Epoxy-based inline infrared (IR) filter assembly, and manufacture and use of the same. Co-axial infrared filter assemblies comprise a substantially cylindrical filter body forming a central cavity characterized by opposing holes at each end. The filter body forms an outer conductor, and SMA connectors coupled to the opposing holes at each end of the body are electrically coupled to form an inner conductor positioned along a long axis of the filter body. An infrared absorbing material (such as castable epoxy resin) fills the central cavity of the filter body. Methods for producing the co-axial infrared filter include pressing SMA connectors into the respective ends of the filter body, electrically coupling the SMA connectors, and filling the filter body with epoxy. Electronic systems for operating a dark matter detector include a feedline comprising a coaxial filter configured to advantageously block infrared noise.

A building material apparatus includes at least one building material transport part which follows a building material drum, wherein the building material transport part is designed to transport building material which is to be at least partially cured, and at least one part sensor. The part sensor is arranged on and/or in the building material transport part and is designed to detect at least one intensive variable, or at least one variable which corresponds at least to the intensive variable, of the building material in the building material transport part.

A method for internal calibration of a detector comprising using one or more hardware processors for the following actions. The method comprises an action of receiving a request for internal calibration of a detector comprising a switchable termination resistor (Dicke switch) and connecting electronically one or more internal calibration circuits to the termination resistor. The method comprises an action of applying two or more input voltage signals to the detector from the calibration circuit and measuring two or more output readings from the detector, each output reading corresponding to one of the input voltage signals. The method comprises an action of computing internal calibration coefficients based on the input voltage signals and the output readings. The method comprises an action of storing the internal calibration coefficients on a non-transitory computer-readable storage medium connected to the hardware processor(s) for subsequent calibration of output values from the detector.

A guided wave radar (GWR)-based method of measuring steam pressure includes transmitting at least a first microwave pulse signal from a GWR sensor system having a pulsed radar gauge (PRG) implementing a steam measurement algorithm coupled to a transceiver that is coupled to a GWR probe in a steam boiler tank having a reference reflector (RR) providing an impedance discontinuity. The transmitting the first microwave pulse signal is with water and steam in the steam boiler tank. An echo emanating from the RR is received responsive to the first microwave pulse signal generates that respective time of flight (TOF) measurement data. A refractive index value for the steam is determined from the TOF measurement data and a reference TOF value representing a TOF measurement without the steam in the steam boiler tank. A physical property of the steam is determined from the refractive index value, such as the pressure.

A microwave ablation system incorporates a microwave thermometer that couples to a microwave transmission network connecting a microwave generator to a microwave applicator to measure noise temperature. The noise temperature is processed to separate out components the noise temperature including the noise temperature of the tissue being treated and the noise temperature of the microwave transmission network. The noise temperature may be measured by a radiometer while the microwave generator is generating the microwave signal or during a period when the microwave signal is turned off. The microwave ablation system may be configured as a modular system having one or more thermometry network modules that are connectable between a microwave applicator and a microwave generator. Alternatively, the modular system includes a microwave generator, a microwave applicator, and a microwave cable that incorporate a microwave thermometry network module.

A microwave radiometric sensor probe module configured to fit within at least an external portion of an auditory or ear canal of a patient encloses a microwave integrated circuit and associated waveguide printed probe. The probe is configured to receive microwave radiation from a dielectric rod antenna of the module oriented into the auditory canal towards a tympanic membrane. Radiation from the tympanic membrane is coupled into the rod antenna, projected towards the printed probe, and received at the integrated circuit. A communications interface connects the integrated circuit to a temperature monitor and control unit for receiving the sensor output and for deriving at least a measure of patient brain temperature from the sensor output. The temperature monitor and control unit may be connected to a targeted temperature management system for controlling the temperature of a patient on the basis of the derived brain temperature.

A radiometer for a microwave receiver according to an embodiment of the present invention comprises: an antenna line through which radiation power corresponding to the temperature of a probe is received from an antenna; a first reference rod having a first reference temperature fixed in advance; a second reference rod having a second reference temperature fixed in advance; a first microwave switch for selectively switching the antenna line, the first reference load, and the second reference load; a second microwave switch switched with the same clock as the first microwave switch; a demodulator for multiplying a signal output from the second microwave switch by a predetermined gain value and outputting same; an integrator for integrating the signal output from the demodulator; and a controller for measuring the temperature of the probe on the basis of a signal output from the integrator.

This invention relates to a method and apparatus for automated measurement of the temperatures of samples on a production line without any human intervention. In one aspect the apparatus has a conveyance system; and a temperature measurement unit having: a first member and a second member which are movable relative to each other between at least a first position in which the first and second members cooperate to form an internal space which is substantially internally reflective of radiofrequency radiation and a second position in which the object can be introduced into said internal space; and a radiometer arranged so that it is coupled to said internal space, wherein the conveyance system is arranged to convey the object to a measurement position in said internal space whilst the first and second members are in the second position, for a measurement of the radiation emitted from the object to be performed by the radiometer when the first and second members are in the first position and to convey the object away from said measurement position once the measurement has been performed and said first and second members have returned to the second position. The apparatus allows for recording and storing of measured temperature information. Embodiments of the invention provide for auto-calibration of the apparatus and automated testing and rejection of samples which do not meet pre-defined criteria.

The present invention provides a system and method of detecting the presence of a foreign substance, such as ice, in an air-flow path within an operating jet engine by providing one or more electromagnetic sensors that are tuned to receive electromagnetic waves at one or more frequencies generated by the operating jet engine that change upon the presence of the foreign substance. In at least one embodiment, the waves can be transmitted to the electromagnetic sensor through an electromagnetically transparent window in a wall of the jet engine. In at least another embodiment, the electromagnetic sensor can be coupled with a connector that penetrates an operating chamber in the jet engine to measure the electromagnetic parameters of one or more components from within the chamber of the jet engine. In some embodiments, the amount of ice or other foreign substances can be measured or estimated.

A container is disclosed which may be used with fluids sensitive to light of one or more known wavelengths. The container may be formed of a thermochromic material or including a thermochromic coating. The properties of the thermochromic material or coating may be selected so as to be transparent to light of the wavelength to which the fluid is sensitive at a first temperature and to be opaque to that wavelength of light at a second temperature. While a technician is handling the container, the container is controlled to be at the first temperature. When the technician is finished, the container is controlled to move to the second temperature to protect the fluid within the container.