KR101964078B1 - Electrophoresis display device and method for driving the same - Google Patents

Abstract

The present invention relates to an electrophoretic display device and a driving method thereof capable of reducing afterimage and flashing of a screen during a telephone call.
The method of driving an electrophoretic display device according to an embodiment of the present invention includes resetting odd pixels to a first image among all pixels using a first reset waveform in a first reset period, .

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 that can reduce afterimage and flashing of a screen during a telephone call.

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 device using the electrophoresis phenomenon has a characteristic of bistability, so that even if the applied voltage is removed, the displayed image can be displayed for a long time. That is, the electrophoretic display device is suitable for the e-book field in which it is not required to swiftly change the screen because the electrophoretic display device can maintain a certain screen for a long time without continuously applying a voltage.

The electrophoretic display device has no dependence on the viewing angle and displays an image by reflecting external light, so that it is possible to provide a comfortable image to the eye to a degree similar to that of paper.

1 is a view showing a driving method of an electrophoretic display device according to the related art.

Referring to FIG. 1, the electrophoretic display device can not display a frame on a frame-by-frame basis, such as an LCD, since the screen switching is not fast due to its bistability. Accordingly, the image is displayed by supplying the data voltage using a wave form, which is a sequence of image data, and the image is switched from the previous image to the next image.

Here, the new image data is written into the display panel through the image updating process for about one second, and then the current image data is maintained until the next data update, so that the once displayed image is maintained for a long time.

When switching the screen through the image update, the state of the charged particles must be initialized by refreshing because the residual image of the previous image may remain in the next image due to the characteristics of the binocular normal.

The reset period is composed of a white reset period and a black reset period. During the white reset period, the data voltage is supplied to initialize the charged particles so that the entire screen displays a white image. Then, during the black reset period, the data voltage is supplied to display the black image on the entire screen to initialize the charged particles. After the reset period, the pixel is updated with the image data of the next image to switch to the next image.

In the electrophoretic display device according to the related art, the entire screen is displayed in white and black in the reset period and the previous picture is reset, so that the viewer feels flashing of the screen.

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

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide an electrophoretic display device and a driving method thereof capable of reducing screen flushing during image update.

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.

The method of driving an electrophoretic display device according to an embodiment of the present invention includes resetting odd pixels to a first image among all pixels using a first reset waveform in a first reset period, .

A method of driving an electrophoretic display device according to an embodiment of the present invention includes resetting odd pixels to a first image using a second reset waveform in a second reset period and resetting odd pixels to a second image .

In the method of driving an electrophoretic display device according to an embodiment of the present invention, when switching from a previous image to a next image, all the pixels are composed of a plurality of even pixel groups and a plurality of odd pixel groups, Pixels are reset to a first image, and pixels of the plurality of odd pixel groups are reset to a second image.

An electrophoretic display device according to an embodiment of the present invention includes a display panel having even pixels and odd pixels formed therein; A first reset waveform and a second reset waveform for resetting the previous picture, and an update waveform for updating the next picture; A gate driver for supplying scan pulses to the even pixels and odd pixels in the first reset period and the second reset period; And a data driver for supplying a data voltage for reset to even pixels and odd pixels in the first reset period and the second reset period based on the first reset waveform and the second reset waveform, In the first reset period and the second reset period, different images are alternately displayed on the even pixels and odd pixels to reset the previous image.

The electrophoretic display device and the driving method of the electrophoretic display device according to the embodiment of the present invention can reduce flickering of the screen when the screen is switched.

The electrophoretic display device and the driving method thereof according to the embodiment of the present invention can improve the display quality of the screen.

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 showing a driving method of an electrophoretic display device according to the related art.
2 illustrates an electrophoretic display device according to an embodiment of the present invention.
3 is a view showing a display panel to which an electrophoretic film is applied.
4 shows a display panel in which a display solvent is internalized.
5 to 8 are views showing a driving method of an electrophoretic display device according to a first embodiment of the present invention.
9 illustrates a pixel structure according to another embodiment of the present invention.
10 and 11 are views showing a driving method of an electrophoretic display device according to a second embodiment of the present invention.
12 illustrates a method of driving an electrophoretic display device according to a third embodiment of the present invention.
13 to 16 are views showing a driving method of an electrophoretic display device according to a fourth embodiment of the present invention.
17 and 18 are views showing a driving method of an electrophoretic display device according to a fifth embodiment of the present invention.
19 and 20 are views showing a driving method of an electrophoretic display device according to a sixth 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 technical field of the present invention can be omitted, if not related to the core configuration of the present invention.

2 is a view illustrating an electrophoretic display device according to an embodiment of the present invention.

2, an electrophoretic display device according to an embodiment of the present invention includes a display panel 100, a gate driver 200, A data driver 300; A controller 400, and a power unit 500. [

The display panel 100 displays an image according to an input data voltage, and includes a lower substrate, an upper substrate, and an electrophoresis layer.

Here, the electrophoretic layer may be an electrophoretic film including a plurality of microcapsules 10 in which charged particles 12 and a solvent 14 are mounted, as shown in Fig.

