KR20140015040A - Electrophoresis display device and method for driving the same - Google Patents

Abstract

The present invention relates to an electrophoresis display device and a driving method thereof which are capable of reducing flashing when a screen is converted, and are capable of reducing an update time of a screen image. The driving method of an electrophoresis display device according to an embodiment of the present invention comprises: a step of forming a potential difference as great as a first data voltage between a first data line and a second data line by supplying the first data voltage to the first data line and supplying a common voltage or a ground voltage to the second data line which is connected to a source of a TFT within a first period for resetting the previous image; a step of forming a potential difference which corresponds to the two times of the first data voltage or the second data voltage by supplying the second data voltage which has an opposite polarity of the polarity of the first data voltage which is supplied during the first period and connecting the second data line to a high-impedance terminal; and a step of resetting the previous image by supplying a data voltage which corresponds to the two times of the first data voltage or the second data voltage by turning on the TFT.

Description

ELECTROPHORESIS DISPLAY DEVICE AND METHOD FOR DRIVING THE SAME [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrophoretic display device, and more particularly, to an electrophoretic display device and a driving method thereof capable of reducing flashing when switching screens and reducing an update time of an image.

An electrophoretic display device refers to an apparatus that displays an image using an electrophoresis phenomenon in which colored charged particles move by an electric field applied from the outside. Here, the electrophoresis phenomenon means that the charged particles move in the solvent by the Coulomb force when an electric field is applied while the charged particles are dispersed in the solvent.

The electrophoretic display apparatus using the electrophoretic phenomenon has a feature of bistable, and even if the applied voltage is removed, the displayed image can be displayed for a long time. That is, the electrophoretic display device is a display device suitable for the field of e-books that do not require a rapid exchange of the screen because it can maintain a constant screen for a long time even without applying a voltage continuously.

The electrophoretic display device is not only dependent on the viewing angle, but also reflects external light to display an image, thereby providing a comfortable image to the eye as much as paper.

1 is a view schematically showing a electrophoretic display device according to the prior art, Figure 2 is a view showing a driving method of the electrophoretic display device according to the prior art.

1 and 2, the electrophoretic display device according to the related art includes an opposing lower substrate 10, an upper substrate 20, and an electrophoretic film 30.

In the lower substrate 10, a plurality of pixels is formed in a matrix form. In the plurality of pixels, a thin film transistor TFT is formed as a switching element, and a pixel electrode 12 for supplying a data voltage to the pixel is formed.

The upper substrate 20 is formed with a common electrode 22 for supplying a common voltage Vcom to a plurality of pixels.

The electrophoretic film 30 is interposed between the lower substrate 10 and the upper substrate 20, and includes a plurality of microcapsules 32 and an adhesive layer 34.

The plurality of microcapsules 32 include a plurality of charged particles and a solvent. Some of the charged particles are partially charged with positive (+) polarity, and some are charged with negative (-) polarity. For example, the black charged particles may be charged with negative polarity and the white charged particles may be charged with positive polarity.

The adhesive layer 34 protects the microcapsules 32 and adheres the electrophoretic film 30 to the lower substrate 10.

When an electric field is formed between the pixel electrode of the lower substrate 10 and the common electrode 22 of the upper substrate 20, the charged particles included in the microcapsule 32 move by electrophoresis to implement an image. .

Moving the white charged particles toward the upper substrate reflects light incident from the outside, and moving the black charged particles toward the upper substrate absorbs the light incident from the outside. As such, the image is displayed by absorbing or reflecting light incident from the outside through the charged particles mounted on the electrophoretic film.

Referring to FIG. 2, the electrophoretic display device cannot display a screen in units of frames, such as an LCD, because the screen switching is not fast due to the characteristics of bistable stability. Therefore, the image is displayed by supplying a data voltage using a wave form, which is a sequence of image data, and the image is switched from a previous image to a next image.

When switching the screen through image updating, the image of the previous image may remain in the next image due to the characteristics of bistable, so that the charged particles must be initialized by refreshing.

The reset period is composed of a white reset period and a black reset period. In the white reset period, the previous image is reset by supplying a data voltage so that the entire screen displays a white image for a plurality of subframes. In the black reset period, a data voltage is supplied so that the entire screen displays a black image during a plurality of subframes, thereby resetting the charged particles, that is, resetting the previous image. After the reset period, the pixels are updated to switch the image of the next image.

The electrophoretic display device according to the related art has a problem in that the viewer feels flickering of the screen by resetting the previous image by displaying the entire screen in black and white in the reset period.

In addition, there is a problem in that an image update time is long due to reset driving performed during a plurality of subframes.

