Abstract:
An analog buffer, and a driving method thereof, that has a low power consumption in driving a data line of a liquid crystal display and is insensitive to a deviation of device parameters to have a minor error between an input voltage and an output voltage, includes a first transistor and a second transistor connected in such a manner to be driven into a push-pull circuit. A first switch and a third switch connect and disconnect a first reference voltage and a second reference voltage such that the same current flows in the sources of the first and second transistors. A first capacitor charges the voltage between the gate and the source of the first transistor, and a second capacitor charges the voltage between the gate and the source of the second transistor. A second switch switches an application of the input voltage to the input stage of the push-pull circuit, and a fourth switch switches a charge of voltages between the gates and the sources of the first and second transistors in the first and second capacitors.

Description:
This application is a continuation of application Ser. No. 09/892,477 filed Jun. 28, 2001, ABANDONED. 
    
    
     REFERENCES TO RELATED APPLICATIONS 
     This application claims benefit of Korean Patent Application No. P2000-46579, filed on Aug. 11, 2000, the entirety of which is hereby incorporated by reference for all purposes as if fully set forth herein. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to a liquid crystal display device, and more particularly to an analog buffer and a driving method thereof that requires low power consumption in driving a data line of the liquid crystal display and is insensitive to a deviation of device parameters to have a minor error between an input voltage and an output voltage. 
     2. Description of the Related Art 
     Nowadays, a display device requires an ability to display a larger amount of information in conformity to the development into an intelligent society. In addition to this trend, the display device also needs to have high resolution, small thickness, light weight and low power consumption. Research has been actively conducted to meet these requirements. 
     Generally, a liquid crystal display (LCD) controls light transmissivities of liquid crystal cells in response to a video signal to thereby display a picture. An active matrix LCD provided with a switching device for each liquid crystal cell is suitable for displaying a moving picture. The active matrix LCD mainly uses a thin film transistor (TFT) as the switching device. 
     The active matrix LCD displays a picture corresponding to video signals, such as television signals, on a picture element or pixel matrix having pixels arranged at each intersection between gate lines and data lines. Each pixel includes a liquid crystal cell controlling a transmitted light quantity in accordance with a voltage level of a data signal from the data line. A TFT is arranged at each intersection between the gate lines and the data lines to switch a data signal delivered into the liquid crystal cell in response to a scanning signal (i.e., a gate signal) from the gate line. 
     FIG.  1 A and FIG. 1B show structures of an amorphous silicon thin film transistor LCD and a poly-crystalline silicon thin film transistor LCD, respectively. 
     Referring to FIG. 1A, the amorphous silicon thin film transistor (a-Si TFT) LCD includes a TFT array  3  provided on a substrate  1 , a data driver  6  and a gate driver  8  for driving the TFT array  3 , and a printed circuit board (PCB)  4  for connecting the TFT array  3  to the data and gate drivers  6  and  8 . The a-Si TFT LCD has a low electric field mobility and thus has the drivers  6  and  8  provided at the exterior thereof. 
     On the other hand, a poly-crystalline silicon thin film transistor (poly-Si TFT) LCD as shown in FIG. 1B includes a TFT array  5  provided on a substrate  2 , and a data driver  7  and a gate driver  9  for driving the TFT array  5 . In the poly-Si TFT LCD, driving circuits such as the data driver  7  and the gate driver  9  are mounted in the panel to largely reduce the number of signal lines connected to the exterior thereof, so that a product responsibility can be improved to largely reduce a manufacturing cost. Also, a poly-Si TFT having a smaller size than an a-Si TFT is used as a pixel switch owing to a high electric field mobility, to thereby obtain a high aperture ratio easily. Accordingly, research on the poly-Si TFT LCD has been actively conducted. 
     The poly-Si TFT LCD has a most significant advantage over the a-Si TFT LCD in that it can mount a CMOS circuit onto a cheap large-size glass substrate. Accordingly, with the poly-Si TFT LCD, it is possible to form on the same glass substrate the driving circuits such as the data driver  6  and the gate driver  7 , which are provided at the exterior thereof in the case of an a-Si TFT LCD. If the performance of the poly-Si TFT is improved continuously, then the poly-Si TFT LCD can have an increased circuit density and dimension, so that a central processing unit (CPU) and various sensors can be integrated to make a future ideal display device. However, although such an expectation can be realized only on a large-scale screen, the poly-Si TFT LCD has thus far only been applied to a medium/small-scale screen for a viewer of a digital camera or a projector, due to problems in the circuit performance according to device characteristics and fabrication technique. In the mean time, the poly-Si TFT LCD trends toward a large-scale screen and an improved performance, e.g., a 10.4″ XGA low-temperature poly-Si TFT LCD made by Toshiba corp. and a 12.1″ XGA low-temperature poly-Si TFT LCD made by LG PHILIPS LCD corp. 
