JP4873431B2 - Liquid crystal display device, driving circuit and driving method thereof - Google Patents

Description

  The present invention relates to a driving circuit and a driving method for a liquid crystal display device, and more particularly to a driving circuit and a driving method for driving an auxiliary capacitance electrode.

  2. Description of the Related Art In recent years, an active matrix type liquid crystal display device including a TFT (Thin Film Transistor) as a switching element is known. This liquid crystal display device includes a liquid crystal panel composed of two insulating substrates facing each other. On one substrate of the liquid crystal panel, scanning signal lines (gate bus lines) and video signal lines (source bus lines) are provided in a lattice pattern, and TFTs are provided in the vicinity of the intersections of the scanning signal lines and the video signal lines. ing. The TFT includes a gate electrode branched from the scanning signal line, a source electrode branched from the video signal line, and a drain electrode. The drain electrode is connected to pixel electrodes arranged in a matrix on the substrate in order to form an image. The other substrate of the liquid crystal panel is provided with an electrode (hereinafter referred to as “common electrode”) for applying a voltage to the pixel electrode, and a liquid crystal capacitor is formed by the pixel electrode and the common electrode. ing.

  In such a liquid crystal display device, in order to sequentially select each scanning signal line by one horizontal scanning period, application of an active scanning signal to each scanning signal line is repeated with one vertical scanning period as a cycle. For this reason, the electric charge accumulated in each liquid crystal capacitor must be held for approximately one vertical scanning period. However, since the accumulated electric charge is not held only by the liquid crystal capacitor, an auxiliary capacitor is provided in parallel with the liquid crystal capacitor.

  FIG. 5 is a circuit diagram showing the vicinity of a TFT of a conventional liquid crystal display device. The gate electrode 57 of the TFT 51 is connected to the scanning signal line GL, the source electrode 58 is connected to the video signal line SL, and the drain electrode 59 is connected to the pixel electrode 52. A liquid crystal capacitor 55 and an auxiliary capacitor 56 are provided in parallel. The liquid crystal capacitor 55 is formed by the pixel electrode 52 and the common electrode 53, and the auxiliary capacitor 56 is formed by the pixel electrode 52 and the auxiliary capacitor electrode 54.

  By the way, in the liquid crystal display device as described above, the auxiliary capacitance electrode 54 is provided on the same substrate as the pixel electrode 52, and a leak current is generated between the pixel electrode 52 and the auxiliary capacitance electrode 54 due to manufacturing defects or the like. It can happen. Here, with reference to FIG. 5 and FIG. 6, an influence when a leak current is generated between the pixel electrode 52 and the auxiliary capacitance electrode 54 will be described. In the configuration shown in FIG. 5, when a leakage current is generated between the pixel electrode 52 and the auxiliary capacitance electrode 54, it can be regarded as a short circuit as shown in FIG. The potential of 52 and the potential of the auxiliary capacitance electrode 54 are equal. As a result, a voltage corresponding to the potential difference between the auxiliary capacitor electrode 54 and the common electrode 53 is applied to the liquid crystal capacitor 55. Here, conventionally, the potential of the auxiliary capacitance electrode 54 (hereinafter referred to as “CS potential”) Vcs and the potential of the common electrode 53 (hereinafter referred to as “COM potential”) Vcom are driven to be equal. For this reason, for example, in a liquid crystal display device adopting a normally white system, a place where the above leakage current occurs is visually recognized as a bright spot. This is called a bright spot defect. Conventionally, such a bright spot defect has been subjected to a treatment (black spotting) for displaying it black with a laser or the like.

