System and method for optimal load and source scheduling in context aware homes

The invention claimed is: 1. A controller for controlling energy consumption in a home, the controller comprising: a constraints engine to define sets of constraints for multiple appliances in the home corresponding to various home modes, convenience of service, and persona of an occupant of the home; a modeling engine to model multiple paths of energy utilization of the multiple appliances to place the home into a desired state from a current context; an optimal scheduler to receive the multiple paths of energy utilization, to generate a schedule as a function of the multiple paths and a selected persona with corresponding sets of constraints to place the home in a desired state, and to suggest a plurality of load schedules and set points for optimal energy conservation; and an occupancy module to determine whether or not the home is currently occupied; wherein the occupancy module infers occupancy from an overall energy utilization signature and indoor air quality sensor data, wherein the optimal scheduler automatically resets at least one thermostat mode of the home and automatically adjusts at least one thermostat setting of the home, in response to the occupancy module determining that the home is not occupied; and wherein the controller correlates and maps fuzzy data to parameters that are used for scheduling and controlling operation of home loads. 2. The controller of claim 1 wherein the constraints engine comprises variables for each appliance and subsystem under each mode. 3. The controller of claim 2 wherein the modes include a normal mode, a party mode, and a vacation mode. 4. The controller of claim 1 wherein the persona is indicative of a user high level preferences and goals. 5. The controller of claim 4 wherein the user preference and goals include at least one of optimal energy conservation, dollar saving and comfort conditions. 6. The controller of claim 1 wherein the context of the home includes weather conditions, present state, expected states of sources and loads, and time of use price signal. 7. The controller of claim 1 wherein the controller is driven by anomaly detection. 8. The controller of claim 1 wherein the controller is driven by difference between desired state and current context of the home. 9. The controller of claim 1 wherein the modeling engine includes a model of heating ventilation and air conditioning (HVAC) that captures time to complete state operation, energy required for completing this state transition and cost of energy for this transition. 10. The controller of claim 1 wherein the modeling engine includes a look up table for an appliance that describes state, energy consumption, cost of energy, and time to complete an operation. 11. The controller of claim 1 , comprising a cost function engine operable to analyze, for all appliances and for all modes of each appliance, a cost of energy at a discrete time interval. 12. The controller of claim 1 , wherein the modeling engine models a plurality of different rates and combinations of rates for the multiple appliances in the home, the plurality of different rates and combinations of rates having a plurality of costs of energy. 13. The controller of claim 12 , wherein the plurality of different rates and combinations of rates comprises flow rates of a pool pump. 14. A method for controlling energy consumption in a home, the method comprising: modeling multiple paths of energy utilization of multiple appliances via a specifically programmed computer to place a home in a desired state from a current context, wherein the appliances have variables selected as a function of home modes and home occupant persona; receiving the multiple paths of energy utilization via the computer; generating a schedule via the computer for control of the appliances as a function of the multiple paths and a selected persona to place the home in a desired state, wherein the schedule suggests a plurality of load schedules and set points for optimal energy conservation; inferring occupancy from an overall energy utilization signature and indoor air quality sensor data; and correlating and mapping fuzzy data to parameters that are used for scheduling and controlling operation of home loads; wherein at least one thermostat mode of the home is automatically reset and at least one thermostat setting of the home is automatically adjusted, in response to the home being determined not occupied. 15. The method of claim 14 wherein the modes include a normal mode, a party mode, and a vacation mode, and wherein the persona is indicative of a user preferences and goals. 16. The method of claim 14 and further comprising detecting occupancy of the home, and modifying a mode based on an anomaly between the detected occupancy and an expected mode. 17. The method of claim 16 wherein occupancy is inferred from an overall energy utilization signature. 18. The method of claim 14 wherein the context of the home includes weather conditions, present state, expected states of sources and loads, and time of use price signal. 19. The computer readable storage device of claim 14 wherein the method further comprises detecting occupancy of the home, and modifying a mode based on an anomaly between the detected occupancy and an expected mode, wherein occupancy is inferred from an overall energy utilization signature. 20. A computer readable storage device having instructions to cause a computer to execute a method for controlling energy consumption in a home, the method comprising: modeling multiple paths of energy utilization of multiple appliances via a specifically programmed computer to place a home in a desired state from a current context, wherein the appliances have variables selected as a function of home modes and home occupant persona; receiving the multiple paths of energy utilization via the computer; generating a schedule via the computer for control of the appliances as a function of the multiple paths and a selected persona to place the home in a desired state, wherein the schedule suggests a plurality of load schedules and set points for optimal energy conservation; inferring occupancy from an overall energy utilization signature and indoor air quality sensor data; and correlating and mapping fuzzy data to parameters that are used for scheduling and controlling operation of home loads; wherein at least one thermostat mode of the home is automatically reset and at least one thermostat setting of the home is automatically adjusted, in response to the home being determined not occupied.