Patent Application
20100007591
1. Field of the Invention
The present invention relates to a pixel unit and driving method thereof, more particularly, to a pixel unit and driving method thereof that alter a reference voltage provided to a storage element.
2. Description of the Related Art
With regard to the semiconductor process, a common electrode (not illustrated in
As known, an AC driving is performed in liquid crystal display device for obviating DC residual voltage remained on liquid crystal. To perform the AC driving, also called polarity inversion, the common voltage Vcom applied on the common electrode is used as the reference potential. The pixel voltages having positive polarity and negative polarity with respect to the common voltage Vcom are provided to the pixel electrode Pi in different frame periods. Positive polarity and negative polarity are determined according to the electric field direction applied to liquid crystal. If the voltage of the pixel electrode Pi is greater than the common voltage Vcom, the liquid crystal is driven with positive polarity voltage. Otherwise, the liquid crystal is driven with negative polarity voltage.
As mentioned previously, the switch T1 can be implemented by P-type transistor or N-type transistor, but both of the P-type transistor or N-type transistor are affected by body effect, which results in the restricted range of the pixel voltage stored in the storage capacitor Cst with the fixed common voltage Vcom. It is assumed that the power supply voltages VDDA and VSSA are exemplary 15 volts and 0 volts utilized in the driving system of the display panel 100. If the range of the provided pixel voltage is between 0 volts and 15 volts, due to the body effect, the range of the pixel voltage delivered to the pixel electrode Pi via the switch T1 implemented by the P-type transistor is restricted to be between 5 volts and 15 volts. Accordingly, the common voltage Vcom is set at 10 volts in order to perform polarity inversion. Namely, the pixel voltage between 5 volts and 10 volts serves as negative polarity voltage and the pixel voltage between 10 volts and 15 volts serves as positive polarity voltage with respect to the common voltage Vcom. Consequently, only 5 volts of the pixel voltage range can be applied for representing the gray-scale values of an image and results in poor contrast ratio of the display panel 100.
Similarly, if the switch T1 is implemented by the N-type transistor, due to the body effect, the range of the pixel voltage delivered to the pixel electrode Pi is restricted to be between 0 volts and 10 volts. Accordingly, the common voltage Vcom needs to be set at 5 volts for polarity inversion, and results in the same problem aforementioned. Simply speaking, the switch T1 implemented by transistors can not deliver the full range of the power supply voltages to the pixel electrode Pi because of the characteristic of the electronic components. Therefore, how to increase the maximum voltage range applied to the pixel electrode Pi for controlling the rotation of liquid crystal becomes an important issue for designing the driving system of the display panel.
Accordingly, the present invention provides a pixel unit and the driving methods thereof that can make maximum voltage range of the first electrode of the storage element to be close to a full range of power supply voltages and enlarge the voltage range stored in the storage element. The contrast ratio of a display panel can be enhanced since the greater the voltage range stored in the storage element is, the more the details of the image can be displayed.
The pixel unit is provided in the present invention. The pixel unit includes a switch, a storage element and a first multiplexer. The switch develops a charge transfer path according to a scan signal associated with a scan line. The storage element has a first electrode and a second electrode coupled to the switch and a reference voltage respectively for receiving a pixel voltage via the charge transfer path. The first multiplexer coupled to the second electrode of the storage element selectively provides the reference voltage with a default value and the reference voltage with a determined value to the second electrode of the storage element according to a modulating signal.
In an embodiment of the present invention, the pixel unit further includes a second multiplexer coupled to the switch for selectively providing a pixel voltage and a reset voltage to the storage element via the charge transfer path according to a control signal.
A driving method for a pixel unit is provided in the present invention. The pixel unit includes a switch and a storage element, wherein the storage element has a first electrode and a second electrode respectively, coupled to the switch and a reference voltage. In the driving method, a first frame with a first polarity and a second frame with a second polarity are displayed during a first frame period and a second frame period respectively. During the first frame period, a scan signal associated with a scan line is asserted to the switch for developing a charge transfer path. A first pixel voltage is supplied to the first electrode of the storage element via the charge transfer path and the reference voltage is altered from a default value to a determined value during the delivering step. Then the scan signal is de-asserted for terminating the charge transfer path and the reference voltage is altered from the determined value to the default value. During the second frame period, the scan signal associated with the scan line is asserted to the switch for developing the charge transfer path. A second pixel voltage is supplied to the first electrode of the storage element via the charge transfer path. Then the scan signal is de-asserted for terminating the charge transfer path.
A driving method for a pixel unit is provided in the present invention. The pixel unit includes a switch and a storage element, wherein the storage element has a first electrode and a second electrode respectively coupled to the switch and a reference voltage. In the driving method, a first frame with a first polarity and a second frame with a second polarity are displayed during a first frame period and a second frame period respectively. During the first frame period, the scan signal associated with a scan line is asserted to the switch for developing a charge transfer path and a first pixel voltage is supplied to the first electrode of the storage element via the charge transfer path. Then the scan signal is de-asserted for terminating the charge transfer path and the reference voltage is altered from a default value to a determined value. During the second frame period, the reference voltage is altered from the determined value to the default value. Then the scan signal associated with the scan line is asserted to the switch for developing the charge transfer path and a second pixel voltage is supplied to the first electrode of the storage element via the charge transfer path. Next, the scan signal is de-asserted for terminating the charge transfer path.
