In a thermal infrared detector having trench structures, at least one sensor element is provided between the trench structures, an etching hole through which the sensor element is hollowed out and thereby thermally insulated is provided in a substrate rear surface or on the periphery of a pixel area, and an opening portion is provided below the pixel area.

An infrared sensor forming an infrared solid-state imaging device includes a sensor element portion disposed in a package. In the sensor element portion, an absorption structure supported on a substrate is provided. The absorption structure has a structure in which a second insulating film, an absorption film, and a first insulating film are stacked on a reflective film. The first insulating film and the second insulating film are formed so as to have a film thickness with which the index of absorption of infrared radiation entering the absorption structure is maximized with consideration given to the energy loss in an optical transmission path to the absorption structure.

A semiconductor sensor system, in particular a bolometer, includes a substrate, an electrode supported by the substrate, an absorber spaced apart from the substrate, a voltage source, and a current source. The electrode can include a mirror, or the system may include a mirror separate from the electrode. Radiation absorption efficiency of the absorber is based on a minimum gap distance between the absorber and mirror. The current source applies a DC current across the absorber structure to produce a signal indicative of radiation absorbed by the absorber structure. The voltage source powers the electrode to produce a modulated electrostatic field acting on the absorber to modulate the minimum gap distance. The electrostatic field includes a DC component to adjust the absorption efficiency, and an AC component that cyclically drives the absorber to negatively interfere with noise in the signal.

A method makes an electromagnetic radiation detecting device including at least one thermal detector with an absorbent membrane suspended above a substrate, intended to be located in a sealed cavity. The method includes depositing, on the substrate, a gettering metallic layer including a metallic material with a gettering effect; depositing a carbonaceous sacrificial layer of amorphous carbon on the gettering metallic layer; depositing at least one sacrificial mineral layer on the carbonaceous sacrificial layer; chemical-mechanical planarization of the sacrificial mineral layer; fabricating the thermal detector so that the absorbent membrane is produced on the sacrificial mineral layer; removing the sacrificial mineral layer; and removing the carbonaceous sacrificial layer.

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.

The invention relates to a method and an apparatus for the direct and precise measurement of the power and/or energy of a laser beam, which make a measurement possible even in areas close to the focus of a laser beam, A device is proposed for this purpose that contains a radiation sensor, an expansion device, and a support mount. The radiation sensor has a receiving surface and is configured for the generation of an electrical signal, which is dependent on the power of the laser beam or the energy of the laser beam. The expansion device and the radiation sensor are positioned on the support mount at a distance from one another. The expansion device is configured in such a way as to increase the angle range of the laser beam. The laser beam propagates to the radiation sensor with an increased angle range. A diameter of the laser beam propagated on the receiving surface is greater than a diameter of the laser beam in the area of the expansion device. The receiving surface of the radiation sensor encloses at least 90% of the cross-section surface of the laser beam propagated.

An infrared detector is provided, and the infrared detector includes: a thermoelectric element; an infrared light absorber, located on and in contact with the thermoelectric element, and configured to absorb infrared light and convert infrared light into heat; an electrical signal detector, electrically connected to the thermoelectric element and configured to detect a change in electrical performance of the thermoelectric element; wherein the infrared light absorber includes a carbon nanotube array, the carbon nanotube array includes a plurality of carbon nanotubes, a height of the plurality of carbon nanotubes are substantially the same, and the plurality of carbon nanotubes are perpendicular to the thermoelectric element.

A decoupling radiant and convective heat sensing device, and a decoupling radiant and convective heat sensing device with a means for performing calculations and then determining a heat flux and an ambient temperature using formulas or reference tables, and also with a means for alerting a person of hazardous fire conditions based on a calculated heat flux and ambient temperature.

A bolometric detector of LWIR wavelengths, including: a substrate; a membrane suspended above the substrate by supporting elements; an absorbing element comprising several MIM structures each formed with a lower metal element, an upper metal element specific to each MIM structure and with a dielectric element positioned between the lower and upper metal elements; a thermometric element comprising at least one thermometric material; wherein: the membrane includes the upper metal element, the thermometric material and one portion of the dielectric element of each MIM structure, the upper metal elements of at least two MIM structure have different dimensions relatively to each other in the main plane of the membrane, and the dielectric element of each of the MIM structures includes at least one of the following materials having vibrational modes in the LWIR range: Al.sub.2O.sub.3, AlN, TiO.sub.2.

A micromechanical sensor device and a corresponding production method include a substrate that has a front and a rear and a plurality of pillars that are formed on the front of the substrate. On each pillar, a respective sensor element is formed, which has a greater lateral extent than the associated pillar. A cavity is provided laterally to the pillars beneath the sensor elements. The sensor elements are laterally spaced apart from each other by respective separating troughs and make electrical contact with a respective associated rear contact via the respective associated pillar.