1. Field of the Invention
The present invention relates to an active-matrix liquid crystal display device.
2. Description of Related Art
Recently, a liquid crystal display device is widely used, which drives display elements (liquid crystal elements) using liquid crystal for video display. In such a liquid crystal display device, arrangement of liquid crystal molecules is changed in a liquid crystal layer enclosed between substrates such as glass substrates, so that light from a light source is transmitted or modulated for display.
In the liquid crystal display device, active matrix drive is typically used. In such a drive method, frame reversal drive, in which polarity of voltage applied to liquid crystal is reversed every frame period, is performed to suppress degradation of liquid crystal. In addition, line reversal drive, in which polarity of voltage applied to liquid crystal is reversed every horizontal period (1H), is performed to suppress occurrence of flicker in each frame due to reversal of polarity of voltage applied to liquid crystal in the frame reversal drive. Furthermore, common reversal drive, in which polarity of voltage applied to a common electrode is reversed, is performed to reduce amplitude of a signal voltage applied to each pixel electrode.
The above previous drive methods are described in, for example, Japanese Patent Application, Publication Nos. 11-271787 and 2001-159877.
Recent advance in resolution and luminance of a display image reveals difficulties that have not been considered seriously. In particular, flicker and high power consumption are serious difficulties. As a cause of bad flicker, a fact is listed: display has been more affected by a current leaking from a pixel circuit through reduced pixel capacitance associated with high resolution. As another cause, a fact is listed: luminance of a light source has been increased to compensate reduction in luminance through reduction in aperture ratio associated with high resolution. Increase in power consumption is caused by the fact that luminance of a light source has been increased to compensate reduction in luminance through reduction in aperture ratio associated with high resolution as described above.
As a measure to suppress flicker, for example, improvement in manufacturing process or improvement in liquid crystal material is considered. However, in such a case, manufacturing cost or a trial production period has been increased, leading to a difficulty. Therefore, a center value ((upper limit value+lower limit value)/2) of voltages applied to the common electrode in the common reversal drive has been adjusted to a value at which flicker is minimized in the past.
However, the value at which flicker is minimized is different depending on display gray levels. This is because main causes of flicker are different between an intermediate gray level and a high gray level. Specifically, leakage current in a holding period is a main cause of flicker in the intermediate gray level, while a flexoelectric effect is a main cause of flicker in the high gray level. The flexoelectric effect refers to a phenomenon that polarization, which occurs at a molecular level in liquid crystal molecules due to asymmetry in shape of each liquid crystal molecule, comes up to the surface when the molecules are aligned.
Therefore, when the center value of voltages applied to the common electrode in the common reversal drive is adjusted to a value suitable for the intermediate gray level, flicker increases in the high gray level, and when the center value is adjusted to a value suitable for the high gray level, flicker increases in the intermediate gray level. In this way, flicker has not been easily suppressed in all display gray levels in the previous adjustment methods.
It is desirable to provide a liquid crystal display device that may reduce flicker in all display gray levels.
A liquid crystal display device according to an embodiment of the invention includes a pixel array section, a scan line drive circuit, a signal line drive circuit, and a common connection line drive circuit. The pixel array section has a plurality of scan lines arranged in columns, a plurality of signal lines arranged in rows, and a plurality of pixel circuits arranged in a matrix in correspondence to intersections between the scan lines and the signal lines, the pixel circuits being connected to scan lines and signal lines corresponding to the intersections, respectively. The pixel array section further has a plurality of liquid crystal elements arranged in a matrix in correspondence to the intersections, the liquid crystal elements being connected to the pixel circuits corresponding to the intersections, respectively, and a plurality of common connection lines connected to the plurality of liquid crystal elements for each row. The scan line drive circuit sequentially applies selection pulses to the plurality of scan lines to sequentially select the plurality of liquid crystal elements in scan lines as a unit. The signal line drive circuit applies a signal voltage corresponding to a video signal to each signal line such that polarity of the voltage is reversed every frame period for writing into a liquid crystal element as a selection object. The common connection line drive circuit applies a voltage, of which the polarity is opposite to polarity of the signal line, to a common connection line corresponding to a liquid crystal element as a selection object in a write period for writing into the liquid crystal element as a selection object. Furthermore, the common connection line drive circuit applies one or multiple voltages, each voltage having a value different from a center value between an upper limit value and a lower limit value of voltages applied to the common connection lines in the write period, to the common connection lines in a holding period after writing into the liquid crystal element as a selection object is performed.
