Patent Grant
8643683
This application claims the priority benefit of Taiwan application serial no. 98137310, filed on Nov. 3, 2009. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of specification.
1. Field of the Invention
The present invention generally relates to a driver, and more particularly, to a driver of a field sequential display and a driving method thereof.
2. Description of Related Art
The backlight module of a conventional liquid crystal display (LCD) is usually designed with a white light source (usually emitted by a Cold cathode fluorescent lamp (CCFL)), and the white light source provides a backlight for each pixel through color filters. A red, a green, and a blue color filters are disposed above each pixel in the pixel array. Such a design increases the fabricating cost, and color mixing problem may be occurred between the red, green, and blue color filters. Besides, since color filters are disposed in a LCD, the light generated from the white light source is blocked by the color filters and accordingly the brightness of the LCD is reduced.
To resolve aforementioned problems, a color sequential display is developed based on a color sequential technique and a control circuit. In such a display, color fields are alternatively displayed. Accordingly, a color sequential display is also referred to as a field sequential display. In a field sequential display, light-emitting diodes (LEDs) of different colors are adopted to replace the conventional white light source, and the LEDs of different colors are alternatively lit at different time so that different colors can be displayed at different pixels. The theory of field sequential display is to rapidly alternate between red, blue and green images in succession within the time range of visual persistence of human eyes, so as to produce a color mixing effect and allow the human eyes to see full-color images.
Because the working principle of field sequential display is similar to that of super twisted nematic (STN) LCD, a field sequential display can display monochromatic images as a STN LCD if the LEDs of the field sequential display are not driven. Thus, when a field sequential display is in a color mode, the LEDs corresponding to one of the colors are sequentially lit so as to display color images, and when the field sequential display is in a monochrome mode, the LEDs thereof are turned off so that monochromatic images are displayed.
As described above, when the field sequential display is in the color mode, because the frame period is divided, the driving time of each scan line (i.e., the pulse period) is shorter. In order to prevent the effective driving time from being shortened, the pulse rising and falling time of the driving signals have to be reduced (i.e., the rising and falling rates have to be increased). Accordingly, a high current is necessary. Besides, in order to improve the display quality of the field sequential display, a high voltage has to be supplied in the field sequential display.
Contrarily, when the field sequential display is in the monochrome mode, because the frame period is not divided, the driving time of each scan line is longer than that in the color mode. Accordingly, the rising and falling time of the driving signals are longer than those in the color mode (means can adopt relatively low current in this model). Besides, in the monochrome mode, the display quality of the field sequential display is not that obvious and accordingly a relatively low voltage can be supplied in the field sequential display.
Generally speaking, only one power supply (or power device) is disposed in a field sequential display. Since a field sequential display is mostly in the color mode, the power supply is usually designed with a high voltage and a high current to meet the requirement of driving signals and displayed data in the color mode. Thus, when the field sequential display is in the monochrome mode, it is meaningless to generate the driving signals and displayed data by using a power with a high voltage and a high current, and power is consumed unnecessarily.
According to an embodiment of the present invention, a driver of a field sequential display is provided. The driver includes a first power device, a second power device, and a driving waveform generator. The first power device generates a first power when the field sequential display is in a color mode, and the second power device generates a second power when the field sequential display is in a monochrome mode, wherein the voltage and current of the second power are smaller than the voltage and current of the first power. The driving waveform generator is coupled to the first power device and the second power device and generates a plurality of scan signals and a plurality of display signals according to the first power or the second power, so as to drive a display panel of the field sequential display. The first power device and the second power device are enabled respectively when the field sequential display is in the color mode and the monochrome mode, according to a control signal.
According to an embodiment of the present invention, a driving method of a field sequential display is provided. The driving method includes following steps. First, whether the field sequential display is in a color mode or a monochrome mode is determined. A first power is generated if the field sequential display is in the color mode, and a second power is generated if the field sequential display is in the monochrome mode. Then, a plurality of scan signals and a plurality of display signals are generated according to the first power or the second power, so as to drive a display panel of the field sequential display. The voltage and current of the second power and smaller than the voltage and current of the first power.
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.
Reference will now be made in detail to the present embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
A conventional field sequential display has only one power device that is designed to have a high voltage and a high current due to the requirement of a color mode. As a result, the power consumption of the conventional field sequential display cannot be reduced when the conventional field sequential display is in a monochrome mode. Accordingly, a driver of field sequential display with two power devices is provided in the present invention to resolve aforementioned problem. Embodiments of the present invention will be described below with reference to accompanying drawings.
The driver 320 includes a control unit 321, power devices 322 and 323, a timing controller (TCON) 324, and a driving waveform generator 325. The control unit 321 can be a microcontroller. The power devices 322 and 323 can be power generators, power supplies, or other circuits or devices that can generate powers. To be specific, the power device 322 can be a voltage boost circuit for generating a power P1 with a high voltage and a high current, and the power device 323 can be a charge pump circuit for generating a power P2 with a low voltage and a low current. The terms high and low voltage (or current) as described herein should be considered as relative term rather than a specific standard of voltage or current.
