If an abnormality detecting unit detects an output abnormality of an internal temperature sensor, a discharge control unit obtains the amount of discharge (a limit value L of gas flow rate F) on the basis of an ambient temperature measured by an ambient temperature sensor, and controls the discharge of fuel gas on the basis of the obtained amount of discharge.

The present application relates to method and system of monitoring liquefied gas in a cryogenic liquefied gas tank having an inner shell and an outer shell and an insulation between the inner and outer shell. An exemplary method includes arranging an array of temperature sensors for measuring a temperature of the inner shell wall at different vertical positions, reading sensors in the array, performing a validity check of the sensors, and using only sensors which passed the validity check only, determining a state of the gas based on the temperature data.

A mask structure and a manufacturing method of the mask structure are provided. The mask structure includes a transparent substrate, a patterned metal layer, and a plurality of microlens structures. The patterned metal layer is disposed on the transparent substrate and exposing a portion of the transparent substrate. The microlens structures are disposed on the transparent substrate exposed by a portion of the patterned metal layer and being in contact with the portion of the patterned metal layer.

A radar device (100) is described that includes at least one transceiver (105) configured to support frequency modulated continuous wave (FMCW); radar device (100) and a digital controller (262). A temperature sensor system includes a plurality of temperature sensors (222, 232, 242) coupled to one or more circuits (220, 230, 240) in the at least one transceiver (105). The digital controller (262, 306) comprises or is operably coupled to an over-temperature emulation circuit (308) configured to emulate an over-temperature shutdown state by injecting an over-temperature force signal (290) into the temperature sensor system (270).

There is provided a detection method for detecting a failure of a thermistor, the detection method comprising: applying a load to the thermistor over time; measuring a physical property value of the thermistor at least at a first time and a second time during a time period in which the load is being applied to the thermistor; and detecting the failure of the thermistor based on first data indicating the physical property value of the thermistor measured at the first time and second data indicating the physical property value of the thermistor measured at the second time.

A temperature measuring apparatus for measuring a temperature of a battery pack is provided. A first resistor is connected between a first power supply and a first node, and a second resistor is connected between a second node and a second power supply. A temperature-variable resistive element whose resistance is varied depending on a temperature is connected to between the first node and the second node. A processor measures the temperature of the battery pack based on at least one of a first temperature measured based on a voltage of the first node and a second temperature measured based on a voltage of the second node.

A method for identifying the probe abnormality includes: obtaining current temperature data of a plurality of probes, and calculating a temperature difference value between every two pieces of current temperature data; comparing the temperature difference value with a preset temperature difference, and when the temperature difference value exceeds the preset temperature difference, determining that at least one of the plurality of probes is abnormal; and heating the device to a preset temperature, and determining an abnormal probe from the plurality of probes.

Devices, methods, and systems for testing a heat detector of a self-testing hazard sensing device are described herein. One device includes a heat detector, and a controller configured to provide energy to the heat detector to heat the heat detector to a threshold temperature, determine an amount of time it takes for the heat detector to heat to the threshold temperature, determine whether the amount of time it takes for the heat detector to heat to the threshold temperature meets or exceeds a threshold amount of time, and determine whether the heat detector is functioning properly based on whether the amount of time it takes for the heat detector to heat to the threshold temperature meets or exceeds the threshold amount of time.

Devices, systems and methods for using system-level malfunction indicators to monitor the operation and resiliency of the autonomous driving system components are described. One example of a method for diagnosing a fault in a component of an autonomous vehicle includes receiving, from an electrical sub-component of the component, an electrical signal, receiving, from an electronic sub-component of the component, a message, and determining, based on the electrical signal and the message, an operational status of the component.

A temperature sensor evaluation method is mentioned. The temperature sensor is arranged in a memory device and includes a comparator, a voltage divider and a band gap reference voltage source. The comparator compares a temperature reference voltage that varies with temperature with a plurality of divided voltages generated by the voltage divider. The evaluation method for a plurality of predetermined testing temperatures includes changing the plurality of divided voltages of the voltage divider, using the comparator to compare the divided voltages with the temperature reference voltage to determine the first detection voltage, and based on the voltage difference between a target divided voltage and the first detection voltage, retrieving the value of a temperature error between the sensing temperature of the temperature sensor and the testing temperature.