An embodiment of the invention may include a semiconductor structure, method of use and method of manufacture. The structure may include a heating element located underneath a temperature-controlled portion of the device. A method of operating the semiconductor device may include providing current to a thin film heater located beneath a temperature-controlled region of the semiconductor device. The method may include performing temperature dependent operations in the temperature-controlled region.

Systems and methods for providing network connectivity and remote monitoring, optimization, and control of pool/spa equipment are provided. “Internet-of-Things” (IoT) functionality is provided for pool and spa equipment in a flexible and cost-effective manner. Network connectivity and remote monitoring/control of pool and spa equipment is provided by various components such as a network communication and local control subsystem installed in pool/spa equipment, and other components. Also disclosed are various control processes (“pool logic”) which can be embodied as software code installed in any of the various embodiments of the present disclosure.

The present disclosure acquires information on a cold insulator. The cold insulator includes: at least one cold storage material; a packaging unit configured to package the at least one cold storage material; one or more first temperature sensors disposed on the packaging unit; and a transmission unit disposed on the packaging unit to transmit a result of measurement performed by the one or more first temperature sensors to an external device.

The present technology is directed to multi-frequency controllers for inductive heating and associated systems and methods. The systems can be configured to precisely heat a module via a coil to a target temperature using oscillating, pulsed electrical signals associated with unique frequencies and/or capacitance values. Each unique frequency can correspond to heating the module to a particular depth, relative to an outer surface of the module. A first pulsed electrical signal having a first frequency can heat the module to a first depth, and a second pulsed electrical signal having a second frequency can heat the module to a second depth different than the first depth. The system can include a thermal sensor for measuring a temperature associated with at least one of the module or a fluid associated with the module. Based on the temperature, the system can adjust signal delivery parameters of the first and/or second electrical signals.

The present disclosure is directed to an instrument kit tracking system that includes a housing that has tracking electronics that is contained in either a compartment or wall of the medical instrument kit or in a standalone unit that is affixed to a medical instrument kit to contain and protect an electronic device from external temperatures between 120-135° C.; where the medical instrument kit contains at least one medical instrument. The internal temperature of the instrument kit tracking system is maintained such that the electronic device contained therein is operable when the external temperature is between 120-135° C. A further layer, such as of a thickness of 1 mm, resides between the electronic device and the outer walls of the compartment or module. Access to the tracking electronics may also be selectively lockable.

Systems and methods are described for securely monitoring a shipping container for an environmental anomaly using elements of a wireless node network of sensor-based ID nodes disposed within the container and a command node associated with the container. The method has the command node identifying which of the ID nodes are confirmed as trusted sensors based upon a security credential specific to each of the ID nodes; monitoring only the confirmed ID nodes for sensor data broadcast those ID nodes; detecting the anomaly based upon the sensor data from at least one of the confirmed ID nodes; automatically generating an alert notification related to the detected environmental anomaly for the shipping container; and transmitting the alert notification to the external transceiver to initiate a mediation response related to the detected environmental anomaly.

Devices, systems and method for remotely monitoring temperature and humidity are disclosed. Sensor units are capable of reading temperature experienced by liquid pharmaceuticals. Each of a plurality of sensor units may be placed in a variety of locations and communicate temperature data to one or more controllers. Controllers also monitor ambient temperature and humidity. Collected data is transmitted over a network, and monitored according to user-configurable policies and workflows. Alerts and notifications may be generated according to workflows and user devices receive notifications.

Controlling temperature of a surface of the electronic device. The electronic device includes: a speaker, an adaptive control circuit configured to receive an audio input signal responsive to an audio input power to the speaker and a temperature sensor configured to sense a temperature internal to the electronic device. A temperature signal responsive to the sensed temperature is input to the adaptive control circuit. Responsive to the audio input signal and the temperature signal a power control signal is computed by the adaptive control circuit so that a temperature of the surface of the electronic device at a later time approaches a previously determined target temperature. An audio limiter is configured to limit the audio input power to the speaker responsive to the power control signal.

In one embodiment, a method includes receiving at a thermal modeling module, data from a Power Sourcing Equipment device (PSE) for cables extending from the PSE to Powered Devices (PDs), the cables configured to transmit power and data from the PSE to the PDs, calculating at the thermal modeling module, thermal characteristics for the cables based on the data, and identifying a thermal rise above a specified threshold at one of the cables. The data comprises real-time electrical data for the cables. An apparatus and logic are also disclosed herein.

Methods, systems, and apparatus, including computer programs encoded on computer storage mediums, for a smartlock device that can be integrated in a door at a property. The smartlock device includes a locking mechanism configured to lock the door and to unlock the door. The device includes a radio device and a sensor that determines a first temperature of the smartlock device and a second temperature of a room that is accessible via the door. The radio device is operable to: i) receive parameter signals from the sensor indicating each of the first and second temperatures; ii) transmit data that includes the first and second temperatures to a monitoring system; and iii) receive a command to cause the locking mechanism to unlock the door based on information from the monitoring system. The information includes a determined routing of occupants at the property and is presented on a display of the device.