Abstract:
A driving system of an liquid crystal display (LCD) device and an LCD driving method in which an insufficient charging of a liquid crystal capacitor caused by a delayed time taken for raising source and gate signals applied to each pixel of the LCD panel to normal voltage levels is overcome by delaying the source signal output by a predetermined number of source driver IC units or by delaying the gate signal that is output by a predetermined number of gate driver IC units, includes a power supply unit, a controller, a gray voltage generating unit, a gate voltage generating unit, a source drive unit, a gate drive unit, and a liquid crystal panel, wherein the source drive unit or the gate drive unit has a delay unit for delaying an enable signal or a load signal, to thereby output delayed source and gate signals. As a result, a charging rate of the liquid crystal capacitor of pixels contained in the liquid crystal panel is enhanced, which prevents a degradation of the screen and ensures a uniformity achieving a large screen and a high resolution.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a driving system of a liquid crystal display (LCD) device, and more particularly, to a driving system of an LCD device and an LCD driving method in which an insufficient charging of a liquid crystal capacitor caused by a delayed time taken for raising source and gate signals applied to each pixel of the LCD panel to normal voltage levels is overcome by delaying the source signal generated by a predetermined number of source driver IC units or by delaying the gate signal output by a predetermined number of gate driver IC units. 
     2. Description of the Related Art 
     An LCD device is a widely used form of a flat panel display. It takes advantage of light transmittance variations of liquid crystal depending on the voltages applied to each pixel. Especially, the smaller dimension, lighter weight and lower power consumption make an LCD device replace a traditional cathode ray tube (CRT). 
     LCD devices consist of a liquid crystal panel module, a backlight assembly, and other fixtures. The liquid crystal panel module is a liquid crystal panel with a printed circuit board (PCB) attached. Source driver ICs, gate driver ICs and other components, for example, a controller, are mounted onto the PCB. 
     A liquid display panel displays an image. Data signals and gate signals are applied to each pixel of the liquid crystal panel. A gate signal is applied to a gate electrode of a thin film transistor (TFT) via a gate line formed in the liquid crystal panel. 
     The TFT is turned on or off according to a level of the gate voltage. When the TFT is turned on or off according to a gate voltage, the liquid crystal array changes according to the electric field between a pixel electrode and an opposing electrode determined by a voltage level applied to a source electrode. Thus, the liquid crystal capacitor is charged, which varies the degree of light transmittance. 
     A liquid crystal display displays a certain image according to the above-described method. 
     Referring to FIG. 1, a gate drive unit  4  having a plurality of gate driver ICs applies gate signals to a liquid crystal panel  2  and a data drive unit  6  having a plurality of source driver ICs applies source signals to a liquid crystal panel  2 . Gate drive unit  4  sequentially applies gate signals to the liquid crystal panel  2  vertically in order to turn on and turn off the pixel. Data drive unit  6  sequentially applies source signals to the liquid crystal panel  2  horizontally to charge the liquid crystal. A timing for applying gate voltages and source voltages is set as shown in FIG.  2 A. 
     However, generally, the gate signal is gradually delayed as it goes from position A toward position B of liquid crystal panel  2 , and the source signal is delayed as it goes from position A toward position C. 
     In more detail, as shown in FIG. 2A, the voltages applied for gate signals and source signals are in order at position A of FIG.  1 . The gate voltage swings between turn-on voltage Von of 20V and turn-off voltage Voff of −-7V, and the source voltage has a black level which varies in accordance with a positive or a negative polarity. 
     Voltages of the source signal for each pixel swing between voltage V+ and voltage V− for indicating a specific grey level according to the polarity. In FIG. 2, G and S respectively denote the gate voltage and the source voltage. A data signal is applied to a source electrode of TFT as a gray voltage. Hereinafter, data signals and source signals may be used interchangeably. 
     Source signals and gate signals have timings according to a preset sequence as shown in FIG. 2A. A gate signal rises a certain period after a source signal has risen. The source signal falls down a certain period after the gate signal has fallen. When the source signal maintains the voltage level of V+, the gate signal transits to the turn-on level. Thus, a TFT turns on a pixel and the signal is charged to the liquid crystal capacitor. The source signal charges the liquid crystal capacitor during the time gap Ts, and the lowered gate signal turns off the TFT and pixel during the time gap Tg. These time gaps are adjustable. 