  Therefore, a liquid crystal display device has been proposed in which the auxiliary capacitance electrode 54 and the common electrode 53 are driven so that a predetermined potential difference always occurs between the CS potential Vcs and the COM potential Vcom. FIG. 7 is a block diagram showing the overall configuration of the liquid crystal display device. This liquid crystal display device includes a gate power supply 100, a display control circuit 200, a video signal line driving circuit 300, a scanning signal line driving circuit 400, a liquid crystal panel 500, a common electrode driving circuit 600, an auxiliary capacitance electrode driving circuit 700, and a CS potential setting circuit 800. And. Inside the liquid crystal panel 500, a plurality of scanning signal lines GL and a plurality of video signal lines SL are provided in a lattice pattern, and correspond to the intersections of the plurality of scanning signal lines GL and the video signal lines SL, respectively. Thus, a TFT 51 as a switch element is provided. The gate electrode 57 of the TFT 51 is connected to the scanning signal line GL, the source electrode 58 is connected to the video signal line SL, and the drain electrode 59 is connected to the pixel electrode 52. A common electrode 53 is provided to face the pixel electrode 52, and a liquid crystal capacitor 55 is formed by the pixel electrode 52 and the common electrode 53. An auxiliary capacitance electrode 54 is also provided on the substrate on which the pixel electrode 52 is provided, and an auxiliary capacitance 56 is formed by the pixel electrode 52 and the auxiliary capacitance electrode 54. The scanning signal line GL is connected to the scanning signal line driving circuit 400, and the video signal line SL is connected to the video signal line driving circuit 300. The auxiliary capacitance electrode 54 is connected to the auxiliary capacitance electrode drive signal line CsL, and the auxiliary capacitance electrode drive signal line CsL is connected to the auxiliary capacitance electrode drive circuit 700. Note that only a part of the internal configuration of the liquid crystal panel 500 is shown for convenience of explanation.

  A storage capacitor electrode drive signal for driving the storage capacitor electrode 54 is output from the storage capacitor electrode drive circuit 700. Incidentally, the upper limit value of the CS potential Vcs given to the auxiliary capacitance electrode 54 by the auxiliary capacitance electrode drive signal is set by the CS potential setting circuit 800 as described later. As shown in FIG. 7, the CS potential setting circuit 800 includes a diode 81, resistors 83 and 84, and a capacitor 85. The anode of the diode 81 is connected to the auxiliary capacitance electrode drive signal line CsL. On the other hand, the cathode of the diode 81 is connected to the gate OFF power supply line GoffL. One end of the gate OFF power supply line GoffL is connected to the ground wiring 82. A connection point b between the anode of the diode 81 and the auxiliary capacitance electrode drive signal line CsL is connected to the auxiliary capacitance electrode drive circuit 700 via the capacitor 85. With such a configuration, the CS potential setting circuit 800 functions as a so-called clamp circuit. Note that the gate OFF power supply line GoffL is a power supply line for supplying a low potential voltage (hereinafter referred to as “gate OFF voltage”) among the voltages to be supplied from the gate power supply 100 to the scanning signal line driving circuit 400. is there. A high potential voltage among the voltages to be supplied from the gate power supply 100 to the scanning signal line driving circuit 400 is hereinafter referred to as a “gate ON voltage”.

  Next, the driving of the auxiliary capacitance electrode 54 will be described with reference to FIGS. 7, 8 and 9. A connection point b between the anode of the diode 81 and the auxiliary capacitance electrode drive signal line CsL is connected to one end of the capacitor 85. FIG. 8 is a waveform diagram showing a change in the potential at the connection point d between the other end of the capacitor 85 and the auxiliary capacitance electrode driving circuit 700. FIG. 9 is a waveform diagram showing changes in potential at the connection point b. 8 and 9, the potential at the connection point a between the cathode of the diode 81 and the gate-off power supply line GoffL is denoted by reference numeral Va, the potential at the connection point b is denoted by reference sign Vb, and the potential at the connection point d is denoted by reference sign. This is indicated by Vd. Further, a potential difference (Vd−Va) between the potential Vd and the potential Va when the potential Vd at the connection point d is at a high potential is indicated by a symbol Vc, and the potential Vd when the potential Vd at the connection point d is at a low potential. A potential difference (Va−Vd) from the potential Va is indicated by a symbol Ve. The storage capacitor electrode drive circuit 700 outputs a storage capacitor electrode drive signal in which a high potential and a low potential alternately appear every horizontal scanning period (1H), and the potential Vd changes as shown in FIG. When the potential Vd is lower than the potential Va, the potential Vb increases as the potential Vd increases until the potential Vb and the potential Va become the same potential. At this time, the diode 81 is in a non-conductive state. When the potential Vd further increases, the diode 81 becomes conductive from the time when the potential Vb and the potential Va become the same potential. The capacitor 85 is charged according to the potential difference between the potential Vd and the potential Va. Further, the potential Vb does not become higher than the potential Va. When the potential Vd decreases, the potential Vb also decreases accordingly. At this time, the potential Vb is lower than the potential Va by a potential difference corresponding to the sum of the potential difference (Va−Vd) between the potential Vd and the potential Va and the potential difference due to charging of the capacitor 85. As a result, the change in the potential Vb is as shown in FIG. Here, since the connection point b and the auxiliary capacitance electrode 54 are at the same potential, the change in the CS potential Vcs is also as shown in FIG. On the other hand, the COM potential Vcom also changes so that a high potential and a low potential appear alternately every horizontal scanning period (1H), but its lower limit value is substantially equal to the ground potential GND. As described above, changes in the CS potential Vcs and the COM potential Vcom are as shown in FIG. A voltage drop occurs when the diode 81 is turned on, but the voltage drop is sufficiently small and is ignored in this description.

