Thermostat with self-configuring connections to facilitate do-it-yourself installation

What is claimed is: 1. A thermostat configured for automated compatibility with HVAC systems that are either single-HVAC-transformer systems or dual-HVAC-transformer systems, the compatibility being automated in that a manual jumper installation is not required for adaptation to either single-HVAC-transformer systems or dual-HVAC-transformer systems, the thermostat comprising: a housing; one or more temperature sensors positioned within the housing for measuring ambient temperature; a plurality of HVAC wire connectors configured for receiving a corresponding plurality of HVAC control wires, wherein the HVAC wire connectors include a first call relay wire connector, a first power return wire connector, a second call relay wire connector, and a second power return wire connector; a thermostatic control circuit coupled to the one or more temperature sensors and configured to at least partially control the operation of the HVAC system responsive to a sensed temperature, the thermostatic control circuit including a first switching device that operatively connects the first call relay wire connector to the first power return wire connector to actuate a first HVAC function and including a second switching device that operatively connects the second call relay wire connector to the second power return wire connector to actuate a second HVAC function; and an insertion sensing and connecting circuit coupled to said first and second power return wire connectors and configured such that: (i) if first and second external wires have been inserted into the first and second power return wire connectors, respectively, then the first and second power return wire connectors are electrically isolated from each other; and (ii) otherwise, the first and second power return wire connectors are electrically connected. 2. The thermostat of claim 1 , wherein said insertion sensing and connecting circuit is configured to cause said electrical isolation of said first and second power return wire connectors upon a completion of an insertion of both of said first and second external wires without requiring a processing function from a digital processor. 3. The thermostat of claim 2 , wherein said insertion sensing and connecting circuit is configured to open a pre-existing electrical connection between said first and second power return wire connectors by operation of first and second mechanically actuated switches coupled respectively to said first and second power return wire connectors, each said mechanically actuated switch being actuated by a physical wire insertion into the associated power return wire connector. 4. The thermostat of claim 1 , further comprising a common connector and a second sensing circuitry that detects the presence of a common wire in the common connector, and causes a connection of the common connector to a power extraction circuit if the common wire is inserted, wherein the thermostat extracts power from the common wire if the common wire is inserted. 5. The thermostat of claim 4 , wherein the second sensing circuitry is configured to detect the presence of a call relay wire in a corresponding call relay wire connector, and cause a connection of that connector to the power extraction circuit if (a) the common wire is not inserted, and (b) that call relay wire is inserted. 6. The thermostat of claim 4 , wherein the second sensing circuitry is configured to detect the presence of a first call relay wire in the first call relay connector, and cause a connection of the first call relay wire to the power extraction circuit if (a) the common wire is not inserted, and (b) the first call relay wire is inserted. 7. The thermostat of claim 4 , wherein the second sensing circuitry is configured to detect the presence of a second call relay wire in the second call relay connector, and cause a connection of the second call relay wire to the power extraction circuit if (a) the common wire is not inserted, and (b) the first call relay wire is not inserted. 8. A method for automating compatibility of a thermostat with HVAC systems that are either single-HVAC-transformer systems or dual-HVAC-transformer systems, the compatibility being automated in that a manual jumper installation is not required for adaptation to either single-HVAC-transformer systems or dual-HVAC-transformer systems, the thermostat including a plurality of HVAC wire connectors configured for receiving a corresponding plurality of HVAC control wires, wherein the HVAC wire connectors include a first call relay wire connector, a first power return wire connector, a second call relay wire connector, and a second power return wire connector, the method comprising: operatively connecting the first call relay wire connector to the first power return wire connector to actuate a first HVAC function; operatively connects the second call relay wire connector to the second power return wire connector to actuate a second HVAC function; if first and second external wires have been inserted into the first and second power return wire connectors, respectively, then electrically isolating the first and second power return wire connectors; and otherwise, electrically connecting the first and second power return wire connectors. 9. The method of claim 8 , further comprising electrical isolating said first and second power return wire connectors upon a completion of an insertion of both of said first and second external wires without requiring a processing function from a digital processor. 10. The method of claim 9 , further comprising opening a pre-existing electrical connection between said first and second power return wire connectors by operation of first and second mechanically actuated switches coupled respectively to said first and second power return wire connectors, each said mechanically actuated switch being actuated by a physical wire insertion into the associated power return wire connector. 11. The method of claim 8 , wherein the thermostat further including a common connector, wherein the method further comprises detecting the presence of a common wire in the common connector, and causing a connection of the common connector to a power extraction circuit if the common wire is inserted, wherein the thermostat extracts power from the common wire if the common wire is inserted. 12. The method of claim 11 , further comprising detecting the presence of a call relay wire in a corresponding call relay wire connector, and causing a connection of that connector to the power extraction circuit if (a) the common wire is not inserted, and (b) that call relay wire is inserted. 13. The method of claim 11 , further comprising detecting the presence of a first call relay wire in the first call relay connector, and causing a connection of the first call relay wire to the power extraction circuit if (a) the common wire is not inserted, and (b) the first call relay wire is inserted. 14. The method of claim 11 , further comprising detecting the presence of a second call relay wire in the second call relay connector, and causing a connection of the second call relay wire to the power extraction circuit if (a) the common wire is not inserted, and (b) the first call relay wire is not inserted. 15. A thermostat configured for automated compatibility with HVAC systems that are either single-HVAC-transformer systems or dual-HVAC-transformer systems, the compatibility being automated in that the thermostat is adapted to either single-HVAC-transformer systems or dual-HVAC-transformer systems without requiring a manual jumper installation and without requiring a processing function from a digital processo