A microbolometer for measuring thermal radiation comprises an electrical circuit on a perforated plastic substrate. The electrical circuit comprises at least one thermistor having a temperature dependent electric resistance, wherein the thermistor is arranged to receive the thermal radiation for changing its temperature depending on a flux of the received thermal radiation. The electrical circuit is configured to measure the electric resistance of the thermistor for calculating the thermal radiation. The microbolometer is configured to cause a gas flow through the perforations for improving thermal characteristics.

Systems, methods, and apparatuses for providing electromagnetic radiation sensing using sequential beam splitting. The apparatuses can include a micro-mirror chip having a plurality of light reflecting surfaces, an image sensor having an imaging surface, and a beamsplitter unit located between the micro-mirror chip and the image sensor. The beamsplitter unit includes a plurality of beamsplitters aligned along a horizontal axis that is parallel to the micro-mirror chip and the imaging surface. The beamsplitters implement the sequential beam splitting. Because of the structure of the beamsplitter unit, the height of the arrangement of the micro-mirror chip, the beamsplitter unit, and the image sensor is reduced such that the arrangement can fit within a mobile device. Within a mobile device, the apparatuses can be utilized for human detection, fire detection, gas detection, temperature measurements, environmental monitoring, energy saving, behavior analysis, surveillance, information gathering and for human-machine interfaces.

The invention relates to a thermopile infrared individual sensor in a housing that is filled with a gaseous medium having optics and one or more sensor chips with individual sensor cells with infrared sensor structures with reticulated membranes, the infrared-sensitive regions of which are spanned by, in each case, at least one beam over a cavity in a carrier body with good thermal conduction. The object of the invention consists of specifying a thermopile infrared sensor using monolithic Si-micromechanics technology for contactless temperature measurements, which, in the case of a sufficiently large receiver surface, outputs a high signal with a high response speed and which can operated in a gaseous medium with normal pressure or reduced pressure and which is producible in mass produced numbers without complicated technology for sealing the housing. This is achieved by virtue of, in each case, combining a plurality of individual adjacent sensor cells (18) with respectively one infrared-sensitive region with thermopile structures (14, 15) on the membrane (12) on a common carrier body (1) of an individual chip to a single thermopile sensor structure with a signal output in the housing, consisting of a cap (12) sealed with a base plate (3) with a common gaseous medium (10).

A thermal infrared sensor array in a wafer-level package includes at least one infrared-sensitive pixel produced using silicon micro mechanics, comprising a heat-isolating cavity in a silicon substrate surrounded by a silicon edge, and a thin membrane connected to the silicone edge by of thin beams. The cavity extends through the silicon substrate to the membrane, and there are slots between the membrane, the beams and the silicon edge. A plurality of infrared-sensitive individual pixels are arranged in lines or arrays and are designed in a CMOS stack in a dielectric layer, forming the membrane, and are arranged between at least one cover wafer which is designed in the form of a cap and has a cavity and a base wafer. The cover wafer, the silicon substrate and the base wafer are connected to one another in a vacuum-tight manner and enclosing a gas vacuum.

The use of silicon or vanadium oxide nanocomposite consisting of graphene deposited on top of an existing amorphous silicon or vanadium oxide microbolometer can result in a higher sensitivity IR detector. An IR bolometer type detector consisting of a thermally isolated nano-sized (<one micron feature size) electro-mechanical structure comprised of Si3N4, SiO2 thins films, suspended over a cavity with a copper thin film reflecting surface is described. On top of the suspended thin film is a nanostructure composite comprised of graphene monolayers, covered with various surface densities of VoXy or amorphous nanoparticles, followed by another graphene layer. The two conducting legs are connected to a readout integrated circuit (ROIC) fabricated on a CMOS wafer underneath. The nanostructure is fabricated after the completion of the ROIC process and is integrate able with the CMOS process.

An infrared detector includes: a laminate of semiconductor in which a first electrode layer, a light receiving layer, and a second electrode layer are laminated in this order; a first insulating film configured to be in contact with the laminate and covers a surface of the laminate; and a second insulating film configured to be in contact with and covers a surface of the first insulating film opposite to an interface between the first insulating film and the laminate, wherein the first insulating film is configured to have a lower Gibbs free energy than an oxide of a material from which the laminate is formed, and in the second insulating film, diffusion of impurity is larger than in the first insulating film.

This infrared imaging element includes: a substrate which has a front surface and a back surface and to which a circuit unit is provided; a support leg wiring line that is disposed above the front surface of the substrate; and an infrared-ray detection unit which is held on the support leg wiring line and to which a diode electrically connected to the circuit unit via the support leg wiring line is provided, wherein the temperature change of the infrared-ray detection unit is detected as an electrical signal change of the diode by the circuit unit. The substrate, the support leg wiring line, and the infrared-ray detection unit are laminated at intervals in a direction perpendicular to the front surface of the substrate.

Systems, methods, and apparatuses for providing on-board electromagnetic radiation sensing using beam splitting in a radiation sensing apparatus. The radiation sensing apparatuses can include a micro-mirror chip including a plurality of light reflecting surfaces. The apparatuses can also include an image sensor including an imaging surface. The apparatuses can also include a beamsplitter unit located between the micro-mirror chip and the image sensor. The beamsplitter unit can include a beamsplitter that includes a partially-reflective surface that is oblique to the imaging surface and the micro-mirror chip. The apparatuses can also include an enclosure configured to enclose at least the beamsplitter and a light source. With the apparatuses, the light source can be attached to a printed circuit board (PCB). Also, the enclosure can include an inner surface that has an angled reflective surface that is configured to reflect light from the light source in a direction towards the beamsplitter.

Systems, methods, and apparatuses for providing electromagnetic radiation sensing using sequential beam splitting. The apparatuses can include a micro-mirror chip having a plurality of light reflecting surfaces, an image sensor having an imaging surface, and a beamsplitter unit located between the micro-mirror chip and the image sensor. The beamsplitter unit includes a plurality of beamsplitters aligned along a horizontal axis that is parallel to the micro-mirror chip and the imaging surface. The beamsplitters implement the sequential beam splitting. Because of the structure of the beamsplitter unit, the height of the arrangement of the micro-mirror chip, the beamsplitter unit, and the image sensor is reduced such that the arrangement can fit within a mobile device. Within a mobile device, the apparatuses can be utilized for human detection, fire detection, gas detection, temperature measurements, environmental monitoring, energy saving, behavior analysis, surveillance, information gathering and for human-machine interfaces.

A complementary metal oxide semiconductor (CMOS) device embedded with micro-electro-mechanical system (MEMS) components in a MEMS region. The MEMS components, for example, are infrared (IR) thermosensors. The device is encapsulated with a CMOS compatible IR transparent cap to hermetically seal the MEMS sensors in the MEMS region. The CMOS cap includes a base cap with release openings and a seal cap which seals the release openings.