Wall-mountable wireless remote control device

What is claimed is: 1. A switch device for controlling an amount of power delivered from an alternating-current (AC) power source to an electrical load device, the switch device comprising: an enclosure configured to be installed in an electrical wallbox; an air-gap switch located inside of the enclosure and configured to be electrically coupled in series between the AC power source and the electrical load device; an air-gap switch actuator mechanically coupled to the air-gap switch and configured to be actuated by a user to open and close the air-gap switch; and a mounting structure connected to the enclosure and configured to mount a wireless communication device to the enclosure in such a way that the wireless communication device is located at least partially outside of the electrical wallbox when the enclosure is installed in the electrical wallbox. 2. The switch device of claim 1 , further comprising: a power supply electrically coupled in series with the air-gap switch and configured to conduct a charging current through the electrical load device to generate a direct-current (DC) supply voltage across an energy storage element of the wireless communication device. 3. The switch device of claim 2 , wherein the power supply is configured to be electrically coupled to the energy storage element of the wireless communication device. 4. The switch device of claim 3 , wherein the mounting structure comprises pogo pins adapted to contact electrical contacts on the wireless communication device to electrically coupled the power supply to the energy storage element. 5. The switch device of claim 2 , wherein the power supply is configured to be inductively coupled to the energy storage element. 6. The switch device of claim 2 , wherein the energy storage element comprises a capacitor or a battery. 7. The switch device of claim 2 , wherein the power supply is configured to conduct the charging current through the electrical load device without significantly distorting a load voltage developed across the electrical load device. 8. The switch device of claim 1 , further comprising a yoke portion, wherein: the yoke portion is connected to the enclosure, the yoke portion is configured to be mounted to the electrical wallbox such that the enclosure is located inside of the electrical wallbox, and the yoke portion defines the mounting structure. 9. The switch device of claim 8 , wherein the mounting structure is configured such that the wireless communication device is removable from the mounting structure after the yoke portion is mounted to the electrical wallbox. 10. The switch device of claim 9 , wherein the mounting structure further comprises an opening sized to receive the wireless communication device, and a leaf positioned in the opening configured to receive the wireless communication device in such a way that the wireless communication device is retained in position on the mounting structure and the wireless communication device is framed by the opening. 11. The switch device of claim 10 , wherein the leaf is further configured to receive a flanged recess disposed on a rear surface of the wireless communication device. 12. The switch device of claim 8 , wherein the yoke portion comprises openings configured to receive screws to mount a faceplate to the yoke portion. 13. The switch device of claim 12 , wherein the air-gap switch actuator is further configured such that when the faceplate is mounted to the yoke portion, the air-gap switch actuator is located behind the faceplate and is hidden from view. 14. The switch device of claim 12 , wherein the air-gap switch actuator is further configured such that when the faceplate is mounted to the yoke portion, the air-gap switch actuator protrudes past an edge of the faceplate such that the air-gap switch actuator is accessible to a user. 15. The switch device of claim 1 , wherein the air-gap switch actuator is further configured to be pulled horizontally away from the switch device to open the air-gap switch. 16. The switch device of claim 1 , wherein the air-gap switch actuator is further configured to slide horizontally to open the air-gap switch. 17. The switch device of claim 1 , wherein the air-gap switch is further configured to provide an actual air-gap barrier between the AC power source and the electrical load device when the air-gap switch is open. 18. The switch device of claim 1 , wherein the switch device further comprises a two-wire device.