1. Field of the Invention
The present invention relates to methods of image processing of liquid crystal display (LCD) devices, and more particularly to methods of displaying balanced chromatic images for LCD devices.
2. Description of the Related Art
Liquid crystal display (LCD) devices are widely used as displays in electronic devices such as portable computers, PDAs and cell phones. Liquid crystal display devices are classified into two types. One is transmissive type, and the other is reflective type. The former utilizes a backlight as the light source and the latter utilizes ambient light. It is difficult to reduce power consumption in transmissive LCDs due to the power requirements of the backlight. Reflective LCDs have the advantage of lower power consumption under bright ambient light, but are hindered by environments with less ambient light.
In order to overcome the drawbacks of these two types of LCDs, a transflective LCD is disclosed. Transflective LCDs are capable of displaying images in both transmissive and reflective modes. Under bright ambient light, the backlight can be turned off to reduce power consumption to lower than that of a transmissive LCD. Additionally, when less ambient light is available, the backlight can be turned on, thus offering improved image quality over that of reflective LCDs.
In the lower substrate 20, on a surface opposing the upper substrate 10, a TFT “T” serving as a switching device is formed in the shape of an array matrix corresponding to the color filter layer 14. In addition, a plurality of crossing gate and data lines 26 and 28 are positioned such that each TFT is located near each cross point of the gate and data lines 26 and 28. Further on the lower substrate 20, a plurality of pixel regions (P) is defined by the gate and data lines 26 and 28. Each pixel region P has a pixel electrode 22 comprising a transparent portion 22a and an opaque portion 22b. The transparent portion 22a comprises a transparent conductive material, such as ITO (indium tin oxide) or IZO (indium zinc oxide), and the opaque portion 22b comprises a metal having high reflectivity, such as Al (aluminum).
Referring to
U.S. Pat. No. 5,233,385 discloses a method for increasing the brightness of a scene in a color projection. This method uses a white light to raise the brightness in both temporal and spatial filtering systems.
U.S. Pat. No. 5,929,843 discloses a method and apparatus for processing image data comprising the steps of extracting white component data from input R, G, B data, suppressing the white component data in accordance with a non-linear characteristic, generating R, G, B, W display data and driving a liquid crystal display panel having R, G, B, W filters in accordance with R, G, B, W data in order to display a full color image.
U.S. Publication No. 2004/0046725 discloses a four color liquid crystal display including R, G, B and W pixels, for improving optical efficiency.
Moreover, U.S. Publication No. 2003/0128872, the entirety of which is hereby incorporated by reference, discloses a method for generating a white signal component and for controlling the brightness of an image of a transmissive LCD.
None of the above cited references are directed to LCD devices with balanced chromatic image in the transmissive and the reflective displaying modes.
The invention is directed to a novel method for displaying balanced chromatic images for an LCD and an LCD structure configured to reduce the difference in chromaticity between the transmissive mode and the reflective mode by providing a substantively white light. In one aspect of the present invention, a novel structure is disclosed wherein the pixel area comprises a white sub-pixel area providing a white light in the reflective mode, compared to the transmissive mode. In another aspect of the present invention, a method for normalizing chromaticity between transmissive and reflective modes of a transflective LCD device is disclosed. The structure and method of the present invention comprises the provision of a white sub-pixel area that supports a white light to increase brightness in the reflective mode, compared to the transmissive mode.
The invention provides a method of displaying balanced chromatic images for a liquid crystal display (LCD) device with a transmissive mode and a reflective mode. The method comprises displaying images on the LCD device in the transmissive mode with a first white output signal, and displaying images on the LCD device in the reflective mode with a second white output signal, wherein the first white output signal is different from the second white output signal.
The invention also provides a method of displaying balanced chromatic image for a liquid crystal display (LCD) device with a transmissive mode and a reflective mode. The method comprises displaying the LCD device in the transmissive mode without a white input signal, and displaying the LCD device in the reflective mode with a white output signal, wherein the white output signal equals a×Ri+b×Gi+c×Bi, where 0<a<1, 0<b<1, or 0<c<1 respectively.