In the liquid crystal display device according to the embodiment of the invention, one or multiple voltages, each voltage having a value different from a center value between an upper limit value and a lower limit value of voltages applied to common connection lines in a write period, is applied to the common connection lines in a holding period. Thus, a voltage value at which flicker is minimized in an intermediate gray level may be made similar to a voltage value at which flicker is minimized in a high gray level in a holding period compared with a case where a voltage equal to the center value is applied to the common connection lines.
According to the liquid crystal display device of the embodiment of the invention, a voltage value at which flicker is minimized in an intermediate gray level may be made similar to a voltage value at which flicker is minimized in a high gray level. Thus, flicker may be reduced in all display gray levels.
Other and further objects, features and advantages of the invention will appear more fully from the following description.
Hereinafter, preferred embodiments of the invention will be described in detail with reference to drawings. Description is made in the following sequence.
Schematic Configuration
Pixel Array Section 13
Each sub pixel 11 has, for example, two transistors 14 and 15 and a liquid crystal element 16 as shown in
One end of the liquid crystal element 16 is connected to the source or drain of the transistor 15, and the other end thereof is connected to the common connection line COM. The gates of the transistors 14 and 15 are connected to the scan line WSL, and one of the source and drain of the transistor 15, which is unconnected to the liquid crystal element 16, is connected to the source or drain of the transistor 14. One of the source and drain of the transistor 14, which is unconnected to the transistor 15, is connected to the signal line DTL. In a plurality of sub pixels 11 in one horizontal line, for example, the gates of the transistors 14 and 15 are connected to the common scan line WSL. That is, a plurality of sub pixels 11 connected to one scan line WSL are arranged in a line along the scan line WSL.
In one horizontal line, while not shown, for example, gates of transistors 14 and 15 of one sub pixel 11 may be connected to one scan line WSL of two scan lines WSL provided on both sides of each sub pixel 11, and gates of transistors 14 and 15 of the other sub pixel 11 may be connected to the other scan line WSL of the two scan lines WSL. In this case, a plurality of sub pixels 11 connected to one scan line WSL may be alternately (zigzag) arranged with respect to the scan line WSL. In such a case, liquid crystal elements 16 selected by one scan line WSL among a plurality of liquid crystal elements 16 are alternately arranged with respect to the one scan line WSL.
Backlight 20
The backlight 20 irradiates the liquid crystal display panel 10 from the back, and includes, for example, a light guide plate, a light source disposed on a side face of the light guide plate, and an optical element disposed on a top (light emitting surface) of the light guide plate. The light guide plate guides light from the light source to the top of the light guide plate, and has, for example, a predetermined patterned-shape on at least one of the top and a bottom, and thus has a function of scattering light entering from a side face to uniform the light. The light source is a linear light source, and includes, for example, a hot cathode fluorescent lamp (HCFL), a cold cathode fluorescent lamp (CCFL), or a plurality of light emitting diodes (LED) arranged in a line. The optical element is formed by stacking a diffuser plate, a diffuser sheet, a lens film, a polarization separation sheet and the like. The backlight 20 may be a direct backlight having a diffuser plate and other optical elements directly above a light source.
