Abstract:
There is provided an LCD capable of being reduced by a whole size and a defective proportion thereof being minimized. An LCD panel of the LCD includes a gate driving circuit that drives gate lines formed extended along a row direction and a line block selecting circuit that drives data lines extended along a column direction. On the LCD panel, an integrated driving chip having a controller, a memory, a level shifter, a source driver, a common voltage generator and a DC/DC converter is mounted. The integrated driving chip not only drives the gate driving circuit and line block selecting circuit, but also controls the operation of the LCD panel to display an image. Thus configured, a defective proportion of the LCD is decreased, with the whole size thereof being reduced.

Description:
BACKGROUND OF THE INVENTION  
         [0001]    1. Field of the Invention  
           [0002]    The present invention relates generally to a liquid crystal display (LCD), and more particularly, to an LCD capable of being reduced by a whole size with a defective proportion thereof being minimized.  
           [0003]    2. Description of the Related Art  
           [0004]    Information processing devices presently in existence have been rapidly developed to have various architectures, various functions and faster information processing speeds. Information processed in these information processing devices has an electrical signal format. In order to visually confirm the information processed in the information processing device, a display device is typically provided as an interface.  
           [0005]    Compared with the traditional cathode ray tube (CRT), liquid crystal displays (LCDs) have certain advantages such as lighter weight, small size, high resolution, and lower power consumption. In addition, LCDs are easily adapted to their intended environment, and are further able to display a full range of colors. Such advantages allow LCDs to replace the CRTs and to be spotlighted as a next generation display.  
           [0006]    In general, LCDs employ two substrates that have, respectively, an electrode and a thin film transistor LCD (TFT-LCD) that switches power applied to the electrode. A TFT-LCD may include amorphous silicon TFT-LCD (a-Si TFT-LCD) or polycrystalline silicon TFT-LCD (poly-Si TFT-LCD). Poly-Si TFT-LCD has advantages of lower power consumption and lower price as compared to a-Si TFT-LCD. However, a drawback of the Poly-Si TFT-LCD is that it has a relatively complicated manufacturing process. Thus, poly-Si TFT-LCD is mainly used in small sized display devices such as mobile phones. On the other hand, amorphous-Si TFT-LCD is typically used in large screen-sized display devices such as notebook computers, LCD monitors, high definition (HD) television receivers, and the like.  
           [0007]    [0007]FIG. 1 is a simplified schematic view showing a liquid crystal display panel of an a-Si TFT-LCD in accordance with the conventional art.  
           [0008]    Referring to FIG. 1, a-Si TFT-LCD  50  includes an LCD panel  10  having pixel arrays, driving printed circuit boards  36  and  42  for providing driving signals to the LCD panel  10 , and tape carrier packages (TCP)  32  and  38  that electrically connect the LCD panel  10  to the driving printed circuit boards  36  and  42 .  
           [0009]    The driving printed circuit boards  36  and  42  include a data printed circuit board  36  that drives a plurality of data lines formed in the LCD panel  10  and a gate printed circuit board  42  that drives a plurality of gate lines formed in the LCD panel  10 . The data printed circuit board  36  is connected to terminals of the plurality of data lines through the data side TCP  32 , and the gate printed circuit board  42  is connected to terminals of the plurality of gate lines through the gate side TCP  38 .  
           [0010]    The a-Si TFT-LCD has a data driving chip  34  formed on the data side TCP  32  in accordance with a COF (Chip-On-Film) technique, and a gate driving chip  40  also formed on the gate side TCP  38  by COF.  
           [0011]    Recently, there have been many endeavors to decrease the number of assembly process steps by simultaneously forming the data driving circuit and the gate driving circuit, along with the pixel array on a glass substrate in both a-Si TFT-LCDs and poly-Si TFT-LCDs.  
           [0012]    [0012]FIG. 2 is a simplified schematic view showing an a-Si TFT-LCD panel having data and gate driving chips are disposed thereon, in accordance with the conventional art.  
           [0013]    Referring to FIG. 2, a-Si TFT-LCD  90  includes a glass substrate  60  having a display region  60   a , in which the pixel array is formed, and a peripheral region  60   b  adjacent to the display region  60   a . On the peripheral region  60   b , a plurality of data driving chips  61  and a plurality of gate driving chips  62  are formed thereon. Each of the output terminals of the plurality of data driving chips  61  is connected to a corresponding data line of a plurality of data lines, and each of output terminals of the plurality of gate driving chips  62  is connected to corresponding gate line of a plurality of gate lines. Output terminals of the data and gate driving chips  61  and  62  are connected to an integrated printed circuit board (not shown) through a flexible printed circuit board  70 .  
           [0014]    The flexible printed circuit board  70  includes a control driving chip  71  and a common voltage generator  72 . The control driving chip  71  provides a timing signal and an image data signal to the data driving chips  61  and gate driving chips  62 , respectively. The common voltage generator  72  generates a common voltage.  
           [0015]    The structure in which the data and gate driving chip  61  and  62  are formed on the glass substrate  60  decreases the cost of the LCD and also minimizes power consumption due to the integration of the driving circuits. However, when a plurality of driving chips is formed on a glass substrate as shown in FIG. 2, there are several problems that arise. First, when a plurality of driving chips is formed on a glass substrate, the defect proportion increases in proportion to the number of the chips formed on the substrate. As a result, the yield of the LCD decreases because the LCD module is not able to be used, even if a single chip among the plurality of driving chips is defective. Further, when the defect proportion increases, the process time of the LCD becomes longer, and the productivity thereof becomes lower.  
           [0016]    Second, from the standpoint of instrumental structure, the resulting size of the LCD increases by mounting a plurality of chips on the glass substrate. This is because the number of patterns to be formed on the glass substrate increases as the total number of the chips increases, and thus the size of the LCD panel has to be increased in order to obtain space for forming the patterns. As a result, the desired high resolution may not be achieved in an LCD having a restricted size requirement.  
           [0017]    Third, since the plurality of chips is formed in one side portion adjacent to the LCD panel, the structure of the LCD panel becomes lopsided, and the whole size of the LCD becomes larger.  
           [0018]    Fourth, from the standpoint of image displaying characteristics through the LCD panel, a uniformity of image cannot be maintained due to contact resistance between the plurality of chips and the glass substrate.  
         BRIEF SUMMARY OF THE INVENTION  
         [0019]    An embodiment of the invention provides a liquid crystal display capable of decreasing a process time required to form the liquid crystal display and reducing a whole size thereof.  
           [0020]    Another embodiment of the invention provides a liquid crystal display having an integrated driving chip, in which channel terminals are compatible with data lines.  
           [0021]    A further embodiment of the invention provides a liquid crystal display capable of being applied to a display apparatus having a high vertical resolution.  
           [0022]    Still another embodiment of the invention provides a liquid crystal display capable of increasing an effective display area thereof.  
           [0023]    There is provided a liquid crystal display apparatus comprising a first substrate having a display region and a peripheral region adjacent to the display region, a second substrate facing the first substrate, and a liquid crystal interposed between the first and second substrates.  
           [0024]    The first substrate includes a plurality of switching devices, a plurality of pixel electrodes, a plurality of gate lines, a plurality of data lines, a gate driving circuit, and an integrated driving chip. The plurality of switching devices is formed in the display region in a matrix. The plurality of pixel electrodes is formed in the display region in the matrix, and each of the plurality of pixel electrodes are connected to a first current electrode of each switching device of the plurality of switching devices. The plurality of gate lines is arranged in a row, and each of the plurality of gate lines is commonly connected to control electrodes of switching devices arranged in the row among the plurality of switching devices. The plurality of data lines is arranged in a column, and each of the plurality of date lines is commonly connected to second current electrodes of switching devices arranged in the column among the plurality of switching devices. The gate driving circuit is formed in a first region of the peripheral region to which first ends of the plurality of gate lines are extended, and sequentially scans the plurality of gate lines. The integrated driving chip is formed in a second region of the peripheral region to which first ends of the plurality of data lines are extended, for providing a driving control signal to the gate driving circuit in response to an external image data and a external control signal, and provides an analog signal to the plurality of data lines, respectively.  
           [0025]    In another embodiment, there is provided a liquid crystal display apparatus comprising a first substrate having a display region and a peripheral region adjacent to the display region, a second substrate facing with the first substrate, and a liquid crystal interposed between the first and second substrates.  
