Object detection for wireless energy transfer systems

What is claimed is: 1. A living object detector for a wireless energy transfer system, comprising: a sensor comprising a first conductor positioned adjacent to a first surface of a substrate; a shield comprising a second conductor different from the first conductor, wherein at least a portion of the second conductor is positioned proximal to the first conductor and adjacent to the first surface of the substrate; a ground reference comprising a third conductor spaced from the substrate and positioned on a side of the substrate opposite to the first surface, wherein during operation of the living object detector, the third conductor is maintained at a ground reference electrical potential; first and second switches; and an electrical circuit coupled to the first, second and third conductors and to the first and second switches, and configured so that during the operation of the living object detector: the electrical circuit applies a first electrical potential to the first conductor and a second electrical potential to the second conductor, the first and second electrical potentials being approximately similar; and the electrical circuit can charge and discharge the first conductor by activating the first and second switches. 2. The detector of claim 1 , comprising third and fourth switches coupled to the electrical circuit, wherein the electrical circuit is configured so that during the operation of the living object detector, the electrical circuit can charge and discharge the second conductor by activating the third and fourth switches. 3. The detector of claim 1 , wherein the electrical circuit is configured so that during the operation of the detector, the electrical circuit: measures a capacitance of the sensor; and determines whether a living object is present within a spatial region proximal to the sensor based on the measured capacitance. 4. The detector of claim 1 , wherein: the first conductor comprises one or more electrical traces formed on the first surface of the substrate; and the second conductor is at least partially formed on multiple surfaces of the substrate, wherein the multiple surfaces comprise the first surface and a second surface of the substrate opposite the first surface. 5. The detector of claim 4 , wherein the second conductor wraps around at least a portion of the substrate. 6. The detector of claim 1 , further comprising an enclosure. 7. The detector of claim 6 , wherein the first, second, and third conductors are each positioned within the enclosure. 8. The detector of claim 3 , wherein the detector is coupled to a wireless energy transfer system, and wherein the spatial region corresponds to a region through which electrical energy is transferred wirelessly between a wireless energy source of the system and a wireless energy receiver. 9. The detector of claim 1 , wherein the second conductor surrounds portions of multiple surfaces of the substrate and comprises an opening, and wherein the first conductor is positioned within the opening. 10. A wireless energy transfer system, comprising: the detector of claim 1 ; and a wireless energy source positioned in proximity to the detector, wherein the wireless energy source is configured so that during operation of the system, the wireless energy source transfers energy wirelessly to a device configured to receive the energy. 11. The detector of claim 7 , wherein the enclosure comprises a support surface configured to contact at least one of a floor surface and a ground surface, and at least one of the sensor and the shield is oriented at an angle with respect to the support surface. 12. A wireless energy transfer system, comprising: a chassis; a wireless energy source, wherein the wireless energy source is configured to transfer energy wirelessly to a wireless energy receiver; and a living object detection system positioned in proximity to the wireless energy source and comprising: a sensor comprising a first conductor positioned adjacent to a first surface of a substrate; a shield comprising a second conductor different from the first conductor, wherein at least a portion of the second conductor is positioned proximal to the first conductor and adjacent to the first surface of the substrate; a ground reference comprising a third conductor spaced from the substrate and positioned on a side of the substrate opposite to the first surface, wherein during operation of the living object detector, the third conductor is maintained at a ground reference electrical potential; and an electrical circuit coupled to the first, second, and third conductors and configured so that during the operation of the living object detector, the electrical circuit applies a first electrical potential to the first conductor and a second electrical potential to the second conductor, the first and second electrical potentials being approximately similar, wherein an extended portion of the second conductor is positioned between the wireless energy source and the chassis. 13. The system of claim 12 , wherein the electrical circuit is configured so that during the operation of the living object detector, the electrical circuit: measures a capacitance of the sensor; and determines whether a living object is present within a spatial region proximal to the sensor based on the measured capacitance. 14. The system of claim 13 , wherein the spatial region corresponds to a region through which electrical energy is transferred wirelessly between the wireless energy source of the device. 15. A living object detector for a wireless energy transfer system, comprising: a sensor comprising a first conductor positioned adjacent to a first surface of a substrate, wherein the sensor has a resistance R sensor and a capacitance C sensor ; a shield comprising a second conductor different from the first conductor, wherein at least a portion of the second conductor is positioned proximal to the first conductor and adjacent to the first surface of the substrate, and wherein the shield has a resistance R shield and a capacitance C shield ; a ground reference comprising a third conductor spaced from the substrate and positioned on a side of the substrate opposite to the first surface, wherein during operation of the living object detector, the third conductor is maintained at a ground reference electrical potential; and an electrical circuit coupled to the first, second and third conductors and configured so that during the operation of the living object detector, the electrical circuit: applies a first electrical potential to the first conductor and a second electrical potential to the second conductor, the first and second electrical potentials being approximately similar; and applies the first and second electrical potentials to the first and second conductors so that a parasitic capacitance between the first and second conductors is within 30% or less of a minimum value of the parasitic capacitance between the first and second conductors, wherein the minimum value of the parasitic capacitance between the first and second conductors occurs when a switching frequency at which the first and second electrical potentials are applied to the first and second conductors is less than 1/(R sensor *C sensor ) and less than 1/(R shield *C shield ). 16. The detector of claim 15 , wherein the electrical circuit is configured so that during the operation of the detector, the electrical circuit: measures a capacitance of the sensor; and determines whether a living object is present within a spatial region proximal to the sensor based on the