This application claims priority, under 35 USC §119, of Korean Patent Application No. 2007-79661 filed on Aug. 8, 2007, the entire contents of which are herein incorporated by reference.
1. Field of the Invention
The present invention relates to a driving device, a liquid crystal display having the driving device, and a method of driving the liquid crystal display. More particularly, the present invention relates to a driving device capable of improving display quality, a liquid crystal display having the driving device, and a method of driving the liquid crystal display.
2. Description of the Related Art
Liquid crystal displays (LCD) that display an image using a liquid crystal layer are widely used as flat panel display devices in computers, televisions, digital cameras, cell phones and other electronic devices. An LCD typically includes a liquid crystal display panel and a driver circuit. The liquid crystal display panel displays an image in response to data voltages provided from the driver applied to its pixels. The driver receives an image signal and an image control signal from exterior source to generate the data voltages.
When data voltages each having the same polarity and the same voltage level are applied to a pixel in the liquid crystal layer during several consecutive frames, electric charges accumulate in the liquid crystal layer. If the accumulated electric charges are not completely discharged, a lingering after-image occurs.
For example, when a pixel in the LCD is turned OFF, the after-image remains, due to the non-discharge of the accumulated electric charge, and gradually disappears from the liquid crystal display panel, thereby causing deterioration of the image display quality of the LCD.
An aspect of the present invention provides a driving device capable of reducing an after-image to improve a display quality.
Another aspect of the present invention also provides a liquid crystal display having the driving device.
Another aspect of the present invention also provides a method of driving the liquid crystal display.
According to one aspect of the present invention, a driving device for outputting data voltages to a plurality of data lines of an LCD panel, comprising a data driver configured to output the data voltages wherein during a power-down mode, indicated by a logic state of a power-down mode signal, after the normal display mode, the voltage level of all of the data voltages is substantially the same. During the normal display mode, the voltage level of each data voltage is based on dynamically selecting one among a plurality of normal gray-scale voltages, wherein each of the normal gray-scale voltages is different, and wherein each selection is based on received image data. The driving circuit may also include a voltage selector having first and second output terminals and configured to receive the power-down mode signal, a first voltage, a second voltage having a lower voltage level than that of the first voltage, and a third voltage between the first voltage and the second voltage, and configured to output the first voltage and the second voltage at its first and second output terminals, respectively, during the normal display mode, and configured to output the third voltage to both of the first and second output terminals during the power-down mode. The driving device may further include a gray-scale voltage generator including first and second reference terminals respectively electrically connected to the first and second output terminals, and including a resistor string connected in series between the first reference terminal and the second reference terminal, wherein the gray-scale voltage generator is configured to generate the plurality of normal gray-scale voltages having different voltage levels by voltage-dividing the first and second voltages during the normal display mode, and configured to output a plurality of common gray-scale voltages during the power-down mode, wherein the gray-scale voltages output by the gray-scale voltage generator are output to the data driver.
According to another aspect of the present invention, a driving device includes a signal controller, a voltage selector, a gray-scale voltage generator, and a data driver.
The signal controller generates a data signal corresponding to an image, and a control signal indicating a power-down mode.
The voltage selector receives a first voltage, a second voltage, and a third voltage having a voltage level corresponding to between the first voltage and the second voltage, outputs either the first voltage or the third voltage through a first output terminal, and outputs either the second voltage or the third voltage through a second output terminal according to the control signal.
The gray-scale voltage generator includes first and second reference terminals respectively electrically connected to the first and second output terminals, receives the first and second voltages through the first and second output terminals, respectively, to generate first (normal) gray-scale voltages having different voltage levels, and receives the third voltage through the first and second reference terminals during the power-down to generate second (common) gray-scale voltages each having the same voltage level as that of the third voltage level.
The data driver changes the data signal to a positive/negative data voltage using the first (normal) gray-scale voltages to output the positive/negative data voltage and changes the data signal to a common data voltage using the second (common) gray-scale voltages to output the common data voltage.
In another aspect of the present invention, a liquid crystal display includes a signal controller, a voltage selector, a gray-scale voltage generator, a data driver, and a liquid crystal display panel.