4, a partition wall 50 is formed so as to surround the pixel region, and a display solvent 40 composed of the charged particles 42 and the solvent 44 is formed on the partition wall 50 may be formed of an internalization type filled in a space provided by the internal combustion engine.

In the lower substrate 1 of the display panel 100, n gate lines and m data lines cross each other. M x n pixels (Cells) are formed in a matrix form by the intersection of the data lines and the gate lines. In each pixel, a TFT is formed as a switching element, and a pixel electrode 20 is formed for supplying a data voltage to the pixel.

The TFT switches the supply of image data (data voltage) to the pixel. The gate electrode of the TFT is connected to the gate line, the source electrode is connected to the data line, and the drain electrode is connected to the pixel electrode.

A common electrode 30 for supplying the common voltage Vcom is formed on the upper substrate 2 of the display panel 100 and an electrophoretic film or an internal electrode 30 is formed between the pixel electrode 20 and the common electrode 30. [ Type electrophoresis layer is formed.

2, when the power source of the electrophoretic display device is turned on, the power source unit 500 uses the input power source Vin in accordance with a preset power on sequence, (VCC, VSS, Vcom, VPOS, VNEG, VGH, and VGL) necessary for driving are generated.

The gate driver 200, the data driver 300, and the control unit 400 supply the generated driving voltages VCC, VSS, Vcom, VPOS, VNEG, VGH, and VGL. At this time, the power-on sequence may be preset in the control unit 400 or an external host system, or may be stored in a memory such as an EEPROM.

The power supply unit 500 generates a VPOS voltage which is a positive data voltage and a VNEG which is a negative data voltage based on a power supply control signal supplied from the control unit 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 VPOS voltage and the VNEG voltage generated in the power supply unit 500 are supplied to the data driver 300.

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

The common voltage Vcom supplied to the common electrode is generated with a DC voltage of -1.4V to + 1.1V.

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

In the first reset period, the second reset period, and the data update period, the power supply unit 500 generates VPOS and VNEG necessary for generating data voltages, that is, positive data pulses and negative data pulses, and supplies them to the data driver 300.

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. In addition, when the image is reset and the image is updated, the control unit 400 forms a waveform, which is a sequence of image data, and supplies the waveform to the data driver 300.

Here, the waveforms supplied from the controller 400 to the data driver 300 can be broadly classified into two types.

The waveform consists of a reset waveform for resetting the screen in the first reset period and a second reset period and an update waveform for updating the data of the next picture.

The entire pixels of the display panel 100 are divided into even pixels and odd pixels in order to prevent the screen from flickering due to the reset driving at the time of screen switching, And supplies a reset waveform to the data driver 300 so that different data voltages are supplied to the data driver 300.

The reset waveform may consist of a first reset waveform for resetting the screen in the first reset period and a second reset waveform for resetting the screen in the second reset period.

The controller 400 generates an even waveform for refreshing the even pixels among all the pixels of the display panel 100 as a first reset waveform to be applied to the first reset period, 300). In addition, during the first reset period, an odd waveform for refreshing odd pixels in all the pixels is generated and supplied to the data driver 300.

The controller 400 generates a second reset waveform applied to the second reset period to generate an even waveform for refreshing even pixels among all the pixels of the display panel 100 and supplies the generated waveform to the data driver 300 . Further, in the second reset period, an odd waveform for refreshing odd pixels in all the pixels is generated and supplied to the data driver 300.

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. Then, the scan pulse is sequentially supplied to the gate lines formed in the display panel 100 during a reset period and a data update period. This allows the pixels to be driven in an active matrix fashion to initialize the previous image and update the data.

The data driver 300 generates a data voltage according to the waveform input from the controller 400 and supplies the data voltage to data lines formed on the display panel 100. Here, the data voltage is generated as a positive (+) voltage or a negative (-) voltage. The data voltage supplied to the data line is applied to the pixel electrode 20 via the TFT.

When the image is reset and the image is updated, the pixel electrode 20 formed on the lower substrate 1 is supplied with a data voltage of -15 V or +15 V. At this time, a common voltage Vcom of -1.4 V to + 1.1 V is supplied to the common electrode 30 formed on the upper substrate 2, and an electric field is formed between the pixel electrode 20 and the common electrode 30.

In the reset period, the data driver 300 generates a data voltage according to the reset waveform input from the control unit 400, and supplies the data 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 alternately supplied to the pixels to initialize the states of the charged particles.

Specifically, the entire pixels of the display panel 100 are divided into even pixels and odd pixels. The reset period may consist of a first reset period (1 ^st reset period) and a second reset period (2 ^nd reset period).

The data driver 300 supplies the data voltages of the white image to the even pixels and the data voltages of the black image to the odd pixels in the first reset period.

The data driver 300 supplies a black image data voltage to the even pixels and a white image data voltage to the odd pixels in the second reset period.

Thus, different data voltages are supplied to the even pixels and the odd pixels at the same time to reset the previous image.

After the reset period, the pixel is updated with the image data to display the next image. As an example, pixels are driven in an active matrix manner during a data update period, and data voltages of positive (+) and negative (-) polarities are supplied to the pixel electrode 20 for several to several tens of frames depending on the gradation of image data And updates the data of the next image.

