Abstract:
A display device, in at least one embodiment, includes: a gate driver including a plurality of shift register stages each provided so as to correspond to each row, the gate driver outputting a gate signal for turning on switching elements in the each row; and a source driver outputting a data signal in accordance with an image to be displayed. For a row (first row) located at an outermost position from which scanning by use of the gate signal starts, a dummy line is provided. The dummy line is driven by a gate start pulse inputted into a shift register in the first row.

Description:
TECHNICAL FIELD 
       [0001]    The present invention relates to a matrix display device and a method for driving the matrix display device. 
       BACKGROUND ART 
       [0002]    Commonly known matrix display devices are, for example, a liquid crystal display device including an active matrix substrate, on which TFTs (Thin Film Transistors) are formed, and driver ICs (Integrated Circuits) for driving the TFTs. 
         [0003]      FIG. 6  illustrates a TFT active matrix liquid crystal display device  101 . The liquid crystal display device  101  is provided with a gate driver  102  and a source driver  103 . The gate driver  102  is a circuit for driving rows of a matrix, and the source driver  103  is, a circuit for driving columns of the matrix. 
         [0004]    On a transparent substrate, a plurality of gate lines Gn, Gn+1, . . . (hereinafter denoted by a reference sign G, when collectively termed) and a plurality of source lines Sn, Sn+1, . . . (hereinafter denoted by a reference sign S, when collectively termed) are formed so as to orthogonally intersect with each other. The plurality of gate lines G are driven by the gate driver  102  and the plurality of source lines S are driven by the source driver  103 . In a position at each of intersections of the gate lines G and the source lines S, a pixel PIX is provided. The pixel PIX includes a TFT  104 , a liquid crystal  105 , and a storage capacitor  106 . In each of areas surrounded by the gate lines G and the source lines S, a pixel electrode  107  ( FIG. 7 ) is formed. The pixel electrode  107  serves as one electrode of the liquid crystal  105  and one electrode of the storage capacitor  106 , and is connected to a drain electrode of the TFT  104 . In a pixel PIX in an n-th row and in an n-th column, a source electrode of the TFT  104  is connected to a source line Sn in the n-th column, and a gate electrode of the TFT  104  is connected to a gate line Gn in the n-th row. 
         [0005]    When a relationship between the gate lines and the pixel electrodes  107  is spotlighted in the liquid crystal display device  101  in which the pixels PIX are thus formed, it is recognized that the liquid crystal display device  101  in  FIG. 6  is a so-called below-pixel-electrode gate type liquid crystal display device in which the gate line Gn in the n-th row is provided below the pixel electrode  107  in the n-th row. Further, as illustrated in  FIG. 7 , between the pixel electrode  107  and the gate line Gn and between the pixel electrode  107  and the gate line Gn−1, parasitic capacitances Cgd 1  and Cgd 2  are generated, respectively. In regard to the pixels in the first row, a gate line G 0 , which corresponds to the foregoing gate line Gn−1 for the pixels PIX in the n-th row, is not provided, so that a parasitic capacitance corresponding to the foregoing parasitic capacitance Cgd 2  is not generated.  FIG. 6  illustrates a difference between an equivalent circuit of a pixel in the first row (line G 1 ) in which the parasitic capacitance Cgd 2  is not generated and an equivalent circuit of a pixel in each of the second and subsequent rows (Gn (n≠1)) in which both the parasitic capacitances Cgd 1  and Cgd 2  are generated. 
         [0006]    In the meantime, as illustrated in  FIG. 8 , a gate signal having an amplitude of Vgpp is sequentially applied to each gate line G. This gate signal varies a drain level of the TFT  104 . That is, in each of the pixels PIX in the n-th row, via the parasitic capacitance Cgd 2 , the gate signal of the gate line Gn−1 varies the drain level of the TFT  104  by ΔV 2 , and via the parasitic capacitance Cgd 1 , the gate signal of the gate line Gn varies the drain level of the TFT  104  by ΔV 1 . Here, provided that the capacitance of the liquid crystal of the pixel PIX is denoted by Clc and the storage capacitance is denoted by Ccs, the above-mentioned ΔV 2  and ΔV 1  can be expressed as follows: 
         [0000]      Δ V 1 =Vgpp×{Cgd 1/( Clc+Ccs+Cgd 1 +Cgd 2)}
 
