Wireless sensor device with wireless remote programming

What is claimed is: 1. A battery-powered wireless sensor device, comprising: a battery for providing power to the wireless sensor device; a sensor for sensing one or more conditions in or around the wireless sensor device; a wireless transceiver for wirelessly sending and receiving messages to/from a remotely located device; a memory for storing one or more parameter values; a controller in communication with the battery, the sensor, the wireless transceiver and the memory, the controller configured to: switch the wireless sensor device between a lower power sleep mode and a higher power awake mode, wherein in the lower power sleep mode, the wireless sensor device does not send or receive messages to/from the remotely located device via the wireless transceiver; receive one or more messages from the remotely located device via the transceiver, wherein the one or more messages specify a sleep algorithm to be used by the controller to determine when to switch the wireless sensor device between the lower power sleep mode and the higher power awake mode; and subsequently switch between the lower power sleep mode and the higher power awake mode in accordance with the sleep algorithm specified by the one or more messages from the remotely located device; wherein the sensor is configured to provide a sensor signal, and wherein the sleep algorithm is configured to use a measure related to a rate of change of the sensor signal to determine when to switch the wireless sensor device between the lower power sleep mode and the higher power awake mode. 2. The battery-powered wireless sensor device of claim 1 , further comprising a battery condition monitor configured to provide a measure related to the current condition of the battery, wherein the sleep algorithm is configured to use, at least in part, the measure related to the current condition of the battery to determine when to switch the wireless sensor device between the lower power sleep mode and the higher power awake mode. 3. The battery-powered wireless sensor device of claim 2 , wherein the sleep algorithm is configured to increase the sleep time in response to deterioration of the condition of the battery over time. 4. The battery-powered wireless sensor device of claim 1 , wherein the controller, through the transceiver, is configured to establish communication with a network, and wherein the sleep algorithm is configured to keep the wireless sensor device in the higher power awake mode during establishment of communication with the network by the controller and transceiver. 5. A wireless controller for controlling a building control actuator, comprising: a wireless transceiver for wirelessly sending and receiving messages to/from a remotely located device; a controller for issuing commands to one or more actuators of a building control system, the controller coupled to the wireless transceiver and configured to: switch the wireless building controller unit between a lower power sleep mode and a higher power awake mode, wherein in the lower power sleep mode, the wireless building controller unit does not send or receive messages to/from the remotely located device via the wireless transceiver; receive one or more messages from the remotely located device via the wireless transceiver, wherein the one or more messages specify a sleep algorithm to be used by the wireless controller to determine when to switch the wireless controller between the lower power sleep mode and the higher power awake mode; and subsequently switch between the lower power sleep mode and the higher power awake mode in accordance with the sleep algorithm specified by the one or more messages from the remotely located device; further comprising a sensor for sensing a condition and providing an output sensor signal, wherein the sleep algorithm is configured to use a measure related to a rate of change of the sensor signal to determine when to switch the wireless controller between the lower power sleep mode and the higher power awake mode. 6. The wireless controller of claim 5 , wherein the wireless controller is configured to control a damper actuator and/or a valve actuator.