Embodiments of the present disclosure relate to liquid crystal displays (LCDs), and more particularly to an LCD employing a polarity analyzing unit to determine polarities of pixels thereof.
LCDs are widely used in various information products, such as notebooks, personal digital assistants, video cameras, and the like. A conventional LCD utilizes liquid crystal molecules to control light transmission in each pixel of the LCD. In general, the conventional LCD employs an inversion system, such as a frame inversion system, for example, to drive the liquid crystal molecules.
By employing the frame inversion system, the LCD can be protected from what is known as “burn in” where continual operation of the video signal causes damage to the LCD. However, because the polarities of all the pixels are the same in each frame period, and are simultaneously inverted in the subsequent frame period, a user may perceive that an image displayed by the LCD is skipping during the inversion of the polarities of the pixels. Thereby, a so-called flicker phenomenon is generated in the LCD, and the display quality of the LCD is unsatisfactory.
From the foregoing, it should be appreciated that there is a need for an LCD to overcome the “burn-in” effect. To this end, there is a need for an LCD to overcome the so-called flicker phenomenon.
In one aspect, a liquid crystal display includes a plurality of pixels arranged in a matrix, a brightness identification unit configured for identifying a brightness of an image element to be displayed by at least one pixel from the plurality of pixels, a polarity analyzing unit configured for analyzing a result of the identification, and for generating a composed binary signal, and a data circuit configured to provide a data voltage to drive the at least one pixel according to the composed binary signal. The brightness of the image element is determined by a corresponding primary display signal. The composed binary signal having a first binary portion the same as the primary display signal and an additive second binary portion. A value of the data voltage is determined by the first binary portion of the composed binary signal, and a polarity of the at least one pixel is determined by the second binary portion of the composed binary signal.
In another aspect, a liquid crystal display includes a plurality of pixels, a brightness identification unit, a polarity analyzing unit, and a data circuit. Each pixel corresponds to a first signal having a bright state or a dark state. The brightness identification unit is configured for identifying the first signal of each pixel. The polarity analyzing unit is configured for analyzing a result of the identification in order to generate a second signal having an additive portion. The data circuit is configured to provide a data voltage to drive the pixel according to the second signal. A value of the data voltage is determined by the first signal, and a polarity of the pixel is determined by the additive portion of the second signal.
Other novel features and advantages will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
Reference will now be made to the drawings to describe certain embodiments of the present disclosure in detail.
The liquid crystal panel 310 includes m rows of parallel scanning lines X1˜Xm (where m is a natural number), n columns of parallel data lines Y1˜Yn (where n is also a natural number) perpendicular to the scanning lines X1˜Xm, and a plurality of pixels P(i, j) (where i, j are both natural numbers, 1≦i≦m, 1≦j−n) cooperatively defined by the crossing scanning lines X1˜Xm and data lines Y1˜Yn. Thereby, the pixels P(i, j) are arranged in a matrix having m rows and n columns. The scanning lines X1˜Xm are electrically coupled to the scanning circuit 320, and the data lines Y1˜Yn are electrically coupled to the data circuit 330. In the liquid crystal panel 310, each pixel P(i, j) has a respective address corresponding to a digital address signal. The digital address signal includes a horizontal address code indicating which row the pixel P(i, j) is located in, and a vertical address code indicating which column the pixel P(i, j) is located in. In the following description, P(i, j) refers to the pixel located in the (i)th row and (j)th column of the matrix.
Each pixel P(i, j) includes a thin-film transistor (TFT) 311, a pixel electrode 312, and a common electrode 313. A gate electrode of the TFT 311 is electrically coupled to a corresponding one of the scanning lines X1˜Xm, and a source electrode of the TFT 311 is electrically coupled to a corresponding one of the data lines Y1˜Yn. Furthermore, a drain electrode of the TFT 311 is electrically coupled to the pixel electrode 312. The common electrode 313 is generally opposite to the pixel electrode 312, with a plurality of liquid crystal molecules (not shown) sandwiched therebetween, so as to cooperatively form a liquid crystal capacitor 314.
