1. Technical Field
The present disclosure relates to a driving circuit of a liquid crystal display (LCD) and a driving method thereof, and more particularly to a driving circuit that has a gamma correction function and method thereof.
2. Description of Related Art
LCDs are widely used in the field of computers, televisions, and other devices.
The LCD includes a liquid crystal panel and a backlight module providing a planar light thereto. The liquid crystal panel includes a first substrate having a common electrode thereon, a second substrate on which a pixel electrode is arranged in a matrix array corresponding to pixels, and liquid crystal molecules sandwiched therebetween. During operation, a common voltage signal is applied to the common electrode and a gray-level voltage signal is applied to the pixel electrode, thereby changing polarities of the liquid crystal molecules in response to an electric field generated by the pixel electrode and the common electrode. Luminance of transmissive light emitted from the backlight module changes following the changes in polarity, such that light and dark are displayed. Color display is accomplished by arranging primary colors of red (R), green (G), and blue (B) on the first substrate and driving the pixel electrode in along a row or column orientation so that power corresponding to color is applied thereto.
Recently, LCD panels having an 8 or 12 millisecond response time widely use a 6-bit color display panel. Accordingly, 26=64 gray levels of each color are represented, and as many as (26)8=262144 colors can be generated by all of the R (red), G (green), and B (blue) colors. Further, if a frame rate control (FRC) algorithm is used to drive the 6-bit color liquid crystal panel, the panel has the same color display ability as an 8-bit color liquid crystal panel, being capable of displaying 16.7M colors.
Referring to
Referring to
What is needed, therefore, is a driving method that can overcome the limitations described, and an LCD using the method.
The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of at least one embodiment. In the drawings, like reference numerals designate corresponding parts throughout the various views.
The driving circuit 20 includes a plurality of scanning lines 201 parallel to each other, and each extending along a first axis, a plurality of data lines 202 parallel to each other, and each extending along a second axis orthogonal to the first, a scanning driving circuit 21, a data driving circuit 22, a detector 23, an analog-digital converter 24, a look-up table 26 and a timing controller 27. The look-up table 26 can be integrated into the timing controller 27.
The scanning lines 201 and the data lines 202 intersect, thereby defining a plurality of pixel units 203. Each pixel unit 203 includes a thin film transistor (TFT) 204 that functions as a switching element, a pixel electrode 205 and a common electrode 206 arranged opposite to the pixel electrode 205. A gate electrode (not labeled), a source electrode (not labeled) and a drain electrode (not labeled) of the TFT 204 are respectively connected to a corresponding scanning line 201, a corresponding data line 202 and a corresponding pixel electrode 205. The pixel electrode 205, the common electrode 206 and liquid crystal molecular sandwiched therebetween form a liquid crystal capacitor (not labeled).
The detector 23 detects a current environmental temperature, and converts the detected temperature signal to a corresponding analog electric signal. The analog-digital converter 24 converts the corresponding analog electric signal to a digital electric signal, and applies the digital electric signal to the look-up table 26.
The timing controller 27 receives a plurality of 8-bit binary data signals generated by an external circuit (not shown), and includes eight frame rate controller Mi (the number i is an integer from 0 to 7). The 8-bit binary data signals range from 00000000 to 11111111. The eight frame rate controllers M0˜M7 simultaneously receive a common 8-bit binary data signal, and are respectively driven by corresponding control signals Ci generated from the look-up table 26. When the control signal ci is applied to a corresponding frame rate controller Mi, the 8-bit binary data signal is converted to a 6-bit binary data signal using an FRC algorithm, and is applied to the data driving circuit 22.
Referring to
Thus, according to the above FRC algorithm, when the gray level n is from 0 to 62, the eight frame rate controllers M0˜M7 output corresponding 6-bit binary data signals that respectively represent the gray levels n, (n+1/8), (n+2/8), (n+3/8), (n+4/8), (n+5/8), (n+6/8), (n+7/8) and (n+1). When the gray level n is the gray level 63, only the frame rate controller M0 outputs the corresponding 6-bit binary data signal that represents the gray level 63.
Referring also to
As viewed in
When the higher 6 bits binary datum of one 8-bit binary data signal is 111111 (n=63), the higher 6 bits binary datum merely corresponds to the control signal C0. Thus, the frame rate controller M0 is driven by the control signal C0, and the liquid crystal panel displays the gray level 63.
The data driving circuit 22 converts the 6-bit binary data signals to corresponding analog data signals, and output gray-level voltages corresponding to the analog data signals to the pixel electrodes 205 via the data lines.
Referring to
In step S1, a 8-bit binary data signal is applied to the eight frame rate controllers M0˜M7 and the look-up table 26 simultaneously. Higher 6 bits binary datum of the 8-bit binary data signal represents the gray level n, and lower 2 bits binary datum thereof forms the selecting signal.
In step S2, the current environmental temperature is detected by the detector 23, which then outputs an analog electric signal according thereto.
In step S3, the analog electric signal is converted to a digital electric signal Tk by the analog-digital converter 24, and then transmitted to the look-up table 26.
In step S4, a corresponding control signal Ci is acquired from the look-up table 26, and then output to the timing controller 27. When the digital electric signal Tk is applied to the look-up table 26, a corresponding control signal Ci is acquired from the look-up table 26 according to the relationship among the digital electric signal Tk, the higher 6 bits binary datum and the lower 2 bits binary datum, and the corresponding control signal Ci is applied to the timing controller 27.
In step S5, a corresponding frame rate controller Mi is driven according to the corresponding control signal Ci, and outputs a 6-bit binary data signal representing the gray level (n+i/8) to the data driving circuit 22.
In step S6, the 6-bit binary data signal is converted to an analog data signal by the data driving circuit 22, and the data driving circuit 22 outputs the gray-level voltage corresponding to the analog data signal to the pixel electrodes 205 via the data lines 202.
Because the timing controller 27 can regulate the gray level voltages with the current environmental temperature, even if the same 8-bit binary data signal generated by the external circuit is applied to the liquid crystal panel in different environmental temperatures, the pixels 203 can obtain the same transmission ratio. Thus, color quality of the LCD is improved.
When the 8-bit binary data signal applied to the LCD is 11111100 to 11111111, the LCD can display four gray levels. But when the 8-bit binary data signal applied to the LCD of the first embodiment is 11111100 to 11111111, the LCD merely displays one gray level. Thus, the number of gray levels displayed exceeds that of the gray levels displayed by the LCD of the first embodiment. That is, the LCD can display 256 gray levels.
In addition, the digital electric signals stored in the second column of the look-up table 26 or 36 represent different temperature value ranges, not a specific temperature value.
Furthermore, the relationship between the higher 6 bits binary data from 111110 to 111111 and the control signals Ci of the look-up table 36 can also be altered, so that the LCD can display eight gray levels when the 8-bit binary data signal is 11111000 to 11111111.
It is to be understood that even though numerous characteristics and advantages of the present embodiments have been set forth in the foregoing description with details of the structures and functions of the embodiments, the disclosure is illustrative only, and changes made in detail, especially in matters of shape, size, and arrangement of parts, within the principles of the embodiments, to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
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