The present invention relates to storage displays displaying images using memory devices, such as digital books, and more particularly, to an electrophoretic display employing electrophoretic devices as the memory devices and a method for driving the electrophoretic display.
Known electrophoretic displays include a step of resetting a display such that no image is displayed on the display and no afterimages caused by image data already written on electrophoretic devices are present when writing other image data subsequent to the previously written image data, which is described in Japanese Unexamined Patent Application Publication No. 2002-149115.
Unfortunately, with the reset step in the known electrophoretic displays, a relatively high voltage is applied to the electrophoretic devices in order that the afterimages caused by the image data already written on the electrophoretic devices do not occur. Accordingly, the known electrophoretic displays suffer from a problem in that energy consumption is large.
To solve the aforementioned problems, a method for driving an electrophoretic display according to one aspect of the present invention includes: a first reset step of setting a plurality of electrophoretic devices to a second non-display state in which no image is displayed and afterimages caused by writing first image data in a first writing step may be present by applying a first voltage to the plurality of electrophoretic devices between the first writing step for writing the first image data representing a first image in the plurality of electrophoretic devices so as to display the first image on the plurality of electrophoretic devices and a second writing step for writing second image data representing a second image in the plurality of electrophoretic devices so as to display the second image on the plurality of electrophoretic devices, the first voltage being lower than a non-display-without-afterimage voltage for setting the plurality of electrophoretic devices to a first non-display state in which no image is displayed and the afterimages are not present; and a second reset step for applying a second voltage serving as the non-display-without-afterimage voltage to the plurality of electrophoretic devices so as to set the plurality of electrophoretic devices to the first non-display state at a frequency less than that at which the first reset step is performed.
According to the aspect of the present invention, the first voltage lower than the non-display-without-afterimage voltage, which is used in the known reset process, is applied in the first reset corresponding to the known reset process, whereas the second voltage equal to the non-display-without-afterimage voltage is applied in the second reset step at a frequency less than that at which the first reset step is performed. Consequently, power consumption is suppressed as compared to the known electrophoretic display, while no afterimages are present on the electrophoretic elements similarly to the known electrophoretic display.
The method for driving an electrophoretic display according to the aspect of the present invention may further include a determination step of determining whether or not erasing the afterimages is necessary, wherein when it is determined that erasing the afterimages is necessary in the determination step, the second reset step is performed.
In the method for driving an electrophoretic display according to the aspect of the present invention, the determination step may be performed by perceiving the afterimages or detecting the presence of the afterimages.
An electrophoretic display according to another aspect of the present invention includes: a plurality of electrophoretic devices; and a controlling unit for performing a first reset for applying a first voltage to the plurality of electrophoretic devices between the first writing for writing first image data representing a first image in the plurality of electrophoretic devices so as to display the first image on the plurality of electrophoretic devices and a second writing for writing second image data representing a second image in the plurality of electrophoretic devices so as to display the second image on the plurality of electrophoretic devices, the first voltage being lower than a non-display-without-afterimage voltage for setting the plurality of electrophoretic devices to a first non-display state in which no image is displayed and afterimages caused by the first writing are not present and for performing a second reset for applying a second voltage serving as the non-display-without-afterimage voltage to the plurality of electrophoretic devices so as to set the plurality of electrophoretic devices to the first non-display state at a frequency less than that at which the first reset is performed.
The electrophoretic display according to the aspect of the present invention may further include an input unit for inputting a command indicating that erasing the afterimages is necessary, wherein when the command indicating that erasing the afterimages is necessary is input, the control unit performs the second reset.
A storage display according to another aspect of present invention includes: a plurality of memory devices; and a controlling unit for performing a first reset for applying a first voltage to the plurality of memory devices between the first writing for writing first image data representing a first image in the plurality of memory devices so as to display the first image on the plurality of memory devices and a second writing for writing second image data representing a second image in the plurality of memory devices so as to display the second image on the plurality of memory devices, the first voltage being lower than a non-display-without-afterimage voltage for setting the plurality of memory devices to a first non-display state in which no image is displayed and afterimages caused by the first writing are not present and for performing a second reset for applying a second voltage serving as the non-display-without-afterimage voltage to the plurality of memory devices so as to set the plurality of memory devices to the first non-display state at a frequency less than that at which the first reset is performed.
The aforementioned and further objects, features, and advantages of the present invention will become apparent from the following description of preferred embodiments of the present invention with reference to the attached drawings.
Embodiments of an electrophoretic display and a method for driving the electrophoretic display according to the present invention will now be described by referring to the drawings.
