JP2004163667A - Electro-optical apparatus, its driving method and electronic appliance - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electro-optical apparatus in which disturbance in image display can be suppressed and to provide its driving method and an electronic appliance. <P>SOLUTION: The apparatus is equipped with electrophoretic particles which are held between a common electrode and a segment electrode, which have hysteresis characteristics with a first threshold voltage Vth1 and a second threshold voltage Vth2 in accordance with voltage applied between the common electrode and the segment electrode, and which changes the characteristics in one side and the other side. A scanning line driving circuit supplies a first selected voltage at a potential VH to the common electrode in a first selected period of the common electrode and supplies a second selected voltage at a potential VL to the common electrode in a second selected period of the common electrode. A data line driving circuit supplies a data voltage at a potential VD to the segment electrode in accordance with the image data corresponding to the selected period of the common electrode. An image is formed by controlling changes in the characteristics of the electrophoretic particles in accordance with the voltage applied between the common electrode and the segment electrode based on the first or second selected voltage and the data voltage. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electro-optical device, a driving method thereof, and an electronic apparatus.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in electro-optical devices, an electrophoretic display device using an electrophoretic phenomenon has been proposed. In particular, as such an electrophoretic phenomenon, a phenomenon in which when an electric field is applied to fine particles (electrophoretic particles) in a gas or a vacuum, the particles migrate (float, etc.) is known. An electrophoretic display device using the same has been proposed.
[0003]
That is, in Patent Document 1, electrophoretic particles having different charging polarities (positive / negative) and colors (white / black) are sealed between substrates. When an electric field is applied between the substrates, the electrophoretic particles having different characteristics move (migrate) in different directions from each other and adhere to the substrates (electrodes) in the directions. At this time, electrophoretic particles distributed on the substrate on the opposite side can be seen. In Patent Literature 1, for electrophoretic particles having different characteristics arranged in a matrix on a display panel, an image is formed by controlling display density by individually controlling the electrophoretic particles distributed on a substrate. .
[0004]
[Patent Document 1]
JP 2001-313225 A
[0005]
[Problems to be solved by the invention]
Incidentally, such electrophoretic particles exhibit hysteresis characteristics when the display density is increased or decreased by switching the distribution on the substrate to one side or the other side. In addition, these electrophoretic particles have different predetermined threshold voltages when the display density is increased or decreased.
[0006]
Therefore, in driving an electrophoretic display device using these electrophoretic particles, it is common to reset the image once when changing the display density and rewrite the image, and to always change the distribution on the substrate from a fixed direction. It is a target. For example, as a driving method of such an electrophoretic display device, there is a method that employs a so-called horizontal period two-division method. That is, the selection period of the scanning line electrode (common electrode) is divided into two equal parts, and the image is reset in the first half and the image is rewritten in the second half.
[0007]
Alternatively, as another driving method of such an electrophoretic display device, there is a method employing a so-called two-field method. That is, in the field period in which all the scanning lines have been selected, the image is reset in the first field period and the image is rewritten in the next field period.
[0008]
However, in each of these driving methods, since the image is reset once when the image is rewritten, the change in the image becomes discontinuous, and display disturbance such as flicker and jitter occurs.
[0009]
An object of the present invention is to provide an electro-optical device capable of suppressing disturbance of image display, a driving method thereof, and an electronic apparatus.
[0010]
[Means for Solving the Problems]
In order to solve the above problem, the electro-optical device of the present invention is sandwiched between a first electrode and a second electrode, and a first threshold voltage and a second threshold voltage with respect to a voltage applied between the first electrode and the second electrode. An electrophoretic particle having a hysteresis characteristic having a threshold voltage and having characteristic fluctuations on one side and the other side, and the first electrode in the first selection period obtained by dividing the selection period of the first electrode into two, A first selection voltage having a first predetermined level corresponding to a first threshold voltage is supplied, and the second threshold is applied to the first electrode in the other second selection period obtained by dividing the selection period of the first electrode into two. First driving means for supplying a second selection voltage having a second predetermined level corresponding to a voltage, and data having a signal level corresponding to image data for the second electrode corresponding to a selection period of the first electrode And second driving means for supplying a voltage. The first and second selection voltages supplied by the first driving unit and the data voltage supplied by the second driving unit based on the applied voltage between the first electrode and the second electrode based on the data voltage An image is formed by controlling the characteristic fluctuation of the electrophoretic particles.
[0011]
According to the electro-optical device of the present invention, the first electrode having the first predetermined level corresponding to the first threshold voltage with respect to the first electrode in one first selection period obtained by dividing the selection period of the first electrode into two. A selection voltage is provided. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing over one threshold voltage, the characteristics of the electrophoretic particles can be changed to one side. On the other hand, a second selection voltage having a second predetermined level corresponding to the second threshold voltage is supplied to the first electrode in another second selection period obtained by dividing the selection period of the first electrode into two. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing two threshold voltages, the characteristics of the electrophoretic particles can be changed to the other side.
[0012]
By changing the characteristics of the electrophoretic particles to either one side or the other side, an image corresponding to the characteristic change can be formed. That is, even if the electro-optical device includes the electrophoretic particles having the hysteresis characteristics having the first threshold voltage and the second threshold voltage with respect to the applied voltage, it is not necessary to perform the reset process every time the image is rewritten. In addition, display disturbances such as flicker and jitter due to discontinuous image changes are suppressed.
[0013]
According to one aspect of the electro-optical device of the present invention, the electro-optical device includes a storage unit configured to store the image data, and a determination unit configured to determine increase / decrease of the current image data with respect to the stored immediately preceding image data; Has a signal level corresponding to the image data for the second electrode corresponding to one of the first and second selection periods of the first electrode according to the increase or decrease of the determined image data. A data voltage is supplied, and a hold voltage having a predetermined level is supplied to the second electrode in response to the other of the first and second selection periods of the first electrode.
[0014]
According to this aspect, according to the increase or decrease of the determined image data, the second electrode is made to respond to the image data only in response to one of the first and second selection periods of the first electrode. A data voltage having a signal level is supplied. Then, a hold voltage having a predetermined level is supplied to the second electrode corresponding to the other of the first and second selection periods of the first electrode. Therefore, the data voltage needs to be supplied only during one of the first and second selection periods required for rewriting the image in accordance with the increase or decrease of the image data. Alternatively, even when it is difficult to secure the second threshold voltage), an image is displayed with high accuracy. In other words, the condition of the threshold voltage in the other one of the first and second selection periods that is unnecessary for rewriting the image is relaxed.
[0015]
In another aspect of the electro-optical device of the present invention, the first drive unit is configured to supply the hold voltage to the second electrode in a first or second selection period of the first electrode. The supply of any one of the first and second selection voltages to the first electrode is stopped.
[0016]
According to this aspect, the hold voltage is supplied to the second electrode, and the first and second electrodes with respect to the first electrode are provided during any of the first and second selection periods that are not necessary for rewriting an image. Is stopped, and power consumption is reduced.
[0017]
The electro-optical device of the present invention has a hysteresis characteristic which is sandwiched between a first electrode and a second electrode and has a first threshold voltage and a second threshold voltage with respect to a voltage applied between the first electrode and the second electrode. An electrophoretic particle having a characteristic change on one side and the other side, and a first predetermined level corresponding to the first threshold voltage with respect to the first electrode during a selection period of a first field period of the first electrode. And a second predetermined level corresponding to the second threshold voltage with respect to the first electrode in a selection period of a second field period following the first field period of the first electrode. A first driving unit that supplies a second selection voltage; and a second driving unit that supplies a data voltage having a signal level corresponding to image data to the second electrode corresponding to a selection period of the first electrode. The first drive The voltage of the electrophoretic particles is determined based on an applied voltage between the first electrode and the second electrode based on a first or second selection voltage supplied by a stage and a data voltage supplied by the second driving unit. An image is formed by controlling the characteristic fluctuation.