         [0000]      Δ V 2 =Vgpp×{Cgd 2/( Clc+Ccs+Cgd 1 +Cgd 2)}
 
         [0007]    The ΔV 1  produced by the gate signal of the gate line Gn of the n-th stage causes a center value Vcom of an amplitude of the drain level of the TFT  104  to be lower than a center value Vsc of an amplitude of a source signal by ΔV 1 . The ΔV 2  produced by the gate signal of the gate line Gn−1 of the preceding stage raises an effective value of a voltage applied to the liquid crystal  105 . 
         [0008]    As described above, each of the pixels PIX in the first row is not provided with the gate line G 0  that is a preceding stage which forms the parasitic capacitance. Cgd 2 . For this reason, the ΔV 2  does not occur. Consequently, the effective value of the voltage applied to the liquid crystal  105  only in the pixels PIX in the first row becomes lower than the effective values supplied to the respective pixels PIX of the remaining rows. Due to this difference of the effective values, brightness of the pixels PIX only in the first row appears different in display from brightness of the remaining pixels PIX in a case where a driving condition of the display device deteriorates, for example, in a case where the value ΔV 2  is large or in a case where a temperature becomes too high or low. For instance, when normally white liquid crystal is adopted, the first line appears a bright line. 
         [0009]    In order to solve the above problem, various techniques have been conventionally proposed. For example, Patent Literature 1 discloses a liquid crystal display device in which a below-pixel-electrode gate type panel is provided with a dummy gate line (dummy line G 0 ) in the vicinity of pixels of the first row. This dummy gate line is not involved in displaying but compensates the aforementioned asymmetry between the pixels of the first row and the remaining pixels.  FIG. 9  is a circuit diagram illustrating a configuration of the liquid crystal display device according to Patent Literature 1.  FIG. 10  is a timing chart of signals inputted into the dummy line and the gate lines of the liquid crystal display device of Patent Literature 1. 
         [0010]    As shown in  FIG. 9 , in the liquid crystal display device of Patent Literature 1, the dummy line G 0  for producing capacitances is arranged on an outer side of a gate line (i.e., in the example shown in  FIG. 9 , a top gate line) G 1  located at an outermost position from which scanning by use of a scanning signal starts. The dummy line G 0  is arranged to be parallel to the gate line G 1 , and to face the gate line G 1  so that a pixel electrode  6  connected to a TFT  5  connected to the gate line G 1  is between the dummy line G 0  and the gate line G 1 . 
         [0011]    With this configuration, the pixel electrode  6  connected to the TFT  5  connected to the top gate line G 1  is located between the dummy line G 0  above and the gate line G 1  below. Consequently, all of the pixels are geometrically symmetrical in a vertical direction. Therefore, the pixels driven by the top gate line G 1  have completely the same conditions as the pixels driven by the other gate lines G 2 , G 3 , . . . . Consequently, in a case of a normally white liquid crystal, for example, it is possible to restrain such a conventional phenomenon that a line of pixels in the top row appears a bright line or the like. 
         [0012]    However, the above conventional technique  1  has a problem in that it is necessary to provide a dummy line. This results in an increase in the number of wirings and accordingly an increase in the circuit area. This is against a recent trend of decreasing cost, weight and thickness of liquid crystal displays. 
         [0013]    In the meantime, Patent Literature 2 discloses a method according to which a dummy line G 0  driving signal is generated in a mode in which display timing is controlled by a data enable signal in a liquid crystal display device.  FIG. 11  is a plane view schematically illustrating a configuration of a gate driver of the liquid crystal display device according to Patent Literature 2.  FIG. 12  is a timing chart of signals that are involved in timing control. 
         [0014]    As illustrated in  FIG. 11 , a liquid crystal display panel  3  of the liquid crystal display device includes 768 gate lines G 1 , G 2 , . . . , and G 768  connected to respective effective pixels. Furthermore, a dummy line G 0 , which serves as a dummy gate line, is provided in a stage preceding the gate line G 1 . In order to drive these 769 gate lines, a gate driver  2  includes cascade-connected three driver ICs each of which has 258 output terminals. 
         [0015]    In the above configuration, a control IC generates a gate start pulse signal GSP and a gate clock signal GCK based on a data enable signal ENAB and a clock signal CK, respectively, with reference to timing of inputting the data enable signal ENAB. Then, the control IC supplies these generated signals to the gate driver  2  so that, before a source driver starts to output a write signal corresponding to display data of the first horizontal period in one vertical period, the gate driver  2  outputs a gate signal to a top output terminal OG 0 . Thus, on the occasion of performing display in the data enable mode, it is possible to drive the dummy line G 0  before the write signal of the first horizontal period is outputted to a source line S. 
         [0016]    In this way, the liquid crystal display device of Patent Literature 2 uses only the data enable signal but does not use horizontal and vertical synchronization signals, for generating liquid crystal driving signals. In consequence, it is possible to reduce the number of wirings for input signals. 
       Citation List 
       [0017]    Patent Literature 1 
         [0018]    Japanese Patent Application Publication, Tokukaihei, No. 9-288260 A (Publication Date: Nov. 4, 1997) 
         [0019]    Patent Literature 2 
         [0020]    Japanese Patent Application Publication, Tokukai, No. 2004-85891 A (Publication Date: Mar. 18, 2004) 
         [0021]    Patent Literature 3 
         [0022]    Japanese Patent Application Publication, Tokukai, No. 2002-189203 A (Publication Date: Jul. 5, 2002) 
       SUMMARY OF INVENTION 
       [0023]    In the technique of Patent Literature 2, a driving pulse of the dummy line G 0  is generated in a period from the input of the data enable signal ENAB to output of a driving pulse of the gate line G 1 . Therefore, as shown in  FIG. 12 , a pulse width of the driving pulse of the dummy line G 0  becomes narrower than a pulse width of each of driving pulses of the gate line G 1  and the subsequent gate lines. For this reason, it is not possible to adequately charge the pixels on the dummy line G 0 . As a result, the dummy line cannot provide an adequate effect as a dummy line. 
         [0024]    In view of this problem, Patent Literature 3 discloses a configuration of a dummy signal generation circuit that generates a pulse for driving a dummy line G 0 .  FIG. 13  is a circuit diagram illustrating a configuration of the dummy signal generation circuit.  FIG. 14  is a timing chart of various signals that are relevant to the dummy signal generation circuit. 
         [0025]    According to the configuration of this dummy signal generation circuit, generation of an A signal for driving the dummy line G 0  precedes, by one horizontal period, generation of a GSP signal. This makes it possible for the signal applied to the dummy line G 0  to have the same pulse width as the signals applied to the other gate lines. In consequence, all of the pixels can have the same charging characteristics. The technique disclosed in Patent Literature 3 can thus solve the problem arising from the influence of the pulse width as set forth in Patent Literature 2. 