As shown in
The display 10 is driven by, e.g., a known point-sequential driving method and a line-sequential driving method. In the electrophoretic device P11, for example, the thin film transistor TR11 is turned on when the gate driver 11, shown in
In a case where the electrophoretic devices P11 to Pmn display “black”, when an electric field E1 is applied from the back surface to the front surface, as shown in
On the other hand, in a case where the electrophoretic devices P11 to Pmn display “white”, when an electric field E2 is applied from the front surface to the back surface, as shown in
Referring back to
The signal-processing circuit 20 processes a gate signal and image data necessary for the gate driver 11 and the source driver 12 in the display unit 1 to display an image on the display 10 in accordance with various signals, such as an image signal, a clock signal, or a periodic signal received from the display-device-control unit 3. The signal-processing circuit 20 outputs the gate signal to the gate driver 11 and outputs the processed image data to the source driver 12.
The shade-controlling circuit 21 generates a shade signal for modifying or changing the grayscale level of the image data using the image data received from the display-control unit 3 and outputs the shade signal to the source driver 12.
The common-electrode-driving circuit 22 controls the amplitude of voltage to be applied to the common electrode CE, shown in
The display-device-control unit 3 includes an image memory 30 and a display-device-controlling circuit 31 in order to supply signals and data, such as image data, required for the display-control unit 2 to control the operation of the display unit 1 to the display-control unit 2. The image memory 30 stores image data to be displayed on the display 10 in the display unit 1. The display-device-controlling circuit 31 has a function to control the overall operation of the electrophoretic display D. More specifically, the display-device-controlling circuit 31 reads out image data stored in the image memory 30 and outputs the read-out image data to the signal-processing circuit 20 and the shade-controlling circuit 21 in the display-control unit 2. Furthermore, the display-device-controlling circuit 31 outputs a control signal in accordance with the driving method of the electrophoretic devices P11 to Pmn to the common-electrode-driving circuit 22 in the display-control unit 2. The common-electrode-driving circuit 22 defines the voltage to be applied to the common electrode CE in response to the control signal.
The display-device-controlling circuit 31 allows the display-control unit 2 to perform the normal reset and the forced reset of the electrophoretic devices P11 to Pmn in response to a reset signal for erasing afterimages received from the input unit 4, as will be described below. As necessary, the display-device-controlling circuit 31 allows the display-control unit 2 to write image data to the electrophoretic devices P11 to Pmn, besides the normal reset and the forced reset.
The input unit 4 determines the types of forced reset to be performed on the electrophoretic devices P11 to Pmn in accordance with afterimages perceived by the user or afterimages detected by an afterimage-detecting circuit (not shown). The input unit 4 includes a white switch 40, a black switch 41, and a rewritable switch 42.
The white switch 40 turns all the electrophoretic devices P11 to Pmn “white”; that is, the white switch 40 is used to perform white reset. The black switch 41 turns all the electrophoretic devices P11 to Pmn “black”; that is, the black switch 41 is used to perform black reset. The rewritable switch 42 is used to input a command to write image data after the forced reset.
On the other hand, when all the electrophoretic devices P11 to Pmn are reset to “black”, that is, when normal black reset is performed, voltage −VL is applied to the common electrode CE and zero voltage is applied to the pixel electrodes PE11 to PEmn; that is, the electric field E1, shown in
By contrast, when all the electrophoretic devices P11 to Pmn are reset to “white”, that is, when normal white reset is performed, voltage VL is applied to the common electrode CE and zero voltage is applied to the pixel electrodes PE11 to PEmn; that is, the electric field E2, shown in
The absolute value of the voltage VL is smaller than that of voltage VH, which is a non-display-without-afterimage voltage necessary for displaying no image on the electrophoretic devices P11 to Pmn without any afterimages. Therefore, even though the aforementioned normal black reset or normal white reset is performed, afterimages caused by writing the image data may occur.
