KR100809713B1 - Driving device for display driver ic enduring electrical static discharge - Google Patents

Abstract

A device for driving a display driver IC enduring electrical static discharge is provided to prevent an error due to the electrical static discharge by sharing an inverting signal with plural display driver ICs(Integrated Circuit). A device for driving a DDI(Display Driver Integrated circuit) includes first and second DDIs(210,220), and first and second inverting units(214,224). The first and second DDIs include first and second inverting units which output first and second inverting signals for preventing the deterioration of an LCD(Liquid Crystal Display) device, and first and second selection units, respectively. When the first DDI is selected as a master, the first and second selection units share the first inverting signal. When the second DDI is selected as the master, the first and second selection units share the second inverting signal.

Description

DVD driving device resistant to ESD {Driving device for Display driver IC enduring electrical static discharge}

BRIEF DESCRIPTION OF THE DRAWINGS In order to more fully understand the drawings recited in the detailed description of the invention, a brief description of each drawing is provided.

1 shows an inversion operation state by a conventional two-chip DDI (Display Driver IC) driving device.

2A is a diagram illustrating an embodiment of a DDI driving apparatus according to the present invention.

2B is a view showing another embodiment of a DDI driving apparatus according to the present invention.

3 is a timing diagram of signals used in the DDI driving apparatus according to the present invention.

The present invention relates to a display driver IC (DDI) driving device for driving a display panel, and more particularly to a display driver IC (DDI) driving device resistant to electrical static discharge (ESD).

In recent years, display devices such as personal computers and televisions have been required to be lighter and thinner, and in order to satisfy such demands, liquid crystal displays (LCDs) instead of cathode-ray tubes (CRTs) are required. Flat panel display devices such as displays have been developed and put into practical use in various fields.

The LCD receives red, green, and blue n-bit RGB data from an external graphic source. The RGB data is converted into a data format by a timing controller of the LCD, an analog gradation voltage suitable for RGB data is selected in DDI, and the display operation is performed by applying the selected gradation voltage to a pixel on the LCD. do.

In general, driving a liquid crystal display (LCD) using one-chip DDI is widely used. However, as the size of the LCD increases, the LCD may be driven using a two-chip DDI. In this case, two DDI chips perform the same function and are designated as masters or slaves, respectively. The LCD screen is divided into two, and the left side displays the image by the master IC and the right side by the slave IC, or the right side by the master IC and the left side by the slave IC.

As described above, when using the LCD device using the DDI, when the gray voltage of the same polarity is continuously applied to the pixels on the LCD, liquid crystals deteriorate in each pixel. As a method for preventing the deterioration of liquid crystals inside the LCD, a method of inverting the direction of the potential is generally used. Such inversion methods include one-line inversion or frame inversion. In addition, there is a method of mixing the above two methods, that is, inverting one line but inverting the frame every frame again.

This inversion operation is also used when driving an LCD using a two-chip DDI, and there is a problem in particular when an electric shock such as an electric static discharge (ESD) is received.

1 shows an inversion operation state by a conventional two-chip DDI driving apparatus.

The figure on the left shows the normal reverse operation. In the normal operation state, the entire image of every frame is displayed in the same inversion mode in the left and right two DDIs.

The figure on the right shows a case where an error occurs due to an electric shock such as ESD. When the polarity of the reference inversion signal, in which one of the two-chip DDIs determines the inversion mode, is changed due to an electric shock such as an ESD, a half of the screen may be inverted as shown in the right side. In this case, since the inversion state is not partially recovered and the error state persists, there is a problem that the entire system must be reset and initialized to solve the problem.

As one means for solving this problem, the present invention proposes that two DDIs share and use an inverted signal which is a reference for determining an inversion mode.

An object of the present invention is to provide an ESD-resistant display driver IC (DDI) driving device that can solve the problem of failure caused by the electrical shock, such as the ESD.

DDI driving apparatus according to an embodiment of the present invention for achieving the above technical problem, has a first DDI (Display Driver IC) and a second DDI,

The first DDI includes a first inversion signal generator and a first selection unit for generating a first inversion signal for preventing degradation of a liquid crystal display (LCD), and the second DDI prevents degradation of the LCD. And a second inverted signal generator and a second selector for generating a second inverted signal, wherein when the first DDI is selected as a master, the first selector and the second selector are configured as the first selector. The inverted signal is selected and shared, and when the second DDI is selected as a master, the first selecting means and the second selecting means select and share the second inverted signal.