     Meanwhile, the liquid crystal panel  2  has a resistance and a capacitance due to the gate lines and the data lines. The resistance and the capacitance change the waveforms of source signals and gate signals at each position, as shown in FIG.  2 . The waveforms change more as getting away from the terminal where signals are applied. Therefore, as shown in FIGS. 2B and 2D, the waveform of the gate signal changes slowly as getting away from the gate drive unit  4 , and as shown in FIGS. 2C and 2D, the waveform of the source signal changes slowly as getting away from the data drive unit  6 . 
     In general, a scanning period of a gate line gets shorter as high resolution and large screen products are developed. When driving a liquid crystal display as shown in FIG. 2, a conventional driving method may not secure a sufficient turn-on time for the pixel. Especially, pixels may be dramatically undercharged when the line resistance and capacitance affect the source signals and the gate signals. This degrades the picture quality and an overall uniformity of display. 
     As the technology for a high resolution and large screen display develops, a need has risen for a method to secure a sufficient charging time for the liquid crystal capacitor even when a gate line scanning period gets shorter. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of the present invention to adjust a source signal to be delayed by data line units connected to a source driver IC, considering that it takes longer for gate signals and source signals to rise to the level required for charging the liquid crystal capacitor as getting away from the terminal to which gate signals and source signals are applied. This ensures a turn-on time period of a pixel and enhances a charging rate of a liquid crystal capacitor. 
     It is another object of the present invention to adjust a gate signal to be delayed by gate line units connected to a gate driver IC, considering that it takes longer for gate signals and source signals to rise to the level required for charging the liquid crystal capacitor as getting away from the terminal to which gate and source signals are applied. It also ensures a turn-on time period of a pixel and enhances a charging rate of a liquid crystal capacitor. 
     According to one aspect of the present invention, there is provided a driving system of an LCD device including a power supply unit for supplying a direct current voltage, a controller for outputting data and control signals for forming a selected image, a gray voltage generating unit for generating a plurality of gray voltages using a voltage supplied from the power supply unit, a gate voltage generating unit for outputting a gate voltage using the voltage supplied from the power supply unit, a source drive unit for outputting source signals with an input of the data, a portion of the signal contained in the control signals, and the gray voltages, a gate drive unit for outputting gate signals by having other portion of the signal contained in the control signals, and a gate turn-off or turn-on voltage applied thereto, and a liquid crystal panel for displaying the image driven by the gate and source signals applied thereto. 
     Here, the data drive unit includes a delay part that accepts a load signal and outputs load signals delayed as passing through a first, a second, a third, . . . , and an mth delay units, and n number of source driver ICs that outputs a certain number of source signals according to the control signals (n≧m). Load signals from the delay units are applied to at least one source driver IC that outputs the source signal delayed according to the delay time of the load signal. 
     The delay part consists of a serially arranged delay units having a resistance and a capacitor arranged in parallel. It delays the load signal. Preferably, the first input load signal and the delayed load signal coming from each delay unit are input to at least one source driver IC. The delay unit corresponds one-to-one to the source driver IC or one-to-many to the source driver ICs. 
     According to another aspect of the present invention, there is provided a driving system of an LCD device including a power supply unit for supplying a DC voltage, a controller for outputting data and control signals for forming a selected image, a gray voltage generating unit for generating a plurality of gray voltages using the voltage applied from the power supply unit, a gate voltage generating unit for outputting a gate turn-on and turn-off voltage using the voltage applied from the power supply unit, a source drive unit for outputting source signals by having the data, a portion of the signal contained in the control signals, and the gray voltage which are input thereto, a gate drive unit for outputting gate signals by having other portion of the signal contained in the control signals, and the gate turn-on or turn-off voltage are applied thereto, and a liquid crystal panel for displaying the image being driven by the gate and source signal applied thereto. 
     Here, the gate drive unit includes a delay part that accepts an enable signal and outputs enable signals delayed as passing through a first, a second, a third, . . . , and an xth delay units, and y number of gate driver ICs for outputting a predetermined number of gate signals being driven by the control signals (wherein, y≧x). Enable signals from the delay units are input to at least one gate driver IC that outputs the gate signal delayed according to the delay time of the enable signal. 
