KR20100071702A - Common voltage generation circuit unit and common voltage generation method for electrophoresis display device - Google Patents

Abstract

PURPOSE: A circuit unit and a method for generating a common voltage for an electrophoresis display device are provided to simplify manufacturing processes by automatically measuring and correcting the variation of the common voltage. CONSTITUTION: The common electrode of a display panel applies an offset variation voltage which is varied according to a kickback phenomenon to an input buffer(110). An analog to digital converter(120) outputs a first digital data which is corresponds to the offset variation voltage. A common voltage data provider(130) provides a second digital data for generating a common voltage in which the offset variation voltage is corrected. A digital to analog converter(140) generates a voltage which corresponds to the second digital data. An output buffer(150) provides the voltage from the digital to analog converter to the common electrode as a common voltage.

Description

Common voltage generation circuit unit and common voltage generation method for electrophoresis display device}

The present invention relates to a common voltage generation circuit for an electrophoretic display device and a common voltage generation method thereof, and more particularly, to an electrophoretic display device capable of automatically measuring and compensating a common voltage fluctuation caused by the application of a gate driving signal. A common voltage generation circuit and a common voltage generation method thereof.

Recently introduced electrophoresis display devices are much cheaper to produce than conventional flat panel displays, and require no additional backlighting, and can be driven with very little energy. Most importantly, it exhibits features that can bend repeatedly like paper without changing resolution and contrast.

Therefore, it is currently applied to portable computers, electronic newspapers or smart cards, and is expected to be a next-generation display device that will widely replace traditional printing media such as books, newspapers and magazines in the near future.

The driving principle of such an electrophoretic display device is to use a system according to the electrophoretic state of the electronic ink. That is, the electron ink is configured by immersing charged particles so as to float in a predetermined fluid, and then artificially electrophores the particles by applying an electric field, thereby expressing two contrast levels of black and white, for example.

Hereinafter, an example of a display medium using an electrophoretic method will be described with reference to the drawings.

1 is a view illustrating a driving principle of a general electrophoretic display device.

As shown, the ink in the form of a capsule 44 of the charged particles (40a, 40b) through the condensation polymerization reaction is used as the charge layer 46, and on one side and the other side of the charged layer 46, respectively Electrodes 48 and 50 are constructed.

In this case, the electrode on one side is partially patterned, and is a pixel electrode 48 having a (+) or (-) polarity by the data voltage, and the other electrode is formed on the entire surface of the substrate to have a common voltage of a fixed voltage level ( Vcom) is applied to the common electrode 50.

In general, as an example for manufacturing the charge layer 46 as described above, indium-tin-oxide (ITO), which is a white dye, and carbon, which is a black dye, are dispersed. Encapsulate through condensation polymerization.

At this time, since the size of the capsule 44 including the black die 40a and the white die 40b is not constant, only the capsule 44 having a predetermined size is selected and used through a filtering operation.

When a data voltage having positive (+) or negative (-) is applied to the charged layer 46 manufactured as described above through the pixel electrode 48, the charged black die and white in the capsule 44 are applied. Dies 40a and 40b are moved.

In this case, black is displayed when the black die 40b moves upward, and white is displayed when the white die 40a moves upward.

However, the electrophoretic display device operated in the same manner as described above may fix the common voltage Vcom applied to the common electrode 50 to a predetermined voltage and apply a data voltage to the pixel electrode 48 to display an image. That's the way.

FIG. 2 is a view for explaining a method of generating a common voltage Vcom in an electrophoretic display device according to the related art. Configure

The pixel unit 60 represents an equivalent circuit for one pixel, representing a plurality of display pixels of a display panel, and includes a switching thin film transistor S-TFT connected to a gate line GL and a data line DL; It consists of an electrophoretic capacitor (EPC) and a storage capacitor (Cst).

In addition, the common voltage generator 70 configures a variable resistor Rv and a buffer 72 to generate the common voltage Vcom provided to the pixel unit 60. Through the operation, the voltage level of the common voltage Vcom can be changed as necessary.

However, the electrophoretic display device displaying an image through the above-described configuration has a parasitic capacitance Cp of the switching thin film transistor S-TFT when a gate driving signal applied to the gate line GL is applied. A kickback phenomenon occurs in which the potential of the common voltage Vcom is changed. Usually, an offset offset voltage of the common voltage Vcom that is changed by the gate driving signal swinging with a voltage difference of + 22V to -20V. "The level is about -2V ~ -1V, and when the electrophoretic display device is manufactured to improve the kickback phenomenon as described below, the method is as follows.

