This relates to sensor systems, detectors, imagers, and readout integrated circuits (ROICs) configured to selectively detect one or more frequencies or polarizations of light, capable of operating with a wide dynamic range, or any combination thereof. In some examples, the detector can include one or more light absorbers; the patterns and/or properties of a light absorber can be configured based on the desired measurement wavelength range and/or polarization direction. In some examples, the detector can comprise a plurality of at least partially overlapping light absorbers for enhanced dynamic range detection. In some examples, the detector can be capable of electrostatic tuning for one or more flux levels by varying the response time or sensitivity to account for various flux levels. In some examples, the ROIC can be capable of dynamically adjusting at least one of the frame rate integrating capacitance, and power of the illumination source.

An infrared thermal sensor for detecting infrared radiation, comprising a substrate and a cap structure together forming a sealed cavity, the cavity comprising a gas at a predefined pressure; a membrane arranged in said cavity for receiving infrared radiation; a plurality of beams for suspending the membrane; a plurality of thermocouples for measuring a temperature difference between the membrane and the substrate; wherein the ratio of the thermal resistance between the membrane and the substrate through the thermocouples, and the thermal resistance between the membrane and the substrate through the beams and through the gas is a value in the range of 0.8 to 1.2. A method of designing such a sensor, and a method of producing such a sensor is also disclosed.

A device for detecting electromagnetic radiation, including a substrate; at least one thermal detector, placed on the substrate, including an absorbing membrane suspended above the substrate; and an encapsulating structure encapsulating the thermal detector, including an encapsulating layer extending around and above the thermal detector so as to define with the substrate a cavity in which the thermal detector is located; wherein the encapsulating layer includes at least one through-orifice that is what is referred to as an exhaust vent, each exhaust vent being placed so that at least one thermal detector has a single exhaust vent located facing the corresponding absorbing membrane, preferably plumb with the center of said absorbing membrane.

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.

We disclose a chemical sensing device for detecting a fluid. The sensing device comprises: at least one substrate region comprising at least one etched portion; a dielectric region formed on the at least one substrate region, the dielectric region comprising at least one dielectric membrane region adjacent to the at least one etched portion; an optical source for emitting an infra-red (IR) signal; an optical detector for detecting the IR signal emitted from the optical source; one or more further substrates formed on or under the dielectric region, said one or more further substrates defining an optical path for the IR signal to propagate from the optical source to the optical detector. At least one of the optical source and optical detector is formed in or on the dielectric membrane region.

A device for detecting electromagnetic radiation is provided, including a substrate; at least one thermal detector placed on the substrate; and an encapsulating structure encapsulating the detector, including a thin encapsulating layer of a material that is transparent to said radiation, extending around and above the detector so as to define with the substrate a cavity in which the detector is located; wherein the thin encapsulating layer comprises a peripheral wall that encircles the detector, and that has a cross section, in a plane parallel to the plane of the substrate, of square or rectangular shape, corners of which are rounded.

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.

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.

Pyroelectric detection device, including at least: a substrate; a membrane arranged on the substrate; a pyroelectric detection element arranged on the membrane or forming at least one part of the membrane, and including at least one portion of pyroelectric material arranged between first and second electrodes; a cavity passing through the substrate, emerging opposite a part of the membrane which forms a bottom wall of the cavity, and including side edges formed by the substrate; an element for stiffening the membrane arranged in the cavity, partially filling the cavity, made integral with the side edges of the cavity at at least two distinct anchoring regions, and arranged against the membrane.

Systems, methods, and apparatus for providing an improved electromagnetic radiation sensing micromechanical device to be utilized in high pixel-density pixel sensor arrays. The device includes an improved design for improved and adjustable performance through simple geometric or fabrication means. Furthermore, the design of the device lends itself to simple micromechanical manufacturing procedures. Additionally, the manufacturing procedures include a method to enable high uniformity and high yield sensor arrays. Arrays of the device can be utilized as IR imaging detectors for use in applications such as human presence detection, nonvisual environment monitoring, security and safety, surveillance, energy monitoring, fire detection and people counting.