Drive Circuit 30
Next, each of the circuits in the drive circuit 30 provided in the periphery of the pixel array section 13 will be described with reference to
The video signal processing circuit 31 corrects a digital video signal 30A inputted from the outside, and converts a corrected video signal into an analog signal and outputs the analog signal to the signal line drive circuit 33. The timing generator circuit 32 controls the signal line drive circuit 33, the scan line drive circuit 34, and the common connection line drive circuit 35 so that the circuits operate in conjunction with one another. For example, the timing generator circuit 32 outputs a control signal 32A to each of the circuits in response to (in synchronization with) a synchronizing signal 30B inputted from the outside.
The signal line drive circuit 33 applies the analog video signal (signal voltage corresponding to the video signal 30A) inputted from the video signal processing circuit 31 to each signal line DTL to write the signal to a sub pixel 11 as a selection object. For example, the signal line drive circuit 33 may output a signal voltage Vsig corresponding to the video signal 30A. For example, the signal line drive circuit 33 may perform frame reversal drive, in which a signal voltage Vsig, of which the polarity is reversed every frame period with respect to a reference voltage Vref, is applied to each signal line DTL so that the signal is written to a sub pixel 11 as a selection object, as shown in
The scan line drive circuit 34 applies selection pulses to a plurality of scan lines in response to (in synchronization with) input of a control signal 32A to select a plurality of sub pixels 11 in a desired unit. As a unit of selecting the sub pixels 11, a various number of lines may be selected as necessary, for example, one line or adjacent two lines. In addition, the lines may be selected sequentially or randomly. For example, the scan line drive circuit 34 may output a voltage Von applied when the transistor 15 is turned on, and a voltage Voff applied when the transistor 15 is turned off. The voltage Von has a value (fixed value) equal to or larger than a value of on voltage of the transistor 15. The voltage Voff has a value (fixed value) smaller than a value of the on voltage of the transistor 15.
Next, the common connection line drive circuit 35 will be described.
The above “polarity of a sub pixel 11” means that whether voltage of a sub pixel 11 (each broken line in
While the signal line drive circuit 33 performs 1H reversal drive, the common connection line drive circuit 35 performs common reversal drive, in which polarity of voltage supplied to the common electrodes (common connection lines COM) is reversed by a predetermined number of lines. Specifically, the common connection line drive circuit 35 applies a voltage, of which the polarity with respect to the reference voltage Vref is opposite to polarity of the signal line DTL with respect to the reference voltage Vref, to a common connection line COM corresponding to a sub pixel 11 as a selection object. For example, as shown in
Moreover, the common connection line drive circuit 35 applies multiple voltages different from one another to the common electrode (common connection lines COM) in the holding period Th. For example, as shown in
The common connection line drive circuit 35 electrically isolates a common connection line COM disposed in correspondence to a sub pixel 11 as a selection object from a plurality of common connection lines COM disposed in correspondence to sub pixels 11 as a non-selection object in the holding period Th. For example, as shown in
Furthermore, in the embodiment, while the signal line drive circuit 33 performs frame reversal drive, the common connection line drive circuit 35 performs common reversal drive, in which polarity of a voltage supplied to the common electrode (common connection lines COM) is reversed every frame period, as shown in
Next, an internal configuration of the common connection line drive circuit 35 will be described. The common connection line drive circuit 35 has, for example, switching elements 36, each of which is electrically connected to each common connection line COM, as shown in
The common connection line drive circuit 35 connects a common connection line COM, which is disposed in correspondence to a horizontal line including sub pixels 11 (as a selection object) being on through application of Von to a scan line WSL, to an output terminal of the pulse generator 37. For example, as shown in
The common connection line drive circuit 35 connects a common connection line COM, which is disposed in correspondence to a plurality of horizontal lines including sub pixels 11 (as a non-selection object) being off through application of the voltage Voff to scan lines WSL, to the wiring 36B. For example, as shown in
While not shown, the common connection line drive circuit 35 may have a constant voltage supply 38 in place of the logic circuit 41.