           [0026]    The first substrate includes a plurality of switching devices, a plurality of pixel electrodes, a plurality of gate lines, a plurality of data lines, a gate driving circuit, a line block selecting circuit, and an integrated driving chip. The plurality of switching devices is formed in the display region in a matrix. The plurality of pixel electrodes is formed in the display region in the matrix, and each of the plurality of pixel electrodes is connected to a first current electrode of each switching device of the plurality of switching devices. The plurality of gate lines is arranged in a row, and each of the plurality of gate lines is commonly connected to control electrodes of switching devices arranged in the row among the plurality of switching devices. The plurality of data lines is arranged in a column, and each of the plurality of date lines is commonly connected to second current electrodes of switching devices arranged in the column among the plurality of switching devices. The gate driving circuit is formed in a first region of the peripheral region to which first ends of the plurality of gate lines are extended, and sequentially scans the plurality of gate lines. The line block selecting circuit is formed in a second region of the peripheral region to which first ends of the plurality of data lines are extended, receives analog driving signals of block-units, selects one of line blocks of the plurality of data lines, and switches the analog driving signals of a block-unit to data lines of the selected line block. The integrated driving chip is formed in the second region, provides driving control signals to the gate driving circuit in response to an external image data and external control signals, and provides line block selecting signals and the analog signals of a block-unit to the line block selecting circuit.  
           [0027]    The integrated driving chip comprises an interfacing part for interfacing the external image data and the external control signals, a memory for storing the external image data, a source driver for outputting the analog driving signals of block-units in response to image data of block-unit read out from the memory block by block, a level shifter for shifting a level of the driving control signals and the line block selecting signals, and a controller for storing the external image data into the memory in response to the external control signals inputted from the interfacing part, generating the driving control signals and the line block selecting signal, providing the driving control signals and the line block selecting signal to the level shifter, reading out image data block by block from the memory, and providing the image data read out block by block to the source driver.  
           [0028]    The integrated driving chip further comprises a common voltage generator for generating a common voltage, and providing the common voltage to common electrode lines formed on a liquid crystal panel, and a DC/DC converter for receiving a external voltage, pulling-up or pulling-down the external voltage, and providing the pulled-up or pulled-down external voltage to the controller, the level shifter, the source driver and the common voltage generator.  
           [0029]    The control signals include a main clock signal, a horizontal synchronizing signal, a vertical synchronizing signal, a data enable signal and a mode selecting signal, and the controller generates the line block selecting signal in response to the mode selecting signal.  
           [0030]    The first line block comprises odd number data lines when the block has the size corresponding to ½ of the horizontal resolution and a second line block comprises even number data lines.  
           [0031]    The line block selecting circuit comprises a plurality of first selecting transistors and a plurality of second selecting transistors. Each of the first current electrodes of the of first selecting transistors is connected to a corresponding first output terminal of first output terminals outputting the analog driving signals of the integrated driving chip, each of the second current electrodes is connected to a corresponding odd number data line of the odd number data lines, and each of control electrodes is connected to a corresponding second output terminal of second output terminals outputting the first line block selecting signals. Each of the first current electrodes is connected to the corresponding first output terminal of the first output terminals, each of the second current electrodes is connected to a corresponding even number data line of the even number data lines, and each of the control electrodes is connected to a corresponding third output terminal of third output terminals outputting the second line block selecting signals.  
           [0032]    The first line block comprises (3n−2) number of data lines, a second line block comprises (3n−1) number of data lines, and a third line block comprises (3n) number of data lines when the block has the size corresponding to ⅓ of the horizontal resolution, wherein n is a natural number.  
           [0033]    The line block selecting circuit comprises a plurality of first selecting transistors, a plurality of second selecting transistors, and a plurality of third selecting transistors. Each of the first current electrodes of the of first selecting transistors is connected to a corresponding first output terminal of first output terminals outputting the analog driving signals of the integrated driving chip, each of the second current electrodes is connected to a corresponding (3n−2) number data line of the (3n−2) number data lines, and each of the control electrodes is connected to a corresponding second output terminal of second output terminals outputting the first line block selecting signals. Each of the first current electrodes is connected to the corresponding first output terminal of the first output terminals, each of the second current electrodes is connected to a corresponding (3n−1) number data line of the (3n−1) number data lines, and each of the control electrodes is connected to a corresponding third output terminal of third output terminals outputting the second line block selecting signals. Each of the first current electrodes is connected to the corresponding first output terminal of the first output terminals, each of the second current electrodes is connected to a corresponding (3n) number data line of the (3n) number data lines, and each of the control electrodes is connected to a corresponding fourth output terminal of fourth output terminals outputting the third line block selecting signals.  
           [0034]    In another embodiment, there is provided a liquid crystal display apparatus comprising a first substrate having a display region and a peripheral region adjacent to the display region, a second substrate facing the first substrate, and a liquid crystal interposed between the first and second substrates.  
           [0035]    The first substrate includes a plurality of switching devices, a plurality of pixel electrodes, a plurality of gate lines, a plurality of data lines, a first gate driving circuit, a second gate driving circuit, a line block selecting circuit, and an integrated driving chip. The plurality of switching devices is formed in the display region in a matrix. The plurality of pixel electrodes is formed in the display region in the matrix, and each of the plurality of pixel electrodes is connected to a first current electrode of each switching device of the plurality of switching devices. The plurality of gate lines is arranged in a row, and each of the plurality of gate lines is commonly connected to control electrodes of switching devices arranged in the row among the plurality of switching devices. The plurality of data lines is arranged in a column, each of the plurality of date lines is commonly connected to second current electrodes of switching devices arranged in the column among the plurality of switching devices. The first gate driving circuit is formed in a first region of the peripheral region to which first ends of the plurality of gate lines are extended, and drives odd number gate lines of the plurality of gate lines. The second gate driving circuit is formed in a second region of the peripheral region to which second ends of the plurality of gate lines are extended, drives even number gate lines of the plurality of gate lines, and is connected to the first gate driving circuit through the plurality of gate lines in order to sequentially scan the plurality of gate lines. The line block selecting circuit is formed in a third region of the peripheral region to which first ends of the plurality of data lines are extended, receives analog driving signals of block-units, selects one of line blocks of the plurality of data lines, and switches the analog driving signals of a block-unit to data lines of the selected line block. The integrated driving chip is formed in the third region, provides driving control signals to the first and second gate driving circuits in response to an external image data and external control signals, and provides a line block selecting signals and the analog signals of a block-unit to the line block selecting circuit.  
           [0036]    In a further embodiment, there is provided a liquid crystal display apparatus comprising a first substrate having a display region and a peripheral region adjacent to the display region, a second substrate facing with the first substrate, and a liquid crystal interposed between the first and second substrates.  
           [0037]    The first substrate includes a plurality of switching devices, a plurality of pixel electrodes, a plurality of gate lines, a plurality of data lines, a line block selecting circuit, and an integrated driving chip. The plurality of switching devices is formed in the display region in a matrix. The plurality of pixel electrodes are formed in the display region in the matrix, and each of the plurality of pixel electrodes is connected to a first current electrode of each switching device of the plurality of switching devices. The plurality of gate lines is arranged in a row, and each of the plurality of gate lines is commonly connected to control electrodes of switching devices arranged in the row among the plurality of switching devices. The plurality of data lines is arranged in a column, each of the plurality of date lines is commonly connected to second current electrodes of switching devices arranged in the column among the plurality of switching devices. The line block selecting circuit is formed in a peripheral region to which first ends of the plurality of data lines are extended, receives analog driving signals of block-units, selects one of line blocks of the plurality of data lines, and switches the analog driving signals of a block-unit to the data lines of the selected line block. The integrated driving chip is formed in the peripheral region in which the line block selecting circuit is formed, receives external image data and external control signals, provides first gate driving signals to odd number gate lines of the plurality of gate lines, provides second gate driving signals to even number gate lines thereof, and provides line block selecting signals and the analog driving signals of a block-unit to the line block selecting circuit.  