On the other hand, if the reset of the previous image is omitted or the reset time is reduced in order to reduce the flicker of the screen, there is another problem in that the afterimage of the previous image remains until the next image and the display quality is deteriorated.

Disclosure of Invention The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an electrophoretic display device and a driving method thereof capable of reducing screen flickering when updating an image.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and an object thereof is to provide an electrophoretic display device and a driving method thereof capable of reducing an image update time.

Other features and advantages of the invention will be set forth in the description which follows, or may be obvious to those skilled in the art from the description and the claims.

In a method of driving an electrophoretic display device according to an exemplary embodiment of the present invention, a first data voltage is supplied to a first data line in a first period for resetting a previous image, and is applied to a second data line connected to a source of a TFT. Supplying a common voltage or a ground voltage to form a potential difference between the first data line and the second data line by the first data voltage; In a second period, a second data voltage opposite to the polarity of the first data voltage supplied in the first period is supplied to the first data line, and the second data line is connected to a high impedance terminal to connect the first data. Forming a potential difference corresponding to a voltage or twice the second data voltage between the second data line and the pixel; And turning on the TFT to supply a data voltage corresponding to twice the first data voltage or the second data voltage to the pixel to reset the previous image.

An electrophoretic display device according to an embodiment of the present invention includes n gate lines; M first data lines and m second data lines formed to intersect the n gate lines; A TFT formed for each of the plurality of pixels; A gate driver for supplying a scan signal to the gate of the TFT; A data driver for supplying a first data voltage to the first data line and for supplying a common voltage or a ground voltage to a second data line connected to a source of the TFT; A controller for supplying a waveform for updating the image to the data driver; And a switch that connects the second data line to a common voltage output or ground terminal of the data driver, or connects the second data line to a high impedance terminal.

An electrophoretic display device and a driving method thereof according to an embodiment of the present invention can reduce flicker of a screen when an image is updated.

An electrophoretic display device and a driving method thereof according to an embodiment of the present invention can reduce an image update time.

The electrophoretic display device and the driving method thereof according to the embodiment of the present invention can improve the display quality by eliminating the afterimage of the previous image.

Other features and effects of the present invention may be newly understood through the embodiments of the present invention in addition to the features and effects of the present invention mentioned above.

1 is a view schematically showing an electrophoretic display device according to the prior art.
2 is a view showing a method of driving an electrophoretic display device according to the prior art.
3 is a view showing an electrophoretic display device according to an embodiment of the present invention.
4 is a diagram illustrating a lower substrate structure of a display panel.
5 is a diagram illustrating a structure of a display panel and a connection structure of a display panel and a driving circuit unit according to a first embodiment;
6 shows a display panel of an internalization type;
7 to 9 are diagrams showing a method of driving an electrophoretic display device according to a first embodiment of the present invention.
10 is a view showing the effect of applying the electrophoretic display device and its driving method according to an embodiment of the present invention.
11 is a diagram illustrating a structure of a display panel and a connection structure of a display panel and a driving circuit unit according to a second embodiment;
12 is a view illustrating a structure of a display panel and a connection structure of a display panel and a driving circuit unit according to a third embodiment;
13 to 15 are views showing a method of driving an electrophoretic display device according to a second embodiment of the present invention.

Hereinafter, an electrophoretic display device and a driving method thereof according to an embodiment of the present invention will be described with reference to the accompanying drawings. Like reference numerals throughout the specification denote substantially identical components. In the following description, detailed descriptions of configurations and functions known in the art and not related to the core configuration of the present invention may be omitted.

3 is a view showing an electrophoretic display device according to an embodiment of the present invention, Figure 4 is a view showing the lower substrate structure of the display panel.

3 and 4, an electrophoretic display (EPD) device according to an embodiment of the present invention includes a display panel 100 and a gate driver 200; A data driver 300; A controller 400, a power unit 500, and a memory 600.

The display panel 100 displays an image according to an inputted data voltage, and an electrophoresis layer is formed between the lower substrate and the upper substrate.

Here, as shown in FIG. 5, the electrophoretic layer may include an electrophoretic film 30 including a plurality of microcapsules on which charged particles and a solvent are mounted.

On the other hand, as shown in FIG. 6, partition walls 160 are formed to surround each of the pixel regions, and the charged particles 172 and the solvent (172) are filled in the filling space provided by the partition walls 160. An internalization type filled with the display solvent 170 configured as 174 may be applied.

In FIG. 6, a plastic substrate is applied to the lower base substrate 102, and the TFT 140 is formed as a bottom gate structure as an example. A gate insulating layer 104 is formed between the gate G and the active A, and a protective layer 106 is formed to cover the TFT 140.