[0018]
According to the electro-optical device of the present invention, the first selection voltage having the first predetermined level corresponding to the first threshold voltage is supplied to the first electrode during the selection period of the first field of the first electrode. You. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing over one threshold voltage, the characteristics of the electrophoretic particles can be changed to one side. On the other hand, a second selection voltage having a second predetermined level corresponding to the second threshold voltage is supplied to the first electrode during a selection period of the second field period of the first electrode. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing two threshold voltages, the characteristics of the electrophoretic particles can be changed to the other side.
[0019]
By changing the characteristics of the electrophoretic particles to either one side or the other side, an image corresponding to the characteristic change can be formed. That is, even if the electro-optical device includes the electrophoretic particles having the hysteresis characteristics having the first threshold voltage and the second threshold voltage with respect to the applied voltage, it is not necessary to perform the reset process every time the image is rewritten. In addition, display disturbances such as flicker and jitter due to discontinuous image changes are suppressed.
[0020]
According to one aspect of the electro-optical device of the present invention, the electro-optical device includes a storage unit configured to store the image data, and a determination unit configured to determine increase / decrease of the current image data with respect to the stored immediately preceding image data; A signal corresponding to image data to the second electrode corresponding to a selection period of one of the first and second field periods of the first electrode in accordance with an increase or decrease in the determined image data. A data voltage having a level is supplied, and a hold voltage having a predetermined level is supplied to the second electrode corresponding to a selection period of the other of the first and second field periods of the first electrode.
[0021]
According to this aspect, according to the increase or decrease of the determined image data, the image is applied to the second electrode only in response to the selection period of one of the first and second field periods of the first electrode. A data voltage having a signal level corresponding to the data is supplied. Then, a hold voltage having a predetermined level is supplied to the second electrode corresponding to the selection period of the other of the first and second field periods of the first electrode. Therefore, the data voltage needs to be supplied only during the selection period of one of the first and second field periods necessary for rewriting the image according to the increase or decrease of the image data. Even when it is difficult to secure the (first or second threshold voltage), an image is displayed with high accuracy. In other words, the condition of the threshold voltage in the selection period of the other one of the first and second field periods that is not necessary for rewriting the image is relaxed.
[0022]
In another aspect of the electro-optical device of the present invention, the first driving unit may be configured to supply the hold voltage to the second electrode and to perform any one of a first and a second field period of the first electrode. The supply of any one of the first and second selection voltages to the first electrode is stopped in response to the selection period.
[0023]
According to this aspect, the hold voltage is supplied to the second electrode, and during the selection period of any of the first and second field periods unnecessary for rewriting an image, the first electrode with respect to the first electrode is selected. And the supply of any one of the second selection voltages is stopped, and power consumption is reduced.
[0024]
The method of driving an electro-optical device according to the present invention includes a first threshold voltage and a second threshold voltage with respect to a voltage applied between the first electrode and the second electrode, the first threshold voltage being applied between the first electrode and the second electrode. A method for driving an electro-optical device including electrophoretic particles having hysteresis characteristics and having characteristic fluctuations on one side and the other side, wherein a selection period of the first electrode is divided into two in a first selection period. A first selection voltage having a first predetermined level according to the first threshold voltage is supplied to the first electrode, and the first electrode is supplied to the first electrode in a second selection period obtained by dividing the selection period of the first electrode into two. A second selection voltage having a second predetermined level corresponding to the second threshold voltage is supplied to the electrode, and a signal level corresponding to image data is supplied to the second electrode in accordance with a selection period of the first electrode. Providing a data voltage having the first and second data voltages. One of the selection voltage and the said basis of the data voltage and the voltage applied between the first electrode and the second electrode based on controlling the characteristic variation of the electrophoretic particles form an image of.
[0025]
According to the electro-optical device driving method of the present invention, the first predetermined level corresponding to the first threshold voltage is applied to the first electrode during one of the first selection periods obtained by dividing the selection period of the first electrode into two. Is supplied. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing over one threshold voltage, the characteristics of the electrophoretic particles can be changed to one side. On the other hand, a second selection voltage having a second predetermined level corresponding to the second threshold voltage is supplied to the first electrode in another second selection period obtained by dividing the selection period of the first electrode into two. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing two threshold voltages, the characteristics of the electrophoretic particles can be changed to the other side.
[0026]
By changing the characteristics of the electrophoretic particles to either one side or the other side, an image corresponding to the characteristic change can be formed. That is, even in the method of driving the electro-optical device including the electrophoretic particles having the hysteresis characteristics having the first threshold voltage and the second threshold voltage with respect to the applied voltage, it is necessary to perform the reset process every time the image is rewritten. Since there is no change, display disturbances such as flicker and jitter due to discontinuous changes in the image are suppressed.
[0027]
The method of driving an electro-optical device according to the present invention includes a first threshold voltage and a second threshold voltage with respect to a voltage applied between the first electrode and the second electrode, the first threshold voltage being applied between the first electrode and the second electrode. A method of driving an electro-optical device including electrophoretic particles having hysteresis characteristics and having characteristic fluctuations on one side and the other side, wherein the first electrode is connected to a first electrode during a selection period of a first field period. On the other hand, a first selection voltage having a first predetermined level corresponding to the first threshold voltage is supplied, and the first electrode is supplied to the first electrode in a selection period of a second field period following the first field period of the first electrode. A second selection voltage having a second predetermined level corresponding to the second threshold voltage is supplied, and a data voltage having a signal level corresponding to image data to the second electrode corresponding to a selection period of the first electrode. Supply the The gist of the invention is to form an image by controlling a characteristic variation of the electrophoretic particles based on a voltage applied between the first electrode and the second electrode based on one of the first and second selection voltages and the data voltage. .
[0028]
According to the driving method of the electro-optical device of the present invention, the first selection voltage having the first predetermined level corresponding to the first threshold voltage with respect to the first electrode during the selection period of the first field period of the first electrode. Is supplied. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing over one threshold voltage, the characteristics of the electrophoretic particles can be changed to one side. On the other hand, a second selection voltage having a second predetermined level corresponding to the second threshold voltage is supplied to the first electrode during a selection period of the second field period of the first electrode. At this time, a data voltage having a signal level corresponding to image data is supplied to the second electrode corresponding to the selection period of the first electrode, and the applied voltage between the first electrode and the second electrode is changed to the second voltage. By crossing two threshold voltages, the characteristics of the electrophoretic particles can be changed to the other side.
[0029]
By changing the characteristics of the electrophoretic particles to either one side or the other side, an image corresponding to the characteristic change can be formed. That is, even if the electro-optical device includes the electrophoretic particles having the hysteresis characteristics having the first threshold voltage and the second threshold voltage with respect to the applied voltage, it is not necessary to perform the reset process every time the image is rewritten. In addition, display disturbances such as flicker and jitter due to discontinuous image changes are suppressed.
[0030]
An electronic apparatus of the present invention includes the above-described electro-optical device of the present invention (including its various aspects).
According to the electronic apparatus of the present invention, it is possible to realize image display with high display quality.
[0031]
BEST MODE FOR CARRYING OUT THE INVENTION
(1st Embodiment)
Hereinafter, a first embodiment in which the present invention is embodied in an electrophoretic display device as an electro-optical device will be described with reference to FIGS.
[0032]
In FIG. 1, the electrophoretic display device includes an electrophoretic display panel 2. The electrophoretic display panel 2 has a common substrate 3 and a segment substrate 4. The common substrate 3 is made of a material such as glass, a semiconductor, and an organic material. On the common substrate 3, a grid-shaped partition wall 5 is formed. More specifically, the electrophoretic display panel 2 is provided with a display area Z1. And, on the common substrate 3 corresponding to the display area Z1, a grid-shaped partition wall 5 is formed. The segment substrate 4 is formed on the grid-shaped partition walls 5.
