1. Field of the Invention
The invention relates in general to a display panel and an operating method thereof, and more particularly to an active matrix display panel and an operating method thereof.
2. Description of the Related Art
Display devices have been widespread used in a variety of applications, such as lap-top computers, mobile phones, or personal digital assistants. In such devices, bit numbers employed to express the respective pixels of an image, determine the color depth of the image. In general, the visual quality of the image increases with the bit numbers.
However, most of conventional memory in pixel (MIP) circuits usually use a memory which is for storing one bit data. This means that the color depth or grayscale reproducibility is intrinsically limited in two levels, black or white. Although intermediate gray-levels can be generated by pixel rendering, or dithering, in which a number of adjacent pixels can be grouped as a new pixel for displaying, the resolution will be reduced.
The invention is directed to a display panel and an operating method thereof, in which a pixel element is implemented as a multi-bit memory for being operated to increase the number of gray-levels of the active matrix pixel array.
According to an aspect of the present invention, a display panel is provided. The display panel includes a data driver, a source driver, and an active matrix pixel array includes a number of gate lines, a number of source lines, and a number of pixel elements arranged in a matrix. The source driver is for driving the source lines. The gate driver is for driving the gate lines. Each pixel element is coupled to the corresponding gate line and the corresponding source line. Each pixel element includes an image data storage capacitor and a gate switch. The image data storage capacitor stores an image data. The gate switch has a control terminal coupled to the corresponding gate line. The gate switch is coupled between the corresponding source line and the image data storage capacitor. Each pixel element further includes a first to shunt units and a capacitive element. The sample unit has a control terminal for receiving a sample control signal. The capacitive element has a first terminal coupled to a pixel electrode of the image data storage capacitor via the sample unit. The first refresh unit has a control terminal coupled to the first terminal of the capacitive element. The second refresh unit has a control terminal for receiving a refresh control signal. The second refresh unit and the first refresh unit are serially coupled with each other. The first refresh unit and second refresh unit are coupled between the corresponding source line and the image data storage capacitor for receiving a data signal. The shunt unit has a control terminal coupled to the pixel electrode, a data terminal coupled to the first terminal, and another data terminal for receiving a shunt control signal.
According to another aspect of the present invention, a control method is provided. The control method includes a number of steps. An image data is stored in an image data storage capacitor. The image data of the image data storage capacitor is stored in a capacitive element through a sample unit. In a first period, a shunt control signal having a first shunt voltage is provided to selectively control the voltage of the first terminal of the capacitive element through a shunt unit, and a data signal having a first data voltage is provided to selectively refresh the image data of the image data storage capacitor through a first refresh unit and a second refresh unit. The first refresh unit is controlled by the voltage of the first terminal of the capacitive element. The shunt unit is controlled by the voltage of the pixel electrode of the image data storage capacitor. In a second period, the shunt control signal having a second shunt voltage is provided to selectively control the voltage of the first terminal of the capacitive element through the shunt unit, and the data signal having a second data voltage is provided to selectively refresh the image data of the image data storage capacitor through the first refresh unit and the second refresh unit. When the image data is of a first image data, the image data of the image data storage capacitor are refreshed during the first period, and when the image data is of a second image data, the image data of the image data storage capacitor are refreshed during the second period.
According to another aspect of the present invention, a display panel. The display panel includes a number of gate lines, a number of source lines, and a number of pixel elements. The pixel elements are arranged in a matrix, each pixel element being coupled to the corresponding gate line and the corresponding source line. Each pixel element includes an image data storage capacitor for storing an image data; a sample unit controlled by a sample control signal; a capacitive element having a first terminal coupled to a pixel electrode of the image data storage capacitor via the sample unit; a first refresh unit controlled by the voltage on the first terminal; a second refresh unit controlled by a refresh control signal, the first and second refresh units transmitting a data signal from the corresponding source line to the image data storage capacitor when both of the first and second refresh units are enabled; and a shunt unit controlled by the voltage on the pixel electrode, the shunt unit having a data terminal coupled to the first terminal, and another data terminal for receiving a shunt control signal.