In addition, in order to encapsulate the display solvent 170 filled in the filling space provided by the partition wall 160, a sealing layer 180 is formed on the partition wall 160. The upper substrate 190 includes a transparent upper base substrate 192 and a common electrode 194 formed on the upper base substrate 192.

4, n gate lines 120, m first data lines 130, and m second data lines 132 are formed on the lower substrate 110 of the display panel 100. have. The gate lines 120 are formed in the first direction, and the first data lines 130 and the second data lines 132 are formed in the second direction to intersect the gate line 120.

Although n gate lines and m data lines are formed in a display panel of a general electrophoretic display device, 2m data lines are formed in the display panel 100 of the present invention.

As illustrated in FIG. 5, the first data line 130 is connected to the first data voltage output unit 330 of the data driver 300. The second data line 132 is connected to the source S and the switch SW of the TFT 140.

Since the first data line 130 and the second data line 132 are formed adjacent to each other, parasitic capacitance is formed between the two lines 130 and 132. In the present invention, the parasitic capacitance formed between the first data line 130 and the second data line 132 is referred to as a first capacitor C1. In addition, a parasitic capacitance is formed between the second data line 132 and the pixel, which is referred to as a second capacitor C2 in the present invention.

According to the capacitance ratio of the first capacitor C1 and the second capacitor C2, the voltage value supplied to the pixel may vary. In the present invention, the capacitance ratio of the first capacitor C1 and the second capacitor C2 may be changed. 10: 1 and a voltage twice or three times the data voltage supplied from the data driver 300 may be supplied to the pixel.

When a voltage is applied to the first data line 130 and the second data line 132, the potential difference between the two lines 130 and 132 is charged in the first capacitor C1. By changing the voltage applied to the first data line 130 and the second data line 132 by using the characteristic of maintaining the potential difference charged in the first capacitor C1, the second data line 132 and the pixel are changed. The high voltage may be charged in the second capacitor C2 formed in the second capacitor C2.

When a scan pulse is applied to the gate of the TFT 140 and the TFT 140 is turned on, the high voltage charged in the second capacitor C2 may be supplied to the pixel electrode 150. Through this, the high voltage twice as high as the data voltage supplied from the data driver 130 can be supplied to the pixel, thereby reducing the reset time of the previous image.

The first data lines 130 and the second data lines 132 are formed on the display panel 100, and when the number of ICs of the data driver 300 is doubled, the data voltage supplied from the data driver 130 is increased. A higher voltage three times higher can be supplied to the pixel, further reducing the reset time of the previous image.

Here, the second data line 132 is connected to the common voltage output unit 310 or the high impedance (Hi-Z) terminal 320 of the data driver 300 by the switch SW. That is, the switch SW connects the second data line 132 to the common voltage output unit 310 so that the common voltage Vcom is applied, or the second data line 132 has a high impedance Hi-Z. ) To be connected to the terminal 320.

In this case, the switch SW is switched according to a control signal (CS) applied from the data driver 300 or the controller 400. Since the switch SW may be formed as a switching element inside the data driver 300, there is no particular difficulty or limitation in configuring the switch SW.

A detailed driving method for resetting the previous image by high voltage driving using the output voltages of the first data line 130, the second data line 132, and the data driver 300 will be described later.

By the intersection of the first data lines 130, the second data lines 132, and the gate lines 120, m × n pixels are formed in a matrix form. In each pixel, a TFT 140 is formed as a switching element, and a pixel electrode 150 for supplying a data voltage to the pixel is formed.

The TFT 140 switches the supply of image data, that is, a data voltage, to the pixel. The gate G of the TFT 140 is connected to the gate line 120, the source S is connected to the second data line 132, and the drain D is connected to the pixel electrode 150.

In addition, a common electrode 194 for supplying a common voltage Vcom to a plurality of pixels is formed on the upper substrate 190 of the display panel 100.

Referring back to FIG. 3, when the power of the electrophoretic display device is turned on, the power supply unit 500 of the display panel 100 according to a preset power on sequence using the input power Vin. Generate driving voltages VCC, VSS, Vcom, VPOS, VNEG, VGH, and VGL required for driving.

The generated driving voltages VCC, VSS, Vcom, VPOS, VNEG, VGH, and VGL are supplied to the gate driver 200, the data driver 300, and the controller 400. In this case, the power-on sequence may be previously set in the controller 400 or an external host system or may be stored in a separate memory (EEPROM).