     If the performance of such a poly-Si TFT is improved to increase an operation speed of the circuit, then it is essential to implement an analog buffer capable of driving the data lines on the panel. Although a typical single-crystalline silicon circuit has used an operational amplifier as the analog buffer, employing an operational amplifier for a poly-Si TFT having a large characteristic variation has a problem in that it has a large offset voltage and a large power consumption caused by a normal current due to its difficult matching characteristic. For this reason, it becomes difficult to use an operational amplifier as the analog buffer for the poly-Si TFT. This requires an analog buffer that is insensitive to a characteristic variation of the poly-Si TFT and has a simple structure to reduce the occupied area and power consumption. To use an analog buffer in which an N-channel poly-Si TFT is connected to a P-channel poly-Si TFT in a push-pull configuration, instead of the operational amplifier, forces an output voltage to generate a direct current voltage error corresponding to a threshold voltage. An analog buffer suggested for the purpose of overcoming such a direct current voltage error is as shown in FIG.  2 . 
     FIG. 2 is a circuit diagram of a conventional analog buffer with a capacitance capable of eliminating a direct current voltage error, and FIG. 3 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG.  2 . 
     Referring to FIG.  2  and FIG. 3, the analog buffer includes: a first node P 1  receiving an externally applied input voltage; first and third switches SW 1  and SW 3  connected to the first node P 1  to control the input voltage Vin; a second node P 2  connected to the first switch SW 1 ; a third node P 3  connected to the third switch SW 3 ; a capacitor Cvt connected between the second node P 2  and the third node P 3  to charge a desired voltage; a second switch SW 2  for conducting a desired voltage charged in the capacitor Cvt into a buffer; a fourth node P 4  connected to the second switch SW 2 ; and an N-channel poly-Si TFT T 1  and a P-channel poly-Si TFT T 2  connected between the second node P 2  and the fourth node P 4 . In this case, the N-channel poly-Si TFT T 1  is connected to the P-channel poly-Si TFT in a push-pull configuration. 
     The driving operation of such an analog buffer can be divided into three cases, depending on a range of the input voltage applied to the first node P 1 . 
     The first case is when the input voltage Vin is larger than the sum of the output voltage Vout and the threshold voltage Vtn of the N-channel poly-Si TFT T 1 . 
     First, in an initialization interval of the analog buffer, the first switch SW 1  and the second switch SW 2  are closed at the same time while the third switch SW 3  is open. An input voltage Vin applied to the first node P 1  is applied, via the closed first and second switches SW 1  and SW 2 , to gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  and the capacitor Cvt. By the input voltage Vin applied to the gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  and the capacitor Cvt, the N-channel poly-Si TFT T 1  is turned on while the P-channel poly-Si TFT T 2  is not turned on. Upon turning-on the N-channel poly-Si TFT T 1 , an output voltage Vout, corresponding to the input voltage Vin, reduced by Vtp (the threshold voltage of the N-channel poly-Si TFT T 1 ) is output to the fourth node P 4 . Also, the threshold voltage Vtn of the N-channel poly-Si TFT T 1  is charged in the capacitor Cvt. This is because the capacitor Cvt and the gate electrode and the source electrode of the N-channel poly-Si TFT T 1  form a single loop and are connected to each other in parallel. 
     In an error elimination interval of the analog buffer, the first switch SW 1  and the second switch SW 2  are opened while the third switch SW 3  is closed. At this time, the input voltage Vin is applied, via the third switch SW 3 , to the third node P 3 . The input voltage Vin applied to the third node P 3  is added to the threshold voltage Vtn charged in the capacitor Cvt during the initialization interval of the analog buffer. This sum voltage (Vin+Vtn) is applied to the gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2 . At this time, the P-channel poly-Si TFT T 2  maintains a turned-off state. The sum voltage (Vin+Vtn) applied to the gate electrode of the N-channel poly-Si TFT T 1  is reduced by the threshold voltage Vtn of the N-channel poly-Si TFT T 1  and, thereafter, the input voltage Vin only is output to the fourth node P 4  as it is. In other words, an output voltage Vout at the fourth node P 4  becomes equal to the input voltage Vin. 
