Abstract:
A display device which enhances time-wise likelihood for a leak current from a floating memory node by increasing the number of writings of a voltage to a floating memory node. A vertical driver includes: a shift register including basic circuits which output common electrode driving pulses based on a transfer; and a common electrode driver including common basic circuits which receive the common electrode driving pulses and the transfer clock. Each common basic circuit includes: a circuit A which fetches an AC signal based on the common electrode driving pulse; a circuit B which outputs, based on the AC signal, a first common voltage or a second common voltage which differs from the first common voltage in voltage level to the common electrodes corresponding to the AC signal; and a circuit C which holds a state of the circuit B based on the transfer clock.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     The disclosure of Japanese Patent Application No. 2008-54732 filed on Mar. 5, 2008 including the specification, drawings and abstract is incorporated herein by reference in its entirety. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a display device, and more particularly to a technique which is effectively applicable to a display device having a common electrode driver circuit which drives common electrodes. 
     2. Description of the Related Art 
     For example, in an active-matrix-type liquid crystal display device which uses thin film transistors (TFT) as active elements, on a liquid-crystal-side surface of one substrate out of substrates which are arranged to face each other in an opposed manner with liquid crystal sandwiched therebetween, pixel regions each of which is surrounded by scanning signal lines which extend in the x direction and are arranged parallel to each other in the y direction and video signal lines which extend in the y direction and are arranged parallel to each other in the x direction are formed. The pixel region includes a pixel-use transistor (TFT) which is operated in response to the supply of a scanning signal from the scanning signal line. 
     The liquid crystal display device includes a vertical driver circuit which supplies a scanning signal to the respective scanning signal lines, and a horizontal driver circuit which supplies a video signal to the respective video signal lines, and these driver circuits respectively include a shift register circuit. 
     On the other hand, there has been also known a polysilicon-type liquid crystal display device in which a semiconductor layer of a thin film transistor which constitutes the above-mentioned active element is made of polycrystalline silicon (polysilicon). In such a polysilicon-type liquid crystal display device, the thin film transistor (for example, MOS transistor) which constitutes the vertical driver circuit and the horizontal driver circuit is also formed on the above-mentioned surface of one substrate in the same step as the thin film transistors which constitutes the active elements. 
     For example, Japanese Patent Laid-Open No. 2007-156054 (patent document 1) discloses a related art of the present invention. That is, patent document 1 discloses a liquid crystal display device which includes a single-channel (n-MOS) common electrode driver circuit in a vertical driver circuit. 
     SUMMARY OF THE INVENTION 
     In the single-channel common electrode driver circuit disclosed in the above-mentioned patent document 1, a transistor which outputs a common voltage of positive polarity or a common voltage of negative polarity to common electrodes corresponding to the common voltage has a gate thereof connected to a node which constitutes a floating memory node. With respect to writing of the voltage to the floating memory node, one writing (refreshing) is performed during 1 frame. 
     Accordingly, a leak current from the floating memory node influences the operational stability. Particularly, when the threshold voltage Vth of the transistor which is connected to the floating memory node is low, the leak current from the transistor is increased and hence, a stable operation is deteriorated resulting in a possibility of lowering of likelihood of a threshold value. 
     The present invention has been made to overcome the above-mentioned drawbacks of the related art, and it is an object of the present invention to provide, in a display device having a single-channel common electrode driver circuit, a technique which can enhance time-wise likelihood for a leak current from a floating memory node by increasing the number of times of writing of a voltage in the floating memory node. 
     The above-mentioned and other objects and novel features of the present invention will become apparent from the description of this specification and attached drawings. 
     To briefly explain the summary of typical inventions among the inventions disclosed in this specification, they are as follows. 
     (1) According to one aspect of the present invention, there is provided a display device which includes: a display panel which includes a plurality of pixels and a plurality of common electrodes; and a vertical driver circuit, wherein a vertical driver circuit includes a shift register circuit and a common electrode driver circuit, the shift register circuit is constituted of a plurality of basic circuits which outputs common electrode driving pulses based on a transfer clock inputted from the outside, the common electrode driver circuit is constituted of a plurality of common basic circuits to which the respective common electrode driving pulses outputted from the respective basic circuits of the shift register circuit and the transfer clock are inputted, and each of the common basic circuits includes: a circuit A which fetches AC signals based on the common electrode driving pulse; a circuit B which outputs, based on the AC signals fetched by the circuit A, a first common voltage or a second common voltage which differs from the first common voltage in voltage level to the common electrodes corresponding to the AC signals; and a circuit C which holds a state of the circuit B based on the transfer clock. 