[0033]
As shown in FIG. 2, a common electrode 6 serving as a first electrode of each of the scanning lines Y1 to Ym (see FIG. 3) is provided on the upper surface of the common substrate 3 at a substantially intermediate portion of each partition 5 extending in the X direction. Is formed. Further, a segment electrode 7 as a second electrode of the data lines X1 to Xn (see FIG. 3) is formed on the lower surface of the segment substrate 4 at a substantially intermediate portion of each partition 5 extending in the Y direction. The segment substrate 4 and the segment electrode 7 are each formed of a transparent material.
[0034]
The divided cells 10 are formed by the spaces surrounded by the partition walls 5 formed in a grid pattern. The black first electrophoretic particles 8 and white color are contained in each closed space formed by the partition walls 5, the common substrate 3 (common electrode 6) and the segment substrate 4 (segment electrode 7) formed in a grid pattern. The second electrophoretic particles 9 are sealed to form the pixel section 11. Therefore, each pixel section 11 is formed at a portion where the common electrode 6 of each of the scanning lines Y1 to Ym and the segment electrode 7 of each of the data lines X1 to Xn intersect at a substantially right angle. The divided cells 10 are defined by the partition walls 5, but may be defined by, for example, microcapsules. Also, if the uniformity of the electrophoretic particles is maintained, the partition may be omitted and the same space may be used. The first electrophoretic particles 8 are charged, for example, with a negative charge, and the second electrophoretic particles 9 are charged, for example, with a positive charge.
[0035]
FIG. 5 is a graph showing the relationship between the applied voltage between the common electrode 6 and the segment electrode 7 and the display density (gradation) in each pixel section 11 formed on the display area Z1. FIG. 6 is an explanatory diagram schematically showing the operation of the first electrophoretic particles 8 and the second electrophoretic particles 9 according to the voltage applied between the common electrode 6 and the segment electrode 7 in each pixel unit 11. 6 (a) to 6 (d), the operation is described using three first and second electrophoretic particles 8, 9 each for simplification.
[0036]
Here, the gray level recognized by a person is determined by the ratio of the first and second electrophoretic particles 8 and 9 attached to the segment electrode 7 on the segment substrate 4 side. In other words, the larger the ratio of the black first electrophoretic particles 8 adhering to the segment electrodes 7, the blacker it looks, and conversely, the larger the ratio of the white second electrophoretic particles 9 adhering to the segment electrodes 7, it looks whiter. Become. Hereinafter, an outline of electro-optical characteristics of each pixel portion 11 formed on the display region Z1 will be described.
[0037]
First, the transition will be described on the assumption that the applied voltage increases to the plus side from the state O with the smallest (thin) gradation in FIG. At this time, most of the first electrophoretic particles 8 are attached to the common electrode 6, and most of the second electrophoretic particles 9 are attached to the segment electrode 7 on the segment substrate 4 side. In FIG. 6A corresponding to this state, all the first electrophoretic particles 8 adhere to the common electrode 6 and all the second electrophoretic particles 9 adhere to the segment electrode 7. I have.
[0038]
While the applied voltage is increased from the state O to the plus side in the range from the second threshold voltage Vth2, the gradation does not change, and the first and second electrophoretic particles 8, 9 change the state of FIG. maintain. When the applied voltage is further increased to the voltage Va beyond the second threshold voltage Vth2 to the plus side, the state shifts to the state A in which the gradation is increased with the increase of the voltage. At this time, the first electrophoretic particles 8 attached to the segment electrode 7 and the second electrophoretic particles 9 attached to the common electrode 6 gradually increase due to the action of the electric field, as shown in FIGS. On the contrary, the first electrophoretic particles 8 attached to the common electrode 6 and the second electrophoretic particles 9 attached to the segment electrode 7 gradually decrease. When the applied voltage further increases from the state A to the voltage Vb on the plus side, the state shifts to the state B where the gray scale is larger.
[0039]
Then, when the applied voltage further increases to the maximum voltage Vmax, most of the first electrophoretic particles 8 adhere to the segment electrode 7 on the segment substrate 4 side, and most of the second electrophoretic particles 9 become common. It adheres to the electrode 6. In FIG. 6D corresponding to the state where the gradation is the largest (darkest), all the first electrophoretic particles 8 adhere to the segment electrode 7 and all the second electrophoretic particles 9 are attached to the common electrode. 6 is attached.
[0040]
On the other hand, while the applied voltage is reduced in the range from the state A to the first threshold voltage Vth1 on the minus side, the gradation does not change and the first and second electrophoretic particles 8, 9 maintain the state at that time. I do. Then, when the applied voltage falls below the first threshold voltage Vth1 and further decreases to the voltage Vc, the state shifts to a state C in which the gradation is reduced with the decrease in the applied voltage. At this time, the first electrophoretic particles 8 adhering to the segment electrode 7 and the second electrophoretic particles 9 adhering to the common electrode 6 gradually decrease due to the action of the electric field according to the above. On the contrary, the first electrophoretic particles 8 attached to the common electrode 6 and the second electrophoretic particles 9 attached to the segment electrode 7 gradually increase. When the applied voltage is further reduced to the negative side to the minimum voltage Vmin, most of the first electrophoretic particles 8 adhere to the common electrode 6 and most of the second electrophoretic particles 9 are on the segment substrate 4 side. It adheres to the electrode 7 (see FIG. 6A).
[0041]
Therefore, when shifting from the state A to the state B having a larger gray scale, the applied voltage is increased to the voltage Vb exceeding the second threshold voltage Vth2. Further, when shifting from the state A to the state C where the gradation is smaller, the applied voltage is reduced to the voltage Vc lower than the first threshold voltage Vth1. Further, when the applied voltage is held at least in the range of the first threshold voltage Vth1 to the second threshold voltage Vth2, the gradation in this state is maintained. As described above, the first and second electrophoretic particles 8 and 9 have the hysteresis characteristics having the first and second threshold voltages Vth1 and Vth2. The transition of the first and second electrophoretic particles 8, 9 from the state shown in FIG. 6D to the state shown in FIG. 6A is referred to as a characteristic change particularly toward one side. The transition of the first and second electrophoretic particles 8, 9 from the state shown in FIG. 6A to the state shown in FIG. 6D is particularly referred to as a characteristic change to the other side. The electrical configuration of the electrophoretic display device will be described below in consideration of such electro-optical characteristics of each pixel unit 11.
[0042]
3, the electrophoretic display device includes a display panel unit 21, a scanning line driving circuit 22, a data line driving circuit 23, and a control circuit 24.
The display panel unit 21 has the data lines X1 to Xn extending in the column direction (Y direction) and the scanning lines Y1 to Ym extending in each row direction (X direction). In the display panel section 21, unit circuits 21a are arranged corresponding to intersections of the data lines X1 to Xn and the scanning lines Y1 to Ym. Each unit circuit 21a includes the first and second electrophoretic particles 8 and 9 described above. Therefore, the terminals on one side and the other side of each unit circuit 21a are connected to the common electrode 6 and the segment electrode 7 sandwiching the first and second electrophoretic particles 8, 9, respectively.
[0043]
The scanning line driving circuit 22 is supplied with a voltage from a power supply circuit (not shown), selects one of the plurality of scanning lines Y1 to Ym, that is, outputs a scanning signal and connects to the selected scanning line. This is a circuit for driving the group of unit circuits 21a. Although the scanning line driving circuit 22 is not shown in FIG. 1 in the present embodiment, the scanning line driving circuit 22 is configured as a well-known simple matrix panel. And mounted with an anisotropic conductive film or the like.
[0044]
The scanning line driving circuit 22 outputs the scanning signals VY1 to VYm to the respective scanning lines Y1 to Ym (common electrode 6) at a predetermined timing based on various signals from the control circuit 24. Each of the scanning signals VY1 to VYm has a potential of VL and a potential of a second predetermined level, respectively, in a first selection period and a second selection period that divide the selection period of the scanning lines Y1 to Ym (common electrode 6) into two equal parts. It is switched to VH as one predetermined level. The potential of each of the scanning signals VY1 to VYm is switched to Vo in a non-selection period (holding period) of the scanning line Y1 to Ym. Note that the selection period of each scanning line is one horizontal scanning period 1H of the scanning line. Each of the first selection period and the second selection period is half the horizontal scanning period 1 / 2H.