The power supply unit 500 generates a positive voltage VPOS voltage and a negative voltage VNEG based on a power supply control signal supplied from the controller 400. The VPOS voltage can be generated with a DC voltage of + 15V, and the VNEG voltage can be generated with a DC voltage of -15V. The power supply unit 500 supplies the generated VPOS voltage and the VNEG voltage to the data driver 300.

The logic power supply voltage VCC is a logic voltage required to drive the controller 400, the data driver 300, and the gate driver 200, and is generally generated at a DC voltage of 3.3V.

The negative gate voltage VGL is generated at a DC voltage of -20V to -22V and is supplied to the gate driver 200, and the positive gate voltage VGH is generated at a DC voltage of + 20V to + 22V and thus the gate driver 200. Supplied to.

The control unit 400 generates a gate control signal for controlling the gate driver 200 using the timing signal TS input from the outside and supplies the gate signal to the gate driver 200.

The control unit 400 generates a data control signal for controlling the data driver 300 and supplies the data control signal to the data driver 300.

Here, the timing signal TS includes a vertical synchronization signal V-sync, a horizontal synchronization signal H-sync, and a clock signal CLK.

 When updating the image, the control unit 400 loads the waveform, which is a sequence of image data, from the memory 600 and supplies the waveform to the data driver 300.

To this end, the memory 600 stores a plurality of waveforms for converting from the previous picture to the next picture. The memory 600 may be a nonvolatile flash memory, a ROM, an EEPROM, or a magnetic computer storage medium.

The plurality of waveforms stored in the memory 600 may be generated in various versions reflecting the characteristics of materials constituting the electrophoresis layer and characteristics of a manufacturing process inherent to the manufacturer. That is, when materials or manufacturers that make up the electrophoretic layer applied to the plurality of electrophoretic display devices are different, a plurality of different waveforms may be stored in the memory 600 of each of the plurality of electrophoretic display devices.

The gate driver 200 generates a scan pulse swinging between the gate high voltage VGH and the gate low voltage VGL based on the gate control signal supplied from the control unit 400. [ The scan pulse is sequentially supplied to the gate lines formed in the display panel 100 so that the reset voltage and the data voltage according to the waveform can be supplied to the pixels. In this case, the scan pulse is sequentially supplied to the plurality of gate lines 120 in the reset period for refreshing the previous image and the date update period of the next image.

The data driver 300 generates a common voltage Vcom and supplies it to the common electrode 194. In this case, the common voltage Vcom is generated as a DC voltage in the range of -1.4 V to +1.1 V. In the present invention, a common voltage is generated at a value of 0 V and supplied to the common electrode. In addition, the data driver 300 may generate a ground (GND) voltage and allow the line connected through the high impedance (Hi-Z) terminal to be in a floating state.

The data driver 300 continuously generates an analog reset voltage and a data voltage using a waveform input from the controller 400, and generates the first data formed on the display panel 100 using the generated data reset voltage and the data voltage. To the lines 130. In this way, the pixels are driven in an active matrix manner so that the previous screen is reset and the next screen is updated.

The data voltages supplied from the data driver 300 to the first data lines 130 are generated as positive voltages and negative voltages. The data voltage supplied to the data line is applied to the pixel electrode 150 via the TFT.

In the reset period, the data driver 300 generates a reset voltage according to the reset waveform input from the controller 400 and supplies the reset voltage to the pixels of the display panel 100 to reset the previous image. At this time, the data voltage of the white image and the data voltage of the black image are supplied to the pixels to reset the state of the charged particles.

After the reset period, the next screen is displayed by updating the data of the next image in the pixels. As an example, the pixel is driven in an active matrix method during a data update period, and a data voltage of positive (+) and negative (-) polarities is supplied to the pixel electrode 150 for several to several tens of frames according to the gray level of the image data. To update the data of the next image.

The movement characteristics of the charged particles are affected by the intensity of the applied voltage and the time of application of the voltage. The force for moving the charged particles becomes larger in proportion to the intensity of the voltage and the applied time. Even after the charged particles are moved by the voltage, the charged particles move little by little in the direction of movement due to inertia.

The migration characteristics of the charged particles vary depending on the type and amount of the particles and the viscosity of the solvent. The larger the force applied to the charged particles, the more the charged particles move due to the inertia to move.

It is said that the charged particles move to a desired position and then the charged particles remain in the current state without moving the charged particles, and that the bistability is good, and the bistable characteristic is the ratio of the charged particles and the material constituting the solvent It depends on the characteristics. Due to this bistable characteristic, when the image is changed, the previous image is reset. When the reset period is long, the screen flickers.