           [0038]    The integrated driving chip comprises an interfacing part, a memory for storing the external image data, a source driver, a level shifter, a first gate driver, a second gate driver, and a controller. The interfacing part interfaces the external image data and the external control signals. The source driver outputs the analog driving signals of block-units in response to image data of block-unit read out from the memory block by block. The level shifter shifts a level of a first driving control signal, a second driving control signal and the line block selecting signals. The first gate driver provides the first gate driving signal to the odd number gate lines of the plurality of gate lines in response to the first driving control signal. The second gate driver provides the second gate driving signal to the even number gate lines of the plurality of gate lines in response to the second driving control signal. The controller stores the external image data into the memory in response to the external control signals inputted from the interfacing part, generates the first and second driving control signals and the line block selecting signals, provides the first and second driving control signals and the line block selecting signals to the level shifter, reads out image data block by block from the memory, and provides the image data read out block by block to the source driver. According to the aforementioned LCD, only one integrated driving chip for driving the LCD panel is disposed in the peripheral region of the display region, thereby decreasing a process time, minimizing a defective proportion and reducing the whole size of the LCD panel.  
           [0039]    In addition, the line block selecting circuit, which is formed in the peripheral region of the display region, and the TFT transistor, which is formed in the display region, are formed by means of only one process. The pixel data corresponding to one line is driven by means of the line block selecting circuit in a time-sharing method. Thereby, the channel terminals of the integrated driving chip are compatible with the data lines.  
           [0040]    Further, the gate line driving circuit, which is formed in the left and right side of the peripheral regions of the display region, and the TFT transistor, which is formed in the display region, are formed by means of only one process. The gate line driving circuit is formed in a zigzag so that the gate line driving circuit is symmetrically formed in the left and right side of the peripheral regions. Also, the gate line driving circuit can be applied to a LCD having a high vertical resolution.  
           [0041]    Moreover, the integrated driving chip, which has the gate driver for driving the plurality of gate lines and the source driver for driving the plurality of data lines, is disposed on the LCD panel, thereby increasing an effective display region of the LCD panel.  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0042]    The above objects and other advantages of the present invention will become more apparent by describing in detail the exemplary embodiments thereof with reference to the accompanying drawings, in which:  
         [0043]    [0043]FIG. 1 is a simplified schematic view showing a liquid crystal display panel of an a-Si TFT-LCD in accordance with the conventional art;  
         [0044]    [0044]FIG. 2 is a simplified schematic view showing an a-Si TFT-LCD panel on which data and gate driving chips are disposed in accordance with the conventional art;  
         [0045]    [0045]FIG. 3 is a disassembled perspective view of an LCD according to one embodiment of the present invention;  
         [0046]    [0046]FIG. 4 is a schematic view showing a first embodiment of the TFT substrate shown in FIG. 3;  
         [0047]    [0047]FIG. 5 is a schematic view showing a second embodiment of the TFT substrate shown in FIG. 3;  
         [0048]    [0048]FIG. 6 is a block diagram showing a first embodiment of the integrated driving chip shown in FIG. 5;  
         [0049]    [0049]FIG. 7 is a block diagram showing a second embodiment of the integrated driving chip, according to another embodiment of the present invention;  
         [0050]    [0050]FIG. 8 is a circuit diagram showing a first line block selecting circuit that selectively drives the plurality of data lines divided into two blocks;  
         [0051]    [0051]FIG. 9 is an output waveform of the first line block selecting circuit shown in FIG. 8;  
         [0052]    [0052]FIG. 10 is a circuit diagram showing the second line block selecting circuit that selectively drives the plurality of data lines divided into three blocks;  
         [0053]    [0053]FIG. 11 is an output waveform of the second line block selecting circuit shown in FIG. 10;  
         [0054]    [0054]FIG. 12 is a circuit diagram showing the third line block selecting circuit that selectively drives the plurality of data lines divided into four blocks;  
         [0055]    [0055]FIG. 13 is an output waveform of the third line block selecting circuit shown in FIG. 12;  
         [0056]    [0056]FIG. 14 is a block diagram of a first shift register in the gate driving circuit shown in FIG. 5, according to a first embodiment of the present invention;  
         [0057]    [0057]FIG. 15 is a detailed circuit diagram of the first shift register shown in FIG. 14;  
         [0058]    [0058]FIG. 16 is an output waveform of the first shift register shown in FIG. 14;  
         [0059]    [0059]FIG. 17 is a block diagram of a second shift register in the gate driving circuit shown in FIG. 5, according to a second embodiment of the present invention;  
         [0060]    [0060]FIG. 18 is a block diagram of a third shift register in the gate driving circuit shown in FIG. 5, according to a third embodiment of the present invention;  
         [0061]    [0061]FIG. 19 is a circuit diagram of the third shift register shown in FIG. 18;  
         [0062]    [0062]FIG. 20 is a perspective view showing a structure of an FPC shown in FIG. 3;  
         [0063]    [0063]FIG. 21 is a schematic view showing an LCD panel according to another embodiment of the present invention;  
         [0064]    [0064]FIG. 22 is a block diagram of a fourth and a fifth shift registers of the first and second gate driving circuits shown in FIG. 21;  
         [0065]    [0065]FIG. 23 is an output waveform of the fourth and fifth shift registers shown in FIG. 22;  
         [0066]    [0066]FIG. 24 is a schematic view showing an LCD panel according to another embodiment of the present invention; and  
         [0067]    [0067]FIG. 25 is a block diagram showing an integrated driving chip shown in FIG.  24 . 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0068]    Reference will now be made in detail to the exemplary embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Hereinafter, exemplary embodiments are described with reference to the accompanying drawings.  
         [0069]    [0069]FIG. 3 is a disassembled perspective view of an LCD in accordance with the present invention.  
         [0070]    Referring to FIG. 3, an LCD  500  includes an LCD panel assembly  100 , a backlight assembly  200 , a chassis  300  and a cover  400 .  
         [0071]    The LCD assembly  100  includes an LCD panel  110 , a flexible printed circuit board (hereinafter referred to as an “FPC”)  190 , and an integral driving chip  180 . The LCD panel  110  includes a TFT substrate  120  as a lower substrate, a color filter substrate  130  disposed on the TFT substrate  120 , and a liquid crystal. The liquid crystal is injected between the TFT substrate  120  and the color filter substrate  130 , and then an injection inlet of liquid crystal is sealed. On the TFT substrate  120 , there are disposed a display cell array circuit, a gate driving circuit, and the integrated driving chip  180 . The TFT substrate  120  faces the color filter substrate  130 . The integrated driving chip  180  is electrically connected to an external circuit substrate (not shown) through the FPC  190 .  
         [0072]    RGB (red, green, blue) pixels and transparent common electrodes are formed on the color filter substrate  130 .  
         [0073]    The backlight assembly  200  includes a lamp assembly  220 , a light guiding plate  240 , a series of optical sheets  260 , a reflector plate  280  and a mold frame  290 .  
         [0074]    [0074]FIG. 4 is a schematic view showing a first embodiment of the TFT substrate shown in FIG. 3 in accordance with the present invention.  
         [0075]    Referring to FIG. 4, the TFT substrate  120  is divided into a first region corresponding to the color filter substrate  130  and a second region not corresponding to the color filter substrate  130 . The first region includes a display region and a peripheral region adjacent to the display region. On the display region, there are arranged a plurality of data lines DL extended along the row direction and a plurality of gate lines GL extended along the column direction. A gate driving circuit  140 , which is connected to the plurality of gate lines GL, is integrated in the left side of the peripheral region.  
         [0076]    In the second region of the TFT substrate  120 , there is arranged the integrated driving chip  180  for controlling the operation of the LCD panel  110 . The integrated driving chip  180  receives an external image data signal  181   a  and an external control signal  181   b  from the external circuit substrate separately disposed from the LCD panel  110 . The integrated driving chip  180  provides a driving control signal GC to the gate driving circuit  140 , and provides an analog driving signal (or, analog pixel data) to the plurality of data lines DL. First and second external connection terminals of the integrated driving chip  180  are connected to the FPC  190  that electrically connects the external circuit substrate and the integrated driving chip  180 . The external image data signal  181   a  is inputted through the first external connection terminal, and the external control signal  181   b  is inputted through the second external connection terminal.  
