JP4296116B2 - Electrophoretic display device - Google Patents

Description

  The present invention relates to a display device, and more particularly to an electrophoretic display device.

  Expectations for electrophoretic display devices, which are reflective display devices, are increasing from the viewpoint of reducing power consumption and reducing the burden on eyes. The electrophoretic display device includes an electrophoretic particle having a charge, a dispersion liquid made of an insulating liquid, and a pair of electrodes. By applying an electric field to the dispersion liquid through the electrode, the electrophoretic particle is converted into the charge. Is moved over the opposite polarity electrode to display an image. In addition to a wide viewing angle, high contrast, and low power consumption, the electrophoretic display device has an advantage that the structure is simple and the display panel is easily enlarged.

As such an electrophoretic display device, for example, a device is known in which an insulating liquid in which a dye is dissolved bears the contrast color of electrophoretic particles (see, for example, Non-Patent Document 1). More specifically, when the electrophoretic particles adhere to the surface of the first electrode close to the observer, the observer observes the color of the electrophoretic particles and the electrophoretic particles are distant from the observer. When adhering to the surface of the electrode, the color of the electrophoretic particles is concealed by the insulating liquid, so that the color of the insulating liquid is observed. On the other hand, an electrophoretic display device in which a dispersion composed of a colored solvent and colored particles is enclosed in microcapsules is also known (see, for example, Patent Document 1). Recently, electrophoretic display technology that displays two colors by dispersing white and black particles of different polarities in a transparent solvent and enclosing them in microcapsules and changing the polarity of the applied voltage is also known. (For example, refer nonpatent literature 2).
Japanese Patent No. 2551783 Proceedings of SID (Proc. SID), Vol. 18, 267 (1977) Nature, 394, 253 (1998)

  Generally, in the electrophoretic display method, there is no threshold characteristic between the applied voltage and the display color characteristic. Therefore, when the display panel is driven in a matrix, a thin film transistor (TFT) matrix array conventionally used in a liquid crystal display or the like is used. Each pixel electrode is used for switching driving.

  However, in general, the information retention time possessed by the electrophoretic particles, that is, the time that the electrophoretic particles remain in place when the voltage application is cut off, is short and exceeds the information retention time possessed by the electrophoretic particles. In order to hold the information, it is necessary to drive the TFT circuit at a predetermined time interval to refresh the information. Conventionally, it is desired to solve such a problem in the driving technology of an electrophoretic display device using TFTs.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a display device that realizes a desired memory function with a simple cell structure.

According to this invention,
A partition structure that defines pixel spaces arranged in rows and columns, each of which is finely partitioned;
A dispersion liquid in which electrophoretic particles colored in a first color are dispersed and stored in the pixel space;
A plurality of pixel electrodes, each facing the pixel space and electrically isolated from each other;
A plurality of common electrodes that are opposed to the pixel electrode columns along the columns through the dispersion liquid, each extending along the corresponding column;
The pixel electrode column or the pixel electrode row along the column or the row is opposed to the pixel electrode column or the pixel electrode row through the dispersion liquid, and each extends along the corresponding column or row, and is electrically separated from the common electrode. A plurality of columns or rows of control electrodes,
In the display mode, a first voltage or a second voltage is applied to each of the pixel electrodes according to an image to be displayed, a third voltage between the first and second voltages is applied to the common electrode, and the pixel A display voltage generation unit configured to display the first color and the second color different from the first color by accumulating the electrophoretic particles toward one of the pixel electrode and the common electrode for each space; and In the image holding mode, a control voltage generator that applies a control voltage to the control electrode to hold the accumulation of the electrophoretic particles in the display mode;
And a display device.

Moreover, according to this invention,
A partition structure that defines pixel spaces arranged in rows and columns, each of which is finely partitioned;
A dispersion liquid in which electrophoretic particles colored in a first color are dispersed and stored in the pixel space;
A plurality of pixel electrodes, each facing the pixel space and electrically isolated from each other;
A plurality of common electrodes that are opposed to the pixel electrode columns along the columns through the dispersion liquid, each extending along the corresponding column;
The common electrodes are a plurality of columns or rows of first and second control electrodes, each extending along the corresponding column or row, wherein the first and second control electrodes are electrically separated. The second control electrode is disposed in each pixel space, and is opposed to the pixel electrode column or pixel electrode row along the column or row via the dispersion liquid. A control electrode;
In the display mode, a first voltage or a second voltage is applied to each of the pixel electrodes according to an image to be displayed, a third voltage between the first and second voltages is applied to the common electrode, and the pixel A display voltage generation unit configured to display the first color and the second color different from the first color by accumulating the electrophoretic particles toward one of the pixel electrode and the common electrode for each space; and In the image holding mode, a control voltage generating unit that applies a control voltage to the first and second control electrodes to hold the accumulation of the electrophoretic particles in the display mode;
And a display device.

Furthermore, according to the present invention,
A partition structure that defines pixel spaces arranged in rows and columns, each of which is finely partitioned;
A dispersion liquid in which electrophoretic particles colored in a first color are dispersed and stored in the pixel space;
A plurality of pixel electrodes, each facing the pixel space and electrically isolated from each other;
A plurality of common electrodes that are opposed to the pixel electrode columns along the columns through the dispersion liquid, each extending along the corresponding column;
The pixel electrode column or the pixel electrode row along the column or the row is opposed to the pixel electrode column or the pixel electrode row through the dispersion liquid, and each extends along the corresponding column or row, and is electrically separated from the common electrode. A plurality of columns or rows of control electrodes,
In a method for driving a display device comprising:
In the display mode, a first voltage or a second voltage is applied to each of the pixel electrodes according to an image to be displayed, a third voltage between the first and second voltages is applied to the common electrode, and the pixel In each image, the electrophoretic particles are accumulated toward one of the pixel electrode and the common electrode to display one of the first color and a second color different from the first color, and in an image holding mode, A method for driving the display device is provided, wherein a control voltage is applied to the control electrode to maintain the accumulation of the electrophoretic particles in the display mode.

