Modeling the behavior of an enclosure for use by a control system of an HVAC system is described. A model for the enclosure that describes the enclosure's behavior for use by the control system is updated based on weather forecast data. The weather forecast data can include predictions more than 24
Modeling the behavior of an enclosure for use by a control system of an HVAC system is described. A model for the enclosure that describes the enclosure's behavior for use by the control system is updated based on weather forecast data. The weather forecast data can include predictions more than 24 hours in the future, and can include predictions on temperature, humidity and/or dew point, solar output, precipitation. The model for the enclosure can also be updated based on additional information and data. The model for the enclosure can be updated based also on an enclosure model stored in a database, and/or enclosure information from a user. The model can be updated based on active testing of the enclosure which can be performed automatically or in response to user input. The testing can include heating and/or cooling the enclosure at times when the enclosure is not likely occupied.
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1. A method for modeling an internal environmental behavior of an enclosure for use by a control system of an HVAC system installed in the enclosure, the method comprising: determining, by the control system, historical weather data corresponding to a location of the enclosure;collecting, by the con
1. A method for modeling an internal environmental behavior of an enclosure for use by a control system of an HVAC system installed in the enclosure, the method comprising: determining, by the control system, historical weather data corresponding to a location of the enclosure;collecting, by the control system, occupancy data of the enclosure;determining, by the control system, an amount of heat and/or humidity within the enclosure caused by activities carried out by one or more occupants based on a difference in temperature and/or humidity between when the enclosure is determined to be occupied based on the occupancy data and unoccupied based on the occupancy data for a temperature and/or humidity setting;creating, by the control system, a thermodynamic model for the enclosure using:the determined historical weather data corresponding to the location of the enclosure, the occupancy data, and the amount of heat and/or humidity within the enclosure caused by the activities carried out by the one or more occupants, wherein the thermodynamic model describes the thermodynamic behavior of the enclosure for use by the control system;receiving, by the control system, weather forecast data corresponding to the location of the enclosure;predicting, by the control system, using the created thermodynamic model, the occupancy data, and a thermodynamic behavior prediction engine, how the enclosure will thermally react to activity of the HVAC system when the enclosure is exposed to forecast weather indicated by the weather forecast data; andcontrolling, by the control system, based on the created thermodynamic model for the enclosure, the HVAC system to adjust a temperature of the internal environment of the enclosure. 2. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 1, wherein determining the historical weather data comprises obtaining the historical weather data from one or more private weather stations. 3. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 1, further comprising: collecting, by the control system, occupancy data of the enclosure, wherein updating the thermodynamic model for the enclosure comprises updating the thermodynamic model based on the occupancy data for the enclosure. 4. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 1, further comprising: accessing, by the control system, from an enclosure models database, an enclosure model from a plurality of enclosure models, wherein the plurality of enclosure models correspond to a plurality of types of enclosures; andretrieving, by the control system, from the enclosure models database, the enclosure model, wherein the enclosure model is used in creating the thermodynamic model of the enclosure. 5. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 1, further comprising: updating the thermodynamic model if an error metric exceeds an error threshold, by: inducing, by the control system, a change in an internal environment of the enclosure using the HVAC system;measuring, by the control system, a response of the internal environment of the enclosure at least in part due to the induced change; andupdating, by the control system, the thermodynamic model based on the measurement of the response of the internal environment of the enclosure from the induced change. 6. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 5, further comprising: generating, by the control system, the error metric based upon a comparison of an indoor temperature of the enclosure predicted using the updated model and at least one sensor reading within the enclosure indicative of a measured indoor temperature. 7. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 1, wherein the weather forecast data comprises weather predictions at least twenty four hours in the future. 8. The method for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 1, further comprising: receiving, by the control system, localized weather data from one or more sensors on or around the enclosure, wherein creating the thermodynamic model for the enclosure using the received historical weather data further comprises using the received localized weather data to create the thermodynamic model. 