The timing controller 340 includes a receiving unit 341, a timing control unit 342, a brightness identification unit 343, and a polarity analyzing unit 344. The receiving unit 341 is configured to receive digital display signals from an external circuit (not shown), and store the digital display signals in the memory 350. The timing control unit 342 is configured to control drive timings of the scanning circuit 320, the data circuit 330, and the brightness identification unit 343. The brightness identification unit 343 is configured to identify a brightness of a color to be displayed by each pixel P(i, j) according to the corresponding digital display signal. Furthermore, the brightness identification unit 343 is configured to provide a brightness sign bit B1 to the display signal according to a result of the brightness identification. The polarity analyzing unit 344 is configured to analyze the brightness sign bit B1, and correspondingly convert the brightness sign bit B1 into a polarity control bit B2. The polarity analyzing unit 344 includes an inner register (not shown).
Referring to
Operation of the LCD 300 is as follows. To simplify the following description, only an operation of the (i)th row of pixels P(i, j) of the LCD 300 in an Nth frame period is taken as an example. However, it may be understood that a similar operation may take place according to any row of the pixels P(i, j) and in any frame period. In addition, the following definitions and labels may be defined. A primary display signal D0(i, j) refers to a digital display signal corresponding to the pixel P(i, j) received by the receiving unit 341 in the Nth frame period. A brightness sign bit B1(i, j) refers to one of the brightness sign bits B1 corresponding to the pixel P(i, j) provided by the brightness identification unit 343 in the Nth frame period. A polarity control bit B2(i, j) refers to one of the polarity control bits B2 corresponding to the pixel P(i, j) provided by the polarity analyzing unit 344 in the Nth frame period. A polarity control bit B2*(i, j) refers to one of the polarity control bits B2 corresponding to the pixel P(i, j) in an (N−1)th frame period. A first display signal D1(i, j) refers to the primary display signal D0(i, j) with the brightness sign bit B1(i, j). A second display signal D2(i, j) refers to the primary digital display signal D0(i, j) with the polarity control bit B2(i, j).
Moreover, the pixel P(i, j) is defined as having a positive polarity when the data voltage received by the pixel electrode 312 is greater than a reference voltage (usually named as a common voltage generated by a common voltage circuit (not shown)) received by the common electrode 313. Conversely, the pixel P(i, j) is defined as having a negative polarity when the data voltage is lower than the reference voltage.
The receiving unit 341 may receive digital display signals from an external circuit (not shown) and output the digital display signals to the timing controller 340 in the Nth frame period. The receiving unit 341 may further output the primary display signal D0(i, j) to the memory 350. In particular, each primary display signal D0(i, j) is an 8-bit digital signal selected from the binary numbers 00000000˜11111111, corresponding to one of 256 gray levels.
The brightness identification unit 343 receives and processes the primary display signal D0(i, j) under the control of an internal timing control signal provided by the timing control unit 342. The brightness identification unit 343 then recognizes a value of each primary display signal D0(i, j) to identify a brightness of a color to be displayed by the corresponding pixel P(i, j), and accordingly generates a corresponding brightness sign bit B1(i, j). For example, when the primary display signal D0(i, j) is in a range from 00000000˜01110111, the primary display signal D0(i, j) corresponds to a gray level selected from the first to the 119th gray level. The brightness identification unit 343 identifies the primary display signal D0(i, j) as being a dark signal (i.e. in a dark state), and provides a brightness sign bit B1(i, j) equal to 0 to the primary display signal D0(i, j). In another example, when the primary display signal D0(i, j) is in a range from 01111000˜11111111, the primary display signal D0(i, j) corresponds to a gray level selected from the 120th to the 256th gray level. The brightness identification unit 343 identifies the primary display signal D0(i, j) as being a bright signal (i.e. in a bright state, and provides a brightness sign bit B1(i, j) equal to 1 to the primary display signal D0(i, j). The brightness sign bit B1(i, j) is added to the primary display signal D0(i, j) and treated as an independent most significant bit (i.e. the ninth bit) of the primary display signal D0(i, j). Thus, the 8-bit primary display signal D0(i, j) is converted into a 9-bit first display signal D1(i, j). For example, the corresponding first display signal D1(i, j) is 000000001 when the primary display signal D0(i, j) is 00000001. It may be appreciated that the bright state and the dark state may refer to an intensity of the corresponding gray levels of the primary display signal D0(i, j).