  According to the electrophoretic display device of the present invention, after the image information is rewritten, a predetermined voltage is applied to the control wiring, and the image information can be held. Therefore, there is no need to rewrite the displayed information by always driving the switching element. In other words, according to the display device of the present invention, it is possible to provide a display device that realizes a memory function that can hold display information for a long time with a simple structure.

  Further, according to the electrophoretic display device of the present invention, the display element can be changed by selectively driving the switching element, and information can be rewritten at a high speed. Furthermore, according to the electrophoretic display device of the present invention, since the control electrode can be provided in the vicinity of the common electrode, the voltage applied to the control electrode when information is held can be lowered. Furthermore, according to the electrophoretic display device of the present invention, since two or more control electrodes are provided in the pixel space and the voltage can be set independently, an electric field suitable for rewriting information can be formed, and the response speed In addition, display characteristics can be improved.

  Hereinafter, an electrophoretic display device according to an embodiment of the present invention will be described with reference to the drawings.

  In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic, and the relationship between the thickness and the planar dimensions, the ratio of the thickness of each layer, and the like are different from the actual ones. Therefore, specific thicknesses and dimensions should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included in the drawings. Further, the following first and second embodiments exemplify apparatuses and methods for embodying the technical idea of the present invention, and the technical idea of the present invention is a component part. The material, shape, structure, arrangement, etc. are not specified below. The technical idea of the present invention can be variously modified within the scope of the claims.

(First embodiment)
FIG. 1 is a sectional view schematically showing an electrophoretic display device according to a first embodiment of the present invention. FIG. 2 is a plan view schematically showing the electrophoretic display device shown in FIG. FIG.

  In the electrophoretic display device shown in FIG. 1, colored electrophoretic particles 2 are dispersed in an insulating liquid 1 in a state having a surface charge. The insulating liquid 1 is filled in pixel spaces, and each pixel space is defined by a partition wall 4, a transparent first substrate 5, and a second substrate 6. That is, the first substrate 5 and the second substrate 6 are arranged to face each other, and the space between them is partitioned into a plurality of minute pixel spaces by the partition walls 4 arranged at equal intervals to form a partition structure. .

  In the display device, pixel electrodes 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Are formed on the first substrate 5 in each pixel space. The pixel electrode 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...) And the pixel space are arranged in a matrix of a matrix. Each constitutes a display pixel (Qi, j, Qi, j + 1, Qi + 1, j, Qi + 1, j + 1,...). As shown in FIG. 2, a plurality of common electrodes 9 (9j-1, 9j,...) Extend in the column direction and are arranged on the second substrate 6 at regular intervals. Each common electrode 9 (9j-1, 9j,...) Is connected to a pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...). ..) formed in a smaller area and arranged so that the common electrode 9 (9j-1, 9j,...) Is located around the pixel electrode 7 as viewed from the observer as shown in FIG. Has been. That is, each common electrode 9 (9j-1, 9j,...) Is formed on the second substrate 6 so as to face the end face of the partition wall 4.

  The dispersion liquid 3 includes, for example, black resin toner (particle diameter: 1 μm) as the electrophoretic particles 2, and includes, for example, isoparaffin as the insulating liquid 1. The electrophoretic particles 2 and the insulating liquid 1 are mixed so that the mixing weight ratio of the electrophoretic particles 2 is 10%. In order to improve the dispersion stability of the electrophoretic particles 2, a small amount of surfactant is used. Is added to the dispersion 3. In the dispersion 3 as in this example, the surface of the electrophoretic particle 2 is positively charged.

  As already described, the pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Is formed on the first substrate 5 as follows. Each of the pixels (Qi, j, Qi, j + 1, Qi + 1, j, Qi + 1, j + 1,...) Corresponds to the other pixels (Qi, j, Qi, j + 1). , Qi + 1, j, Qi + 1, j + 1,...). The pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Is formed on the surface of the first substrate 5 facing the insulating liquid. For example, aluminum (Al) is sputtered, and then the aluminum (Al) is etched into a desired pattern by photolithography.

  Further, on the second substrate 6, each pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Is opposed. A transparent control electrode 8 (8j-1, 8j, 8j + 1,...) Is formed so as to be electrically separated from the common electrode 9 (9j-1, 9j,...). Yes. As shown in FIG. 2, the control electrodes 8 (8j-1, 8j, 8j + 1,...) Are also arranged in the column direction in the same manner as the common electrodes 9 (9j-1, 9j,...). It extends and is arranged on the second substrate 6 at a constant interval. In the structure shown in FIG. 2, the control electrodes 8 (8j-1, 8j, 8j + 1,...) Extend in the column direction, but the control electrodes 8 (8j-1, 8j,. 8j + 1,... May be insulated from the common electrode 9 (9j-1, 9j,...) And may extend in the row direction.

  The control electrodes 8 (8j-1, 8j, 8j + 1,...) Are provided for holding and storing images displayed on the pixels. When the electrophoretic particle 2 is positively charged, a positive voltage is applied to the control electrode 8 (8j-1, 8j, 8j + 1,...), And the electrophoretic particle 2 is negative. Is negatively charged, a negative voltage is applied to the control electrode 8 (8j-1, 8j, 8j + 1,...). By applying such a voltage to the control electrode 8 (8j-1, 8j, 8j + 1,...), The control electrode 8 (8j-1, 8j, 8j + 1,. ...) can be prevented.

  In the display device shown in FIG. 1, when image data is supplied to the drive circuit 16, the common electrode voltage at the common electrode 9 (9j-1, 9j,...) Is set in the display mode. Then, a signal voltage is applied to the pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) To display an image. Thereafter, when the display mode is shifted to the image holding mode, a voltage is applied to the control electrode 8 (8j-1, 8j, 8j + 1,...) To hold the displayed image.

  In the display device shown in FIG. 1, each of the pixel electrodes 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Is an insulating film 11. The control electrode 8 (8j-1, 8j, 8j + 1,...) And the common electrode 9 (9j-1, 9j,. It is covered. The insulating films 10 and 11 are preferably provided to adjust the adsorption ability of the electrophoretic particles 2 to the electrodes 7 and 9, but the insulating films 10 and 11 are not necessarily provided. When the insulating film 10 is provided, the insulating film 10 needs to be transparent in order to see through the pixel space.

