A medical thermometer including a curved mirror and a radiation sensor is disclosed. The radiation sensor is disposed relative to the mirror in a configuration whereby the mirror reflects away from the sensor radiation that passes through the radiation entrance and that is oriented outside a range of angles relative to the mirror, and reflects toward the sensor radiation that passes through the radiation entrance and that is oriented within a range of angles relative to the mirror.

A device for measuring temperature of a turbine wheel in a turbocharger includes: a guide that passes infrared ray generated from the turbine wheel and includes a coolant path; a protection unit that protects an optical head which senses the infrared ray; and a signal processing unit that measures a temperature of the turbine wheel by processing a signal corresponding to the sensed infrared ray.

Embodiments disclosed herein provide an RTP system for processing a substrate. An RTP chamber has a radiation source configured to deliver radiation to a substrate disposed within a processing volume. One or more pyrometers are coupled to the chamber body opposite the radiation source. In one example, the radiation source is disposed below the substrate and the pyrometers are disposed above the substrate. In another example, the radiation source is disposed above the substrate and the pyrometers are disposed below the substrate. The substrate may be supported in varying manners configured to reduce physical contact between the substrate support and the substrate. An edge ring and shield are disposed within the processing volume and are configured to reduce or eliminate background radiation from interfering with the pyrometers. Additionally, an absorbing surface may be coupled to the chamber body to further reduce background radiation interference.

The present invention relates to a method and a system of automatically calibrating a radiation thermometer disposed in a polishing apparatus. This method includes: placing a heating device (61), to which a measurement body (68) is attached, below the radiation thermometer (48); and using a controller (40) of the polishing apparatus coupled to the heating device (61) to heat a temperature of the measurement body (68) to a plurality of target temperatures (Ta), to measure the temperatures of the measurement body (68) at each target temperature (Ta) with the radiation thermometer (48), to calculate temperature deviation amounts which are differences between each of the target temperatures (Ta) and temperature output values of the radiation thermometer (48) corresponding to each target temperature (Ta), and to calibrate the radiation thermometer (48) so that all the temperature deviation amounts are within a preset reference range.

Aspects and examples described herein provide a lightweight radiation shielding structure for infrared cameras. In one example, a top radiation shielding element and a bottom radiation shielding element are placed as close as possible to an infrared detector to minimize excess weight added to the infrared camera while providing optimal radiation shielding. Such aspects and examples provide important functionality for numerous weight-sensitive applications in high-radiation environments.

Passive detector structures for imaging systems are provided which implement unpowered, passive front-end detector structures with direct-to-digital measurement data output for detecting incident photonic radiation in various portions (e.g., thermal (IR), near IR, UV and visible light) of the electromagnetic spectrum.

A line of sight blocker including a cover defining a duct bounded by the cover and a heated surface when the cover is fastened over the heated surface. The cover blocks transmission of infrared radiation emitted from the heated surface; the cover comprises a material having a lower thermal conductivity than the heated surface; and the duct comprises a vent and a path for latent heat from the heated surface to escape through the vent.

A thermal sensor including a thermal sensing array and a calibration circuit is provided. The thermal sensing array includes a plurality of thermal sensing cells. The thermal sensing cells include a first unmasked thermal sensing cell and a first masked thermal sensing cell. The first unmasked thermal sensing cell senses and obtains a first unmasked sensing data. The first masked thermal sensing cell is disposed adjacent to the first unmasked thermal sensing cell, and the first masked thermal sensing cell obtains a first masked sensing data. The calibration circuit is coupled to the first masked thermal sensing cell and the first unmasked thermal sensing cell. The calibration circuit calibrates the first unmasked sensing data obtained by the first unmasked thermal sensing cell according to the first masked sensing data obtained by the first masked thermal sensing cell to which the first unmasked thermal sensing cell is adjacent.

Techniques are disclosed for optical imager devices, systems, and methods. In one example, an imaging system includes a focal plane array (FPA) and a light shield. The FPA includes a detector array configured to detect a first portion of electromagnetic radiation and generate a detector signal based on the first portion. The FPA further includes a readout circuit coupled to the detector array and configured to receive the detector signal. The light shield is coupled to the FPA and configured to block a second portion of the electromagnetic radiation. Related devices and methods are also provided.

A temperature detector configured for use in a mobile terminal includes a lens, a collimator hole, and an infrared sensor that are arranged on an optical path. The lens is configured to converge ambient light, and the ambient light includes target area light and another area light. The collimator hole is used to obtain the target area light by screening and block the other area light. That is, the collimator hole screens the incident ambient light, and allows only the target area light to reach the infrared sensor.