Power-preserving communications architecture with long-polling persistent cloud channel for wireless network-connected thermostat

What is claimed is: 1. A thermostat, comprising: a plurality of heating, ventilation, and air conditioning (HVAC) connectors; an energy-storage device; a charging circuit configured to harvest power from an HVAC system to charge the energy-storage device; a processor powered at least in part by the energy-storage device, wherein: the processor is configured to operate in a low-power state; and the processor is configured to operate in a high-power state; and a wireless communication module operatively coupled to the processor and configured to: establish and maintain wireless communications with a router, including receiving transmissions from the router; process the transmissions from the router by discriminating between a first type of transmission, a second type of transmission, and a third type of transmission, wherein: the first type of transmission comprises keep-alive messages associated with a communication channel sent from a remote thermostat-controller server to the thermostat, the second type of transmission is characterized as having a high thermostatic priority and comprising information associated with controlling the HVAC system; and the third type of transmission is characterized as having a low thermostatic priority and comprising information associated with updating the thermostat itself; and during times when the processor is operating in the low-power state: discard transmissions from the router of the first type; cause the processor to transition from the low-power state to the high-power state in response to receiving transmissions of the second type, and forwarding the transmissions of the second type to the processor to control the HVAC system, and save transmissions of the third type until the processor has transitioned to the high-power state, then forwarding the transmissions of the third type to the processor to update the thermostat itself. 2. The thermostat of claim 1 , wherein causing the processor to transition from the low-power state to the high-power state comprises the wireless communication module sending an interrupt to the processor. 3. The thermostat of claim 1 , wherein discriminating between the first type of transmission and the second type of transmission is based at least in part on one or more entries in a filter table of the wireless communication module, wherein the one or more entries are sent from the processor to the wireless communication module. 4. The thermostat of claim 1 , wherein the charging circuit comprises: a power extraction circuit configured to extract electrical power from one or more of the plurality of HVAC connectors up to a first level of electrical power; and a power control circuit coupled to the power extraction circuit, the energy-storage device, and the processor, wherein the power control circuit is configured such that: during a first time period in which an electrical load power required by the processor is less than said first level of electrical power, the power control circuit supplies the electrical load power required by the processor and charges the energy-storage device, if needed, using power from the power extraction circuit; and during a second time period in which the electrical load power required by the thermostat processing and control circuit is greater than said first level of electrical power, the power control circuit discharges the energy-storage device and supplies the electrical load power required by the processor using both power from the power extraction circuit and power from the energy-storage device. 5. The thermostat of claim 1 , wherein the wireless communication module is configured to receive the first type of transmission according to at least a first time interval, wherein the first time interval is less than a second time interval, and wherein the second time interval is determined by a maximum time that the router that is associated with said communication channel between the processor and the remote thermostat-controller server is expected to allow an idle communication channel to persist. 6. The thermostat of claim 1 , wherein the processor operating in the low-power state requires less than 100 mW, and wherein the processor operating in the high-power state requires more than 200 mW. 7. The thermostat of claim 1 , further comprising a second processor. 8. The thermostat of claim 7 , further comprising, in response to identifying a transmission of the second type during a time period in which the processor is operating in the low-power state, causing, by the processor, the second processor to transition from the low-power state to the high-power state. 9. The thermostat of claim 1 , wherein the wireless communication module operatively is further configured to: receive transmissions through a second communication channel; receive an indication that an energy stored in the energy-storage device is below a threshold; receive third transmissions through the second communication channel; and process the third transmissions while the processor is in the low-power state based on the indication that the energy stored in the energy-storage device is below the threshold. 10. A method of controlling an environmental condition, the method comprising: charging an energy-storage device using a first power harvested from an external power source; powering a circuit at least in part with energy from the energy-storage device, wherein: the circuit is configured to operate in a low-power mode; and the circuit is configured to operate in a high-power mode; establishing one or more communication channels with a server; communicating with the server using a protocol, wherein the protocol comprises: a first type of transmission comprising keep-alive messages sent from the server at least in part to maintain one or more communication channels, a second type of transmission characterized as having a high environmental priority and comprising information for controlling the environmental condition; and a third type of transmission characterized as having a low environmental priority and comprising information associated with updating the circuit itself; and discriminating between transmissions of the first type, transmissions of the second type, and transmissions of the third type; in response to identifying a transmission of the first type during a time period in which the circuit is operating in the low-power mode, allowing the circuit to continue operating in the low-power mode and discarding the transmission of the first type; in response to identifying a transmission of the second type during a time period in which the circuit is operating in the low-power mode, causing the circuit to transition from the low-power mode to the high-power mode, and forwarding the transmissions of the second type to the circuit to control the environmental condition; and in response to identifying a transmission of the third type during a time period in which the circuit is operating in the low-power mode, saving the transmission of the third type until the circuit has transitioned to the high-power mode, then forwarding the transmission of the third type to the circuit to update the circuit itself. 11. The method of claim 10 , wherein the one or more communication channels comprises a first channel and a second channel. 12. The method of claim 11 , further comprising: receiving the transmission of the second type from the server through the first channel; determining that the transmission of the second type is classified as a high-priority transmission at least in part because it was received through the first channel. 13. Th