         [0026]    However, in the technique of Patent Literature 3, output of gate pulses subsequent to the GSP signal is delayed. On this account, the technique of Patent Literature 3 requires a line memory for delaying output of data signals. That is, the problem of cost increase remains unsolved. Moreover, additional problems, such as an increase of power consumption, arise. 
         [0027]    In recent years, liquid crystal display devices are strongly required not only to have a better display quality but also to achieve reduced cost and power consumption. From this point of view, the technique disclosed in Patent Literature 3 is not necessarily sufficient. 
         [0028]    One technique for reducing cost of liquid crystal displays is monolithic integration of a gate driver. With this technique which has been adopted in recent years, the gate driver is formed on a display panel with use of amorphous silicon.  FIG. 15  illustrates an example of a configuration of a shift register constituting a gate driver formed by monolithic integration.  FIG. 16  is a circuit diagram of shift register stages constituting a shift register, and  FIG. 17  is a timing chart illustrating waveforms of various signals in the shift register stages. 
         [0029]    The gate driver formed by monolithic integration includes a shift register including a plurality of shift register stages  31  cascade-connected. An output terminal out of each shift register stage  31  is connected to a set input terminal set of a subsequent shift register stage  31  and a reset input terminal reset of a preceding shift resister stage  31 . That is, an output signal SRout outputted from the output terminal out of each shift register stage  31  serves as a set signal for the subsequent shift register stage  31  and a reset signal for the preceding shift register stage  3   a . Note that, as shown in  FIG. 16 , for example, each shift register stage  31  includes a plurality of transistors T 1  to T 4  and a capacitor C 1 . 
         [0030]    In a case where a gate driver is thus configured by the monolithic integration, it is common that a potential of a node n 1  is boosted for restraining a decrease in a potential level of the output signal SRout due to a fall in a threshold of a transistor. On this account, as shown in the timing chart of  FIG. 17 , prior to output of the output signal SRout, an output signal SRoutn−1 of the preceding shift register stage  31  is inputted as a set signal. 
         [0031]    In such a gate driver, for the purpose of preventing the aforementioned problem of a bright line, a dummy line G 0  may be provided, as illustrated in  FIG. 18 . In such a case, it is necessary to generate a signal at a timing prior to output to the dummy line G 0  ( FIG. 19 ). Accordingly, when, e.g., the technique of Patent Literature 2 is adopted, it is necessary to further shorten the pulse width of the signal for driving the dummy line G 0 . Consequently, it becomes more difficult to charge pixels of the dummy line G 0 . As a result, the dummy line G 0  cannot provide an effect as a dummy line G 0 . This makes it impossible to reliably restrain the problem of a bright line. Furthermore, the potential of the node n 1  in the shift register  31  for the dummy line G 0  cannot be adequately boosted, because the time period for boosting the potential is shortened. As such, it becomes impossible to obtain an output signal of a desired potential level, which may lead to a malfunction. 
         [0032]    As described above, though the conventional techniques can reduce an influence of the occurrence of a bright line by providing a dummy line, the provision of the dummy line produces various problems. In other words, according to the conventional techniques, it is difficult to restrain deterioration of display quality due to the bright line without causing problems such as an increase in cost and circuit area. 
         [0033]    The present invention is accomplished in view of the above conventional problems, and an object of the present invention is to provide, by equalizing the parasitic capacitances generated in each pixel but causing no increase in cost and circuit area, a display device that can prevent display quality from deteriorating due to, for example, a bright line caused by pixels of a particular section or the like, and a method for controlling the display device. 
         [0034]    In order to attain the above object, a display device according to the present invention is a display device which includes: a display panel including: scanning signal lines; data signal lines; pixel electrodes; and switching elements, and in the display panel, each of the switching elements has (i) one terminal connected with one of the pixel electrodes and (ii) another terminal connected with one of the data signal lines, each of the scanning signal lines turns on/off switching elements corresponding thereto, the each scanning signal line forms one of rows together with the switching elements connected thereto, and pixel electrodes respectively connected to these switching elements, a scanning signal line driving circuit including a plurality of shift registers each provided so as to correspond to each of the rows, the scanning signal line driving circuit outputting a scanning signal for turning on the switching elements in the each row; a data signal line driving circuit outputting a data signal in accordance with an image to be displayed; and a dummy scanning signal line provided for an outermost row located at an outermost position from which scanning by use of the scanning signal starts, and in the display device according to the present invention, the dummy scanning signal line is driven by a gate start pulse inputted into a shift register corresponding to the outermost row located at the outermost position. 
         [0035]    Note that, in a typical configuration of a liquid crystal display device, in many cases, the terms “row” and “horizontal” express a sequence in a lateral direction of a display panel and the terms “column” and “vertical” express a sequence in a longitudinal direction of a display panel. However, the definitions are not necessarily limited thereto, and the lateral and longitudinal directions in the definitions may be reversed. As such, in the present invention, the terms “row”, “column”, “horizontal”, and “vertical” do not particularly limit directions. 
         [0036]    According to the above configuration, a dummy scanning signal line is provided for a row located at the outermost position from which scanning by use of the scanning signal starts. As a result, in each of the pixels in the row corresponding to the scanning signal line G 1  located at the outermost position from which the scanning starts, parasitic capacitances are produced by the scanning signal line G 1  and the dummy scanning signal G 0 . Consequently, the pixels driven by the scanning signal line G 1  have completely the same conditions as the pixels driven by the other scanning signal lines G 2 , G 3 , . . . , which makes it possible to equalize the parasitic capacitances produced in each of the pixels. As such, in a case of a normally white mode, for example, it is possible to reduce such a phenomenon that a line of pixels at the outermost position appears a bright line. 
         [0037]    Moreover, according to the above configuration, the dummy scanning signal line is driven by the gate start pulse inputted into the shift register corresponding to the row located at the outermost position. That is, the gate start pulse is not only inputted into the first shift register but also used to drive the dummy scanning signal line G 0 . The use of one same signal in this way can make it possible to use the dummy scanning signal line G 0  also as the gate start pulse line. As such, the number of wirings can be reduced in comparison with the conventional techniques. In addition, it becomes unnecessary to provide a shift register corresponding to the dummy scanning signal line G 0 . This also makes it possible to achieve reduction in cost and circuit area. 