[0045]
The data line drive circuit 23 is supplied with a voltage from a power supply circuit (not shown). Then, the data line driving circuit 23 outputs the data signals VX1 to VXn to the data lines X1 to Xn (segment electrodes 7), respectively, and is a unit circuit 21a connected to the data line and selected by a scanning line. And a circuit for outputting the data signal to the unit circuit 21a. Although the data line driving circuit 23 is not shown in FIG. 1 in this embodiment, the data line driving circuit 23 is configured as a separate component from the electrophoretic display panel 2 and is mounted with an anisotropic conductive film or the like. ing.
[0046]
A description will be given below as a voltage to which a difference voltage between the potential of the common electrode 6 and the potential of the segment electrode 7 is relatively applied. The potential VD as a signal level of each of the data signals VX1 to VXn is controlled in accordance with the gradation of each pixel unit 11. More specifically, as shown in FIG. 5, when the potential VD of the data signal becomes −VDmax (VDmax> 0) when the potential of the scanning signal is VH, the applied voltage (VH + VDmax) between the common electrode 6 and the segment electrode 7. ) Matches the maximum voltage Vmax. While the potential of the scanning signal is VH and the potential VD of the data signal decreases in the range up to −VDmax, the potential is applied when the applied voltage between the common electrode 6 and the segment electrode 7 exceeds the second threshold voltage Vth2. As the VD decreases (the voltage applied between the common electrode 6 and the segment electrode 7 increases), the gradation can be increased. On the other hand, when the potential VD of the data signal becomes −VDmin (VDmin <0) when the potential of the scanning signal is VL, the applied voltage (VL + VDmin) between the common electrode 6 and the segment electrode 7 matches the minimum voltage Vmin. It has become. While the potential of the scanning signal is VL and the potential VD of the data signal increases in a range up to −VDmin, the potential is applied when the applied voltage between the common electrode 6 and the segment electrode 7 falls below the first threshold voltage Vth1. As the VD increases (the applied voltage between the common electrode 6 and the segment electrode 7 decreases), the gradation can be reduced.
[0047]
As described above, in the period in which the potential of the scan signal is VL (the first selection period) and the period in which the potential of the scanning signal is VH (the second selection period), the data signal having the potential VD corresponding to the gradation (display data) is output. Can change the same gradation. In other words, a so-called amplitude modulation (AM) method in which the data signal is amplitude-modulated according to the gradation in the pixel portion 11 is employed.
[0048]
When the potential VD of the data signal becomes −VDmin when the potential of the scanning signal is Vo, the applied voltage (Vo + VDmin) between the common electrode 6 and the segment electrode 7 is higher than the first threshold voltage Vth1. Is set to satisfy the following expression (1).
[0049]
Vo + VDmin> Vth1 (1)
Therefore, when the potential of the scanning signal is Vo, a data signal in which the potential VD is -VDmin is output, and even if the applied voltage between the common electrode 6 and the segment electrode 7 is minimized, the gradation is changed ( Drop) does not occur. Naturally, even if a data signal whose potential VD is -VDmin is output when the potential of the scanning signal is VH (> Vo), this does not cause a change (decrease) in gradation.
[0050]
In addition, when the potential VD of the data signal becomes −VDmax when the potential of the scanning signal is Vo, the applied voltage (Vo + VDmax) between the common electrode 6 and the segment electrode 7 is smaller than the second threshold voltage Vth2. Is set to satisfy the following expression (2).
[0051]
Vo + VDmax <Vth2 (2)
Therefore, when the potential of the scanning signal is Vo, a data signal in which the potential VD becomes −VDmax is output, and even if the applied voltage between the common electrode 6 and the segment electrode 7 is maximized, the gradation is changed ( Increase) does not occur. Naturally, even if a data signal whose potential VD is -VDmax is output when the potential of the scanning signal is VL (<Vo), this does not cause a change (increase) in the gradation.
[0052]
A control circuit 24 that controls the scanning line driving circuit 22 and the data line driving circuit 23 receives an input image signal VID and a basic clock CLK from an external device (not shown). The control circuit 24 generates image data D based on the input image signal VID, and outputs the image data D to the data line driving circuit 23. The image data D is used for setting the potential VD of the data signal in the data line driving circuit 23. Further, the control circuit 24 outputs the data line side control clock signal CLKX to the data line drive circuit 23 for determining the timing of outputting the data signal based on the basic clock CLK. Further, the control circuit 24 outputs a scan line side control clock signal CLKY to the scan line drive circuit 22 for determining the timing of outputting the scan signals VY1 to VYm based on the basic clock CLK. .
[0053]
Next, an operation of the electrophoretic display device will be described with reference to a time chart of FIG. In the present embodiment, a description will be given assuming that a so-called horizontal period dividing method is employed as a driving method of the electrophoretic display device. However, it goes without saying that various other driving methods may be employed as the driving method of the electrophoretic display device.
[0054]
FIG. 4 shows the scanning signals VY1 and VY2 applied to the first and second scanning lines Y1 and Y2 in the horizontal period dividing method, and the data signals VX1 and VX1 applied to the first column data line X1. 5 is a time chart illustrating a waveform example of a voltage V (X1, Y1) applied to a pixel unit 11 in a row and a first column. Note that the following description is applied to a case where the present invention is applied to a scanning line Yi of an i-th row (an integer satisfying 1 ≦ i ≦ m) and a data line Xj of a j-th column (an integer satisfying 1 ≦ j ≦ n). Needless to say,
[0055]
In FIG. 4, the scanning line driving circuit 22 supplies a first selection voltage at which the potential of the scanning signal VY1 becomes VL to the scanning line Y1 (common electrode 6) in the first selection period of the selection period. The scanning line drive circuit 22 supplies a second selection voltage at which the potential of the scanning signal VY1 becomes VH to the scanning line Y1 (common electrode 6) in the second selection period of the selection period. When the scanning line Y1 shifts to a non-selection period (holding period), the scanning line driving circuit 22 supplies a non-selection voltage (holding voltage) at which the potential of the scanning signal VY1 becomes Vo to the scanning line Y1. .
[0056]
When the scanning line Y1 shifts to the non-selection period (holding period), the next scanning line Y2 shifts to the selection period, and the scanning signal VY2 changes in the same manner as described above. Thereafter, the scanning signal changes similarly for all the scanning lines. Note that a period in which all the scanning lines Y1 to Ym are selected in one cycle is called one field period 1F (one vertical scanning period). When one field period has elapsed from the previous selection of the scanning line Y1, the scanning line shifts to a new selection period, and the scanning signal changes in the same manner as described above.
[0057]
On the other hand, the data line driving circuit 23 supplies the data line X1 (segment electrode 7) with a data voltage in which the potential (amplitude) of the data signal VX1 becomes VD11 and VD12 in each of the selection periods of the scanning lines Y1 and Y2. . These data voltages are controlled in accordance with the gradation of each pixel section 11 based on the image data D from the control circuit 24.