The above and other aspects of the invention will become better understood with regard to the following detailed description of the preferred but non-limiting embodiment(s). The following description is made with reference to the accompanying drawings.
A display panel, a pixel element, and an operating method thereof are provided in a number of embodiments of the invention as follows. The display panel is adapted of being operated at two modes, one of which is, for example, an active mode such as the video mode of a display device, while the other is, for example, a passive or refresh mode such as a standby mode of an electronic device including the active matrix display device. When being operated at the active mode, the active matrix display device writes image data in the pixel element. When being operated at the refresh mode, the active matrix display device allows the pixel element to refresh its stored image data, i.e., to maintain the image data of the pixel element, thus generating a constant output such as static image over a prolonged period of time.
In an embodiment, the display panel including a number of image data storage capacitors. The control method includes a number of steps as follows. An image data is stored in an image data storage capacitor. The image data of the image data storage capacitor is stored in a capacitive element through a sample unit. In a first period, a shunt control signal having a first shunt voltage is provided to selectively control the voltage of the first terminal of the capacitive element through a shunt unit, and a data signal having a first data voltage is provided to selectively refresh the image data of the image data storage capacitor through a first refresh unit and a second refresh unit. The first refresh unit is controlled by the voltage of the first terminal of the capacitive element. The shunt unit is controlled by the voltage of the pixel electrode of the image data storage capacitor. In a second period, the shunt control signal having a second shunt voltage is provided to selectively control the voltage of the first terminal of the capacitive element through the shunt unit, and the data signal having a second data voltage is provided to selectively refresh the image data of the image data storage capacitor through the first refresh unit and the second refresh unit. When the image data is of a first image data, the image data of the image data storage capacitor are refreshed during the first period, and when the image data is of a second image data, the image data of the image data storage capacitor are refreshed during the second period. In this way, the image data storage capacitor can be used to stored different image data and refreshed by a corresponding data voltage of the data signal, enabling the display panel to reveal an increased number of gray-levels for displaying.
In an embodiment, the refresh unit 200 performs a sample operation and a number of refresh operations. In the sample operation, the capacitive element 220 is used for storing the image data of the image data storage capacitor C. The capacitive element 220 preferably can be implemented as having a smaller capacitance than that of the image data storage capacitor C, preventing the image data stored in the image data storage capacitor C from being significantly affected in the sample operation. The capacitive element 220 is regarded as a memory for storing the data of the image data storage capacitor C. The voltage of the first terminal CT on the capacitive element 220 is used to control the first refresh unit 212, so as to determine whether or not a refresh voltage such as the data signal SOURCE is used to refresh the image data storage capacitor C in a refresh operation. This renders the pixel element P(x,y) to become a self-refreshing memory in pixel (MIP). With the MIP, the active matrix pixel array can be operated similarly based on a DRAM concept and suitable for high resolution display such as high end smart phone or e-reader applications.
In these refresh operations, each of the shunt control signal SHUNT and the data signal SOURCE sequentially has a number of voltages, and the voltages are in a monotonic order. In an exemplary embodiment, there can be four refresh operations performed to refresh 2-bit image data. To put it simply, the image data of the image data storage capacitor C can be one of four binary values “11”, “10”, “01”, “00”, and can be refreshed in a corresponding one of the four refresh operations which are sequentially performed to provide the data signal SOURCE with one of four voltage levels. As such, the pixel element P(x,y) of the active matrix pixel array 110 can be used to store one of different image data and refreshed in one of the refresh operations, thus becoming a multi-bit MIP circuit with which the numbers of gray-levels can be increased.
Based on at least above, the refresh unit 200 refreshes the image data stored in the image data storage capacitor C in one of the refresh operations. Exemplary configurations and the further description are described as follows.
The operation of the pixel element in
As is shown in
As is shown in
The following description is made as an example that the refreshed image data has the same polarity as the polarity of the image data stored in the image data storage capacitor C in the sample operation. In the example, the sample control signal SAMPLE is first enabled, and the refresh control signal REFRESH is repeatedly enabled four times. The to-be-refreshed image data can be of one of four binary values “11”, “10”, “01”, and “00”, which are respectively illustrated below.
