KR20070033784A - Square reversing display device and its driving method - Google Patents

Abstract

The display apparatus according to the present invention includes a panel, a timing controller for outputting an operation start signal, and a driver for receiving the operation start signal to drive the panel, wherein the driver is composed of a plurality of data driver chips, Each of the data driver chips may generate an output operation start signal having a pulse width different from a pulse width of the operation start signal input from a previous data driver chip.

Description

DISPLAY DEVICE OF SQUARE INVERSION SYSTEM AND DRIVING METHOD THEREOF}

1 is a block diagram illustrating a liquid crystal display according to an exemplary embodiment of the present invention.

2 shows a square inversion scheme.

FIG. 3 is a detailed block diagram illustrating the data driver IC shown in FIG. 1.

4 is a waveform diagram showing signals of a data driver IC for square inversion driving.

Explanation of symbols on the main parts of the drawings

10: liquid crystal display device 100: liquid crystal panel

200: timing controller 300: data driver

311: DIO generating unit 312: inverting driving unit

313: data register 314: latch

315: level shifter 316: digital-to-analog converter

317: output buffer 400: gate driver

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly to a liquid crystal display device (LCD).

Liquid crystal displays have advantages of miniaturization and low power consumption, and are used in notebook computers and LCD TVs. In particular, an active matrix type liquid crystal display device using a thin film transistor (TFT) as a switch element is suitable for displaying moving images.

The liquid crystal display device is a display device in which a liquid crystal is injected between two substrates (glass substrates) bonded to each other with a predetermined space. The liquid crystal display device can control the amount of light transmitted to the substrate by applying an electric field to the liquid crystal and adjusting the intensity of the electric field. In this control manner, a desired image signal is displayed.

In order to prevent deterioration of the liquid crystal, the liquid crystal display uses an inversion driving method in which a positive voltage (+) and a negative voltage (−) are alternately applied to the liquid crystal. The inversion driving method includes a line inversion method, a column inversion method, a frame inversion method, a dot inversion method, and a square inversion method.

The square inversion method is a method in which the polarity of the liquid crystal applied voltage is inverted in units of 2 X 2 dots, and thus, power consumption is reduced compared to the dot inversion method. In the square inversion method, the voltage output from the even-numbered data driver IC and the voltage output from the odd-numbered data driver IC among the plurality of data driver integrated circuits (Data Driver Integrated Circuit) constituting the data driver operate to have opposite polarities. . To this end, the timing controller constituting the liquid crystal display outputs a polarity signal (POL or REV) along with a separate selection signal for inverting the polarity of the output voltage depending on whether the data driver IC is even or odd. Must be authorized. Accordingly, the square inversion liquid crystal display device has a problem in that a circuit configuration is complicated because a separate signal line for the selection signal must be provided between the timing controller and each data driver IC.

Therefore, the technical problem to be achieved by the present invention has been proposed to solve the above-mentioned problems, and to provide a data driver that enables square inversion driving without adding a separate signal line.

The display apparatus according to the present invention includes a panel, a timing controller for outputting an operation start signal, and a driver for receiving the operation start signal to drive the panel, wherein the driver is composed of a plurality of data driver chips, Each of the data driver chips may generate an output operation start signal having a pulse width different from a pulse width of the operation start signal input from a previous data driver chip.

In this exemplary embodiment, the first data driver chip of the plurality of data driver chips may receive the operation start signal from the timing controller.

In this embodiment, the output operation start signal is characterized in that the operation start signal of the next data driver chip.

In this embodiment, the operation start signal may be a control signal for enabling the operation of each data driver chip.

In this embodiment, if the pulse width of the operation start signal input to the data driver chip is equal to one clock cycle, the data driver chip generates the output operation start signal with a pulse width equal to two clock cycles. It features.

In this embodiment, if the pulse width of the operation start signal input to the data driver chip is equal to two clock cycles, then the data driver chip generates the output operation start signal with a pulse width equal to one clock cycle. It features.

In this embodiment, the timing controller outputs a polarity signal to each of the data driver chips.

In this exemplary embodiment, the data driver chip generates an internal polarity signal in which the polarity signal is inverted or non-inverted according to the pulse width of the operation start signal.

