Variable total internal reflection electrowetting lens assembly for a detector

What is claimed is: 1. A detection device, comprising: a photoreceptive transducer configured to detect light and generate signals in response to the detected light; a signal interface coupled to the transducer to receive the generated signals from the transducer and configured to output detection signals based on the received generated signals; and a lens of a transparent material having a first index of refraction, the transparent lens comprising: an optical lens aperture, opposite a lens interface, configured to receive light from field of view for direction through the transparent lens toward the transducer, a lens interface to provide light to the transducer, and a transparent exterior lens wall extending from the lens interface to the optical lens aperture; and a controllable electrowetting assembly surrounding the transparent lens, the controllable electrowetting assembly being coupled to the signal interface and configured to respond to electrowetting signals received from the signal interface, the controllable electrowetting assembly comprising: sealed container walls including at least one wall spaced about the transparent lens, wherein the sealed container walls form a fluidic sealed cell with the exterior wall of the transparent lens, a high index of refraction liquid and a low index of refraction liquid contained in the sealed cell, one of the liquids being conductive and the other of the liquids being an insulator, an electrowetting optical aperture through one or more of the container walls and extending outward from the optical lens aperture, and electrodes coupled to the signal interface and electrically coupled with at least the low index of refraction liquid, wherein: the low index of refraction liquid is responsive to the electrowetting signals output from the signal interface, to vary an amount of the exterior wall of the transparent lens covered by the low index of refraction liquid and cause total internal reflection of light within the transparent lens to thereby vary a direction and/or shape of light received from the field of view via the electrowetting optical aperture and/or the optical lens aperture. 2. The detection device of claim 1 , wherein: an index of refraction of the high index of refraction liquid is higher than the first index of refraction of the transparent lens, and an index of refraction of the low index of refraction liquid is lower than the first index of refraction of the transparent lens. 3. The detection device of claim 1 , wherein the photoreceptive transducer is a photo-detector, a light detecting diode, a photoconductive cell, a photo-emissive cell or a photo-voltaic cell. 4. The detection device of claim 1 , wherein the transparent material of the transparent lens is a glass or plastic having the first index of refraction. 5. The detection device of claim 1 , wherein the electrodes of the controllable electrowetting assembly extend at predetermined positions along a length of the sealed container walls in a direction from the lens interface to the optical lens aperture. 6. The detection device of claim 1 , wherein: a narrow field of view through the optical lens aperture is provided in response to the low index of refraction liquid extending over a larger amount of the transparent lens wall than the high index of refraction index liquid. 7. The detection device of claim 1 , wherein: a wide field of view through the optical lens aperture and the electrowetting optical aperture is provided in response to the high index of refraction liquid extending over a larger amount of the transparent lens wall than the low index of refraction index liquid. 8. A device, comprising: a transducer that converts optical energy into an electrical signal; and a variable lens assembly, coupled to deliver light to the transducer, comprising: (a) a structurally static lens formed of a transparent material having a first index of refraction in a fixed shape, including: a lens interface at a proximal end of the shape to provide light to the transducer; an optical aperture at a distal end of the shape opposite the proximal end to receive light from an environment in which the device is located; and an exterior wall that extends from a portion of the lens interface to a portion of the optical aperture; and (b) a controllable electrowetting cell coupled to the exterior wall of the transparent lens, comprising: a container wall spaced from the exterior wall of the transparent lens, the container wall and the exterior wall of the transparent lens forming a fluidic leakproof container; an electrode associated with the container wall to receive a control signal; a high index of refraction liquid within the container; and an electrically conductive low index of refraction liquid within the container, wherein: the high index of refraction liquid and the low index of refraction liquid are immiscible, and in response to a change of the control signal, the high index of refraction liquid and the low index of refraction liquid change positions within the electrowetting cell thereby altering internal light reflection characteristics of the exterior wall of the transparent lens. 9. The device of claim 8 , wherein the lens assembly has predetermined optical characteristics based on a configuration of the transparent lens, positions of the high index of refraction liquid and the low index of refraction liquid within the electrowetting cell and a configuration of the transducer. 10. The device of claim 8 , wherein an extent of change in positions of the high index and low index of refraction liquids relative to one another is based upon a value of the control signal applied to the electrode. 11. The device of claim 8 , wherein: the high index of refraction liquid has a first volume; the low index of refraction liquid has a second volume; and the ratio of the volume of the high index of refraction liquid to the volume of the low index of refraction liquid contributes to the alteration of the internal light reflection characteristics of the exterior wall of the transparent lens when a control signal is received. 12. The device of claim 8 , further configured to: receive light from a narrower field of view through the optical lens aperture in response to the low index of refraction liquid extending over a larger area of the exterior wall of the transparent lens than an area of the exterior wall of the transparent lens covered by the high index of refraction liquid. 13. The device of claim 12 , further comprising: a coupling to a signal interface, wherein the transducer is further configured to: in response to the received light, output via the coupling a signal to the signal interface. 14. The device of claim 8 , wherein: the electrowetting cell further comprises: an electrowetting optical aperture that receives light from the environment and that is substantially co-planar with the optical aperture of the transparent lens; and the device is further configured to: receive light from a wider field of view through the optical lens aperture and the electrowetting optical aperture of the electrowetting cell in response to the high index of refraction liquid extending over a larger area of the exterior wall of the transparent lens than an area of the exterior wall of the transparent lens covered by the low index of refraction index liquid. 15. The device of claim 14 , further comprising: a coupling to a signal interface, wherein the transducer is further configured to: in response to the received light, output via the coupling a signal to the sign