  As shown in FIG. 10, a predetermined potential difference is always maintained between the CS potential Vcs and the COM potential Vcom. When a leak current occurs, a voltage corresponding to the potential difference between the CS potential Vcs and the COM potential Vcom is applied to the liquid crystal capacitor 55 as described above. In the case of a liquid crystal display device adopting a normally white system, if the CS potential Vcs and the COM potential Vcom are the same potential, the leak current is a bright spot, but the CS potential Vcs and the COM potential Vcom. By always maintaining a predetermined potential difference between the two, a black display can be obtained where a leak current is generated.

JP 2001-188217 A

  However, according to the liquid crystal display device as described above, the upper limit value of the CS potential Vcs is set based on the voltage supplied by the power supply line such as the gate OFF power supply line GoffL. Therefore, when the gate OFF power supply line GoffL is used to set the upper limit value of the CS potential Vcs as described above, the gate power supply 100 includes a gate ON voltage and a gate OFF voltage supplied to the scanning signal line drive circuit 400. In addition to this, a power supply capability capable of supplying a voltage for setting the upper limit value of the CS potential Vcs is required. Further, the cost of components and the like for configuring the CS potential setting circuit 800 as shown in FIG. 7 is also required.

  Accordingly, an object of the present invention is to provide a liquid crystal display device capable of preventing the occurrence of bright spot defects due to leakage current while realizing reduction of power consumption and cost reduction, and a driving circuit and a driving method thereof. To do.

According to a first aspect of the present invention, a pixel electrode arranged in a matrix for displaying an image and a liquid crystal capacitor which is a first predetermined capacitor are provided so as to be opposed to the pixel electrode at every predetermined period. The pixel electrode is provided on the same substrate so that a common electrode alternately set to a high potential and a low potential and an auxiliary capacitor which is a second predetermined capacitor are formed. A predetermined electrode is provided between the common electrode and the common electrode. So that the common electrode is alternately set to a high potential and a low potential so that the potential difference of the auxiliary capacitance electrode is maintained. A drive circuit for driving a display unit including a storage capacitor electrode drive signal line for transmitting a storage capacitor electrode drive signal for driving,
An auxiliary capacitance electrode drive circuit for outputting the auxiliary capacitance electrode drive signal to the auxiliary capacitance electrode drive signal line;
A capacitor element; and a rectifier element having an anode connected to the auxiliary capacitor electrode drive signal line and a cathode connected to a ground wiring, and the potential of the anode of the rectifier element is set to the potential of the auxiliary capacitor electrode drive signal An auxiliary capacitance potential setting circuit,
A connection point between the anode of the rectifying element and the auxiliary capacitance electrode drive signal line is connected to the auxiliary capacitance electrode drive circuit via the capacitance element.

The second invention is a liquid crystal display device,
A drive circuit according to the first invention is provided.