[0058]
When the voltage V (X1, Y1), which is an applied voltage between the common electrode 6 and the segment electrode 7, exceeds the second threshold voltage Vth2, the gradation of the pixel unit 11 increases and falls below the first threshold voltage Vth1. Sometimes, the gradation of the pixel portion 11 is reduced. Therefore, in FIG. 4, in the first selection period of the scanning line Y1, the gradation of the pixel portion 11 changes (decreases) in the first selection period. Further, in the next selection period of the scanning line Y1, the gradation of the pixel portion 11 changes (increases) in the second selection period. Needless to say, the gradation of the pixel portion 11 changes stepwise according to the degree of the voltage exceeding the second threshold voltage Vth2 or the voltage falling below the first threshold voltage Vth1 (see FIG. 5). That is, according to the potential (amplitude) of the data signal VX <b> 1 based on the image data D, it is possible to display in the halftone in the pixel unit 11. In other words, the greater the gray level to be given to the pixel unit 11, the greater the extent to which the voltage V (X1, Y1) exceeds the second threshold voltage Vth2, and the greater the decrease, the greater the level of the voltage V (X1, Y1). The potential of the data signal VX1 is set so that the degree of falling below the first threshold voltage Vth1 increases.
[0059]
When the scanning signal is the non-selection voltage (Vo), a data signal having the potential VD of -VDmin is output, and even if the voltage V (X1, Y1) is minimized, the gradation is changed (reduced). ) Does not occur as described above. Further, when the scanning signal is the non-selection voltage (Vo), a data signal having the potential VD of -VDmax is output, and even if the voltage V (X1, Y1) becomes maximum, the gradation is changed (increased). ) Does not occur, as described above.
[0060]
As described in detail above, according to the present embodiment, the following effects can be obtained.
(1) In the present embodiment, the first selection having the potential VL corresponding to the first threshold voltage Vth1 with respect to the common electrode 6 in one first selection period obtained by dividing the selection period of the common electrode 6 (scanning line) into two. Voltage is supplied. At this time, a data voltage having a potential VD corresponding to the image data is supplied to the segment electrodes 7 corresponding to the selection period of the common electrode 6, and the applied voltage between the common electrode 6 and the segment electrodes 7 becomes the first threshold voltage. If it is lower than Vth1, the characteristics of the first and second electrophoretic particles 8, 9 can be changed to one side. On the other hand, a second selection voltage having a potential of VH according to the second threshold voltage Vth2 is supplied to the common electrode 6 in the other second selection period obtained by dividing the selection period of the common electrode 6 into two. At this time, a data voltage having a potential VD corresponding to the image data is supplied to the segment electrode 7 corresponding to the selection period of the common electrode 6, and the applied voltage between the common electrode 6 and the segment electrode 7 becomes the second threshold voltage Vth2. Is exceeded, the characteristics of the first and second electrophoretic particles 8, 9 can be changed to the other side.
[0061]
By changing the characteristics of the first and second electrophoretic particles 8 and 9 to both one side and the other side, an image corresponding to the characteristic change can be formed. That is, even if the electro-optical device includes the first and second electrophoretic particles 8 and 9 having the hysteresis characteristics having the first and second threshold voltages Vth1 and Vth2 with respect to the applied voltage, each time the image is rewritten. There is no need to perform reset processing. For this reason, display disturbances such as flicker and jitter due to discontinuous changes in the image can be suppressed.
[0062]
(2) In the present embodiment, since the supply of the data voltage to the segment electrodes 7 may be performed without distinguishing the first and second selection periods of the common electrode 6, the circuit configuration of the data line drive circuit 23 is simplified. Can be
[0063]
(2nd Embodiment)
Hereinafter, a second embodiment in which the present invention is embodied in an electrophoretic display device will be described with reference to FIG. Note that the second embodiment has a configuration in which only the driving mode of the pixel unit 11 in the first embodiment is changed, and a detailed description of similar portions will be omitted.
[0064]
FIG. 7 shows the scanning signals VY1 and VY2 applied to the first and second scanning lines Y1 and Y2 in the horizontal period dividing method, and the data signals VX1 and VX1 applied to the first column data line X1. 5 is a time chart illustrating a waveform example of a voltage V (X1, Y1) applied to a pixel unit 11 in a row 1 column. Note that the following description is applied to a case where the present invention is applied to a scanning line Yi of an i-th row (an integer satisfying 1 ≦ i ≦ m) and a data line Xj of a j-th column (an integer satisfying 1 ≦ j ≦ n). Needless to say,
[0065]
In FIG. 7, the scanning lines Y1 and Y2 change in the same manner as in the first embodiment according to their selection periods (first and second selection periods) and non-selection periods (holding periods).
On the other hand, the data line driving circuit 23 according to the present embodiment supplies the data voltage only when the gradation (display data) of the pixel unit 11 in the current field period is lower than the same gradation in the previous field period. I do. That is, the data line driving circuit 23 supplies a data voltage at which the potential (amplitude) of the data signal VX1 becomes VD11 to the data line X1 (segment electrode 7) corresponding to the first selection period of the scanning line Y1. Then, the data line driving circuit 23 supplies a hold voltage at which the potential (amplitude) of the data signal VX1 becomes Vo as a predetermined level to the data line X1 corresponding to the second selection period of the scanning line Y1.
[0066]
Further, the data line drive circuit 23 performs the second selection period of the scanning line Y1 only when the gradation (display data) of the pixel unit 11 in the current field period is higher than the same gradation in the previous field period. In response to the above, a data voltage is supplied to the data line X1 so that the potential (amplitude) of the data signal VX1 becomes VD11. Then, the data line driving circuit 23 supplies a hold voltage at which the potential (amplitude) of the data signal VX1 becomes Vo to the data line X1 corresponding to the first selection period of the scanning line Y1. It should be noted that the gradation (display data) increase / decrease determination in the previous and current field periods is performed by storing the gradation (display data) of each pixel unit 11 in the previous field period in a memory as storage means. Therefore, it can be easily realized, for example, by comparing with a comparison circuit as a determination unit.
[0067]
In FIG. 7, the transition of the data signal VX1 in accordance with the above-described gradation increase / decrease determination is illustrated with vertical and horizontal lines for convenience. That is, in a period in which a vertical line is added corresponding to the first selection period of the scanning line Y1, in the present field period, the gradation of the pixel unit 11 is lower than the same gradation in the previous field period. Only the data voltage is supplied to the data line X1.
[0068]
Here, an example is shown in which a data voltage in which the potential (amplitude) of the data signal VX1 is VD11 (n) is supplied in the first selection period of the first selection period of the scanning line Y1. Needless to say, this data voltage is controlled according to the gradation of each pixel section 11 based on the image data D from the control circuit 24. On the other hand, in the period with the vertical line, when the gradation of the pixel unit 11 in the current field period increases from the same gradation in the previous field period, the data signal VX1 is applied to the data line X1. A hold voltage whose potential (amplitude) becomes Vo is supplied.
[0069]
Also, in the period marked with a horizontal line corresponding to the second selection period of the scanning line Y1, only when the gradation of the pixel unit 11 in the current field period is higher than the same gradation in the previous field period. , A data voltage is supplied to the data line X1.
[0070]
Here, an example is shown in which a data voltage in which the potential (amplitude) of the data signal VX1 is VD11 (n + 1) is supplied in a second selection period following the selection period of the scanning line Y1. Needless to say, this data voltage is controlled according to the gradation of each pixel section 11 based on the image data D from the control circuit 24. On the other hand, in the period indicated by the horizontal line, when the gray level of the pixel unit 11 is lower than the same gray level in the previous field period in the current field period, the potential of the data signal VX1 is applied to the data line X1. A hold voltage whose (amplitude) becomes Vo is supplied.
[0071]
In particular, when the gray scale in the previous and current field periods does not change, the potential of the data signal VX1 with respect to the data line X1 (both vertical and horizontal lines corresponding to the selection period of the scanning line Y1). (Holding voltage) whose amplitude is Vo.