The signal controller generates a data signal corresponding to an image and a control signal indicating a power-down;
The voltage selector receives a first voltage, a second voltage, and a third voltage having a voltage level corresponding to between the first voltage and the second voltage, outputs either the first voltage or the third voltage through a first output terminal, and outputs either the second voltage or the third voltage through a second output terminal according to the control signal.
The gray-scale voltage generator includes first and second reference terminals respectively electrically connected to the first and second output terminals, receives the first and second voltages through the first and second output terminals, respectively, to generate first (normal) gray-scale voltages having different voltage levels, and receives the third voltage through the first and second reference terminals during the power-down to generate second (common) gray-scale voltages each having a same voltage level as that of the third voltage level.
The data driver changes the data signal to a positive/negative data voltage using the first (normal) gray-scale voltages to output the positive/negative data voltage and changes the data signal to a common data voltage using the second (common) gray-scale voltages to output the common data voltage.
The liquid crystal display panel displays a normal image based on the positive/negative data voltage and displays an abnormal image based on the common data voltage during the power-down.
In further aspect of the present invention, a method of driving a liquid crystal display is provided as follows. First (normal) gray-scale voltages corresponding to between a first voltage and a second voltage are generated to have different voltage levels from each other. Second (common) gray-scale voltages corresponding to an intermediate value between the first voltage and the second voltage are generated during a power-down to have the same voltage level as that of a third voltage. A data signal corresponding to an image is changed to a first data voltage using the first (normal) gray-scale voltages, and the data signal corresponding to the image is changed to a second data voltage using the second (common) gray-scale voltages generated during the power-down of the liquid crystal display. Then, a normal image corresponding to the first data voltage is displayed through the liquid crystal display, and during the power-down, an abnormal image corresponding to the second data voltage is displayed through the liquid crystal display.
According to the above, the liquid crystal display displays a white image during the power-down. The data voltage corresponding to the white image has a voltage level that is equal to or near to the common voltage. Thus, electric charges accumulated in the liquid crystal layer may be easily discharged, thereby removing an after-image effectively during the power-down of the liquid crystal display.
It will be understood that when an element is referred to as being “connected to” or “coupled to” another element, it can be directly connected or coupled to the other element or intervening elements may be present. In contrast, when an element is referred to as being “directly connected to” or “directly coupled to” another element, there are no intervening elements present. Like numbers refer to like elements throughout. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.
It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, components, regions, and/or parts, these elements, components, regions, layers and/or parts should not be limited by these terms. These terms are only used to distinguish one element, component, region, layer or part from another region, layer or part. Thus, a first element, component, region, layer or part discussed below could be termed a second element, component, region, layer or part without departing from the teachings of the present invention.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms, “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “having”, “includes” and/or “including”, when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
The above and other features of the present invention will become readily apparent by reference to the following detailed description when considered in conjunction with the accompanying drawings, wherein:
In the exemplary embodiments that will be described hereinafter, the terms of a first voltage, a second voltage, and a third voltage used in claims represent an positive power voltage +AVDD, a negative power voltage −AVDD, and a common voltage Vcom, respectively. Accordingly, the first, second, and third voltages will be referred to hereinafter as the positive power voltage +AVDD, the negative power voltage −AVDD, and the common voltage Vcom, respectively.
Also, the terms first gray-scale voltages and second gray-scale voltages used in claims represent the normal gray-scale voltages and the common (abnormal) gray-scale voltages, respectively. Accordingly, the terms first gray-scale voltages and second gray-scale voltages will be referred to hereinafter with the normal gray-scale voltages and the common gray-scale voltages.
Referring to
The driving device 100 includes a signal controller 120 configured to receive and transmit data with an external system 10, a voltage generator 130 configured to generate various reference voltages applied to generate gray-scale voltages VG, a voltage selector 140 configured to selectively output the reference voltages, a gray-scale voltage generator 150 configured to generate the gray-scale voltages VG using the selectively output reference voltages, and a driver 160 configured to output data voltages D1˜Dm corresponding to the gray-scale voltages VG to the liquid crystal display panel according to a control of the signal controller 120.
Also, the driving device 100 further includes a low voltage differential signaling (LVDS) receiver 110 that is interfaced with the external system 10 for the data communication between the external system 10 and the driving device 100.