     The delay part consists of a serially arranged delay units having a resistance and a capacitor arranged in parallel. It delays each enable signal. Preferably, the first input enable signal and the delayed enable signals coming from each delay unit are input to at least one gate driver IC. The delay unit may correspond one-to-one to the gate driver IC or one-to-many to the gate driver ICs. 
     According to the present invention, there is provided a liquid crystal panel driving method in which gate signals and source signals are output to the liquid crystal panel by driving a plurality of gate and source driver ICs in accordance with a data signal for displaying an image, control signals, gray voltages, or a selectively applied gate turn-on or turn-off voltage and operating the liquid crystal panel by said gate and source signals, wherein the gate and the source signals has a sequence of the source signal rising, the gate signal turning on, the gate signal turning off, and the source signal falling, and the source signals are divided into a selected number of source line units, and applied to the liquid crystal panel being accumulatively delayed by a selected time from the time when the gate signal is turned off. 
     According to the present invention, there is provided a liquid crystal panel driving method, including the steps of outputting gate and source signals to the liquid crystal panel by driving a plurality of gate and source driver ICs in accordance with a data signal for displaying an image, control signals, gray voltages, or a selectively applied gate turn-on or turn-off voltage and operating the liquid crystal panel by a gate and a source signals, wherein the gate and the source signals has a sequence of the source signal rising, the gate signal turning on, the gate signal turning off, and the source signal falling, and the gate signals are divided into a selected number of gate line units, and applied to the liquid crystal panel being accumulatively delayed by a selected time from the time when the source signal is applied. 
     Here, the gate signal is accumulatively delayed for each gate driver IC and applied to the liquid crystal display. Preferably, the gate driver IC most adjacent to the output terminal of the source signal, from the liquid crystal panel, outputs a gate signal being delayed by total delay time divided by the total number of gate driver lCs after the source signal is output. Subsequently, the other gate driver ICs output gate signals delayed by the total time delay/total number of gate driver ICs. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above object and other advantages of the present invention will become more apparent by describing in detail the preferred embodiments thereof with reference to the accompanying drawings, in which: 
     FIG. 1 is a block diagram showing a conventional LCD module; 
     FIGS. 2A to  2 D illustrate waveforms of a gate voltage and a source voltage by pixel units of the liquid crystal panel shown in FIG. 1; 
     FIG. 3 is a block diagram showing an LCD device according to the present invention; 
     FIG. 4 is a detailed block diagram showing an individual source driver IC of the data drive unit shown in FIG. 3; 
     FIG. 5 is a detailed block diagram showing an individual gate driver IC of the gate drive unit shown in FIG. 3; 
     FIG. 6 is a block diagram showing a structure of the source driver ICs constituting the data drive unit shown in FIG. 3 according to a first embodiment of the present invention; 
     FIG. 7 is a circuit diagram of the delay unit shown in FIG. 6; 
     FIG. 8 illustrates a waveform of the delayed source signal according to a first embodiment of the present invention; 
     FIG. 9 illustrates waveforms of a gate voltage and a source voltage for each pixel according to a first embodiment of the present invention; 
     FIG. 10 is a block diagram showing a structure of the gate driver ICs constituting the gate drive unit shown in FIG. 3 according to a second embodiment of the present invention; 
     FIG. 11 illustrates a waveform of the delayed gate signal according to a second embodiment of the present invention; 
     FIG. 12 illustrates waveforms of gate and source signals for each pixel according to a second embodiment of the present invention; 
     FIG. 13 is a block diagram showing a variation of the first embodiment of the present invention; and 
     FIG. 14 is a block diagram showing a variation of the second embodiment of the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. 
     The first embodiment (FIGS. 6 to  9 ) of the present invention is for compensating for a delay of a gate line by delaying the source, signal, and the second embodiment (FIGS. 10 to  12 ) of the present invention is for compensating for a delay of a data line by delaying the gate signal. 
     Referring to FIG. 3, a controller  10  receives a selected color data and a control signal. A power supply unit  12  receives a DC power and supplies stable voltages to a controller  10 , a gray voltage generating unit  14 , and a gate voltage generating unit  16 . Gray voltage generating unit  14  provides gray voltages to a source drive unit  20 . Gate voltage generating unit  16  provides voltages to a gate drive unit  18  to generate a turn-on voltage and a turn-off voltage. Gate drive unit  18  and data drive unit  20  have a plurality of gate driver ICs and source driver ICs. 