Next, operation of the liquid crystal display device 1 according to the embodiment will be described.
Write Period Tw
In a write period Tw as the first half of each frame period, the scan line drive circuit 34 applies the voltage Von to a plurality of scan lines WSL in a desired number of lines as a unit so that transistors 14 and 15 are turned on. Furthermore, the signal line drive circuit 33 applies the signal voltage Vsig to each signal line DTL, and the common connection line drive circuit 35 applies the signal voltage VL or VH to a common connection line COM corresponding to a sub pixel 11 as a selection object.
At that time, the signal line drive circuit 33 applies a signal voltage Vsig, of which the polarity is reversed every 1H period and, reversed every frame period with respect to the reference voltage Vref, to each signal line DTL (1H reversal drive and frame reversal drive). Furthermore, the common connection line drive circuit 35 applies a voltage, of which the polarity with respect to the reference voltage Vref is opposite to polarity of the signal line DTL with respect to the reference voltage Vref, to a common connection line COM corresponding to a sub pixel 11 as a selection object in the write period Tw of each frame period (common reversal drive). Thus, a voltage Vw corresponding to the signal voltage Vsig is written into the sub pixel 11 as a selection object in the write period Tw (see
Holding Period Th
In a holding period Th as the second half of each frame period, the scan line drive circuit 34 applies the voltage Voff to scan lines WSL corresponding to sub pixels 11 as a non-selection object so that transistors 14 and 15 are turned off. Thus, the voltage Vw written during the write period Tw is kept in each of the sub pixels 11 as a non-selection object. As a result, each sub pixel 11 is lighted with a luminance corresponding to the voltage Vw.
The voltage Vw is principally not easily kept during the holding period Th. For example, in the VH frame period, as shown in
For example, in the VL frame period, as shown in
Therefore, for example, when the common connection line drive circuit 35 continuously applies a voltage Vcent to common connection lines COM corresponding to sub pixels 11 as a non-selection object in the holding period Th as shown in
In the embodiment, for example, the common connection line drive circuit 35 continuously applies a voltage V1 (<Vcent) to common connection lines COM corresponding to sub pixels 11 as a non-selection object in the holding period Th as shown in
Next, description will be made on an advantage obtained by adjusting the voltage of the common connection line COM in the holding period Th. In the embodiment, magnitude of a voltage Tw, applied to the liquid crystal element 16 is controlled by adjusting the voltage of the common connection line COM in the holding period Th as described before. For example, in the VH frame period, the voltage of the common connection line COM is adjusted to the voltage V1 (<Vcent) in the holding period Th. Thus, the voltage Vpix of the liquid crystal element 16 is reduced compared with a case where the voltage of the common connection line COM in the holding period Th is adjusted to the voltage Vcent, for example, as shown in
For example, in the VL frame period, the voltage of the common connection line COM is adjusted to the voltage V1 in the holding period Th. Thus, the voltage Vpix of the liquid crystal element 16 is reduced compared with a case where the voltage of the common connection line COM in the holding period Th is adjusted to the voltage Vcent, for example, as shown in
In this way, in the embodiment, voltage of the common connection line COM in the holding period Th is adjusted to the voltage V1 lower than the voltage Vcent. Thus, a voltage value (optimum value Vbest), at which flicker is minimized, is increased in the holding period Th (see
Thus, in the embodiment, respective values of the voltages VH and VL are adjusted in production (shipment) of the liquid crystal device 1 such that the center value ((upper limit value (voltage VH)+lower limit value (voltage VL))/2) of voltages applied to the common connection lines COM in the write period Tw is the optimum value Vbest-2. In this way, in the liquid crystal device 1 according to the embodiment, the voltage of each common connection line COM in the holding period Th is adjusted to the voltage V1 lower than the voltage Vcent, thereby flicker may be easily adjusted in all display gray levels unlike in the past. This may reduce burn-in caused by flicker in a high gray level.