     The second case is when an input voltage Vin is smaller than the sum of the output voltage Vout and the threshold voltage Vtp of the P-channel poly-Si TFT T 2 . 
     In an initialization interval of the analog buffer, the first switch SW 1  and the second switch SW 2  are closed at the same time while the third switch SW 3  is open. An input voltage Vin applied to the first node P 1  is applied, via the closed first and second switches SW 1  and SW 2 , to the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  and the capacitor Cvt. By the input voltage Vin applied to the N-channel poly-Si TFT T 1 , the P-channel poly-Si TFT T 2  and the capacitor Cvt, the P-channel poly-Si TFT T 2  is turned on while the N-channel poly-Si TFT T 1  is not turned on. Upon turning-on of the P-channel poly-Si TFT T 2 , an output voltage Vout corresponding to the input voltage Vin, reduced by Vtp (the threshold voltage of the P-channel poly-Si TFT T 2 ) is output to the fourth node P 4 . Also, a threshold voltage Vtp of the P-channel poly-Si TFT T 2  is charged in the capacitor Cvt. This is because the capacitor Cvt and the gate electrode and the source electrode of the P-channel poly-Si TFT T 2  form a single loop and are connected to each other in parallel. 
     In an error elimination interval of the analog buffer, the first switch SW 1  and the second switch SW 2  are opened while the third switch SW 3  is closed. At this time, an input voltage Vin is applied, via the third switch SW 3 , to the third node P 3 . The input voltage Vin applied to the third node P 3  is added to the threshold voltage Vtp charged in the capacitor Cvt during the initialization interval of the analog buffer. This sum voltage (Vin+Vtp) is applied to the gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2 . At this time, the N-channel poly-Si TFT T 1  maintains a turned-off state. The sum voltage (Vin+Vtp) applied to the gate electrode of the N-channel poly-Si TFT T 1  is reduced by the threshold voltage Vtn of the P-channel poly-Si TFT T 2  and, thereafter, the input voltage Vin only is output to the fourth node P 4  as it is. In other words, an output voltage Vout at the fourth node P 4  becomes equal to the input voltage Vin. 
     The third case is when an output voltage Vout does keep up with an input voltage Vin. This phenomenon is called a cross-over distortion. The cross-over distortion phenomenon of the analog buffer is negligible if an absolute value of the threshold voltage Vth of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  is less than twice the threshold voltage of the liquid crystal upon driving of the LCD in a dot inversion mode. However, an analog driving circuit configured by utilizing FIG. 2 causes a loss of an electric charge stored in an analog memory in the initialization interval of the analog buffer because an input voltage Vin is stored in a capacitor as the analog memory. This increases an error between the input voltage Vin to the output voltage Vout. In order to solve this problem, a reference voltage Vref should be applied to an input stage to initialize the analog buffer. 
     FIG. 4 is a circuit diagram showing a configuration of a conventional analog buffer having a capacitor for eliminating a direct current voltage error using a reference voltage, and FIG. 5 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG.  4 . 
     The analog buffer shown in FIG. 4 has the same driving characteristic as the analog buffer shown in FIG. 2 except that a reference voltage Vref separated from an input voltage Vin is individually applied to the first switch SW 1  so as to initialize the analog buffer. In other words, the analog buffer in FIG. 4 employs a scheme in which a driving method in FIG. 2 of storing a difference between the input voltage Vin and the output voltage Vout on the basis of the input voltage Vin in the initialization interval of the analog buffer is modified to store a difference between an input reference voltage Vref and the output voltage Vout on the basis of an external reference voltage Vref. This results in an advantage of reducing an error between the input voltage Vin to the output voltage Vout because a loss of an electric charge in the analog memory does not exist in the initialization interval of the analog buffer in FIG.  4 . 
     However, the conventional analog buffer has a problem in that its elements generate an error between an input voltage input to the analog buffer and an output voltage output via the analog buffer due to a current flowing at the vicinity of a threshold voltage. 
