Abstract: The pneumatic solar tracking system for solar panels adjusts the angular orientation of a solar panel to maximize exposure of an upper surface of the solar panel to incident solar radiation from the sun as the sun moves across the sky. The pneumatic solar tracking system includes a base and a platform supported above the base. The platform has an opening formed therein. A plurality of pneumatic actuators are supported on the base beneath the opening formed in the platform. The solar panel is supported on an upper surface of the platform, and a plurality of pivotal connectors pivotally connect the lower surface of the solar panel to respective pistons of the plurality of pneumatic actuators. Each of the pivotal connectors pivots along at least two orthogonal axes. An optical sensor is provided for detecting and tracking the angular position of the sun.

Abstract: A temperature detection system includes a housing, a thermal imaging system at least partially disposed within the housing, and a data correction system communicatively coupled with the thermal imaging system. The thermal imaging system is configured to capture at least one thermal image of a subject. The data correction system is configured to correct at least one error associated with the at least one thermal image of the subject.

Abstract: A method is described for enabling Raman Based Distributed Temperature Sensing (DTS) systems to operate over larger environmental temperature ranges than any systems available today.

Abstract: The present disclosure provides a combined fabrication and calibration process for sensor modules and temperature sensor modules in particular. The present disclosure also provides the completed calibrated sensor module and an electronic device containing the calibrated sensor module.

Abstract: This disclosure describes a slide comprising a substrate, a WISP, and a temperature sensor, wherein the slide is capable of communicating with an external communications device via the WISP. In some implementations, the WISP comprises an antenna, an integrated circuit, and a memory unit, that are powered wirelessly by an external device, such that it is capable of measuring, logging, and communicating data. The data, such as time and temperature, may be collected via sensors connected to the WISP. In some implementations, the WISP and temperature sensor are embedded in the substrate to prevent direct contact with mounted specimens. In some implementations the slide further comprises displayed content. In some implementations, the displayed content is linked to a database of information. The various implementations of this invention may describe a slide utilizing any number of the features described above in any combination.

Abstract: The present disclosure relates to temperature detection equipment and in particular to a wireless detecting thermometer for barbecue, which comprises a host and a temperature probe, wherein the host is provided with a storage slot and a control circuit board integrated with a Bluetooth adapter, a central processing unit and a digital display; the temperature probe comprises a metal casing, a temperature-sensing resistor and a temperature measuring chip; the temperature measuring chip is connected to a Bluetooth transceiver signally communicated with the Bluetooth adapter in the host. A Bluetooth protocol is applied for data transmission to get rid of a data cable, so that the temperature probe can be put into an oven, thus to improve the convenience of the product. Besides, the temperature data and the power data are shown on the digital display, which is convenient to observe, and the temperature detection is convenient.

Abstract: The invention relates to a method for monitoring the temperature of a cryopreserved biological sample. The invention also relates to a device for monitoring the temperature of a cryopreserved biological sample. The device (10) for monitoring the temperature of a cryopreserved biological sample comprises a sample container (1) having a receiving space (2) for receiving a biological sample (6). The device also comprises at least one chamber (11) having an interior that is not fluidically connected to the receiving space (2) and is only partially filled with an indicator substance (7) with a melting temperature in a region of ?20° C. to ?140° C. The chamber (11) has a barrier (13) that causes the indicator substance (7) to move into a second sub-region (12b) of the chamber (11) when the indicator substance (7) in a first sub-region (12a) of the chamber is in the fluid aggregate state.

Abstract: A technique for measuring the resistance of a resistive element 4 in the presence of a series diode is provided. By supplying three different currents I1, I2, I3 and measuring corresponding voltages V1, V2, V3 across the resistive element and diode, the voltages can be combined to at least partially eliminate an error in the measured resistance of the resistive element caused by a voltage drop across the diode. A technique for current control in an array of resistive elements is also described in which a column of resistive elements is provided with two or more current sources switched so that while one current source is providing current to the column line corresponding to a selected resistive element, another current source has its amount of current adjusted.

Abstract: Embodiments of the present disclosure discloses a temperature detecting device, a temperature detecting system and a temperature detecting method. The temperature detecting device includes: a bearing support, a first end of the bearing support being fixed; a temperature detector, provided on a second end of the bearing support; a moving component, configured to be connected with the bearing support, wherein the second end of the bearing support is movable with respect to the first end under driving of the moving component.

Abstract: A hybrid temperature sensor for an integrated circuit includes two temperature sensors—an application temperature sensor for measuring temperature during normal use of the integrated circuit, and a calibration temperature sensitive element. By providing two temperature sensitive elements within the integrated circuit, it is possible to take advantage of different characteristics of temperature sensors to achieve high accuracy calibration of the application temperature sensor relatively quickly and at low cost, whilst also maintaining desirable characteristics for the application temperature sensor, such as high speed, low power consumption, high resolution, etc.