Preferably, the first selecting means is a multiplexer.

Preferably, the second selecting means is a multiplexer.

When each of the first DDI or the second DDI is selected as a master, the first selecting means selects a first inverted signal, and the second selecting means selects a second inverted signal so that the first DDI and the second DDI are selected. 2 DDI can be driven independently.

Each of the first DDI or the second DDI may further include a timing controller for converting a format of a signal applied to the LCD.

The DDI driving apparatus according to the present invention includes a master DDI generating an inversion signal for preventing degradation of the LCD and a slave DDI receiving the inversion signal and sharing it with the master DDI as a signal for preventing the degradation.

Therefore, in the present invention, since the DDI driving apparatus shares and uses an inverted signal that is a reference for determining the inversion mode, the DDI driving apparatus can solve the problem that an error occurs due to an electric shock such as ESD. Can be.

DETAILED DESCRIPTION In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings that describe exemplary embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

2A is a diagram illustrating an embodiment of a DDI driving apparatus according to the present invention.

Referring to FIG. 2A, the DDI driving apparatus according to the present invention includes a first DDI 210 and a second DDI 220. The first DDI 210 includes a first inversion signal generator 212 and first selection means 214. The second DDI 220 includes a second inverted signal generator 222 and second selection means 224. The first DDI 210 may further include a flip-flop 216 and a timing controller 218. The second DDI 220 may further include a flip-flop 226 and a timing controller 228.

In the DDI driving apparatus of FIG. 2A, the first DDI 210 on the left side is configured as a master chip. The second DDI 220 on the right side is configured as a slave chip.

The first inversion signal generator 212 generates an inversion signal used in an inversion mode for preventing degradation of the LCD (not shown).

The first selecting means 214 selects and outputs the inverted signal generated by the first inverted signal generator 212. The inverted signal BASE_INV output from the first selecting means 214 is applied to the flip-flop 216 in the first DDI 210 and the second selecting means 224 in the second DDI 220. In general, the first selecting means 214 is composed of a multiplexer.

The inversion signal BASE_INV output from the first selecting means is applied to the timing controller 218 via the flip-flop 216.

The timing controller 218 converts the format of the signal applied to the LCD (not shown) based on the inverted signal BASE_INV applied.

The second inversion signal generator 222 generates an inversion signal used in the inversion mode for preventing degradation, but the second selection means 224 does not select the inversion signal.

The second selecting means 224 selects the inverted signal BASE_INV output from the first selecting means 214 and outputs the inverted signal BASE_INV to the flip-flop 226 in the second DDI 220. In general, the second selecting means 224 is composed of a multiplexer.

The inversion signal BASE_INV output from the second selecting means is applied to the timing controller 228 via the flip-flop 226.

The timing controller 228 in the second DDI 220 converts a format of a signal applied to the LCD (not shown) based on the inversion signal BASE_INV applied.

As such, when the first DDI 210 is selected as the master, the first selecting means 214 and the second selecting means 224 select the inverted signal BASE_INV output from the first inverted signal generator 212. Share.

2B is a view showing another embodiment of a DDI driving apparatus according to the present invention.

2B, the DDI driving apparatus according to the present invention includes a first DDI 230 and a second DDI 240. The first DDI 230 includes a first inverted signal generator 232 and a first selector 234. The second DDI 240 includes a second inverted signal generator 242 and second selection means 244. The first DDI 230 may further include a flip-flop 236 and a timing controller 238. The second DDI 240 may further include a flip-flop 246 and a timing controller 248.

In the DDI driving apparatus according to the present invention of FIG. 2B, unlike FIG. 2A, the first DDI 230 on the left is configured as a slave chip, and the second DDI 240 on the right is configured as a master chip.

The second inversion signal generator 242 generates an inversion signal used in an inversion mode for preventing degradation of the LCD (not shown).

The second selecting means 244 selects and outputs the inverted signal generated by the second inverted signal generator 242. The inverted signal BASE_INV output from the second selecting means 244 is applied to the flip-flop 246 in the second DDI 240 and the first selecting means 234 in the first DDI 230. In general, the second selecting means 244 is composed of a multiplexer.

The inversion signal BASE_INV output from the second selecting means is applied to the timing controller 248 via the flip-flop 246.