The invention further provides an LCD device having a plurality of main pixel areas, wherein each main pixel area comprises three primary sub-pixels and a white sub-pixel. Each sub-pixel comprises a transmissive portion and a reflective portion and corresponds to a color filter. The color filter comprises three primary color regions and a white region, wherein the primary sub-pixels correspond to the primary color regions and the white sub-pixel corresponds to the white region. The white region may have no color layer or have a transparent resist layer. When the transflective LCD device is operated in a transmissive mode, the white sub-pixel is driven to not emit light. Conversely, when the transflective LCD device is operated in a reflective mode, the white sub-pixel area is driven to emit light. That is, the white sub-pixel only provides the white light in the reflective mode, thereby normalizing chromaticity between transmissive and reflective modes.
The invention further provides an LCD device comprising a plurality of main pixel areas, wherein each main pixel area comprises three primary sub-pixels and a white sub-pixel and a color filter corresponding to the sub-pixels. Each primary sub-pixel comprises a transmissive portion and a reflective portion and the white sub-pixel is a reflective pixel. The color filter comprises three primary color regions and a white region, wherein the primary sub-pixels correspond to the primary color regions and the white sub-pixel corresponds to the white region. The white region may have no color layer or have a transparent resist layer. When the transflective LCD device is operated in a transmissive mode, there is no light transmitted through the white sub-pixel. Conversely, when the transflective LCD device is operated in a reflective mode, the white sub-pixel reflects ambient light to display white light, thereby normalizing chromaticity between transmissive and reflective modes.
The invention further provides a liquid crystal display (LCD) device with three primary color sub-pixels and a white sub-pixel. A first substrate and a second substrate are disposed opposite to each other with a liquid crystal layer interposed therebetween. A transparent electrode is disposed on the first substrate at each of the three primary color sub-pixels. An electrode with a reflective portion is disposed on the first substrate at the white sub-pixel.
The invention can be more fully understood by reading the subsequent detailed description in conjunction with the examples and references made to the accompanying drawings, wherein:
The following description is of the best-contemplated mode of carrying out the invention. This description is made for the purpose of illustrating the general principles of the invention and should not be taken in a limiting sense. The scope of the invention is best determined by reference to the appended claims.
A first substrate 400, serving as a lower substrate, can be a glass substrate including an array of pixel driving elements (not shown), such as an array of thin film transistors (TFTs). A backlight device 401 is disposed at the outer side (i.e. the backside) of the first substrate 400. Three sub-pixel electrodes 410 and a sub-pixel electrode 415 are formed on the first substrate 400, wherein each sub-pixel electrode 410 is located in each primary color sub-pixel area 3101/3102/3103 and the sub-pixel electrode 415 is located in the white sub-pixel area 3104. Note that a representative sub-pixel electrode 410 is shown in
A second substrate 490, such as glass, opposite the first substrate 400 is provided. The second substrate 490 serves as an upper substrate. A color filter 480 is formed on the inner side of the second substrate 490. The color filter 480 comprises three primary color regions R, G and B and a white region W. The white region W may have no color layer or have a transparent resist layer. Note that a representative primary color region R/G/B is shown in
A common electrode 470 is then formed on an inner side of the second substrate 490. The common electrode 470 may be an ITO or IZO layer. In
When operating in transmissive mode, a backlight 402 from the backlight device 401 passes through the primary color regions R, G and B once. According to this embodiment, the liquid crystal orientation above the sub-pixel electrode 415 is controlled to transmit backlight at different levels of brightness. In one aspect of this embodiment, when the white sub-pixel area 3104 is driven to not transmit light (i.e. the white sub-pixel area 3104 is dark), the color gamut is preserved in the transmissive mode. In another aspect of this embodiment, when the white sub-pixel area 3104 is allowed to transmit light, the color gamut will change with the different brightness levels.
When operating in reflective mode, a reflective light 403 from an exterior light source (not shown) passes through the primary color regions R, G and B twice, causing display color in the reflective mode to be darker than that in the transmissive mode. At this time, according to the present invention, the liquid crystal orientation above the sub-pixel electrode 415 is controlled to cause the reflective light 403 to penetrate the liquid crystal layer 465 above the second reflective portion 4152 (i.e. the sub-pixel electrode 415). That is, when the white sub-pixel area 3104 is driven to transmit white light to raise display brightness and dilute the color purity in the reflective mode, the color gamut is thereby varied with different brightness levels.
Thus, the overall chromaticity and color gamut for the two modes may be controlled to a desired value, which may be substantially the same or different chromaticity.
An operational example of this embodiment is illustrated hereinafter.