The image data of “11” is refreshed while its polarity remained, e.g., “Vpix, Vcom”=“6V, 0V” to “6V, 0V”.
First, it is assumed that the pixel voltage Vpix is initially 6V and the common voltage Vcom is initially 0V, indicating that the image data stored in the image data storage capacitor C is “11”, i.e., the voltage across the image data storage capacitor C is 6V. Refer to a time t0 where a sample operation is performed. The sample control signal SAMPLE is enabled at a high level to turn on the sample unit 211. Via the turn-on sample unit 211, the first terminal CT of capacitive element 220 is biased at substantially the same level of the current pixel voltage Vpix. This means that the pixel voltage Vpix is sampled as a sample voltage Vsample and stored in the capacitive element 220, i.e., Vsample=6V. The enable signal CE is disabled at a first level of, for example, 0V.
Then, refer to a time t1 where a first refresh operation is performed. The data signal SOURCE has a first voltage LV1 of, for example, 6V at time t1. The enable signal CE is transited from the first level to a second level of, for example, from 0V to 1.5V. The different between the first level and the second level of the enabled signal CE is, in this example, 1.5V, higher than the threshold voltage of the first refresh unit 212, so as to compensate for the threshold voltage of the first refresh unit 212. The enable signal CE pushes up the sample voltage Vsample to about 7.5V (=6V+1.5V) via the capacitive element 220. Between the sample voltage Vsample and the pixel voltage Vpix, there is a voltage difference of 1.5 V (Vsample−Vpix=7.5V−6V) higher than the threshold voltage of 1V of the first refresh unit 212, so that the first refresh unit 212 is turned on. Also, the refresh control signal REFRESH is enabled to turn on the second refresh unit 213. Via the turn-on second and second refresh units 212 and 213, the first voltage LV1 (=6V) of the data signal SOURCE is provided to refresh the pixel voltage Vpix of 6V which may have decayed due to TFT leakage current. Meanwhile, the common voltage Vcom is remained at a low level of, for example, 0V. Thus, when the first refresh operation is performed, the refreshed image data at time t1 (“Vpix, Vcom”=“6V, 0V”) has the same polarity as the polarity of the image data at time t0 (“Vpix, Vcom”=“6V, 0V”).
Next, refer to a time t2 where a second refresh operation is performed. The data signal SOURCE has a second voltage LV2 of, for example, 4V at time t2. Similarly, the shunt control signal SHUNT has the second voltage of 4V. The second voltage LV2 is used to refresh another image data of 4V stored in another image data storage capacitor in the second refresh operation. Between the pixel voltage Vpix and the second voltage LV2 of the shunt control signal SHUNT, there is a voltage difference of 2V (Vpix−LV2=6V−4V) higher than the threshold voltage of 1V of the shunt unit 214, so that the shunt unit 214 is turned on. Via the turn-on shunt unit 214, the first terminal CT of the capacitive element 220 is biased at the second voltage LV2 of the shunt control signal SHUNT, i.e., Vsample=4V. At this time, the first refresh unit 212 is turned off since the voltage difference therebetween is −2V (Vsample−Vpix=4V−6V), lower than its threshold voltage of 1V. In this way, the second voltage LV2 (=4V) of the data signal SOURCE will not be used to refresh the pixel voltage Vpix of 6V, neither the third voltage LV3 (=2V) and the fourth voltage LV4 (=0V) of the data signal SOURCE.
The image data of “10” is refreshed while its polarity remained, e.g., “Vpix, Vcom”=“4V, 0V” to “4V, 0V”.
Similar operation can be referred to previous description for the image data of 6V, and is abbreviated for the sake of brevity. First, it is assumed that the pixel voltage Vpix is initially 4V and the common voltage Vcom is initially 0V, indicating that the image data stored in the image data storage capacitor C is 4V. Then, refer to the time t0, the sample voltage Vsample is about 4V.