     Controller  10  outputs control signals and data signals. Data signals determine gray levels for each pixel. Gate drive unit  18  receives control signals and data drive unit  20  receives data signals. 
     Data drive unit  20  applies source signals to the liquid crystal panel  22  and gate drive unit  18  applies gate signals to the liquid crystal panel  22 . 
     Liquid crystal panel  22  has a TFT at each intersection of matrix defined by gate lines and data lines. The source of the TFT receives a source signal and the gate of the TFT receives a gate signal. The TFT forms a storage capacitor C s  and liquid crystal capacitor C LC  at its drain. 
     FIG. 4 shows the structure of the individual source driver IC, which is a component of source drive unit  20 . It has a shift register  30 , a latch  32 , a digital-to-analog converter  34 , and a buffer  36 . A shift register  30  receives a horizontal clock signal H—CLK and a shift signal STH that have a predetermined frequency. Here, the horizontal clock signal H—CLK has a frequency of a master clock signal from the controller  10  divided by two or four. The shift signal STH is input by one pulse per one horizontal period. 
     Shift register  30  outputs pulses horizontally to latch  32  at every certain number of clocks, according to the horizontal clock signal H—CLK. A certain number of shift signals generate a carry-out signal. The carry-out signal is applied to the subsequent shift register (not shown). 
     Image data from controller  10  is serially input to latch  32 . The latch  32  then stores the data according to a shift sequence of shift register  30  and outputs data when it receives a load signal TP. 
     Digital-to-analog converter  34  encodes the data coming from latch  32  and selects the gray voltage for each source line. Then, the digital-to-analog converter  34  selects a voltage according to the encoding from the gray voltages generated by gray voltage generating unit  14  and outputs it to buffer  36 . Gray voltages are output for each line according to the sequence of the data input of latch  32 . 
     Buffer  36  receives gray voltages from digital-to-analog converter  34  and controls their output. Source signals are gray voltages applied to liquid crystal panel  22 . 
     Gate drive unit  18  consists of a plurality of delay units and gate driver ICs. Each gate driver IC has a shift register  40 , a level shifter  42 , and an amplifier unit  44 . 
     Shift register  40  receives a shift signal STV and a vertical clock signal V—CLK and outputs a plurality of signals in a vertical direction. Then, it generates a carry-out signal to feed another shift register as a carry-in signal. 
     Gate voltage generating unit  16  sends turn-on voltage Von and turn-off voltage Voff to level shifter  42 . Level shifter  42  converts input signals from shift register  40  to a turn-on voltage or a turn-off voltage level and outputs them to amplifier unit  44 . 
     Amplifier unit  44  amplifies the input signal to a predetermined gain value and sends it to liquid crystal panel  22  as a gate signal. Here, an output enable signal OE determines the output of amplifier unit  44 . 
     FIG. 4 is a detailed block diagram showing an individual source driver IC of the source drive unit shown in FIG.  3 . FIG. 6 shows data drive unit  20  made up of such source driver ICs as a first embodiment. 
     The number of source driver ICs of data drive unit  20  may vary according to the purpose and the resolution of products. The first embodiment consists of eight source driver ICs. 
     Data drive unit  20  as shown in FIG. 6 has source driver ICs  50  through  57  that receive horizontal clock signal H—CLK, gray voltages, and data. 
     Source driver IC  50  receives shift signal STH and transmits the carry-out signal to the subsequent driver IC  51 . The carry-out signal transmits from a source driver IC  51  through a source driver IC  57 . 
     A load signal TP is input to delay unit  60  and source driver IC  50 , and delayed by a predetermined time period sequentially passing through delay units  60  through  66 . Delay units  60  through  65  input load signals TP 1  through TP 6  to driver ICs  51  through  56  and delay units  61  through  66  respectively. Delay unit  66  inputs the final-delayed load signal TP 7  to source driver IC  57 . 
     If the total amount of source voltage delay time is “B”, load signal TP 1  is set to rise earlier than the gate signal by a period of “B” or longer. Then, each of load signals TP 2  through TP 7  are respectively delayed by a period of “B/ 8 ”, and applied to source driver ICs  51  through  57 . Output operation of the source signal will be explained in more detail with reference to FIG.  8 . 