When operating in transmissive mode, a backlight 402 emitted from the backlight device 401 passes through the primary color regions R, G and B once. Note that the sub-pixel electrode 515 blocks backlight 402 from the backlight device 401 because the sub-pixel electrode 515 is opaque. That is, the white sub-pixel area 3104 does not transmit light (i.e. the white sub-pixel area 3104 is dark) in the transmissive mode.
When operating in reflective mode, a reflective light 403 from an exterior light source (not shown) passes through the primary color regions R, G and B twice, causing display color in the reflective mode to be darker than that in the transmissive mode. At this time, according to the invention, the white sub-pixel area 3104 displays a white light to raise brightness by reflection of the sub-pixel electrode 515; furthermore, the white sub pixel area can be driven to display different brightness levels to change the color gamut in the reflective mode.
A first substrate 400, serving as a lower substrate, can be a glass substrate including an array of pixel driving elements (not shown), such as an array of thin film transistors (TFTs). A backlight device 401 is disposed at the outer side (i.e. the backside) of the first substrate 400. Three sub-pixel electrodes 510 and a sub-pixel electrode 520 are formed on the first substrate 400, wherein each sub-pixel electrode 510 is located in each primary color sub-pixel area 3101/3102/3103 and the sub-pixel electrode 520 is located in the white sub-pixel area 3104. Note that a representative sub-pixel electrode 510 is shown in
A second substrate 490, such as glass, opposite the first substrate 400 is provided. The second substrate 490 serves as an upper substrate. A color filter 480 is formed on the inner side of the second substrate 490. The color filter 480 comprises three primary color regions R, G and B and a white region W. The white region W may have no color layer or have a transparent resist layer. Note that a representative primary color region R/G/B is shown in
A common electrode 470 is then formed on an inner side of the second substrate 490. The common electrode 470 may be an ITO or IZO layer. In
When operating in transmissive mode, a backlight 402 from the backlight device 401 passes through the primary color regions R, G and B once. According to this embodiment, the liquid crystal orientation above the sub-pixel electrode 520 is controlled to transmit backlight at different brightness light levels. In one aspect of this embodiment, when the white sub-pixel area 3104 is driven to not transmit light (i.e. the white sub-pixel area 3104 is dark), thus, the color gamut is preserved in the transmissive mode. In another aspect of this embodiment, when the white sub-pixel area 3104 is allowed to transmit light, thus the color gamut will change with the different brightness levels.
When operating in reflective mode, a reflective light 403 from an exterior light source (not shown) passes through the primary color regions R, G and B twice and is reflected by the semi-transmissive layer 405, causing display color in the reflective mode to be darker than that in the transmissive mode. At this time, according to the present invention, the liquid crystal orientation above the sub-pixel electrode 520 is controlled to cause the reflective light 403 to penetrate the liquid crystal layer 465. That is, when the white sub-pixel area 3104 is driven to transmit white light to raise display brightness and dilute the color purity in the reflective mode, the color gamut is thereby varied with different brightness levels.
Thus, the overall chromaticity and color gamut for the two modes may be controlled to a desired value, which may be substantially the same chromaticity or different chromaticity.
An operational example of this embodiment is illustrated hereinafter.
When operating in transmissive mode, a backlight 402 from the backlight device 401 passes through the primary color regions R, G and B once. Note that the sub-pixel electrode 525 blocks backlight 402 emitted from the backlight device 401 because the sub-pixel electrode 515 is opaque. That is, the white sub-pixel area 3104 does not transmit light (i.e. the white sub-pixel area 3104 is dark) in the transmissive mode. Thus, the color gamut can keep the same value for the transmissive mode.
When operating in reflective mode, a reflective light 403 from an exterior light source (not shown) passes through the primary color regions R, G and B twice and is reflected by the semi-transmissive layer 405, causing display color in the reflective mode to be darker than that in transmissive mode. At this time, according to the invention, the white sub-pixel area 3104 displays a white light to raise brightness by reflection of the sub-pixel electrode 515; furthermore, the white sub pixel area can be driven to display different brightness levels to change the color gamut in reflective mode.