In this embodiment, the internal polarity signal is characterized in that it controls the polarity of the voltage applied from the data driver chip to the panel.

In this embodiment, each data driver chip includes a DIO generator for receiving the operation start signal and generating the output operation start signal, and an inversion driver for generating the internal polarity signal. .

According to an aspect of the present invention, there is provided a method of driving a display device including a panel and a plurality of data driver chips. Generating an internal polarity signal inverting or non-inverting the polarity signal, controlling a polarity of a voltage applied from the data driver chip to the panel according to the internal polarity signal, and pulse of the operation start signal And generating an output operation start signal having a pulse width different from the width.

In this embodiment, the output operation start signal is characterized in that the operation start signal of the next data driver chip.

In this embodiment, if the pulse width of the operation start signal input to the data driver chip is equal to one clock cycle, the data driver chip generates the output operation start signal with a pulse width equal to two clock cycles. It features.

In this embodiment, if the pulse width of the operation start signal input to the data driver chip is equal to two clock cycles, then the data driver chip generates the output operation start signal with a pulse width equal to one clock cycle. It features.

(Example)

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

1 is a block diagram illustrating a liquid crystal display according to an exemplary embodiment of the present invention. The liquid crystal display device 10 includes a liquid crystal panel 100, a timing controller 200, a data driver 300, and a gate driver 400.

The liquid crystal panel 100 includes a plurality of pixels. Each pixel 110 includes a thin film transistor (TR), a storage capacitor (CST) for reducing current leakage from the liquid crystal, and a liquid crystal capacitor (CLC). The thin film transistor TR is turned on / off in response to a signal driving the gate line GL, and one terminal of the thin film transistor TR is connected to the data line DL. The storage capacitor CST is connected between the other terminal of the thin film transistor TR and the ground voltage VSS, and the liquid crystal capacitor CLC is connected between the other terminal of the thin film transistor TR and the common voltage VCOM. Connected.

The timing controller 200 adjusts and outputs image data signals to match the timing required by the data driver 300 and the gate driver 400. In addition, the timing controller 200 outputs control signals for controlling the data driver 300 and the gate driver 400.

The data driver 300 or the source driver 300 includes a plurality of data driver ICs 310 to 3n0. The data driver 300 receives a DIO signal (or STH: Start horizontal signal for source driver) DIO1 as an input from the timing controller 200 to start the operation of the first data driver IC 310. The data driver 300 outputs a data line driving signal for driving the data lines DL disposed on the liquid crystal panel 100.

Each data driver IC 310 to 3n0 includes a DIO generator 311 and an inversion driver 312. The first data driver IC 310 receives the polarity signal REV and the first operation start signal DIO1 from the timing controller 200 and outputs i data line driving signals DL1 [1: i]. . The DIO generating unit 311 of the first data driver IC 310 receives the first operation start signal DIO1 from the timing controller 200 and transmits the second operation start signal DIO2 to the second data driver IC 320. ) The DIO generator 311 adjusts the pulse width of the input first operation start signal DIO1 to be different from the pulse width of the output second operation start signal DIO2. For example, if the pulse width of the first operation start signal DIO1 is equal to one clock period, the pulse width of the output second operation start signal DIO2 is two clock periods. On the contrary, if the pulse width of the second operation start signal DIO2 input from the second data driver IC 320 is equal to the clock two period, the pulse width of the output third operation start signal DIO3 is equal to one clock period. do. As such, the pulse widths of the operation start signals DIO1, DIO3, ... input to the odd data driver IC and the pulse widths of the operation start signals DIO2, DIO4, ... input to the even data driver IC are Will be different. If the pulse width of the operation start signals (DIO1, DIO3, ...) input to the odd data driver IC is equal to the clock 1 period, the operation start signals (DIO2, DIO4,...) Input to the even data driver IC. Pulse width is equal to two clock cycles. The operation start signal DIO having a different pulse width applied to each of the data driver ICs 310 to 3n0 becomes a selection signal for the liquid crystal display 10 to perform square inversion driving.