According to a third aspect of the present invention, a pixel electrode arranged in a matrix for displaying an image and a liquid crystal capacitor which is a first predetermined capacitor are provided facing the pixel electrode so as to be formed at predetermined intervals. The pixel electrode is provided on the same substrate so that a common electrode alternately set to a high potential and a low potential and an auxiliary capacitor which is a second predetermined capacitor are formed. A predetermined electrode is provided between the common electrode and the common electrode. So that the common electrode is alternately set to a high potential and a low potential so that the potential difference of the auxiliary capacitance electrode is maintained. A drive method of a display unit comprising an auxiliary capacitance electrode drive signal line for transmitting an auxiliary capacitance electrode drive signal for driving,
A storage capacitor electrode drive circuit provided outside the display unit outputs the storage capacitor electrode drive signal to the storage capacitor electrode drive signal line;
An auxiliary capacitance potential setting circuit provided outside the display unit sets the potential of the auxiliary capacitance electrode drive signal,
The auxiliary capacitance potential setting circuit includes a capacitance element, and a rectifying element having an anode connected to the auxiliary capacitance electrode drive signal line and a cathode connected to a ground wiring,
A connection point between the anode of the rectifying element and the auxiliary capacitance electrode drive signal line is connected to the auxiliary capacitance electrode drive circuit via the capacitive element,
In the step of setting the potential of the auxiliary capacitance electrode drive signal, the potential of the anode of the rectifying element is set to the potential of the auxiliary capacitance electrode drive signal.

  According to the first aspect of the invention, the auxiliary capacitance potential setting circuit for setting the potential of the auxiliary capacitance electrode drive signal relates to a configuration for maintaining a predetermined potential difference between the auxiliary capacitance electrode and the common electrode. As for the rectifying element, the anode is connected to the auxiliary capacitance electrode drive signal line, and the cathode is connected to the ground wiring. As for the capacitive element, one end is connected to a connection point between the anode of the rectifying element and the auxiliary capacitive electrode drive signal line, and the other end is connected to an auxiliary capacitive electrode drive circuit that outputs an auxiliary capacitive electrode drive signal. With such a configuration, the upper limit value of the potential of the auxiliary capacitance electrode drive signal is set with reference to the ground potential. On the other hand, conventionally, the upper limit value of the potential of the auxiliary capacitance electrode drive signal applied to the auxiliary capacitance electrode is set based on the voltage supplied from the power supply line in the liquid crystal display device. As described above, the necessary power supply capability is reduced as compared with the conventional case, and the auxiliary capacitance potential setting circuit can be realized with a simple circuit configuration. As a result, it is possible to prevent the occurrence of a bright spot defect when a leakage current occurs in the auxiliary capacitor while reducing the size and cost of the power supply IC.

  According to the second aspect of the invention, in the liquid crystal display device, even when the auxiliary capacitance potential setting circuit has a simpler circuit configuration than the conventional one, the occurrence of a bright spot defect is prevented when a leakage current occurs in the auxiliary capacitance. be able to. As a result, a liquid crystal display device can be provided that can reduce power consumption, downsize, and reduce costs as compared with the prior art.

1 is a block diagram illustrating an overall configuration of a liquid crystal display device according to an embodiment of the present invention. In the said embodiment, it is a signal waveform diagram of the auxiliary capacity drive signal output from an auxiliary capacity electrode drive circuit. FIG. 4 is a waveform diagram showing a change in potential at a connection point between an anode of a diode and a storage capacitor electrode drive signal line in the CS potential setting circuit in the embodiment. It is a wave form diagram showing change of potential of an auxiliary capacity electrode and a common electrode in the above-mentioned embodiment. It is a figure for demonstrating the influence when a leak current arises between a pixel electrode and an auxiliary capacity electrode. It is a figure for demonstrating the influence when a leak current arises between a pixel electrode and an auxiliary capacity electrode. It is a block diagram which shows the whole structure of the liquid crystal display device in a prior art example. In the conventional example, it is a signal waveform diagram of the auxiliary capacity drive signal output from the auxiliary capacity electrode drive circuit. In the conventional example, it is a wave form diagram which shows the change of the electric potential of the connection point of the anode of the diode in a CS electric potential setting circuit, and an auxiliary capacity electrode drive signal line. It is a wave form diagram which shows the change of the electric potential of the auxiliary capacity electrode and common electrode in a prior art example.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