[0072]
When the voltage V (X1, Y1), which is an applied voltage between the common electrode 6 and the segment electrode 7, exceeds the second threshold voltage Vth2, the gradation of the pixel unit 11 increases and falls below the first threshold voltage Vth1. Sometimes, the gradation of the pixel portion 11 is reduced. Therefore, in FIG. 7, in the first selection period of the scanning line Y1, the gradation of the pixel portion 11 changes (decreases) in the first selection period. Further, in the next selection period of the scanning line Y1, the gradation of the pixel portion 11 changes (increases) in the second selection period. Needless to say, the gradation of the pixel portion 11 changes stepwise according to the degree of the voltage exceeding the second threshold voltage Vth2 or the voltage falling below the first threshold voltage Vth1 (see FIG. 5). That is, according to the potential (amplitude) of the data signal VX <b> 1 based on the image data D, it is possible to display in the halftone in the pixel unit 11. Only when the gradation of the pixel section 11 is changed, the potential (amplitude) of the data signal VX1 is changed during the first or second selection period according to the gradation increase / decrease determination in the previous and current field periods. This is as described above.
[0073]
When the potential of the scanning signal is Vo, it goes without saying that it is necessary to satisfy the expressions (1) and (2) in the first embodiment. In the second embodiment, similar conditions are required for the hold voltage. More specifically, when a hold voltage at which the potential (amplitude) of the data signal VX1 becomes Vo is supplied to the data line X1 during the first selection period of the scanning line Y1, the voltage V (X1, Y1) becomes (VL). −Vo). At this time, it is set so as to satisfy the following expression (3) so that a change (decrease) in the gradation does not occur.
[0074]
VL−Vo> Vth1 (3)
Further, when a hold voltage that causes the potential (amplitude) of the data signal VX1 to be Vo is supplied to the data line X1 during the second selection period of the scanning line Y1, the voltage V (X1, Y1) becomes (VH−Vo). It becomes. At this time, it is set so as to satisfy the following expression (4) so that a change (increase) does not occur in the gradation.
[0075]
VH−Vo <Vth2 (4)
Incidentally, the potential of the hold voltage of the data signal VX1 is not limited to Vo, which is the potential of the non-selection voltage (holding voltage) of the scanning signal VY1, but may be any potential Vhold between the potentials VL and VH. . In particular, since the supply of the data voltage is selectively performed in the first and second selection periods, the potential of the hold voltage in each selection period is individually set according to the restrictions of the first and second threshold voltages Vth1 and Vth2. May be. In short, it is only necessary that the conditional expression be satisfied when Vo is replaced with Vhold in both conditional expressions.
[0076]
As described above in detail, according to the present embodiment, the following effect can be obtained in addition to the effect (1) in the first embodiment.
(1) In the present embodiment, the potential VD corresponding to the image data is applied to the segment electrode 7 only in response to one of the first and second selection periods of the common electrode 6 according to the increase or decrease of the image data. Is supplied. Then, a hold voltage at which the potential becomes Vo is supplied to the segment electrode 7 corresponding to the other of the first and second selection periods of the common electrode 6. Therefore, by supplying the data voltage only in one of the first and second selection periods required for rewriting the image in accordance with the increase or decrease of the image data, the threshold voltage (the first or the second) is applied to the supply of the data voltage. Even when it is difficult to secure the second threshold voltages Vth1 and Vth2), an image can be displayed with high accuracy. In other words, the conditions of the first or second threshold voltages Vth1 and Vth2 in the first or second selection period that is unnecessary for rewriting the image can be relaxed.
[0077]
(Third embodiment)
Hereinafter, a third embodiment in which the present invention is embodied in an electrophoretic display device will be described with reference to FIG. Note that the third embodiment has a configuration in which only the driving mode of the pixel unit 11 in the first and second embodiments is changed, and a detailed description of the same parts will be omitted. In the present embodiment, a so-called two-field method is employed as a driving method of the electrophoretic display device.
[0078]
FIG. 8 shows the scanning signals VY1 and VY2 applied to the first and second scanning lines Y1 and Y2 in the two-field method, the data signal VX1 applied to the first column data line X1, and the first row and first row. 5 is a time chart illustrating a waveform example of a voltage V (X1, Y1) applied to a pixel unit 11 in a column. Note that the following description is applied to a case where the present invention is applied to a scanning line Yi of an i-th row (an integer satisfying 1 ≦ i ≦ m) and a data line Xj of a j-th column (an integer satisfying 1 ≦ j ≦ n). Needless to say,
[0079]
In FIG. 8, for the scanning line Y1 (common electrode 6) in the selection period of the first field period (hereinafter, referred to as the first field period), the scanning line driving circuit 22 causes the scanning signal VY1 to have the first potential VL. Supply the selection voltage. When the scanning line Y1 shifts to a non-selection period (holding period), the scanning line driving circuit 22 supplies a non-selection voltage (holding voltage) at which the potential of the scanning signal VY1 becomes Vo to the scanning line Y1. . When the scanning line Y1 shifts to the non-selection period (holding period), the next scanning line Y2 shifts to the selection period, and the scanning signal VY2 changes in the same manner as described above. Thereafter, the scanning signal changes similarly for all the scanning lines.
[0080]
For the scanning line Y1 (common electrode 6) in the selection period of the next field period after the first field period (hereinafter referred to as the second field period), the scanning line driving circuit 22 sets the potential of the scanning signal VY1 to VH. Is supplied.
[0081]
On the other hand, the data line driving circuit 23 according to the present embodiment operates only when the gradation of the pixel unit 11 in the first field period is lower than the same gradation in the previous field period (the immediately preceding second field period). Supply data voltage. That is, the data line driving circuit 23 supplies a data voltage at which the potential (amplitude) of the data signal VX1 becomes VD11 to the data line X1 (segment electrode 7) corresponding to the selection period of the scanning line Y1.
[0082]
Here, an example is shown in which a data voltage in which the potential (amplitude) of the data signal VX1 is VD11 (n) is supplied in the selection period of the first field period of the scanning line Y1. Needless to say, this data voltage is controlled according to the gradation of each pixel section 11 based on the image data D from the control circuit 24. If the gradation of the pixel section 11 does not decrease in the first field period from the same gradation in the previous field period (immediately before the second field period), the data line driving circuit 23 selects the scanning line Y1. A hold voltage at which the potential (amplitude) of the data signal VX1 becomes Vo is supplied to the data line X1 corresponding to the period.
[0083]
Further, the data line driving circuit 23 determines that the gradation of the pixel unit 11 in the next field period (second field period) after the end of the first field period is the same as that in the previous field period (immediately before the first field period). The data voltage is supplied only when the data voltage is higher than the gradation. That is, the data line driving circuit 23 supplies a data voltage at which the potential (amplitude) of the data signal VX1 becomes VD11 to the data line X1 corresponding to the selection period of the scanning line Y1.
[0084]
Here, an example is shown in which a data voltage is supplied such that the potential (amplitude) of the data signal VX1 becomes VD11 (n + 1) during the selection period of the second field period of the scanning line Y1. Needless to say, this data voltage is controlled according to the gradation of each pixel section 11 based on the image data D from the control circuit 24. If the gray level of the pixel section 11 does not increase in the second field period from the same gray level in the previous field period (the immediately preceding first field period), the data line driving circuit 23 selects the scanning line Y1. A hold voltage at which the potential (amplitude) of the data signal VX1 becomes Vo is supplied to the data line X1 corresponding to the period. It should be noted that the gradation (display data) increase / decrease determination in the previous and current field periods is performed by storing the gradation (display data) of each pixel unit 11 in the previous field period in a memory, for example. It can be easily realized by comparing in a circuit.
[0085]
When the voltage V (X1, Y1), which is an applied voltage between the common electrode 6 and the segment electrode 7, exceeds the second threshold voltage Vth2, the gradation of the pixel unit 11 increases and falls below the first threshold voltage Vth1. Sometimes, the gradation of the pixel portion 11 is reduced. Accordingly, in FIG. 8, the gray scale of the pixel portion 11 changes (decreases) during the selection period of the first field period of the scanning line Y1. Further, the gradation of the pixel portion 11 changes (increases) in the selection period of the next field period (second field period) after the first field period of the scanning line Y1 ends. Needless to say, the gradation of the pixel portion 11 changes stepwise according to the degree of the voltage exceeding the second threshold voltage Vth2 or the voltage falling below the first threshold voltage Vth1 (see FIG. 5). That is, according to the potential (amplitude) of the data signal VX <b> 1 based on the image data D, it is possible to display in the halftone in the pixel unit 11. Only when the gradation of the pixel section 11 is changed, the potential (amplitude of the data signal VX1) of the data signal VX1 in the selection period of the first or second field period in accordance with the gradation increase / decrease determination in the previous and current field periods. Is changed as described above.