The driving waveform generator 325 includes a gate driver 327 and a source driver 326. The gate driver 327 and the source driver 326 generate the scan signals SSC and the display signals SD according to a clock signal CLK generated by the TCON 324 and the power P1, or according to the clock signal CLK and the power P2.
When the field sequential display 300 is in the color mode, the control unit 321 generates a control signal Sco1 to enable the power device 322 and disable the power device 323. Herein the power P1 with the high voltage and high current is sent to the driving waveform generator 325, and the gate driver 327 and the source driver 326 respectively generate the scan signals SSC and the display signals SD according to the power P1 and the clock signal CLK. Herein the pulse of the scan signals SSC have a high rising/falling rate that can be referred to the driving signals COM0˜COM31 illustrated in
When the field sequential display 300 is in the monochrome mode, the control unit 321 generates the control signal Sco1 to enable the power device 323 and disable the power device 322. The power P2 with the low voltage and low current is sent to the driving waveform generator 325, and the gate driver 327 and the source driver 326 respectively generate the scan signals SSC and the display signals SD according to the power P2 and the clock signal CLK. The pulses of the scan signals SSC have a low rising/falling rate that can be referred to the driving signals COM0˜COM31 illustrated in
It should be mentioned that those having ordinary knowledge in the art can adjust the voltages and currents of the power P1 and the power P2 respectively generated by the power device 322 and the power device 323 according to the actual requirement. In other words, the voltages and currents of the power P1 and the power P2 vary along with the circuit design of the driver and the specification of the display panel and are not limited in embodiments of the present invention. Additionally, the period of the clock signal CLK generated by the TCON 324 in the monochrome mode can be greater than that of the clock signal CLK generated by the TCON 324 in the color mode.
In the present embodiment, the control signal Sco1 is generated by the control unit 321. However, the present invention is not limited thereto, and in other embodiments, the control signal Sco1 may also be inputted from an external circuit. In the present embodiment, the control signal Sco1 is generated according to an input signal Sin. The input signal Sin can be generated by an input device (not shown), and the input device may be a button or a touch panel. If the input signal Sin requests the field sequential display 300 to enter the color mode, the control unit 321 controls the TCON 324 and the driving waveform generator 325 according to the input signal Sin so as to switch the field sequential display 300 into the color mode, and the control unit 321 generates the control signal Sco1 to enable the power device 322 and disable the power device 323. If the input signal Sin requests the field sequential display 300 to enter the monochrome mode, the control unit 321 controls the TCON 324 and the driving waveform generator 325 according to the input signal Sin so as to switch the field sequential display 300 into the monochrome mode, and the control unit 321 generates the control signal Sco1 to enable the power device 323 and disable the power device 322. If the input signal Sin requests to turn off the field sequential display 300, the control unit 321 controls the TCON 324 and the driving waveform generator 325 according to the input signal Sin so as to turn off the field sequential display 300, and the control unit 321 generates the control signal Sco1 to disable the power devices 322 and 323.
The field sequential display 300 can also be applied in amusement equipment or toy. In this case, the control unit 321 generates the control signal Sco1 according to a unused time so as to switch the field sequential display 300 to the monochrome mode or turn off the field sequential display 300 when the field sequential display 300 is unused, so as to reduce the power consumption of the field sequential display 300. To be specific, assuming that the control unit 321 constantly receives the input signal Sin when the field sequential display 300 is operated, the control unit 321 controls the field sequential display 300 to be operated in the color mode and generates the control signal Sco1 to enable the power device 322 and disable the power device 323.
The control unit 321 does not receive the input signal Sin when the field sequential display 300 is unused. If the control unit 321 does not receive the input signal Sin for a predetermined time period (for example, 30 seconds) (i.e., when the field sequential display 300 is in the color mode and the control unit 321 still doesn't receive the input signal Sin after a first period of time), it is determined that the field sequential display 300 has not been used for some time. In this case, the control unit 321 switches the field sequential display 300 into the monochrome mode and generates the control signal Sco1 to enable the power device 323 and disable the power device 322.
After that, if the field sequential display 300 is still unused after predetermined time period (for example, one minute) (i.e., when the field sequential display 300 is in the monochrome mode and the control unit 321 still doesn't receive the input signal Sin after a second period of time), the control unit 321 turns off the field sequential display 300 and generates the control signal Sco1 to disable the power devices 322 and 323. It should be mentioned that in the present embodiment, whether the field sequential display 300 is used is determined based on whether the input signal Sin is received. However, the present invention is not limited thereto.
A method for driving a field sequential display can be derived from the operations of the driver 320 described above.
As described above, the present invention provides a driver of a field sequential display and a driving method thereof. According to the present invention, in a color mode, a power device supplies a power with a high voltage and a high current, and scan signals with high rising/falling rate and data signals with high maximum voltage are generated correspondingly. In a monochrome mode, another power device supplies a power with a low voltage and a low current, and scan signals with low rising/falling rate and data signals with low voltage are generated correspondingly. Thereby, the power consumption of the field sequential display is reduced in the monochrome mode.
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.
| Number | Date | Country | Kind |
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| 20110102476 A1 | May 2011 | US |