         [0038]    Furthermore, according to the above configuration, the gate start pulse can be used as a driving signal for both the first shift register and the dummy scanning signal line G 0 . As such, unlike a case where the conventional data enable mode is adopted, it is not necessary to shorten a pulse width of the signal for driving the dummy scanning signal line G 0 . This makes it possible to sufficiently charge the pixels corresponding to the dummy scanning signal line G 0 , and therefore to attain a more even display. 
         [0039]    As described above, with the configuration of the present invention, it is possible to equalize the parasitic capacitances generated in each of the pixels without causing an increase in cost and circuit area. As a result, the present invention provides an effect of restraining deterioration of display quality due to, for example, a bright line that is caused by the pixels in a particular section. 
         [0040]    The display device according to the present invention may preferably be the display device in which the dummy scanning signal line is arranged so as to sandwich pixel electrodes in the outermost row between the dummy scanning signal line and a scanning signal line in the outermost row so that a distance between the dummy scanning signal line and the scanning signal line in the outermost row is equal to a distance between other two adjacent scanning signal lines, and the outermost row is located at the outermost position. 
         [0041]    According to this configuration, the pixels in the row corresponding to the scanning signal line G 1  located at the outermost position from which the scanning starts is sandwiched between the dummy scanning signal line G 0  above and the scanning signal line G 1  below. That is, all of the pixels are geometrically symmetrical in a vertical direction. Therefore, the pixels driven by the scanning signal line G 1  can have completely the same conditions as the pixels driven by the other scanning signal lines G 2 , G 3 , . . . . Consequently, it is possible to reliably equalize the parasitic capacitances produced in each of the pixels. This makes it possible to reliably restrain deterioration of display quality. 
         [0042]    The display device according to the present invention may preferably be arranged such that the gate start pulse driving the dummy scanning signal line has a voltage level allowing the switching element to be turned on/off. 
         [0043]    It is preferable that the gate start pulse driving the dummy scanning signal line is set at the voltage level by a buffer. 
         [0044]    With the above configuration, it is possible to make the voltage level of the signal for driving the dummy line G 0  the same as the voltage level of the signal (scanning signal) for driving the other scanning signal lines G 2 , G 3 , . . . . Therefore, the pixels driven by the scanning signal line G 1  can have completely the same conditions as the pixels driven by the other scanning signal lines G 2 , G 3 , . . . . This can restrain such a phenomenon that a line of pixels appears a bright line or the like, thereby restraining deterioration of display quality. Furthermore, because it is possible to generate the gate start pulse by a buffer, the display device of the present invention can be realized in a simple configuration. 
         [0045]    The display device according to the present invention is preferably the display device which further includes: a control device generating the gate start pulse and a clock for driving the scanning signal line driving circuit, and the control device includes the buffer for generating the gate start pulse. 
         [0046]    With this configuration, it is possible to generate, by the buffer included in the control device, the gate start pulse which drives the dummy scanning signal line G 0  and the first shift register. Therefore, the effect as described above can be achieved without complicating the configuration. 
         [0047]    In addition, it is possible to apply the above configuration to a monolithically-integrated gate driver, because the gate start pulse can be inputted from an external control device. This can further reduce cost for the display device. 
         [0048]    It is preferable that, in the display device according to the present invention, the dummy scanning signal line is connected to a signal line connecting the control device with the scanning signal line driving circuit; and the gate start pulse is inputted into the scanning signal line driving circuit and the dummy scanning signal line via the signal line. 
         [0049]    With this configuration, the gate start pulse outputted from the control device directly drives the dummy scanning signal line G 0 , and the same gate start pulse is inputted into the first shift register as a gate start pulse for the first shift register. Thus, the dummy scanning signal line G 0  can be used also as the signal line (gate start pulse line) that connects the control device with the scanning signal line driving circuit. As a result, the number of wirings can be reduced. 
         [0050]    In order to attain the above object, a method for driving a display device according to the present invention is a method for driving a display device which includes a display panel including: scanning signal lines; data signal lines; pixel electrodes; and switching elements, and in the display panel, each of the switching elements has (i) one terminal connected with one of the pixel electrodes and (ii) another terminal connected with one of the data signal lines, each of the scanning signal lines turns on/off the switching elements corresponding thereto, and the each scanning signal line forms one of rows together with the switching elements connected thereto, and pixel electrodes respectively connected to these switching elements, and the method according to the present invention includes the steps of: driving the scanning signal line by outputting a scanning signal for turning on the switching elements in each of the rows; driving a data signal line by outputting a data signal in accordance with an image to be displayed; and driving, by use of a gate start pulse, a dummy scanning signal line provided for a row located at an outermost position from which scanning by use of the scanning signal starts, and the gate start pulse is inputted into a shift register corresponding to the row located at the outermost position. 
         [0051]    Similarly to the effect of the display device as described above, this method restrains deterioration of display quality due to the occurrence of a bright line or the like. 
         [0052]    The display device according to the present invention is arranged as described above such that a dummy scanning signal line is provided for the row located at the outermost position from which scanning by use of the scanning signal starts and that the dummy scanning signal line is driven by the gate start pulse inputted into the shift register corresponding to the row located at the outermost position. 
         [0053]    The method for driving a display device according to the present invention is to drive the dummy scanning signal line provided for the row located at the outermost position from which scanning by use of the scanning signal starts, by the gate start pulse inputted into the shift register corresponding to the row located at the outermost position. 
         [0054]    Therefore, the present invention makes it possible to equalize the parasitic capacitances generated in each of the pixels but to cause no increase in cost and circuit area, thereby achieving an effect of restraining deterioration of display quality due to, for example, a bright line caused by pixels in a particular section. 
     