     (2) In the display device having the above-mentioned constitution (1), the circuit A includes: a first transistor which receives inputting of the common electrode driving pulse to a control electrode thereof, and fetches a first AC signal inputted to a second electrode thereof based on the common electrode driving pulse; a second transistor which receives inputting of the common electrode driving pulse to a control electrode thereof, and fetches a second AC signal inputted to a second electrode thereof based on the common electrode driving pulse; a third transistor in diode connection which is connected to a first electrode of the first transistor; and a fourth transistor in diode connection which is connected to a first electrode of the second transistor. 
     (3) In the display device having the above-mentioned constitution (2), the circuit A further includes: a fifth transistor which has a second electrode thereof connected to a first electrode of the third transistor, and has a control electrode thereof connected to a first electrode of the first transistor; and a sixth transistor which has a second electrode thereof connected to a first electrode of the fourth transistor, and has a control electrode thereof connected to a first electrode of the second transistor. 
     (4) In the display device having the above-mentioned constitution (2) or (3), the circuit B further includes: a seventh transistor which receives inputting of the first AC signal fetched by the first transistor to a control electrode thereof, and outputs the first common voltage to a common electrode thereof corresponding to the first AC signal based on the first AC signal; and an eighth transistor which receives inputting of the second AC signal fetched by the second transistor to a control electrode thereof, and outputs the second common voltage to a common electrode thereof corresponding to the second AC signal based on the second AC signal. 
     (5) In the display device having the above-mentioned constitution (4), the circuit C further includes: a first capacitive element; a second capacitive element; a circuit C 1  which charges the first capacitive element for every first transfer clock, and boosts a voltage of a node thereof to which the control electrode of the seventh transistor is connected via the first capacitive element for every second transfer clock which differs from the first transfer clock in phase; and a circuit C 2  which charges the second capacitive element for every first transfer clock, and boosts a voltage of a node thereof to which the control electrode of the eighth transistor is connected via the second capacitive element for every said second transfer clock. 
     (6) In the display device having the above-mentioned constitution (5), the circuit C 1  includes: a ninth transistor in diode connection which receives inputting of the first transfer clock to a second electrode thereof; a tenth transistor which has a second electrode thereof connected to a first electrode of the ninth transistor, and has a control electrode thereof connected to a control electrode of a seventh transistor; an eleventh transistor in diode connection which has a second electrode thereof connected to a first electrode of the tenth transistor, and has a first electrode thereof connected to the control electrode of the seventh transistor; and a twelfth transistor which receives inputting of the second transfer clock to a second electrode thereof, and has a control electrode thereof connected to the control electrode of the seventh transistor, wherein the first capacitive element is connected between a first electrode of the twelfth transistor and a first electrode of the tenth transistor, and the circuit C 2  includes: a thirteenth transistor in diode connection which receives inputting of the first transfer clock to a second electrode thereof; a fourteenth transistor which has a second electrode thereof connected to a first electrode of the thirteenth transistor, and has a control electrode thereof connected to a control electrode of an eighth transistor; a fifteenth transistor in diode connection which has a second electrode thereof connected to a first electrode of the fourteenth transistor, and has a first electrode thereof connected to the control electrode of the eighth transistor; and a sixteenth transistor which receives inputting of the second transfer clock to a second electrode thereof, and has a control electrode thereof connected to the control electrode of the eighth transistor, wherein the second capacitive element is connected between a first electrode of the sixteenth transistor and a first electrode of the fourteenth transistor. 
     (7) In the display device having the above-mentioned constitution (5) or (6), the circuit C includes: the sixteenth transistor which has the second electrode thereof connected to the control electrode of the eighth transistor, and has the control electrode thereof connected to the control electrode of the seventh transistor; a seventeenth transistor which has a second electrode thereof connected to the first electrode of the sixteenth transistor, has a control electrode thereof connected to the control electrode of the seventh transistor, and receives inputting of a reference voltage to the first electrode thereof; the eighteenth transistor which has a second electrode thereof connected to the control electrode of the seventh transistor, and has the control electrode thereof connected to the control electrode of the eighth transistor; and a nineteenth transistor which has a second electrode thereof connected to a first electrode of the eighteenth transistor, has a control electrode thereof connected to the control electrode of the eighth transistor, and receives inputting of a reference voltage to the first electrode thereof. 
     (8) In the display device having any one of the above-mentioned constitutions (2) to (7), the first AC signal and the second AC signal are signals which make phases thereof different from each other for every 1 display line, and each of the common electrode driver circuits outputs the first common voltage and the second common voltage alternately for every 1 display line to the respective common electrodes corresponding to the first AC signal and the second AC signal. 
     (9) In the display device having any one of the above-mentioned constitutions (2) to (7), a voltage level of the first AC signal and a voltage level of the second AC signal are not changed within 1 frame, the voltage level of the first AC signal and a voltage level of the second AC signal are inverted within a next frame, and the respective common electrode driver circuits alternately output the first common voltage and the second common voltage for every 1 frame to the respective common electrodes corresponding to the first AC signal and the second AC signal. 