Hereinafter, driving methods of the electrophoretic display device according to an embodiment of the present invention will be described with reference to FIGS. 5 to 12. FIG.

5 to 8 are views showing a driving method of an electrophoretic display device according to an embodiment of the present invention.

Referring to FIG. 5, the entire image update period for switching the screen from the previous image to the next image may be composed of a reset period and a data update period. Here, the reset period may consist of a first reset period and a second reset period.

In the electrophoretic display device according to the embodiment of the present invention, in the first reset period, the even pixels corresponding to 1/2 of all the pixels are reset to the first image (for example, the white image) Can be reset to a second image (e.g., a black image).

Then, in the second reset period, odd pixels corresponding to 1/2 of all pixels are reset to a first image (e.g., a white image), and the remaining odd pixels are reset to a second image , Black image).

To this end, the reset waveform may consist of a first reset waveform for resetting the screen in the first reset period and a second reset waveform for resetting the screen in the second reset period.

The first reset waveform applied in the first reset period includes an even waveform for refreshing the even pixels and an odd waveform for refreshing the odd pixels among all the pixels of the display panel 100. [

The second reset waveform applied to the second reset period includes an even waveform for refreshing the even pixels and an odd waveform for refreshing the odd pixels among the entire pixels of the display panel 100. [

6 to 8, in the first reset period, a first data voltage based on an even waveform for refreshing even pixels among all the pixels of the display panel 100 is applied to the even- . At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the even pixels to a white image.

Further, in the first reset period, a second data voltage based on an odd waveform is supplied to the odd pixels for refreshing odd pixels among all the pixels of the display panel 100. [ At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the odd pixels to a black image.

In the above description, the data voltage of the white image based on the even waveform is supplied to the even pixels in the first reset period, the data voltage of the black image based on the odd waveform is supplied to the odd pixels, Resetting the entire pixels has been described.

However, the present invention is not limited to this. In the first reset period, the even waveform may be generated as a reset waveform for generating the data voltage of the black image, and the odd waveform may be the reset waveform for generating the data voltage of the white image. Lt; / RTI >

Thus, in the first reset period, the data voltage of the black image based on the even waveform can be supplied to the even pixels, and the data voltage of the white image based on the odd waveform can be supplied to the odd pixels to reset the entire pixel.

Then, in the second reset period, the first data voltage based on the odd waveform is supplied to the odd pixels for refreshing the odd pixels among all the pixels of the display panel 100. [ At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the odd pixels to a white image.

In addition, in the second reset period, a second data voltage based on the even waveform is supplied to the even pixels for refreshing even pixels among all the pixels of the display panel 100. [ At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the even pixels to a black image.

In the above description, the data voltage of the black image based on the even waveform is supplied to the even pixels in the second reset period, and the data voltage of the white image based on the odd waveform is supplied to the odd pixels, Resetting the entire pixels has been described.

However, the present invention is not limited to this, and in the second reset period, an even waveform may be generated as a reset waveform for generating a data voltage of a white image, and an odd waveform may be generated as a reset waveform Lt; / RTI >

Therefore, in the second reset period, the data voltages of the white image based on the even waveform can be supplied to the even pixels, and the data voltages of the black image based on the odd waveform can be supplied to the odd pixels to reset the entire pixels.

As shown in FIGS. 7 and 8, the even pixels and odd pixels of the display panel 100 may be formed in a plaid shape. If the even pixels and the odd pixels are formed in a lattice pattern, the white pixels and the black pixels may be alternately displayed in the first reset period and the second reset period in units of dot pixels to reset the entire pixels.

As described above, since the white image and the black image are alternately displayed in the unit of pixel at the same time, that is, the first reset period and the second reset period, the screen flicker due to the refresh of the pixels does not occur.

9 is a view showing a pixel structure according to another embodiment of the present invention.

Referring to FIG. 9, as another embodiment of the present invention, the pixels formed on the even horizontal lines and the pixels formed on the od horizontal lines may be arranged so as to have a delta structure by staggering them. In the case of the pixel structure shown in FIG. 9, the reset driving described above with reference to FIGS. 6 to 8 can be similarly applied.

10 and 11 are views showing a driving method of an electrophoretic display device according to a second embodiment of the present invention.

10 and 11, the even pixels and odd pixels may be formed in a vertical stripe shape with respect to the vertical direction. If the even pixels and odd pixels are formed in the vertical stripe form, the white pixels and the black pixels may be alternately displayed in the first reset period and the second reset period in units of vertical lines to reset the entire pixels.

Specifically, in the first reset period, the first data voltage based on the even waveform is supplied to the even pixels for refreshing the even pixels formed in the even vertical line in the entire pixels of the display panel 100. At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the even pixels to a white image.

Further, in the first reset period, a second data voltage based on the odd waveform is supplied to the odd pixels for refreshing the odd pixels formed in the odd vertical line among all the pixels of the display panel 100. [ At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the odd pixels to a black image.

Then, in the second reset period, the first data voltage based on the odd waveform is supplied to the odd pixels for refreshing the odd pixels among all the pixels of the display panel 100. [ At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the odd pixels to a white image.

In addition, in the second reset period, a second data voltage based on the even waveform is supplied to the even pixels for refreshing even pixels among all the pixels of the display panel 100. [ At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the even pixels to a black image.