[0086]
When the potential of the scanning signal is Vo, it goes without saying that it is necessary to satisfy the expressions (1) and (2) in the first embodiment and the expressions (3) and (4) in the second embodiment.
[0087]
As described in detail above, according to the present embodiment, the effect shown in (2) can be obtained in addition to the effect (1) in the first embodiment.
(1) In the present embodiment, a first selection voltage having a potential of VH according to the second threshold voltage Vth2 is supplied to the common electrode 6 during the selection period of the first field period of the common electrode 6. At this time, a data voltage having a potential VD corresponding to the image data is supplied to the segment electrode 7 corresponding to the selection period of the common electrode 6, and the applied voltage between the common electrode 6 and the segment electrode 7 becomes the second threshold voltage Vth2. Is exceeded, the characteristics of the first and second electrophoretic particles 8, 9 can be changed to the other side. On the other hand, a second selection voltage having a potential of VL corresponding to the first threshold voltage Vth1 is supplied to the common electrode 6 during the selection period of the second field period of the common electrode 6. At this time, a data voltage having a potential VD corresponding to the image data is supplied to the segment electrode 7 corresponding to the selection period of the common electrode 6, and the applied voltage between the common electrode 6 and the segment electrode 7 becomes the first threshold voltage Vth1. If the ratio is smaller than the above, the first and second electrophoretic particles 8 and 9 can be changed in characteristic to one side.
[0088]
By changing the characteristics of the first and second electrophoretic particles 8 and 9 to both one side and the other side, an image corresponding to the characteristic change can be formed. That is, even if the electro-optical device includes the first and second electrophoretic particles 8 and 9 having the hysteresis characteristics having the first and second threshold voltages Vth1 and Vth2 with respect to the applied voltage, each time the image is rewritten. There is no need to perform reset processing. For this reason, display disturbances such as flicker and jitter due to discontinuous changes in the image can be suppressed.
[0089]
(2) In the present embodiment, in response to the increase or decrease of the image data, the segment electrode 7 responds to the image data only in response to the selection period of one of the first and second field periods of the common electrode 6. A data voltage having the potential VD is supplied. Then, a hold voltage at which the potential becomes Vo is supplied to the segment electrode 7 corresponding to the selection period of the other one of the first and second field periods of the common electrode 6. Therefore, by supplying the data voltage only during the selection period of one of the first and second field periods necessary for rewriting the image in accordance with the increase or decrease of the image data, the threshold voltage ( Even when it is difficult to secure the first or second threshold voltage Vth1, Vth2), an image can be displayed with high accuracy. In other words, the conditions of the first or second threshold voltages Vth1 and Vth2 in the first or second selection period that is unnecessary for rewriting the image can be relaxed.
[0090]
(Electronics)
Next, an example in which the electro-optical device according to each of the above-described embodiments is used for an electronic device will be described. Such electro-optical devices include personal computers, mobile computers, outdoor signs, billboards, car navigation devices, mobile phones, digital still cameras, projection display devices, televisions, pagers, electronic notebooks, electronic books, calculators, word processors, The present invention is applicable to various electronic devices such as a viewfinder type or a monitor direct-view type video tape recorder, a workstation, a videophone, a POS terminal, and a device having a touch panel. In the electrophoretic display device, since a backlight required for a transmissive / semi-transmissive liquid crystal display device is unnecessary, each electronic device can be reduced in size and weight. Then, it is possible to significantly reduce the power consumption. As a result, each device can achieve both low power consumption and sufficient display quality.
[0091]
<Mobile computer>
First, an example in which the above-described electro-optical device is applied to a display unit of a personal computer will be described. FIG. 9 is a perspective view showing the configuration of this personal computer. In this figure, a computer 60 includes a main body 62 having a keyboard 61 and a display device 63 using the above-described electro-optical device.
[0092]
(Modification)
The present invention is not limited to the embodiments described above, and various modifications are possible, for example, as follows.
[0093]
In the first and second embodiments, each of the scanning lines Y1 to Ym is sequentially selected, and the image is rewritten (changes in gradation) in the corresponding selection period (first or second selection period). . On the other hand, in each field period, a so-called block (partial) in which only the scanning line or the block of the scanning line of the pixel portion 11 whose gradation changes from the previous field period is selected to rewrite an image (change gradation). The horizontal period method may be employed as a driving method of the electrophoretic display device. In this case, the selection period of each scanning line may be equally divided according to the number of scanning lines selected while keeping one field period constant. Alternatively, one field period may be expanded or contracted according to the number of scanning lines selected while keeping the selection period of each scanning line constant.
[0094]
In the second embodiment, a scanning line selection period during which a data voltage is not supplied to a data line (segment electrode 7) (a hold voltage is supplied) (one of the first and second selection periods) , The supply of the corresponding selection voltage (first or second selection voltage) may be stopped. In this case, power consumption can be reduced by stopping supply of the selection voltage.
[0095]
In the third embodiment, during the scanning line selection period and when the data voltage is not supplied to the data line (segment electrode 7) (the hold voltage is supplied) (in either the first or second field period) During the selection period, the supply of the corresponding selection voltage (first or second selection voltage) may be stopped. In this case, power consumption can be reduced by stopping supply of the selection voltage.
[0096]
In the third embodiment, according to the increase or decrease of the image data, the segment electrode 7 responds to the image data only in response to the selection period of one of the first and second field periods of the common electrode 6. The data voltage having the potential VD is supplied. On the other hand, a data voltage having a potential VD corresponding to the image data is supplied to the segment electrode 7 corresponding to both of the first and second field periods without determining whether the image data increases or decreases. You may. In this case, the supply of the data voltage to the segment electrodes 7 may be performed without distinguishing the selection periods of the first and second field periods of the common electrode 6, so that the circuit configuration of the data line driving circuit 23 can be simplified. .
[0097]
In the third embodiment, in the first and second field periods, each of the scanning lines Y1 to Ym is sequentially selected, and the image is rewritten (changes in gradation) during the selection period of the corresponding field period. . On the other hand, in each field period, a so-called block (partial) in which only the scanning line or the block of the scanning line of the pixel portion 11 whose gradation changes from the previous field period is selected and the image is rewritten (gradation is changed). The horizontal period method may be adopted as a driving method of the electrophoretic display device. In this case, in the first field period in which the gradation is reduced and the second field period in which the gradation is increased, the selected scanning line may be the same or different. Further, the selection period of each scanning line may be equally divided according to the number of scanning lines selected while keeping the first or second field period constant. Alternatively, the first or second field period may be expanded or contracted in accordance with the number of scanning lines selected while keeping the selection period of each scanning line constant.
[0098]
In the above embodiments, the variation in the distribution of the first and second electrophoretic particles 8, 9 attached to the common electrode 6 and the segment electrode 7 according to the applied voltage is used as the characteristic variation of the electrophoretic particles. The charging polarity of the first and second electrophoretic particles 8 and 9 which is a premise of such a characteristic change is an example. For example, the first electrophoretic particles 8 are charged with a positive charge, and the second electrophoretic particles 9 are charged. A material that is charged with a negative charge may be used. Such a reversal of the polarity only causes a reversal of the display density with respect to the polarity of the applied voltage.