     To briefly explain advantageous effects obtained by the typical inventions among the inventions disclosed in this specification, they are as follows. 
     According to the present invention, in the display device having a single-channel common electrode driver circuit, the number of times of writing of a voltage in the floating memory node can be increased thus enhancing time-wise likelihood for a leak current from the floating memory node. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a circuit diagram showing an equivalent circuit of a liquid crystal display device of an embodiment according to the present invention; 
         FIG. 2  is a block diagram showing the schematic constitution of a vertical driver circuit of the embodiment according to the present invention; 
         FIG. 3  is a circuit diagram showing the circuit constitution of a common basic circuit shown in  FIG. 2 ; 
         FIG. 4A  is a timing chart showing input signals inputted to the circuit shown in  FIG. 3  and voltage changes at respective nodes; 
         FIG. 4B  is a timing chart showing a modification of the input signals inputted to the circuit shown in  FIG. 3 ; 
         FIG. 5  is a block diagram showing the schematic constitution of a conventional vertical driver circuit; 
         FIG. 6  is a timing chart showing input signals inputted to a shift register circuit shown in  FIG. 5  and output signals outputted from the shift register circuit; 
         FIG. 7  is a circuit diagram showing the circuit constitution of a common basic circuit shown in  FIG. 5 ; and 
         FIG. 8  is a timing chart showing input signals inputted to the circuit shown in  FIG. 7  and voltage changes at respective nodes. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Hereinafter, an embodiment in which the present invention is applied to a liquid crystal display device is explained in detail in conjunction with drawings. 
     Here, in all drawings for explaining the embodiment, parts having identical functions are given same symbols and their repeated explanation is omitted. 
       FIG. 1  is a circuit diagram showing an equivalent circuit of a liquid crystal display device of an embodiment according to the present invention. 
     As shown in  FIG. 1 , the liquid crystal display device of this embodiment includes, on a liquid-crystal surface of one substrate out of a pair of substrates which is arranged to face each other in an opposed manner with liquid crystal therebetween, n pieces of scanning signal lines (also referred to as gate lines) (X 1 , X 2 , . . . Xn) which extend in the x direction, n pieces of common electrodes (also referred to as common lines) (CT 1 , CT 2 , . . . CTn) which extend in the x direction, and m pieces of video signal lines (also referred to as drain lines or source lines) (Y 1 , Y 2 , . . . Ym) which intersect with the x direction and extend in the y direction. 
     Regions which are surrounded by the scanning signal lines and the video signal lines constitute pixel regions. Each pixel region is provided with a pixel-use transistor (TFT) which has a gate thereof connected to the scanning signal line, a drain (or a source) thereof connected to the video signal line, and a source (or a drain) thereof connected to a pixel electrode (PX). Further, liquid crystal capacity (LC) and a holding capacitance (Cadd) are formed between the pixel electrode (PX) and common electrodes (CT 1 , CT 2 , . . . CTn). 
     The respective scanning signal lines (X 1 , X 2 , Xn) are connected to a vertical driver circuit (XDV), and the vertical driver circuit (XDV) sequentially supplies a selection scanning signal to the scanning signal lines in order from the scanning signal line X 1  to the scanning signal line Xn (or in order from the scanning signal line Xn to the scanning signal line X 1 ). 
     The respective common electrodes (CT 1 , CT 2 , . . . CTn) are connected to the vertical driver circuit (XDV), and the vertical driver circuit (XDV) performs AC driving by sequentially changing over polarity of a voltage applied to common electrodes (CT 1 , CT 2 , . . . CTn) in order from the common electrode CT 1  to CTn (or in order from the common electrode CTn to CT 1 ) at the same timing as the selection scanning signal. The respective video signal lines (Y 1 , Y 2 , . . . Ym) are connected to drains (or sources) of switching elements (S 1 , S 2 , . . . Sm). The switching elements (S 1 , S 2 , . . . Sm) have sources (or drains) thereof connected to video lines (DATA) and have gates thereof connected to a horizontal driver circuit (YDV). By the horizontal driver circuit (YDV), scanning is sequentially performed in order from the switching element S 1  to the switching element Sm (or in order from the switching element Sm to the switching element S 1 ). 
     The liquid crystal display panel of this embodiment is constituted as follows. The first substrate on which the pixel electrodes, the thin film transistors and the like are formed (also referred to as TFT substrate or active matrix substrate) (not shown in the drawing) and the second substrate on which color filters and the like are formed (also referred to as counter substrate) (not shown in the drawing) are overlapped with each other with a predetermined gap therebetween, both substrates are adhered to each other by a sealing material which is formed in a frame shape in the vicinity of peripheral portions of both substrates, liquid crystal is filled and sealed in a space defined inside the sealing material between both substrates through a liquid crystal filling port formed in a portion of the sealing material, and a polarizer is laminated to outer surfaces of both substrates. 