As described above, since the white image and the black image are displayed in a vertically-line-by-line manner in the same time, that is, the first reset period and the second reset period, the screen flickering due to the refresh of the pixels does not occur.

12 is a diagram illustrating a method of driving an electrophoretic display device according to a third embodiment of the present invention.

Referring to FIG. 12, the even pixels and the odd pixels may be formed in a horizontal stripe shape with respect to the horizontal direction. If the even pixels and odd pixels are formed in a horizontal stripe shape, the white pixels and the black pixels may be alternately displayed in the first reset period and the second reset period in units of horizontal lines to reset the entire pixels.

Specifically, in the first reset period, the first data voltage may be supplied to even-numbered pixels formed in the even-numbered horizontal lines in the entire pixels of the display panel 100 to reset the even pixels to the white image.

In addition, during the first reset period, the second data voltage may be supplied to the odd pixels formed in the odd horizontal line among all the pixels of the display panel 100 to reset the odd pixels to the black image.

In the second reset period, the first data voltage may be supplied to the odd pixels formed in the odd horizontal line among all the pixels of the display panel 100 to reset the odd pixels to the white image.

In addition, in the second reset period, the second data voltage may be supplied to the even pixels formed in the even horizontal line among the entire pixels of the display panel 100 to reset the even pixels to the black image.

As described above, since the white image and the black image are displayed in the form of a line by line in a horizontal line unit at the same time, that is, the first reset period and the second reset period, the screen flicker due to the refresh of the pixels does not occur.

After the reset period, the image data is updated to all pixels formed on the display panel 100 to display the next image. A data voltage of positive (+) and negative (-) polarity is supplied to the pixels for several to several tens of frames using an update waveform according to the gradation of the screen to be displayed at each pixel, thereby updating the data of the next image.

13 to 16 are views showing a driving method of an electrophoretic display device according to a fourth embodiment of the present invention. Figs. 13 to 16 show part of all the pixels of the display panel 100. Fig.

13 to 16, an electrophoretic display device according to an embodiment of the present invention, when switching from a previous image to a next image, divides all the pixels into a plurality of even pixel groups and a plurality of odd pixel groups (Odd pixel group) to reset the previous image.

Here, each of the even pixel groups and the odd pixel groups may be composed of at least two or more pixels as shown in FIGS. 14 and 16. FIG. It is possible to reconstruct the even pixel groups and the odd pixel groups every time the screen is switched. That is, the boundary between the even pixel groups and the odd pixel groups can be changed without being fixed each time the screen is switched.

As an example, a boundary between even pixel groups and odd pixel groups when converting the Nth image to the (N + 1) th image and a boundary between odd pixel groups and odd pixel groups when converting the (N + 1) And the boundary between the odd pixel groups are different from each other.

14, when the screen is switched from the Nth image (first image) to the N + 1th image (second image), four horizontal lines and four vertical line units, i.e., 4x4 pixels, A pixel group can be constituted.

It is possible to reset the previous image by supplying data voltages according to different waveforms to the pixels of the even pixel group and the pixels of the odd pixel group at the same time point.

16, when switching screens from the (N + 1) th image (second image) to the (N + 2) th image (third image), some pixel groups constitute pixel groups in units of two horizontal lines, Namage pixel groups can form a group of pixels in units of four horizontal lines.

It is possible to reset the previous image by supplying data voltages according to different waveforms to the pixels of the even pixel group and the pixels of the odd pixel group at the same time point.

The even pixel groups and the odd pixel groups of the display panel 100 may be formed in a plaid shape. If the even pixel groups and the odd pixel groups are formed in a lattice pattern, the white pixels and the black pixels may be alternately displayed in the form of dots in the first reset period and the second reset period to reset the entire pixels .

When the Nth image is switched to the (N + 1) th image, the reset waveform for refreshing the image includes a first reset waveform for resetting the screen in the first reset period and a second reset waveform for resetting the screen in the second reset period And a second reset waveform.

The first reset waveform applied in the first reset period includes an even waveform for refreshing the even pixels and an odd waveform for refreshing the odd pixels among all the pixels of the display panel 100. [

The second reset waveform applied to the second reset period includes an even waveform for refreshing the even pixels and an odd waveform for refreshing the odd pixels among the entire pixels of the display panel 100. [

13 and 14 illustrate a method of driving an electrophoretic display device according to a fourth embodiment of the present invention. Referring to FIGS. 13 and 14, For example.

In the first reset period for switching the Nth image to the (N + 1) th image, the pixels of the even pixel groups among all the pixels are reset to the first image (e.g., a white image). The pixels of the odd pixel groups may then be reset to a second image (e.g., a black image).

In the first reset period for switching the Nth image to the (N + 1) th image, the first data voltage is supplied to the pixels of the even pixel groups among the entire pixels of the display panel 100. [ At this time, the first data voltage is for displaying the white image, and the pixels of the even pixel groups can be reset to the white image.

On the other hand, in the first reset period for switching the Nth image to the (N + 1) th image, the second data voltage is supplied to the pixels of the odd pixel groups among all the pixels of the display panel 100. At this time, the second data voltage is for displaying a black image, and the pixels of the odd pixel groups can be reset to a black image.