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         [0055]    
         FIG. 1 
       
           [0056]      FIG. 1  is a block diagram illustrating an entire configuration of a liquid crystal display device according to the present invention. 
           [0057]    
         FIG. 2 
       
           [0058]      FIG. 2  is an equivalent circuit diagram illustrating an electrical configuration of a pixel of the liquid crystal display device illustrated in  FIG. 1 . 
           [0059]    
         FIG. 3 
       
           [0060]      FIG. 3  is a block diagram illustrating a configuration of a gate driver and a control device in the liquid crystal display device illustrated in  FIG. 1 . 
           [0061]    
         FIG. 4 
       
           [0062]      FIG. 4  is an equivalent circuit diagram illustrating electrical configurations of pixels of the liquid crystal display device illustrated in  FIG. 1 . (a) of  FIG. 4  illustrates an electrical configuration of a pixel in the first row, and (b) of  FIG. 4  illustrates an electrical configuration of a pixel in the second and subsequent rows. 
           [0063]    
         FIG. 5 
       
           [0064]      FIG. 5  is a timing chart illustrating waveforms of various signals in a shift register stage constituting a shift register included in the gate driver illustrated in  FIG. 3 . 
           [0065]    
         FIG. 6 
       
           [0066]      FIG. 6  is a block diagram illustrating an entire configuration of a conventional TFT active matrix liquid crystal display device. 
           [0067]    
         FIG. 7 
       
           [0068]      FIG. 7  is a plane view illustrating that parasitic capacitances occur in the liquid crystal display device illustrated in  FIG. 6 . 
           [0069]    
         FIG. 8 
       
           [0070]      FIG. 8  is a voltage waveform chart illustrating changes of a pixel electrode potential due to the parasitic capacitances generated in the liquid crystal display device illustrated in  FIG. 6 . 
           [0071]    
         FIG. 9 
       
           [0072]      FIG. 9  is a circuit diagram illustrating a configuration of a liquid crystal display device according to Patent Literature 1. 
           [0073]    
         FIG. 10 
       
           [0074]      FIG. 10  is a timing chart of signals respectively inputted into a dummy line and gate lines of the liquid crystal display device illustrated in  FIG. 9 . 
           [0075]    
         FIG. 11 
       
           [0076]      FIG. 11  is a plane view schematically illustrating a configuration of a gate driver of the liquid crystal display device according to Patent Literature 2. 
           [0077]    
         FIG. 12 
       
           [0078]      FIG. 12  is a timing chart of respective signals involved in timing control of the liquid crystal display device illustrated in  FIG. 11 . 
           [0079]    
         FIG. 13 
       
           [0080]      FIG. 13  is a circuit diagram illustrating a configuration of a dummy signal generation circuit according to Patent Literature 2. 
           [0081]    
         FIG. 14 
       
           [0082]      FIG. 14  is a timing chart of respective signals relevant to the dummy signal generation circuit illustrated in  FIG. 13 . 
           [0083]    
         FIG. 15 
       
           [0084]      FIG. 15  illustrates an example of a configuration of a shift register constituting a conventional gate driver formed by monolithic integration. 
           [0085]    
         FIG. 16 
       
           [0086]      FIG. 16  is a circuit diagram of a shift register stage constituting the shift register illustrated in  FIG. 15 . 
           [0087]    
         FIG. 17 
       
           [0088]      FIG. 17  is a timing chart showing waveforms of various signals in the shift register stage illustrated in  FIG. 16 . 
           [0089]    
         FIG. 18 
       
           [0090]      FIG. 18  is an example of a configuration in which a dummy line is provided in the gate driver illustrated in  FIG. 15 . 
           [0091]    
         FIG. 19 
       
           [0092]      FIG. 19  is a timing chart illustrating waveforms of various signals in shift register stages illustrated in  FIG. 18 . 
       