Then, refer to the time t1 in the first refresh operation, the enable signal CE pushes up the sample voltage Vsample to about 5.5V (=4V+1.5V) via the capacitive element 220. Between the sample voltage Vsample and the pixel voltage Vpix, there is a voltage difference of 1.5V (Vsample−Vpix=5.5V−4V) higher than the threshold voltage of 1V of the first refresh unit 212, so that the first refresh unit 212 is turned on. Also, the refresh control signal REFRESH is enabled to turn on the second refresh unit 213. Via the turn-on second and second refresh unites 212 and 213, the pixel voltage Vpix of 4V is slightly affected by the first voltage LV1 (=6V) of the data signal SOURCE and increased to, for example, 4.5V, where the voltage increment of the pixel voltage Vpix is under control of its threshold voltage of 1V, i.e., Vsample−Vpix=5.5−4.5.
Next, refer to the time t2 in the second refresh operation. The data signal SOURCE has the second voltage LV2 of, for example, 4V. Between the sample voltage Vsample and the second voltage LV2 of the data signal SOURCE, there is a voltage difference of 1.5 V (Vsample−LV2=5.5V−4V) higher than the threshold voltage of 1V of the first refresh unit 212, so that the first refresh unit 212 is turned on. Also, the refresh control signal REFRESH is enabled again to turn on the second refresh unit 213. Via the turn-on second and second refresh unites 212 and 213, the second voltage LV2 (=4V) of the data signal SOURCE is provided to refresh the pixel voltage Vpix of 4V, thus pushing down the pixel voltage Vpix from 4.5V to 4V as is required. Thus, when the first refresh operation is performed, the refreshed image data at time t2 (“Vpix, Vcom”=“4V, 0V”) has the same polarity as the polarity of the image data at time t1 (“Vpix, Vcom”=“4V, 0V”).
After that, refer to a time t3 where a third refresh operation is performed. The data signal SOURCE has a third voltage LV3 of, for example, 2V at time t3. Similarly, the shunt control signal SHUNT has the third voltage LV3 of 2V. Between the pixel voltage Vpix and the third voltage LV3 of the shunt control signal SHUNT, there is a voltage difference of 2V (Vpix−LV3=4V−2V) higher than the threshold voltage of 1V of the shunt unit 214, so that the shunt unit 214 is turned on. Via the turn-on shunt unit 214, the sample voltage Vsample of the capacitive element 220 is biased at the third voltage LV3 of the shunt control signal SHUNT, i.e., Vsample=2V. At this time, the first refresh unit 212 is turned off since the voltage difference therebetween is −2V (Vsample−Vpix=2V−4V), lower than its threshold voltage of 1V. In this way, the third voltage LV3 (=2V) of the data signal SOURCE will not be used to refresh the pixel voltage Vpix of 4V, neither the fourth voltage LV4 (=0V) of the data signal SOURCE.
As to the image data of “01” (“Vpix, Vcom”=“2V, 0V” to “2V, 0V”) and “00” (“Vpix, Vcom”=“0V, 0V” to “0V, 0V”), their operation, thus, can be described similarly with reference to the above-related description of the refresh operations for the image data storage capacitor C of “11” and “10”, and will not be specified for the sake of brevity.
In a practical example, the transition from the first voltage LV1 to the second voltage LV2 in the shunt control signal SHUNT is in advance of the transition from the first voltage LV1 to the second voltage LV2 in the data signal SOURCE. This assures that there is enough time to control the stored image data in the capacitive element 220, such as to turn on the shunt unit 214 and change the voltage on its first terminal CT before the data signal SOURCE is changed as having a next voltage. In this way, the refreshed image data storage capacitor C can also be prevented from being modified by the next voltage of the data signal SOURCE. However, this invention is not limited thereto. No matter which one of the signals changes or transits from one voltage to another voltage earlier, in case that the second refresh unit 213 should be turned off during the voltage transition of these signals, their timing order will not affect the voltage of the capacitor 220. In other words, in another embodiment, the time that the shunt control signal SHUNT and the data signal SOURCE transited from one voltage to another is a time when the second refresh unit 213 is turned off. From another aspect, such time can also be regarded as a time the refresh control signal REFRESH is disabled, or a time between two adjacent enabled pulses of the refresh control signal REFRESH.