A first substrate 400, serving as a lower substrate, can be a glass substrate including an array of pixel driving elements (not shown), such as an array of thin film transistors (TFTs). A backlight device 401 is disposed at the outer side (i.e. the backside) of the first substrate 400. Three sub-pixel electrodes 510 and a sub-pixel electrode 520 are formed on the first substrate 400, wherein each sub-pixel electrode 510 is located in each primary color sub-pixel area 3101/3102/3103 and the sub-pixel electrode 520 is located in the white sub-pixel area 3104. Note that a representative sub-pixel electrode 510 is shown in
A second substrate 490, such as glass, opposite the first substrate 400 is provided. The second substrate 490 serves as an upper substrate. A color filter 480 is formed on the inner side of the second substrate 490. The color filter 480 comprises three primary color regions R, G and B and a white region W. The white region W may have no color layer or have a transparent resist layer. Note that a representative primary color region R/G/B is shown in
A common electrode 470 is then formed on an inner side of the second substrate 490. The common electrode 470 may be an ITO or IZO layer. In
When operating in transmissive mode, a backlight 402 from the backlight device 401 passes through the primary color regions R, G and B once. According to this embodiment, the liquid crystal orientation above the sub-pixel electrode 520 is controlled to transmit backlight at different brightness light levels. In one aspect of this embodiment, when the white sub-pixel area 3104 is driven to not transmit light (i.e. the white sub-pixel area 3104 is dark), thus, the color gamut is preserved in the transmissive mode. And in another aspect of this embodiment, when the white sub-pixel area 3104 is allowed to transmit light, so the color gamut will change with the different brightness levels.
When operating in reflective mode, a reflective light 403 from an exterior light source (not shown) passes through the primary color regions R, G and B twice and is reflected by the reflective film of the backlight device 401 or is reflected by the PCF, causing display color in the reflective mode to be darker than that in the transmissive mode. At this time, according to the present invention, the liquid crystal orientation above the sub-pixel electrode 520 is controlled to cause the reflective light 403 to penetrate the liquid crystal layer 465. That is, when the white sub-pixel area 3104 is driven to transmit white light to raise display brightness and dilute the color purity in the reflective mode, thereby the color gamut varies with different brightness level.
Thus, the overall chromaticity and color gamut for the two modes may be controlled to a desired value, which may be substantially the same chromaticity or different chromaticity.
The invention improves the chromaticity of the conventional LCD devices by introducing a white sub-pixel to provide white light in the transmissive and reflective modes. The white sub-pixel comprises a reflective portion reflecting the white light when in the reflective mode. Thus, the chromaticity of the reflective mode approaches that of transmissive mode, improving display quality.
Normalizing Chromaticity and Adjusting Color Gamut
According to the invention, the white sub-pixel is driven to pass white light to dilute color purity so that the LCD device can display brighter images with faithful color purity in the reflective mode. Because the LCD device in the transmissive mode has less reflection in the white sub-pixel area, to obtain better display performance, the white sub-pixel is suggested to be driven by at least 1% of maximum reflection ratio of white sub-pixel.
Ri:Gi:Bi=(Ro+Wo):(Go+Wo):(Bo+Wo)
Ri, Gi, and Bi denote color inputs of red, green and blue respectively. Ro, Go, Bo, and Wo denote color outputs of red, green, blue, and white respectively. Ro, Go, Bo, and Wo can be given as:
Ro=M×Ri−Wo
Go=M×Gi−Wo
Bo=M×Bi−Wo
Wo=f(Ri,Gi,Bi)
M is a predetermined constant and f(Ri, Gi, Bi) can be regarded as a function to show white color component extracted from color inputs of Ri, Gi, and Bi. Note that the f(Ri, Gi, Bi) is dependent from conditions of viewing angles, brightness, or applying electrical fields.
For reflective mode, the algorithm I and II 930 and 940 converted from RGB to RGBW are represented as follows:
Ro=M×Ri−Wo
Go=M×Gi−Wo
Bo=M×Bi−Wo
Wo′=Wo+a×Ri+b×Gi+c×Bi,
where 0<a<1, 0<b<1, or 0<c<1 respectively.
While the invention has been described by way of example and in terms of the preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. To the contrary, it is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art). Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.
This application is a Continuation-In-Part of pending U.S. patent application Ser. No. 11/023,219, filed on Dec. 27, 2004 and entitled “transflective liquid crystal display device with balanced chromaticity”, the teachings of which are incorporated herein by reference.
Number | Date | Country | |
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60654373 | Feb 2005 | US |
Number | Date | Country | |
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Parent | 11023219 | Dec 2004 | US |
Child | 11317447 | Dec 2005 | US |