     SUMMARY OF THE INVENTION 
     Accordingly, it is an object of the present invention to provide an analog buffer and a driving method thereof that requires low power consumption in driving a data line of the liquid crystal display and is insensitive to a deviation of device parameters to have a minor error between an input voltage and an output voltage. 
     In order to achieve these and other objects of the invention, an analog buffer according to one aspect of the present invention includes a first transistor and a second transistor connected in such a manner to be driven into a push-pull circuit; a first switch and a third switch for switching a first reference voltage and a second reference voltage such that the same current flows in the sources of the first and second transistors; a first capacitor for charging the same voltage as a voltage between the gate and the source of the first transistor; a second capacitor for charging the same voltage as a voltage between the gate and the source of the second transistor; a second switch for switching an application of the input voltage to the input stage of the push-pull circuit; and a fourth switch for switching a charge of the same voltage as voltages between the gates and the sources of the first and second transistors in the first and second capacitors. 
     The analog buffer further includes a third transistor and a fourth transistor connected to the drain electrodes of the first transistor and the second transistor, respectively, for a cascade connection with the push-pull circuit; a fifth switch and a sixth switch for switching a third reference voltage and a fourth reference voltage such that the same current flows in the sources of the third and fourth transistors; a third capacitor for charging a voltage being equal to a voltage difference between the third reference voltage and the first reference voltage; and a fourth capacitor for charging a voltage being equal to a voltage difference between the second reference voltage and the fourth reference voltage. 
     Furthermore, the analog buffer includes a seventh switch connected to a node at which the sources of the first and second transistors are connected between the data lines such that the same current can be rapidly formed at the sources of the first and second transistors. 
     In the analog buffer, each of the first transistor and the third transistor consists of a N-channel poly-crystalline thin film transistor, and each of the second transistor and the fourth transistor consists of a P-channel poly-crystalline thin film transistor. 
     In the analog buffer, the first capacitor is connected between the gate and the source of the first transistor, and the second capacitor is connected between the gate and the source of the second transistor. The first switch is connected between a line to which the first reference is inputted and a node to which the first capacitor and the gate of the first transistor are connected, the second switch is connected between an input line to which the input voltage is applied and a node to which one stage of the first and second capacitor is connected, the third switch is connected between a line to which the second reference voltage is inputted and a node to which the second capacitor and the gate of the second transistor are connected; and the fourth switch is connected a node to which the sources of the first and second transistor are connected and a node to which the first capacitor and the second capacitor are connected. The third capacitor is connected between the gate of the first transistor and the gate of the third transistor, and the fourth capacitor is connected between the gate of the second transistor and the gate of the fourth transistor. The fifth switch is connected between a line to which the third reference voltage is inputted and a node to which the third capacitor and the gate of the third transistor are connected, and the sixth switch is connected between a line to which the fourth reference voltage is inputted and a node to which the fourth capacitor and the gate of the fourth transistor are connected. 
     A method of driving an analog buffer according to another aspect of the present invention includes an analog buffer initialization step of switching a first reference voltage and a second reference voltage such that the same current flows in source terminals and output terminals of a first transistor and a second transistor connected to be driven into a push-pull circuit and storing threshold voltages between the gates and the sources of the first transistor and the second transistors in first and second capacitors, respectively; and an analog buffer driving step of switching the input voltage such that an output voltage of the output terminal is equal to the input voltage and applying a sum voltage of the switched input voltage with the threshold voltages stored in the first and second capacitors to the gate terminals of the first and second transistors. 
     In the driving method, said analog buffer initialization step further includes switching a third reference voltage and a fourth reference voltage for a biasing of third and fourth transistors by connecting the third and fourth transistors to drain electrodes of the first and second transistors for a cascade connection to the push-pull circuit and charging voltages equal to a difference voltage between the third reference voltage and the first reference voltage and a difference voltage between the second reference voltage and the fourth reference voltage in third and fourth capacitors, respectively; and said analog buffer driving step further includes applying a sum voltage of the voltages stored in the first and third capacitors with the voltages stored in the second and fourth capacitors to the gates of the third and fourth transistors connected in cascade, respectively. 
     The driving method further includes allowing the same current to be rapidly formed at the sources of the first and second transistors by connecting a switch between nodes to which the sources of the first and second transistors are connected and a load, thereby opening the switch in said analog buffer initialization interval such that the analog buffer is not influenced by said load while closing the switch in said analog buffer driving interval to drive said drive. 