In the above description, the pixels in the even pixel groups are reset to the white image and the pixels in the odd pixel groups are reset to the black image in the first reset period for switching the Nth image to the (N + 1) th image.

However, it is also possible to reset the pixels of odd pixel groups to a black image and reset the pixels of odd pixel groups to a white image in the first reset period for switching the Nth image to the (N + 1) th image have.

Then, during the second reset period for switching the Nth image to the (N + 1) th image, the pixels of the odd pixel groups among all the pixels are reset to the first image (e.g., a white image). The pixels of the even pixel groups may then be reset to a second image (e.g., a black image).

In the second reset period for switching the Nth image to the (N + 1) th image, the first data voltage is supplied to the pixels of the odd pixel groups among all the pixels of the display panel 100. [ At this time, the first data voltage is for displaying a white image, and the pixels of odd pixel groups can be reset to a white image.

On the other hand, in the second reset period for switching the Nth image to the (N + 1) th image, the second data voltage is supplied to the pixels of the even pixel groups among the entire pixels of the display panel 100. At this time, the second data voltage is for displaying a black image, and the pixels of the even pixel groups may be reset to a black image.

In the above description, in the second reset period for switching the Nth image to the (N + 1) th image, the pixels of the odd pixel groups are reset to the white image, and the pixels of the even pixel groups are reset to the black image.

However, not limited thereto, it is also possible to reset the pixels of the odd pixel groups to a black image and reset the pixels of the even pixel groups to the white image in the second reset period for switching the Nth image to the (N + 1) have.

15 and 16 show an example of a driving method for refreshing a previous image when the (N + 1) -th image is switched to the (N + 2) -th image.

The pixel groups formed when the Nth image is converted into the (N + 1) th image are refreshed to refresh the previous image when the (N + 1) th image is converted into the (N + 2) th image. It is possible to reconstruct the even pixel groups and the odd pixel groups every time the screen is switched. That is, the boundary between the even pixel groups and the odd pixel groups is changed each time the screen is changed.

During the first reset period for switching the (N + 1) -th image to the (N + 2) -th image, the pixels of the even-numbered groups of pixels among all the pixels are reset to a first image (e.g., a white image). The pixels of the odd pixel groups may then be reset to a second image (e.g., a black image).

During the first reset period for switching the (N + 1) th image to the (N + 2) th image, the first data voltage is supplied to the pixels of the even pixel groups among all the pixels of the display panel 100. At this time, the first data voltage is for displaying the white image, and the pixels of the even pixel groups can be reset to the white image.

On the other hand, in the first reset period for switching the (N + 1) th image to the (N + 2) th image, the second data voltage is supplied to the pixels of the odd pixel groups among all the pixels of the display panel 100. At this time, the second data voltage is for displaying a black image, and the pixels of the odd pixel groups can be reset to a black image.

Then, in a second reset period for switching the (N + 1) -th image to the (N + 2) -th image, the pixels of the odd pixel groups among all the pixels are reset to a first image (e.g., a white image). The pixels of the even pixel groups may then be reset to a second image (e.g., a black image).

During the second reset period for switching the (N + 1) -th image to the (N + 2) -th image, the first data voltage is supplied to the pixels of the odd pixel groups among all the pixels of the display panel 100. At this time, the first data voltage is for displaying a white image, and the pixels of odd pixel groups can be reset to a white image.

On the other hand, in the second reset period for switching the (N + 1) th image to the (N + 2) th image, the second data voltage is supplied to the pixels of the even pixel groups among all the pixels of the display panel 100. At this time, the second data voltage is for displaying a black image, and the pixels of the even pixel groups may be reset to a black image.

As described above, in the first reset period and the second reset period, the white image and the black image are alternately displayed in units of pixel groups, and the boundaries of the pixel groups are formed differently each time the image is switched, Screen blinking phenomenon and afterimage are not generated.

17 and 18 are views showing a method of driving an electrophoretic display device according to a fifth embodiment of the present invention.

17 and 18, the even pixel groups and the odd pixel groups may be formed in a vertical stripe shape with respect to the vertical direction.

If the even pixel group and the odd pixel group are alternately formed in the vertical stripe form, the white image and the black image are alternately displayed in the vertical line unit in the first reset period and the second reset period for image switching, The entire pixel can be reset without blinking.

Here, each of the even pixel groups and the odd pixel groups may be composed of at least two or more pixels. It is possible to reconstruct the even pixel groups and the odd pixel groups every time the screen is switched. That is, the boundary between the even pixel groups and the odd pixel groups can be changed without being fixed each time the screen is switched.

As an example, a boundary between even pixel groups and odd pixel groups when converting the Nth image to the (N + 1) th image and a boundary between odd pixel groups and odd pixel groups when converting the (N + 1) And the boundary between the odd pixel groups are different from each other.

FIG. 17 shows an example of a driving method for refreshing a previous image when the Nth image is switched to the (N + 1) th image.

In the first reset period for switching the Nth image to the (N + 1) th image, the first data voltage based on the even waveform is supplied to the pixels in the even pixel group to reset the image. At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the pixels of the even pixel group to a white image.