The present invention provides a pixel unit and the driving methods for the pixel unit that changes the first electrode voltage of the storage element by altering the reference voltage coupled to the second electrode of the storage element according to the characteristic of storage element. Since the potential stored within the storage element is maintained invariable when the pixel voltage is supplied to the storage element, the voltage range of the first electrode of the storage element can be enlarged by altering the second electrode voltage of the storage element and then reacts on the liquid crystal for displaying an image. Therefore, the contrast ratio of a display panel can be enhanced since the greater voltage range stored in the storage element can control the liquid crystal rotating for displaying the more details of the image.
In order to make the features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.
It is to be understood that both the foregoing general description and the following detailed description are exemplary, and are intended to provide further explanation of the invention as claimed.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
The switch P1, for example, is a P-type transistor in the embodiment, which has a control terminal receiving a scan driving signal Scan1 associated with a scan line 201, a first terminal receiving a pixel voltage Vp through a data line 202, and a second terminal coupled to the pixel electrode Pix. The switch P1 develops a charge transfer path in response to the scan driving signal Scan1. The pixel voltage Vp is supplied to the pixel electrode Pix and stored in the storage capacitor Cs via the charge transfer path. The output terminal of multiplexer 210 is coupled to the second electrode of the storage capacitor Cs, and selectively provides the reference voltage with a default value VM1 and the reference voltage with a determined value VM2 to the second electrode of the storage capacitor Cs according to a modulating signal Mod1, wherein the second electrode voltage of the storage capacitor Cs is denoted as Vs.
The pixel unit 200 can be applied to the liquid crystal display (LCD) panel or the liquid crystal on silicon (LCOS) panel. For describing the operation of the pixel unit 200 in detail, it is assumed that the power supply voltages VDDA and VSSA are exemplary 15 volts and 0 volts in the embodiment, so the range of the pixel voltage Vp provided by the source driver (not illustrated in
As shown in
Then, the modulating signal Mod1 is de-asserted and makes the multiplexer 210 provide the reference voltage with the default value VM1 (i.e. 7.5 volts) to the second electrode of the storage capacitor Cs. In the meanwhile, the second electrode voltage Vs of the storage capacitor Cs is altered from the determined value VM2 (i.e. 15 volts) to the default value VM1 (i.e. 7.5 volts). Since the storage capacitor Cs is able to maintain the potential stored within it invariable and the second electrode voltage Vs is lowered to the reference voltage with the default value VM1 (i.e. 7.5 volts), the range of the pixel electrode voltage Vpix between 7.5 volts and 15 volts is altered to be between 0 volts and 7.5 volts for driving liquid crystal. As mentioned previously, the pixel electrode voltage Vpix between 0 volts and 7.5 volts can serve as negative polarity voltage with respect to the common voltage Vcom. Therefore, the frame with negative polarity is displayed.
Afterward the frame with positive polarity is displayed during the frame period F22, the scan driving signal Scan1 is asserted to conduct the switch P1 and develop the charge transfer path. The pixel voltage Vp between 7.5 volts and 15 volts is supplied to the pixel electrode Pix via the charge transfer path. The modulating signal Mod1 remains constant and makes the multiplexer 210 provide the reference voltage with the default value VM1 (i.e. 7.5 volts) to the second electrode of the storage capacitor Cs. After the sufficient time for the storage capacitor Cs to store the pixel voltage Vp, the scan driving signal Scan1 is de-asserted for terminating the charge transfer path. The potential range stored within the storage capacitor Cs is between 0 volts and 7.5 volts. Accordingly, the pixel electrode voltage Vpix between 7.5 volts and 15 volts, which is same as the range of the pixel voltage Vp, can serve as positive polarity voltage with respect to the common voltage Vcom and the frame with positive polarity is displayed. To sum up, this embodiment utilizes the pixel voltage Vp between 7.5 volts and 15 volts for driving the pixel unit 200, and the range of the pixel electrode voltage Vpix can be enlarged to be nearly equivalent to the range of the power supply voltages VDDA and VSSA without the influences of body effect.
When the frame with negative polarity is displayed during the frame period F31, the scan driving signal Scan2 is asserted (logic high for N-type transistor in the embodiment) to conduct the switch N1 for developing the charge transfer path. The pixel voltage Vp is supplied to the pixel electrode Pix via the charge transfer path, wherein the range of the pixel voltage Vp is between 0 volts and 7.5 volts and can be fully delivered to the pixel electrode Pix without body effect. The modulating signal Mod2 remains constant and makes the multiplexer 310 provide the reference voltage with the default value VM1 (i.e. 7.5 volts) to the second electrode of the storage capacitor Cs. After sufficient time for storing the pixel voltage Vp, the scan driving signal Scan2 is de-asserted (logic low for N-type transistor in the embodiment) for terminating the charge transfer path. The potential range stored within the storage capacitor Cs is between 0 volts and 7.5 volts. Accordingly, the pixel electrode voltage Vpix between 0 volts and 7.5 volts, which is same as the range of the pixel voltage Vp, can serve as negative polarity voltage with respect to the common voltage for displaying the frame with negative polarity.
