Abstract:
A display device displays images with reduced glare from external incident light. The device includes a back light located on a bottom surface of the display device to provide internal light. Moreover, the device includes an internal circular X-polarizer located external to the back light to circularly polarize internal light. In addition, the device includes a mirror to reflect external incident light. Furthermore, the device includes a liquid crystal display located external to the mirror and the internal circular X-polarizer to display images. The device also includes an external circular X-polarizer located external to the liquid crystal display to circularly polarize external incident light, and absorb reflected external incident light and polarized internal light.

Description:
BACKGROUND 
   As computing becomes more mobile, the areas in which computing devices such as laptops, PDAs, pagers, etc., are used is ever increasing. However, an application is only useful if it can provide information to the user in an intelligible manner. The conditions under which known displays can be used are limited by limitations in their ability to be read when there is too much or too little light. Even when conditions are not severe enough to prevent reading the displays, problems such as glare and light loss may reduce the effectiveness of such displays. These conditions are especially prevalent in outdoor applications. Glare occurs when light reflected from display components causes increased luminance of black screen pixels and decreases overall contrast. Light loss may occur where the light path involves a high number of passes through a polarizer, with each pass resulting in the absorption of a portion of the available light. Glare is especially problematic for touch screens, since such screens require an additional component which also reflects a portion of the light incident thereon. 
   SUMMARY OF THE INVENTION 
   A display device displays images with reduced glare from external incident light. The device includes a back light located on a bottom surface of the display device to provide internal light. Moreover, the device includes an internal circular X-polarizer located external to the back light to circularly polarize internal light. In addition, the device includes a mirror to reflect external incident light. Furthermore, the device includes a liquid crystal display located external to the mirror and the internal circular X-polarizer to display images. The device also includes an external circular X-polarizer located external to the liquid crystal display to circularly polarize external incident light, and absorb reflected external incident light and polarized internal light. 
   A method for reducing glare in a display device by generating and transmitting light using a back light from within the display device toward an external surface thereof. In addition, the method reduces glare by circularly polarizing transmitted light using a first circular X-polarizer external to the back light. The method also involves circularly polarizing external incident light using a second circular X-polarizer external to the first circular X-polarizer. Moreover, the method involves reflecting external incident light using a mirror internal to the first circular X-polarizer. Furthermore, the method reduces glare by absorbing reflected external incident light and transmitted light using the second circular X-polarizer. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  shows an exemplary transflective display with a touch panel according to the present invention with light-ray paths in a black-screen mode; 
       FIG. 2  shows an exemplary transflective display with a touch panel according to the present invention with light-ray paths in a white-screen mode; 
       FIG. 3  shows an exemplary method by which the present invention may achieve decreased black screen luminance in a reflective mode; 
       FIG. 4  shows an exemplary method by which the present invention may achieve decreased black screen luminance in a transmissive mode; 
       FIG. 5  shows an exemplary method by which the present invention may achieve increased white screen luminance in a reflective mode; 
       FIG. 6  shows an exemplary method by which the present invention may achieve increased white screen luminance in a transmissive mode; and 
       FIG. 7  shown an exemplary computing device utilizing the transflective display according to the present invention. 
   

   DETAILED DESCRIPTION 
   The present invention may be further understood with reference to the following description and the appended drawings, wherein like elements are referred to with the same reference numerals. Transflective displays are often asked to operate in a variety of external light conditions ranging from complete darkness to bright outdoor light. When the external light is sufficient to illuminate the display, a reflective surface (such as a mirror) located on the back of the display reflects this external light, using a combination of linear polarizers and LCD pixels to illuminate desired portions of the display. When the external light is insufficient to adequately illuminate the display, a back light, also located on the back of the display, serves as a source of light for the LCD. 
     FIG. 1  shows an exemplary transflective display with a touch panel according to the present invention. The light rays are shown following pathways which would result from the display being configured for a black screen. This display may consist of an external circular X-polarizer (“ECP”)  20  which constitutes an outermost layer of the display. Internal to this polarizer  20  a touch panel (“TP”)  22  may be positioned to enable users to interact with the display for a multitude of functions. An LCD  24  is located internal to the TP  22 . Internal to the LCD  24  is a mirror  26  which reflects external light in order to illuminate the display. Internal to the LCD  24  and next to the mirror  26  may be an internal circular X-polarizer (“ICP”)  30 . A back light  28  is positioned beneath the ICP  30  for generating light in transmissive mode to illuminate the display. Each of the ECP  20  and the ICP  30  includes a linear X-polarizer in combination with a quarter wave plate. 
     FIG. 2  also shows an exemplary transflective display with a touch panel according to the present invention. The components and their orientations relative to one another are identical to those shown in  FIG. 1 , except that the light rays are shown following pathways which would result from the display being configured for a white screen. This configuration is accomplished by setting the LCD to quarter-wave retardation, which accomplishes an additional ninety degree phase-shift of the light moving from the surface of display to the mirror  2  and toward the surface of the display from back light  28 . The present invention may be also used in a reflective display, where the ICP  30  and back light  28  are eliminated and replaced with a front light. 