  An active element layer 13 is provided on the substrate 5, and pixel electrodes 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,. ... And an insulating layer 11 are provided. As shown in FIG. 2, a plurality of signal wirings 14j, 14j + 1, 14j + 2,... Extend in the column direction in parallel to each other, and a plurality of gate wirings 15i-1, 15i, 15i + 1,. Are formed in the active element layer 13 so as to extend in parallel to each other in the row direction orthogonal to the signal wirings 14j, 14j + 1, 14j + 2,. As shown in FIGS. 3 and 4, the signal wirings 14j-1, 14j, 14j + 1,... And the gate wirings 15i-1, 15i, 15i + 1,. , Selection transistors Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,... Are arranged as switching elements. Note that the select transistor is omitted in FIGS. 1 and 2 for the sake of simplicity.

  The plurality of signal wirings 14j, 14j + 1,... Are arranged on the first substrate 5 in a region between adjacent pixel electrodes 7j-1, 7j, 7j + 1,. Is extended in the direction. The gate wirings 15i, 15i + 1,... Are a plurality of pixels Qi, j, Qi, j + 1, Qi + 1, j, Qi + 1, j + 1, arranged in the row direction of the matrix. .. Corresponding to each other in the row direction.

FIG. 4 shows a structure of a selection transistor Ti, j and its wiring. The selection transistor Ti, j shown in FIG. 4 constitutes a thin film transistor having an inverted stagger structure. 3, the gate electrode 21 connected to the gate wirings 15i, 15i + 1,... Is formed on the first substrate 5, and the gate electrode 21 and the first substrate 5 are gated. It is covered with an insulating film 24. A semiconductor layer 25 is formed in a region on the gate insulating film 24 so as to face the gate electrode 21. On the source and drain regions of the semiconductor layer 25, the source electrode 22 and the drain are spaced apart from each other by a predetermined distance. An electrode 23 is provided. The source electrode 22 and the drain electrode 23 extend in opposite directions, the source electrode 22 is connected to the signal electrode 14j, and the drain electrode 23 is connected to the pixel electrode Ti, j. The source electrode 22, the drain electrode 23, and the gate insulating film 24 are covered with an insulating resin layer 26, and pixel electrodes 7 i, j are formed on the resin layer 26. The pixel electrode 7 i, j is connected to the drain electrode 23 through a contact hole 28 provided in the resin layer 26. An insulating layer 11 as a first dielectric layer is formed on the pixel electrode 7i, j.

  As described above, the insulating layer as the first dielectric layer 11 is the pixel electrode 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,... ..)) To prevent irreversible adsorption of the electrophoretic particles 2, and the insulating layer 11 as the first dielectric layer is disposed to bear a contrasting color with respect to the electrophoretic particles 2. Yes. The insulating layer 11 as the first dielectric layer may be formed, for example, by spin coating with a barium sulfate (BaSO4) fine powder mixed in a fluororesin so as to have a thickness of about 0.5 μm.

  FIG. 4 shows only one transistor Ti, j, and other transistors Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,... Are omitted. . As is clear from the equivalent circuit of the transistor matrix array 27 shown in FIG. 5, a plurality of selection transistors Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, constituting the active element layer 13 are formed. Each gate electrode 21 of j + 1,... is connected to a corresponding gate wiring 15i, 15i + 1,..., and each source electrode 22 is connected to a corresponding signal wiring 14j, 14j + 1,. The drain electrodes 23 are connected to the corresponding pixel electrodes 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,... )It is connected to the.

  FIG. 5 shows a transistor matrix array in which an insulating liquid is regarded as capacitors Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... For each pixel space. 27 equivalent circuits are shown. That is, the capacitors Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... Are connected to the pixel electrodes 7 (7i, j, 7i, j + 1,7i +). 1, j, 7i + 1, j + 1,...) And the common electrode 9 (9j-1, 9j,...) And the first and second liquids. This corresponds to the capacitor of the insulating layers 10 and 11 as a dielectric. As is apparent from FIG. 5, the drain electrode 23 of each selection transistor Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,. 7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...)), And capacitors Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... That is, the common electrode 9 (9j-1, 9j,...) Has a plurality of pixel electrodes 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,. ... Is one electrode of capacitors Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... Opposing to the plurality of pixel electrodes 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...) So as to function as the other electrode of the capacitor. Has been placed. A plurality of capacitors Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... Are formed between one electrode and the other electrode. .

  The signal lines 14j-1, 14j, 14j + 1,... And the gate lines 15i-1, 15i, 15i + 1,... Are connected to the column driver 16a and the row driver 16b of the drive circuit 16, respectively. The driver 16 a and the row driver 16 b are connected to a common power supply circuit unit 16 c of the drive circuit 16. Accordingly, the pixel electrodes 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Are selected by the selection transistors Ti, j, Ti, j + 1,. Connected to the column driver 16a of the drive circuit 16 through Ti + 1, j, Ti + 1, j + 1,... And signal wirings 14j-1, 14j, 14j + 1,. The gate electrodes 21 of the transistors Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,... Are gate wirings 15i-1, 15i, 15i + 1,. To the row driver 16b of the drive circuit 16.

  The control electrode 8 (8j-1, 8j, 8j + 1,...) And the common electrode 9 (9j-1, 9j,...) Are common drive circuits that control the circuit shown in FIG. 16c. The common drive circuit 16c further controls data transfer to the column driver 16a and row driver 16b and ON / OFF timing of each driver.

  As already described, the plurality of common wirings 9 (9j-1, 9j,...) Are adjacent to the adjacent pixels Qi, j, Qi, j + 1, Qi + 1, j, Qi + 1. , j + 1,... extend in the column direction of the matrix, and the control wirings 8 (8j-1, 8j, 8j + 1,...) are adjacent to each other. Arranged between the electrodes 9 (9j-1, 9j, 9j + 1,...) And extended in parallel to the plurality of common electrodes 9 (9j-1, 9j,...). ing. On the common electrode 9 (9j-1, 9j,...) And the control electrode 8 (8j-1, 8j, 8j + 1,...), A second dielectric in contact with the insulating liquid. An insulating layer 10 as a layer is formed. For example, a transparent indium oxide (In 2 O 3) film is deposited as the second dielectric layer so as to have a thickness of about 0.1 μm, and the insulating layer 10 is formed as the second dielectric layer.