When the frame with positive polarity is displayed during the frame period F32, the scan driving signal Scan2 is asserted for developing the charge transfer path and supplying the pixel voltage Vp between 0 volts and 7.5 volts to the pixel electrode Pix. The modulating signal Mod2 asserted follows the scan driving signal Scan2 and makes the multiplexer 310 provide the reference voltage with the determined value VM2 (i.e. 0 volts) to the second electrode of the storage capacitor Cs. The second electrode voltage Vs of the storage capacitor Cs is altered from the default value VM1 (i.e. 7.5 volts) to the determined value VM2 (i.e. 0 volts). After sufficient time for storing the pixel voltage Vp, the scan driving signal Scan2 is de-asserted for terminating the charge transfer path. The potential range stored within the storage capacitor Cs is between 0 volts and 7.5 volts.
Then, the modulating signal Mod2 is de-asserted and makes the multiplexer 310 provide the reference voltage with the default value VM1 (i.e. 7.5 volts) to the second electrode of the storage capacitor Cs. In the meanwhile, the second electrode voltage Vs of the storage capacitor Cs is altered from the determined value VM2 (i.e. 0 volts) to the default value VM1 (i.e. 7.5 volts). Since the storage capacitor Cs maintains the potential stored within it invariable and the second electrode voltage Vs is risen to the reference voltage with the default value VM1 (i.e. 7.5 volts), the range of the pixel electrode voltage Vpix between 0 volts and 7.5 volts is altered to be between 7.5 volts and 15 volts and can serve as positive polarity voltage with respect to the common voltage Vcom for displaying the frame with positive polarity. Therefore, only the range of the pixel voltage Vp between 0 volts and 7.5 volts is utilized for driving the pixel unit 300, and the range of the pixel electrode voltage Vpix is nearly equivalent to the full range between the power supply voltages VDDA and VSSA in the embodiment.
Referring to
To reason by analogy, referring to
However, the multiplexer 420 may occupy the layout area of the display panel and consumes the cost. There is still another embodiment for improving the withstand voltage problem of the switch.
Then, the modulating signal Mod1 is de-asserted and makes the multiplexer 210 provide the reference voltage with the default value VM1 (i.e. 7.5 volts) to the second electrode of the storage capacitor Cs so that the second electrode voltage Vs of the storage capacitor Cs is altered from the determined value VM2 (i.e. 15 volts) to the default value VM1 (i.e. 7.5 volts) after the charge transfer path is terminated. The operation of this embodiment is similar to the embodiment in
When the frame with positive polarity is displayed during the frame period F52, the modulating signal Mod1 is asserted and makes the multiplexer 210 provide the reference voltage with the determined value VM2 (i.e. 15 volts) to the second electrode of the storage capacitor Cs before the scan driving signal is asserted. The second electrode voltage Vs of the storage capacitor Cs is altered from the default value VM1 (i.e. 7.5 volts) to the determined value VM2 (i.e. 15 volts). Then the scan driving signal Scan1 is asserted for developing the charge transfer path and the pixel voltage Vp between 7.5 volts and 15 volts is supplied to the pixel electrode Pix via the charge transfer path. After the sufficient time, the scan driving signal Scan1 is de-asserted for terminating the charge transfer path and the modulating signal Mod1 maintain constant. The range of the pixel electrode voltage Vpix is same as the range of the pixel voltage Vp, which is between 7.5 volts and 15 volts, for serving as positive polarity voltages with respect to the common voltage Vcom.
To reason by analogy,
When the frame with positive polarity is displayed during the frame period F62, the scan driving signal Scan2 is asserted for developing the charge transfer path and supplying the pixel voltage Vp between 0 volts and 7.5 volts to the pixel electrode Pix. After the scan driving signal Scan2 is de-asserted for terminating the charge transfer path, the modulating signal Mod2 is de-asserted for altering the second electrode voltage Vs of the storage capacitor Cs from the determined value VM2 (i.e. 0 volts) to the default value VM1 (i.e. 7.5 volts) so that the range of the pixel electrode voltage Vpix is altered from being between 0 volts and 7.5 volts to be between 7.5 volts and 15 volts for serving as positive polarity voltage.
In summary, by employing a small range of the pixel voltage, the said embodiments enlarge the range of the pixel electrode voltage Vpix to be nearly equivalent to the range of the power supply voltages VDDA and VSSA for performing the driving of polarity inversion. Besides, the potential range stored within the storage capacitor Cs is also enlarged since the body effect issue is overcome. The greater the voltage range stored in the storage capacitor Cs is employed for representing the gray scales of the image, the more the detail of the image can be displayed.
Furthermore, considering with the issue of the withstand voltage of the switch, the said embodiment in
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