The external system 10 includes a graphic controller 12, an LVDS transmitter 14, and a power supplier 16.
The graphic controller 12 receives a video signal VS and a video control signal VCT that controls the video signal VS and changes the video signal VS and the video control signal VCT to an image signal DATAO in a digital form and an image control signal CTO that controls the image signal DATAO, respectively, to output the image signal DATAO in the digital form and the image control signal CTO. Also, the graphic controller 12 configured to output a power-down control signal (e.g. an enabled clock signal) CLKO that stops the operation of the driving device 100 in response to an external power-down signal POWER-OFF. The power-down control signal CLKO is in a digital (e.g., binary) form and may include multiple parallel data bits. The graphic controller 12 changes the power-down control signal CLKO from an inactivated state to an activated state in response to the external power-down signal POWER-OFF. The power-down control signal CLKO may be synchronized with the data control (clock) signal CT1 and so may be implemented as a gated clock signal.
The power supplier 16 provides an alternating current (AC) voltage VIN within a range from 100 volts to 240 volts to the voltage generator 130 arranged in the driving device 100 in order to operate the driving device 100.
Meanwhile, in order to reduce electromagnetic interference (EMI) between channels connecting the external system 10 and the driving device 100, the driving device 100 performs a data communication with the external system 10 using a differential signaling transmission method, such as the LVDS transmission method and a reduced swing differential signaling (RSDS) transmission method. In the present exemplary embodiment, the driving device 100 using only the LVDS transmission method will be described in detail.
In order to perform the data communication according to the LVDS differential signaling transmission method, the external system 10 includes the LVDS transmitter 14 and the driving device 100 includes the LVDS receiver 110.
The LVDS transmitter 14 changes the image signal DATAO, the image control signal CTO, and the power-down control signal CLKO from the graphic controller 12 to a differential image signal LVDS-DATAO, a differential image control signal LVDS-CTO, and a differential power-down control (enabled clock) signal LVDS-CLKO, respectively, and outputs the differential image signal LVDS-DATAO, the differential image control signal LVDS-CTO, and the differential power-down control signal LVDS-CLKO.
The differential image signal LVDS-DATAO, the differential image control signal LVDS-CTO, and the differential power-down control signal LVDS-CLKO are output to the LVDS receiver 110 in the driving device 100 through at least one channel.
The LVDS receiver 110 receives the differential image signal LVDS-DATAO, the differential image control signal LVDS-CTO, and the differential power-down control signal LVDS-CLKO and restores the image signal DATAO, the image control signal CTO, and the power-down control signal CLKO from the differential image signal LVDS-DATAO, the differential image control signal LVDS-CTO, and the differential power-down control signal LVDS-CLKO.
The restored image signal DATAO and the restored image control signal CTO are applied to the signal controller 120, and the restored power-down control (enabled clock) signal CLKO (hereinafter, referred to as a power-down control signal and/or a power-down mode-indicating signal) is applied to the voltage selector 140.
The signal controller 120 receives the image data DATAO and the image control signal CTO and changes the image data DATAO and the image control signal CTO. The signal controller 120 receives data signal DATA1 and the control signals CT1 and CT2, respectively, to output the data signal DATA1 and the control signals CT1 and CT2.
The control signals CT1 and CT2 include a data control signal CT1 and a gate control signal CT2.
The data control signal CT1 is applied to a data driver 162 of the driver 160 with the data signal DATA1 and controls parallel output of data voltages D1˜Dm from the data driver 162. The gate control signal CT2 is applied to a gate driver 164 of the driver 160 and controls sequential output of gate voltages G1˜Gn from the gate driver 164.
The voltage generator 130 receives the alternating current (AC) power voltage VIN from the power supplier 16 in the external system 10 to generate a power voltage VDD, an positive power voltage +AVDD, an negative power voltage −AVDD, and a common voltage Vcom supplied to the voltage selector 140. The control signal CLK0 is applied to the voltage selector 140 and controls output of voltages +AVDD, −AVDD, and Vcom that are output from the voltage selector 140.
positive power voltage +AVDD negative power voltage −AVDD
Although not shown in
The AC-DC rectifier may have a power factor correction function and changes (rectifies) the alternating current (AC) power voltage VIN to a direct current (DC) voltage having a high voltage level.