  Image data is externally supplied to the common drive circuit 16c of the drive circuit 16, and the common drive circuit 16c generates a row selection signal from the row driver 16b in accordance with the frame signal included in the image data, and the pixel driver 16a A selection signal is generated. Further, the common drive circuit 16c controls the control electrode 8 (8j-1, 8j, 8j + 1,...) And the common electrode 9 (9j-1, 9j,...) For each frame signal during the image holding period. ... Are provided with a control signal and a holding voltage signal for holding the frame.

  As described above, the capacitors Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... In the equivalent circuit shown in FIG. , j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1, ...) and the common electrode 9 (9j-1, 9j, ...) This corresponds to the capacity of the insulating liquid and the capacity of the insulating layers 10 and 11 as the first and second dielectrics. The insulating layer 11 as the second dielectric layer includes a common electrode 9 (9j-1, 9j,...) And a control electrode 8 (8j-1, 8j, 8j + 1,...). This is a layer provided to prevent irreversible adsorption of the electrophoretic particles 2 to the surface.

  In the electrophoretic display device shown in FIGS. 1 to 5, the pixel electrode 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...), Control A voltage is applied to the electrode 8 (8j-1, 8j, 8j + 1,...) And the common electrode 9 (9j-1, 9j,...) From the drive circuit 16 at a predetermined timing. As a result, the movement of the electrophoretic particles 2 is controlled. That is, according to the direction of the electric field, the electrophoretic particles 2 in the insulating liquid 1 are moved to an appropriate electrode.

  When the electrophoretic particles 2 are moved to the pixel electrode 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...) By this voltage control. The pixel electrode 7 (through the first substrate 5 in which the electrophoretic particles 2 are transparent, the transparent control electrode 8 (8j-1, 8j, 8j + 1,...), And the transparent insulating film 10). 7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Are observed, and the pixels are colored and displayed. The When the electrophoretic particles 2 are moved toward the common electrode 9 (9j-1, 9j,...), The common electrode 9 (9j-1, 9j,...) The electrophoretic particles 2 are accumulated in the pixel space of the transparent substrate 1 through the transparent first substrate 5, the transparent control electrode 8 (8j-1, 8j, 8j + 1,...), And the transparent insulating film 10. If the insulating film 11 is transparent, the pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Is observed. Therefore, the insulating film 11 is light-reflective white or the pixel electrode 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...) Is light-reflective. If it is white, white is displayed. If the pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Insulating film 11 is transparent, the surface color of the substrate 5, for example, A light-reflective white is observed.

  In addition, the organic or inorganic insulating material as a material for forming the partition wall 4 is almost transparent. Therefore, even when the electrophoretic particles 2 are uniformly distributed on the pixel electrodes 7 to display black, the transparent partition walls 4 are visually recognized, which may reduce the contrast. In addition, the use of colored partition walls has technical problems such as the elution of pigments and dyes from the partition walls. Therefore, the common electrode 9 (9j-1, 9j,...) Provided on the upper part of the partition wall 4 corresponding to the area around the pixel electrode 7 is preferably formed of a light shielding material. If a general metal is used, sufficient light shielding ability can be given to the common electrode 9 (9j-1, 9j,...) Even with a thin film.

  In this way, the voltage of the pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,...) Is applied to the common electrode 9 (9j-1, By applying a voltage higher or lower than the voltage 9j,..., The electrophoretic particles 2 are moved to the pixel electrode 7 or the common electrode 9 (9j-1, 9j,...) Side. Desired information can be displayed. That is, the voltage of a specific pixel electrode Qp, q in a plurality of pixel electrodes 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...) Is set. By applying a voltage higher or lower than the voltage of the common electrode 9 (9j-1, 9j,...), The electrophoretic particles 2 are applied to the specific pixel electrode Qp, q side or the common electrode 9 (9j-1, 9j,. ...)) Can be moved to display desired information.

  At the time of holding information, a predetermined voltage is applied to the control electrode 8, and the electrophoretic particles 2 in the region close to the pixel electrode 7 or the region close to the common electrode 9 (9j-1, 9j,...) It is held in the area, and the color of each pixel is held as it is, so that a desired memory function can be realized. That is, when holding information, the selection transistor Tp, q corresponding to the specific pixel electrode Qp, q is turned off, and a predetermined voltage is applied to the control electrode. That is, the display holding voltage is applied to all the control electrodes 8j-1, 8j, 8j + 1,... After the pixels of the gate wirings 15i, 15i + 1,. Then, a region close to the pixel electrode 7 (7i, j, 7i, j + 1,7i + 1, j, 7i + 1, j + 1,...) Or the common electrode 9 (9j-1,9j) The electrophoretic particles 2 moved to a region close to (,...) Are held in the region, and a desired memory function can be realized. Therefore, it is not necessary to always drive the selection transistors Ti, j + 1, Ti, j, Ti, j + 1,... And rewrite the displayed information. Therefore, display information can be held with a simple structure. Specifically, when one pixel has a substrate interval of 30 μm and one side of the pixel is 127 μm, when +40 V is applied to the control electrode 8, the pixel electrode 7 and the common electrode 9 (9j-1, 9j,...) Electrophoretic particles in a region close to are retained in that region.

  Next, the operation of the display device will be described in more detail with reference to FIGS. Here, the selection transistors Ti, j + 1, Ti, j, Ti, j + 1,... Are n-channel thin film transistors. The rewrite operation in the image display mode is performed from the top to the bottom of the paper in FIG. 5 with a plurality of pixels Qi, j + 1, Qi, j, Qi, j + 1, i-th rows along the i-th gate wiring 15i. ..., A plurality of (i + 1) th row pixels Qi + 1, j + 1, Qi + 1, j, Qi + 1, j + 1,... Along the (i + 1) th gate wiring 15i + 1. ..,... Shall be rewritten in the order.