9. A system for modeling the internal environmental behavior of an enclosure for use by a control system of an HVAC system installed in the enclosure, the system comprising: at least one processor; anda non-transitory storage medium having instructions stored thereon, the instructions executable by the at least one processor to: determine historical weather data corresponding to a location of the enclosure;receive occupancy data of the enclosure;determine an amount of heat and/or humidity within the enclosure directly caused by one or more occupants based on a difference in temperature and/or humidity between when the enclosure is determined to be occupied based on the occupancy data and unoccupied based on the occupancy data for a temperature and/or humidity setting;create a thermodynamic model for the enclosure using the received historical weather data corresponding to the location of the enclosure, the occupancy data, and the amount of heat and/or humidity within the enclosure directly caused by the one or more occupants, wherein the thermodynamic model describes behavior of the enclosure for use by the control system;receive weather forecast data corresponding to the location of the enclosure;predict, using the created model, the occupancy data, and a thermodynamic behavior prediction engine, how the enclosure will thermally react to activity of the HVAC system when the enclosure is exposed to forecast weather indicated by the weather forecast data; andcontrol based on the created thermodynamic model for the enclosure, the HVAC system to adjust a temperature of an internal environment of the enclosure. 10. The system for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 9, wherein the historical weather data indicates historical precipitation data. 11. The system for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 9, wherein the instructions further being executable by the at least one processor to: collect occupancy data of the enclosure based on sensing occupancy with the enclosure, wherein creating the thermodynamic model for the enclosure comprises creating the thermodynamic model based on the occupancy data for the enclosure. 12. The system for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 9, wherein the instructions further being executable by the at least one processor to: predict occupancy data of the enclosure, wherein creating the thermodynamic model for the enclosure comprises creating the thermodynamic model based on the occupancy data for the enclosure. 13. The system for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 9, wherein the instructions further being executable by the at least one processor to: receive, from an online real estate database, enclosure data indicative of numbers and types of rooms within the enclosure, wherein creating the thermodynamic model for the enclosure comprises creating the thermodynamic model based on the enclosure data. 14. The system for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 9, wherein the instructions further being executable by the at least one processor to: receive, calendar data that is indicative of at least weekdays and weekends, wherein creating the thermodynamic model for the enclosure comprises creating the thermodynamic model based on the calendar data. 15. A non-transitory processor-readable medium for modeling an internal environmental behavior of an enclosure for use by a control system of an HVAC system installed in the enclosure comprising processor-readable instructions configured to cause one or more processors to: determine historical weather data corresponding to a location of the enclosure;receive occupancy data of the enclosure;determine an amount of heat and/or humidity within the enclosure caused by activities carried out by one or more occupants based on a difference in temperature and/or humidity between when the enclosure is determined to be occupied based on the occupancy data and unoccupied based on the occupancy data for a temperature and/or humidity setting;create a thermodynamic model for the enclosure using the received historical weather data corresponding to the location of the enclosure, the occupancy data, and the amount of heat and/or humidity within the enclosure caused by the activities carried out by the one or more occupants, wherein the thermodynamic model describes behavior of the enclosure for use by the control system;receive weather forecast data corresponding to the location of the enclosure;predict using the created thermodynamic model, the occupancy data, and a thermodynamic behavior prediction engine, how the enclosure will react to activity of the HVAC system when the enclosure is exposed to forecast weather indicated by the weather forecast data; andcontrol based on the created thermodynamic model for the enclosure, the HVAC system to adjust a temperature of the internal environment of the enclosure. 16. The non-transitory processor-readable medium for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 15, wherein the processor-readable instructions are further configured to cause the one or more processors to: receive HVAC output data indicative of a power level of the HVAC system, wherein creating the thermodynamic model for the enclosure is further based on the HVAC output data. 17. The non-transitory processor-readable medium for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 15, wherein the processor-readable instructions are further configured to cause the one or more processors to: detect an open window performance fault based upon a measured rapid change in a rate of heat exchange between the enclosure and an outside environment. 18. The non-transitory processor-readable medium for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 15, wherein the processor-readable instructions are further configured to cause the one or more processors to: update the thermodynamic model if an error metric exceeds an error threshold, by causing the one or more processors to: induce a change in an internal environment of the enclosure using the HVAC system;measure a response of the internal environment of the enclosure at least in part due to the induced change; andupdate the thermodynamic model based on the measurement of the response of the internal environment of the enclosure from the induced change. 19. The non-transitory processor-readable medium for modeling the internal environmental behavior of the enclosure for use by the control system of the HVAC system installed in the enclosure of claim 18, wherein the processor-readable instructions are further configured to cause the one or more processors to: generate the error metric based upon a comparison of an indoor temperature of the enclosure predicted using the updated model and at least one sensor reading within the enclosure indicative of a measured indoor temperature.
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