The DC-DC converter changes the direct current voltage having the high voltage level provided from the AC-DC rectifier to generate the power voltage VDD, the positive power voltage +AVDD used to control transmittance of liquid crystals of the liquid crystal display panel. The DC-DC converter also generates the negative power voltage −AVDD that is opposite to the positive power voltage +AVDD, and the common voltage Vcom. In the present exemplary embodiment, the common voltage Vcom has a voltage level that is substantially equal to the intermediate (e.g., mean) value between the positive power voltage +AVDD and the negative power voltage −AVDD.
The voltage selector 140 receives the power voltage VDD, the positive power voltage +AVDD, the negative power voltage −AVDD, the common voltage, and the restored control signal CLKO from the LVDS receiver 120.
The voltage selector 140 outputs the common voltage Vcom and selectively outputs either one of the positive power voltage +AVDD and the negative power voltage −AVDD according to the logic state of the control signal CLKO that indicates a power-down mode.
The gray-scale voltage generator 150 generates normal gray-scale voltages and common gray-scale voltages using the selectively output voltages.
The driver 160 includes the data driver 162 and the gate driver 164.
The data driver 162 changes the data signal DATA1 from the signal controller 120 to normal the data voltages D1˜Dm using the normal gray-scale voltages provided from the gray-scale voltage generator 150.
Meanwhile, during the power-down of the driving device 100, the data driver 162 changes the data signal DATA1 to common data voltages D1′˜Dm′ using the common gray-scale voltages provided from the gray-scale voltage generator 150.
The data driver 162 outputs a selection among the image data voltages D1˜Dm and the common data voltages D1′˜Dm′ to the liquid crystal display panel 200 (shown in
The gate driver 164 changes the gate signals among voltages Von and Voff provided from the voltage generator 130 to output gate voltages G1˜Gn in response to the gate control signal CT2 from the signal controller 120 and outputs the gate voltages G1˜Gn to the liquid crystal display panel.
The liquid crystal display panel (200 in
Referring to
The first selection circuit 142 receives the control signal CLKO provided from the LVDS receiver 110 and selectively outputs either the positive power voltage +AVDD or the common voltage Vcom according to the logic state of the control signal CLKO. The second selection circuit 144 receives the control signal CLKO provided from the LVDS receiver 110 and selectively outputs either the negative power voltage −AVDD or the common voltage Vcom according to the logic state of the control signal CLKO.
Referring to
The first switching part 142A includes a first switching device T1. The first switching device T1 includes a first terminal TE1 electrically connected to a first power line L1 that transmits the positive power voltage +AVDD, a second terminal TE2 electrically connected to the first output terminal OUT1, and a third terminal TE3 electrically connected to the first input terminal IN1.
The second switching part 142B includes a second switching device T2 and a third switching device T3. The second switching device T2 includes a first terminal TE4 electrically connected to a fourth power line L4 that transmits the power voltage VDD provided from the voltage generator 130, a second terminal TE5 electrically connected to a ground voltage VSS, and a third terminal TE6 receiving the control signal CLKO.
The third switching device T3 includes a first terminal TE7 electrically connected to a second power line L2 that transmits the common voltage Vcom, a second terminal TE8 electrically connected to the first output terminal OUT1, and a third terminal TE9 electrically connected to the first terminal TE4 of the second switching device T2.
When the control signal CLKO in a logic high state is applied through the first input terminal IN1, the first and second switching devices T1 and T2 are turned ON, and the third switching device T3 is turned OFF. Thus, the positive power voltage +AVDD is output to the first output terminal OUT1 through the first switching device T1.
On the other hand, when the control signal CLKO in a logic low state is applied through the first input terminal IN1, the first and second switching devices T1 and T2 are turned OFF, and the third switching device T3 is turned ON. Accordingly, the common voltage Vcom is output to the first output terminal OUT1 through the third switching device T3.
Referring to
The third switching part 144A includes a fourth switching device T4. The fourth switching device T4 includes a first terminal TE10 electrically connected to the second power line L2 that transmits the common voltage Vcom, a second terminal TE11 electrically connected to a third power line L3 that transmits the analog power voltage −AVDD provided from the voltage generator 130, and a third terminal TE12 electrically connected to the second input terminal IN2.
