Electronic thermostats are expanding to a higher integration of services that includes, for example, the integration of a home Internet-of-Things (IoT) gateway, local rule control, local machine learning capability, and higher resolution thin-film transistor (TFT) display. However, the required incorporation of higher processing power control units and/or large display typically results in a higher heat dissipation of electronic components, thus increasing the temperature around the components of an electronic thermostat. The system heat dissipation consequently degrades the accuracy of the on-board temperature sensors. An aspect of the embodiments provides a compensation for the temperature rise effect on the printed circuit board (PCB) of the electronic thermostat to obtain better precision and performance. Once the measurements from the temperature sensors have stabilized, the compensated ambient temperature may be used by an associated system (for example, a HVAC system).

One aspect of the invention provides a system including: at least one temperature-regulation element configured for fluidic communication with a fluid repository; and a processor in electronic communication with the at least one temperature-regulation element. The processor is configured to: determine a temperature threshold value for a volume of fluid contained by the fluid repository; calculate an amount of solar radiation to which the volume of fluid is exposed; calculate, from the amount of solar radiation and a set of temperature-regulation factors, a time period for reaching the temperature threshold value for the volume of fluid, wherein the set of temperature-regulation factors comprises at least a current temperature of the fluid volume and an energy-transfer rate for the temperature-regulation element; identify a desired use time for the volume of fluid; and activate the at least one temperature-regulation element according to the time period and the desired use time.

One aspect of the invention provides a system including: at least one temperature-regulation element configured for fluidic communication with a fluid repository; and a processor in electronic communication with the at least one temperature-regulation element. The processor is configured to: determine a temperature threshold value for a volume of fluid contained by the fluid repository; calculate an amount of solar radiation to which the volume of fluid is exposed; calculate, from the amount of solar radiation and a set of temperature-regulation factors, a time period for reaching the temperature threshold value for the volume of fluid, wherein the set of temperature-regulation factors comprises at least a current temperature of the fluid volume and an energy-transfer rate for the temperature-regulation element; identify a desired use time for the volume of fluid; and activate the at least one temperature-regulation element according to the time period and the desired use time.

A method can include obtaining a set of images of a set of occupants located in an interior environment. The interior environment can have a first temperature. The method can include identifying, based on the set of images, a set of occupant characteristics corresponding to the set of occupants. The method can include obtaining a second temperature of an external environment. The method can include generating, by comparing the set of occupant characteristics to the second temperature, a discrepancy factor. The method can include determining that the discrepancy factor exceeds a threshold. The method can include initiating, in response to the determining that the discrepancy factor exceeds the threshold, a modification of the first temperature.

A method can include obtaining a set of images of a set of occupants located in an interior environment. The interior environment can have a first temperature. The method can include identifying, based on the set of images, a set of occupant characteristics corresponding to the set of occupants. The method can include obtaining a second temperature of an external environment. The method can include generating, by comparing the set of occupant characteristics to the second temperature, a discrepancy factor. The method can include determining that the discrepancy factor exceeds a threshold. The method can include initiating, in response to the determining that the discrepancy factor exceeds the threshold, a modification of the first temperature.

An aspect of the embodiments provides a compensation for the temperature rise effect on the printed circuit board (PCB) of an electronic thermostat to obtain better precision and performance. Once the measurements from the temperature sensors have stabilized, the compensated ambient temperature may be used by an associated system (for example, a Heating, Ventilation, and Air Conditioning (HVAC) system).

An aspect of the embodiments provides a compensation for the temperature rise effect on the printed circuit board (PCB) of an electronic thermostat to obtain better precision and performance. Once the measurements from the temperature sensors have stabilized, the compensated ambient temperature may be used by an associated system (for example, a Heating, Ventilation, and Air Conditioning (HVAC) system).

One aspect of the invention provides a system including: at least one temperature-regulation element configured for fluidic communication with a fluid repository; and a processor in electronic communication with the at least one temperature-regulation element. The processor is configured to: determine a temperature threshold value for a volume of fluid contained by the fluid repository; calculate an amount of solar radiation to which the volume of fluid is exposed; calculate, from the amount of solar radiation and a set of temperature-regulation factors, a time period for reaching the temperature threshold value for the volume of fluid, wherein the set of temperature-regulation factors comprises at least a current temperature of the fluid volume and an energy-transfer rate for the temperature-regulation element; identify a desired use time for the volume of fluid; and activate the at least one temperature-regulation element according to the time period and the desired use time.

One aspect of the invention provides a system including: at least one temperature-regulation element configured for fluidic communication with a fluid repository; and a processor in electronic communication with the at least one temperature-regulation element. The processor is configured to: determine a temperature threshold value for a volume of fluid contained by the fluid repository; calculate an amount of solar radiation to which the volume of fluid is exposed; calculate, from the amount of solar radiation and a set of temperature-regulation factors, a time period for reaching the temperature threshold value for the volume of fluid, wherein the set of temperature-regulation factors comprises at least a current temperature of the fluid volume and an energy-transfer rate for the temperature-regulation element; identify a desired use time for the volume of fluid; and activate the at least one temperature-regulation element according to the time period and the desired use time.

One aspect of the invention provides a system including: at least one temperature-regulation element in fluidic communication with a fluid repository; and a processor in electronic communication with the at least one temperature-regulation element. The processor can: determine a temperature threshold value for a volume of fluid contained by the fluid repository; calculate an amount of solar radiation to which the volume of fluid is exposed; calculate, from the amount of solar radiation and a set of temperature-regulation factors, a time period for reaching the temperature threshold value for the volume of fluid; identify a desired use time for the volume of fluid; and activate the at least one temperature-regulation element according to the time period and the desired use time. The set of temperature-regulation factors includes at least a current temperature of the fluid volume and an energy-transfer rate for the temperature-regulation element.