Increasing the intensity of the voltage applied to the pixel in the reset period can reduce the reset period, that is, reset the previous image with fewer sub-frames. However, since the output of the data voltage of the data driver 300 is fixed at -15V and + 15V, high voltage driving cannot be performed without changing the design for increasing the output voltage of the data driver 300. On the other hand, although a data driver designed to have a high output voltage can be applied, a data driver capable of outputting a high voltage is expensive, so it is not easy to apply in consideration of price competitiveness of a product.

According to an embodiment of the present invention, an electrophoretic display device and a method of driving the same according to an embodiment of the present invention form a data line twice in the display panel 100 and a switch SW inside or outside the data driver 300. The voltage supplied can be doubled.

Since the electrophoretic display device displays an image by reflecting and absorbing external light, even if the number of data lines is doubled, the aperture ratio and the brightness of the image are not affected.

7 to 9 are diagrams illustrating a method of driving an electrophoretic display device according to a first embodiment of the present invention.

Referring to FIG. 7, in the reset period, a white reset data voltage of +30 V is advanced to all pixels to reset the previous image to the white image.

Then, the black reset data voltage of -30V is supplied to all the pixels to reset the previous image to the black image.

Thereafter, a data voltage of -15V or + 15V is supplied to the pixels of the display panel 100 to update the next image. The subframes to which the data voltages are supplied for each pixel to update the next image may be different according to the gray level of the image that each pixel is intended to display.

In FIG. 7, when converting from the previous image to the next image, all pixels are displayed as a white image, and then a black image is displayed to reset the previous image. Next, an example of displaying the next image by matching the gray of the next image with the white signal is illustrated. However, the present invention is not limited thereto, and the order of displaying the black image and the white image may be changed when resetting the previous image.

Referring to FIG. 8, high voltage driving twice as high as the data voltage supplied from the data driver 300 may be implemented using a capacitance characteristic to maintain a potential difference charged in a capacitor. 8 illustrates an example in which a data voltage is supplied to one pixel among a plurality of pixels.

First, referring to the configuration of the display panel 100, n gate lines 120 are formed, and m first data lines 130 and m second data lines 132 are formed.

The first data line 130 is connected to the first data voltage output unit 330 of the data driver 300. The second data line 132 is connected to the source S and the switch SW of the TFT 140.

The switch SW connects the second data line 132 to the common voltage output unit 310 so that the common voltage Vcom is applied, or the second data line 132 is a high impedance Hi-Z terminal. Switch to be connected to 320.

As shown in FIG. 8A, the first data voltage output unit 330 supplies a -15V data voltage to the first data line 130. In this case, the switch SW is switched by the control signal CS to connect the second data line 132 to the common voltage output unit 310.

Accordingly, -15 V is supplied to the first data line 130 and a common voltage of 0 V is supplied to the second data line 132, so that 15 V is supplied to the first capacitor C1 formed between the two lines 130 and 132. Is charged. In this case, the potential of the second data line 132 is 15V higher than that of the first data line 130.

Subsequently, referring to FIG. 8B, the first data voltage output unit 330 supplies a + 15V data voltage to the first data line 130. At this time, the switch SW is switched by the control signal CS to connect the second data line 132 to the high impedance Hi-Z terminal 320.

Accordingly, +15 V is supplied to the first data line 130 and the second data line 132 is in a floating state. 15V is charged in the first capacitor C1 formed between the two lines 130 and 132.

Since the potential of the second data line 132 is 15V higher than that of the first data line 130 in the previous state, the second data line 132 has a + potential to maintain the potential difference between the two lines 130 and 132. 30V potential is formed.

Thus, a + 30V voltage + 15V higher than the 15V voltage charged in the first capacitor C1 is charged in the second capacitor C2, and when the TFT 140 is turned on, a data voltage of + 30V is applied to the pixel electrode ( The high voltage driving of the pixel is performed.

The data voltage of + 30V, that is, the reset voltage is supplied to all the pixels to reset all the pixels to the white image.

Next, a method of resetting all pixels to a black image by driving a high voltage of -30V will be described with reference to FIG. 9.

As shown in FIG. 9A, the first data voltage output unit 330 supplies a + 15V data voltage to the first data line 130. In this case, the switch SW is switched by the control signal CS to connect the second data line 132 to the common voltage output unit 310.

Accordingly, since + 15V is supplied to the first data line 130 and a common voltage of 0V is supplied to the second data line 132, 15V is supplied to the first capacitor C1 formed between the two lines 130 and 132. Is charged. In this case, the potential of the first data line 132 is 15V higher than that of the second data line 130. That is, the potential of the second data line 132 is lower than that of the first data line 130 by -15V.