<1. Overall configuration and operation>
FIG. 1 is a block diagram showing the overall configuration of a liquid crystal display device according to an embodiment of the present invention. This liquid crystal display device includes a gate power supply 100, a display control circuit 200, a video signal line driving circuit 300, a scanning signal line driving circuit 400, a liquid crystal panel 500, a common electrode driving circuit 600, an auxiliary capacitance electrode driving circuit 700, and a CS potential setting circuit 800. And. Inside the liquid crystal panel 500, a plurality of scanning signal lines GL and a plurality of video signal lines SL are provided in a lattice pattern, and correspond to the intersections of the plurality of scanning signal lines GL and the video signal lines SL, respectively. Thus, a TFT 51 as a switch element is provided. The gate electrode 57 of the TFT 51 is connected to the scanning signal line GL, the source electrode 58 is connected to the video signal line SL, and the drain electrode 59 is connected to the pixel electrode 52. A common electrode 53 is provided to face the pixel electrode 52, and a liquid crystal capacitor 55 is formed by the pixel electrode 52 and the common electrode 53. An auxiliary capacitance electrode 54 is also provided on the substrate on which the pixel electrode 52 is provided, and an auxiliary capacitance 56 is formed by the pixel electrode 52 and the auxiliary capacitance electrode 54. The scanning signal line GL is connected to the scanning signal line driving circuit 400, and the video signal line SL is connected to the video signal line driving circuit 300. The auxiliary capacitance electrode 54 is connected to the auxiliary capacitance electrode drive signal line CsL, and the auxiliary capacitance electrode drive signal line CsL is connected to the auxiliary capacitance electrode drive circuit 700. Note that only a part of the internal configuration of the liquid crystal panel 500 is shown for convenience of explanation.

  The gate power supply 100 outputs a gate ON voltage and a gate OFF voltage. The display control circuit 200 receives the image data Dv from the outside, the display image data Da, and the horizontal synchronization signal HSY, the vertical synchronization signal VSY, the clock signal CK, and the like for controlling the timing for displaying the image on the liquid crystal panel 500. A start pulse signal SP is output. The video signal line drive circuit 300 generates a video signal for driving the liquid crystal panel 500 based on the image data Da, the clock signal CK, and the start pulse signal SP output from the display control circuit 200, and generates the video signal. Applied to each video signal line SL. The scanning signal line drive circuit 400 selects an active scanning signal based on the horizontal synchronizing signal HSY and the vertical synchronizing signal VSY output from the display control circuit 200 in order to sequentially select each scanning signal line GL one horizontal scanning period. Are repeatedly applied to each scanning signal line GL with one vertical scanning period as a cycle.

  The common electrode drive circuit 600 drives the common electrode 53. The auxiliary capacitance electrode drive circuit 700 outputs an auxiliary capacitance electrode drive signal for driving the auxiliary capacitance electrode 54. The CS potential setting circuit 800 sets an upper limit value of the CS potential Vcs to be given to the auxiliary capacitance electrode 54, as will be described later.

  The CS potential setting circuit 800 includes a diode (rectifying element) 81 and a capacitor (capacitance element) 85. The anode of the diode 81 is connected to the auxiliary capacitance electrode drive signal line CsL. On the other hand, the cathode of the diode 81 is connected to the ground wiring 82. A connection point b between the anode of the diode 81 and the auxiliary capacitance electrode drive signal line CsL is connected to the auxiliary capacitance electrode drive circuit 700 via the capacitor 85. With such a configuration, the CS potential setting circuit 800 functions as a so-called clamp circuit.