First, the pixel unit 60 and the common voltage generator 70 are electrically disconnected by using a switch SW configured between the pixel unit 60 and the common voltage generator 70.

Next, the data line DL applies a predetermined data voltage (generally 0V) to fix the potential, and then applies a gate driving signal to the gate line GL to separate the voltage output to the buffer 80. Measure with the measuring instrument of. In this case, the buffer 80 may be the same circuit as the buffer 72 configured in the common voltage generator 70.

According to this method, since the common electrode of the pixel unit 60 to which the common voltage Vcom is applied is in a floating state due to disconnection through the switch SW, the parasitic capacitance when the gate driving signal is applied. The voltage shaken at the common electrode by Cp, that is, the "offset variation voltage", can be measured by the measuring device through the buffer 80, and then the operator adjusts the variable resistance Rv to the kickback voltage. The common voltage Vcom on which the compensation is performed is output again.

However, the common voltage generation method performed in this manner has the following problems.

First, the operator must directly measure and record the offset variable voltage output through the buffer 80, and second, the adjustment of the variable resistor Rv also has to be performed manually by the operator. The manual process not only lengthens the manufacturing process, but sometimes requires more than two people.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a common voltage generation circuit for an electrophoretic display device that can shorten the manufacturing process time and reduce manpower costs.

In order to achieve the above object, the present invention includes an input buffer to which an offset variable voltage that is varied according to a kickback phenomenon is applied from a common electrode of a display panel; An analog-digital converter configured to output first digital data corresponding to the offset voltage change; A common voltage data providing unit providing second digital data for generating a common voltage compensated for the offset variation voltage corresponding to the first digital data; A digital-analog converter for generating and outputting a voltage corresponding to the second digital data; An output buffer providing the common electrode with the voltage generated by the digital-analog converter as a common voltage; A common voltage generation circuit for an electrophoretic display device includes a switch for controlling an electrical circuit connection between the common electrode and the output buffer.

In the common voltage generation circuit, the input buffer and the output buffer are characterized in that the same circuit.

In the common voltage generation circuit, the common voltage data providing unit may further include a lookup table in which the second digital data corresponding to the first digital data is stored.

In the common voltage generation circuit, the common voltage data providing unit is a memory device.

The present invention also provides an electrophoretic display comprising a switching thin film transistor having a gate line and a data line, connected to the gate line and a data line, and an electrophoretic capacitor connected to the switching thin film transistor and having a pixel electrode and a common electrode. A common voltage generation method in a common voltage generation circuit constituted in an apparatus,

A first step of detecting an offset variation voltage that is changed from the common electrode according to a kickback phenomenon; Outputting first digital data corresponding to the offset change voltage; Outputting second digital data for generating a common voltage compensated for the offset variation voltage corresponding to the first digital data; A common voltage generation method of a common voltage generation circuit for an electrophoretic display device includes a fourth step of generating a common voltage corresponding to the second digital data and outputting the common voltage to the common electrode.

In the common voltage generation method, the first step includes: shorting an electrical circuit connection between the common electrode and the common voltage generation circuit; Fixing the data line to an arbitrary data voltage and applying a gate driving signal to the gate line; The method may further include receiving an offset change voltage generated at the common electrode by the gate driving signal.

In the common voltage generation method, the arbitrary data voltage is 0V.

In the common voltage generation method, the third step includes: setting first digital data according to the offset change voltage; Setting second digital data with respect to the common voltage whose compensation voltage is compensated for; The method may further include determining and outputting the second digital data corresponding to the first digital data.

In the common voltage generation method, the fourth step may further include performing electrical connection when the common electrode and the common voltage generation circuit are electrically shorted.

According to the present invention having the above characteristics, a separate manpower is not required for the common voltage correction in the automatically performed electrophoretic display device, and thus, the manufacturing process time and the manpower cost can be reduced, thereby improving the product competitiveness. have.

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

3 is a block diagram showing the configuration of a common voltage generation circuit 100 for an electrophoretic display device according to the present invention. The input buffer 110, the analog-to-digital conversion unit 120, the common voltage data storage unit ( 130, the digital-analog converter 140, the output buffer 150, and the switch SW.