Subsequently, referring to FIG. 9B, the first data voltage output unit 330 supplies a -15V data voltage to the first data line 130. At this time, the switch SW is switched by the control signal CS to connect the second data line 132 to the high impedance Hi-Z terminal 320.

Accordingly, -15V is supplied to the first data line 130 and the second data line 132 is in a floating state. 15V is charged in the first capacitor C1 formed between the two lines 130 and 132.

In the previous state, since the potential of the second data line 132 is lower than that of the first data line 130 by -15V, the second data line 132 is not provided to maintain the potential difference between the two lines 130 and 132. A -30V potential is formed.

As a result, a -30V voltage lower -15V than the -15V voltage charged in the first capacitor C1 is charged in the second capacitor C2, and when the TFT 140 is turned on, a data voltage of -30V is applied to the pixel electrode. The high voltage driving of the pixel is performed at 150.

A data voltage of -30V, that is, a reset voltage is supplied to all the pixels so that all the pixels are reset to a black image.

According to the capacitance of the first capacitor C1 formed between the first data line 130 and the second data line 132 and the second capacitor C2 formed between the second data line 132 and the pixel, The data voltage value supplied can vary.

According to the exemplary embodiment of the present invention, the data voltage value supplied to the pixel is measured by setting the capacitance ratio of the first capacitor C1 and the second capacitor C2 to 10: 1, and as a result, a data voltage of ± 27.3 V is applied to the pixel. Confirmed to be supplied.

10 is a view showing the effect of applying the electrophoretic display device and its driving method according to an embodiment of the present invention.

10, the reflectance of the electrophoretic layer when the high voltage is supplied to the pixel is measured and shown.

In the black screen, the data voltage was changed to -5V, -10V, -15V, -20V, -25V, and -30V while measuring the reflectance when converting to the white screen. As the data voltage decreases, the number of subframes applied to reach the same reflectance increases, that is, the time for which the data voltage is applied decreases.

In addition, while changing the data voltage on the white screen to -5V, -10V, -15V, -20V, -25V, -30V, the reflectance when converting to a black screen was measured. As the data voltage increases, the number of subframes applied to reach the same reflectance increases, that is, the time for which the data voltage is applied decreases.

The reflectance reaches 4% to 34%, and the reset time is reduced by 65% when applying a -30V data voltage compared to applying a -30V data voltage. It can be seen.

Conversely, the reflectivity reaches 34% to 4%, compared with applying + 30V data voltage and + 15V data voltage, and the reset time is 65% when applying + 30V data voltage. It can be seen that the decrease.

Although the effect of reducing the reset time described with reference to FIG. 10 may vary depending on the structure and material of the electrophoretic layer, the reset time may be reduced by 50% or more due to high voltage driving.

As described above, a voltage twice higher than the voltage output from the data driver 300 (the actual supplied data voltage becomes ± 27.3 V due to an error) can be supplied to the pixel, so that the reset of the previous image by high voltage driving It can save time. In addition, the afterimage can be removed by effectively resetting the previous image. After the reset period, the next image can be updated to shorten the overall image update time and improve the display quality.

11 is a diagram illustrating a structure of a display panel and a connection structure of a display panel and a driving circuit unit according to a second embodiment.

Referring to FIG. 11, the switch SW connects the second data line 132 to the ground GND terminal 315 of the data driver 300 so that a 0V voltage is applied or the second data line 132 is applied. May be connected to the high impedance (Hi-Z) terminal 320. The other configuration is the same as that shown in FIG. 5, and the driving method is described with reference to FIGS. 7 to 9 except that the ground (GND) voltage is supplied to the second data line 132 in place of the common voltage. It is the same as the first driving method. Therefore, detailed description thereof will be omitted.

12 is a view illustrating a structure of a display panel and a connection structure of a display panel and a driving circuit unit according to a third embodiment, and FIGS. 13 to 15 illustrate a method of driving an electrophoretic display device according to a second embodiment of the present disclosure. It is a figure which shows.

Referring to FIG. 12, the first data lines 130 and the second data lines 132 are formed on the display panel 100, and when the number of ICs of the data driver 300 is doubled, the data driver 130 is increased. The high voltage, which is three times higher than the data voltage supplied by the second pixel, can be supplied to the pixel, further reducing the reset time of the previous image.

The first data line 130 is connected to the first data voltage output unit 330, and the second data line 132 is connected to the second data voltage output unit 340 or the high impedance (Hi-Z) terminal 320. Is connected to.

Here, the second data line 132 or the high impedance (Hi-Z) terminal of the data driver 300 is switched to switch according to the control signal CS input to the switch SW. (320).