Further, in the first reset period for switching the Nth image to the (N + 1) th image, the second data voltage based on the odd waveform is supplied to the pixels of the odd pixel group to reset the image. At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the pixels of the odd pixel group to a black image.

Here, since the even pixel groups and the odd pixel groups are formed in a mutually orthogonal direction, the white image and the black image are displayed symmetrically in the form of a vertical stripe so that the Nth image is refreshed.

18 shows an example of a driving method for refreshing a previous image when the (N + 1) -th image is switched to the (N + 2) -th image.

In the first reset period for switching the (N + 1) -th image to the (N + 2) -th image, the first data voltage based on the even waveform is supplied to the pixels in the even pixel group to reset the image. At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the pixels of the even pixel group to a white image.

Further, in the first reset period for switching the (N + 1) -th image to the (N + 2) -th image, the second data voltage based on the odd wave form is supplied to the pixels of the odd pixel group to reset the image. At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the pixels of the odd pixel group to a black image.

Here, since the even pixel groups and the odd pixel groups are formed in a mutually orthogonal direction in the vertical line direction, the white image and the black image are displayed symmetrically in the form of a vertical stripe so that the (N + 1) th image is refreshed .

As described above, in the first reset period and the second reset period for switching the image, the white image and the black image are displayed in a mutually orthogonal line unit, so that the screen flickering due to the refresh of the pixels is not generated.

Also, every time the image is switched, the pixel groups are reconstructed to change the boundary between the even pixel groups and the odd pixel groups, so that the screen flickering due to the refresh and the after-image of the previous image are not generated.

19 and 20 are views showing a driving method of an electrophoretic display device according to a sixth embodiment of the present invention.

Referring to FIGS. 19 and 20, the even pixel groups and the odd pixel groups may be formed in a horizontal stripe shape with respect to the horizontal direction.

If the odd pixel groups and the odd pixel groups are alternately formed in the horizontal stripe form, the white image and the black image are alternately displayed in the first reset period and the second reset period in units of horizontal lines, The pixel can be reset.

Here, each of the even pixel groups and the odd pixel groups may be composed of at least two or more pixels. It is possible to reconstruct the even pixel groups and the odd pixel groups every time the screen is switched. That is, the boundary between the even pixel groups and the odd pixel groups can be changed without being fixed each time the screen is switched.

As an example, a boundary between even pixel groups and odd pixel groups when converting the Nth image to the (N + 1) th image and a boundary between odd pixel groups and odd pixel groups when converting the (N + 1) And the boundary between the odd pixel groups are different from each other.

FIG. 19 shows an example of a driving method for refreshing a previous image when the Nth image is switched to the (N + 1) th image.

In the first reset period for switching the Nth image to the (N + 1) th image, the first data voltage based on the even waveform is supplied to the pixels in the even pixel group to reset the image. At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the pixels of the even pixel group to a white image.

Further, in the first reset period for switching the Nth image to the (N + 1) th image, the second data voltage based on the odd waveform is supplied to the pixels of the odd pixel group to reset the image. At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the pixels of the odd pixel group to a black image.

Here, since the even pixel groups and the odd pixel groups are formed symmetrically with respect to the horizontal line direction, the white image and the black image are displayed symmetrically in the form of a horizontal stripe so that the Nth image is refreshed.

Next, FIG. 20 shows an example of a driving method for refreshing a previous image when the (N + 1) -th image is switched to the (N + 2) -th image.

In the first reset period for switching the (N + 1) -th image to the (N + 2) -th image, the first data voltage based on the even waveform is supplied to the pixels in the even pixel group to reset the image. At this time, the first data voltage may be supplied with a voltage for displaying a white image to reset the pixels of the even pixel group to a white image.

Further, in the first reset period for switching the (N + 1) -th image to the (N + 2) -th image, the second data voltage based on the odd wave form is supplied to the pixels of the odd pixel group to reset the image. At this time, the second data voltage may be supplied with a voltage for displaying a black image to reset the pixels of the odd pixel group to a black image.

Here, since the even pixel groups and the odd pixel groups are formed symmetrically with respect to the horizontal line direction, the white image and the black image are displayed symmetrically in the form of a horizontal stripe so that the (N + 1) th image is refreshed .

As described above, in the first reset period and the second reset period for switching the image, the white image and the black image are displayed in a mutually orthogonal line unit, so that the screen flickering due to the refresh of the pixels is not generated.

Also, every time the image is switched, the pixel groups are reconstructed to change the boundary between the even pixel groups and the odd pixel groups, so that the screen flickering due to the refresh and the after-image of the previous image are not generated.

After the reset period described with reference to Figs. 7 to 20, the image data is updated to all pixels formed on the display panel 100 to display a new image, as shown in Fig. A data voltage of positive (+) and negative (-) polarity is supplied to the pixels for several to several tens of frames using an update waveform according to the gradation of the screen to be displayed at each pixel, thereby updating the data of the next image.

The previous image displayed on the display panel 100 may be reset by the electrophoretic display device and the driving method thereof according to the embodiment of the present invention, and the next image may be displayed by updating the data of the next image. Particularly, when the screen is switched, the afterimage and blinking of the previous image can be reduced to improve the display quality.