     In this manner, the liquid crystal display panel of this embodiment adopts the structure in which liquid crystal is sandwiched between a pair of substrates. Further, the counter electrodes are formed on a counter substrate side when the liquid crystal display panel is a TN-type or VA-type liquid crystal display panel. When the liquid crystal display panel is an IPS (In Plane Switching)-type liquid crystal display panel, the counter electrodes are formed on a TFT substrate side. Since the present invention is not relevant to the inner structure of the liquid crystal display panel, the detailed explanation of the inner structure of the liquid crystal display panel is omitted. Further, the present invention is applicable to a liquid crystal display panel having any structure. Still further, although a backlight is arranged on a back surface side of the liquid crystal display panel, since the present invention is not relevant to the inner structure of the backlight, the detailed explanation of the inner structure of the backlight is also omitted in this specification. 
     In this embodiment, with respect to transistors which are used in the vertical driver circuit (XDV) and the horizontal driver circuit (YDV) respectively, a semiconductor layer is made of polycrystalline silicon (polysilicon), and is formed on a surface of one substrate in the same step as the thin film transistor which constitutes the active element. 
     Prior to the explanation of the vertical driver circuit of this embodiment, the constitution of a conventional vertical driver circuit is explained. 
       FIG. 5  is a block diagram showing the schematic constitution of the conventional vertical driver circuit. 
     In  FIG. 5 , symbol  10  indicates a shift register circuit, symbol  11  indicates a common electrode driver circuit, symbol S/R indicates a plurality of basic circuits which constitutes the shift register circuit  10 , and symbol COMA indicates a plurality of common basic circuits which constitutes the common electrode driver circuit. 
     The nth common basic circuit (COMAn) has an output terminal (O 1   n ) and an input terminal (I 2   n ) thereof connected to the preceding-stage common basic circuit (COMAn−1), while the nth common basic circuit (COMAn) has an input terminal (I 1   n ) and an output terminal (O 2   n ) thereof connected to the succeeding-stage common basic circuit (COMAn+1). Here, a start pulse (VIN) is inputted to an input terminal (I 2   l ) of the first-stage common basic circuit (COMA 1 ). 
       FIG. 6  shows input signals and output signals of the shift register circuit  10 . 
     Driving of the shift register circuit  10  is started when the start pulse (VIN) is inputted to the first-stage basic circuit (S/R 1 ) and the shift register circuit  10  outputs signals whose phases are shifted by 1 clock for every stage from an uppermost stage to a lowermost stage in synchronism with a first transfer clock (SV 1 ) and a second transfer clock (SV 2 ). 
     Each basic circuit (S/R) outputs a selection scanning voltage supplied to the respective scanning signal lines (G) and a common-electrode-driving pulse (COMAIN) which is inputted to each common basic circuit (COMA). 
       FIG. 7  shows the circuit constitution of the common basic circuit (COMA) shown in  FIG. 5 . 
     In n-type MOS transistors (hereinafter, simply referred to as transistors) (Tr 101 , Tr 102 ), when the common-electrode-driving pulse (COMAIN) assumes a High level (hereinafter, referred to as H level), one of two nodes consisting of a node (node 11 ) and a node (node 12 ) assumes an H level and another node assumes a Low level (hereinafter, referred to as L level) in response to voltage level of AC signals M 1 , M 2 . 
     When the node (node 11 ) assumes an H level, a transistor (Tr 103 ) is turned on so that a common voltage (CM 11 ) of positive polarity is outputted to the common electrode (CT), while when the node (node 12 ) assumes an H level, a transistor (Tr 104 ) is turned on so that a common voltage (CM 12 ) of negative polarity is outputted to the common electrode (CT). 
     In this specification, “positive polarity” in the term “common voltage of positive polarity” implies that the common voltage is on a high potential side compared to a voltage applied to the pixel electrode (PX), and whether or not the common voltage is larger or smaller than 0V does not matter. In the same manner, “negative polarity” in the term “common voltage of negative polarity” implies that the common voltage is on a low potential side compared to a voltage applied to the pixel electrode (PX), and whether or not the common voltage is larger or smaller than 0V does not matter. 
     In transistors (Tr 105 , Tr 106 ), when the common-electrode-driving pulse (COMAIN) is changed from an H level to an L level (that is, when a node (node 13 ) is changed from an H level to an L level), the H level of the node (node 11 ) is held. In the same manner, in transistors (Tr 116 , Tr 117 ), when the common-electrode driving pulse (COMAIN) is changed from an H level to an L level, the H level of the node (node 12 ) is held. 