Next, a liquid crystal device according to a second embodiment of the invention will be described. The liquid crystal device according to the embodiment is different in configuration from the liquid crystal device 1 according to the first embodiment in that the common connection line drive circuit 35 applies multiple voltages different from one another to the common connection lines COM in the holding period Th. Hereinafter, description on contents common to those in the first embodiment is omitted, and differences from the first embodiment are mainly described.
The common connection line drive circuit 35 applies multiple voltages different from one another to the common connection lines COM in the holding period Th. For example, the common connection line drive circuit 35 sequentially applies two voltages V1 and V2 (V1>V2) in the holding period Th as shown in
The common connection line drive circuit 35 electrically connects common connection lines COM applied with the same voltage to each other in the holding period Th. For example, as shown in
The common connection line drive circuit 35 electrically isolates a common connection line COM disposed in correspondence to a sub pixel 11 as a selection object from a plurality of common connection lines COM disposed in correspondence to sub pixels 11 as a non-selection object in the holding period Th. For example, as shown in
Furthermore, in the embodiment, while the signal line drive circuit 33 performs frame reversal drive, the common connection line drive circuit 35 performs common reversal drive, in which polarity of voltages supplied to the common electrode (common connection lines COM) is reversed every frame period, as shown in
Voltages in the holding period Th are preferably the same between the frame periods. For example, as shown in
The voltages in the holding period Th may not be the same during all frame periods. For example, voltages may be different from each other between the VH frame period and the VL frame period. Specifically, it is acceptable that two voltages are sequentially applied in the holding period Th, and a second voltage VB in a holding period Th of a VH frame period is different from a second voltage VA in a holding period Th of a VL frame period as shown in
The number of voltages in the holding period Th may not be the same during all frame periods. For example, in the case that the transistors 14 and 15 are a p-type transistor, it is acceptable that two voltages (V1 and V2) are sequentially applied in the holding period Th of the VH frame period, and one voltage (V1) is applied in the holding period Th of the VL frame period as shown in
When multiple voltages exist in the holding period Th, voltages equal to voltages (VH and VL) applied in the writing period Tw may be applied in an AC manner (alternately) at the beginning of the holding period Th. For example, as shown in
In addition, when multiple voltages exist in the holding period Th, application timings of the voltages in the holding period Th may be shifted from one another by 1H every one line within one field period, for example, as shown in
In particular, for a natural image, when multiple voltages exist in the holding period Th, one voltage may be a floating voltage. This is because even if one voltage is a floating voltage, degradation in image quality is hardly viewed in the natural image. For example, as shown in
For example, the predetermined voltage V1 and a floating voltage may be alternately applied to a common connection line COM in the first half of the holding period Th. For example, in a 1H period, it is acceptable that a voltage in an ON period (or a period including the ON period), in which a signal voltage corresponding to a video signal 30A is applied from the video signal processing circuit 31 to a signal line DTL (i), is the floating voltage, and a voltage in another period is V1, as shown in
Next, an internal configuration of the common connection line drive circuit 35 will be described. Hereinafter, description is made on an example of an internal configuration in the case that two voltages exist in the holding period Th.
The common connection line drive circuit 35 has switching elements 36 each of which is electrically connected to each common connection line COM, for example, as shown in
The common connection line drive circuit 35 connects a common connection line COM, which is disposed in correspondence to a horizontal line including a sub pixel 11 (as a selection object) being on through application of Von to a scan line WSL, to an output terminal of the pulse generator 37. For example, as shown in
The common connection line drive circuit 35 connects a common connection line COM to the wiring 36B, the common connection line COM being disposed in correspondence to a horizontal line, where a predetermined non-selection time has not elapsed, until the predetermined time passes among a plurality of horizontal lines including sub pixels 11 (as a non-selection object) being off through application of a voltage Voff to scan lines WSL. For example, as shown in
Furthermore, the common connection line drive circuit 35 connects a common connection line COM to the wiring 36C, the common connection line COM being disposed in correspondence to a horizontal line, in which a predetermined non-selection time has elapsed, among the plurality of horizontal lines including sub pixels 11 (as a non-selection object) being off through application of the voltage Voff to scan lines WSL. For example, as shown in
When at least three voltages exist in the holding period Th, while not shown, it is enough that the common connection line drive circuit 35 has, for example, the following configuration. That is, it is enough that the common connection line drive circuit 35 has, for example, switching elements 36, a pulse generator 37, at least three types of constant voltage circuits, a wiring 36A connected to the pulse generator 37, and wirings connected to the respective constant voltage circuits.