In the electrophoretic display device and the driving methods thereof according to the embodiments of the present invention described with reference to FIGS. 2 to 20, when an image is displayed at 16 gray levels, 256 (16gray.times.16gray) Is required. At this time, in the present invention, since two kinds of reset waveforms for resetting the white image to black and resetting the black image to white are further added, a total of 512 reset waveforms are provided and 512 reset waveforms Refresh the previous image.

The first reset period and the second reset period of the plurality of reset waveforms (for example, 512 reset waveforms) applied to the electrophoretic display device and the driving methods thereof according to the embodiment of the present invention have the same time and synchronization May be matched.

However, without being limited thereto, the first reset period and the second reset period of the plurality of reset waveforms (for example, 512 reset waveforms) may not coincide with the same time and synchronization.

The start point of the first reset period for resetting the previous picture and the point of time at which the data update of the next picture ends are determined by the waveform applied to the pixel requiring the most time for the reset and data update.

Here, the pixel requiring the most time for resetting and updating data is a pixel for resetting the white image of the previous image to the black image, and then updating the next image to the white image. Also, it is a pixel that resets the black image of the previous image to the white image, and then updates the next image to the black image.

In addition, the total length of the waveform applied to the pixel where the data is updated by Gray to Gray is short.

The length of the first reset period (generally any gray to white or black) may also vary depending on the gray of the previous image that each pixel was displaying. The gray of the previous image and the gray of the next image may be different for each pixel so that the start point of the second reset period or the data update start point and end point of the next image may also be different for each pixel or for each pixel group.

Since the gray of the previous image may be different for each pixel or for each pixel group, the first reset period and the second reset period are not clearly separated in time, and the gray of the previous image, Therefore, the time and synchronization of the first reset period and the second reset period can be flexibly changed.

Depending on the gray of the previous image displayed at each pixel, the start and end points of the first reset period may be different. Further, depending on the gray of the previous image displayed in each pixel, the start point and the end point of the second reset period may be different. In addition, depending on the gray of the next image to be displayed in each pixel, the end point of data update may be different.

When refreshing a previous image by pixel units as in the first to third driving methods of the present invention and setting an even pixel group and an odd pixel group as in the fourth to sixth driving methods to refresh the previous image , The time and synchronization of the first reset period and the second reset period of the reset waveform may be different.

That is, when the previous picture is reset in units of individual pixels by using the first waveform and the previous picture is reset in units of the pixel group composed of a certain number of pixels by using the second waveform, The start and end points of the first and second reset periods of the two-wave form may be different.

The electrophoretic display device and the driving methods thereof according to the embodiment of the present invention described with reference to FIGS. 2 to 20 can be applied even when the first reset period and the second reset period are not clearly separated temporally in all the pixels.

In the above description, the first through third driving methods and the fourth through sixth driving methods are applied, respectively. However, the present invention is not limited to this, and the first through sixth driving methods may be mixed and applied. In this case, one of the first to third driving methods may be applied to the pixels corresponding to 1/2 of all the pixels, and one of the fourth to sixth driving methods may be applied to the remaining half of the pixels have.

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.

1: lower substrate 2: upper substrate
10: electrophoretic capsule 12, 42: charged particle
14, 44: solvent 20: pixel electrode
30: common electrode 40: display solvent
50: partition wall 100: display panel
200: gate driver 300: data driver
400: control unit 500:

Claims (24)