When all the electrophoretic devices P11 to Pmn are reset to “black”, that is, when forced black reset is performed, voltage −VH with the same absolute value as that of non-display-without-afterimage voltage is applied to the common electrode CE and zero voltage is applied to the pixel electrodes PE11 to PEmn; that is, an electric field larger than the electric field E1 is applied to all the electrophoretic devices P11 to Pmn in the same direction as that of the electric field E1, shown in
On the other hand, when all the electrophoretic devices P11 to Pmn are reset to “white”, that is, when forced white reset is performed, voltage VH with the same absolute value as that of non-display-without-afterimage voltage is applied to the common electrode CE and zero voltage is applied to the pixel electrodes PE11 to PEmn; that is, an electric field larger than the electric field E2 is applied to all the electrophoretic devices P11 to Pmn in the same direction as that of the electric field E2, shown in
In the normal black reset and forced black reset, unlike when writing image data to be displayed in “black”, shown in
Step S1: When the signal-processing circuit 20 in the display-control unit 2 receives a command signal (not shown) to display image data D2 subsequent to the image data D1, shown in
Step 2: The display-device-controlling circuit 31 in the display-device-control unit 3 confirms whether or not an external switch (not shown) for terminating the operation of image display by the electrophoretic display D inputs a signal for the termination of the display operation. When the signal is input, the display-device-controlling circuit 31 terminates the display of the image data D2 by the electrophoretic devices P11 to Pmn. When the signal is not input, the display-device-controlling circuit 31 continues displaying the image data D2.
Step S3: The display-device-controlling circuit 31 in the display-device-control unit 3 confirms whether or not the forced reset is input from the input unit 4 by way of the white switch 40, the black switch 41, or the rewritable switch 42, that is, whether or not a command to perform the forced reset is input. When the display-device-controlling circuit 31 confirms that the forced reset is input, a process for the forced reset is performed.
Step S4: The signal-processing circuit 20 performs the following forced reset in accordance with the type of forced reset input from the input unit 4.
Step S4-1: When a command to perform “forced white reset” is input through the white switch 40, the display-device-controlling circuit 31 notifies the signal-processing circuit 20 to perform “forced white reset”. When the signal-processing circuit 20 receives this notification, the signal-processing circuit 20 outputs voltage VH, which is supposed to be applied to the common electrode CE shown in
Step S4-2: When a command to perform “forced black reset” is input through the black switch 41, the display-device-controlling circuit 31 notifies the signal-processing circuit 20 to perform “forced black reset”. When the signal-processing circuit 20 receives this notification, the signal-processing circuit 20 outputs voltage −VH, which is supposed to be applied to the common electrode CE, as shown in
Step S4-3: When a command to perform “forced reset and writing of image data” is input through the rewritable switch 42, the display-device-controlling circuit 31 notifies the signal-processing circuit 20 to perform “forced reset and writing of image data”. Similarly to the forced white reset, when the signal-processing circuit 20 receives this notification, the signal-processing circuit 20 outputs voltage VH, which is supposed to be applied to the common electrode CE shown in
Subsequent to the forced white reset, the signal-processing circuit 20 controls the gate driver 11 and the source driver 12 so as to apply zero voltage to the common electrode CE, as shown in
Step S1: When the aforementioned forced reset is completed, the signal-processing circuit 20 returns back to Step S1 to perform a process for displaying image data D3 subsequent to the image data D2.
As described above, in the electrophoretic display D according to the embodiment, when a command to perform the forced white reset, forced black reset, or forced rewriting by way of the white switch 40, the black switch 41, or the rewritable switch 42 in the input unit 4 is input, under the control of the display-device-controlling circuit 31 in the display-device-control unit 3, the signal-processing circuit 20 in the display-control unit 2 performs the normal reset on the electrophoretic devices P11 to Pmn by using voltage VL lower than that used in the known normal reset, that is, using a voltage VL less than the voltage used in the known normal reset for erasing afterimages. On the other hand, the forced reset is performed using voltage VH higher than that used in the known normal reset, that is, using a voltage VH higher than the voltage used in the known normal reset for erasing afterimages. Accordingly, power consumption in the electrophoretic display of the embodiment is reduced as compared to the known electrophoretic display, while afterimages on the electrophoretic devices P11 to Pmn are eliminated on the same level with the known electrophoretic display.
In the forced rewriting in Step S4-3, “writing” is performed after “forced white reset” and “forced black reset” or “writing” is performed after “forced black reset” and “forced white reset” in place of “writing” subsequent to “forced white reset” or “writing” subsequent to “forced black reset”. In other words, by performing both “forced black reset” and “forced white reset” prior to “writing”, afterimages can be eliminated more effectively than the electrophoretic display D of the embodiment.
The same effects can be achieved by writing the image data D3 subsequent to the image data D2, instead of writing the image data D2 in Step S4.
Number | Date | Country | Kind |
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2004-095608 | Mar 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2005/006448 | 3/25/2005 | WO | 00 | 8/28/2006 |
Publishing Document | Publishing Date | Country | Kind |
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WO2005/093509 | 10/6/2005 | WO | A |
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