 are respectively used to transmit scanning signals configured for turning on/off the pixel units 360, 362, 364.

When the scanning lines 350, 352, 354 are used to transmit scanning signals configured for turning on the pixel units 360, 362, 364, the gate driving units 320, 322, 324 need to provide corresponding gate high level voltage signals to the scanning lines 350, 352, 354. In the exemplary embodiment, the gate high level voltage signals provided by the gate driving units 320, 322, 324 and enable signals for controlling those gate driving units 320, 322, 324 to be actuated are generated by the signal generating module 330.

The enable signals are sequentially transmitted along a direction from the gate driving unit 320 to the gate driving units 322, 324 and gradually far from the signal generating module 330. As soon as an enable signal is transmitted to start up one of the gate driving units, such as the gate driving unit 322, the gate driving unit permits the received gate high level voltage signals to be passed therefrom and transmitted to the corresponding scanning line, such as the scanning line 352. In addition, according to feed-through effect with different degrees, the signal generating module 330 generates at least two different gate high level voltage signals and provides to the gate driving units 320, 322, 324.

Referring to FIG. 2 together, a signal wave diagram of the two different gate high level voltage signals is shown. Operating periods of the gate high level voltage signals 400 and 410 are substantially same. The gate high level voltage signals 400 and 410 have two falling edges 400a and 410a with inclination respectively. The inclination of the falling edge 400a has a slope the same as that of the inclination of the falling edge 410a. However, a duration time of the falling edge 400a of the gate high level voltage signals 400 is different from that of the falling edge 410a of the gate high level voltage signals 410. In the exemplary embodiment, the duration time of the falling edge 400a is t1, the duration time of the falling edge 410a is t2 and t1 is longer than t2. Because the feed-through voltages V_f respectively corresponding to the pixel units of the display panel 300 are different.

Particularly in the vertical direction, the difference of the feed-through voltages V_f are mainly caused by a voltage drop of a current and a resistance. When the gate high level voltage Vgh and the gate low level voltage Vgl are provided to the display panel 300, and transmitted along metal lines or thin film lines (on the display panel 300), the voltage difference (Vgh−Vgl) of the gate lines is gradually decreased with the signals being transmitted downward along the conductive lines 326 in the control circuit 32. The feed-through voltage V_f can be obtained according to following formula:

$V_f=\left(V_{\mathrm{gh}}-V_{\mathrm{gl}}\right)\frac{C_{\mathrm{GD}}}{C_S+C_{\mathrm{LC}}+C_{\mathrm{GD},\mathrm{ON}}}$

wherein, C_GD,ON is a parasitic capacitor of a conductive thin film transistor 200 of FIG. 8A. Because the gate driving unit far from the signal generating module 330 (as showing in FIG. 1, a distance between the gate driving unit 322 and the signal generating module 330 is farther than the distance between the gate driving unit 320 and the signal generating module 330) has a lesser voltage difference (Vgh−Vgl), the corresponding feed-through voltage V_f is decreased. Thus, the high level voltage signal 400a having a falling edge with the longer duration time, hereafter call as a first high level voltage signal, is provided to a gate driving unit close to the signal generating module 330. The high level voltage signal 410a having a falling edge with the shorter duration time, hereafter call as a second high level voltage signal, is provided to a gate driving unit far away from the signal generating module 330.

The following description will explain how to generate the gate high level voltage signals with different duration time. Referring to FIG. 3, a flow chart of generating gate high level voltage signals with different duration time is shown according to an exemplary embodiment.

Step S500 is generating an original gate high level voltage signal defined as a basis. Step S510 is generating a plurality of chamfering control signals, each of which has a different duty cycle. Step S520 is generating a plurality of different gate high level voltage signals by respectively gradually decreasing the voltage of the original gate high level voltage signal in the different duty cycles of the corresponding chamfering control signals.

The original gate high level voltage signal generated in step S500 can be denoted by any one of the original gate high level voltage signals 600, 610, 620 as showing in FIG. 4. An amplitude of the original gate high level voltage signal is vibrated between the gate high level voltage Vgh and the gate low level voltage Vgl. An exemplary chamfering control signals referred in the step S510 can be denoted by chamfering control signals 600a, 610a, 620a as showing in FIG. 4. The chamfering control signals 600a, 610a and 620a respectively have a different duty cycle t₃, t₄ and t₅.

As showing in FIG. 4, the original gate high level voltage signals 600, 610 and 620 respectively correspond to the chamfering control signals 600a, 610a and 620a.

The voltage of the original gate high level voltage signal 600 is gradually decreased in the duty cycle t₃ of the chamfering control signal 600a by a fixed slope to form a gate high level voltage signal 600b with a falling edge 601. Similarly, the voltage of the original gate high level voltage signal 610 is gradually decreased in the duty cycle t₄ of the chamfering control signal 610a by the fixed slope to form a gate high level voltage signal 610b with a falling edge 611, and the voltage of the original gate high level voltage signal 620 is gradually decreased in the duty cycle t₅ of the chamfering control signal 620a by the fixed slope to form a gate high level voltage signal 620b with a falling edge 621.