     In the driving method, each of the first transistor and the third transistor consists of a N-channel poly-crystalline thin film transistor, and each of the second transistor and the fourth transistor consists of a P-channel poly-crystalline thin film transistor. 
     In the driving method, the first capacitor is connected between the gate and the source of the first transistor, and the second capacitor is connected between the gate and the source of the second transistor. The first switch is connected between a line to which the first reference is inputted and a node to which the first capacitor and the gate of the first transistor are connected, the second switch is connected between an input line to which the input voltage is applied and a node to which one stage of the first and second capacitor is connected, the third switch is connected between a line to which the second reference voltage is inputted and a node to which the second capacitor and the gate of the second transistor are connected; and the fourth switch is connected a node to which the sources of the first and second transistor are connected and a node to which the first capacitor and the second capacitor are connected. The third capacitor is connected between the gate of the first transistor and the gate of the third transistor, and the fourth capacitor is connected between the gate of the second transistor and the gate of the fourth transistor. The fifth switch is connected between a line to which the third reference voltage is inputted and a node to which the third capacitor and the gate of the third transistor are connected, and the sixth switch is connected between a line to which the fourth reference voltage is inputted and a node to which the fourth capacitor and the gate of the fourth transistor are connected. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     These and other objects will be apparent from the following detailed description of the embodiments of the present invention with reference to the accompanying drawings, in which: 
     FIG.  1 A and FIG. 1B are schematic views showing structures of a conventional amorphous silicon thin film transistor liquid crystal display and a conventional polycrystalline silicon thin film transistor liquid crystal display; 
     FIG. 2 is a circuit diagram of a conventional analog buffer; 
     FIG. 3 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG. 2; 
     FIG. 4 is a circuit diagram of a conventional analog buffer in which the analog buffer shown in FIG. 2 has been improved; 
     FIG. 5 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG. 4; 
     FIG. 6 is a circuit diagram of an analog buffer according to a first embodiment; 
     FIG. 7 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG. 6; 
     FIG. 8 is a circuit diagram of an analog buffer according to a second embodiment; 
     FIG. 9 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG. 8; 
     FIG. 10 is a circuit diagram of an analog buffer according to a third embodiment; and 
     FIG. 11 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG.  10 . 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIG. 6 is a circuit diagram of an analog buffer according to a first embodiment, and FIG. 7 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG.  6 . 
     Referring to FIG.  6  and FIG. 7, the analog buffer according to the first embodiment includes: a first switch SW 1  for controlling a first externally applied reference voltage Vref1; a second switch SW 2  for controlling an input voltage Vin, a third switch SW 3  for controlling a second externally applied reference voltage Vref2; first, second and third nodes P 1 , P 2  and P 3  connected to the first, second and third switches SW 1 , SW 2  and SW 3 , respectively; a first capacitor C 1  connected between the first node P 1  and the second node P 2 ; a second capacitor C 2  connected between the second node P 2 ; and the third node P 3 , a fourth switch SW 4  connected to the second node P 2 ; a fourth node P 4  connected to the fourth switch SW 4 ; an N-channel poly-Si TFT T 1  connected between the first node PI and the fourth node P 4 ; and a P-channel poly-Si TFT T 2  connected between the third node P 3  and the fourth node P 4 . The N-channel poly-Si TFT T 1  is connected to the P-channel poly-Si TFT T 2  in a push-pull configuration. 
     With reference to driving the analog buffer, if the first reference voltage Vref1 and the second reference voltage Vref2 are applied to the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  in the push-pull circuit, respectively, then a source current of the N-channel poly-Si TFT T 1  becomes equal to that of the P-channel poly-Si TFT T 2 . At this time, threshold voltages between the gate and source electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  are stored in the first capacitor C 1  and the second capacitor C 2 . Thereafter, a sum voltage (Vin+Vtn+Vtp), in which the threshold voltages, stored in the first capacitor C 1  and the second capacitor C 2  are added to the input voltage Vin, is applied to the gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  to be divided into two operation ranges as shown in FIG. 7 for driving an output stage, thereby driving the analog buffer. 
