Abstract:
A flash module has a first light-emitting diode (“LED”) optically coupled to a first lens having a first viewing angle, and a second LED optically coupled to a second lens having a second viewing angle. The second viewing angle is greater than the first viewing angle. A first control signal line coupled to the first LED allows selectively activating the first LED. A second control signal line coupled to the second LED activates the second LED.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     Not applicable.  
       STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT  
       [0002]     Not applicable.  
       REFERENCE TO MICROFICHE APPENDIX  
       [0003]     Not applicable.  
       BACKGROUND OF THE INVENTION  
       [0004]     Digital still imaging devices, such as digital still cameras (“DSCs”) and mobile telephones that include imaging devices (“camera phones”) often need auxiliary lighting, such as from a flash module, when taking pictures in low-light conditions. DSCs and camera phones often have a built-in flash module for this purpose. It is generally desirable that the flash module produce light within the viewing angle of the camera to uniformly illuminate the object of the picture.  
         [0005]     Different types of light sources are used to produce light for the flash. White light is generally desired to achieve good color in the image. Gas discharge tubes are one type of light source used in flash applications. Light-emitting diodes (“LEDs”) are another type of light source used in flash applications. LED chips produce essentially a single color (wavelength) of light. A “white LED” is obtained by using wavelength-converting materials to convert light from an LED chip to different wavelengths, and the combination of lights from LED chip plus wavelength-converting materials will produce white light.  
         [0006]     Auxiliary lighting is also used in some DSCs to assist in auto-focusing the device on the object before the picture is taken. A separate LED is provided for this purpose, and is commonly referred to as an “auto focus auxiliary LED (“AFA LED”). An AFA LED typically produces high brightness through a narrow viewing angle, as opposed to a flash module, which produces light through a relatively broad viewing angle, and is separate from the flash source.  
         [0007]      FIG. 1A  shows a prior art DSC  100  having an AFA LED  102  and a flash module  104 . The flash module is a non-LED light source, such as a gas discharge tube. There is sufficient area on the face of the DSC  100  to put both the AFA and flash light sources; however, it is difficult to accommodate both light sources on smaller digital imaging devices, such as smaller DSCs and camera phones. AFA LEDs are often omitted from camera phones, which affects their auto-focus function, particularly in low-light conditions. It is desirable to provide an auto-focus auxiliary light that avoids the problems described above.  
       BRIEF SUMMARY OF THE INVENTION  
       [0008]     A flash module has a first light-emitting diode (“LED”) optically coupled to a first lens having a first viewing angle, and a second LED optically coupled to a second lens having a second viewing angle. The second viewing angle is greater than the first viewing angle. A first control signal line coupled to the first LED allows selectively activating the first LED. A second control signal line coupled to the second LED activates the second LED. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0009]      FIG. 1  shows a prior art DSC having an AFA LED and a flash module.  
         [0010]      FIG. 2  is a cross section of a flash module according to an embodiment of the present invention.  
         [0011]      FIG. 3  shows plots of relative light intensity versus off-axis angle of the light source of  FIG. 2  in both AF mode and flash mode.  
         [0012]      FIG. 4  is a diagram of an imaging device according to an embodiment of the present invention.  
         [0013]      FIG. 5  is a flow chart of a method of operating an imaging device according to an embodiment of the invention. 
     
    
     DETAILED DESCRIPTION OF THE EMBODIMENTS  
       [0014]      FIG. 2  is a cross section of a flash module  200  according to an embodiment of the present invention. The flash module  200  has three LED chips  202 ,  204 ,  206 . In a particular embodiment each LED chip emits blue light. Alternatively, each LED chip emits ultraviolet (“UV”) light. In yet other embodiments, the LED chips emit different wavelengths of light. For example, the first chip  202  is a blue-emitting LED, the second chip  204  is a red-emitting LED, and the third chip  206  is a green-emitting LED. The LED used for auto-focusing can be any color compatible with the auto-focusing system. The LED chips  202 ,  204 ,  206  are covered with wavelength-converting material  208 . The wavelength-converting material converts the light emitted by the LED chips (commonly referred to as “primary radiation”) to other wavelengths. Thus, the blue light emitted by the LED chips is converted to different colors in the visible spectrum that combine to produce white light from the flash module  200 .  
         [0015]     In a particular embodiment, the wavelength-converting material  208  has very fine particles of phosphor materials dispersed in an epoxy resin matrix. When illuminated by the primary radiation from the LED chips, a phosphor particle emits light having a longer wavelength (commonly referred to as “secondary radiation”). Different phosphor materials emit secondary radiation at different wavelengths (colors), thus phosphor materials are combined in the epoxy resin matrix to produce white light from the primary emissions of the LED chips.  
         [0016]     Alternatively, such as when the LED chips emit different primary radiation, different wavelength-converting materials are used with the different LED chips. Similarly, quantum dots may be used in combination with or alternatively to phosphor particles. In a yet alternative embodiment, wavelength-converting materials, such as phosphor particles and/or quantum dots, are dispersed in a matrix, such as a silicone elastomer, and applied to the top of the LED chips.  
         [0017]     A lensed structure  210  has three lenses (optical domes)  212 ,  214 ,  216  that are optically coupled to the respective LED chips  202 ,  204 ,  206  to disperse the light in selected radiation patterns (“viewing angles”). The first  212  and third  216  optical domes disperse light at a viewing angle  218  of between about fifty-five degrees and about seventy degrees. The second optical dome  214  disperses light at a viewing angle  220  of between about eight and about ten degrees. Alternatively, the lensed structure has two optical domes. In an embodiment, the lensed structure is formed (e.g. cast or molded) as a single piece of optical polymer.  