     As shown in FIG. 7, the delay unit is made up of an RC delay circuit having a resistance R and a capacitor C. The signal to an input terminal  68  is delayed by a predetermined time period and output via an output terminal  69 . Here, a parasitic capacitor formed by data lines and gate lines can be used. 
     The first embodiment applies the source signal to the liquid crystal panel in a fashion that the source signal rises before the gate signal rises to a turn-on level and falls after the level of the gate signal falls down to a turn-off level, for a selected pixel. 
     The first embodiment sets the finally delayed source signal to fall down prior to or at lest at the same time when the gate signal transits to the turn-off level. Provided that the final delay time of the source signal is “Tg”, each source signal is delayed by “Tg/number of source driver ICs.” For example, source signal So 1  from source driver IC  50  falls down delayed by “Tg/number of source driver ICs”, after the gate signal transits to the turn-off level. Accordingly, source signals So 2  through So 7  that are respectively coming from source driver ICs  51  through  56  are accumulatively delayed by a period of “Tg/number of source driver ICs”. Thus, the source signal So 8  from source driver IC  57  falls down delayed by a period of Tg, after the gate signal starts to transit down to the turn-off level. 
     Delay operation of the source signal will be explained with reference to FIG. 8 hereinafter. Gate drive unit  18  outputs the gate signal at the falling edge of the output enable signal OE coming from controller  10 . Data drive unit  20  receives shift signal STH and load signal TP and source driver ICs  50  through  57  output source signals So 1  through So 8 . 
     When source driver IC  50  receives shift signal STH, it generates a carry-out signal through an internal operation of the shift register and transmits it to the subsequent source driver IC  51  as a carry-in signal. Source driver IC  52  in turn generates a carry-out signal through an internal operation of the shift register and inputs the same to the subsequent source driver IC  53  as a carry-in signal. In this manner, carry-out signals are sequentially input to source driver ICs. Each of source driver ICs  50  through  57  latches data, when received shift signal STH or the carry-out signal. Source driver ICs  50  through  57  output source signals to the liquid crystal panel when received the load signal. 
     Source driver ICs  50  through  57  output source signals delayed corresponding to the delay of load signals TP through TP 7  which are delayed by Tg/8, 2Tg/8, 3Tg/8, 4Tg/8 , . . . 8Tg/8(equals Tg) to a plurality of source lines. 
     Accordingly, source driver IC  51  has output source signal So 2  delayed by Tg/8 compared to the output source signal So 1  of source driver IC  50 , and source driver IC  52  in turn has output source signal So 3  delayed by Tg/8 compared to the output source signal So 2 . Thus, each source signal is accumulatively delayed. As a result, source signal So 8  of source driver IC  57  is delayed by 7 Tg/8 than source signal So 2 . 
     FIG. 9 shows source and gate signals applied to each pixel according to the first embodiment. Here, i) through iv) are source and gate signals applied to positions i) through iv) of liquid crystal panel  22  of FIG.  3 . Positions i) and ii) are for the pixels that receive a source signal at first, and positions i) and iii) are for the pixels that receive a gate signal at first. 
     At positions i) and iii) of liquid crystal panel  22 , the time gap between the transition of the gate signal to the turn-off level and the falling of the source signal is Tg/8. Pixels at positions i) and iii) receive. Source signal So 1  output from source driver IC  50  at the same time. In addition, turn-on period of the level of the gate signal is contained in a period when the source signal has a normal level. Thus, pixels at positions i) and iii) can be charged to the desired voltage level. As a result, a light transmittance can be performed at a correct gray level. 
     At positions ii) and iv) of liquid crystal panel  22 , the time gap between the transition of the gate signal to the turn-off level and the falling of the source signal is 7Tg/8, as the source signal is accumulatively delayed. Pixels at positions ii) and iv) are those to which source signal So 8  output from source driver IC  57  is applied at the same time. Positions ii) and iv) are farthest from the gate drive unit and where the gate signal is extremely delayed due to the resistance and capacitance. Turn-on period of the gate signal is contained in a period when the source signal has a normal level. Thus, pixels at positions ii) and iv) can be charged to the desired level. As a result, a light transmittance can be performed at a correct gray level. 