In detail, the input buffer 110 is a buffer circuit that outputs the offset variation voltage Vk input from the pixel portion by the kickback phenomenon from the common electrode of the electrophoretic display panel having the pixel portion. It may be the same circuit as the buffer 72 of FIG.

At this time, the pixel unit, as in the configuration of the pixel unit 60 of FIG. 2, the switching thin film transistor S-TFT connected to the gate line GL and the data line DL, the electrophoretic capacitor EPC, and the storage capacitor. (Cst), the electrophoretic capacitor (EPC) is a common voltage (Vcom) from the pixel electrode and the common voltage generation circuit 100, the data voltage is input through the switching thin film transistor (S-TFT) The input common electrode is provided.

The analog-to-digital converter 120 is an analog-digital converter (ADC) circuit, and includes first digital data D1 composed of digital codes corresponding to the offset variation voltage Vk transmitted from the input buffer 110. Outputs

The common voltage data storage unit 130 receives the first digital data D1 and selects and outputs the second digital data D2 corresponding thereto, wherein the second digital data D2 is the offset. In order to generate the common voltage Vcom with the variable voltage Vk compensated, the common voltage Vcom calculated in advance by the designer in consideration of the offset variation voltage Vk input to the first digital data D1 through experiments or the like. ) Can be generated by the digital-to-analog converter 140 to be described later.

In this case, the first digital data D1 and the second digital data D2 corresponding to the first digital data D1 are created and stored as a look-up table, and the common voltage data is stored therein. The unit 130 uses a memory device.

The digital-analog converter 140 is a digital-analog converter (DAC) for generating an analog voltage corresponding to the second digital data D2 transferred from the common voltage data storage unit 130. The voltage output from the digital-analog converter 140 is a common voltage Vcom with the offset variation voltage Vk compensated.

Thereafter, the common voltage Vcom generated by the digital-analog converter 140 is applied to the common electrode of the electrophoretic display panel through the output buffer 150. In this case, the output buffer 150 may be the same circuit as the input buffer 110.

The switch SW is a component for controlling an electrical circuit connection between the common electrode of the electrophoretic display panel and the output buffer 150. For example, the switch SW has an offset variable voltage through the input buffer 110. The switch SW is switched to a short state when Vk) is input, and is switched to a connected state when the common voltage Vcom is output through the output buffer 150.

Hereinafter, a common voltage generation method of the common voltage generation circuit 100 for an electrophoretic display device according to the present invention will be described with reference to the operation flowcharts of FIGS. 4 to 6.

Referring to FIG. 4, the common voltage generation circuit 100 receives an offset shift voltage Vk generated by a kickback phenomenon from a common electrode of an electrophoretic display panel to generate a common voltage Vcom. )

At this time, the "offset variation voltage (Vk)" is a parasitic capacitance of the switching thin film transistor (S-TFT) when a gate driving signal is applied to the gate line (GL), which is usually changed from + 22V to -20V. A common voltage fluctuation due to a kickback phenomenon in which the potential of the common voltage Vcom applied by Cp is changed.

This first step st1 will be described in more detail with reference to FIGS. 3 and 5.

First, in order to measure the offset variation voltage Vk, the switch SW is switched to an off-switching state so that the common electrode of the electrophoretic display panel and the common voltage generation circuit 100 are placed in an electrical short circuit state. Switch to (st1-1)

Next, an arbitrary data voltage, preferably 0V, is applied to the data line DL, and a gate driving signal is applied to the gate line GL. (St1-2) As shown in the above example, the gate driving signal is + 22V. The potential of the common electrode is shaken by the parasitic capacitance (Cp in FIG. 2) when the voltage level is rapidly changed from the high level to the low level of -20V. At this time, since the data voltage is 0V, The fluctuation voltage is detected as an offset fluctuation voltage Vk as it is and input to the input buffer 110. (st1-3)

4, the input buffer 110 outputs the offset change voltage Vk to the analog-digital converter 120, and the analog-digital converter 120 outputs the offset. A digital code corresponding to the variable voltage Vk, that is, the first digital data D1 is output. (St2)

The output first digital data D1 is transferred to the common voltage data providing unit 130, and the common voltage data providing unit 130 corresponds to the first digital data D1 in a stored lookup table. The second digital data D2 is output. (St3)