     Transistors (Tr 107 , Tr 108 ) completely hold the node (node 12 ) at an L level during a period in which the node (node 11 ) assumes an H level thus preventing the node (node 11 ) and the node (node 12 ) from assuming the H level simultaneously. In the same manner, transistors (Tr 122 , Tr 123 ) completely hold the node (node 11 ) at an L level during a period in which the node (node 12 ) assumes an H level thus preventing the node (node 11 ) and the node (node 12 ) from assuming the H level simultaneously. 
     In a transistor (Tr 109 ) to which a succeeding-stage common-electrode-driving pulse (COMAINn+1) is inputted via a transistor (Tr 111 ), when the node (node 11 ) is in an H-level state, a node (node 15 ) assumes an H level. In the same manner, in a transistor (Tr 110 ), when the node (node 12 ) is in an H-level state, a node (node 16 ) also assumes an H level. 
     In the transistor (Tr 111 ) in diode connection, when the common electrode driving pulse (COMAINn+1) is changed from an H level to an L level, a node (node 14 ) is held at an H level. 
     A capacitive element (C 11 ) holds the H-level state of the node (node 11 ) and, at the same time, when the node (node 15 ) is changed from an L level to an H level, boosts a voltage of the node (node 11 ) thus making the voltage of the node (node 11 ) higher than the H level whereby ON resistance of a transistor (Tr 103 ) is lowered. A capacitive element (C 13 ) also performs an operation similar to the operation of the capacitive element (C 11 ). 
     A capacitive element (C 12 ) holds an H-level state of the node (node 15 ). A capacitive element (C 14 ) holds an H-level state of the node (node 16 ). 
     A transistor (Tr 112 ) is provided for preventing a voltage of the node (node 15 ) from being boosted by the capacitive element (C 11 ) when the node (node 11 ) is changed from the L level to the H level. In the same manner, a transistor (Tr 118 ) is provided also for preventing a voltage of the node (node 16 ) from being boosted by the capacitive element (C 13 ) when the node (node 12 ) is changed from the L level to the H level. 
     In a transistor (Tr 113 ), when the preceding-stage common-electrode-driving pulse (COMAINn−1) assumes an H level, the node (node 15 ) assumes an L level. In the same manner, in a transistor (Tr 119 ), when the preceding-stage common-electrode-driving pulse (COMAINn−1) assumes an H level, the node (node 16 ) assumes an L level. 
     In transistors (Tr 114 , Tr 115 ), when the preceding-stage common-electrode-driving pulse (COMAINn−1) assumes an H level, the node (node 11 ) assumes an L level. In the same manner, in transistors (Tr 120 , Tr 121 ), when the preceding-stage common-electrode-driving pulse (COMAINn−1) assumes an H level, the node (node 12 ) assumes an L level. 
       FIG. 8  shows the input signals inputted to the circuit shown in  FIG. 7  and voltage changes at the respective nodes. 
     When the preceding-stage common-electrode driving pulse (COMAINn−1) assumes an H level during a period t 11 , the transistors (Tr 113  to Tr 115 ) and the transistors (Tr 119  to Tr 121 ) are turned on so that the node (node 11 ), the node (node 12 ), the node (node 15 ) and the node (node 16 ) assume an L level. 
     Next, when the own-stage common electrode driving pulse (COMAINn) assumes an H level during a period t 12 , the transistors (Tr 101 , Tr 102 ) are turned on. Further, when the AC signal (M 1 ) assumes an H level simultaneously with such an operation, the transistors (Tr 105 , Tr 106 ) are turned on and hence, the node (node 11 ) assumes an H level whereby the capacitive element (C 11 ) is charged with electricity. 
     During a period in which the node (node 11 ) holds the H level, the node (node 12 ) is fixed to the L level by the transistors (Tr 107 , Tr 108 ). Further, at this point of time, the node (node 15 ) which constitutes a floating node is fixed to the L level since the transistor (Tr 112 ) is turned on. 
     The node (node 11 ) holds an H-level state due to the capacitive element (C 11 ) and hence, the transistor (Tr 109 ) is in an ON state. In such a state, when the succeeding-stage common-electrode-driving pulse (COMAINn+1) assumes an H level during a period t 13 , the node (node 15 ) assumes an H level. 
     When the node (node 15 ) assumes an H level, a voltage of the node (node 11 ) is boosted (or charged up) by the capacitive element (C 11 ) and hence, the voltage of the node (node 11 ) is set higher than the H level whereby ON resistance of the transistor (Tr 103 ) is lowered. 