     First, in an initialization interval of the analog buffer, the first, third and fourth switches SW 1 , SW 3  and SW 4  are closed while the second switch SW 2  is opened. Thus, the first and second reference voltages Vref1 and Vref2 are applied to the gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  respectively, in the push-pull circuit, and an output voltage Vout of the output stage is determined such that a source current of the N-channel poly-Si TFT T 1  becomes equal to that of the P-channel poly-Si TFT T 2 . The threshold voltages Vtn and Vtp between the gate and source electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2  allowing the source current of the N-channel poly-Si TFT T 1  to be equal to that of the P-channel poly-Si TFT T 2  are stored in the capacitor C 1  and the capacitor C 2 , respectively. 
     Then, in a driving interval of the analog buffer, the first, third and fourth switches SW 1 , SW 3  and SW 4  are opened while the second switch SW 2  is closed. Thus, the input voltage Vin is applied between the first capacitor C 1  and the second capacitor C 2  and a sum voltage (Vin+Vtn+Vtp) in which the voltages Vtn and Vtp stored in the first capacitor C 1  and the second capacitor C 2  are added to the input voltage Vin is applied to the gate electrodes of the N-channel poly-Si TFT T 1  and the P-channel poly-Si TFT T 2 , respectively, so that an output voltage Vout of the output stage is determined such that a source current of the N-channel poly-Si TFT T 1  is equal to that of the P-channel poly-Si TFT T 2 . Further, this output voltage Vout keeps up with the input voltage Vin automatically to operate the analog buffer. 
     FIG. 8 is a circuit diagram of an analog buffer according to a second embodiment, and FIG. 9 is a driving waveform diagram for explaining an operation of the analog buffer shown in FIG.  8 . 
     Referring to FIG.  8  and FIG. 9, the analog buffer according to the second embodiment includes: a first switch SW 1  for controlling a first externally applied reference voltage Vref1; a second switch SW 2  for controlling a second externally applied reference voltage Vref2; a third switch SW 3  for controlling an input voltage Vin; a fourth switch for controlling a third externally applied reference voltage Vref3; a fifth switch SW 5  for controlling a fourth externally applied reference voltage Vref4; first to fifth nodes P 1  to P 5  connected to the first to fifth switches SW 1  to SW 5 , respectively; a first capacitor C 1  connected between the first node P 1  and the second node P 2 ; a second capacitor C 2  connected between the second node P 2  and the third node P 3 ; a third capacitor C 3  connected between the third node P 3  and the fourth node P 4 ; a fourth capacitor C 4  connected between the fourth node P 4  and the fifth node P 5 ; a sixth switch SW 6  connected between the third node P 3  and a sixth node P 6 ; a first N-channel poly-Si TFT T 1  and a second N-channel poly-Si TFT T 2  connected between the first and second nodes P 1  and P 2  and the sixth node P 6 , respectively; and a third P-channel poly-Si TFT T 3  and a fourth P-channel poly-Si TFT T 4  connected between the fourth and fifth nodes P 4  and P 5  and the sixth node P 6 , respectively. 
     The first N-channel poly-Si TFT T 1  and the fourth P-channel poly-Si TFT T 4  are connected, in cascade, to drains of the second N-channel poly-Si TFT T 2  and the third P-channel poly-Si TFT T 3  connected in a push-pull configuration. The first capacitor C 1  and the fourth capacitor C 4  are connected between the gates of the second N-channel poly-Si TFT T 2  and the third P-channel poly-Si TFT T 3 , connected in a push-pull configuration, and the gates of the first N-channel poly-Si TFT T 1  and the fourth P-channel poly-Si TFT T 4  connected in cascade, respectively, so as to bias the first N-channel poly-Si TFT T 1  and the fourth P-channel poly-Si TFT T 4  connected in cascade. Values of the first reference voltage Vref1 and the fourth reference voltage Vref4 are set such that the first N-channel poly-Si TFT T 1  and the fourth P-channel poly-Si TFT T 4  connected in cascade are operated at saturation areas. 
     The analog buffer configured as described above is divided into two operation ranges for its driving, as shown in FIG.  9 . 