<2. Driving method>
Next, a method of driving the auxiliary capacitance electrode 54 and the common electrode 53 in the present embodiment will be described with reference to FIGS. A connection point b between the anode of the diode 81 and the auxiliary capacitance electrode drive signal line CsL is connected to one end of the capacitor 85. FIG. 2 is a waveform diagram showing a change in the potential Vd at the connection point d between the other end of the capacitor 85 and the auxiliary capacitance electrode driving circuit 700. FIG. 3 is a waveform diagram showing changes in the potential Vb at the connection point b. In FIGS. 2 and 3, the ground potential is indicated by GND. Further, a potential difference (Vd−GND) between the potential Vd when the potential Vd at the connection point d is at a high potential and the ground potential GND is indicated by a symbol Vf, and the potential Vd when the potential Vd at the connection point d is at a low potential. And the ground potential GND (GND-Vd) is indicated by the symbol Vg. The auxiliary capacitance electrode drive circuit 700 outputs an auxiliary capacitance electrode drive signal in which a high potential and a low potential alternately appear every horizontal scanning period (1H), and the potential Vd changes as shown in FIG. When the potential Vd is lower than the ground potential GND, the potential Vb increases as the potential Vd increases until the potential Vb becomes the ground potential GND. At this time, the diode 81 is in a non-conductive state. When the potential Vd further rises, the diode 81 becomes conductive from the time when the potential Vb becomes the ground potential GND. The capacitor 85 is charged according to the potential difference between the potential Vd and the ground potential GND. Further, the potential Vb does not become higher than the ground potential GND. When the potential Vd decreases, the potential Vb also decreases accordingly. At this time, the potential Vb is lower than the ground potential GND by a potential difference corresponding to the sum of the potential difference (GND−Vd) between the potential Vd and the ground potential GND and the potential difference due to charging of the capacitor 85. As a result, the change in the potential Vb is as shown in FIG. Here, since the connection point b and the auxiliary capacitance electrode 54 are at the same potential, the change in the CS potential Vcs is also as shown in FIG. On the other hand, the COM potential Vcom also changes so that a high potential and a low potential appear alternately every horizontal scanning period (1H), but the lower limit value of the COM potential Vcom is almost equal to the ground potential. . From the above, changes in the CS potential Vcs and the COM potential Vcom are as shown in FIG.

<3. Action>
As shown in FIG. 4, the CS potential Vcs and the COM potential Vcom repeat the high potential and the low potential at the same timing. For CS potential Vcs, the upper limit value is set substantially at ground potential GND. On the other hand, for the COM potential Vcom, the lower limit value is almost set to the ground potential GND. As a result, a predetermined potential difference is always maintained between the CS potential Vcs and the COM potential Vcom.

  Here, when a leak current is generated between the pixel electrode 52 and the auxiliary capacitor electrode 54, a voltage corresponding to the potential difference between the CS potential Vcs and the COM potential Vcom is applied to the liquid crystal capacitor 55. In the present embodiment, a voltage indicated by reference symbol V in FIG. 4 is applied. As described above, since a predetermined potential difference is always maintained between the CS potential Vcs and the COM potential Vcom, in the case of a liquid crystal display device adopting a normally white method, even if a leak current occurs, a bright spot defect occurs. Can be prevented.

<4. Effect>
As described above, in the present embodiment, in the CS potential setting circuit 800, the anode of the diode 81 is connected to the auxiliary capacitance electrode drive signal line CsL, and the cathode of the diode 81 is connected to the ground wiring 82. Further, the connection point b between the anode of the diode 81 and the auxiliary capacitance electrode drive signal line CsL is connected to the auxiliary capacitance electrode drive circuit 700 via the capacitor 85. Thereby, CS potential setting circuit 800 functions as a clamp circuit, and the upper limit value of CS potential Vcs is set to the ground potential. Since the lower limit of the COM potential Vcom is set to the ground potential, a predetermined potential difference can be maintained between the CS potential Vcs and the COM potential Vcom.

  On the other hand, conventionally, in order to maintain a predetermined potential difference between the CS potential Vcs and the COM potential Vcom, for example, an upper limit value of the CS potential Vcs based on a voltage supplied from a power supply line in the apparatus such as a gate OFF power supply line. Was set. When this embodiment is compared with the conventional example, the present embodiment does not require a power supply line in the apparatus in order to maintain a predetermined potential difference between the CS potential Vcs and the COM potential Vcom. Power consumption can be reduced. As a result, the power supply capability required for the gate power supply or the like is reduced, so that the size and cost of the power supply IC can be reduced. Furthermore, according to the present embodiment, it is possible to reduce the components for configuring the CS potential setting circuit 800 as compared with the conventional example. Thereby, further downsizing and cost reduction of the liquid crystal display device can be achieved. Thus, it is possible to provide a liquid crystal display device that can prevent the occurrence of bright spot defects when a leakage current occurs, and that can reduce power consumption, downsize, and reduce costs as compared with the prior art. Can do.

