An arrangement for monitoring an aseptic manufacturing process includes product condition sensors capable of making closely spaced measurements of a product condition such as temperature or humidity. The measurements are made using closely spaced sensors arranged in a linear array on a single probe, which may be used to take measurements at multiple levels within the product. Data from the sensors is transmitted to a data collection point via short range wireless digital communications. The sensors may be used to measure temperature and humidity at a single point. For example, when the sensors are used in pharmaceutical freeze drying, the location of a sublimation front may be calculated for each vial, and the freeze drying process may be controlled using the data.

A damper control device may include an appliance control programmed processor for controlling a gas burner, the appliance control programmed processor including a lockout register for storing electronic data information, and a damper control programmed processor for controlling a damper, the damper control programmed processor including a damper request register for storing electronic data information. The damper control programmed processor may be configured for selectively opening or closing the damper responsive to status of the damper request register and controlling status of the lockout register to indicate status of the damper, and the appliance control programmed processor may be configured for controlling status of the damper request register responsive to a call for operation of the gas burner and operating the gas burner only if the lockout register is in an unlock status.

Remote health services may be provided, for example, in real time, based on values of health metrics monitored remotely, and in some embodiments, continuously, for a recipient. The system may include a mobile health device configured to continually monitor or intermittently detect values of one or more health metrics. A mobile health device may be locally coupled to a recipient, and may include a health sensor that detects values of one or more health metrics of the recipient. Servers may be remotely coupled to the mobile health device and provide one or more health services based at least in part on health metric values detected by the health device. Providing the services may include determining health communication characteristics, and sending health communications from one or more servers to the mobile health device according to determined health communication characteristics.

A thermostat is disclosed. The thermostat can include one or more temperature sensors configured to measure a plurality of temperature values within a building. The thermostat can include a processing circuit coupled to the one or more temperature sensors. The processing circuit can receive the plurality of measured temperature values from the one or more temperature sensors. The processing circuit can determine, based on a time invariant Non-Linear Least Squares (NLSQ) technique and the plurality of measured temperature values, a compensated temperature value within the building, wherein the compensated temperature value accounts for an unknown temperature state of the thermostat when the thermostat is turned on.

A rack temperature controlling method includes performing the following operations through a controller: obtaining a rack temperature data, calculating a temperature variant according to the rack temperature data, calculating a temperature deviation according to the temperature variant and a reference temperature, calculating a target speed according to the temperature deviation, and adjusting a speed of a fan to the target speed. A rack temperature controlling system including a thermometer and a controller is further provided. The thermometer measures and outputs a rack temperature data. The controller receives the rack temperature data, and calculates a temperature variant according to the rack temperature data. The controller further calculates a temperature deviation according to the temperature variant and a reference temperature, calculates a target speed according to the temperature deviation, and adjusts a speed of a fan to the target speed.

Systems and methods for orchestrating the operation of energy-consuming loads, so as to minimize power consumption, are described. In some embodiments, the loads can be HVAC, refrigeration systems, air compressors, and the like, and orchestration is effected either directly or by means of the loads' respective controllers. In some aspects, the controllers can be Smart Thermostats and orchestration is effected through a Cloud-based orchestration platform or “COP.” In certain aspects, a COP uses specifically programmed application programming interfaces, or APIs, to control the operation of a single manufacturer's Smart Thermostats, where the manufacturer provides its own Cloud-based control platform, through which the COP operates. The COP can similarly orchestrate the operation of two or more manufacturers' Smart Thermostats through their respective Cloud-based control platforms. By these and other means, the operation of a variety of energy-consuming loads can be more easily and efficiently orchestrated.

A device that can float in a liquid can be used to adjust the temperature of the liquid by monitoring the temperature of the liquid and comparing to a desired temperature and pumping liquid into contact with a thermal adjustment element in the device. The device comprises a thermal adjustment element, a temperature detector to measure the temperature of the liquid exterior to the device, a controller to turn the device on when temperature measured is outside a desired range, a pump to take a portion of the liquid from outside the device to thermal contact with the thermal adjustment element and return the portion of the liquid to outside the device, and a photovoltaic module mounted in a position to be exposed to light which photovoltaic module provides energy to operate the device.

A thermostat is disclosed. The thermostat can include one or more temperature sensors configured to measure one or more temperature values. The thermostat can include a processing circuit. The processing circuit can receive the one or more temperature values from the one or more temperature sensors. The processing circuit can receive one or more central processing unit (CPU) usage values, wherein the one or more CPU usage values indicate computing usage of the processing circuit. The processing circuit can determine, based on an empirical model comprising one or more gain values and one or more filters and based on one or more signals, a temperature of the building. The one or more signals comprise the one or more temperature values and the one or more CPU usage values. The empirical model accounts for dynamics of heat generated by the processing circuit and airflow acting on the thermostat.

The present invention relates to systems and methods for improved building systems management and maintenance. The present invention provides a system for providing an augmented reality-like interface for the management and maintenance of building systems, specifically the mechanical, electrical, and plumbing (MEP) systems within a building, including the heating, ventilation, and air-conditioning (HVAC) systems.

A method for controlling temperature of a chemical reaction without measuring a temperature of the chemical reaction. Changes in mass of a chemical reaction are monitored and are used to calculate the temperature of the system. The reaction can be maintained at a desired temperature (T) without measuring the temperature. The disclosed method is useful for reactions that occur at non-equilibrium conditions where any measured temperature would presume steady-state conditions.