Lighting control system and method with battery powered control devices

What is claimed is: 1. A lighting control system installed in a room comprising: at least one battery powered lighting control device, each comprising: a user interface adapted to receive control commands from a user; a first wireless network interface adapted to transmit messages over a wireless network; and a first processor adapted to detect a low battery level, wherein upon detecting the low battery level the first processor transmits a low battery message and enters into a low battery mode during which the at least one lighting control device ceases transmitting any messages until the battery is replaced; a load controller connected to a power source and to a lighting load to control an operation of the lighting load, wherein the load controller comprises: a second wireless network interface adapted to receive messages over the wireless network; and a second processor adapted to receive the low battery message from the at least one lighting control device, wherein upon receiving the low battery message the second processor enters into a low battery mode during which the load controller maintains the lighting load turned on, and wherein upon receiving a subsequent message from at least one lighting control device the second processor exits the low battery mode and resumes normal operation. 2. The lighting control system of claim 1 , wherein the load controller is hard wired to the power source and to the lighting load. 3. The lighting control system of claim 1 , wherein the load controller comprises a receptacle for receiving a plug of the lighting load. 4. The lighting control system of claim 1 , wherein the load controller comprises a switch adapted to turn the lighting load on or off. 5. The lighting control system of claim 4 , wherein the switch comprises an electromechanical relay, a solid-state relay, or a combination thereof. 6. The lighting control system of claim 1 , wherein the load controller comprises a dimmer adapted to provide a dimmed voltage output to the lighting load. 7. The lighting control system of claim 1 , wherein the first processor is adapted to detect the low battery level by reading a battery voltage level of the battery and determining whether the battery voltage level is below a predetermined low battery threshold. 8. The lighting control system of claim 7 , wherein the low battery threshold comprises a value that exceeds a voltage level required for at least one wireless transmission over the wireless network. 9. The lighting control system of claim 1 , wherein during the low battery mode of the lighting control device, the at least one lighting control device shuts down. 10. The lighting control system of claim 1 , wherein during the low battery mode of the lighting control device, the at least one lighting control device disables one or more of its operations such that it cannot transmit messages to the load controller. 11. The lighting control system of claim 10 , wherein during the low battery mode of the lighting control device, the at least one lighting control device turns off its wireless network interface. 12. The lighting control system of claim 10 , wherein during the low battery mode of the lighting control device, the at least one lighting control device turns off its user interface. 13. The lighting control system of claim 10 , wherein during the low battery mode of the lighting control device, the first processor of the at least one lighting control device does not initiate any messages to the load controller. 14. The lighting control system of claim 1 , wherein the at least one lighting control device comprises a status light indicator; wherein during the low battery mode of the lighting control device, the at least one lighting control device visually indicates via the light indicator that its battery level is low. 15. The lighting control system of claim 1 further comprising at least one sensor, wherein during the low battery mode of the load controller, the load controller ignores any messages from the at least one senor to turn the lights off. 16. The lighting control system of claim 1 further comprising at least one daylight sensor adapted to detect and measure light intensities in the room and transmit the measured light intensities to the load controller, wherein during the low battery mode of the load controller the load controller ignores any message received from the daylight sensor. 17. The lighting control system of claim 1 , wherein the load controller is adapted to operate in a daylighting mode by dimming its output to dim the lighting load based on sunlight levels reported by a daylight sensor; wherein during the low battery mode of the load controller, the load controller exits the daylighting mode. 18. The lighting control system of claim 1 further comprising an occupancy sensor adapted to detect an occupancy state of the room and transmit a room occupied signal when the room is occupied and a room vacant signal when the room is vacant. 19. The lighting control system of claim 18 , wherein during the low battery mode of the load controller, the load controller ignores a room vacant signal received from the occupancy sensor. 20. The lighting control system of claim 18 , wherein during the low battery mode of the load controller, upon receipt of the room occupied signal the load controller enters into an occupancy low battery mode and sends a command to the occupancy sensor to operate in an occupancy mode, wherein during the occupancy low battery mode the load controller turns the lighting load on upon receiving the room occupied signal and turns the lighting load off upon receiving the room vacant signal. 21. The lighting control system of claim 1 further comprising: an occupancy sensor adapted to detect an occupancy state of the room, wherein the occupancy sensor is adapted to operate in an occupancy mode or a vacancy mode, wherein during the occupancy mode the occupancy sensor transmits a room occupied action signal when the room becomes occupied and a room vacant signal when the room becomes vacant, wherein during the vacancy mode the occupancy sensor transmits a room occupied no action signal when the room becomes occupied and a room vacant signal when the room becomes vacant; wherein during the normal operation of the load controller, the load controller is adapted to turn the lighting load on upon receipt of the room occupied action signal, turn the lighting load off upon receipt of the room vacant signal, and not change the operation of the lighting load upon receipt of the room occupied no action signal; wherein during the low battery mode of the load controller, upon receipt of the room occupied action signal or the room occupied no action signal, the load controller enters into an occupancy low battery mode and sends a command to the occupancy sensor to operate in an occupancy mode; wherein in response to the command to operate in an occupancy mode, the occupancy sensor toggles to operate in the occupancy mode. 22. The lighting control system of claim 21 , wherein during the low battery mode of the load controller, the load controller ignores the room vacant signal received from the occupancy sensor. 23. The lighting control system of claim 21 , wherein during the occupancy low battery mode, the load controller is adapted to turn the lighting load on upon receipt of the room occupied action signal, turn the lighting load off upon receipt of the room vacant signal, and