Although in the exemplary embodiment of FIG. 4, the corresponding gate high level voltage signals are generated by using a plurality of original high level voltage signals, in an alternative embodiment, the corresponding gate high level voltage signals can also be generated in a manner as showing in FIG. 5. That is, only one original high level voltage signal is generated and transmitted to a plurality of circuits to generate different gate high level voltage signals after the original high level voltage signal being processed respectively in accordance with corresponding chamfering control signals.

Referring to FIG. 5, a block diagram of an exemplary signal generating module 70 is shown. The signal generating module 70 includes a chamfering control signal generating unit 700 and a gate high level voltage signal generating unit 710. The gate high level voltage signal generating unit 710 includes an original signal generating unit 712, and a plurality of processing circuits 714, 716 . . . 718. The chamfering control signal generating unit 700 is configured to generate a plurality of different chamfering control signals YC1,YC2 . . . YCn and provide the chamfering control signals YC1,YC2 . . . YCn to the gate high level voltage signal generating unit 710.

The original signal generating unit 712 is firstly employed to generate an original gate high level voltage signal as showing in FIG. 4 and respectively provide the original gate high level voltage signal to the processing circuits 714, 716 . . . 718. At the same time, the processing circuits 714, 716 . . . 718 respectively process the received the chamfering control signals YC1,YC2 . . . YCn incorporated with the original gate high level voltage signal to obtain corresponding high level voltage signals VG1, VG2 . . . VGn.

Understandably, in an alternative embodiment, the original gate high level voltage signal employed in the gate high level voltage signal generating unit 710 can also be generated by other circuit of the flat display device 30 and then provided to the gate high level voltage signal generating unit 710. The above described exemplary circuit is given by way of example, and not limitation.

Except the above described circuit and method of the exemplary embodiments, a plurality of detailed adjusting parts of an alternative embodiment of the present invention are also provided. For example, referring to FIG. 6, a block diagram of an exemplary control circuit 82 according to an alternative embodiment is shown. In the exemplary embodiment, the control circuit 82 includes a signal generating module 830 and a plurality of gate driving units 820, 822, 824 et al. The signal generating module 830 provides different gate high level voltage signals to the gate driving units 820, 822, 824 via a respective conducting line. In FIG. 1, the gate driving units 320, 322, 324 are electrically coupled to the signal generating module 300 via a same conducting line or a same electronic route. Thus the gate high level voltage signals provided by the signal generating module 330 can all be received by each of the gate driving units 320, 322 and 324.

Comparing with FIG. 1, the gate driving units 820, 822 and 824 of the control circuit 82 showing in FIG. 6 are respectively electrically connected to the signal generating module 830 via different conducting lines, thus each gate high level voltage signal can be independently transmitted to the corresponding gate driving unit.

In further alternative embodiments, for example, a plurality of gate driving units can be defined as a gate driving group for using a same gate high level voltage signal. The chamfering control signal generating unit 700 showing in FIG. 5 can also serially output the chamfering control signals YC1, YC2 . . . YCn in a certain order. A circuit design layout of the signal generating module the can also be adjusted as long as the essential technology of the present invention can be achieved.

Because the gate high level voltage signals are generated by decreasing with a same slope in different duration time, the voltage drops in a moment is somewhat changed. Therefore, different compensation effects can be provided according to the feed-through effect generated by the momentary changed voltage drop.

The above description is given by way of example, and not limitation. Given the above disclosure, one skilled in the art could devise variations that are within the scope and spirit of the invention disclosed herein, including configurations of the circuit and/or designs of the control method. Further, the various features of the embodiments disclosed herein can be used alone, or in varying combinations with each other and are not intended to be limited to the specific combination described herein. Thus, the scope of the claims is not to be limited by the illustrated embodiments.

Claims

1. A method for controlling a flat display apparatus comprising a plurality of gate driving units, each of which controls the operation of a scan line in the flat display apparatus, the method comprising:

providing a first gate high level voltage signal and a second gate high level voltage signal to the gate driving units respectively such that the first and second gate high level voltage signals are used as gate voltage signals transmitted to corresponding scan lines,

wherein the first and second gate high level voltage signals respectively comprises a falling edge with a slope, and a duration time of the falling edge of the first gate high level voltage signal is longer than a duration time of the falling edge of the second gate high level voltage signal.

2. The method as claimed in claim 1, wherein the step of providing the first gate high level voltage signal and the second gate high level voltage signal comprises:

providing the first gate high level voltage signal to a first gate driving unit of the gate driving units; and

providing the second gate high level voltage signal to a second gate driving unit of the gate driving units,

wherein an enable signal is employed to actuate the gate driving units, the gate driving units being arranged in series so as to receive the enable signal in order.

3. The method as claimed in claim 1, further comprising:

generating an original gate high level voltage signal with a fixed duty cycle;

generating a first chamfering control signal and a second chamfering control signal;

generating the first gate high level voltage signal by gradually decreasing the voltage of the original gate high level voltage signal in a first duty cycle of the first chamfering control signal;

generating the second gate high level voltage signal by gradually decreasing the voltage of the original gate high level voltage signal in a second duty cycle of the second chamfering control signal,

wherein the first duty cycle of the first chamfering control signal is longer than the second duty cycle of the second chamfering control signal.