  (A) First, as a rewriting operation, a voltage 0 V is applied from the drive circuit 16 to the common electrode 9 (9j-1, 9j,...), And all the control electrodes 8j-1, 8j,. An intermediate voltage of 5V is applied to 8j + 1,.

  (B) Next, a voltage of 50 V is applied from the row driver 16b shown in FIG. 5 to the i-th row gate wiring 15i. Accordingly, the selection transistors Ti, j-1, Ti, j, Ti, j + 1,... In the i-th row along the i-th row gate wiring 15i are turned on. Then, the voltage + 10V or the voltage −10V is applied to the signal wirings 14j−1, 14j, 14j + 1,... According to the desired image data from the column driver 16a. Accordingly, the pixel electrode 7 (7i, j-1,7i, j, 7i, j + 1,...) Is maintained at the voltage + 10V or the voltage −10V depending on the color to be displayed. As a result, in the display mode, a line image is displayed in i row of a certain pixel.

  (C) Thereafter, a voltage of 0 V is applied from the row driver 16b to the gate wiring 15i in the i-th row. Accordingly, the selection transistors Ti, j + 1, Ti, j, Ti, j + 1,... Along the i-th gate wiring 15i are turned off. At the same time, the voltage 50V is applied to the gate wiring 15i + 1 in the (i + 1) th row, and each of the selection transistors Ti + 1, j + 1, Ti + 1, j, Ti + 1, j + 1, along the gate wiring 15i + 1. ... are turned on. At the same timing, a voltage + 10V or a voltage −10V is applied from the column driver 16a to the signal wirings 14j-1, 14j, 14j + 1,. Accordingly, the pixel electrode 7 (7i + 1, j-1, 7i + 1, j, 7i + 1, j + 1,...) Is set to a voltage + 10V or a voltage −10V depending on the color to be displayed. Maintained. Accordingly, the pixel electrode 7 (7i + 1, j-1, 7i + 1, j, 7i + 1, j + 1,...) Is set to a voltage + 10V or a voltage −10V depending on the color to be displayed. Maintained. As a result, a line image is displayed in the (i + 1) row of a certain pixel in the display mode.

  (D) The above operation is repeated up to the last row, that is, the row along the n-th gate wiring 15n (assuming there are n rows). That is, when the information rewriting operation is completed for the entire screen, the voltage 0V is applied from the row driver 16b to the last gate wiring 15n, and all the selection transistors Ti, j + 1, Ti, j, Ti, j + are applied. 1,..., Ti + 1, j + 1, Ti + 1, j, Ti + 1, j + 1,..., Tn, j + 1, Tn, j, Tn, j + 1,... Are turned off, and the display mode is switched to the image holding mode. In the image holding mode, select transistors Ti, j + 1, Ti, j, Ti, j + 1,..., Ti + 1, j + 1, Ti + 1, j, Ti + 1, j + 1,..., Tn, j + 1, Tn, j, Tn, j + 1,... Are maintained in the OFF state, and the column driver 16a is connected to all the control electrodes 8j-1. , 8j, 8j + 1,... Therefore, the holding voltage 40V is applied to the control electrodes 8j-1, 8j, 8j + 1,..., The pixels of the entire screen are maintained as they are, and the image is stored. In the image holding mode, the holding voltage 40V is held while being applied to the control electrodes 8j-1, 8j, 8j + 1,..., And the voltages are controlled by the control electrodes 8j-1, 8j, 8j + 1,. The image is stored as long as it is applied to.

  FIG. 6 is a timing chart for explaining the display rewriting operation of the electrophoretic display device shown in FIG. In FIG. 6, when the gate wiring 15i is on, + 10V is applied to the signal wiring 14j, and −10V is applied to the signal wiring 14j + 1. When the gate wiring 15i + 1 is on, −10V is applied to the signal wiring 14j and + 10V to the signal wiring 14j + 1. The example which applies is shown.

  In the image display process in the image display mode described above, the movement of the electrophoretic particles 2 when the electrophoretic particles 2 are positively charged will be described.

  (1) In the image display mode, when a voltage 50V is applied to a certain gate wiring 15i as shown in FIG. 6B, selection transistors Ti, j + 1, Ti, j corresponding to the row of the gate wiring 15i. , Ti, j + 1,... Are turned on. Here, as shown in FIGS. 6D and 6E, a voltage +10 V is applied to any one of the signal wirings 14j-1, 14j, 14j + 1,. When a voltage of -10 V is applied to the other signal wirings 14j-1, 14j, 14j + 1,..., The selection transistors Ti, j + 1, Ti, j, Ti, j + 1,. The voltages of approximately + 10V and −10V are applied to the pixel electrodes 7 (7i, j, 7i, j + 1...) Connected to the drain electrodes 23 of. Therefore, the electrophoretic particles 2 of the pixel corresponding to the pixel electrode 7 (7i, j, 7i, j + 1...) To which the voltage +10 V is applied are the common electrodes formed on the second substrate 6. 9 (9j-1, 9j, ...) side. As a result, the electrophoretic particles 2 are hardly visually recognized, and the color of the first substrate 5, for example, white is observed as the pixel color through the second substrate 6 or the like. In addition, the electrophoretic particles 2 of the pixel corresponding to the pixel electrode 7 (7i, j, 7i, j + 1...) To which the voltage −10 V is applied are connected to the pixel electrode 7 (7i, j, 7i, j). +1 ...) moved to the side. As a result, the electrophoretic particles 2 are not visually recognized, and the color of the electrophoretic particles 2, for example, black, is observed as the pixel color through the second substrate 6 or the like. In a certain row of pixels on the screen, black and white pixels are displayed according to the movement of the electrophoretic particles 2, and a line image having an image to be displayed is formed.