The group of signals in
Besides, as to the data signal SOURCE and the shunt control signal SHUNT shown in
With the circuit architecture shown in
In response to the signals in
The image data of “11” is refreshed while its polarity inversed, e.g., “Vpix(11), Vcom”=“0V, 6V” to “6V, 0V”.
First, it is assumed that the pixel voltage Vpix(11) is initially 0V and the common voltage Vcom is initially 6V, indicating that the image data stored in the image data storage capacitor C is “11”, i.e., the voltage across the image data storage capacitor C is 6V. Refer to a time t0′ where a sample operation is performed. The sample control signal SAMPLE is enabled at a high level to turn on the sample unit 211. Via the turn-on sample unit 211, the first terminal CT of the capacitive element 220 is biased at substantially the same level as the current pixel voltage Vpix(11). This means that the pixel voltage Vpix(11) of 0V is sampled as a sample voltage Vsample(11) and stored in the capacitive element 220, i.e., Vsample(11)=0V at time t0′.
After that, refer to a time t1′. The enable signal CE is transited from a first level to a second level, e.g., from 0V to 8V. The transition of the enable signal CE at time t1′ pushes up the sample voltage Vsample(11) to about 8V (=0V+8V) via the capacitive element 220. Also, at time t1′, the shunt control signal SHUNT is transited from a first shunt voltage to a second shunt voltage, e.g., from 0V to 8V.
Then, refer to a time t2′. The refresh control signal REFRESH is enabled to turn on the second refresh unit 213. The data signal SOURCE has a data voltage LV1 of, for example, 6V. Between the sample voltage Vsample(11) and the pixel voltage Vpix(11), there is a voltage difference of 8V (Vsample−Vpix=8V−0V) higher than the threshold voltage of 1V of the first refresh unit 212, so that the first refresh unit 212 is turned on. Via the turn-on second and second refresh unites 212 and 213, the data voltage LV1 (=6V) of the data signal SOURCE is provided to refresh the pixel voltage Vpix(11), i.e., Vpix(11)=6V at time t2′. Meanwhile, the common voltage Vcom is flipped from for example 6V to 0V at time t2′. Thus, the refreshed image data at time t2′ (“Vpix(11), Vcom”=“6V, 0V”) has an inversed polarity as the polarity of the image data at time t0′ (“Vpix(11), Vcom”=“0V, 6V”).
After that, refer to a time t3′. The enable signal CE is transited from the second level to a third level, e.g., from 8V to 4V. The transition of the enable signal CE at time t3′ pushes down the sample voltage Vsample(11) to about 4V (=8V−4V) via the capacitive element 220. Also, at time t3′, the shunt control signal SHUNT is transited from the shunt voltage LV1′ (=8V) to a shunt voltage LV2′ (=6V).
Next, refer to a time t4′. The data signal SOURCE has a data voltage LV2 of, for example, 4V at time t4′. The data voltage LV2 of 4V is used to refresh another image data of 4V stored in another image data storage capacitor in the second refresh operation. Between the pixel voltage Vpix(11) and the shunt voltage LV2′ of the shunt control signal SHUNT, there is a voltage difference of 0V (Vpix(11)−LV2′=6V−6V) lower than the threshold voltage of 1V of the shunt unit 214, so that the shunt unit 214 is turned off. As regards Vsample(11)=4V at time t4′, the first refresh unit 212 is turned off since the voltage difference therebetween is −2V, i.e., Vsample(11)−Vpix(11)=4V−6V at time t4′, lower than its threshold voltage of 1V. In view of this, the data voltage LV2 (=4V) of the data signal SOURCE will not refresh the pixel voltage Vpix(11) of 6V at time t4′, neither the data voltage LV3 (=2V) at time t6′ and the data voltage LV4 (=0V) of the data signal SOURCE at time t8′.
The image data of “10” is refreshed while its polarity inversed, e.g., “Vpix(10), Vcom”=“0V, 4V” to “4V, 0V”.
Similar operation can be referred to previous description for the image data of 6V, and is abbreviated for the sake of brevity. First, it is assumed that the pixel voltage Vpix(10) is initially 2V and the common voltage Vcom is initially 6V, indicating that the image data stored in the image data storage capacitor C is 4V.