The common connection line drive circuit 35 may have a logic circuit in place of the constant voltage supplies 38 and 39. For example, the common connection line drive circuit 35 may have a logic circuit 41 in place of the constant voltage supply 38 as shown in
In the case that multiple voltages exist in the holding period Th, when one of the voltages is a floating voltage, it is enough that the common connection line drive circuit 35 has, for example, the following configuration. That is, for example, as shown in
Next, operation of the liquid crystal display device according to the embodiment will be described. Hereinafter, description is made on operation in the case that two voltages exist in the holding period Th.
Write Period Tw
In a write period Tw as the first half of each frame period, the scan line drive circuit 34 applies a voltage Von to a plurality of scan lines WSL in a desired number of lines as a unit, so that the transistors 14 and 15 are turned on. Furthermore, the signal line drive circuit 33 applies a signal voltage Vsig to each signal line DTL, and the common connection line drive circuit 35 applies the signal voltage VL or VH to a common connection line COM corresponding to a sub pixel 11 as a selection object.
At that time, the signal line drive circuit 33 applies a signal voltage Vsig, of which the polarity is reversed every 1H period, and reversed every frame period with respect to a reference voltage Vref, to each signal line DTL (1H reversal drive and frame reversal drive). Furthermore, the common connection line drive circuit 35 applies a voltage, of which the polarity with respect to the reference voltage Vref is opposite to polarity of the signal line DTL with respect to the reference voltage Vref, to a common connection line COM corresponding to a sub pixel 11 as a selection object in the write period Tw of each frame period (common reversal drive). Thus, a voltage Vw corresponding to the signal voltage Vsig is written into the sub pixel 11 as a selection object in the write period Tw (see
Holding Period Th
In a holding period Th as the second half of each frame period, the scan line drive circuit 34 applies the voltage Voff to scan lines WSL corresponding to sub pixels 11 as a non-selection object so that transistors 14 and 15 are turned off. Thus, the voltage Vw written during the write period Tw is kept in each of the sub pixels 11 as a non-selection object. As a result, each sub pixel 11 is lighted with a luminance corresponding to the voltage Vw.
The voltage Vw is principally not easily kept during the holding period Th. For example, in the VH frame period, as shown in
For example, in the VL frame period, as shown in
Therefore, for example, when the common connection line drive circuit 35 continuously applies a constant voltage to common connection lines COM corresponding to sub pixels 11 as a non-selection object in the holding period Th as shown in
In the embodiment, for example, the common connection line drive circuit 35 applies multiple (two) voltages to common connection lines COM corresponding to sub pixels 11 as a non-selection object in the holding period Th as shown in
In other words, in the embodiment, the sub pixels 11 are driven such that the holding period Th of each frame period has a period (Td) in which voltage of one liquid crystal element 16 decreases, and a period (Tu) in which the voltage increases. Furthermore, multiple (two) voltages are applied to a plurality of common connection lines COM such that average values of voltages applied to the liquid crystal element 16 are equal to each other between a period (Th1) in which one voltage (V1) is applied and a period (Th2) in which the other voltage (V2) is applied.