  (2) Similarly, when the voltage 50V is applied to the next gate wiring 15i + 1 as shown in FIG. 6C, the selection transistors Ti + 1, j + 1, Ti + 1, j, Ti + 1, j + 1,... are turned on. Here, as shown in FIGS. 6D and 6E, a voltage +10 V is applied to any one of the signal wirings 14j-1, 14j, 14j + 1,. When a voltage of −10 V is applied to the other signal wirings 14j−1, 14j, 14j + 1,..., The selection transistors Ti + 1, j + 1, Ti + 1, j, Ti + 1, Voltages of approximately + 10V and −10V are applied to the pixel electrodes 7 (7i + 1, j, 7i + 1, j + 1...) connected to the drain electrodes 23 of j + 1,. Applied according to the image. Therefore, the electrophoretic particles 2 of the pixels corresponding to the pixel electrodes 7 (7i + 1, j, 7i + 1, j + 1,...) To which the voltage +10 V is applied are formed on the second substrate 6. To the common electrode 9 (9j-1, 9j,...) Side. As a result, the electrophoretic particles 2 are hardly visually recognized, and the color of the first substrate 5, for example, white is observed as the pixel color through the second substrate 6 or the like. In addition, the electrophoretic particles 2 of the pixel corresponding to the pixel electrode 7 (7i + 1, j, 7i + 1, j + 1,...) To which the voltage −10 V is applied are the pixel electrode 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,... As a result, the electrophoretic particles 2 are not visually recognized, and the color of the electrophoretic particles 2, for example, black, is observed as the pixel color through the second substrate 6 or the like. In a row of pixels on the screen, black and white pixels are displayed in accordance with the movement of the electrophoretic particles 2, and the next line image of the image to be displayed is formed.

  (3) Then, after rewriting of the pixels of the gate wirings 15i-1, 15i, 15i + 1,... 15n in all rows is completed, in the image holding mode, as shown in FIG. When the display holding voltage 40V is applied to all the control wirings 8j-1, 8j, 8j + 1,..., The pixel electrodes 7 (7i, j, 7i, j + 1,. 7i + 1, j, 7i + 1, j + 1,... Or a region close to the common electrode 9 (9j-1, 9j,...) Of the second substrate 6. The electrophoretic particles 2 that have moved are held in that region as they are.

  After the image display mode, the pixel electrodes 7 (7i, j, 7i, j + 1,7i +) corresponding to the respective rows of the gate wirings 15i-1, 15i, 15i + 1,. 1, j, 7i + 1, j + 1,...) Are applied to the respective select transistors Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1, Determined by the resistance and capacitance Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,. Decay with time constant. Therefore, in order to display desired information for a time longer than the time determined by this time constant, it is necessary to return to the image display mode and repeat the rewriting operation for a certain period. According to the display device according to the first embodiment, after rewriting the information on the entire screen, 40 V is applied as the display holding voltage to all the control electrodes 8j-1, 8j, 8j + 1,. Since the display mode is shifted to the image holding mode, the selection transistors Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,... Are not driven. The desired information can be displayed for a long time.

  As described above, the display device according to the first embodiment of the present invention can provide an electrophoretic display device that realizes a desired memory function for a long time with a simple cell structure. Further, according to the display device of the present invention, the display color is changed by driving the selection transistors Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,. It is possible to rewrite information at high speed.

(Second Embodiment)
Next, a display device according to a second embodiment of the present invention will be described with reference to FIG. 7, FIG. 8, and FIG.

  As shown in FIGS. 7 and 8, two control electrodes 8 are provided in the pixel space instead of one control electrode 8. When two control electrodes 8 are provided in the pixel space as compared with the case where one control electrode 8 is provided in the pixel space, the voltage applied to the control electrode 8 at the time of holding an image can be reduced. Responsiveness can be improved when rewriting images.

  As shown in FIG. 7, the pixel structure in which the two control electrodes 8 are provided in the pixel space has a distance d between the control electrode 8 and the pixel electrode 7 as shown in FIG. The control electrode 8 and the common electrode 9 (9j-1) which are close to each other are applied to the pixel structure (d / W <0.5) in the case where the pixel structure is smaller than 1/2 (W / 2). , 9j,...) Are arranged so that the distances S between them are substantially equal.

  As shown in FIG. 1, one control electrode 8 is provided in the pixel space, and the pixel structure has a distance d between the control electrode 8 and the pixel electrode 7 as shown in FIG. 9B or 9C. Is applied to a pixel structure (d / W = 0.5, or d / W> 0.5) where is equal to or larger than 1/2 (W / 2) of the pixel width W. In such a pixel structure, since the control electrode 8 is provided in the center of the pixel, as shown in FIG. 9B or 9C, the control electrode 8 and the common electrode 9 (9j-1, 9j). ,...), The distance d between the control electrode 8 and the pixel electrode 7 is larger, and as a result, the electric field that affects image holding is between the control electrode 8 and the pixel electrode 7. It is determined by the distance d. Even if the number of control electrodes 8 is two, the distance d cannot be reduced. Therefore, the distance d between the control electrode 8 and the pixel electrode 7 is equal to ½ (W / 2) of the width W of the pixel. Alternatively, in the case of a pixel structure (d / W = 0.5 or d / W> 0.5) when it is large, only one control electrode 8 is sufficient.

  Instead of providing two control electrodes 8 in the pixel space, one wide control electrode 8 is provided, and the distance between the control electrode 8 and the common electrode 9 (9j-1, 9j,...) Is set. If it is narrowed, the control voltage can be lowered. However, there is a problem that display characteristics deteriorate when information is rewritten, particularly when black is displayed. As shown in FIG. 10A, when rewriting information, it is necessary to apply a voltage equal to or higher than the potential of the pixel electrode 7 to the control electrode 8 so that electrophoretic particles do not adhere during white display. is there. However, if the control electrode 8 is made higher than the potential of the pixel electrode 7, the electrophoretic particles are difficult to spread to the center of the pixel electrode 7 when displaying black as shown in FIG.