From time t0′ to time t3′, the operation of the pixel voltage Vpix(10) is similar to that for the pixel voltage Vpix(11), and is omitted for the sake of brevity.
Refer to the time t4′. Between the pixel voltage Vpix(10) and the shunt voltage LV2′ of the shunt control signal SHUNT, there is a voltage difference of −2V (Vpix(10)−LV2′=4V−6V) lower than the threshold voltage of 1V of the shunt unit 214, so that the shunt unit 214 is turned off. As regards Vsample(10)=6V at time t4′, the first refresh unit 212 is turned on since the voltage difference therebetween is 2V (Vsample−Vpix(10)=6V−4V), higher than its threshold voltage of 1V. Also, at the time t4′, the refresh control signal REFRESH is enabled again to turn on the second refresh unit 213. Via the turn-on second and second refresh unites 212 and 213, the data voltage LV2 (=4V) of the data signal SOURCE is provided to refresh the pixel voltage Vpix(10), thus pushing down the pixel voltage Vpix(10) from 6V to 4V, which is desired. Thus, the refreshed image data at time t4′ (“Vpix(10), Vcom”=“4V, 0V”) has an inversed polarity as the polarity of the image data at time t0′ (“Vpix(10), Vcom”=“0V, 4V”)
After that, refer to a time t5′. The enable signal CE is transited from the second level to a third level, e.g., from 4V to 0V. The transition of the enable signal CE at time t5′ pushes down the sample voltage Vsample(10) to about 2V (=6V−2V) via the capacitive element 220. Also, at time t5′, the shunt control signal SHUNT is transited from the shunt voltage LV2′ (=8V) to a shunt voltage LV3′ (=6V).
Next, refer to a time t6′. The data signal SOURCE has a data voltage LV3 of, for example, 2V at time t6′. The data voltage LV3 of 2V is used to refresh another image data of 2V stored in another image data storage capacitor in the second refresh operation. Between the pixel voltage Vpix(10) and the shunt voltage LV3′ of the shunt control signal SHUNT, there is a voltage difference of 0V (Vpix(10)−LV3′=4V−4V) lower than the threshold voltage of 1V of the shunt unit 214, so that the shunt unit 214 is turned off. As regards Vsample(10)=4V at time t6′, the first refresh unit 212 is turned off since the voltage difference therebetween is −2V, i.e., Vsample(10)−Vpix(10)=2V−4V at time t6′, lower than its threshold voltage of 1V. In view of this, the data voltage LV3 (=2V) of the data signal SOURCE will not refresh the pixel voltage Vpix(10) of 4V at time t6′, neither the data voltage LV4 (=0V) of the data signal SOURCE at time t8′.
As to the image data of “01” (“Vpix(01), Vcom”=“0V, 2V” to “2V, 0V”) and “00” (“Vpix(00), Vcom”=“0V, 0V” to “0V, 0V”), their operation, thus, can be described similarly with reference to the above-related description of the refresh operations for the image data storage capacitor C of “11” and “10”, and will not be specified for the sake of brevity.
There are several circuit variations of the MIP circuit according to the embodiment of the current invention in
Employing the proper control signals, such as the sample control signal SAMPLE, gate control signal GATE, refresh control signal REFRESH, data signal SOURCE, enabled signal CE, and shunt control signal SHUNT as shown in
According to the active matrix pixel array, the pixel element and the operating method thereof disclosed in the embodiment of the invention, a switch is provided to control the stored data of a capacitive element which is implemented as a memory for storing image data of the image data storage capacitor. This pixel element can be served as a multi-bit memory, so that the image data storage capacitor can be used to store different image data and refreshed by one of the voltages of the data signal. Therefore, a multi-bit pixel element can be achieved with high resolution and an increased number of gray-levels.
While the invention has been described by way of example and in terms of the preferred embodiment(s), it is to be understood that the invention is not limited thereto. On the contrary, it is intended to cover various modifications and similar arrangements and procedures, and the scope of the appended claims therefore should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.
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