     In the next frame, phases of AC signals (M 1 , M 2 ) are inverted, and when the preceding-stage common electrode driving pulse (COMAINn−1) assumes an H level during a period t 14 , the node (node 11 ), the node (node 12 ), the node (node 11 ) and the node (node 15 ) assume an L level. Hereinafter, the similar operations are performed at the node (node 12 ). 
     In the common basic circuit (COMA) shown in  FIG. 7 , the nodes to which the gates of the transistors (Tr 103 , Tr 104 ) which output the common voltage (CM 11 ) of positive polarity or the common voltage (CM 12 ) of negative polarity to the respective common electrodes are connected constitute floating memory nodes (node 11 , node 12 ) and writing of a voltage to such floating memory nodes is performed such that the writing (refreshing) is preformed one time for every 1 frame. 
     Accordingly, a leak current from the transistors connected to the floating memory nodes (node 11 , node 12 ) influences the operational stability. Particularly, when the threshold voltage Vth of the transistor which is connected to the floating memory node (node 11 , node 12 ) is low, the leak current from the transistor is increased and hence, a stable operation is deteriorated resulting in a possibility of lowering of likelihood of a threshold value. 
     Further, the common basic circuit (COMA) requires, as constitutional elements thereof, (a) a capacity element (C 11 ) for holding and boosting a voltage of the node (node  11 ), a capacity element (C 13 ) for holding and boosting a voltage of the node (node  12 ), a capacity element (C 12 ) for holding and boosting a voltage of the node (node  15 ), and a capacity element (C 14 ) for holding and boosting a voltage of the node (node  16 ), and (b) resetting transistors (Tr 107 , Tr 108 , Tr 114 , Tr 115 ) for the node (node  11 ), resetting transistors (Tr 122 , Tr 123 , Tr 120 , Tr 121 ) for the node (node  12 ), resetting transistors (Tr 112 , Tr 113 ) for the node (node  15 ), and resetting transistors (Tr 118 , Tr 119 ) for the node (node  16 ). In this manner, the common basic circuit (COMA) requires a large number of elements and hence, it is difficult to decrease a circuit scale of the common basic circuit (COMA). 
       FIG. 2  is a block diagram showing the schematic constitution of the vertical driver circuit of this embodiment. 
     As shown in  FIG. 2 , in this embodiment, each common basic circuit (COMB) of the common electrode driver circuit  11  receives inputting of no signals from the preceding-stage or succeeding-stage common basic circuit, and first and second transfer clocks (SV 1 , SV 2 ) are inputted to each common basic circuit (COMB). 
     Also in this embodiment, input signals inputted to the shift register circuit  10  and output signals outputted from the shift register circuit  10  are equal to the input signals and output signals shown in  FIG. 6 . The shift register circuit  10  starts driving thereof when a start pulse (VIN) is inputted to the first-stage basic circuit (S/R 1 ), and performs a function of outputting signals whose phases are shifted by 1 clock for every stage from an uppermost stage to a lowermost stage in synchronism with the first transfer clock (SV 1 ) and the second transfer clock (SV 2 ). 
     Each basic circuit (S/R) outputs a selection scanning voltage supplied to the respective scanning signal lines (G) and a common electrode driving pulse (COMBIN) inputted to each common basic circuit (COMA). 
       FIG. 3  shows the circuit constitution of the common basic circuit (COMB) shown in  FIG. 2 . 
     A common-electrode-driving pulse (COMBIN) is inputted to a gate of the transistor (Tr 201 ), and an AC signal (M 1 ) is inputted to a drain of the transistor (Tr 201 ). Further, a transistor (Tr 205 ) in diode connection is connected to a source of the transistor (Tr 201 ), a drain of a transistor (Tr 206 ) is connected to a source of a transistor (Tr 205 ), and a gate of the transistor (Tr 206 ) is connected to a source of the transistor (Tr 201 ). 
     Further, a common-electrode-driving pulse (COMBIN) is inputted to a gate of the transistor (Tr 202 ), and an AC signal (M 2 ) is inputted to a drain of the transistor (Tr 202 ). Further, a transistor (Tr 213 ) in diode connection is connected to a source of the transistor (Tr 202 ), a drain of a transistor (Tr 214 ) is connected to a source of a transistor (Tr 213 ), and a gate of the transistor (Tr 214 ) is connected to a source of the transistor (Tr 202 ). 
     A source of the transistor (Tr 206 ) is connected to a gate of the transistor (Tr 203 ), and the common voltage (CM 21 ) of positive polarity is inputted to a drain of the transistor (Tr 203 ). In the same manner, a source of the transistor (Tr 214 ) is connected to a gate of the transistor (Tr 204 ), and the common voltage (CM 22 ) of negative polarity is inputted to a drain of the transistor (Tr 204 ). 