Abstract: Examples of a fiber optic temperature measuring system for measuring a temperature of a surface at multiple points simultaneously in real time is provided. The fiber optic temperature measuring system comprises a fiber optic probe with fiber bundle with plurality of individual fibers with thermographic phosphor at the fiber's tip and a high-speed camera. Invention allows accurate multipoint measurement of ESC' surface temperature. The thermographic phosphor is embedded in a nudge at the tip of each individual fibers or on the surface (under the surface) at predetermined positions.

Abstract: One general aspect includes a tethered temperature sensor (300) for use within a vehicle track (100). The tethered temperature sensor (300) includes one or more sensors (308) for measuring temperature located in a high strain and high temperature region (104) of the vehicle track (100). The sensor also includes circuitry (402) configured to control and/or monitor the one or more sensors and located in a low strain and low temperature region (102) of the vehicle track (100). The sensor also includes a housing (406) to contain the circuitry. The sensor also includes an encapsulating material (408) that fills an interior of the housing (406).

Abstract: A temperature sensor for measuring temperature is described. The sensor comprises a fibre optic cable (104) comprising optical fibre (102) and an interrogator unit (106) configured to interrogate the optical fibre with electromagnetic radiation, detect any radiation that is Rayleigh backscattered within the optical fibre and determine a measurement signal indicative of temperature changes for at least one longitudinal sensing portion of the optical fibre. A controllable thermal element, which may be a heating element, such as an electrically conducting element (108), is arranged along the length of the fibre optic cable (104) and in thermal communication with the fibre optic cable (104). A controller (110) is configured to generate a thermal variation in the controllable thermal element, e.g. by generating a time varying electric current in the electrically conducting element (108).

Abstract: An apparatus and method for inspecting cooling holes in an engine component can include a cover that is placed over the engine component and positioned proximate at least some of the cooling holes. A fluid is passed through the engine component to exhaust out of the cooling holes and impinge upon the cover. Analysis of the signature of the fluid impinging on the cover can be used to determine operation of the cooling holes with comparison of the signature to a reference signature.

Abstract: The present invention relates to integrated circuits. More specifically, embodiments of the present invention provide methods and systems for determining temperatures of an integrated circuit using an one-point calibration technique, where temperature is determined by a single temperature measurement and calculation using known electrical characteristics of the integrated circuit.

Abstract: A device for measuring the internal temperature of heap fermentation includes an infrared thermal imaging camera, a distance detection camera, and a controller. The infrared thermal imaging camera obtains a temperature distribution image of a surface of a fermentation heap. The distance detection camera obtains a distance between the surface of the fermentation heap and the distance detection camera. The controller matches the temperature distribution image of the surface of the fermentation heap with the distance between the surface of the fermentation heap and the distance detection camera, performs semantic segmentation on the image after matching is completed, extracts a three-dimensional (3D) contour temperature map of the surface of the fermentation heap, corrects a surface temperature of the fermentation heap, and predicts an estimated internal temperature of the fermentation heap, such that the internal temperature of the fermentation heap is effectively and accurately predicted.

Abstract: An example device includes a first temperature sensor configured to provide a first current signal indicative of a temperature of a first circuit based on a voltage of a first temperature sensing element. The first circuit includes a power switch device and the first temperature sensing element. A second temperature sensor is configured to provide a second current signal indicative of temperature of a second circuit based on a voltage of a second temperature sensing element. The second circuit includes the second temperature sensing element. A trim circuit is configured to trim current in at least one of the first temperature sensor or the second temperature sensor to compensate for mismatch between temperature coefficients of the first and second temperature sensing elements.

Abstract: 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.

Abstract: A method determines a characteristic temperature of an electric or electronic system. The method includes: during operation of the system, measuring one or more characteristic parameters of the system; estimating the characteristic temperature based on a thermal model of the system and a first subset of the measured characteristic parameters; predicting a first value for a temperature-sensitive electrical parameter (TSEP) based on a TSEP model and the estimated characteristic temperature; determining a second value for the TSEP based on a second subset of the measured characteristic parameters; comparing the first value and the second value for the TSEP; and adapting the thermal model or the TSEP model based on a result of the comparison.

Abstract: A transmission in combination with a temperature measurement device and a device exterior to the transmission. The transmission includes a rotatable housing which drives a wheel of a vehicle, a wireless transceiver in communication with a thermistor embedded within molding, a battery embedded within the molding, and the molding resides within the housing. The temperature measurement device resides in a wall of the rotatable housing and the rotatable housing includes an interior volume. The interior volume of the rotatable housing is partially filled with oil for lubrication of transmission components residing within the interior volume of the housing. The temperature measurement device is rotated through the oil and out of the oil within the rotating housing when the rotating housing is in motion.