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.

Systems and methods of the present invention allow to determine ambient gas temperature in harsh environments such as in a steam autoclave chamber during a sterilization process. In certain embodiments of the invention, temperature data is gathered using a sensor that is placed in an enclosed electronics-based temperature logging device. A capsule seals the temperature logging device except for a through hole that, during regular operation, allows gas to directly contact a surface of the temperature logging device in order to reduce a time lag between the data logging device and an ambient gas. As a result, the data logging device accurately can track temperature variations when placed, for example, inside a chamber.

Systems and methods of the present invention allow to determine ambient gas temperature in harsh environments such as in a steam autoclave chamber during a sterilization process. In certain embodiments of the invention, temperature data is gathered using a sensor that is placed in an enclosed electronics-based temperature logging device. A capsule seals the temperature logging device except for a through hole that, during regular operation, allows gas to directly contact a surface of the temperature logging device in order to reduce a time lag between the data logging device and an ambient gas. As a result, the data logging device accurately can track temperature variations when placed, for example, inside a chamber.

This temperature monitoring device (100) can be placed in a furnace together with a composite material. The temperature monitoring device (100) includes: a pair of internal components (10) that each have a temperature detection surface (11) and are layered such that the temperature detection surfaces (11, 11) face each other; a temperature detection unit (30) disposed so as to be sandwiched between the temperature detection surfaces (11, 11); at least a pair of external components (20) that are respectively disposed on reverse sides from the temperature detection surfaces (11); and an adjustment part (50) capable of adjusting the sizes of the thickness-direction gaps between the internal components (10) and external components (20).

Embodiments described herein are directed to a temperature measurement device that includes a sensor body configured to be placed on a skin of a user. The temperature measurement device can include a first section defining a first lower surface and having a first thickness, a second section defining a second lower surface and having a second thickness, and a channel separating the first lower surface from the second lower surface. The temperature measurement device can also include a first set of temperature sensors positioned across the first thickness, a second set of temperature sensors positioned across the second thickness, and a processor configured to estimate a tissue temperature of the user based on comparing temperature signals from the first set of temperature sensors with temperature signals from the second set of temperature sensors.

An electrical device with thermally controlled performance is disclosed. The electrical device includes at least one die with a plurality of device components disposed upon or at least partially embedded within the die. The electrical device further includes a plurality of signal paths interconnecting the plurality of device components. The electrical device further includes a plurality of temperature sensors disposed upon or at least partially embedded within the die. The temperature sensors are configured to detect thermal loads at respective portions of the die. The electrical device further includes at least one controller disposed upon or at least partially embedded within the die. The controller is configured to adjust one or more operating parameters for one or more of the device components based on the thermal loads detected by the temperature sensors.

A device for determining temperature information from a sensor device, which is configured to transmit sensor information by time-limited electrical pulses according to a defined protocol, including: a data processing unit configured to perform the following: retrieving reference data relating to a relationship between a pulse duration of the electrical pulses and thermal effects in the sensor device; measuring the pulse duration at at least one of the electrical pulses; and determining the temperature information on the basis of at least one result of the measurement and the reference data. Also described are a related sensor system, a related vehicle, related methods, and a computer readable medium.

A device for determining temperature information from a sensor device, which is configured to transmit sensor information by time-limited electrical pulses according to a defined protocol, including: a data processing unit configured to perform the following: retrieving reference data relating to a relationship between a pulse duration of the electrical pulses and thermal effects in the sensor device; measuring the pulse duration at at least one of the electrical pulses; and determining the temperature information on the basis of at least one result of the measurement and the reference data. Also described are a related sensor system, a related vehicle, related methods, and a computer readable medium.

Example embodiments of the described technology provide an apparatus for testing an electrochemical system. The apparatus may comprise a testing module electrically coupled to the electrochemical system. The testing module may comprise a discharge circuit configured to draw current from the electrochemical system at a plurality of different rates. The discharge circuit may be configured to continuously draw current from the electrochemical system once a test of the electrochemical system is commenced. The apparatus may also comprise a measurement module which may be configured to measure voltage across terminals of the electrochemical system and current drawn from the electrochemical system during the test. The apparatus may also comprise a processor. The processor may be configured to compensate at least in part the measured voltage for voltage drift which was generated by continuously drawing current from the electrochemical system. The processor may also be configured to compute a state of health of the electrochemical system based at least in part on the compensated voltage and the measured current.

A process fluid temperature calculation system includes a first temperature sensor disposed to measure an external temperature of a process fluid conduit. The process fluid temperature calculation system has a stem portion having a known thermal impedance. A second temperature sensor is spaced from the first temperature sensor by the stem portion. Measurement circuitry is coupled to the first and second temperature sensors. A microprocessor is coupled to the measurement circuitry to receive temperature information from the measurement circuitry and to provide an estimate of temperature of process fluid within the process fluid conduit using a heat flux calculation.