[0099]
In the above embodiments, the variation in the distribution of the first and second electrophoretic particles 8, 9 attached to the common electrode 6 and the segment electrode 7 according to the applied voltage is used as the characteristic variation of the electrophoretic particles. The variation in the characteristics of the electrophoretic particles due to the applied voltage is not limited to this, and other spatial variations may be used. For example, a change in bulk density when the electrophoretic particles are brought into a floating state by an applied voltage may be used. The characteristic fluctuation of the electrophoretic particles at this time is maintained by the supporting force between the particles. Such a variation in the characteristics of the electrophoretic particles is merely a difference in the mode of the variation in the characteristics of the material, and does not depart from the present invention in terms of the electro-optic effect.
[0100]
In each of the above embodiments, an image was formed using two types of electrophoretic particles having different colors. On the other hand, if the distinction between the color of the electrophoretic particles and the background color can be made clear, an image may be formed using only one type of electrophoretic particles.
[0101]
In the above embodiments, the pixel portion 11 in which the divided cells 10 are formed by the partition walls 5 is formed. A pixel portion in which such divided cells are formed by microcapsules may be employed. Alternatively, the formation of such divided cells may be omitted.
[0102]
In the above embodiments, the shape in which the first and second electrophoretic particles 8, 9 are sandwiched between the common electrode 6 and the segment electrode 7 is not limited to a shape in which the first and second electrophoretic particles 8 and 9 are sandwiched simply. For example, a shape in which a part or the whole of the common electrode 6 is buried in the partition 5 or a shape in which a part of the common electrode 6 is bent toward the segment electrode 7 along the partition 5 may be used. Alternatively, a shape in which part or all of the segment electrode 7 is embedded in the partition wall 5 or a shape in which a part of the segment electrode 7 is bent toward the common electrode 6 along the partition wall 5 may be employed. In short, it is only necessary that the electrophoretic particles can apply an electric field in such a direction as to cause a characteristic change.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view showing an electrophoretic display panel according to a first embodiment.
FIG. 2 is a sectional view of a main part of the electrophoretic display panel.
FIG. 3 is a circuit diagram illustrating an electrical configuration of the electrophoretic display device.
FIG. 4 is a time chart illustrating a driving mode of the electrophoretic display device.
FIG. 5 is a graph showing electro-optical characteristics of electrophoretic particles.
FIG. 6 is a schematic diagram illustrating electro-optical characteristics of electrophoretic particles.
FIG. 7 is a time chart showing a driving mode according to the second embodiment.
FIG. 8 is a time chart showing a driving mode according to a third embodiment.
FIG. 9 is an exemplary perspective view showing a configuration of a mobile computer.
[Explanation of symbols]
21: display panel unit, 6: common electrode as first electrode, 7: segment electrode as second electrode, 8: first electrophoretic particle as electrophoretic particle, 9 ... second electrophoresis as electrophoretic particle Particles, 22: scanning line driving circuit as first driving means, 23: data line driving circuit as second driving means.

Claims (9)

One side and the other side having a hysteresis characteristic having a first threshold voltage and a second threshold voltage with respect to an applied voltage between the first electrode and the second electrode, being sandwiched between the first electrode and the second electrode. Electrophoretic particles whose characteristics vary
In a first selection period obtained by dividing the selection period of the first electrode into two, a first selection voltage having a first predetermined level corresponding to the first threshold voltage is supplied to the first electrode. A first driving unit that supplies a second selection voltage having a second predetermined level corresponding to the second threshold voltage to the first electrode in another second selection period obtained by dividing the electrode selection period into two,
A second driving unit that supplies a data voltage having a signal level corresponding to image data to the second electrode corresponding to a selection period of the first electrode,
The first and second selection voltages supplied by the first driving unit and the data voltage supplied by the second driving unit based on the applied voltage between the first electrode and the second electrode based on the data voltage An electro-optical device for forming an image by controlling the characteristic fluctuation of electrophoretic particles. Storage means for storing the image data;
A determination unit for determining increase / decrease of the current image data with respect to the stored immediately preceding image data,
The second driving unit responds to the second electrode in response to one of the first and second selection periods of the first electrode in response to the increase or decrease in the determined image data. Supplying a data voltage having a predetermined signal level, and supplying a hold voltage having a predetermined level to the second electrode corresponding to the other of the first and second selection periods of the first electrode. The electro-optical device according to claim 1, wherein: The first driving unit is configured to control the first and the second electrodes with respect to the first electrode in response to a first or second selection period of the first electrode to which the hold voltage is supplied to the second electrode. 3. The electro-optical device according to claim 2, wherein the supply of any one of the second selection voltages is stopped. One side and the other side having a hysteresis characteristic having a first threshold voltage and a second threshold voltage with respect to an applied voltage between the first electrode and the second electrode, being sandwiched between the first electrode and the second electrode. Electrophoretic particles whose characteristics vary
In a selection period of a first field period of the first electrode, a first selection voltage having a first predetermined level corresponding to the first threshold voltage is supplied to the first electrode, and the first selection voltage of the first electrode is controlled. First driving means for supplying a second selection voltage having a second predetermined level corresponding to the second threshold voltage to the first electrode during a selection period of a second field period following the field period;
A second driving unit that supplies a data voltage having a signal level corresponding to image data to the second electrode corresponding to a selection period of the first electrode,
The first and second selection voltages supplied by the first driving unit and the data voltage supplied by the second driving unit based on the applied voltage between the first electrode and the second electrode based on the data voltage An electro-optical device for forming an image by controlling the characteristic fluctuation of electrophoretic particles. Storage means for storing the image data;
A determination unit for determining increase / decrease of the current image data with respect to the stored immediately preceding image data,
The second driving unit is responsive to the increase or decrease of the determined image data to cause the second electrode to generate an image corresponding to a selection period of one of the first and second field periods of the first electrode. A data voltage having a signal level corresponding to data is supplied, and a predetermined level is provided to the second electrode corresponding to a selection period of the other of the first and second field periods of the first electrode. The electro-optical device according to claim 4, wherein a voltage is supplied. The first driving unit is configured to control the first electrode with respect to the first electrode in response to a selection period of a first or second field period of the first electrode to which the hold voltage is supplied to the second electrode. 6. The electro-optical device according to claim 5, wherein the supply of the first or second selection voltage is stopped. One side and the other side having a hysteresis characteristic having a first threshold voltage and a second threshold voltage with respect to an applied voltage between the first electrode and the second electrode, being sandwiched between the first electrode and the second electrode. A method of driving an electro-optical device including electrophoretic particles having respective characteristic fluctuations,
In a first selection period obtained by dividing the selection period of the first electrode into two, a first selection voltage having a first predetermined level corresponding to the first threshold voltage is supplied to the first electrode. Supplying a second selection voltage having a second predetermined level corresponding to the second threshold voltage to the first electrode in another second selection period obtained by dividing the electrode selection period into two,
Supplying a data voltage having a signal level corresponding to image data to the second electrode corresponding to a selection period of the first electrode;
An image is formed by controlling a characteristic change of the electrophoretic particles based on a voltage applied between the first electrode and the second electrode based on one of the first and second selection voltages and the data voltage. Driving method of the electro-optical device. One side and the other side having a hysteresis characteristic having a first threshold voltage and a second threshold voltage with respect to an applied voltage between the first electrode and the second electrode, being sandwiched between the first electrode and the second electrode. A method of driving an electro-optical device including electrophoretic particles having respective characteristic fluctuations,
In a selection period of a first field period of the first electrode, a first selection voltage having a first predetermined level corresponding to the first threshold voltage is supplied to the first electrode, and the first selection voltage of the first electrode is controlled. Supplying a second selection voltage having a second predetermined level corresponding to the second threshold voltage to the first electrode in a selection period of a second field period following the field period;
Supplying a data voltage having a signal level corresponding to image data to the second electrode corresponding to a selection period of the first electrode;
An image is formed by controlling a characteristic change of the electrophoretic particles based on a voltage applied between the first electrode and the second electrode based on one of the first and second selection voltages and the data voltage. Driving method of the electro-optical device. An electronic apparatus comprising the electro-optical device according to claim 1.

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