A system and method for rapidly determining ambient temperature in a fluid-analyte meter. The meter includes a housing defining an interior space and an area for receiving a fluid sample. A processor and a first temperature sensor are disposed within the interior space of said the housing. A second temperature sensor is disposed on the housing. One or more processors are configured to determine a first temperature value from temperature data received from the first temperature sensor. The processor(s) are also configured to apply a variable current to a temperature-adjustment source such that the second temperature sensor is adjusted to a predetermined steady-state temperature value different from the first temperature value. The processor(s) are further configured to determine an ambient temperature of an exterior space of the housing based on the applied variable current, pre-determined steady-state temperature, and received first temperature values.

Various non-invasive sensors are adapted to be placed on a surface of an object having a volume with an internal region. The internal region of the object has internal properties indicated by corresponding internal parameters and an internal temperature distribution that is a function of the internal parameters and surface thermal signals. Each non-invasive sensor includes a heat flux sensor having one or more heat flux sensor output terminals to provide a measured heat transfer signal for the surface of the object, and a temperature sensor having one or more temperature sensor output terminals to provide a measured temperature signal for the surface of the object. Systems including one or more of the sensors perform non-invasive sensing of the object including accurate and rapid determination of an internal temperature distribution of the internal region of the object as well as one or more other internal properties of the object.

A method for measuring temperature is used to obtain a room temperature of a room. The method for measuring temperature includes: obtaining a first temperature inside an operating area in a portable electronic device in the room; obtaining a second temperature outside the operating area in the portable electronic device by a first temperature sensor; calculating a temperature difference between the first temperature and the second temperature; obtaining a compensation temperature according to the temperature difference and a compensation temperature table; and calculating the room temperature according to the second temperature and the compensation temperature.

A method and related system for monitoring a time-temperature profile comprises measuring by a temperature sensor a temperature of an object, recording by an electronic device a time-temperature data point including the temperature and a time at which the temperature was measured, communicating the recorded time-temperature data point by the electronic device to a computing system, and determining by the computing system whether the recorded time-temperature data point is outside a predetermined acceptable range.

A brake temperature detection device is configured detect brake temperature more accurately. In a situation in which the temperature in the vicinity of the brake has risen above the atmospheric temperature, indicated by a value read off of the detection signal of the temperature sensor, for example when traveling in congested traffic, a value to correct atmospheric temperature is determined, and atmospheric temperature is corrected on the basis of that atmospheric temperature correction value. Subsequently, brake temperature is calculated on the basis of the corrected air temperature. As a result of this configuration, it is possible to have the calculated brake temperature approach the actual brake temperature. This makes it possible to detect brake temperature more accurately.

A hand-held test meter includes an electrically and thermally insulating case (“ETIC”) with an outwardly facing surface, a test meter electrical component (“TMEC”) with a thermal contact portion disposed within the electrically-insulating case, and at least one thermal channel. The thermal channel includes a proximal contact portion with a proximal contact surface, a distal contact portion with a distal surface, and a channel portion connecting the proximal contact portion and the distal contact portion. The thermal channel is integrated with the ETIC such that the thermal channel extends through the ETIC from the outwardly facing surface and to the thermal contact portion of the TMEC. The extension is such that the proximal contact surface of the thermal channel is outside of the ETIC and the distal surface of the thermal channel is in contact with the thermal contact portion of the TMEC. The thermal channel is thermally conductive and electrically-insulating.

Techniques regarding determining and/or analyzing temperature distributions experienced by quantum computer devices during operation are provided. For example, one or more embodiments described herein can comprise a system, which can comprise a memory that can store computer executable components. The system can also comprise a processor, operably coupled to the memory, and that can execute the computer executable components stored in the memory. The computer executable components can comprise a region component that can define a plurality of temperature regions from a quantum computing device layout. The computer executable component can also comprise a map component that can generate a map that characterizes a temperature distribution by determining at least one temperature achieved within the plurality of temperature regions during an operation of the quantum computing device layout.

In accordance with at least one embodiment, a computer-implemented method for evaluating cooling performance of an electronics system is provided. The method includes acts of dividing the electronics system into a computational grid including a plurality of fluid cells and a plurality of solid cells, determining air flow values for the plurality of fluid cells using a potential flow model analysis, determining a temperature of a fluid cell by calculating heat transfer into the fluid cell from any adjacent fluid cells and from any adjacent solid cells, determining a temperature of a solid cell by calculating heat transfer into the solid cell from any adjacent solid cells and heat transfer out of the solid cell into any adjacent fluid cells, and storing, on a storage device, the air flow values and the temperature of the fluid cell and the temperature of the solid cell.

A method for determining the ambient temperature of a mobile device including: determining an operating condition of the mobile device for determining a thermal condition of the mobile device in a first task, estimating a dynamic parameter, which characterizes the thermal behavior of the mobile device in a second task, and calculating an ambient temperature of the mobile device with the aid of the dynamic parameter in a third task.

A method for determining the ambient temperature of a mobile device including: determining an operating condition of the mobile device for determining a thermal condition of the mobile device in a first task, estimating a dynamic parameter, which characterizes the thermal behavior of the mobile device in a second task, and calculating an ambient temperature of the mobile device with the aid of the dynamic parameter in a third task.