When the control signal CLKO in a logic high state is applied through the second input terminal IN2, the fourth switching device T4 is turned ON. Thus, the negative power voltage −AVDD is output to the second output terminal OUT2.
On the other hand, when the control signal CLKO in a logic low state is applied through the second input terminal IN2, the fourth switching device T4 is turned OFF. Accordingly, the common voltage Vcom is output to the first output terminal OUT1.
Consequently, the voltage selector 140 outputs the positive power voltage +AVDD and the negative power voltage −AVDD through the first and second output terminals OUT1 and OUT2, respectively, in response to the control signal CLKO in the logic high state. Also, the voltage selector 140 simultaneously outputs the common voltage Vcom to both the first and second output terminals OUT1 and OUT2 in response to the control signal CLKO in the logic low state that indicates the power-down mode of the driving device 100.
In the present exemplary embodiment, the first to fourth switching devices T1˜T4 shown in
Referring to
The first reference terminal 152 is electrically connected to the first output terminal OUT1 of the first selection circuit 142 as shown in
The resistor strings RG1˜RG18 include a plurality of resistors connected one after another, in series, between the first reference terminal 152 and the second reference terminal 154, and connecting portions of each resistor have different electric potentials from each other according to a voltage division rule. The electric potentials of the connecting portions of each resistor are defined as gray-scale voltages VG1˜VG18.
When the positive power voltage +AVDD is applied to the first reference terminal 152 and the negative power voltage −AVDD is applied to the second reference terminal 154, the resistor strings RG1˜RG18 generate positive gray-scale voltages VG1˜VG9 and negative gray-scale voltage levels VG9˜VG18 having different voltage levels from each other by voltage-dividing a voltage difference between the positive power voltage +AVDD and the negative power voltage −AVDD.
The normal gray-scale voltages VG1˜VG18 are divided, with reference to the common voltage Vcom input through the third reference terminal 156, into ascending (positive polarity) gray-scale voltages VG1˜VG9 of which the voltage levels are gradually ascending by a predetermined voltage level from the common voltage Vcom to the positive power voltage +AVDD according to gray-scale values G1˜G64 and descending (negative polarity) gray-scale voltages VG10˜VG18 of which the voltage levels are gradually descending by a predetermined voltage level from the common voltage Vcom to the negative power voltage −AVDD according to the gray-scale values G1˜G64.
The lowest gray-scale voltage VG9 that is substantially closest to the common voltage Vcom among the ascending (positive polarity) gray-scale voltages VG1˜VG9 is defined as a first gray-scale G1, and the highest gray-scale voltage VG1 that is substantially farthest from the common voltage Vcom among the ascending (positive polarity) gray-scale voltages VG1˜VG9 is defined as a sixty-fourth gray-scale G64. In the present exemplary embodiment, the highest gray-scale voltage VG1 is defined as the sixty-fourth gray-scale G64, however, the highest gray-scale voltage may be defined as more than the 64-th gray-scale, for instance, 256-th gray-scale.
The highest gray-scale voltage VG10 that is substantially closest to the common voltage Vcom among the descending (negative polarity) gray-scale voltages VG10˜VG18 is defined as the first gray-scale G1, and the lowest gray-scale voltage VG18 that is substantially farthest from the common voltage Vcom among the descending (negative polarity) gray-scale voltages VG10˜VG18 is defined as the sixty-fourth gray-scale G64. When the highest gray-scale voltage VG1 among the ascending (positive polarity) gray-scale voltages VG1˜VG9 has a gray-scale value equal to or greater than 256-th gray-scale, the lowest gray-scale voltage VG18 among the descending (negative polarity) gray-scale voltages VG10˜VG18 has a gray-scale value equal to or greater than 256-th gray-scale. In the present exemplary embodiment, the common voltage Vcom has a voltage level of about 0 volts that is equal to an intermediate value between the positive power voltage +AVDD and the negative power voltage −AVDD.