Thus, luminance of a sub pixel 11 may be made even between the period Th1 and the period Th2. As a result, flicker may be reduced. In the embodiment, since length of each frame period need not be decreased compared with previous length (namely, frame frequency need not be increased), flicker may be reduced even if high-speed drive is not performed. When high-speed drive is not performed, increase in power consumption may be suppressed in addition to reduction in flicker. Since flicker may be reduced, luminance of the backlight 20 may be increased compared with in the past. As a result, high image quality such as high contrast or high luminance may be achieved while flicker is reduced. Moreover, in the embodiment, a configuration or a shape of a sub pixel 11 is not restricted, which eliminates a possibility of reduction in aperture ratio or of increase in number of masks used in a manufacturing process.
In the embodiment, voltage of the common connection line COM in the holding period Th is adjusted to the voltage V1 or V2 lower than the voltage Vcent as in the first embodiment. Thus, a voltage value (optimum value Vbest), at which flicker is minimized, is increased in the holding period Th (see
Thus, even in the embodiment, values of the voltages VH and VL are adjusted in production (shipment) of the liquid crystal device such that the center value ((upper limit value (voltage VH)+lower limit value (voltage VL))/2) of voltages applied to the common connection lines COM in the write period Tw is the optimum value Vbest-2. In this way, even in the liquid crystal device according to the embodiment, the voltage of each common connection line COM in the holding period Th is adjusted to the voltage V1 or V2 lower than the voltage Vcent, thereby flicker may be easily adjusted in all display gray levels unlike in the past. This may reduce burn-in caused by flicker in a high gray level.
In the embodiment, even if voltages of the common connection line COM in the holding period Th are the same or not the same between respective frame periods, an average values of written voltages Vw may be equalized between both holding periods Th of the VH frame period and the VL frame period. In addition, even if the number of voltages of the common connection line COM in the holding period Th is not constant between all frame periods, an average value of written voltages Vw may be equalized between both holding periods Th of the VH frame period and the VL frame period.
In the embodiment, a common connection line COM disposed in correspondence to a sub pixel 11 as a selection object is electrically isolated from a plurality of common connection lines COM disposed in correspondence to sub pixels 11 as a non-selection object in the holding period Th. Thus, capacitance may be reduced during driving compared with a case where a common electrode is provided for all sub pixels 11. Moreover, in the embodiment, among the plurality of common connection lines COM disposed in correspondence to sub pixels 11 as a non-selection object, common connection lines COM applied with different voltages are also electrically isolated from each other in the holding period Th. This prevents occurrence of voltage difference between common connection lines COM applied with the same voltages for the sub pixels 11 as a non-selection object. Thus, charge and discharge of a common connection line COM may be performed at high speed while power consumption and light slipping are controlled to be low/small.
Voltages applied in the holding period Th are preferably not significantly different from one another. In such a case, since a large transverse electric-field is not generated in a region between common connection lines COM applied with voltages different from each other, light slipping may be reduced in the region.
In the embodiment, while the signal line drive circuit 33 performs frame reversal drive, common reversal drive, in which polarity of a voltage supplied to a common electrode (common connection lines COM) is reversed every frame period, is performed as shown in
In the embodiment, for example, in the case that a common connection line COM is floated for a predetermined period as shown in
In the embodiment, for example, as shown in
While not shown, in the case that another common connection line drive circuit 35 is additionally provided on the other end of each common connection line COM, ability of driving the common connection lines COM may be improved.
While the invention has been described with the embodiments hereinbefore, the invention is not limited to the embodiments, and may be variously modified or altered. For example, in the embodiments, while a voltage applied to the common connection line COM or an intermediate node line MID in the holding period Th has been a DC voltage in the embodiments, the voltage may be an AC voltage including a DC component.
The present application contains subject matter related to that disclosed in Japanese Priority Patent Application JP 2009-163134 filed in the Japan Patent Office on Jul. 9, 2009, the entire content of which is hereby incorporated by reference.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalent thereof.
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