Abstract:
In one implementation, a method provides a plurality of graphics. The method backlights the graphics by using reflected light and/or blocking direct light. The method also highlights one of the graphics by using direct light that overpowers the backlighting of the one of the graphics.

Description:
FIELD OF THE INVENTION 
     An embodiment of the present invention relates to an electronic indicator with backlighting. 
     DESCRIPTION OF BACKGROUND INFORMATION 
     Traditional gear shifter indicators include graphics that are backlighted with lighting devices located directly behind the graphics and, also, include highlighting devices that cause a shadow on the graphics. Traditional gear shifter indicators, with graphics and lighting devices of different colors located directly behind the graphics, are also not cost effective and do not supply even lighting. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the drawings, like reference numerals represent similar parts of the illustrated embodiments of the present invention throughout the several views and wherein: 
         FIG. 1  depicts a front view of an embodiment of a gear shifter indicator; 
         FIG. 2  depicts a back view of the gear shifter indicator of  FIG. 1 ; 
         FIG. 3  depicts a cross-sectional view of the gear shifter indicator of  FIG. 1 ; and 
         FIG. 4  depicts side view of the gear shifter indicator of  FIG. 1 . 
     
    
    
     DETAILED DESCRIPTION 
     One embodiment of the present invention (see e.g.,  FIGS. 1-4 ) allows an electronic gear shifter indicator  100 , or any other automotive or general consumer electronic application, to provide constant backlighting in a first wave length and highlighting in a second wave length, for example, without traditional enunciators. The gear shifter indicator (e.g., without enunciators) may backlight graphic indicators  110  in a blue-white color and highlight one of the graphic indicators in amber. The one of the graphic indicators may be highlighted without light spillage to any other graphic indicators. The lighting conditions of backlighting and highlighting may not be affected by any light obstruction that causes shadows on any part of the graphics. 
     A graphic of the gear shifter indicator may be lit for highlighting by a LED  120  located, for example, directly behind a graphic. A transmissibility layer on the graphic may allow the gear shifter indicator to produce even highlighting. 
     The remaining graphics may be backlighted, for example, without any shadowing effect from the LEDs, by reflected light (as opposed to traditional direct lighting approach) to produce an even glow. A reflected light box design may block direct light within the box from reaching the graphics (see  FIG. 2 ). All background lighting may be reflected off an opaque white housing, a white screened PCB, and/or a white connector housing (see  FIG. 4 ). 
     When a graphic is highlighted, the LED behind it may be focused so that all direct light is concentrated in the graphic area (and no direct light leaks from the shielded box containing the LED). The direct light, for example, from the LED overpowers the backlighting so that only the LED light can be seen. Any reflected light from the LED may not be intense enough to reflect back and affect the background lighting of the neighboring graphics. Also, the tunnels of the gear shifter indicator  160  may be molded in the color of the backlighting, so that any stray light from the highlighting LED will not affect any backlighting of the neighboring graphics (see  FIG. 2 ). 
     The gear shifter indicator may include reflective backlighting that is supplied by incandescent bulbs  130 , and direct lighting that is supplied by one or more LEDs  120 . The backlighting may be achieved by incandescent light and/or LED devices depending on the wave length and light intensity requirements. The direct lighting may have a different wave length than the backlighting. A plurality (e.g., 3 or more or less) bulbs may supply the reflective backlighting, where incandescent light may reflect from the white housing walls and a light blue bezel surface. One designated LED may emit the direct light to indicate the proper gear designator in a required wave length and intensity. 
     The color (e.g., light blue) of a bezel  140  may be used to tint any escaping light from the individual highlighting LEDs the same color as the night time background lighting (e.g., the night time background lighting may be light blue). The escaped light from these LEDs may then be more difficult to see since it may blend in with the background light. The blue tint may also reflect a large portion of the blue background light from the incandescent bulbs, thereby making the tunnel areas on the bezel glow  160  and produce even, shadowless background light at night. The prominent position of the LEDs used to highlight the individual graphics may then not block the background lighting and produce an obvious shadow on the graphics. 
     Correlations between variables in the lighting process include:
         LEDs location within the tunnel, from light obstruction perspective (A,D);   correlation between length of the light barriers and LEDs and incandescent bulbs location (B,F);   LEDs location relative to the graphics (A,D);   proper color of the tunnels to prevent light leakage from one gear position to the other and at the same time give sufficient amount of the reflective light; and/or   minimum distance between light barriers and the top portion of the bezel from the heated incandescent bulbs (E).       

     The gear shifter indicator may achieve: no light leakage from one gear position indicator to the other, overpowering of the bright sunlight for the day time indicators intensity, and/or no light obstruction caused by LEDs or bulbs devices. 
     The transmissibility of the diffusing layer  150  may allow a compromise to be reached between the brightest graphic possible and the most even lighting possible. The clearer the diffusing layer  150  is, the more light that will get through and give the brightest LED lit daytime graphic, so that the highlighted graphic is clearly visible when direct sunlight is shining on the graphic (and meet a FMVSS lighting specification). The more the light is scattered by the diffusion layer  150 , the more even the graphic will appear when lit. The scattering of the diffusing layer  150  may be maximized to the point where the highlighted graphic becomes dimmer, but is still clearly visible with direct sunlight shining on it. This maximizes the evenness of the graphics lighting in all conditions (e.g., when it is highlighted by the LED, and when it is background lit at night time) and ensures that it is visible in all conditions. 
     The diffusing layer  150  may be made using a clear ink with white pigment suspended inside it. The more white pigment there is, the more the light is diffused, thereby reducing the overall intensity. This ink may be screened onto a frosted polycarbonate sheet. 
     The diffusing layer  150  may be measured by determining the reduction in the lighting intensity when light passes through the layer. First, the intensity of the light source may be measured through a frosted polycarbonate sheet placed 8 mm in front of the light source. The light intensity may then be measured through the frosted polycarbonate sheet with the diffusing layer  150  screened onto it. This may be recorded as a percentage of the original intensity measurement (through the polycarbonate sheet without the diffusing layer). A value for the diffusing layer  150  may be about 30% of the original light intensity. A measurement of the light intensity without the diffusing layer  150  may be in the range of 16500 cd/m2 and the light intensity measurement of the light passing through the diffusion layer  150  may be in the range of 5000 cd/m2. 
     A technique normally used to diffuse graphics is to screen or paint the graphics white. This however reduces the intensity of the light passing through the graphics considerably (e.g., 2% of the original light intensity). This technique may be unacceptable in some cases. 
     The foregoing presentation of the described embodiment is provided to enable any person skilled in the art to make or use the present invention. Various modifications to the embodiment are possible, and the generic principles presented herein may be applied to other embodiments as well. As such, the present invention is not intended to be limited to the embodiment shown above, and/or any particular configuration of structure but rather is to be accorded the widest scope consistent with the principles and features disclosed in any fashion herein.