1. Field of the Invention
The present invention relates to a source driver, a display device using the same and a driving method of the source driver, and more particularly, to a source driver utilizing a plurality of driving channels, each of which is responsible for outputting a plurality of data driving voltages with same polarity during different scan periods, to perform dot inversion on a display panel.
2. Description of Related Art
As known, the rotation direction of the liquid crystal is related to the electric field direction applied on the liquid crystal. In order to eliminating the DC residual voltage stored within the liquid crystal and avoiding the polarization of the liquid crystal, the LCD device 100 should be driven by polarity inversion. That is to say the driving voltages with different polarities, e.g. positive polarity and negative polarity, are alternatively provided to the pixel cell 131 in different frame periods. There are several kinds of polarity inversion, e.g. column inversion, row inversion, frame inversion and dot inversion.
Referring to
Performing column inversion or frame inversion on the LCD device 100 can save power since each driving channel of the source driver provides the driving voltages with same polarity in different scan periods. However, the LCD device 100 driven by dot inversion still has better display quality than that driven by others due to several advantages, such as low occurrence probability of cross talk and flicker. Therefore, considering with the driving of dot inversion, the design of the source driver should overcome the problem of power consumption.
The present invention provides a source driver and a driving method thereof. The source driver can perform dot inversion on a display panel by utilizing a plurality of driving channels, wherein each driving channel outputs a plurality of data driving voltages with same polarity for saving power consumption. Besides, the present invention further provides a display device using the said source driver, and the display device has the said advantages.
A source driver adapted to a display panel is provided in the present invention, wherein the display panel includes N pixel cells on each of a plurality of scan lines and N is a positive integer. The source driver includes a plurality of driving channel. The N pixel cells on a first scan line of the scan lines are respectively driven by the 1st driving channel to the Nth driving channel during a first scan period, and the N pixel cells on a second scan line of the scan lines are respectively driven by the 2nd to the (N+1)th driving channel during a second scan period.
In an embodiment of the foregoing source driver, the odd-numbered driving channels respectively output a plurality of data driving voltages of a first polarity, and the even-numbered driving channels respectively output a plurality of data driving voltages of a second polarity.
A driving method of a source driver including a plurality of driving channels is provided in the present invention. The driving method is adapted to drive a display panel including N pixel cells on each of a plurality of scan lines, wherein N is a positive integer. A plurality of data driving voltages are transmitted to the N pixel cells on a first scan line of the scan lines via the 1st driving channel to the Nth driving channel of the source driver during a first scan period. The data driving voltages are transmitted to the N pixel cells on a second scan line of the scan lines via the 2nd driving channel to the (N+1)th driving channel of the source driver during a second scan period.
In an embodiment of the foregoing driving method, the data driving voltages transmitted via the odd-numbered driving channels of the source driver have a first polarity, and the data driving voltages transmitted via the even-numbered driving channels of the source driver have a second polarity.
A display device is provided in the present invention. The display device includes a display panel, a first source driver and a second source driver. The display panel includes 2N pixel cells on each of a plurality of scan lines, wherein N is a positive integer. Each of the first source driver and the second source driver includes a plurality of driving channels. The 1st driving channel and the Nth driving channel of the first source driver and the 1st driving channel to the Nth driving channel of the second source driver drive the 2N pixel cells on a first scan lines of the scan lines during a first scan period, while the (N+1)th driving channel of the first source driver and the (N+1)th driving channel of the second source driver are de-activated. The 2nd driving channel to the (N+1)th driving channel of the first source driver and the 2nd driving channel to the (N+1)th driving channel of the second source driver drive the 2N pixel cells on a second scan lines of the scan lines during a second scan period, while the 1st driving channel of the first source driver and the 1st driving channel of the second source driver are de-activated. The (N+1)th driving channel of the first source driver and the 1st driving channel of the second source driver are connected.
In an embodiment of the foregoing display device, the odd-numbered driving channels of the driving channels of the first source driver and the second source driver output a plurality of data driving voltages of a first polarity, and the even-numbered driving channels of the first source driver and the second source driver output a plurality of data driving voltages of a second polarity.
The present invention provides the source driver and the driving method thereof that drive the N pixel cells on the first scan line of the display panel by the 1st driving channel to the Nth driving channel during the first scan period, and drive the N pixel cells on the second scan line of the display panel by the 2nd driving channel to the (N+1)th driving channel during the second scan period. As for a certain driving channel, the driving channel sequentially outputs the driving voltages to the serrated-scanned pixel cells in two adjacent columns during different scan periods. Each driving channel is responsible for outputting the driving voltages with same polarity during different scan periods so as to perform dot inversion on the display device. Besides, the power consumption of the source driver can be reduced thereby.
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.