  In the pixel structure including one control electrode 8, when the electrophoretic particles 2 are captured by the common electrode 9 as shown in FIG. 10A, there is a gap between the control electrode 8 and the pixel electrode 7. The voltage applied to the control electrode 8 is preferably set so that the potential difference between the control electrode 8 and the common electrode 9 is larger than the potential difference. As an example, a voltage of 0 V is applied to the common electrode 9, and a voltage of 15 V and a voltage of 10 V are applied to the control electrode 8 and the pixel electrode 7. In this example, the potential difference between the control electrode 8 and the common electrode 9 is 15V, which is preferably set to be larger than the potential difference 5V between the control electrode 8 and the pixel electrode 7. However, a voltage of 0 V is applied to the common electrode 9, a voltage of 5 V and a voltage of 10 V are applied to the control electrode 8 and the pixel electrode 7, and a potential difference between the control electrode 8 and the common electrode 9 is 5 V. It has been found that when the potential difference between and is 5 V, the electrophoretic particles may be slightly attracted onto the control electrode 7.

  10B, when the electrophoretic particles 2 are captured by the pixel electrode 7, the control electrode 8 and the pixel electrode 7 can be compared with the potential difference between the control electrode 8 and the common electrode 9. Preferably, the voltage applied to the control electrode 8 is set so that the potential difference between the two electrodes increases. As an example, when the electrophoretic particles 2 are captured by the pixel electrode 7, a voltage 5 V is applied to the control electrode 8, a voltage 0 V is applied to the common electrode 9, and a voltage −10 V is applied to the pixel electrode 7. In this case, the potential difference between the control electrode 8 and the common electrode 9 is 5V, and the potential difference 15V between the control electrode 8 and the pixel electrode 7 becomes larger than the potential difference 5V, and the electrophoretic particles 2 It has been confirmed that it is uniformly distributed on the pixel electrode 7. However, when the voltage 15V is applied to the control electrode 8, the voltage 0V is applied to the common electrode 9, and the voltage -10V is applied to the pixel electrode 7, the potential difference between the control electrode 8 and the pixel electrode 7 is 25V. It has been confirmed that the electric field collection between the control electrode 8 and the pixel electrode 7 becomes excessively large and the electrophoretic particles 2 are unevenly distributed on the pixel electrode 7. Here, the electrophoretic particles 2 are non-uniform on the pixel electrode 7 in the region on the pixel electrode 7 where the color of the electrophoretic particles 2 distributed on the pixel electrode 7 should be visible. Means that the center color on the pixel electrode 7 is mixed.

  In the pixel structure including one control electrode 8, since a single voltage is applied to the control electrode 8 in the image holding mode, the voltage applied to the control electrode 8 according to the display color is set as described above. It cannot be adjusted. Therefore, in the pixel structure including one control electrode 7, the voltage applied to the control electrode 8 is such that the potential difference between the control electrode 8 and the pixel electrode 7 is substantially equal to the potential difference between the control electrode 8 and the common electrode 9. It is preferable to set.

  In order to lower the voltage of the control electrode 8, it is effective to provide two control electrodes 8 as shown in FIG. By providing the two control electrodes 8 as shown in FIG. 10 (c), the control electrode 8 can be brought close to the common electrode 9 (9j-1, 9j,...). Can be lowered. Further, when rewriting information, the substrate normal direction component of the electric field at the center of the pixel can be weakened, so that the electrophoretic particles 2 can be moved to the center of the pixel electrode 7. Further, in the white display, since the potential that repels the electrophoretic particles 2 is applied to the control electrode 8, the electrophoretic particles 2 are connected to the common electrode 9 (9j−1) as compared with the case without the control electrode 8. , 9j,...) Is shortened.

  Also in the second embodiment, the members of each part can be formed of the same material as in the first embodiment.

  According to the display device according to the second embodiment of the present invention, a plurality of pixel electrodes 7 (7i, j, 7i, j + 1, 7i + 1, j, 7i + 1, j + 1,... The voltage of the specific pixel electrode Qp, q in () is applied higher or lower than the voltage of the common electrode 9 (9j-1, 9j,...), And the electrophoretic particle 2 is applied to the specific pixel. The desired information is displayed by moving to the electrode Qp, q side or the common electrode side. Then, when holding information, the selection transistor Tp, q corresponding to the specific pixel electrode Qp, q is turned off, and a predetermined voltage is applied to the control electrode 8. In other words, after the pixel rewriting of the gate wirings of all the rows is completed, the display holding voltage is applied to all the control electrodes 8 so that the pixel electrodes 7i, j, 7i, j + 1,7i + 1, j, 7i + 1 are applied. , j + 1,...) or the electrophoretic particles 2 that have moved to the area close to the common wirings 9j-1, 9j,. realizable.

  This eliminates the need to constantly drive the selection transistor and rewrite the displayed information. Therefore, a display device that can hold display information with a simple structure can be provided.

(Other embodiments)
As described above, the present invention has been described according to the first and second embodiments. However, it should not be understood that the description and drawings constituting a part of this disclosure limit the present invention. For example, as an embodiment in which the control electrode is divided into a plurality of parts, the control electrode is divided into two in the second form, but may be divided into three or more. Dividing into three or more can make the electric field distribution more suitable for the information holding state and the rewriting state. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art. Accordingly, the technical scope of the present invention is defined only by the invention specifying matters according to the scope of claims reasonable from the above description.

It is sectional drawing which shows roughly the structure of the display apparatus which concerns on embodiment of this invention. FIG. 2 is a plan view schematically showing a planar arrangement of the display device shown in FIG. 1. FIG. 3 is a wiring diagram schematically showing connections between selection transistors and wirings connected to a certain pixel shown in FIGS. 1 and 2. It is sectional drawing which shows typically the internal structure of the active element layer in which the thin-film transistor (TFT) which has a reverse stagger structure shown by FIG. 3 is formed. FIG. 2 is a block diagram illustrating the display device illustrated in FIG. 1 and a drive circuit that drives the display device. (A)-(c) is a timing chart which shows the drive signal generated from the column driver and row driver which are shown in FIG. It is sectional drawing which shows schematically the structure of the display apparatus which concerns on other embodiment of this invention. FIG. 8 is a plan view schematically illustrating a planar arrangement of the display device illustrated in FIG. 7. (A)-(c) is sectional drawing which shows roughly the dimension of the display apparatus which concerns on various embodiment of this invention. (A)-(c) is sectional drawing which shows roughly the display operation in the display apparatus shown in FIG.1 and FIG.7.