The first gray-scale G1 is a “white” gray-scale that is represented as the brightest color on the liquid crystal display panel, and the 64-th gray-scale G64 is a “black” gray-scale that is represented as the darkest color on the liquid crystal display panel. Thus, except for the first gray-scale G1 and the 64-th gray-scale G64, the remaining gray-scales G8, G16, . . . , G56 are considered to be “gray” gray-scales.
When the driving device 100 is arranged in a liquid crystal display (LCD) operated in a normally white mode (i.e., outputs a white image when the common voltage Vcom is applied as the data voltage to all pixels), the black gray-scale is defined as the highest gray-scale voltage VG1 and the lowest gray-scale voltage VG18 among the gray-scale voltages generated from the gray-scale voltage generator 150. And the white gray-scale is defined as intermediate gray-scale voltages between the highest gray-scale voltage and the lowest gray-scale voltage. Thus the white gray-scale voltages are defined as gray-scale voltages VG9 and VG10 closest to the common voltage Vcom.
When the common voltage Vcom is commonly applied to both the first and second reference terminals 152 and 154, the resistor strings RG1˜RG18 generate common gray-scale voltages VG1˜VG18 each having the same voltage level as the common voltage Vcom. Thus, when the common voltage Vcom is commonly applied to both the first and second reference terminals 152 and 154, the common gray-scale voltages VG1˜VG18 have substantially the same voltage level with the common voltage Vcom because there is no voltage difference to be divided between the first and second reference terminals 152 and 154.
Accordingly, when the common voltage Vcom is commonly applied to both the first and second reference terminals 152 and 154, the ascending (positive polarity) gray-scale voltages VG1˜VG9 have the same voltage level as the lowest gray-scale voltage VG9 corresponding to the first gray-scale G1 (i.e., a white level). Also, the descending (negative polarity) gray-scale voltages VG10˜VG18 have the same voltage level as the highest gray-scale voltage VG10 corresponding to the first gray-scale G1 (i.e., a white level). In the present exemplary embodiment, the lowest gray-scale voltage VG9 among the ascending (positive polarity) gray-scale voltages VG1˜VG9 and the highest gray-scale voltage VG10 among the descending (negative polarity) gray-scale voltages VG10˜VG18 all have the same (“white”) voltage level as that of the common voltage Vcom (see
Referring to
The voltage levels of the data voltages are divided into a positive period (+) during which the voltage level range from the common voltage Vcom by a predetermined voltage level and a negative period (−) during which the voltage level decreases from the common voltage Vcom by a predetermined voltage level.
According to gray-scale values G1˜G64, first to ninth data voltages DV1˜DV9 are used during the positive period (+), and tenth to eighteenth data voltages DV10˜DV18 are used during the negative period (−).
The ninth data voltage DV9 is closest to the common voltage Vcom in the positive period (+) and represents the white gray-scale. In the positive period (+), as the gray-scales become closer to the first data voltage DV1, the gray-scales become farther from the common voltage Vcom and get nearer to the black-gray scale. Therefore, the first data voltage DV1 represents the black gray-scale.
The tenth data voltage DV10 is closest to the common voltage Vcom in the negative period (−) and represents the white gray-scale. In the negative period (−), as the gray-scale become closer to the eighteenth data voltage DV18, the gray-scales become farther from the common voltage Vcom and get nearer to the black gray-scale. Thus, the eighteenth data voltage DV18 represents the black gray-scale.
Referring to
Accordingly, during the power-down, only the data voltage corresponding to a gray-scale voltage that is closest to the common voltage Vcom is output from the data driver 162.
Particularly, in the positive period (+), only the common voltage Vcom is output as the gray-scale values G1˜G64.
Also, in the negative period (−), only the common voltage Vcom is output as the gray-scale values G1˜G64. In the present exemplary embodiment, the ninth data voltage DV9 in the positive period (+) has substantially same common voltage level (Vcom) as that of the tenth data voltage DV10 in the negative period (−).
Accordingly, the only data voltage output from the data driver 162 during the power-down is the “white” voltage.
Referring to
The driving device 100 outputs the gate voltages G˜Gn, and selectively outputs the image data voltages D1˜Dm and the common data voltages D1′˜Dm′. The driving device 100 provides the image data voltages D1˜Dm that are generated using normal gray-scale voltages to the liquid crystal display panel 200 prior to the power-down time initiated by a user or (power-saving) program, and provides the common data voltages D1′˜Dm′ that are generated using common gray-scale voltages to the liquid crystal display panel 200 during the power-down.
