A calibration device for precise calibration of a microwave radiometer is described. The calibration device has a housing that partially encompasses a calibration chamber. The housing includes a microwave transparent portion that is provided at a wall of the housing. The microwave transparent portion defines an entry for microwaves into the calibration chamber. The microwave transparent portion is made by a microwave transparent material that is insulating. An absorber at a defined temperature is provided within the calibration chamber. An interface between the microwave transparent portion and the absorber is provided, which ensures a substantially reflection free entry of the microwaves into the calibration chamber. The substantially reflection free entry of the microwaves corresponds to capturing at least 3 orders of reflection of the microwaves. Further, a method of calibrating a microwave radiometer is described.

Provided is a method of calibrating a microwave radiometer, which eliminates use of liquid nitrogen as a calibration source. The method is applied to a microwave radiometer configured to receive, by a receiver having a primary radiator connected thereto, a radio wave emitted from an object to be measured depending on a temperature of the object to be measured and to measure a brightness temperature of the object to be measured from an output signal of the receiver. In the method, the method a noise temperature T.sub.rx of the receiver appearing on an output side of the receiver is calibrated by observing a plurality of calibration sources having known brightness temperatures. The method includes using a radio wave reflector configured to totally reflect noise radiated from an input side of the receiver as one of the plurality of calibration sources.

Examples include systems and methods for communicating temperature variation information of a transmitter resonator to a receiver resonator in an optical communication system. Some examples provide a transceiver module that includes a transmitter resonator to transmit optical signals emitted from a light source, a photodetector coupled to the transmitter resonator to detect the optical signals transmitted by the transmitter resonator and generate a photocurrent, and a controller to receive the photocurrent from the photodetector, determine temperature variation information of the transmitter resonator from the photocurrent, and encode the temperature variation information in an outgoing data stream transmitted via the transmitter resonator.

The present invention relates to a method and an apparatus for measuring the temperature of optical fibers during fusion splicing or thermal processing, said method comprising: a) measuring, using an interferometric method, a change in an optical path length in an optical fiber due to temperature dependent properties of the optical fiber during fusion splicing or thermal processing; and b) determining the temperature of the optical fiber based on the measured changes in the optical path length.

The invention offers high resolution and accuracy for nanoscale temperature mapping. Instead of collecting light after emission in near-field that decays to far-field, the present invention directly couples the near-field waves to a polaritonic-coated infrared probe. The polaritonic coating can be formed on an IR-tuned optical fiber to receive the coupled IR radiation and form polaritons, including plasmons or phonons, using the IR polaritonic material. The IR polaritons propagate along the probe decay back into the fiber core without substantial losses to far-field and are transmitted to a detector, such as a spectroscope. The coupling of the near-field energy to emission detected through the tip apex of fiber can be expressed as emission spectra. Through mapping with other spatial points, multi-dimensional displays and other information can be provided. The resolution can be less than 100 nanometers, such as at least an order of magnitude less than 100 nanometers.

An online measurement method for temperature stability of production layers in an oil and gas well includes: obtaining a plurality of temperature data at each position point of an optical fiber; according to the temperature data, calculating temperature standard deviations of each position point within a production layer at a plurality of time points; performing probability distribution statistics according to the temperature standard deviations at all position points of the production layer at a same time point, fitting a probability distribution curve according to normal distribution, and obtaining a probability density function; obtaining the temperature standard deviations corresponding to at least one value that integral values of the probability density function at all position points of the production layer at each time point is between (0, 1), generating a standard temperature deviation normal distribution probability time curve of each section of the production layer according to the temperature standard deviations.

A cooking food vessel including a metal body, at least one handle, constrained to a portion of the metal body via a metal fastening element, and at least one thermal signalling device, applied on a portion of the handle placed at a respective component having thermal conductivity properties. The thermal signalling device is provided with at least one indicating element operatively connected to a respective actuating element made of a shape-memory alloy. The actuating element is a shape-memory coil spring, indirectly contacting the component having thermal conductivity properties and configured to switch from a first non-operative configuration, wherein is inactive, to a second operative configuration, wherein is stretched when a predefined temperature value is achieved. Between the actuating element and the component having thermal conductivity properties is interposed a metal base for modulation and/or thermal enhancement which transfers heat to such actuating element.

A cooking food vessel including a metal body, at least one handle, constrained to a portion of the metal body via a metal fastening element, and at least one thermal signalling device, applied on a portion of the handle placed at a respective component having thermal conductivity properties. The thermal signalling device is provided with at least one indicating element operatively connected to a respective actuating element made of a shape-memory alloy. The actuating element is a shape-memory coil spring, indirectly contacting the component having thermal conductivity properties and configured to switch from a first non-operative configuration, wherein is inactive, to a second operative configuration, wherein is stretched when a predefined temperature value is achieved. Between the actuating element and the component having thermal conductivity properties is interposed a metal base for modulation and/or thermal enhancement which transfers heat to such actuating element.

The disclosed embodiments relate to the monitoring and control of additive manufacturing. In particular, a method is shown for removing errors inherent in thermal measurement equipment so that the presence of errors in a product build operation can be identified and acted upon with greater precision. Instead of monitoring a grid of discrete locations on the build plane with a temperature sensor, the intensity, duration and in some cases position of each scan is recorded in order to characterize one or more build operations.

The disclosed embodiments relate to the monitoring and control of additive manufacturing. In particular, a method is shown for removing errors inherent in thermal measurement equipment so that the presence of errors in a product build operation can be identified and acted upon with greater precision. Instead of monitoring a grid of discrete locations on the build plane with a temperature sensor, the intensity, duration and in some cases position of each scan is recorded in order to characterize one or more build operations.