The inversion driver 312 controls the polarity of the liquid crystal applied voltage according to the pulse width of the input operation start signal DIO. For example, if the pulse width of the operation start signal DIO1 is equal to one clock period, the inversion driver 312 of the first data driver IC 310 may have a polarity signal REV input from the timing controller 200. An internal polarity signal IREV having the same polarity is generated and controlled to output a positive liquid crystal applied voltage as the first data line driving signal DL1 [1]. On the contrary, if the pulse width of the operation start signal DIO2 is equal to two clock cycles, the inversion driver 312 of the second data driver IC 320 has the opposite polarity to the polarity signal REV input from the timing controller 200. An internal polarity signal I RV is generated to control the output of the liquid crystal applied voltage having a negative value (−) as the first data line driving signal DL2 [1]. Accordingly, the voltage output from the even-numbered data driver IC and the voltage output from the odd-numbered data driver IC have opposite polarities, and thus the liquid crystal display 10 may perform square inversion driving.

The gate driver 400 includes a plurality of gate driver ICs 410 to 4m0, and outputs a gate line driving signal for driving gate lines GL disposed on the liquid crystal panel 100. . The gate driver 400 may include a shift register that sequentially generates scan pulses in response to a control signal applied from the timing controller 200, and a level for shifting the voltage of the scan pulses to a level suitable for driving the liquid crystal. Level Shifter and so on. The scan pulse sequentially applies a gate-on voltage to the gate line, thereby making the pixel of the gate line GL to which the gate-on voltage is applied write data.

2 shows a square inversion scheme. In the square inversion method, the polarity of the liquid crystal applied voltage is inverted in units of 2 X 2 dots. The voltage output from the even-numbered data driver IC and the voltage output from the odd-numbered data driver IC have opposite polarities. For example, the polarity of the first data line driving signal DL1 [1] output from the first data driver IC 310 and the first data line driving signal DL2 [output of the second data driver IC 320 are output. 1]) polarities are reversed.

FIG. 3 is a detailed block diagram illustrating the data driver IC shown in FIG. 1. The first data driver IC 310 may include a DIO generator 311, an inversion driver 312, a data register 313, a latch 314, a level shifter 315, a digital-to-analog converter 316, and an output. It consists of a buffer 317.

The DIO generator 311 receives the first operation start signal DIO1 from the timing controller 200 and outputs a second operation start signal DIO2 to the second data driver IC 320. In this case, the DIO generator 311 adjusts the pulse width of the input first operation start signal DIO1 and the pulse width of the output second operation start signal DIO2 to be different from each other.

The inversion driver 312 converts the polarity signal REV input from the timing controller 200 into an internal polarity signal according to the pulse width of the first operation start signal DIO1 to control the polarity of the liquid crystal applied voltage. For example, if the pulse width of the first operation start signal DIO1 is equal to one clock period, the inversion driver 312 may have an internal polarity signal having the same polarity as the polarity signal REV input from the timing controller 200. (IREV) is generated and controlled to output a positive liquid crystal applied voltage as the first data line driving signal DL1 [1].

The data register 313 sequentially stores and stores R, G, and B data Data of predetermined bits input from the timing controller 200 in response to the first operation start signal DIO1. The latch 314 stores the R, G, and B data sequentially stored in the data register 313 line by line according to the internal polarity signal IREV output from the inversion driver 312. The level shifter 315 shifts the R, G, and B data to a high level signal since the next stage of the level shifter 315 is a high voltage operation portion. The digital-analog converter 316 converts digital data into analog voltage values. The output buffer 317 receives the converted analog voltage value and outputs data line driving signals DL1 [1: i] to DLn [1: i].

4 is a waveform diagram showing signals of a data driver IC for square inversion driving. Since the pulse width of the first operation start signal DIO1 input to the first data driver IC 310 is equal to one clock period, the inversion driver 312 of the first data driver IC 310 may have a polarity signal REV. The internal polarity signal IREV (DD1) having the same polarity as that of the control signal is generated, and the liquid crystal applied voltage of the positive value (+) is output as the first data line driving signal DL1 [1]. In addition, since the pulse width of the first operation start signal DIO1 is equal to one clock period, the DIO generation unit 311 of the first data driver IC 310 may output the pulse width of the output second operation start signal DIO2. Is generated to be two clock cycles.

