The present invention relates to a method for controlling an evaporation rate of source material (20) in a system (10) for thermal evaporation with electromagnetic radiation (120), wherein the system (10) comprises an electromagnetic radiation source (110) for providing an electromagnetic radiation (120), a vacuum chamber (12) containing a reaction atmosphere (16) and a main detector (40, 100) for measuring electromagnetic radiation (120), wherein a source material (20) and a target material (18) to be coated are arranged in the vacuum chamber (12) and the electromagnetic radiation source (110) is arranged such that its electromagnetic radiation (120) impinges at an angle, preferably at an angle of 45°, on a source surface (22) of the source material (20) for a thermal evaporation and/or sublimation of the source material (20) below the plasma threshold, and wherein the main detector (40, 100) for measuring electromagnetic radiation (120) is arranged such that electromagnetic radiation (120) reflected on the source surface (22) reaches the main detector (40, 100), further wherein the source material (20) is provided by a source element (24), wherein the source surface (22) is located accessible for the electromagnetic radiation (120) at the source element (24), whereby the source element (24) is arranged in a holding structure (28) and movable by the holding structure (28) perpendicular to the source surface (22). Further, the present invention relates to a detector (40) for measuring electromagnetic radiation (120), the detector (40) preferably suitable for a method according to the present invention, and additionally to a system (10) for thermal evaporation with electromagnetic radiation (120) suitable for the method according to the present invention.

A getter assembly is provided and includes a first canister, an internal can including getter, and a second canister. The internal can is disposable in the first canister to occupy a first position at which the getter is hermetically sealable and second positions at which the getter is exposed to an exterior environment. The second canister is engageable with the first canister to drive movements of the internal can between the first position and the second positions following activation and hermetic sealing of the getter.

An electronic device according to various exemplary embodiments of the present disclosure includes: a motion sensor; a temperature sensor configured to acquire temperature information on an external object; an image sensor configured to acquire an image on the external object; and a processor, and the processor is configured to: identify a motion of the electronic device and a motion of the external object using the motion sensor or the image; when the motion falls within a specified range, acquire the temperature information in a first method; when the motion falls within another specified range, acquire the temperature information in a second method; and provide an indicator corresponding to the temperature information through a display functionally connected with the electronic device.

A system, device, and method for managing colors of a color printer by printing color patches on a test sheet of paper associated with a paper type, determining spectral data of the color patches using an inline full width array spectrophotometer of the color printer, determining measurements based on the spectral data, determining that a measurement is equal to or within a range of a measurement associated with an existing paper profile; and printing subsequent sheets of paper associated with the paper type using parameters associated with the existing paper profile.

A turbine engine having an optical imaging system with a housing configured for mounting to a wall of the turbine engine, a camera located in the housing, a hollow probe extending from the housing and having a longitudinal axis, an image receiving device at an end of the hollow probe and communicably coupled with the camera, and method for operating same.

An infra-red sensor assembly may comprise a substrate and an infra-red transmitter electrically coupled to the substrate. An infra-red receiver may be electrically coupled to the substrate. A testing infra-red transmitter may be electrically coupled to the substrate. An infra-red transmission channel may optically couple the testing infra-red transmitter and the infra-red receiver.

The invention relates to a device for measuring the temperature in the anus or in the vagina of an animal, wherein a front longitudinal part, an abutment part and a rear longitudinal part lie in succession on the device, wherein the front longitudinal part is equipped with a temperature sensor and, when used as intended, it is intended to be inserted into the anus or the vagina of the animal until the abutment part approximately rests against the outside of the body of the animal. One or more further temperature sensors are attached to the rear longitudinal part and/or to the abutment part, which, when used as intended, are provided for measuring the temperature in the surroundings of the animal.

A method of measuring ocular surface temperature includes steps as follows. Using a built-in temperature sensor called a black plate herein, an infrared heat sensor is provided and the temperature sensor contacts the black plate. The temperature sensor measures an actual black plate temperature. The infrared heat sensor detects a radiation emitted by the black plate, and the radiation is computed according to a temperature rising curve through a computing unit of a work station to generate a computed black plate temperature. A value of temperature shifting error is determined by subtracting the actual black plate temperature from the computed black plate temperature.

A device for determining the temperature of a road building material applied by a construction machine in a placement width includes an infrared temperature measuring head, a motor and a controller. The infrared temperature measuring head is arranged to be twistable by the motor in a manner transverse to the direction of travel of the construction machine so as to scan the surface of the road building material to capture temperature measuring values of the surface of road building material during a rotational movement at a plurality of measuring points spaced apart from one another. The controller is configured to set a scanning speed as a function of a position of the measuring point.

Disclosed is a sensor shield for use in a multi-shelf merchandise display unit including a plurality of sensors mounted on a wall of the unit and opposite a source of illumination, in which each sensor corresponds to a single shelf and in which the shelves are at least semi-porous to the illumination. The shield comprises i) a plate having a length that is sufficient substantially to reduce or prevent incident illumination from the shelf above reaching the sensor; and ii) means to attach the plate to casing of or around the sensor or the wall of the unit. The plate is opaque to the illumination detected by the sensor. Also disclosed is a method to reduce the interference of light in a multi-shelf merchandise display unit from shelves above a shelf on which stock levels are being measured and a method for monitoring stock levels in a retail display cabinet by measuring light entering the retail display cabinet.