In the embodiment, one-dot inversion is performed on the display device 200. Namely, two adjacent pixel cells 231 are driven by the driving voltages with different polarities, e.g. positive polarity (denoted as “+”) and negative polarity (denoted as “−”). Referring to
During the first scan period, the shift registers SR1 through SRN control the 1st driving channel CH1 to the Nth driving channel CHN to respectively receive the pixel data DP1 through DPN corresponding to the N pixel cells 231 on the scan line S1 by the switching operation of the shift multiplexer 221. Namely, the shift registers SR1 through SRN sequentially activate the data latches L1 through LN to receive the pixel data DP1 through DPN from a data bus. People ordinary skilled in the art realize that each driving channel of the source driver 220 may include the components, such as, level shifter, digital-to-analog converter, output buffer, and etc. The digital-to-analog converters included in the driving channels CH1 through CHN respectively convert the pixel data DP1 through DPN into the driving voltages VP1 through VPN. Then, the driving channels CH1 through CHN respectively output the driving voltages VP1 through VPN to the N pixel cells 231 via the output multiplexer 222.
Referring to
During the second scan period, the shift registers SR1 through SRN control the 2nd driving channel CH2 to the (N+1)th driving channel CHN+1 to respectively receive the pixel data DP1 through DPN corresponding to the N pixel cells 231 on the scan line S2 by the switching operation of the shift multiplexer 221. Namely, the shift registers SR1 through SRN sequentially activate the data latches L2 through LN+1 to receive the pixel data DP1 through DPN from the data bus. The digital-to-analog converters included in the driving channels CH2 through CHN+1 respectively convert the pixel data DP1 through DPN into the driving voltages VP1 through VPN. Then, the driving channels CH2 through CHN+1 respectively output the driving voltages VP1 through VPN to the N pixel cells 231 via the output multiplexer 222.
When the scan line S3 follows the scan line S2 to be asserted by the gate driver 210, the operation of the driving channels CH1 through CHN+1 during the asserted period of the scan line S3 is similar to the operation of
As above-mentioned, each driving channel is responsible for outputting the driving voltages with same polarity during different scan periods. For example, the driving channel CH2 outputs the driving voltage VP2 with positive polarity during the first scan period, and outputs the driving voltage VP1 with positive polarity during the second scan period. The voltage swing range between the driving voltages with same polarity is small so that the power consumption of the source driver 220 can be reduced, so does the temperature of the display device 200.
It is noted that, among the N pixel cells 231 on each scan line, every three sequentially pixel cells, which respectively correspond to red, green and blue, often serve as one pixel perceived by human, that is, N is a multiple of 3. As a result, every three sequential driving channels of the driving channels CH1 through CHN should respectively output the data driving voltages corresponding to red, green and blue during the first scan period. Every three sequential driving channels of the driving channels CH2 through CHN+1 should respectively output the data driving voltages corresponding to red, green and blue during the second scan period. Since the number of the driving channels in one source driver may not be sufficient for the display panel as the increase of display panel size. Designer must employ a plurality of source drivers for driving such display panel. The following embodiment gives the teaching of driving the display panel with high resolution by utilizing several source drivers described above for people ordinary skilled in the art.
Referring to
Taking the source driver 321 as an example, during the first scan period, by the switching operation of the shift multiplexer 221, the shift registers SR1 through SRN sequentially activate the data latches L1 through LN to receive the pixel data DP1 through DPN from the data bus for controlling the 1st driving channel CH1 to the Nth driving channel CHN to respectively receive the pixel data DP1 through DPN corresponding to the 1st pixel cell 331 to the Nth pixel cell 331 on the scan line S1. The driving channels CH1 through CHN utilize the digital-to-analog converters to convert the pixel data DP1 through DPN into the driving voltages VP1 through VPN and then to output the driving voltages VP1 through VPN to the 1st pixel cell 331 to the Nth pixel cell 331 via the data lines D1 through DN. The operation of the source driver 322 during the first scan period is similar to the operation of the source driver 321 during the first scan period, so that the detail is not iterated.
Referring to
Taking the source driver 321 as an example, during the second scan period, by the switching operation of the shift multiplexer 221, the shift registers SR1 through SRN sequentially activate the data latches L2 through LN+1 to receive the pixel data DP1 through DPN from the data bus for controlling the 2nd driving channel CH2 to the (N+1)th driving channel CHN+1 to respectively receive the pixel data DP1 through DPN corresponding to the 1st pixel cell 331 to the Nth pixel cell 331 on the scan line S2. The driving channels CH2 through CHN+1 utilize the digital-to-analog converters to convert the pixel data DP1 through DPN into the driving voltages VP1 through VPN and then to output the driving voltages VP1 through VPN to the 1st pixel cell 331 to the Nth pixel cell 331 via the data lines D2 through DN+1. The operation of the source driver 322 during the second scan period is similar to the operation of the source driver 321 during the second scan period, so that the detail is not iterated.
In summary, the said embodiments describe the source driver that includes the driving channels to the number of N+1 for driving the N pixel cells on each scan line during different scan periods. Each driving channel of the source driver is responsible for outputting the driving voltages with same polarity, e.g. positive polarity or negative polarity, so that the power consumption of the source driver can be reduced. Besides, dot inversion can be simply performed on the display device for obtaining high display quality.
Though the present invention has been disclosed above by the preferred embodiments, they are not intended to limit the present invention. Anybody skilled in the art can make some modifications and variations without departing from the spirit and scope of the present invention. Therefore, the protecting range of the present invention falls in the appended claims.