Controlling an HVAC system using an optimal setpoint schedule during a demand-response event

What is claimed is: 1. A method of carrying out a demand response (DR) event by an intelligent, network-connected thermostat associated with a structure, the method comprising: identifying, by the thermostat, a DR event that defines a DR event period; accessing, by the thermostat, a plurality of parameter sets; generating, by the thermostat, candidate setpoint schedules during the DR event for the plurality of parameter sets; simulating, by the thermostat, each of the candidate setpoint schedules using a thermodynamic model of how the structure responds to a heating, ventilation, and air conditioning (HVAC) system; generating, by the thermostat, predicted indoor temperature profiles or HVAC duty cycle schedules for each of the simulated candidate setpoint schedules; evaluating, by the thermostat, a cost function for each of the predicted indoor temperature profiles or HVAC duty cycle schedules; selecting, by the thermostat, an optimal predicted indoor temperature profile or HVAC duty cycle schedule that minimizes the cost function; selecting, by the thermostat, an optimal setpoint schedule as being the candidate setpoint schedule associated with the optimal predicted indoor temperature profile or HVAC duty cycle schedule; and controlling, by the thermostat, the HVAC system during the DR event period in accordance with the optimal setpoint schedule. 2. The method of claim 1 , further comprising: receiving a request to display a candidate setpoint schedule corresponding to the optimal predicted indoor temperature profile; and causing one or more effective setpoints to be displayed in the place of one or more setpoints in the candidate setpoint schedule. 3. The method of claim 2 , wherein the one or more effective setpoints correspond to peaks and troughs in the optimal predicted indoor temperature profile. 4. The method of claim 2 , wherein the one or more effective setpoints is displayed as a static schedule instead of a continuously changing schedule that would be displayed for the candidate setpoint schedule. 5. The method of claim 2 , wherein the one or more effective setpoints are fewer than the one or more setpoints in the candidate setpoint schedule that are replaced by the one or more effective setpoints. 6. The method of claim 1 , wherein the cost function comprises a combination of: a first factor representative of a total energy consumption of the HVAC system during the DR event period; a second factor representative of a metric of occupant discomfort in the structure; and a third factor representative of deviations of a rate of energy consumption of the HVAC system from an equalized rate of energy consumption of the HVAC system over the DR event period such that the rate of energy consumption by the HVAC system over the DR event period can be made substantially constant. 7. The method of claim 1 , wherein each parameter set comprises: a first parameter indicative of a temperature-wise offset from a temperature setpoint of an original setpoint schedule; and a second parameter indicative of a slope of a linear sequence of temperature setpoints passing through a point at the temperature-wise offset from the temperature setpoint of the original setpoint schedule, wherein the temperature-wise offset and the slope of the linear sequence of temperature setpoints are designed to assist in reducing the deviations of the rate of energy consumption over the DR event period. 8. The method of claim 7 , wherein each parameter set further comprises: a third parameter indicative of a maximum HVAC duty cycle period; and a fourth parameter indicative of a duration of the pre-DR event period. 9. An intelligent network-connected thermostat for controlling an operation of an HVAC system in a structure, the thermostat comprising: HVAC control circuitry operable to actuate one or more elements of the HVAC system; one or more sensors for measuring characteristics of a smart home environment; and a processor coupled to the HVAC control circuitry and the one or more sensors and operable to cause the thermostat to perform operations comprising: identifying a DR event that defines a DR event period; accessing a plurality of parameter sets; generating candidate setpoint schedules during the DR event for the plurality of parameter sets; simulating each of the candidate setpoint schedules using a thermodynamic model of how the structure responds to the HVAC system; generating predicted indoor temperature profiles or HVAC duty cycle schedules for each of the simulated candidate setpoint schedules; evaluating a cost function for each of the predicted indoor temperature profiles or HVAC duty cycle schedules; selecting an optimal predicted indoor temperature profile or HVAC duty cycle schedule that minimizes the cost function; selecting, by the thermostat, an optimal setpoint schedule as being the candidate setpoint schedule associated with the optimal predicted indoor temperature profile or HVAC duty cycle schedule; and controlling, by the thermostat, the HVAC system during the DR event period in accordance with the optimal setpoint schedule. 10. The thermostat of claim 9 , wherein the operations further comprise: determining whether the HVAC system should be controlled in accordance with a different predicted indoor temperature profile or HVAC duty cycle schedule; and upon determining that the HVAC system should be controlled in accordance with a different predicted indoor temperature profile or HVAC duty cycle schedule: identifying a new predicted indoor temperature profile or HVAC duty cycle schedule; and controlling the HVAC system in accordance with the new predicted indoor temperature profile or HVAC duty cycle schedule. 11. The thermostat of claim 10 , wherein determining whether the HVAC system should be controlled in accordance with a different predicted indoor temperature profile or HVAC duty cycle schedule is performed periodically during the DR event period. 12. The thermostat of claim 10 , wherein determining whether the HVAC system should be controlled in accordance with a different predicted indoor temperature profile or HVAC duty cycle schedule includes one or more of: monitoring an indoor temperature of the structure and comparing the monitored indoor temperature of the structure to a predicted indoor temperature of the structure; monitoring a state of the HVAC system and comparing the monitored state of the HVAC system to a predicted state of the HVAC system; monitoring a real-time occupancy of the structure; and determining whether the optimal predicted indoor temperature profile or HVAC duty cycle schedule fails. 13. The thermostat of claim 10 , wherein identifying the new predicted indoor temperature profile or HVAC duty cycle schedule includes one of: determining a newly optimized predicted indoor temperature profile or HVAC duty cycle schedule that minimizes the cost function; determining an original control trajectory; and determining a default control trajectory. 14. The thermostat of claim 9 , wherein the operations further comprise: monitoring an indoor temperature of the structure; comparing the monitored indoor temperature of the structure to a predicted indoor temperature of the structure; and upon determining that the monitored indoor temperature is different from the predicted indoor temperature of the structure by at least a certain amount: determining a default control trajectory; and controlling the HVAC system in accordance with the default control trajectory. 15. The thermostat of claim 9 , wherein the operations further comprise: m