         [0077]    Among the plurality of output terminals of the integrated driving chip  180 , each of the output terminals for outputting the driving control signal GC is connected to a corresponding one of the input terminals of the gate driving circuit  140 . Each of the channel terminals CH is connected to corresponding one of the plurality of data lines DL. In addition, the terminals for outputting the driving control signal output GC further include a start signal output terminal, a first clock signal output terminal, a second clock signal output terminal, a first power voltage terminal and a second power voltage terminal.  
         [0078]    [0078]FIG. 5 is a schematic view showing a second embodiment of the TFT substrate shown in FIG. 3 in accordance with the present invention.  
         [0079]    Referring to FIG. 5, the TFT substrate  120  is divided into the first region corresponding to the color filter substrate  130  and the second region not corresponding to the color filter substrate  130 . The first region includes the display region and the peripheral region adjacent to the display region. On the display region, there are arranged the plurality of data lines DL extended along the row direction and the plurality of gate lines GL extended along the column direction. A gate driving circuit  140  is integrated in the left side of the peripheral region adjacent to the display region, and the gate driving circuit  140  is connected to the plurality of gate lines GL. A line block selecting circuit  150  is integrated in the upper side of the peripheral region, and is connected to the plurality of data lines DL.  
         [0080]    In the second region of the TFT substrate  120 , there is arranged the integrated driving chip  180  for controlling the operation of the LCD panel  110 . The integrated driving chip  180  receives the external image data signal  181   a  and the external control signal  181   b  from the external circuit substrate separately disposed from the LCD panel  110 . The integrated driving chip  180  provides the driving control signal GC and the analog driving signal to the gate driving circuit  140  and the plurality of data lines DL, respectively. First and second external connection terminals of the integrated driving chip  180  are connected to the FPC  190  that electrically connects the external circuit substrate and the integrated driving chip  180 . The external image data signal  181   a  is inputted through the first external connection terminal, and the external control signal  181   b  is inputted through the second external connection terminal.  
         [0081]    Among the plurality of output terminals of the integrated driving chip  180 , each of the output terminals for outputting the driving control signal GC is connected to corresponding one of input terminals of the gate driving circuit  140 . The output terminal of the line block selecting signal TG is connected to control terminals of the gate driving circuit  140 . Each of the channel terminals CH is connected to corresponding one of the input terminals of the line block selecting circuit  150 . Each of the output terminals of the line block selecting circuit  150  is connected to a corresponding one of the plurality of data lines DL. The number of the data lines DL is greater than the number of the channel terminals CH of the integrated driving chip  180  by N times, where N is an integer.  
         [0082]    [0082]FIG. 6 is a block diagram showing a first embodiment of the integrated driving chip shown in FIGS. 4 and 5.  
         [0083]    Referring to FIG. 6, the integrated driving chip  180  includes an interfacing part  181 , a memory  183 , a source driver  185 , a level shifter  184 , a common voltage generator  186  and a controller  182 .  
         [0084]    The interfacing part  181  receives the external image data signal  181   a  and the external control signal  181   b , and interfaces the controller  182  with external devices. The interfacing part  181  is compatible with a CPU interface, a video graphic board interface, and a media-Q interface.  
         [0085]    The controller  182  receives the external image data signal  181   a  and external control signal  181   b  from the interfacing part  181 , and stores the external image data signal  181   a  into the memory  183 . The external control signal  181   b  includes horizontal and vertical synchronizing signals, a main clock signal, a data enable signal and a mode selecting signal. The controller  182  generates the line block selecting signal TG in response to the mode selecting signal.  
         [0086]    In addition, the controller  182  provides the driving control signal GC and the line block selecting signal TG to the level shifter  184 . The driving control signal includes a start signal ST, a first clock signal CK, a second clock signal CKB, a first power voltage VSS and a second power voltage VDD.  
         [0087]    Further, the controller  182  provides digital image data to the source driver  185 . That is, the controller  182  reads out block-by-block the external image data signal  181   a  stored into the memory, and provides the external image data signal to the source driver  185 .  
         [0088]    The memory  183  temporarily stores the external image data signal supplied from the controller  182 . The memory  183  stores the external image data signal frame-by-frame or line-by-line. If a line memory is used as the memory  183  and the external image data signal is supplied from the controller  182  through 360 channels, the memory  183  has a storage capacity corresponding to two lines, that is 360×3×6×2=12,960 bits.  
         [0089]    The source driver  185  receives the digital image data from the memory  183  block by block and outputs the analog driving signal block by block. Each of the channel terminals CH of the source driver  185  is connected to corresponding one of the plurality of data lines DL.  
         [0090]    The level shifter  184  shifts a voltage level of the driving control signal GC and the line block selecting signal TG from the controller  182 , and outputs the level-shifted driving control signal GC and the line block selecting signal TG. The level-shifted driving control signal GC includes a level-shifted start signal ST, a level-shifted first clock signal CK, a level-shifted second clock signal CKB, a level-shifted first power voltage VSS, and a level-shifted second power voltage VDD.  
         [0091]    The common voltage generator  186  applies the common voltage Vcom to the common electrode line formed in parallel with the liquid crystal layer in order to maintain the voltage of the liquid crystal layer.  
         [0092]    [0092]FIG. 7 is a block diagram showing a second embodiment of the integrated driving chip shown in FIGS. 4 and 5.  
         [0093]    Referring to FIG. 7, the integrated driving chip  180  includes the interfacing part  181 , the memory  183 , the source driver  185 , the level shifter  184 , the common voltage generator  186 , a DC/DC converter  187 , and the controller  182 .  
         [0094]    The DC/DC converter  187  receives a first DC power voltage  187   a  supplied from an external power source (not shown), and supplies second DC power voltages (AVDD, VSS, VDD, and VCC) to a corresponding circuit part of the integrated driving chip  180 . In general, the DC/DC converter  187  receives the first DC power voltage  187   a  (being about 7 to 12 volts), and converts the first DC power voltage  187   a  to the second DC power voltages AVDD, VSS, VDD and VCC having (being about 5 volts).  
         [0095]    The second DC power voltages AVDD, VSS, VDD and VCC, converted by means of the DC/DC converter  187 , are supplied to the source driver  185 , level shifter  184 , common voltage generator  186  and controller  182 , respectively. Particularly, the DC/DC converter  187  provides the analog driving power voltage AVDD to the source driver  185  and the common voltage generator  186 , and also provides the image driving power voltage VSS and VDD to the level shifter  184 . The digital driving power VCC is supplied to the controller  182 .  
         [0096]    Hereinafter, the line block selecting circuit  150  (connected between the channel terminals CH of the integrated driving chip  180  and the plurality of data lines DL for selectively applying the pixel data from the integrated driving chip  180  to the plurality of data lines DL) will be described with reference to the accompanying drawings.  
         [0097]    [0097]FIG. 8 is a circuit diagram showing the first line block selecting circuit that selectively drives the data lines that are divided into two blocks, while FIG. 9 is a simulated waveform of the first line block selecting circuit.  
         [0098]    Referring to FIG. 8, the first line block selecting circuit  151  is formed in the upper side of the peripheral region adjacent to the TFT substrate  120 , and periodically applies the analog driving signal provided by the integrated driving chip  180  to the plurality of data lines—(designated DL 1  through DL 2   m ) block by block.  
         [0099]    In particular, the first line block selecting circuit  151  has 2m data lines and is divided into first and second blocks BL 1  and BL 2 , each respectively having m data lines. The first block BL 1  includes m odd numbered data lines from DL 1  to DL 2   m− 1, and the second block BL 2  includes m even numbered data lines from DL 2  to DL 2   m.    
         [0100]    Each of the channel terminals CH 1  through CHm of the integrated driving chip  180  is commonly connected to a corresponding pair of data lines. For example, the first channel terminal CH 1  of the integrated driving chip  180  is commonly connected to the first and second data lines DL 1  and DL 2 .  
         [0101]    The first block BL 1  of the first line block selecting circuit  151 , connected to the channel terminals CH 1  through CHm and the odd numbered data lines DL 1  through DL 2   m− 1, includes a first selecting transistor SW 1  driven by means of the first line block selecting signal (TG 1 ) from the integrated driving chip  180 . Correspondingly, the second block BL 2 , connected to the channel terminals CH 1  through CHm and the even numbered data lines DL 2  through DL 2   m , includes a second selecting transistor SW 2  driven by means of the second line block selecting signal (TG 2 ) from the integrated driving chip  180 . Signals TG 1  and TG 2  are alternately at a logic high level. That is, when TG 1  is at logic high, TG 2  is at logic low, and vice versa.  