4. A control circuit of a flat display apparatus, the control circuit comprising:

a signal generating module for generating a first gate high level voltage signal and a second gate high level voltage signal;

a first gate driving unit electrically coupled to the signal generating module and configured for receiving the first gate high level voltage signal as a voltage signal to be provided to one of scanning lines of the flat display apparatus; and

a second gate driving unit electrically coupled to the signal generating module and configured for receiving the second gate high level voltage signal as a voltage signal to be provided to other one of the scanning lines,

wherein the first gate driving unit and the second gate driving unit are electrically coupled to each other so as to sequentially be enabled, and the first gate high level voltage signal and the second gate high level voltage signal respectively comprise a falling edge with a slope, a duration time of the falling edge of the first gate high level voltage signal is longer than a duration time of the falling edge of the second gate high level voltage signal.

5. The control circuit as claimed in claim 4, wherein the signal generating module comprises:

a chamfering control signal generating unit configured for generating a first chamfering control signal and a second chamfering control signal with different duty cycles; and

a gate high level voltage signal generating unit electrically coupled to the chamfering control signal generating unit for receiving the first chamfering control signal and the second chamfering control signal, and configured for generating the first gate high level voltage signal and second gate high level voltage signal by referring to a falling edge of an original gate high level voltage signal which is changed respectively according to the first chamfering control signal and the second chamfering control signal.

6. The control circuit as claimed in claim 4, wherein the first gate driving unit and the second gate driving unit are electrically coupled to the signal generating module via a same electronic route.

7. The control circuit as claimed in claim 4, wherein the first gate driving unit and the second gate driving unit are electrically coupled to the signal generating module via a respective electronic route.

8. The control circuit as claimed in claim 4, wherein the signal generating module comprises:

a chamfering control signal generating unit for generating a plurality of chamfering control signals; and

a gate high level voltage signal generating unit comprising: an original signal generating unit for generating an original gate high level voltage signal; and a plurality of processing circuits, each of which receives the original gate high level voltage signal and corresponding one of the chamfering control signals,

wherein, each of the processing circuits respectively processing the received chamfering control signals incorporated with the original gate high level voltage signal to obtain corresponding one gate high level voltage signal.

9. A flat display apparatus comprising:

a display panel comprising: a plurality of data lines paralleled extended on the display panel along a first direction for transmitting image data used for display image; a plurality of scanning lines paralleled extended on the display panel along a second direction; and a plurality of pixel units positioned adjacent the intersections of the data lines and the scanning lines, the scanning lines being configured for turning on/off the pixel units;

a plurality of data driving units respectively electrically coupled to the data lines for providing image data for displaying image; and

a control circuit comprising: a signal generating module configured for generating a first gate high level voltage signal and a second gate high level voltage signal; a first gate driving unit electrically coupled to the signal generating module and configured for receiving the first gate high level voltage signal as a voltage signal to be provided to one of the scanning lines; and a second gate driving unit electrically coupled to the signal generating module and configured for receiving the second gate high level voltage signal as a voltage signal to be provided to other one of the scanning lines, wherein the first gate driving unit and the second gate driving unit are electrically coupled to each other so as to sequentially transmit an enable signal for determining which gate driving unit is enabled, and the first gate high level voltage signal and second gate high level voltage signal respectively comprise a falling edge with a slope, a duration time of the falling edge of the first gate high level voltage signal is longer than that of the falling edge of the second gate high level voltage signal.

10. The flat display apparatus as claimed in claim 9, wherein the signal generating module comprises:

a chamfering control signal generating unit configured for generating a first chamfering control signal and a second chamfering control signal with different duty cycles; and

a gate high level voltage signal generating unit electrically coupled to the chamfering control signal generating unit for receiving the first chamfering control signal and the second chamfering control signal, and configured for generating the first gate high level voltage signal and the second gate high level voltage signal by referring to a duration time of a falling edge of the original gate high level voltage signal which is changed respectively according to the first chamfering control signal and the second chamfering control signal.

11. The flat display apparatus as claimed in claim 9, wherein the first gate driving unit and the second gate driving unit are electrically coupled to the signal generating module via a same electronic route.

12. The flat display apparatus as claimed in claim 9, wherein the first gate driving unit and the second gate driving unit are electrically coupled to the signal generating module via a respective electronic route.

13. The flat display apparatus as claimed in claim 9, wherein the signal generating module comprises:

a chamfering control signal generating unit for generating a plurality of chamfering control signals; and

a gate high level voltage signal generating unit comprising: an original signal generating unit for generating an original gate high level voltage signal; and a plurality of processing circuits, each of which receives the original gate high level voltage signal and corresponding one of the chamfering control signals,

wherein, each of the processing circuits respectively processing the received chamfering control signals incorporated with the original gate high level voltage signal to obtain corresponding one gate high level voltage signal.