To convert the brightness sign bit B1(i, j) of the first display signal D1(i, j) into a polarity control bit B2(i, j), the polarity analyzing unit 344 receives the first display signal D1(i, j), and reads a corresponding vertical address code of the target pixel P(i, j) from an address register (not shown) of the LCD 300. The polarity analyzing unit 344 may then convert the brightness sign bit B1(i, j) of the first display signal D1(i, j) into a polarity control bit B2(i, j). Details of the conversion are explained as follows.
In one example, when the vertical address code indicates that the target pixel P(i, j) is located in the first column of the matrix (i.e. j=1), the target pixel P(i, j) is relabeled as P(i, 1), and a polarity control bit B2*(i, 1) of the target pixel P(i, 1) in the (N−1)th frame period is treated as a polarity inversion reference. Subsequently, the polarity analyzing unit 344 reads the polarity control bit B2*(i, 1) from the inner register, and generates a corresponding polarity control bit B2(i, 1) having an opposite polarity to the polarity control bit B2*(i, 1). The polarity control bit B2(i, 1) then replaces the brightness sign bit B1(i, 1), such that the first display signal D1(i, 1) is converted into a second display signal D2(i, 1). For example, if the polarity control bit B2*(i, 1) is equal to 1, the polarity control bit B2(i, 1) of the second display signal D2(i, 1) is equal to 0; and vice versa.
In another example, when the vertical address code indicates that the target pixel P(i, j) is not located in the first column of the matrix (i.e. 2≦j≦n), and the brightness sign bit B1(i, j) of the first display signal D1(i, j) is equal to 0, the polarity analyzing unit 344 treats the polarity control bit B2(i, j−1) of the previous pixel P(i, j−1) as a inversion reference. Subsequently, the polarity analyzing unit 344 generates a corresponding polarity control bit B2(i, j) having an opposite polarity to the polarity control bit B2(i, j−1). For example, if the polarity control bit B2(i, j−1) is equal to 1, the polarity control bit B2(i, j) of the second display signal D2(i, j) is equal to 0; and vice versa. Similarly, the first display signal D1(i, j) is then converted into a second display signal D2(i, j), with the brightness sign bit B1(i, j) being replaced by the polarity control bit B2(i, j).
In another example, when the vertical address code indicates that the target pixel P(i, j) is not located in the first column of the matrix, and the brightness sign bit B1(i, j) of the first display signal D1(i, j) is equal to 1, the polarity analyzing unit 344 analyzes whether the first display signal D1(i, j) is the first bright signal in the (i)th row of pixels P(i, j) (e.g. the brightness sign bits B1(i, 1)˜B1(i, j−1) are all equal to 0, and the brightness sign bit B1(i, j) is equal to 1). If the first display signal D1(i, j) is the first bright signal in the (i)th row of pixels P(i, j), then the brightness sign bit B1(i, j) of the first display signal D1(i, j) is maintained and treated as the polarity control bit B2(i, j). Accordingly, the first display signal D1(i, j) serves as the corresponding second display signal D2(i, j) without any conversion.
If the brightness sign bits B1(i, 1)˜B1(i, j−1) are not all equal to 0, (e.g. at least one of the brightness sign bits B1(i, k) (1≦k≦j−1) is equal to 1), assuming that a maximum value of k is q, a color to be displayed by a target pixel P(i, q), of the first display signal D1(i, q) (1≦q≦k), is in a bright state. In this situation, the polarity analyzing unit 344 treats the polarity control bit B2(i, q) as a polarity inversion reference, and generates a corresponding polarity control bit B2(i, j) having an opposite polarity to the polarity control bit B2(i, q). The polarity control bit B2(i, j) then replaces the brightness sign bit B1(i, j), such that the first display signal D1(i, j) is converted into a second display signal D2(i, j).