The liquid crystal display panel 200 includes a plurality of gate lines GL1˜GLn sequentially receiving the gate voltages G1˜Gn and a plurality of data lines DL1˜DLm that are insulating from and intersecting with the gate lines GL1˜GLn. A plurality of pixel areas is defined by the gate lines GL1˜GLn and the data lines DL1˜DLm.
Pixels are arranged in the pixel areas in a one-to-one correspondence relationship. Each pixel is electrically connected to a corresponding gate line and a corresponding data line to display an image in response to a corresponding gate voltage of the gate voltages G1˜Gn and a corresponding data voltage of the data voltages D1˜Dm or D1′˜Dm′ provided through the corresponding gate and data lines, respectively. The images displayed through the pixels are realized as an image corresponding to one frame.
Also, the liquid crystal display panel 200 includes a liquid crystal layer operated in the normally white mode. The liquid crystal layer operated in the normally white mode has a high light transmittance when a data voltage is not applied or a data voltage at a very low level is applied. Thus, the liquid crystal display panel 200 displays a white color.
Accordingly, a pixel that receives a data voltage having a voltage level equal to or near to that of the common voltage Vcom displays a white color or a gray color similar to the white color.
The liquid crystal display panel 200 receives the image data voltages D1˜Dm from the data driver 162 to display the normal image and receives the common data voltages D1′˜Dm′ from the data driver 162 during the power-down to display the abnormal (white) image.
The common data voltages D1′˜Dm′ have voltage levels that are equal to or near to that of the common voltage Vcom regardless of the gray-scale value information obtained from a data signal DATA1 received from the signal controller 120. The common data voltages D1′˜Dm′ have voltage levels that are substantially equal to or near to that of the common voltage Vcom. Therefore, the liquid crystal display panel 200 that receives the common data voltages D1′˜Dm′ displays the white image or the gray image similar to the white image.
Consequently, the LCD 300 displays the white image during the power-down, thereby preventing an after-image from being displayed thereon.
The common data voltages D1′˜Dm′ corresponding to the abnormal white image have voltage levels that are equal to or near to the common voltage Vcom. Thus, electric charges accumulated in the liquid crystal layer are easily discharged, and during the power-down, the after-image may be prevented more effectively by readily discharging the electric charges accumulated in the liquid crystal layer.
Referring to
According to the principles of the invention, when the LCD is turned OFF, the white image is displayed by all pixels.
In this case, the data voltage corresponding to the white image is equal to or near to the common voltage.
Thus, the electric charges accumulated in the liquid crystal layer may be easily discharged, thereby effectively removing the after-image appearing on the LCD during or after the power-down of the LCD.
Number | Date | Country | Kind |
---|---|---|---|
10-2007-0079661 | Aug 2007 | KR | national |
Number | Name | Date | Kind |
---|---|---|---|
6256025 | Imai et al. | Jul 2001 | B1 |
6459399 | Nozaki | Oct 2002 | B1 |
7864170 | Kida et al. | Jan 2011 | B2 |
7940286 | Pan et al. | May 2011 | B2 |
20020075255 | Baek et al. | Jun 2002 | A1 |
20020149541 | Shin | Oct 2002 | A1 |
20030132906 | Tanaka et al. | Jul 2003 | A1 |
20030151577 | Morita | Aug 2003 | A1 |
20030189564 | Lee et al. | Oct 2003 | A1 |
20040125068 | Lee | Jul 2004 | A1 |
20050017992 | Kudo et al. | Jan 2005 | A1 |
20050243046 | Hong | Nov 2005 | A1 |
20050285832 | Shin et al. | Dec 2005 | A1 |
20060007209 | Nakamura et al. | Jan 2006 | A1 |
20070182670 | Watanabe et al. | Aug 2007 | A1 |
Number | Date | Country |
---|---|---|
2005-250034 | Sep 2005 | JP |
2007-065134 | Mar 2007 | JP |
1020020094348 | Dec 2002 | KR |
Number | Date | Country | |
---|---|---|---|
20090040244 A1 | Feb 2009 | US |