         [0102]    When signal TG 1  is at logic high, the first selecting transistor SW 1  is driven thereby, and the analog driving signals from the channel terminals CH 1  through CHm are supplied to the odd numbered data lines DL 1  through DL 2   m− 1. Conversely, when signal TG 2  is at logic high, the second selecting transistor SW 2  is driven thereby, and the analog driving signal from the channel terminals CH 1  through CHm are supplied to the even numbered data lines DL 2  through DL 2   m.    
         [0103]    As shown in FIG. 9, when gate lines GL 1  through GLn are sequentially driven, signals TG 1  and TG 2  are alternately high during an active period of each of the plurality of gate lines GL 1  through GLn. That is, signal TG 1  is at the logic high level for the first half of the total active period of gate lines GL 1  through GLn, and signal TG 2  thereafter maintains the logic high level for the remaining half of the total period of gate lines GL 1  through GLn. Thus, when signal TG 1  is at logic high, the first selecting transistor SW 1  is driven thereby and the analog driving signal is supplied to data line DL 2   m− 1 of the first block BL 1 . Also, when signal TG 2  is at logic high, the second selecting transistor SW 2  is driven thereby, and the analog driving signal is applied to data line DL 2   m  of the second block BL 2 .  
         [0104]    Further, when the signal TG 1  is at logic high during the active period of the second gate line GL 2 , the first selecting transistor SW 1  is driven, and the analog driving signal is supplied to data line DL 2   m− 1 of the first block BL 1 . When signal TG 2  is at logic high, the second selecting transistor SW 2  is driven, and the analog driving signal is supplied to data line DL 2   m  of the second block BL 2 .  
         [0105]    [0105]FIG. 10 is a circuit diagram showing the second line block selecting circuit that selectively drives the data lines that are divided into three blocks in this embodiment, while FIG. 11 is a simulated waveform of the second line block selecting circuit shown in FIG. 10.  
         [0106]    Referring to FIG. 10, the second line block selecting circuit  152  is formed in the upper side of the peripheral region adjacent to the TFT substrate  120 , and periodically applies the analog driving signal from the integrated driving chip  180  to the plurality of data lines, designated DL 1  through DL 3   m , block by block.  
         [0107]    In particular, the second line block selecting circuit  152  (having 3m data lines) is divided into first, second and third blocks BL 1 , BL 2  and BL 3 , respectively, each having m data lines associated therewith. The first block BL 1  includes m data lines up to data line DL 3   m− 2, (i.e., DL 1 , DL 4 , DL 7 , etc.) The second block BL 2  includes m data lines up to data line DL 3   m− 1, (i.e., DL 2 , DL 5 , DL 8 , etc.) The third block BL 3  includes m data lines up to data line DL 3   m , (i.e., DL 3 , DL 6 , DL 9 , etc.) Each of the channel terminals CH 1  through CHm of the integrated driving chip  180  is commonly connected to a corresponding group of three data lines. That is, the first channel terminal CH 1  of the integrated driving chip  180  is commonly connected to the first, second and third data lines (DL 1 , DL 2  and DL 3 .) The first block BL 1  of the second line block selecting circuit  152  includes a first selecting transistor SW 1 , which is connected to channel terminals CH 1  through CHm and to every third data line from DL 1  to DL 3   m− 2, and is driven by means of the first line block selecting signal (TG 1 ) from the integrated driving chip  180 . Similarly, the second block BL 2  includes a second selecting transistor SW 2 , which is connected to channel terminal CH 1  through CHm and to every third data line from DL 2  to DL 3   m− 1, and is driven by means of the second line block selecting signal (TG 2 ) from the integrated driving chip  180 . Further, the third block BL 3  includes a third selecting transistor SW 3 , which is connected to channel terminal CH 1  through CHm and to every third data line from DL 3  to DL 3   m , and is driven by means of the third line block selecting signal (TG 3 ) from the integrated driving chip  180 . As will be described, signals TG 1 , TG 2  and TG 3  are alternately driven to a high level.  
         [0108]    When signal TG 1  is at logic high, the first selecting transistor SW 1  is driven thereby, and thus the analog driving signals from channel terminals CH 1  through CHm are supplied to DL 1 , DL 4 , DL 7 , . . . , DL 3   m . When signal TG 2  is at logic high, the second selecting transistor SW 2  is driven thereby, and thus the analog driving signal from the channel terminals CH 1  through CHm are supplied to DL 2 , DL 5 , DL 8 , . . . , DL 3   m− 1. Finally, when signal TG 3  is at logic high, the third selecting transistor SW 3  is driven thereby, and thus the analog driving signal from channel terminals CH 1  through CHm are supplied to DL 3 , DL 6 , DL 9 , . . . , DL 3   m.    
         [0109]    As shown in FIG. 11, when gate lines GL 1  through GLn are sequentially driven by the gate line driving circuit  140 , signals TG 1 , TG 2  and TG 3  are sequentially at the logic high level during an active period of each of the gate lines of GL 1  through GLn. That is, signals TG 1 , TG 2  and TG 3  are at the logic high level one-third of the active period of gate lines GL 1  through GLn.  
         [0110]    Accordingly, when signal TG 1  is at logic high during the active period of the first gate line GL 1 , the first selecting transistor SW 1  is driven, and the analog driving signal is supplied to data line DL 3   m− 2 of the first block BL 1 . Also, when signal TG 2  is at logic high, the second selecting transistor SW 2  is driven, and the analog driving signal is applied to data line DL 3   m− 1 of the second block BL 2 . In addition, when signal TG 3  is at logic high, the third selecting transistor SW 3  is driven, and the analog driving signal is applied to the data line DL 3   m  of the third block BL 3 .  
         [0111]    When signal TG 1  is at logic high during the active period of the second gate line GL 2 , the first selecting transistor SW 1  is driven, and the analog driving signal is supplied to data line DL 3   m− 2 of the first block BL 1 . Also, when signal TG 2  is at logic high, the second selecting transistor SW 2  is driven, and the analog driving signal is applied to data line DL 3   m− 1 of the second block BL 2 . When signal TG 3  signal is at logic high, the third selecting transistor SW 3  is driven, and the analog driving signal is applied to data line DL 3   m  of the third block BL 3 .  
         [0112]    [0112]FIG. 12 is a circuit diagram showing the third line block selecting circuit that selectively drives the plurality of data lines divided into four blocks, while FIG. 13 is a simulated waveform of the third line block selecting circuit shown in FIG. 12.  
         [0113]    Referring to FIG. 12, the third line block selecting circuit  153  is formed in the upper side of the peripheral region adjacent to the TFT substrate  120 , and periodically applies the analog driving signal from the integrated driving chip  180  to the plurality of data lines, designated DL 1  through DL 4   m , block by block.  
         [0114]    In particular, the third line block selecting circuit  153  (having 4m data lines) is divided into first, second, third and fourth blocks BL 1 , BL 2 , BL 3  and BL 4 , respectively, each having m data lines associated therewith. The first block BL 1  includes m data lines up to DL 4   m− 3, (i.e., DL 1 , DL 5 , DL 9 , etc.) The second block BL 2  includes m data lines up to DL 4   m− 2, (i.e., DL 2 , DL 6 , DL 10 , etc.) The third block BL 3  includes m data lines up to DL 4   m− 1, (i.e., DL 3 , DL 7 , DL 11 , etc.) The fourth block BL 4  includes m data lines up to DL 4   m , (i.e., DL 4 , DL 8 , DL 12 , etc.) Each of the channel terminals CH 1  through CHm of the integrated driving chip  180  is commonly connected to a corresponding group of four data lines. That is, the first channel terminal CH 1  of the integrated driving chip  180  is commonly connected to DL 1 , DL 2 , DL 3  and DL 4 .  