That is, the switch SW connects the second data line 132 to the second data voltage output unit 340 so that a data voltage of ± 15 V is applied to the second data line 132 or second data. The line 132 is switched so that it can be connected to the high impedance (Hi-Z) terminal 320. Since the switch SW may be formed as a switching element inside the data driver 300, there is no particular difficulty or limitation in configuring the switch SW.

Referring to Fig. 13, in a reset period, a white reset data voltage of +45 V is advanced to all pixels to reset the previous image to a white image.

Then, a black reset data voltage of -45 V is supplied to all the pixels to reset the previous image to the black image.

Thereafter, a data voltage of -15V or + 15V is supplied to the pixels of the display panel 100 to update the next image. The subframes to which the data voltages are supplied for each pixel to update the next image may be different according to the gray level of the image that each pixel is intended to display.

Referring to FIG. 14, a high voltage driving that is three times higher than the data voltage supplied from the data driver 300 may be implemented by using a capacitance characteristic to maintain a potential difference charged in the capacitor.

As shown in FIG. 14A, the first data voltage output unit 330 supplies a -15V data voltage to the first data line 130. At this time, the switch SW is switched by the control signal CS to connect the second data line 132 to the second data voltage output unit 340.

Accordingly, −15 V is supplied to the first data line 130 and +15 V is supplied to the second data line 132, so that 30 V is applied to the first capacitor C1 formed between the two lines 130 and 132. Is charged. At this time, the potential of the second data line 132 is higher than that of the first data line 130 by 30V.

Subsequently, referring to FIG. 14B, the first data voltage output unit 330 supplies a + 15V data voltage to the first data line 130. At this time, the switch SW is switched by the control signal CS to connect the second data line 132 to the high impedance Hi-Z terminal 320. Accordingly, +15 V is supplied to the first data line 130 and the second data line 132 is in a floating state.

Since the potential of the second data line 132 is 30V higher than that of the first data line 130 in the previous state, the second data line 132 has a + potential to maintain the potential difference between the two lines 130 and 132. 45V potential is formed.

Thus, a + 45V voltage + 15V higher than the 30V voltage charged in the first capacitor C1 is charged in the second capacitor C2, and when the TFT 140 is turned on, a data voltage of + 45V is applied to the pixel electrode ( The high voltage driving of the pixel is performed.

A data voltage of +45 V, that is, a reset voltage is supplied to all the pixels to reset all the pixels to the white image.

Next, a method of resetting all pixels to a black image by driving a high voltage of -45V will be described with reference to FIG. 15.

As shown in FIG. 15A, the first data voltage output unit 330 supplies a + 15V data voltage to the first data line 130. At this time, the switch SW is switched by the control signal CS to connect the second data line 132 to the second data voltage output unit 340.

Accordingly, + 15V is supplied to the first data line 130 and -15V is supplied to the second data line 132, so that 30V is applied to the first capacitor C1 formed between the two lines 130 and 132. Is charged. At this time, the potential of the first data line 132 is higher than that of the second data line 130 by 30V. That is, the potential of the second data line 132 is lower than that of the first data line 130 by -30V.

Subsequently, referring to FIG. 15B, the first data voltage output unit 330 supplies a -15V data voltage to the first data line 130. At this time, the switch SW is switched by the control signal CS to connect the second data line 132 to the high impedance Hi-Z terminal 320. Accordingly, -15V is supplied to the first data line 130 and the second data line 132 is in a floating state.

In the previous state, since the potential of the second data line 132 is lower than that of the first data line 130 by -30V, the second data line 132 is not provided to maintain the potential difference between the two lines 130 and 132. A -45V potential is formed.

As a result, a -45V voltage lower -15V than the -30V voltage charged in the first capacitor C1 is charged in the second capacitor C2, and when the TFT 140 is turned on, a data voltage of -45V is applied to the pixel electrode. The high voltage driving of the pixel is performed at 150.

A data voltage of -45V, that is, a reset voltage is supplied to all the pixels so that all the pixels are reset to a black image.

According to the capacitance of the first capacitor C1 formed between the first data line 130 and the second data line 132 and the second capacitor C2 formed between the second data line 132 and the pixel, The data voltage value supplied can vary.

According to the exemplary embodiment of the present invention, the data voltage value supplied to the pixel is measured by setting the capacitance ratio of the first capacitor C1 and the second capacitor C2 to 10: 1, and as a result, a data voltage of ± 42.3 V is applied to the pixel. Confirmed to be supplied.

The reduction of reset time may vary depending on the structure and material of the electrophoretic layer, but the reset time can be further shortened by resetting the previous image to a high voltage of ± 45V.