To simplify the above description, an example is provided. In one example, when the brightness sign bits B1(i, 1)˜B1(i, 7) of the first display signals D1(i, 1)˜D1(i, 7) corresponding to the first to seventh pixels P(i, 1)˜P(i, 7) of the (i)th row of the matrix are respectively 0, 1, 0, 0, 1, 1, and 0, the polarity control bits B2(i, 1)˜B2(i, 7) generated by the polarity analyzing unit 344 are respectively 0, 1, 0, 1, 0, 1, and 0. Furthermore, when the first display signal D1(i, j) is converted to the second display signal D2(i, j), the polarity control bit B2(i, j) is outputted and stored in the inner register of the polarity analyzing unit 344.
Similarly, other primary display signals D0(i, j) of the same row of pixel P(i, j) are then converted to the corresponding second display signals D2(i, j) sequentially. All the second display signals D2(i, j) are further outputted to the data receiver 332 of the source driver 330. The data latch 334 receives each of the second display signals D2(i, j) according to a respective shift pulse provided by the shift register 333, and then distributes the polarity control bit B2(i, j) (i.e. the ninth bit of the second display signal D2(i, j)) to the polarity control unit 335. Furthermore, the data latch 334 distributes the primary display signal D0(i, j) (i.e. the least significant eight bits of the second display signal D2(i, j)) to the D/A converter 336. The polarity control unit 335 provides a corresponding polarity control signal to the D/A converter 336 according to the polarity control bit B2(i, j). The D/A converter 336 then converts each primary display signal D0(i, j) to a data voltage having the corresponding polarity. In particular, the data voltage has a positive polarity when the polarity control bit B2(i, j) is equal to 1, and has a negative polarity when the polarity control bit B2(i, j) is equal to 0.
The data voltages corresponding to all the pixels P(i, j) in the (i)th row of the matrix are then simultaneously outputted to the pixels P(i, j) via the output buffer 337 and the corresponding data lines Yj. In addition, the (i)th row of pixels P(i, j) are activated by a scanning signal outputted from the scanning circuit 320 before the data voltages are applied thereto. Each of the data voltages then charges the corresponding liquid crystal capacitor 341 thereby generating an electric field between the pixel electrode 312 and the common electrode 313. The generated electric field drives the liquid crystal molecules to tilt to corresponding angles thereby displaying a particular color at the pixel P(i, j).
After the pixel P(i, j) generates the particular color, the (i+1)th to (m)th rows of pixels 340 are activated to display corresponding colors sequentially during the Nth frame period. It may be understood that the driving process for each row is similar to the above-described Xth row of pixels 340. Each color serves as an image element, and the aggregation of the image elements displayed by all the pixels P(i, j) of the LCD 300 simultaneously constitutes an image viewed by a user.
In summary, the LCD 300 employs the brightness identification unit 343 to identify the brightness of a color to be displayed by the each pixel P(i, j). The LCD 300 further employs the polarity analyzing unit 344 to determine a polarity of the pixel P(i, j) according to an identification result and an address code of the pixel P(i, j). Thus, the polarities of all the pixels P(i, j) are prevented from being the same in each frame period. When the polarities of the pixels P(i, j) are inverted, a portion of the pixels P(i, j) have their polarities change from positive to negative, while the rest of the pixels P(i, j) have their polarities change from negative to positive. Thus, the skipping of images displayed by the LCD 300, that might otherwise exist, can be reduced or even eliminated. Accordingly, the so-called flicker phenomenon can be diminished or even eliminated, thus improving the display quality of the LCD 300.
It is to be further understood that even though numerous characteristics and advantages of preferred and exemplary embodiments have been set out in the foregoing description, together with details of structures and functions associated with the embodiments, the disclosure is illustrative only, and changes may be made in detail (including in matters of arrangement of parts) within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
Number | Date | Country | Kind |
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200710075050.6 | Jun 2007 | CN | national |