         [0115]    The first block BL 1  of the third line block selecting circuit  153  includes a first selecting transistor SW 1 , which is connected to channel terminals CH 1  through CHm and to every fourth data line from DL 1  to DL 4   m− 3, and is driven by means of the first line block selecting signal (TG 1 ) from the integrated driving chip  180 . Also, the second block BL 2  includes a second selecting transistor SW 2 , which is connected to channel terminals CH 1  through CHm and to every fourth data line from DL 2  to DL 4   m− 2, and is driven by means of the second line block selecting signal (TG 2 ) from the integrated driving chip  180 . The third block BL 3  includes a third selecting transistor SW 3 , which is connected to the channel terminals CH 1  through CHm and to every fourth data lines from DL 3  to DL 4   m− 1, and is driven by means of the third line block selecting signal (TG 3 ) from the integrated driving chip  180 . The fourth block BL 4  includes a fourth selecting transistor SW 4 , which is connected to channel terminals CH 1  through CHm and to every fourth data line from DL 4  to DL 4   m , and is driven by means of the fourth line block selecting signal (TG 4 ) from the integrated driving chip  180 . As will be described, signals TG 1 , TG 2 , TG 3  and TG 4  are alternately driven to a logic high level.  
         [0116]    When the signal TG 1  is at logic high, the first selecting transistor SW 1  is driven thereby, and the analog driving signals from channel terminals CH 1  through CHm are supplied to DL 1 , DL 5 , DL 9 , . . . , DL 4   m− 3. When signal TG 2  signal at logic high, the second selecting transistor SW 2  is driven thereby, and the analog driving signals from channel terminals CH 1  through CHm are supplied to the DL 2 , DL 6 , DL 10 , . . . , DL 4   m− 2. When signal TG 3  is at logic high, the third selecting transistor SW 3  is driven thereby, and the analog driving signal from channel terminals CH 1  through CHm are supplied to DL 3 , DL 7 , DL 11 , . . . , DL 4   m− 1. When signal TG 4  is at logic high, the fourth selecting transistor SW 4  is driven thereby, and the analog driving signal from channel terminals CH 1  through CHm are supplied to DL 4 , DL 8 , DL 12 , . . . , DL 4   m.    
         [0117]    As shown in FIG. 13, when gate lines GL 1  through GLn are sequentially driven by the gate line driving circuit  140 , each of the signals TG 1 , TG 2 , TG 3  and TG 4  has are sequentially at the logic high level during an active period of gate lines GL 1  through GLn. That is, signals TG 1 , TG 2 , TG 3  and TG 4  are at the logic high level for one-fourth of the active period of gate lines of GL 1  through GLn.  
         [0118]    Accordingly, when signal TG 1  is at logic high during the active period of the first gate line GL 1 , the first selecting transistor SW 1  is driven, and the analog driving signal is supplied to data line DL 4   m− 3 of the first block BL 1 . When signal TG 2  I is at logic high, the second selecting transistor SW 2  is driven, and the analog driving signal is supplied to data line DL 4   m− 2 of the second block BL 2 . In addition, when signal TG 3  is at logic high, the third selecting transistor SW 3  is driven, and the analog driving signal is supplied to data line DL 4   m− 1 of the third block BL 3 . When signal TG 4  is at logic high, the fourth selecting transistor SW 4  is driven, and the analog driving signal is supplied to data line DL 4   m  of the fourth block BL 4 .  
         [0119]    When signal TG 1  is at logic high during the active period of the second gate line GL 2 , the first selecting transistor SW 1  is driven, and the analog driving signal is supplied to data line DL 4   m− 3 of the first block BL 1 . When signal TG 2  is at logic high, the second selecting transistor SW 2  is driven, and the analog driving signal is supplied to data line DL 4   m− 2 of the second block BL 2 . In addition, when signal TG 3  is at logic high, the third selecting transistor SW 3  is driven, and the analog driving signal is supplied to data line DL 4   m− 1 of the third block BL 3 . When signal TG 4  is at logic high, the fourth selecting transistor SW 4  is driven, and the analog driving signal is supplied to data line DL 4   m  of the third block BL 4 .  
         [0120]    As shown in FIGS.  8  to  13 , although the number, m, of channel terminals (CH 1  through CHm) of the integrated driving chip  180  is the same for each embodiment, is the chip is still able to supply the analog driving signal to the plurality of data lines by increasing the number (e.g., 2, 3, 4 or more) of the data lines commonly connected to the channel terminals CH 1  through CHm. Thus, the resolution of the LCD  500  can be variously realized. The specific number of the data lines used is determined in accordance with a charging time of the analog driving signal. However, when a main clock signal is divided by 3, 4, 5 or more segments in order to increase the resolution of the LCD  500 , the charging time decreases. Therefore, it is desirable that the resolution of the LCD  500  is increased, while considering the charging time of the analog driving signal.  
         [0121]    Hereinafter, the gate driving circuit  140  formed in the left side of the peripheral region adjacent to the LCD panel will be described with reference to the accompanying drawings in detail.  
         [0122]    [0122]FIG. 14 is a block diagram of a first shift register in the gate driving circuit shown in FIG. 5 according to a first embodiment of the present invention, FIG. 15 is a detailed circuit diagram of each stage in the first shift register shown in FIG. 14, and FIG. 16 is an output waveform simulated at each stage shown in FIG. 15.  
         [0123]    Referring to FIG. 14, the gate driving circuit  140  includes a first shift register  141  that includes a plurality of cascade-connected stages, designated SRC 1  through SRCn. In other words, the output terminal OUT of each stage is connected to the input terminal of the next stage. The n stages of first shift register  141  correspond to the gate lines of GL 1  to GLn, with the addition of one dummy stage SRCn+1. Each individual stage has an input terminal IN, an output terminal OUT, a control terminal CT, a clock signal input terminal CK, a first power voltage terminal VSS, and a second power voltage terminal VDD.  
         [0124]    The input terminal IN of the first stage SRC 1  receives a start signal ST. The start signal ST is a pulse signal synchronized with the vertical synchronizing signal VSYN from the controller  181  shown in FIG. 5.  
         [0125]    Each of the output terminals OUT 1  through OUTn of the stages is connected to a corresponding gate line of GL 1  through GLn. Odd numbered stages SRC 1  and SRC 3  receive the first clock signal CK, and even numbered stages SRC 2  and SRC 4  receive the second clock signal CKB. The first clock signal CK and the second clock signal CKB have a phase opposite to one another.  
         [0126]    The output signals OUT 2 , OUT 3  and OUT 4  of the next stages SRC 2 , SRC 3  and SRC 4  are inputted to respective control terminals CT of the stages SRC 1 , SRC 2  and SRC 3 , respectively, as a control signal. In other words, the control signal inputted to the control terminal CT is used to pull-down the output signal from the previous stage to a logic low level.  
         [0127]    Thus, since the output signals of respective stages are sequentially generated within an active period of a logic high state, the gate lines corresponding to active periods of the respective output signals are selected.  
         [0128]    Referring to FIG. 15, there is shown a circuit diagram illustrating an exemplary stage if the first shift register  141 . As can be seen, each stage of the first shift register  141  includes a pull-up section  142 , a pull-down section  144 , a pull-up driving section  146 , and a pull-down driving section  148 .  
         [0129]    The pull-up section  142  includes a first NMOS transistor NT 1  having a drain connected to a clock signal input terminal, a gate connected to a third node N 3 , and a source connected to an output terminal OUT.  
         [0130]    The pull-down section  144  includes a second NMOS transistor NT 2  having a drain connected to an output terminal OUT, a gate connected to a fourth node N 4 , and a source connected to a first power voltage VSS.  
         [0131]    The pull-up driving section  146  includes a capacitor C and NMOS transistors NT 3 , NT 4  and NT 5 . The capacitor C is connected between the third node N 3  and the output terminal OUT. A drain of the third NMOS transistor NT 3  is connected to the second power voltage VDD, a gate of NT 3  is connected to the input terminal IN, and a source of NT 3  is connected to the third node N 3 . A drain of the fourth NMOS transistor NT 4  is connected to the third node N 3 , a gate of NT 4  is connected to control terminal CT, and a source of NT 4  is connected to the first power voltage VSS. A drain of the fifth NMOS transistor NT 5  is connected to the third node N 3 , a gate of NT 5  is connected to the fourth node N 4 , and a source of NT 5  is connected to the first power voltage VSS. The third NMOS transistor NT 3 , including the channel width thereof is about twice the size than that of the fifth NMOS transistor NT 5 .  