    
    
     REFERENCE SIGNS LIST 
       [0000]    
       
           1  Liquid Crystal Display Device (Display Device) 
           10  Liquid Crystal Display Panel (Display Panel) 
           11  TFT (Switching Element) 
           12  Pixel Electrode 
           20  Source Driver (Data Signal Line Driving Circuit) 
           30  Gate Driver (Scanning Signal Line Driving Circuit) 
           31  Shift Register Stage (Shift Register) 
           40  Control Device 
           41  Timing Control IC 
           42  Level Shifter 
           43  Buffer 
         Sn Source Line (Data Signal Line) 
         Gn Gate Line (Scanning Signal Line) 
         G 0  Dummy Line (Dummy Scanning Signal Line) 
         GSP Gate Start Pulse 
         SR Shift Register 
         CKA, CKB Clock Signals 
       
     
       DESCRIPTION OF EMBODIMENTS 
       [0110]    In the following, an embodiment of the present invention is described with reference to  FIGS. 1 to 5 . 
         [0111]    First, with reference to  FIGS. 1 and 2 , the following describes a configuration of a liquid crystal display device  1  which corresponds to a display device of the present invention.  FIG. 1  is a block diagram illustrating an entire configuration of the liquid crystal display  1 .  FIG. 2  is an equivalent circuit diagram illustrating an electrical configuration of a pixel of the liquid crystal display device  1 . Note that, in a configuration of a liquid crystal display device, in many cases, the terms “row” and “horizontal” express a sequence in a lateral direction of a display panel and the terms “column” and “vertical” express a sequence in a longitudinal direction of a display panel. However, the definitions are not necessarily limited thereto, and the lateral and longitudinal directions in the definitions may be reversed. As such, in the present invention, the terms “row”, “column”, “horizontal”, and “vertical” do not particularly limit directions. 
         [0112]    The liquid crystal display device  1  includes an active matrix liquid crystal display panel (display panel)  10 , a source driver (data signal line driving circuit)  20 , a gate driver (scanning signal line driving circuit)  30 , and a control device  40 . 
         [0113]    The liquid crystal display panel  10  is configured such that liquid crystals are sandwiched between an active matrix substrate and a counter substrate (both not shown). Further, the liquid crystal display panel  10  is provided with a number of pixels P arranged in rows and columns. 
         [0114]    The liquid crystal display panel  10  includes, on the active matrix substrate, source lines Sn corresponding to data signal lines of the present invention, gate lines Gn corresponding to scanning signal lines of the present invention, thin film transistors (hereinafter referred to as TFTs)  11  corresponding to switching elements of the present invention, and pixel electrodes  12  corresponding to pixel electrodes of the present invention. The liquid crystal display panel  10  also includes, on the counter substrate, a common electrode  13 . Furthermore, the liquid crystal display panel  10  is provided with CS lines  15  for forming storage capacitors  14 . 
         [0115]    One of the source lines Sn is formed in each of the columns so as to be parallel to each other in a column (longitudinal) direction. One of the gate lines Gn is formed in each of the rows so as to be parallel to each other in a row (lateral) direction. One of the TFTs  11  and one of the pixel electrodes  12  are provided so as to correspond to each of intersections of the source bus lines Sn and the gate lines Gn. A source electrode of each TFT  11  is connected to the source line Sn. A gate electrode of each TFT  11  is connected to the gate line Gn, and a drain electrode of each TFT  11  is connected to corresponding one of the pixel electrodes  12 . In addition, each pixel electrode  12  and the common electrode  13  sandwiches a liquid crystal and forms a liquid crystal capacitor  16 . 
         [0116]    With this configuration, the gate of the TFT  11  is turned on by a gate signal (scanning signal) supplied to the gate line Gn, and a source signal (data signal) from the source line Sn is written into the pixel electrode  12  so that the pixel electrode  12  is set at a potential corresponding to the source signal. Further, a voltage corresponding to the source signal is applied to the liquid crystal which intervenes between the pixel electrode  12  and the common electrode  13 . This makes it possible to achieve a gray scale display corresponding to the source signal. 
         [0117]    One of the CS lines  15  is formed in each of the rows so as to be parallel to each other in a row (lateral) direction and paired with a corresponding gate line Gn. Each CS line  15  is capacitively-coupled with each corresponding pixel electrode  12  that is provided in one of the rows. Thereby, each CS line  15  and each corresponding pixel electrode  12  form a storage capacitor  14 . 
         [0118]    Due to a structure of each TFT  11 , parasitic capacitors (Cgd 1  and Cgd 2 )  18  and  19  are formed between the gate electrode and the drain electrode. Consequently, a potential of the pixel electrode  12  experiences an influence (feed-through phenomenon) from a potential change of the gate line. 
         [0119]    The liquid crystal display panel  10  as arranged above is driven by the source driver  20 , the gate driver  30 , and a control device  40  controlling the source driver  20  and the gate driver  30 . 
         [0120]    In the present embodiment, horizontal scanning periods are sequentially allocated to the respective rows in an active period (effective scanning period) of a vertical scanning period that is periodically repeated, so that the rows are sequentially scanned. 
         [0121]    Therefore, the gate driver  30  sequentially outputs a gate signal for turning on TFTs  11  to a corresponding gate line Gn in synchronization with a horizontal scanning period of each row. A specific configuration of the gate driver  30  will be described later. 
         [0122]    In the meantime, the source driver  20  outputs a source signal to each of the respective source lines Sn. The source signal is a signal obtained from a video signal which has been supplied to the source driver  20  via the control device  40  and which the source driver  20 , for example, allocates to each of the columns and subjects to a process for raising a voltage. The configuration of the source driver  20  is not particularly limited, and a conventional common structure may be employed. 
         [0123]    The control device  40  controls the source driver  20  and the gate driver  30  so as to cause these circuits to output desired signals, respectively. A specific configuration of the control device  40  will be described later. 