As described above, a voltage three times higher than the voltage output from the data driver 300 (the actual supplied data voltage becomes ± 42.3 V due to an error) can be supplied to the pixel, and the reset of the previous image is performed by high voltage driving. It can save time. In addition, the afterimage can be removed by effectively resetting the previous image. After the reset period, the next image can be updated to shorten the overall image update time and improve the display quality.

It will be understood by those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: display panel 110: lower substrate
120: gate line 130: first data line
132: second data line 140: TFT
150: pixel electrode 160: barrier rib
170: Display solvent 172: charged particles
174: solvent 180: sealing layer
190: upper substrate 192: upper base substrate
194: common electrode 200: gate driver
300: data driver 400:
500: power supply unit 600: memory

Claims (10)

In a first period for resetting a previous image, a first data voltage is supplied to a first data line, and a common voltage or a ground voltage is supplied to a second data line connected to a source of a TFT to provide the first data line and the Forming a potential difference between the second data line by the first data voltage;
In a second period, a second data voltage opposite to the polarity of the first data voltage supplied in the first period is supplied to the first data line, and the second data line is connected to a high impedance terminal to connect the first data. Forming a potential difference corresponding to a voltage or twice the second data voltage between the second data line and the pixel; And
And turning on the TFT to supply a data voltage corresponding to twice the first data voltage or the second data voltage to a pixel to reset the previous image. The method of claim 1,
And wherein the first data voltage and the second data voltage have a voltage value of X, and the data voltage supplied to the pixel has a voltage value of 2X. In a first period for resetting a previous image, a first data voltage is supplied to the first data line, and a second data voltage having a polarity opposite to the first data voltage is supplied to a second data line connected to a source of the TFT. Forming a potential difference between the first data line and the second data line corresponding to twice the first data voltage or the second data voltage;
In a second period, a third data voltage opposite to the polarity of the first data voltage supplied in the first period is supplied to the first data line, and the second data line is connected to a high impedance terminal to provide the first data. Forming a potential difference corresponding to three times the voltage or the second data voltage between the second data line and the pixel; And
Turning on the TFT to supply a data voltage corresponding to three times the first data voltage or the second data voltage to the pixel to reset the previous image. The method of claim 3, wherein
The first data voltage, the second data voltage and the third data voltage have a voltage value of X, and the data voltage supplied to the pixel has a voltage value of 3X. The method according to claim 1 or 3,
A first capacitor is formed between the first data line and the second data line,
A second capacitor is formed between the second data line and the pixel,
And controlling a data voltage value supplied to the pixel by adjusting a capacitance ratio between the first capacitor and the second capacitor. n gate lines;
M first data lines and m second data lines formed to intersect the n gate lines;
A TFT formed for each of the plurality of pixels;
A gate driver for supplying a scan signal to the gate of the TFT;
A data driver for supplying a first data voltage to the first data line and for supplying a common voltage or a ground voltage to a second data line connected to a source of the TFT;
A controller for supplying a waveform for updating the image to the data driver; And
And a switch for connecting the second data line to a common voltage output or ground terminal of the data driver, or for connecting the second data line to a high impedance terminal. The method according to claim 6,
The data driver includes:
A first data voltage output unit supplying a first data voltage to the first data line;
A second data voltage output unit supplying a second data voltage to the second data line;
A common voltage output unit; And
An electrophoretic display device comprising a ground terminal. The method of claim 7, wherein
In a first period for resetting a previous image, the data driver supplies a first data voltage to the first data line,
The switch connects the second data line to the common voltage output or ground terminal,
In a second period, the data driver supplies a second data voltage to the first data line opposite to the polarity of the first data voltage supplied in the first period.
The switch connects the second data line to a high impedance terminal to form a potential difference corresponding to the first data voltage or twice the second data voltage between the second data line and the pixel;
And the TFT is turned on by a scan signal supplied from the gate driver to supply a data voltage corresponding to twice the first data voltage or the second data voltage to the pixel. The method of claim 7, wherein
In a first period for resetting a previous image, the data driver supplies a first data voltage to the first data line,
Supplying a second data voltage having a polarity opposite to the first data voltage to the second data line,
In a second period, the data driver supplies a third data voltage opposite to the polarity of the first data voltage supplied in the first period to the first data line,
The switch connects the second data line to a high impedance terminal to form a potential difference corresponding to three times the first data voltage or the second data voltage between the second data line and the pixel.
And the TFT is turned on by a scan signal supplied from the gate driver to supply a data voltage corresponding to three times the first data voltage or the second data voltage to the pixel. The method according to claim 6,
And the switch is embedded in the data driver.

Images