         [0132]    The pull-down driving section  148  includes sixth and seven NMOS transistors NT 6  and NT 7 . Both a drain and a gate of the sixth NMOS transistor NT 6  are commonly connected to the second power voltage VDD, and a source of the NT 6  is connected to the fourth node N 4 . A drain of the seventh NMOS transistor NT 7  is connected to the fourth node N 4 , a gate of NT 7  is connected to the third node N 3 , and a source of NT 7  is connected to the first power voltage VSS. The sixth NMOS transistor NT 6  has a size about sixteen times larger than that of the seven NMOS transistor NT 7 .  
         [0133]    As shown in FIG. 16, when first and second clock signals CK and CKB, along with start signal ST, are supplied to the shift register  170 , the first stage SRC 1  delays the effect of the first clock signal CK transitioning to logic high for a predetermined time, until the rising edge of the start signal ST. Thereby, a delayed first output signal OUT 1  is outputted through the output terminal OUT once CK goes from low to high, following ST going from low to high. Similarly, the second stage SRC 2  delays the effect of the second clock signal CKB transitioning from low to high, until the rising edge of the first output signal OUT 1  of the first stage SRC 1 . Thereby, a delayed second output signal OUT 2  is outputted through the output terminal OUT. The first to the N-th output signals OUT 1  to OUTn are thus sequentially generated through the output terminals OUT of the respective stages.  
         [0134]    [0134]FIG. 17 is a block diagram of a second shift register in the gate driving circuit shown in FIG. 5, according to a second embodiment of the present invention.  
         [0135]    Referring to FIG. 17, the gate driving circuit  140  includes a second shift register  142  that includes a plurality of cascade-connected stages designated SRC 1  through SRCn. In other words, the output terminal OUT of each stage is connected to the input terminal IN of the next stage. The second shift register  142  specifically includes n stages corresponding to the gate lines GL 1  through GLn, and further includes one dummy stage SRCn+1. As each stage is sequentially operated for a frame period, the n gate lines GL 1  through GLn are sequentially scanned.  
         [0136]    The dummy stage SRCn+1 provides the control signal to the control terminal CT of the Nth stage SRCn, and operates as a last stage. However, since there is no next stage after the dummy stage, the dummy stage SRCn+1 would otherwise be in an unstable state because the control terminal CT of the dummy stage SRCn+1 remains in a floating state.  
         [0137]    Thus, to prevent the dummy stage SRCn+1 from operating in an unstable state, the control terminal CT of the dummy stage SRCn+1 is connected to the start signal input terminal for receiving the start signal ST. That is, the dummy stage SRCn+1 receives the start signal ST as a control signal through the control terminal CT thereof.  
         [0138]    In operation, when a logic high start signal is applied to the start signal input terminal of the first stage SRC 1  (in order to execute a next frame after finishing a frame), the start signal is also applied to the control terminal CT of the dummy stage SRCn+1 as its control signal. In so doing, dummy stage SRCn+1 is prevented from operating in an unstable state by having the control terminal CT of the dummy stage SRCn+1 connected to the input terminal IN of the first stage SRC 1 . Also, as shown in FIG. 18, the control terminal CT of the dummy stage SRCn+1 may alternatively be connected to the previous stage SRCn in order to prevent the dummy stage SRCn+1 from operating in an unstable state.  
         [0139]    More specifically, FIG. 18 is a block diagram of a third shift register in the gate driving circuit shown in FIG. 5, according to a third embodiment of the present invention. FIG. 19 is a circuit diagram of the third shift register shown in FIG. 18.  
         [0140]    Referring to FIG. 18, the gate driving circuit  140  includes a third shift register  143  that includes a plurality of cascade-connected stages SRC 1  through SRCn. Again, the output terminal OUT of each stage is connected to both the input terminal IN of the next stage and the control terminal CT of the previous stage. The third shift register  143  includes n stages corresponding to gate lines GL 1  through GLn, with the addition of dummy stage SRCn+1. The dummy stage SRCn+1 provides the control signal to the control terminal CT of the Nth stage SRCn, and operates as a last stage. However, since there is no next stage after the dummy stage, the control terminal CT of the dummy stage SRCn+1 is connected to the fourth node N 4  of the Nth stage SRCn.  
         [0141]    Hereinafter, the electric potential at the fourth node N 4  will be described with reference to FIG. 19.  
         [0142]    When the output signal of the previous stage is applied from the Nth stage SRCn to the input terminal IN of the next stage SRCn+1, NMOS transistor NT 7  is turnedon. Accordingly, the electric potential of the fourth node N 4  is dropped down to the first power voltage VSS level.  
         [0143]    Although NMOS transistor N 7  is turned-on, the fourth node N 4  maintains the first power voltage VSS because NMOS transistor N 6  sixteen times larger than NMOS transistor N 7 . When the output signal (also supplied to the control terminal CT of the Nth stage SRCn) of the dummy stage SRCn+1 reaches a threshold voltage level, NMOS transistor NT 7  is turned off. At that point, only the second power voltage VDD is supplied to the fourth node N 4  through NMOS transistor NT 6 . Accordingly, the electric potential of the fourth node N 4  increases from the first power voltage VSS level to the second power voltage VDD level.  
         [0144]    When the output signal of the dummy stage SRCn+1 is dropped down to a low level, NMOS transistor NT 4  is turned off. However, the fourth node N 4  still has a bias voltage level at the second power voltage VDD because the second power voltage VDD is applied through the activated transistor NT 6  to the fourth node N 4 .  
         [0145]    The fourth node N 4  is connected to the control terminal CT of the dummy stage SRCn+1, such that the fourth NMOS transistor N 4  of the dummy stage SRCn+1 is turned on by means of the electric potential of the fourth node N 4 . Thus, a state of the output signal from the output terminal of the dummy stage SRCn+1 is changed into a turn-off voltage, and the dummy stage SRCn+1 is able to operate in a stable state.  
         [0146]    Since the control terminal CT of the dummy stage SRCn+1 is connected to the fourth node N 4  of the Nth stage SRCn, a separate line is not needed for electrically connecting the input terminal IN of the first stage SRC 1  to the control terminal CT of the dummy stage SRCn+1.  
         [0147]    [0147]FIG. 20 is a perspective view showing an FPC having only one pattern layer shown in FIG. 3.  
         [0148]    Referring to FIG. 20, the FPC  190  includes a circuit substrate separately disposed from the LCD panel  110  and a plurality of patterns that electrically connect the circuit substrate to the LCD panel  110 . The FPC  190  executes an operation that provides the signal generated from the circuit substrate to the integrated driving chip  180 .  
         [0149]    The integrated driving chip  180  receives the external image data signal and the external control signal  181   b . Particularly, the external control signal  181   b  includes the vertical and horizontal synchronizing signals VSYNC and HSYNC and the main clock signal MCLK.  
         [0150]    When the integrated driving chip  180  is disposed in the LCD panel  110 , the number of signals applied to the LCD panel  110  through the FPC decreases, thereby decreasing the number of patterns  191   a  to be formed in the FPC  190 . Accordingly, the FPC  190  can be formed to have only one pattern layer.  
         [0151]    The patterns  191   a  are formed on a first film  191  of the FPC  190 , and are covered by means of a second film  192  facing the first film  191 .  
         [0152]    [0152]FIG. 21 is a schematic view showing an LCD panel according to another embodiment of the present invention. FIG. 22 is a block diagram of fourth fifth shift registers of the first and second gate driving circuits shown in FIG. 21, and FIG. 23 is an output waveform of the shift register shown in FIG. 22.  
         [0153]    Referring to FIG. 21, the TFT substrate  120  is divided into a first region corresponding to the color filter substrate  130 , and a second region not corresponding to the color filter substrate  130 . The first region includes a display region and a peripheral region adjacent to the display region. On the display region, there are arranged a plurality of data lines DL extended along the row direction, and a plurality of gate lines GL extended along the column direction. First and second gate driving circuits  160  and  170  are integrated in the left and right sides of the peripheral region, respectively. The first gate driving circuit  160 , which is connected to the odd numbered gate lines of the plurality of gate lines GL, is disposed in the left side of the peripheral region. The second gate driving circuit  170 , which is connected to the even numbered gate lines of the plurality of gate lines GL, is disposed in the right side of the peripheral region. On the upper side of the peripheral region adjacent to the display region, the line block selecting circuit  150  connected to the plurality of data lines is disposed.  