     First, in an initialization interval of the analog buffer, the first, second, fourth, fifth and sixth switches SW 1 , SW 2 , SW 4 , SW 5  and SW 6  are closed while the third switch SW 3  is opened. Thus, the first, second, third and fourth reference voltages Vref1, Vref2, Vref3 and Vref4 are applied to the gates of the first N-channel poly-Si TFT T 1 , the second N-channel poly-Si TFT T 2 , the first P-channel poly-Si TFT T 2  and the second P-channel poly-Si TFT T 4 . At this time, the applied first, second, third and fourth reference voltages Vref1, Vref2, Vref3 and Vref4 set a voltage at the sixth node P 6 . A source voltage of the first N-channel poly-Si TFT T 1  and a source voltage of the second P-channel poly-Si TFT T 4  are determined such that source currents of the first N-channel poly-Si TFT T 1 , the second N-channel poly-Si TFT T 2 , the third P-channel poly-Si TFT T 3  and the fourth P-channel poly-Si TFT T 4  become equal to each other. The source voltage of the first N-channel poly-Si TFT T 1  is a voltage given by subtracting a threshold voltage Vt1 of the first N-channel poly-Si TFT T 1  from the first reference voltage Vref1, and the source voltage of the fourth P-channel poly-Si TFT T 4  is a voltage given by subtracting a threshold voltage Vt4 of the fourth P-channel poly-Si TFT T 4  from the fourth reference voltage Vref4. At this time, voltages between the gates and the sources of the second N-channel poly-Si TFT T 2  and the third P-channel polySi TFT T 3 , connected in a push-pull configuration, are stored in the second capacitor C 2  and the third capacitor C 3 , respectively. Further, a voltage difference between the first reference voltage Vref1 and the second reference voltage Vref2 is stored in the first capacitor C 1 , and a voltage difference between the third reference voltage Vref3 and the fourth reference voltage Vref4 is stored in the fourth capacitor C 4 . 
     Then, in a driving interval of the analog buffer, the first, second, fourth, fifth and sixth switches SW 1 , SW 2 , SW 4 , SW 5  and SW 6  are opened while the third switch SW 3  is closed. This allows an input voltage Vin to be loaded between the second capacitor C 2  and the third capacitor C 3 , to thereby apply a voltage given by adding the voltages stored in the first, second, third and fourth capacitors C 1 , C 2 , C 3  and C 4  to the input voltage Vin to the gates of the first N-channel poly-Si TFT T 1 , the second N-channel poly-Si TFT T 2 , the third P-channel poly-Si TFT T 3  and the fourth P-channel poly-Si TFT T 4 . If a voltage is applied to the gates of the first N-channel poly-Si TFT T 1 , the second N-channel poly-Si TFT T 2 , the third P-channel poly-Si TFT T 3  and the fourth P-channel poly-Si TFT T 4 , then a voltage at each node is determined such that source currents of the first N-channel poly-Si TFT T 1 , the second N-channel poly-Si TFT T 2 , the third P-channel poly-Si TFT T 3  and the fourth P-channel poly-Si TFT T 4  becomes equal to each other. Accordingly, an output voltage Vout become equal to the input voltage Vin. 
     A voltage variation between the drains and the sources of the second N-channel poly-Si TFT T 2  and the third P-channel poly-Si TFT T 3  can be considerably reduced by the first channel poly-Si TFT T 1  and the fourth P-channel poly-Si TFT T 4  connected in cascade in the initialization interval and the driving interval of the analog buffer. Accordingly, it becomes possible to considerably reduce an output error of the analog buffer caused by a voltage variation between the drain and the gate of the poly-Si TFT. 
     When a large load capacitance is applied onto the analog buffer according to the first or second embodiment, a long time is required to equalize the source currents of the poly-Si TFTs in the initialization interval of the analog buffer, thereby decreasing the speed of the analog buffer. In order to solve this problem, the first switch SW 1  is connected to the output stage of the present analog buffer as shown in FIG.  10 . FIG. 10 will be described in conjunction with FIG. 11 below. 
     If it is intended to equalize the source currents of the poly-Si TFTs in the initialization interval of the analog buffer, then a large external load capacitance  14  opens the first switch SW 1 , using a switching control signal  12 . If the first switch SW 1  is opened, then the source currents of the poly-Si TFTs become equal to each other within a short time, so that a speed of the analog buffer  10  can be increased. 
     As described above, according to the present invention, it becomes possible to have low power consumption in driving a data line of the liquid crystal display as well as to be insensitive to a deviation of device parameters to have a minor error between an input voltage and an output voltage. 
     Although the present invention has been explained by the embodiments shown in the drawings described above, it should be understood to the ordinary skilled person in the art that the invention is not limited to the embodiments, but rather that various changes or modifications thereof are possible without departing from the spirit of the invention. Accordingly, the scope of the invention shall be determined only by the appended claims and their equivalents.