         [0124]    In such a liquid crystal display device, there is no gate line G 0  of a preceding stage which produces the parasitic capacitance Cgd 2  in each of the pixels P of the first row ( FIG. 6 ), as described in the foregoing description in the section of “Background Art”. For this reason, ΔV 2  does not occur in the pixels P of the first row. This causes only the pixels P of the first row to have a lower effective value of a voltage to be applied to the liquid crystals as compared to effective values of voltages applied to the respective pixels P of the other rows. Therefore, in a case where a driving condition of the display device deteriorates, for example, in a case where the ΔV 2  is large or in a case where a temperature becomes too high or low, brightness of only the pixels P of the first row appears different from brightness of the other pixels P. In view of this problem, conventional techniques prevent deterioration of display quality by providing a dummy gate line (dummy line, dummy scanning signal line) corresponding to the gate line G 0 . However, according to the conventional techniques, the provision of the dummy line causes various problems (e.g., an increase in cost, an increase in circuit area, and/or deterioration in functionality that should be provided by a dummy line). 
         [0125]    In order to solve these problems, as illustrated in  FIG. 1 , the liquid crystal display device of the present embodiment is provided with a dummy line (dummy scanning signal line) corresponding to the pixels P in the first row. Further, this dummy line is driven by a gate start pulse GSP outputted from the control device  40 . A more detailed configuration of the liquid crystal display device  1  is described as below with reference to  FIG. 3 . 
         [0126]      FIG. 3  is a block diagram illustrating a configuration of the gate driver  30  and the control device  40 . 
         [0127]    First, the configuration of the gate driver  30  is described. The gate driver  30  includes a plurality of shift registers  31 . For the sake of convenience in explanation, hereinafter, each shift register  31  is also referred to as a shift register stage  31 . In such a case, a plurality of cascade-connected shift register stages  31  are collectively termed “shift register”. 
         [0128]    Each shift register stage  31  includes a set input terminal set, a reset input terminal reset, an output terminal out, and a clock input terminal ck. An n-th (n=1, 2, 3, . . . ) shift register stage  31  is referred to as SRn, and an output signal outputted from the output terminal out of the SRn is referred to as SRoutn. Each shift register stage  31  denoted by SRn drives a corresponding gate line Gn according to the output signal SRoutn. Into the set input terminal set of the first shift register stage  31 , a gate start pulse GSP is inputted. 
         [0129]    The output terminal out of each shift register stage  31  is connected to the set input terminal set of a subsequent, i.e., (n+1)th shift register stage  31  and the reset input terminal reset of a preceding, i.e., (n−1)th shift register stage  31 . That is, the output signal SRout outputted from the output terminal out of each shift register stage  31  serves as a set signal of the subsequent shift register stage  31  and a reset signal of the preceding shift register stage  31 . 
         [0130]    Into the clock input terminals ck of either one of odd-numbered shift register stages  31  and even-numbered shift register stages  31 , a clock signal CKB is inputted. Into the clock input terminals ck of the other one of the odd-numbered shift register stages  31  and the even-numbered shift register stages  31 , a clock signal CKA is inputted. The clock signals CKA and CKB are in such a relation that they have the same periods but an active period, that is, the high-level period, of the clock signal CKA does not overlap with an active period of the clock signal CKB. 
         [0131]    Each of the gate lines Gn is connected to a corresponding shift register stage  31 . In a preceding stage to the first gate line G 1 , a dummy line G 0  is provided so as to be parallel to the gate line G 1 . The dummy line G 0  is connected to the control device  40  via a signal line for the gate start pulse GSP. In this configuration, the first gate line G 1  is driven by an output signal SRout  1  outputted from the output terminal out of the first shift register stage  31 , while the dummy line G 0  is driven by the gate start pulse GSP outputted from the control device  40 . 
         [0132]    The following describes a configuration of the control device  40 . It is preferable that the gate start pulse GSP, which is outputted from the control device  40 , has a voltage level at which the dummy line G 0  can be driven. Specifically, it is preferable that the gate start pulse GSP has a voltage level at which TFTs can be turned on/off. Further, it is more preferable that the voltage level of the gate start pulse GSP is the same as the voltage level at which a voltage is applied to the gate line Gn. 
         [0133]    In view of this, in the liquid crystal display device  1  according to the present embodiment, the control device  40  includes a timing control IC  41  that generates the clocks and the gate start pulse, and a level shifter  42  that converts a supply voltage level. The level shifter  42  includes buffers  43  each of which outputs an amplified signal in response to an inputted signal. The gate start pulse outputted from the timing control IC  41  is converted by the level shifter  42  so as to have a desired voltage level, and then inputted into the dummy line G 0  and the first shift register stage  31 . 
         [0134]    With this configuration, the level shifter  42  shifts respective levels of the logic signals CKA, CKB, and GSP, which are generated by the timing control IC  41  and have a TTL level, so that each of the levels of the logic signals CKA, CKB, and GSP becomes a DC level (e.g., High level: 20V and Low level: −10V) at which the shift register and the gate lines Gn can be driven. The gate start pulse GSP whose level is shifted is applied to the dummy line G 0 . The level shifter  42  includes the output buffers  43  that are capable of sufficiently driving the gate lines Gn. Among the output buffers  43 , an output buffer  43  for the gate start pulse line is capable of driving both the first shift register  31  and the dummy line G 0 . In the conventional techniques, a current that had a peak value of approximately 1 mA was inputted into the first shift register. In contrast, with the structure according to the present invention in which the first shift register stage  31  and the dummy line G 0  are driven at the same time, in a case of a display panel that has a size of approximately 12 inches, for example, a current that has a peak value of approximately 30 mA is inputted into the first shift register stage  31  and the dummy line G 0 . 