At this time, the third step (st3), referring to Figure 6, the designer sets a plurality of first digital data that can be input from the analog-to-digital converter 120 to store in the look-up table (st3- 1) Also, the designer calculates in advance the common voltage Vcom in which the offset variation voltage Vk is compensated in consideration of the offset variation voltage Vk inputted to the first digital data D1 through experiments, which will be described later. The digital-analog converter 140 sets a plurality of second digital data D2 for generating the target common voltage Vcom and stores the plurality of second digital data D2 in the lookup table. (St3-2)

When the first digital data D1 is input, the common voltage data providing unit 130 determines and outputs the second digital data D2 corresponding to the first digital data D1 input from the lookup table. . (st3-3)

Referring to FIG. 4 again, the second digital data D2 output as described above is input to the digital-analog converter 140 and finally the common voltage Vcom having the offset variation voltage Vk compensated. Generated (st4)

Of course, the common voltage Vcom output from the digital-analog converter 140 is applied to the common electrode of the electrophoretic display panel through the output buffer 150 and the common voltage (Vcom) through the output buffer 150. In order to output Vcom, the switch SW switches the common electrode of the electrophoretic display panel and the common voltage generation circuit 100 into an electrical circuit connection state.

1 is a view for explaining the driving principle of a general electrophoretic display device

2 is a view for explaining a common voltage (Vcom) generating method in the electrophoretic display device according to the prior art

3 is a block diagram showing the configuration of a common voltage generation circuit 100 for an electrophoretic display device according to the present invention.

4 to 6 are flowcharts illustrating a common voltage generation method of the common voltage generation circuit 100 for an electrophoretic display device according to the present invention, respectively.

<Brief description of the main parts of the drawing>

100: common voltage generation circuit 110: input buffer

120: analog-digital conversion unit 130: common voltage data providing unit

140: digital-to-analog converter 150: output buffer

SW: switch

Claims (9)

An input buffer to which an offset variable voltage that is varied according to a kickback phenomenon is applied from a common electrode of the display panel; An analog-digital converter configured to output first digital data corresponding to the offset voltage change; A common voltage data providing unit providing second digital data for generating a common voltage compensated for the offset variation voltage corresponding to the first digital data; A digital-analog converter for generating and outputting a voltage corresponding to the second digital data; An output buffer providing the common electrode with the voltage generated by the digital-analog converter as a common voltage; A switch for controlling an electrical circuit connection between the common electrode and the output buffer Common voltage generation circuit for electrophoretic display including The method according to claim 1, The input buffer and the output buffer common voltage generation circuit for an electrophoretic display device, characterized in that the same circuit The method according to claim 1, The look-up table in which the common voltage data providing unit stores the second digital data corresponding to the first digital data. Common voltage generation circuit for electrophoretic display further comprising The method according to claim 1, The common voltage data providing unit is a common voltage generation circuit for an electrophoretic display device, characterized in that the memory device. A common configuration of an electrophoretic display device including a gate line and a data line, a switching thin film transistor connected to the gate line and a data line, and an electrophoretic capacitor connected to the switching thin film transistor and having a pixel electrode and a common electrode. As a common voltage generation method in a voltage generation circuit, A first step of detecting an offset variation voltage that is changed from the common electrode according to a kickback phenomenon; Outputting first digital data corresponding to the offset change voltage; A third step of outputting second digital data for generating a common voltage compensated for the offset variation voltage corresponding to the first digital data; A fourth step of generating a common voltage corresponding to the second digital data and outputting the common voltage to the common electrode Common voltage generation method of the common voltage generation circuit for electrophoretic display including The method according to claim 5, The first step, Shorting an electrical circuit connection between the common electrode and the common voltage generation circuit; Fixing the data line to an arbitrary data voltage and applying a gate driving signal to the gate line; Receiving an offset change voltage generated at the common electrode by the gate driving signal; Common voltage generation method of the common voltage generation circuit for an electrophoretic display device further comprising The method of claim 6, The common voltage generation method of the common voltage generation circuit for an electrophoretic display device, characterized in that the arbitrary data voltage is 0V. The method according to claim 5, The third step, Setting first digital data according to the offset voltage; Setting second digital data with respect to the common voltage whose compensation voltage is compensated for; Determining and outputting the second digital data corresponding to the first digital data Common voltage generation method of the common voltage generation circuit for an electrophoretic display device further comprising The method according to claim 5, The fourth step, Performing electrical connection when the common electrode and the common voltage generation circuit are electrically shorted. Common voltage generation method of the common voltage generation circuit for an electrophoretic display device further comprising

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