When switching from the previous image to the next image, the entire pixels are composed of a plurality of even pixel groups and a plurality of odd pixel groups,
Resetting the plurality of odd pixel groups to a first image using a first reset waveform in a first reset period, resetting the plurality of odd pixel groups to a second image,
Resetting the plurality of odd pixel groups to a second image using a second reset waveform in a second reset period, resetting the plurality of odd pixel groups to a first image,
Each of the plurality of even pixel groups and some of the plurality of odd pixel groups reconstructs pixel groups in n horizontal line units (n is a natural number) and n vertical line units every time the screen is switched, Wherein the pixel groups reconstruct pixel groups in m horizontal line units (m is a natural number different from n) and m vertical line units. delete The method according to claim 1,
In the first reset period,
Supplying a first data voltage for display of the first image to the plurality of groups of even pixels and supplying a second data voltage for display of the second image to the plurality of odd pixel groups, . The method according to claim 1,
In the second reset period,
Supplying a first data voltage for display of the first image to the plurality of odd pixel groups and supplying a second data voltage for display of the second image to the plurality of even pixel groups, . The method according to claim 1,
Wherein the plurality of odd pixel groups and the plurality of odd pixel groups are formed in a lattice pattern. The method according to claim 1,
Wherein the plurality of odd pixel groups and the plurality of odd pixel groups are formed in a delta structure. When switching from the previous image to the next image, the entire pixels are composed of a plurality of even pixel groups and a plurality of odd pixel groups,
Resetting the plurality of odd pixel groups to a first image using a first reset waveform in a first reset period, resetting the plurality of odd pixel groups to a second image,
Resetting the plurality of odd pixel groups to a second image using a second reset waveform in a second reset period, resetting the plurality of odd pixel groups to a first image,
Each of the plurality of even pixel groups and the plurality of odd pixel groups rearranges pixel groups in units of n (n is a natural number) vertical lines, and the remaining pixel groups are m ≪ / RTI > is a natural number different from n). When switching from the previous image to the next image, the entire pixels are composed of a plurality of even pixel groups and a plurality of odd pixel groups,
Resetting the plurality of odd pixel groups to a first image using a first reset waveform in a first reset period, resetting the plurality of odd pixel groups to a second image,
Resetting the plurality of odd pixel groups to a second image using a second reset waveform in a second reset period, resetting the plurality of odd pixel groups to a first image,
Each of the plurality of even pixel groups and the plurality of odd pixel groups rearranges pixel groups in units of n horizontal lines (n is a natural number), and the remaining pixel groups are m (m Wherein the pixel groups are reconstructed in units of horizontal lines of a natural number different from n. delete 9. The method according to any one of claims 1 to 8,
The number of pixels included in at least one of the at least one even-numbered pixel group and at least one odd-pixel group is changed each time the screen is switched. delete 9. The method according to any one of claims 1 to 8,
Wherein the boundary between the plurality of odd pixel groups and the plurality of odd pixel groups is changed every time the screen is switched. delete 9. The method according to any one of claims 1 to 8,
Wherein the first image is a white image and the second image is a black image. 9. The method according to any one of claims 1 to 8,
Wherein a starting point and an ending point of the first reset period are different from each other and a starting point and an ending point of the second reset period are different according to a gray of a previous image displayed in each pixel. delete 9. The method according to any one of claims 1 to 8,
Wherein the end point of data update differs depending on the gray of the next image to be displayed in each pixel. 9. The method according to any one of claims 1 to 8,
Resetting the previous picture in units of individual pixels using the first waveform,
The second waveform is used to reset the previous picture in units of a pixel group composed of a certain number of pixels,
Wherein a start point and an end point of a first reset period and a second reset period of the first waveform and the second waveform are different from each other. A display panel in which a plurality of even pixel groups and a plurality of odd pixel groups are formed;
A first reset waveform and a second reset waveform for resetting the previous picture, and an update waveform for updating the next picture;
A gate driver for supplying scan pulses to the plurality of odd pixel groups and the plurality of odd pixel groups in a first reset period and a second reset period; And
A data driver for supplying a data voltage for reset in the first reset period and the second reset period to the plurality of odd pixel groups and the plurality of odd pixel groups based on the first reset waveform and the second reset waveform, Including,
Wherein in the first reset period and the second reset period, different images are alternately displayed in the plurality of even pixel groups and the plurality of odd pixel groups to reset the previous image,
Each of the plurality of even pixel groups and some of the plurality of odd pixel groups reconstructs pixel groups in n (n is a natural number) horizontal line unit and n vertical line unit every time the screen is switched, and the remaining pixels Wherein the groups reconstitute the pixel groups in units of m horizontal lines and m vertical lines, where m is a natural number different from n. 20. The method of claim 19,
An electrophoretic display device for alternately supplying a first data voltage for displaying a white image and a second data voltage for displaying a black image to the plurality of odd pixel groups and a plurality of odd pixel groups to reset a previous image, . 21. The method of claim 20,
And resetting the plurality of odd pixel groups to a white image and resetting the plurality of odd pixel groups to a black image using the first reset waveform in the first reset period. 21. The method of claim 20,
And resetting the plurality of odd pixel groups to a white image and resetting the plurality of even pixel groups to a black image using the second reset waveform in the second reset period. A display panel in which a plurality of even pixel groups and a plurality of odd pixel groups are formed;
A first reset waveform and a second reset waveform for resetting the previous picture, and an update waveform for updating the next picture;
A gate driver for supplying scan pulses to the plurality of odd pixel groups and the plurality of odd pixel groups in a first reset period and a second reset period; And
A data driver for supplying a data voltage for reset in the first reset period and the second reset period to the plurality of odd pixel groups and the plurality of odd pixel groups based on the first reset waveform and the second reset waveform, Including,
Wherein in the first reset period and the second reset period, different images are alternately displayed in the plurality of even pixel groups and the plurality of odd pixel groups to reset the previous image,
Each of the plurality of even pixel groups and the plurality of odd pixel groups rearranges pixel groups in units of n (n is a natural number) vertical lines, and the remaining pixel groups are m ≪ / RTI > is a natural number different from n). A display panel in which a plurality of even pixel groups and a plurality of odd pixel groups are formed;
A first reset waveform and a second reset waveform for resetting the previous picture, and an update waveform for updating the next picture;
A gate driver for supplying scan pulses to the plurality of odd pixel groups and the plurality of odd pixel groups in a first reset period and a second reset period; And
A data driver for supplying a data voltage for reset in the first reset period and the second reset period to the plurality of odd pixel groups and the plurality of odd pixel groups based on the first reset waveform and the second reset waveform, Including,
Wherein in the first reset period and the second reset period, different images are alternately displayed in the plurality of even pixel groups and the plurality of odd pixel groups to reset the previous image,
Each of the plurality of even pixel groups and the plurality of odd pixel groups constituting pixel groups in n (n is a natural number) horizontal line units and the remaining pixel groups constitute m (N is a natural number different from n).

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