         [0135]    As described above, in the liquid crystal display device  1  according to the present embodiment, the dummy line G 0  is provided in the preceding stage to the first gate line G 1 . The dummy line G 0  is driven by the gate start pulse GSP that is outputted from the control device  40  and that is inputted into the first shift register stage  31 . The voltage level of the gate start pulse GSP is set by a buffer or the like to a voltage level at which each of the gate lines can be driven. 
         [0136]    The dummy line G 0  is preferably arranged so as to sandwich the pixel electrodes  12  in the first row between the dummy line G 0  and the gate line G 1  so that a distance between the dummy line G 0  and the gate line G 1  is equal to a distance between other two adjacent gate lines (e.g., between the gate lines G 1  and G 2 ). 
         [0137]    With this configuration, as shown in  FIG. 4 , the pixel electrode  12  connected to the TFT  11  connected to the top gate line G 1  is sandwiched between the dummy line G 0  above and the gate line G 1  below. As a result, all of the pixels P are geometrically symmetrical in a vertical direction. Therefore, conditions of the pixels P ((a) of  FIG. 4 ) driven by the top gate line G 1  can become completely the same as conditions of the pixels driven by the other gate lines G 2 , G 3 , . . . . Consequently, for example, in a case of a normally white mode, it is possible to restrain such a phenomenon that a line of pixels P in the top row appears a bright line. 
         [0138]    In addition, with the above configuration, the signal outputted from the control device  40  directly drives the dummy line G 0 . Further, this signal outputted from the control device  40  is inputted to the first shift register as a gate start pulse GSP. Thus, the dummy line G 0  can be used also as the gate start pulse line. This makes it possible to reduce the number of wirings. Moreover, in the above configuration, it is not necessary to provide the shift register stage  31  corresponding to the dummy line G 0 . This makes it possible to reduce a circuit area. 
         [0139]    Furthermore, with the above configuration, the gate start pulse GSP can be used as a driving signal for the dummy line G 0 . As such, unlike the conventional techniques employing a data enable mode, it is not necessary to shorten a pulse width of the signal for driving the dummy scanning signal line G 0  in the above configuration. This makes it possible to sufficiently charge the pixels corresponding to the dummy scanning signal line G 0 , and therefore to attain an even display. 
         [0140]    As a specific configuration of the shift register stage  31 , a conventionally well-known configuration illustrated in FIG.  16  may be employed. 
         [0141]    As illustrated in  FIG. 16 , each shift register stage  31  includes, for example, a capacitor C 1  and transistors T 1  to T 4  each of which is made up of an n-channel (or p-channel) TFT. 
         [0142]    A gate and a drain of the transistor T 1  is connected to the set input terminal set. A gate of the transistor T 2  is connected to a source of the transistor T 1 . A drain of the transistor T 2  is connected to the clock input terminal ck, and a source of the transistor T 2  is connected to the output terminal out. A gate of the transistor T 3  is connected to the reset input terminal reset. A drain of the transistor T 3  is connected to the output terminal out, and a source of the transistor T 3  is connected to a low-potential supply VSS. A gate of the transistor T 4  is connected to the reset input terminal reset and the gate of the transistor T 3 . A drain of the transistor T 4  is connected to the source of the transistor T 1  and the gate of the transistor T 2 , and a source of the transistor T 4  is connected to the low-potential supply VSS. Between the output terminal out and a connection point of the transistors T 1 , T 2 , and T 4  (a node n 1 ), the capacitor C 1  is connected. 
         [0143]    When a clock CK, an output signal SRoutn−1 of the (n−1)th shift register stage  31 , and an output signal Sroutn+1 of the (n+1)th shift register stage  31  are inputted into the n-th shift register stage  31 , the n-th shift register stage  31  outputs an output signal SRout to the (n−1)th and (n+1)th shift register stages  31  and the gate line Gn. 
         [0144]      FIG. 5  is a timing chart illustrating waveforms of various signals in the shift register stage  3   a  illustrated in  FIG. 3 . 
         [0145]    It is clear from the timing chart of  FIG. 5  that, according to the configuration of the present embodiment, a gate start pulse GSP is directly inputted into the dummy line G 0 . Therefore, unlike the conventional techniques, it is not necessary in the configuration of the present embodiment to generate a signal at a timing prior to the driving of the dummy line G 0  ( FIG. 19 ). This makes it possible to ensure a sufficient pulse width of the signal (GSP) for driving the dummy line G 0 . Consequently, the pixels corresponding to the dummy line G 0  can be sufficiently charged. This makes it possible to perform an even display even in an outermost line in the display area of the liquid crystal display panel. 
         [0146]    In the liquid crystal display device of the present embodiment, the gate start pulse GSP for driving the dummy line G 0  is provided from an outside of the gate driver  30 . On this account, the liquid crystal display of the present embodiment is particularly suitable for monolithic integration according to which the gate driver is formed on the panel with use of amorphous silicon. The liquid crystal display panel that has been monolithically formed may be connected with the control device via an FPC (flexible printed circuit board), as illustrated in  FIG. 1 . This makes it also possible to reduce cost for the liquid crystal display device. It should be noted that the gate driver and the control device of the above liquid crystal display device can also be applied to conventionally common liquid crystal display devices that are not monolithically structured. 
         [0147]    The present invention is not limited to the description of the embodiments above, but may be altered within the scope of the claims. An embodiment based on a proper combination of technical means disclosed in different embodiments is encompassed in the technical scope of the present invention. 
       INDUSTRIAL APPLICABILITY 
       [0148]    The present invention has such a configuration that the dummy line is driven by a gate start pulse at a predetermined voltage level. Therefore, the present invention is suitably applied in particular to a display device in which a gate driver is monolithically integrated.