     In the transistors (Tr 201 , Tr 202 ), when the common electrode driving pulse (COMBIN) assumes a High level (hereinafter referred to as H level), one of two nodes consisting of the node (node  21 ) and the node (node  22 ) assumes an H level and another node assumes a Low level (hereinafter referred to as L level) in response to voltage levels of AC signals (M 1 , M 2 ). 
     When the node (node 21 ) assumes an H level, the transistor (Tr 203 ) is turned on so that the common voltage (CM 21 ) of positive polarity is outputted to the common electrode (CT), while when the node (node 22 ) assumes an H level, the transistor (Tr 204 ) is turned on so that the common voltage (CM 22 ) of negative polarity is outputted to the common electrode (CT). 
     In transistors (Tr 205 , Tr 206 ), when the common-electrode-driving pulse (COMBIN) is changed from an H level to an L level, the H level of the node (node 21 ) is held. In the same manner, in transistors (Tr 213 , Tr 214 ), when the common-electrode-driving pulse (COMBIN) is changed from an H level to an L level, the H level of the node (node 22 ) is held. 
     The transistors (Tr 207 , Tr 208 ) which are connected between a source of the transistor (Tr 220 ) and the reference voltage (VSS) have respective gates thereof connected to the gate of the transistor (Tr 203 ). Further, the transistors (Tr 215 , Tr 216 ) which are connected between a source of the transistor (Tr 212 ) and the reference voltage (VSS) have respective gates thereof connected to the gate of the transistor (Tr 204 ). 
     Transistors (Tr 207 , Tr 208 ) completely hold the node (node 22 ) at an L level during a period in which the node (node 21 ) assumes an H level thus preventing the node (node 21 ) and the node (node 22 ) from assuming the H level simultaneously. In the same manner, transistors (Tr 215 , Tr 216 ) completely hold the node (node 21 ) at an L level during a period in which the node (node 22 ) assumes an H level thus preventing the node (node 21 ) and the node (node 22 ) from assuming the H level simultaneously. 
     Compared to the constitution of a conventional circuit shown in  FIG. 7 , in this embodiment, a circuit which is constituted of the transistors (Tr 209  to Tr 212 ) and the capacitive element (C 21 ) is added to a node (node 21 ) side, and a circuit which is constituted of the transistors (Tr 217  to Tr 219 ) and the capacitive element (C 22 ) is added to a node (node 22 ) side. 
     That is, on the node (node 21 ) side, the transistor (Tr 210 ) is connected between a source of the transistor (Tr 209 ) in diode connection and a drain of the transistor (Tr 212 ) in diode connection, and a source of the transistor (Tr 212 ) is connected to a gate of the transistor (Tr 203 ). Further, a capacitive element (C 21 ) is connected between a drain of the transistor (Tr 212 ) and a source of the transistor (Tr 211 ). 
     Here, a gate of the transistor (Tr 210 ) and a gate of the transistor (Tr 211 ) are connected to a gate of the transistor (Tr 203 ). Further, a first transfer clock (SV 1 ) is inputted to a drain of the transistor (Tr 209 ), and a second transfer clock (SV 2 ) is inputted to a drain of the transistor (Tr 211 ). 
     The transistor (Tr 210 ) assumes an ON state during a period in which the node (node 21 ) is at an H level and hence, when the first transfer clock (SV 1 ) assumes an H level, the node (node 24 ) assumes an H level. This H level of the node (node 24 ) is held by the capacitive element (C 21 ). 
     The transistor (Tr 211 ) assumes an ON state during the period in which the node (node 21 ) is at an H level and hence, when the second transfer clock (SV 2 ) assumes an H level, a voltage of the node (node 24 ) is boosted (charged up) for every second transfer clock (SV 2 ) by the capacitive element (C 21 ). Accordingly, a voltage of the node (node 21 ) is also boosted via the transistor (Tr 212 ) in diode connection. The circuit on the node (node 22 ) side has the similar constitution as the above-mentioned circuit on the node (node 21 ) side. 
       FIG. 4A  shows the input signals inputted to the circuit shown in  FIG. 3  and voltage changes at the respective nodes. 
     When the own-stage common-electrode-driving pulse (COMBINn) assumes an H level during a period t 21 , the transistors (Tr 201 , Tr 202 ) are turned on. Further, when an AC signal (M 1 ) assumes an H level simultaneously with such an operation, the transistors (Tr 205 , Tr 206 ) are turned on so that the node (node 21 ) assumes an H level. 
     During a period in which the node (node 21 ) is at an H level, the voltage of the node (node 22 ) is fixed to an L level by the transistors (Tr 207 , Tr 208 ). Here, the first transfer clock (SV 1 ) is also at an H level and hence, the node (node 24 ) also assumes an H level, and this H level is held by the capacitive element (C 21 ). 