         [0018]     The LED chips  202 ,  204 ,  206  are mounted on a substrate  222 , typically within reflective cups  224 ,  226 ,  228 . The substrate is a plastic package substrate, a printed circuit board substrate, or a leadframe substrate, for example. The wavelength-converting material is dispensed onto the package substrate in liquid form and cured, the lensed structure  210  is secured to the package substrate  222 . In a particular embodiment, the cured wavelength-converting epoxy secures the lensed structure to the package substrate. Alternatively, or adhesive, either filling the reflective cups or at the interface of the two components, or heat bonding is used to secure the lensed structure to the package substrate. Thus, the wavelength-converting material  208  essentially fills the space between the LED chips and the lensed structure  210 . The curvatures of the surfaces of the lenses opposing the LED chips are selected in cooperation with the outer surfaces of the lenses to provide the desired radiation pattern. The wavelength-converting material provides index matching between the LED chips and the lensed structure, improving the efficiency of the flash module.  
         [0019]     The distance between the emitting surface of an LED chip  202  and an opposing surface  230  of the lensed structure is selected to provide the desired wavelength conversion(s) without unduly decreasing light intensity. For example, an epoxy matrix that is lightly loaded with phosphor material is thicker than one that is heavily loaded. If primary radiation contributes to the color of (“combined emissions”) the flash module, such as when using blues LEDs, a thick layer of heavily loaded wavelength-converting material might remove too much primary radiation from the flash light, which alters the color balance.  
         [0020]     The second LED chip  204  is independently controllable from the first and third LED chips  202 ,  206 . During operation of an imaging device, the second LED chip  204  is activated to provide a bright, narrow light beam to enhance contrast and enable the DSC sensor to focus in environments having dim lighting. The imaging device focuses on the object, which is illuminated by the second LED chip  204  and second optical dome  214 . Then, all three LED chips  202 ,  204 ,  206  are activated to provide a flash that illuminates the object turning image capture. A wider radiation pattern is desirable during flash operation to more uniformly illuminate the object. Alternatively, the second LED chip  204  is not activated during the flash operation.  
         [0021]      FIG. 3  shows plots of relative light intensity versus off-axis angle (i.e. beam spread) at the distance from the imager (i.e. light source) to the object for the flash module of  FIG. 2 . A first plot  302  shows the light distribution at the object when the second LED chip (refer to  FIG. 2 , ref. num.  204 ) is activated to provide auxiliary light for auto-focusing. A second plot  304  shows the light distribution at the object when the first, second, and third LED chips (refer to  FIG. 2 , ref. nums.  202 ,  204 ,  206 ) are activated to provide a flash function. In a particular embodiment, the LED chip  204  is driven at about 30 mA to about 50 mA in during an auto-focus operation, and is driven at less than 30 mA during the flash operation.  
         [0022]      FIG. 4  is a diagram of a portion of an imaging device  400  according to an embodiment of the present invention. The imaging device  400  includes a flash module  402  having a plurality of LEDs  404 ,  406 ,  408 . Each of the LEDs has an associated lens (not shown, see  FIG. 2 , ref. nums  212 ,  214 ,  216 ). The LEDs are LED chips or alternatively LED chips with a wavelength-converting layer. In the latter instance, additional wavelength-converting material (see  FIG. 2 , ref. num.  208 ) is not required; however, material may be used to index-match between the LEDs and the lenses. The radiation pattern from the first and third LEDs  404 ,  408  is wider than the radiation pattern from the second LED  406 . In a particular embodiment, each of the LEDs is a white-emitting LED.  
         [0023]     The imaging device has a flash module control circuit  410  that provides control signals to the flash module  402  on control signal lines  412 ,  414 . A first control signal activates only the second LED  406  during an AFA operation. A second control signal activates the first and third LEDs  404 ,  408  during a flash operation. In one embodiment, the second LED  406  is also activated by the first control signal during the flash operation. The lens designs avoids formation of a central “hot spot” (i.e. a region that is illuminated more than its surroundings) during image capture. In an alternative embodiment, the second LED  406  is activated by a third control signal during the flash operation. In an embodiment, the third control signal biases the second LED at a lower current than the second control signal. This insures sufficient brightness during the flash operation and further avoids a central hot spot. In a yet further embodiment, the second LED  406  is activated during the flash operation by the same control signal that activates the first and third LEDs  404 ,  408 .  
         [0024]      FIG. 5  is a flow chart of a method of operating an imaging device  500  according to an embodiment of the invention. A first control signal is provided to a flash module to activate a first LED in the flash module to provide an AFA light beam (step  502 ). The imaging device focuses on an object (step  504 ), and then a second control signal is provided to the flash module to activate at least a second LED in the flash module to provide an auxiliary flash beam (“flash”) (step  506 ). In a particular embodiment, the second control signal also activates the first LED. In a further embodiment, the second control signal activates additional LEDs during the flash. In a particular embodiment, the first and second LEDs are white-emitting LEDs.  
         [0025]     While the preferred embodiments of the present invention have been illustrated in detail, it should be apparent that modifications and adaptations to these embodiments might occur to one skilled in the art without departing from the scope of the present invention as set forth in the following claims.