Since the pulse width of the second operation start signal DIO2 input to the second data driver IC 320 is equal to two clock cycles, the inversion driver 312 of the second data driver IC 320 generates the polarity signal REV. An internal polarity signal IREV (DD2) having a polarity opposite to that of the control signal is generated and controlled to output a liquid crystal applied voltage having a negative value (−) as the first data line driving signal DL2 [1]. In addition, since the pulse width of the second operation start signal DIO2 is equal to two clock cycles, the DIO generation unit 311 of the second data driver IC 320 outputs the pulse width of the third operation start signal DIO3 that is output. Is generated to be one clock cycle.

As described above, the operation start signal DIO having different pulse widths applied to the data driver ICs 310 to 3n0 may be a selection signal for the liquid crystal display 10 to perform the square inversion driving. That is, since the voltage output from the even-numbered data driver IC and the voltage output from the odd-numbered data driver IC have opposite polarities with each other using the operation start signal DIO, the liquid crystal display 10 may perform square inversion driving. It becomes possible. Therefore, since a separate signal line for square inversion driving does not need to be provided, the circuit configuration of the liquid crystal display device 10 is not complicated.

On the other hand, the characteristics of the present invention is a flat display device having a driving method similar to the liquid crystal display device, for example, electrochromic display (ECD), Digital Mirror Device (DMD), Actuated Mirror Device (AMD), Grating Light (GLV) Value (PDP), Plasma Display Panel (PDP), Electro Luminescent Display (ELD), Light Emitting Diode (LED) display, VFD (Vacuum Fluorescent Display). The liquid crystal display device to which the present invention is applied may be applied to a large screen TV, a high definition television (HDTV), a portable computer, a camcorder, an automotive display, an information communication multimedia, and a virtual reality field.

As described above, an optimal embodiment has been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

According to the present invention as described above, since the square inversion driving can be applied to the liquid crystal display without additional signal line, there is an effect of reducing the cost.

Claims (14)

panel; A timing controller configured to output an operation start signal; And A driving unit configured to receive the operation start signal and drive the panel; The driving unit includes a plurality of data driver chips, wherein each data driver chip generates an output operation start signal having a pulse width different from a pulse width of the operation start signal input from a previous data driver chip. Device. The method of claim 1, And a first data driver chip of the plurality of data driver chips receives the operation start signal from the timing controller. The method of claim 1, And the output operation start signal is the operation start signal of a next data driver chip. The method of claim 3, wherein And the operation start signal is a control signal for enabling the operation of each data driver chip. The method of claim 4, wherein And when the pulse width of the operation start signal input to the data driver chip is equal to one clock period, the data driver chip generates the output operation start signal with a pulse width equal to two clock cycles. The method of claim 5, And when the pulse width of the operation start signal input to the data driver chip is equal to two clock cycles, the data driver chip generates the output operation start signal having a pulse width equal to one clock cycle. The method of claim 6, And the timing controller outputs a polarity signal to each of the data driver chips. The method of claim 7, wherein And the data driver chip generates an internal polarity signal inverting or non-inverting the polarity signal according to the pulse width of the operation start signal. The method of claim 8, And the internal polarity signal controls a polarity of a voltage applied from the data driver chip to the panel. The method of claim 9, Each data driver chip, A DIO generator configured to receive the operation start signal and generate the output operation start signal; And And an inversion driver configured to generate the internal polarity signal. In the driving method of a display device including a panel and a plurality of data driver chips, Receiving a polarity signal; Receiving an operation start signal from a previous data driver chip; Generating an internal polarity signal inverting or non-inverting the polarity signal according to the pulse width of the operation start signal; Controlling the polarity of the voltage applied from the data driver chip to the panel according to the internal polarity signal; And And generating an output operation start signal having a pulse width that is different from the pulse width of the operation start signal. The method of claim 11, And the output operation start signal is the operation start signal of a next data driver chip. The method of claim 11, When the pulse width of the operation start signal input to the data driver chip is equal to one clock period, the data driver chip generates the output operation start signal with a pulse width equal to two clock cycles. Driving method. The method of claim 13, And if the pulse width of the operation start signal input to the data driver chip is equal to two clock cycles, the data driver chip generates the output operation start signal with a pulse width equal to one clock cycle. Driving method.

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