     The transistor (Tr 211 ) is in an ON state during a period in which the node (node 21 ) is at the H level and hence, when the second transfer clock (SV 2 ) assumes an H level during a period t 22 , the voltage of the node (node 24 ) is boosted. Accordingly, the voltage of the node (node 21 ) becomes higher than the H level via the transistor (Tr 212 ) and hence, the ON resistance of the transistor (Tr 203 ) is lowered. 
     In the next frame, the AC signals M 1 , M 2  are inverted so that the node (node 22 ) assumes an H level, and the voltage of the node (node 22 ) is boosted for every second transfer clock (SV 2 ). 
     In the above-mentioned explanation, the case in which the scanning-signal-line sequential driving adopts the 1 line inversion AC driving method has been explained. However, the present invention is applicable to a case in which the scanning-signal-line sequential driving adopts a frame inversion AC driving method. 
     When the scanning-signal-line sequential driving adopts the frame inversion AC driving method, as AC signals M 1 , M 2 , as shown in  FIG. 4B , AC signals whose voltage levels are inverted for every 1 frame are inputted. 
     With the use of such AC signals, for example, when the AC signal (M 1 ) is at an H level during 1 frame period, a voltage of the H level is constantly applied to the node (node 21 ) of each common basic circuit (COMB) and hence, only the common voltage (CM 21 ) of positive polarity is outputted to all scanning signal lines. 
     In the next frame, the phase of the AC signal (M 1 ) and the phase of the AC signal (M 2 ) are inverted so that only the common voltage (CM 22 ) of negative polarity is outputted to all scanning signal lines. 
     As has been explained heretofore, in this embodiment, using one of pair of clocks consisting of first and second transfer clocks (using the second transfer clock (SV 2 ) in  FIG. 3 ), the voltages of the floating memory nodes (node 21 , node 22 ) are boosted for every clock. 
     Accordingly, in this embodiment, compared to a conventional circuit in which a voltage is written in a memory node one time during 1 cycle, it is possible to remarkably reinforce a stable operation against a leak current thus allowing the driver circuit to maintain high operational stability. To take a common electrode driver circuit having the 240-stage constitution as an example, compared to the conventional circuit, according to this embodiment, the restriction on a holding time of the floating memory node can be alleviated approximately 120 times. That is, this implies that the likelihood for the leak current from the transistor connected to the floating memory nodes (node 21 , node 22 ) is increased approximately 120 times thus realizing the deregulation of standards on threshold voltages Vth of using transistors. 
     Further, in this embodiment, to lower ON resistances of the transistors (Tr 203 , Tr 204 ), the transfer clocks SV 1 , SV 2  are used without using next-stage outputs. Accordingly, each common basic circuit (COMB) requires, as constitutional elements thereof, (a) the capacitive element (C 21 ) for holding and boosting the voltage of the node (node 21 ) and the capacitive element (C 22 ) for holding and boosting the voltage of the node (node 22 ), and (b) the resetting transistors (Tr 207 , Tr 208 ) for the node (node 21 ) and the resetting transistors (Tr 215 , Tr 216 ) for the node (node 22 ). However, different from the conventional circuit, elements for holding and resetting the next-stage output are unnecessary and hence, this embodiment can decrease a circuit scale of the common basic circuit (COMB). 
     Accordingly, this embodiment can realize not only the easy narrowing of a picture frame but also, and the reduction of a manufacturing cost acquired by the enhancement of a yield rate due to the enlargement of time-wise likelihood for a leak current from the floating memory node and the increase of the number of liquid crystal panels which are manufactured from one substrate due to the realization of a compact circuit. 
     In the above-mentioned explanation, the case in which the common electrode driver circuit is constituted of the n-type thin film transistors has been explained. However, in this embodiment, the common electrode driver circuit can adopt not only the n-MOS single-channel constitution formed of the n-type thin film transistors but also the p-MOS single-channel constitution formed of p-type thin film transistors. In this case, a reference voltage VSS assumes an H level so that logic of the common electrode driver circuit is inverted. 
     Further, in the above-mentioned explanation, the case in which the MOS (Metal Oxide Semiconductor)-type TFTs are used as transistors has been explained. However, general-type MOS-FETs or MIS (Metal Insulator Semiconductor) type-FETs or the like can be also used as transistors applicable to the present invention. 
     Further, in the above-mentioned explanation, the explanation is made with respect to the embodiment in which the present invention is applied to the liquid crystal display module. However, it is needless to say that the present invention is not limited to such a liquid crystal display module and, for example, the present invention is applicable to an EL display device which uses organic EL elements or the like. 
     Although the invention made by inventors of the present invention has been specifically explained based on the embodiment, it is needless to say that the present invention is not limited to such an embodiment, and various modifications can be made without departing from the gist of the present invention.