     FIG. 3  shows an exemplary method by which the present invention decreases black screen luminance and increases contrast in a reflective mode. In step  200 , randomly polarized external light is incident upon the outermost layer of the display (e.g., the ECP  20 ). The linear X-polarizer of the ECP  20  may, for example, be positioned on an outer surface thereof with the quarter wave plate on an inner surface. In step  202 , this incident light is first X-polarized and then circularly polarized as it passes through the ECP  20 . 
   In step  204 , this circularly polarized light continues further into the display, passing through the touch panel  22  and the LCD  24 , and reflecting off the mirror  26  on the back of the display. As this light passes inward through the display, portions of the light may be reflected back towards the surface of the display at each of the layers thereof as the light crosses the interfaces between display layers. Those skilled in the art will understand passage through the LCD  24  does not change the polarization of the light because the LCD  24  may be set to zero retardation. 
   In step  206 , the reflected light strikes the inner surface of the ECP  20  (i.e., the quarter wave plate thereof) and the circularly polarized reflected light is transformed into Y-polarized light. In step  208 , this Y-polarized light is absorbed by the linear X-polarizer which constitutes the external layer of the ECP  20  so that the light reflected from inside the display does not escape the display via the outer surface of the ECP  20 , thus the brightness of the black screen is decreased and hence the glare generated by the reflected light. 
     FIG. 4  shows an exemplary method by which the present invention decreases black screen luminance in a transmissive mode using an internal light source  28 . In step  300 , light originates from a back light  28  located on an inner-most layer of the display. In step  302 , this light is X-polarized and then circularly polarized by an internal circular X-polarizer (“ICP”)  30 . This circularly polarized light then travels in step  304  through the LCD  24  and touch panel  22  layers of the display to strike an internal surface of the external circular X-polarizer (“ECP”)  20 . In step  306 , the quarter wave plate in ECP  20  first transforms the circularly polarized light into Y-polarized light. In step  308 , this Y-polarized light is absorbed by the linear X-polarizer component of ECP  20 . 
     FIG. 5  shows an exemplary method by which the present invention increases white screen luminance in a reflective mode. In step  400 , randomly polarized external light is incident upon ECP  20  which forms the outermost layer of the display. 
   In step  402 , this incident light is first X-polarized and then circularly polarized as it passes through ECP  20 . This circularly polarized light passes through the touch panel  22  and LCD  24  layers of the display until it reflects off of the mirror  26  on the back of the display. 
   In step  404 , this light is X-polarized as it passes back through the quarter wave retardation plate of the LCD  24 . This light becomes X-polarized after four passes through the LCD  24 , namely two passes as the light is traveling toward the mirror  26  and two passes as the light is traveling in the reverse direction after being reflected. 
   In step  406 , this light re-emerges from the display. Because it is X-polarized it is not absorbed by the X-polarizer which makes up the outer layer of external circular X-polarizer  20 . This X-polarization is achieved by the two additional passes of the light through the quarter wave retardation plate of the LCD  24 . 
     FIG. 6  shows an exemplary method by which the present invention increases white screen luminance in transmissive mode using an internal light source  28 . In step  500 , the light originates from a back light  28  located on an inner-most layer of the display. 
   In step  502 , this light is X-polarized and then circularly polarized by the internal circular X-polarizer (“ICP”)  30 . This circularly polarized light then travels in step  504  through the LCD  24  set to quarter wave retardation. Due to this retardation, the circularly polarized light becomes Y-polarized. This Y-polarized light then passes through the touch panel  22  and strikes the external circular X-polarizer  20 . 
   In step  506 , the Y-polarized light passes through the ECP  20 . As it passes through the quarter-wave plate of the ECP  20 , it becomes circularly polarized. The light then passes through the linear X-polarizer. Due to its circular polarization, only one-half of the light will be transmitted through the X-polarizer. 
   The system and method of the present invention, described in detail above, possess several advantages over conventional LCDs which use linear polarization. First, the use of an external circular X-polarizer  20  to absorb reflections of light from internal layers results in decreased black screen luminance and hence increased contrast. Second, because the white screen light path makes only two passes through polarizers instead of the four passes made in prior art LCDs using linear polarization, there is a decreased loss of light along the path. This results in increased luminance of the white screen and increased contrast. 
   Those skilled in the art will understand that the transflective display according to the present invention may be utilized in a number of computing/electronic devices, such as laptops, PDAs, pagers, monitors, etc. For example, such a transflective display may be utilized in a mobile computing device as shown in  FIG. 7 . In particular,  FIG. 7  shows an exemplary computing device  100  which utilizes the transflective display  102  according to the present invention. The device  100  may be a handheld mobile computer. The device  100  may be utilized for data capturing functions (e.g., reading barcodes, RFID tags, images, etc.) using a data capturing arrangement  104 . The device  100  may also include an input arrangement  106  which allows the user to enter data into the device  100 . In addition, the device  100  may communicate to further devices using a wireless communication arrangement (not shown). 
   It will be apparent to those skilled in the art that various modifications and variations can be made in the structure and the methodology of the present invention, without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.