     As described above, the source driver IC delays a source signal output, which maintains the source signal at a normal level while TFTs of the pixel are turned on. This effectively increases a gate turn-on pulse width by 7Tg/8 compared to the conventional art, which enhances a charging rate of the liquid crystal capacitor. 
     Gate drive unit  18  of the present invention consists of gate driver ICs shown in FIG. 5 has a structure as shown in FIG.  10 . 
     The number of gate driver ICs of gate drive unit  18  can vary according to the manufacturer&#39;s specification and the display resolution. A second embodiment as shown in FIG. 10 consists of six gate driver ICs. 
     Gate drive unit  18  of FIG. 10 consists of gate driver ICs  70  through  75  that receive vertical clock signal V—CLK and turn-on voltage Von and turn-off voltage Voff. 
     Gate driver IC  70  also receives a shift signal STV and transmits the carry-out signal to the subsequent driver IC  71 . The carry-out signal transmits to gate driver ICs  71  through  75 . 
     Enable signal OE is input to a delay unit  80  and gate driver IC  70 , and is delayed passing through delay units  80  through  84 . Delay units  80  through  83  input enable signals OE 1  through OE 4  to gate driver IC  71  through  74  and delay units  81  through  84  respectively. Delay unit  85  inputs the final-delayed load signal TP 7  to gate driver IC  75 . 
     Provided that the total amount of delay time of the gate voltage is “A”, the first enable signal OE is set to fall down by a time gap of A/ 6  after the source signal is applied. Delay units  80  through  84  delay the inputted enable signal by a period of A/ 6 , respectively. As a result, enable signal OE 5  applied to gate driver IC  75  falls down delayed by a period of A after the source signal. Gate driver ICs  70  through  75  output gate signals when enable signals OE through OE 5  fall down. An output operation of the gate signal will be explained later. 
     Like the first embodiment, the delay unit is made up of an RC delay circuit having a resistance R and a capacitor C. The signal to an input terminal is delayed by a predetermined time period and output to an output terminal. Here, a parasitic capacitor formed by data lines and gate lines can be used. 
     In the second embodiment, the source signal is applied to the liquid crystal panel in a fashion that the source signal rises before the gate signal rises to a turn-on level and falls after the gate signal falls down to a turn-off level, for a selected pixel. The time gap between the respective risings of the source signal and the gate signal varies for each gate line. 
     Supposing that the time gap between the source signal and the most delayed gate signal is Ts, gate signals of gate driver ICs  70  through  75  are delayed by a period of Ts/number of gate driver ICs. Thus, gate signals Go 1  through Go 6  coming from gate driver ICs  70  through  75  are accumulatively delayed by a period of Ts/number of gate driver ICs. As a result, gate signal Go 6  from the last gate driver IC rises delayed by a time gap Ts than the source signal. 
     Delay operation of the gate signal can be explained in more detail with reference to FIGS. 10 and 11. Data drive unit  20  outputs a source signal corresponding to the rising edge of the driving signal Tp, which comes from controller  10 . Gate drive unit  18  receives shift signal STV and enable signal OE, and outputs gate signals Go 1  through Go 6  through gate driver ICs  70  through  75 . 
     When gate driver IC  70  receives shift signal STV of which rising edge is the same as that of the source signal it generates a carry-out signal CO 1  through the internal operation of the shift register and inputs the same to the subsequent gate driver IC  71  as a carry-in signal. Gate driver IC  71  in turn generates carry-out signal C 02  through the internal operation of the shift register and inputs the same to the subsequent gate driver IC  72  as a carry-in signal. In such a manner, carry-out signals C 01  through C 05  are input to the subsequent gate driver IC. Shift signal STV or carry-out signals C 01  through C 05  respectively generates turn-on voltages at each gate driver ICs  70  through  75 . When the enable signal is input, the gate driver ICs  70  through  75  receive the enable signal, turn-on voltages are output to the liquid crystal panel. 
     Pixels connected to gate driver IC  70  are the nearest to source drive unit  20 . Therefore, the charging time for the source signal is short. On the contrary, pixels connected to gate driver IC  75  are the farthest from source drive unit  20 . Therefore, the charging time for the source signal is longer. 
     Accordingly, gate driver ICs  70  through  75  output to a plurality of gate lines gate signals delayed by Ts/6, 2Ts/6, 3Ts/6, 4Ts/6, 5Ts/6, 6Ts/6(equals to Ts) compared to the source signal. 