         [0154]    In the second region of the TFT substrate  120 , there is arranged the integrated driving chip  180  for controlling the operation of the LCD panel  110 . The integrated driving chip  180  receives an external image data signal and an external control signal  181   b  from the external circuit substrate separately disposed from the LCD panel  110 . The integrated driving chip  180  provides first and second driving control signals GC 1  and GC 2  that control the first and second gate driving circuit  160  and  170 , respectively. The first and second driving control signals GC 1 , GC 2  also provide an analog driving signal to each of the plurality of data lines DL.  
         [0155]    Among the plurality of output terminals of the integrated driving chip  180 , each of the output terminals for outputting the first and second driving control signals GC 1  and GC 2  is connected to corresponding input terminals of the first and second gate driving circuit  160  and  170 . Further, an output terminal for outputting the line block selecting signal TG is connected to the control terminals of the line block selecting circuit  150 . Each of the channel terminals CH is connected to corresponding input terminals of the line block selecting circuit  150 , and each of the output terminals of the line block selecting circuit  150  is connected to corresponding data lines of the plurality of data lines DL.  
         [0156]    In particular, the first driving control signal GC 1  includes a start signal ST, a first clock signal CK, a first power voltage VOFF or VSS, and a second power voltage VON or VDD. The second driving control signal GC 2  includes a second clock signal CKB, the first power voltage VOFF or VSS, and the second power voltage VON or VDD.  
         [0157]    Referring to FIG. 22, the first gate driving circuit  160  includes a first shift register  161 . The first shift register  161  is disposed in the left side of the peripheral region of the display region to which the odd numbered gate lines GL 1  through GLn−1 are extended. Each of the output terminals OUT 1  through OUTn−1 of the first shift register  161  is connected to the odd numbered gate lines GL 1  through GLn−1. The second gate driving circuit  170  includes a second shift register  171 . The second shift register  171  is disposed in the right side of the peripheral region of the display region to which the even numbered gate lines GL 2  through GLn are extended. Each of the output terminals OUT 2  through OUTn of the second shift register  171  is connected to the even numbered gate lines GL 2  through GLn.  
         [0158]    The output signal from an i-th stage SRCi of the first shift register  161  is applied to an input terminal INj of the j-th stage SRCj of the second shift register  171 , which is disposed in the right side of the peripheral region, through the i-th gate line GLi. Simultaneously, the output signal from an i-th stage SRCi of the first shift register  161  is applied to a control terminal CTj−1 of the j−1th stage SRCj−1 as a control signal. Also, the output signal from a j-th stage SRCj of the second shift register  171  is applied to an input terminal lNi+1 of the (i+1)-th stage SRCi+1 of the first shift register  161 , and simultaneously applied to a control terminal CTi of the i-th stage SRCi of the first shift register  161  as a control signal. The last stage SRCn+1 of the first shift register  161  operates as a dummy stage, and provides the control signal to the control terminal CTn of the last stage SRCn.  
         [0159]    Referring to FIG. 23, the odd numbered gate lines GL 1  through GLn−1 and the even numbered gate lines GL 2  through GLn are sequentially shifted by the start signal ST. Synchronized with the first and second clock signals CK and CKB, the odd numbered gate lines GL 1  through GLn−1 and the even numbered gate lines GL 2  through GLn are alternately scanned.  
         [0160]    Among a plurality of pixels included in one horizontal line, each of the odd numbered pixels is operated by means of a corresponding gate line of the odd numbered gate lines GL 1  through GLn−1, and each of the even numbered pixels is operated by means of a corresponding gate line of the even numbered gate lines GL 2  through GLn.  
         [0161]    Both gate lines GL 1  and GL 2  are operated simultaneously to drive the total number of pixels included in one horizontal line, thereby increasing the number of gate lines by two. Therefore, when the LCD panel  120  includes 160 horizontal lines, 320 gate lines are used to operate the 160 horizontal lines.  
         [0162]    In accordance with above-described gate driving method, two horizontally adjacent TFT transistors in horizontal direction are commonly connected to a single data line, and are also connected to two lines separated from one another. Although the pixels are disposed in the same horizontal line, the odd numbered pixels are charged by means of the first gate driving circuit  160 , and then the even numbered pixels are charged by means of the second gate driving circuit  170 . The even numbered pixels are charged later than the odd numbered pixels by one clock cycle.  
         [0163]    [0163]FIG. 24 is a schematic view showing an LCD panel according to still another embodiment of the present invention.  
         [0164]    Referring to FIG. 24, the TFT substrate  121  is divided into a first region corresponding to the color filter substrate  130  and a second region not corresponding to the color filter substrate  130 . The first region includes the display region and the peripheral region adjacent to the display region. On the display region, there are arranged the plurality of data lines DL extended along the row direction, and a plurality of gate lines GL is extended along the column direction. A line block selecting circuit  150  is integrated in the upper side of the peripheral region adjacent to the display region to drive the plurality of data lines DL.  
         [0165]    In the second region of the TFT substrate  120 , an integrated driving chip  200  is arranged for controlling the operation of the LCD panel  110 . Specifically, the integrated driving chip  200  receives the external image data signal and the external control signal  181   b  from the external circuit substrate separately disposed from the LCD panel  110 . Then, the integrated driving chip  180  outputs the first gate driving signal GD 1  to drive the odd numbered gate lines GLn−1 and the second gate driving signal GD 2  to drive the even numbered gate lines GLn. Also, the integrated driving chip  180  provides analog driving signals to the plurality of data lines DL, respectively.  
         [0166]    Each of the output terminals for outputting the first gate driving signal GD 1  in the integrated driving chip  200  is connected to a corresponding gate line of the odd numbered gate lines GLn−1, and each of the output terminals for outputting the second gate driving signal GD 2  is connected to a corresponding gate line of the even numbered gate lines GLn. Each of channel terminals CH of the integrated driving chip  200  is connected to corresponding input terminals of the line block selecting circuit  150 , and the selecting signal TG outputted from the integrated driving chip  200  is applied to the line block selecting circuit  150 .  
         [0167]    [0167]FIG. 25 is a block diagram showing an integrated driving chip shown in FIG. 24. Hereinafter, elements performing the same functions with the elements shown in FIG. 7 have the same reference numerals as that of FIG. 7, and wherein the function of the elements is not illustrated.  
         [0168]    Referring to FIG. 25, the integrated driving chip  200  includes an interfacing part  181 , a memory  183 , a source driver  185 , a level shifter  184 , a first gate driver  188 , a second gate driver  189 , and a controller  182 .  
         [0169]    The controller  182  provides the first and second driving control signals GC 1  and GC 2 , as well as the line block selecting signal TG to the level shifter  184 . The first and second driving control signals GC 1  and GC 2  include a start signal ST, a first clock signal CK, a second clock signal CKB, a first power voltage VSS, and a second power voltage VDD.  
         [0170]    The level shifter  184  shifts the level of the first and second driving control signals GC 1  and GC 2 , and provides the level-shifted first and second driving control signals GC 1  and GC 2  to the first and second gate driver  188  and  189 .  
         [0171]    The first gate driver  188  outputs a first gate driving signal GD 1  in response to the first driving control signal GC 1 , thereby driving the odd numbered gate lines GLn−1 by means of the first gate driving signal GD 1 . Also, the second gate driver  189  outputs the second gate driving signal GD 2  in response to the second driving control signal GC 2 , thereby driving the even numbered gate lines GLn by means of the second gate driving signal GD 2 .  
         [0172]    Further, the integrated driving chip  200  includes a common voltage generator  186  and a DC/DC converter  187 . The common voltage generator  186  generates common voltage and supplies the common voltage to the common electrode line formed on the LCD panel  110 . The DC/DC converter  187  receives a DC power voltage  187   a  from an external source (not shown), converts a level of the DC power voltage  187   a , and supplies the converted DC power  187   a  to a controller  182 , a level shifter  184 , a source driver  185  and common voltage generator  186 , respectively.  
         [0173]    While the invention has been described above with reference to the aforementioned embodiments, it will be appreciated 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 embodiments embrace all such alternative modifications and variations as fall within the spirit and scope of the appended claims.