The timing controller 248 converts the format of the signal applied to the LCD (not shown) based on the inversion signal BASE_INV applied.

The first inversion signal generator 232 generates an inversion signal used in the inversion mode for preventing degradation, but the first selection means 234 does not select the inversion signal.

The first selecting means 234 selects the inverted signal BASE_INV output from the second selecting means 244 and outputs the inverted signal BASE_INV to the flip-flop 236 in the first DDI 230. In general, the first selecting means 234 is composed of a multiplexer.

The inversion signal BASE_INV output from the first selecting means 234 is applied to the timing controller 238 via the flip-flop 236.

The timing controller 238 in the first DDI 230 converts a format of a signal applied to the LCD (not shown) based on the inversion signal BASE_INV applied.

As such, when the second DDI 240 is selected as the master, the second selecting means 244 and the first selecting means 234 select the inverted signal BASE_INV output from the second inverted signal generator 242. Share.

2A and 2B, when the first DDI and the second DDI share the inverted signal BASE_INV, which is a reference, an error is generated through an electric shock such as ESD even in the inversion mode for preventing degradation of the LCD. You can solve the problem.

In addition, unlike FIG. 2A and FIG. 2B, the first DDI or the second DDI may be configured independently. That is, when the first DDI or the second DDI is selected as the master, the first selecting means selects the output inverted signal of the first inverted signal generator, and the second selecting means independently outputs the output signal of the second inverted signal generator. It can be configured to select.

3 is a timing diagram of signals used in the DDI driving apparatus according to the present invention.

The inverted signal BASE_INV as a reference is a signal shared by the first DDI and the second DDI. Conventionally, the inverted signal is generated and used separately in each DDI, but in the present invention, the error is not generated even through the electric shock such as ESD by sharing it.

The clock signal CLK is generally used in the DDI driver.

The gradation voltage of the master DDI is determined by the reference voltage VCOM @ Master and the source signal SOURCE @ Master. The inversion operation is performed by applying the determined gray voltage to the pixel on the LCD which the master DDI is responsible to prevent degradation.

The gray voltage of the slave DDI is determined by the reference voltage VCOM @ Slave and the source signal SOURCE @ Slave. The inversion operation is performed by applying the determined gray voltage to the pixels on the LCD in charge of the slave DDI to prevent degradation.

That is, the DDI driving apparatus according to the present invention receives a master DDI (Display Driver IC) for generating an inverted signal to prevent degradation of a liquid crystal display (LCD) and the inverted signal and shares it as a signal for preventing degradation. It is equipped with a slave DDI to be used so that an error does not occur even through an electric shock such as an ESD.

In the above described the present invention with reference to the specific embodiment shown in the drawings, but this is only an example, those of ordinary skill in the art to which the present invention pertains various modifications and variations therefrom. Therefore, the protection scope of the present invention should be interpreted by the claims to be described later, and all technical ideas within the equivalent and equivalent ranges should be construed as being included in the protection scope of the present invention.

As described above, since the DDI driving apparatus of the present invention shares and uses the inverted signal, which is a reference for determining the inversion mode, the DDI driving apparatus has an effect of solving an error caused by an electric shock such as ESD. have.

Claims (6)

A first display driver IC (DDI); And Having a second DDI, The first DDI includes a first inversion signal generator and first selection means for generating a first inversion signal for preventing deterioration of a liquid crystal display (LCD), The second DDI includes a second inversion signal generator and second selection means for generating a second inversion signal for preventing degradation of the LCD. The first selecting means and the second selecting means select and share the first inverted signal when the first DDI is selected as the master, and the first selecting means when the second DDI is selected as the master. And the second selecting means select and share the second inverted signal. The method of claim 1, wherein the first selection means, DDI driver characterized in that the multiplexer (Multiplexer). The method of claim 1, wherein the second selection means, DDI drive characterized in that the multiplexer. The method of claim 1, wherein the first DDI or the second DDI, In the case where each is selected as a master, the first selecting means selects the first inverted signal, and the second selecting means selects the second inverted signal to independently drive the first DDI and the second DDI. DDI drive. The method of claim 1, wherein the first DDI or the second DDI, And a timing controller for converting a format of a signal applied to the LCD, respectively. A master display driver IC (DDI) for generating an inverted signal for preventing deterioration of a liquid crystal display (LCD); And And a slave DDI shared with a master DDI as a signal for receiving the inversion signal and preventing the deterioration thereof.

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