     In detail, enable signal OE that falls down delayed by Ts/6 than the source signal is input to gate driver IC  70 . Delay unit  80  delays enable signal OE by Ts/6 to generate OE 1  and input to gate driver IC  71 . Delay units  81  through  84  delay enable signals OE 1  through OE 5  by Ts/6 respectively and input the delayed signals to the corresponding gate driver ICs  72  through  75 . 
     Accordingly, gate driver IC  71  outputs gate signal Go 2  delayed by Ts/6 than gate driver IC  70 , and gate driver IC  72  outputs gate signal Go 3  delayed by Ts/6 than gate driver IC  71 . As described above, the gate signal output is accumulatively delayed, and gate signal Go 6  of gate driver IC  75  is output delayed by 5Ts/6 than those of the gate driver IC  70 . 
     FIG. 12 shows source signals and gate signals applied to each pixel according to the second embodiment. Here, i) through iv) are source and gate signals applied to positions i) through iv) of liquid crystal panel  22  of FIG.  3 . Positions i) and ii) are for the pixels that receive a source signal at first, and positions i) and iii) are for the pixels that receive a gate signal at first. 
     At positions i) and ii), the gate signal is applied being delayed by Ts/6 than the source signal. Gate signal Go 1  output from source driver IC  70  is applied to pixels at positions i) and ii) at the same time. In addition, the gate signal is turned on while the source signal maintains a normal level. Thus, pixels at positions i) and ii) can be charged to the desired level. As a result, pixels at those positions can be projected at a correct gray level. 
     At positions iii) and iv) of liquid crystal panel  22 , the gate signal is applied delayed by Ts than the source signal. Pixels at positions iii) and iv) receive at the same time gate signal Go 6  coming from gate driver IC  75 . Positions iii) and iv) are the farthest from the source drive unit and the source signal is extremely delayed due to the resistance and capacitance. The gate signal is turned on while the source signal maintains a normal level. Thus, pixels at positions iii) and iv) can be charged to the desired level. As a result, pixels at those positions can be projected at a correct gray level. 
     As described above, the gate driver IC outputs delayed gate signal, which turns on TFTs of the pixel while the source signal maintains a normal level. A gate turn-on time is 5Ts/6 longer than the conventional art, enhancing the charging rate of the liquid crystal capacitor. 
     The present invention adjusts the turn-on period of the gate signal to be included within the period while the level of the source signal is normal. Since the turn-on period of the gate signal has to be reduced to 15 μs or shorter to achieve a large screen and a high resolution display, the turn-on period of the gate signal has to be adjusted to be included within the period while the level of the source signal is normal, in order to enhance the charging rate of the liquid crystal capacitor. 
     The charging period for the source signal may vary due to the characteristics of TFTs. However, manufacturers may overcome this problem by adjusting the degree of the gate signal delay. 
     Although the embodiment of the present invention employs a method of delaying for each source driver IC, the delay time can be adjusted by the unit of two or three source driver ICs. In such a case, the delay unit may consists of two or three units of source driver ICs. 
     Delay units are one less than source or gate driver ICs, because the first load signal and the enable signal are delayed by the period corresponding to total delay time/number of source or driver ICs. 
     Unlike the above-described embodiments, delay units may one-to-one correspond to source driver ICs, as shown in FIGS. 13 and 14. In such a case, the first load signal and the enable signal are not delayed. 
     Referring to FIGS. 13 and 14, a load signal and an enable signal are input respectively to delay units  59  and  79  without a delay. The delay starts from the output signal of delay units  59  and  79 . Thereafter, the load signal and the enable signal are delayed sequentially and the source and gate driver ICs operate in a manner similar to those as described on the first embodiment and the second embodiment of the present invention. 
     The present invention has benefits of enhanced screen uniformity by improving the rate of charging the source voltage to a liquid crystal capacitor for each pixel. Specifically, the present invention is applied to a large screen and a high resolution display, ensuring the sufficient charging rate even during a short period of gate signal turn-on. As a result, the picture quality is enhanced. 
     This invention has been described above with reference to the aforementioned embodiments. It is evident, however, that many alternative modifications and variations will be apparent to those having skills in the art in light of the foregoing description. Accordingly, the present invention embraces all such alternative modifications and variations as fall within the spirit and scope of the appended claims.