51 ... TFT
52 ... Pixel electrode 53 ... Common electrode 54 ... Auxiliary capacitance electrode 55 ... Liquid crystal capacitance 56 ... Auxiliary capacitance 81 ... Diode (rectifier element)
82 ... Ground wiring 85 ... Capacitor (capacitance element)
DESCRIPTION OF SYMBOLS 100 ... Gate power supply 500 ... Liquid crystal panel 600 ... Common electrode drive circuit 700 ... Auxiliary capacitance electrode drive circuit 800 ... CS potential setting circuit Vcom ... Common electrode potential Vcs ... Auxiliary capacitance electrode potential

Claims (3)

A pixel electrode arranged in a matrix for displaying an image and a liquid crystal capacitor which is a first predetermined capacitor are provided so as to face the pixel electrode, and a high potential and a low potential are provided for each predetermined period. Are provided on the same substrate as the pixel electrode so that a common electrode alternately set and an auxiliary capacitance which is a second predetermined capacitance are formed, and a predetermined potential difference is maintained between the common electrode and the common electrode. As described above, an auxiliary capacitance electrode that is alternately set to a high potential and a low potential at the same timing as the common electrode is alternately set to a high potential and a low potential, and an auxiliary capacitance for driving the auxiliary capacitance electrode A drive circuit for driving a display unit including an auxiliary capacitance electrode drive signal line for transmitting an electrode drive signal,
An auxiliary capacitance electrode drive circuit for outputting the auxiliary capacitance electrode drive signal to the auxiliary capacitance electrode drive signal line;
A capacitor element; and a rectifier element having an anode connected to the auxiliary capacitor electrode drive signal line and a cathode connected to a ground wiring, and the potential of the anode of the rectifier element is set to the potential of the auxiliary capacitor electrode drive signal An auxiliary capacitance potential setting circuit,
The drive circuit, wherein a connection point between the anode of the rectifier element and the auxiliary capacitance electrode drive signal line is connected to the auxiliary capacitance electrode drive circuit via the capacitive element.   A liquid crystal display device comprising the drive circuit according to claim 1. A pixel electrode arranged in a matrix for displaying an image and a liquid crystal capacitor which is a first predetermined capacitor are provided so as to face the pixel electrode, and a high potential and a low potential are provided for each predetermined period. Are provided on the same substrate as the pixel electrode so that a common electrode alternately set and an auxiliary capacitance which is a second predetermined capacitance are formed, and a predetermined potential difference is maintained between the common electrode and the common electrode. As described above, an auxiliary capacitance electrode that is alternately set to a high potential and a low potential at the same timing as the common electrode is alternately set to a high potential and a low potential, and an auxiliary capacitance for driving the auxiliary capacitance electrode A driving method of a display unit including an auxiliary capacitance electrode drive signal line for transmitting an electrode drive signal,
A storage capacitor electrode drive circuit provided outside the display unit outputs the storage capacitor electrode drive signal to the storage capacitor electrode drive signal line;
An auxiliary capacitance potential setting circuit provided outside the display unit sets the potential of the auxiliary capacitance electrode drive signal,
The auxiliary capacitance potential setting circuit includes a capacitance element, and a rectifying element having an anode connected to the auxiliary capacitance electrode drive signal line and a cathode connected to a ground wiring,
A connection point between the anode of the rectifying element and the auxiliary capacitance electrode drive signal line is connected to the auxiliary capacitance electrode drive circuit via the capacitive element,
In the step of setting the potential of the auxiliary capacitance electrode drive signal, the potential of the anode of the rectifying element is set to the potential of the auxiliary capacitance electrode drive signal.

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