Explanation of symbols

1. . . Insulating liquid . . 2. Electrophoretic particles . . Dispersion 4. . . Partition wall 5. . . First substrate 6. . . Second substrate 7, 7i, j, 7i, j. . . Pixel electrode 8, 8j. . . Control wiring 9, 9j-1, 9j, ... Common wiring 10． . . First dielectric layer 11. . . Second dielectric layer Qi, j. . . Pixel 13. . . Active element layers 14j-1, 14j, 14j + 1. . . Signal wiring 15i-1, 15i, 15i + 1, 15n. . . Gate wiring 16. . . Drive circuit 16a. . . Column driver 16b. . . Row driver 16c. . . Common drive circuit 21. . . Gate electrode 22. . . Source electrode 23. . . Drain electrode 24. . . Gate insulating film 25. . . Semiconductor film 26. . . Resin layer 27. . . Transistor matrix array Ci, j, Ci, j + 1, Ci + 1, j, Ci + 1, j + 1,... Capacitor Ti, j, Ti, j + 1, Ti + 1, j, Ti + 1, j + 1,... Selection transistor Qi, j, Qi, j + 1, Qi + 1, j, Qi + 1, j + 1,.

Claims (9)

A partition structure that defines pixel spaces arranged in rows and columns, each of which is finely partitioned;
A dispersion liquid in which electrophoretic particles colored in a first color are dispersed and stored in the pixel space;
A plurality of pixel electrodes, each facing the pixel space and electrically isolated from each other;
A plurality of common electrodes that are opposed to the pixel electrode columns along the columns through the dispersion liquid, each extending along the corresponding column;
The pixel electrode column or the pixel electrode row along the column or the row is opposed to the pixel electrode column or the pixel electrode row through the dispersion liquid, and each extends along the corresponding column or row, and is electrically separated from the common electrode. A plurality of columns or rows of control electrodes,
In the display mode, a first voltage or a second voltage is applied to each of the pixel electrodes according to an image to be displayed, a third voltage between the first and second voltages is applied to the common electrode, and the pixel A display voltage generation unit configured to display the first color and the second color different from the first color by accumulating the electrophoretic particles toward one of the pixel electrode and the common electrode for each space; and In the image holding mode, a control voltage generator that applies a control voltage to the control electrode to hold the accumulation of the electrophoretic particles in the display mode;
And a display device.     Each of the pixel electrodes is connected to a display voltage generation unit via a switching element, and the switching element selects the pixel electrode in each row and applies the first voltage or the second voltage to the selected pixel electrode. The display device according to claim 1. A plurality of signal lines extending substantially in parallel with the control electrode, the signal lines connecting the display voltage generating unit to the pixel electrode through the switching element, and extending substantially in parallel with each other; A plurality of gate wirings, and in the display mode, a gate wiring for applying a switching signal from the display voltage generation unit to the switching elements to turn on the switching elements;
The display device according to claim 2, further comprising:     3. The display device according to claim 2, wherein a distance d between the control electrode and the pixel electrode is equal to or greater than ½ of a width W of the pixel space. A partition structure that defines pixel spaces arranged in rows and columns, each of which is finely partitioned;
A dispersion liquid in which electrophoretic particles colored in a first color are dispersed and stored in the pixel space;
A plurality of pixel electrodes, each facing the pixel space and electrically isolated from each other;
A plurality of common electrodes that are opposed to the pixel electrode columns along the columns through the dispersion liquid, each extending along the corresponding column;
The common electrodes are a plurality of columns or rows of first and second control electrodes, each extending along the corresponding column or row, wherein the first and second control electrodes are electrically separated. A second control electrode is disposed in each pixel space, and is opposed to the pixel electrode column or pixel electrode row along the column or row via the dispersion liquid. Electrodes,
In the display mode, a first voltage or a second voltage is applied to each of the pixel electrodes according to an image to be displayed, a third voltage between the first and second voltages is applied to the common electrode, and the pixel A display voltage generation unit configured to display the first color and the second color different from the first color by accumulating the electrophoretic particles toward one of the pixel electrode and the common electrode for each space; and In the image holding mode, a control voltage generating unit that applies a control voltage to the first and second control electrodes to hold the accumulation of the electrophoretic particles in the display mode;
And a display device.     Each of the pixel electrodes is connected to a display voltage generation unit via a switching element, and the switching element selects the pixel electrode in each row and applies the first voltage or the second voltage to the selected pixel electrode. The display device according to claim 5. A plurality of signal lines extending substantially in parallel with each other along the first and second control electrodes, the signal lines connecting the display voltage generating unit to the pixel electrodes through the switching elements, and A plurality of gate wirings extending substantially in parallel, wherein in the display mode, a gate wiring for applying a switching signal from the display voltage generation unit to the switching element to turn on the switching element;
The display device according to claim 6, further comprising: The display device according to claim 6 , wherein a distance d between the control electrode and the pixel electrode is smaller than ½ of a width W of the pixel space. A partition structure that defines pixel spaces arranged in rows and columns, each of which is finely partitioned;
A dispersion liquid in which electrophoretic particles colored in a first color are dispersed and stored in the pixel space;
A plurality of pixel electrodes, each facing the pixel space and electrically isolated from each other;
A plurality of common electrodes that are opposed to the pixel electrode columns along the columns through the dispersion liquid, each extending along the corresponding column;
The pixel electrode column or the pixel electrode row along the column or the row is opposed to the pixel electrode column or the pixel electrode row through the dispersion liquid, and each extends along the corresponding column or row, and is electrically separated from the common electrode. A plurality of columns or rows of control electrodes,
In a method for driving a display device comprising:
In the display mode, a first voltage or a second voltage is applied to each of the pixel electrodes according to an image to be displayed, a third voltage between the first and second voltages is applied to the common electrode, and the pixel In each image, the electrophoretic particles are accumulated toward one of the pixel electrode and the common electrode to display one of the first color and a second color different from the first color, and in an image holding mode, Applying a control voltage to the control electrode to hold the accumulation of the electrophoretic particles in the display mode. A method for driving a display device.

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