Abstract: A semiconductor body comprises a buried layer of a first type of conductivity, a first region of the first type of conductivity, a shallow region of a second type of conductivity at a first surface of the semiconductor body, a sinker of the first type of conductivity located at the first surface of the semiconductor body, and a separating region of the first type of conductivity encircling at least one of the sinker and the buried layer. The first region is between the buried layer and the shallow region.

Abstract: A particulate matter sensor module includes a light source and a light detector mounted on a substrate. A housing is attached to the substrate and includes first and second sections attached to one another in a stack over the substrate such that the first section is disposed between the substrate and the second section. The first and second sections, in combination, define a light reflection chamber, a fluid flow conduit, a particle-light interaction chamber, and a light trap chamber. The first section has a first aperture through which light emitted by the light source can pass to a reflective surface within the light reflection chamber. The reflective surface is configured to reflect the light toward the particle-light interaction chamber where the light can interact with particles in a fluid flowing in the fluid flow conduit.

Abstract: A semiconductor body includes a driver for driving a light source, at least two detectors each including an avalanche diode, a time-to-digital converter arrangement coupled to outputs of the at least two detectors, a memory that is coupled to the time-to-digital converter arrangement and is configured to store at least one histogram, and an evaluation unit coupled to the driver and to the memory.

Abstract: The particle sensor device comprises a substrate, a photodetector, a dielectric on or above the substrate, a source of electromagnetic radiation, and a through-substrate via in the substrate. The through-substrate via is exposed to the environment, in particular to ambient air. A waveguide is arranged in or above the dielectric so that the electromagnetic radiation emitted by the source of electromagnetic radiation is coupled into a portion of the waveguide. A further portion of the waveguide is opposite the photodetector, so that said portions of the waveguide are on different sides of the through-substrate via, and the waveguide traverses the through-substrate via.

Abstract: A particulate matter sensor system for sensing particulate matter in a fluid includes a substrate and a cover disposed on the substrate. The cover defines at least a portion of a flow path through the microfluidic system. The sensor system includes a particulate matter sensor disposed in an interior space between the cover and the substrate. The particulate matter sensor includes an integrated sensor device electrically connected to the substrate. The flow path is defined through the particulate matter sensor. The sensor system includes a fluid circulation device disposed in the interior space between the cover and the substrate and configured to cause fluid to flow along the flow path through the microfluidic system.

Abstract: An optical sensor arrangement for time-of-flight comprises a first and a second cavity separated by an optical barrier and covered by a cover arrangement. An optical emitter is arranged in the first cavity, a measurement and a reference photodetector are arranged in the second cavity. The cover arrangement comprises a plate and layers of material arranged on an inner main surface thereof. The layers comprise an opaque coating with a first and second aperture above the first cavity, and with a third and fourth aperture above the second cavity. The measurement photodetector is configured to detect light entering the second cavity through the fourth aperture. The second and the third aperture establish a reference path for light from the emitter to the reference photodetector.

Abstract: A semiconductor body comprises a buried layer of a first type of conductivity, a first region of the first type of conductivity, a shallow region of a second type of conductivity at a first surface of the semiconductor body, a sinker of the first type of conductivity located at the first surface of the semiconductor body, and a separating region of the first type of conductivity encircling at least one of the sinker and the buried layer. The first region is between the buried layer and the shallow region.

Abstract: The SPAD device comprises a single-photon avalanche diode and a further single-photon avalanche diode having breakdown voltages, the single-photon avalanche diodes being integrated in the same device. The breakdown voltages are equal or differ by less than 10%. The single-photon avalanche diode is configured to enable to induce triggering or to have a dark count rate that is higher than the dark count rate of the further single-photon avalanche diode.

Abstract: A charge pump circuit arrangement includes a multitude of capacitors of a first and a second group controlled by non-overlapping clock pulses. The capacitors are partly realized in a semiconductor substrate including a deep well doping region and a high voltage doping region surrounded by the deep well doping region. Switches are connected to a pair of capacitors to control the deep well doping regions with signals in phase with the corresponding clock signal.

Abstract: The semiconductor device comprises a bipolar transistor with emitter, base and collector, a current or voltage source electrically connected with the emitter, and a quenching component electrically connected with the collector, the bipolar transistor being configured for operation at a collector-to-base voltage above the breakdown voltage.

Abstract: A avalanche diode arrangement comprises an avalanche diode (11) that is coupled to a first voltage terminal (14) and to a first node (15), a latch comparator (12) with a first input (16) coupled to the first node (15), a second input (17) for receiving a reference voltage (VREF) and an enable input (21) for receiving a comparator enable signal (CLK), and a quenching circuit (13) coupled to the first node (15).

Abstract: A particulate matter sensor module includes a light source and a light detector mounted on a substrate. A housing is attached to the substrate and includes first and second sections attached to one another in a stack over the substrate such that the first section is disposed between the substrate and the second section. The first and second sections, in combination, define a light reflection chamber, a fluid flow conduit, a particle-light interaction chamber, and a light trap chamber. The first section has a first aperture through which light emitted by the light source can pass to a reflective surface within the light reflection chamber. The reflective surface is configured to reflect the light toward the particle-light interaction chamber where the light can interact with particles in a fluid flowing in the fluid flow conduit.

Abstract: A single photon avalanche diode, SPAD, comprises an active area which is arranged to generate a photon triggered avalanche current. A cover is arranged on or above the active area. The cover shields the active area from incident photons. The cover comprises a stack of at least the first and a second metal layer. At least one of the metal layers, e.g. the first metal layer, comprises an aperture. The metal layers are arranged in the stack with respect to an optical axis such as to open an effective aperture along the optical axis. By way of the effective aperture a portion of the active area is exposed to incident photons being incident along the optical axis. The effective aperture is smaller than the aperture arranged in the first metal layer.

Abstract: A charge pump circuit arrangement includes a multitude of capacitors of a first and a second group controlled by non-overlapping clock pulses. The capacitors are partly realized in a semiconductor substrate including a deep well doping region and a high voltage doping region surrounded by the deep well doping region. Switches are connected to a pair of capacitors to control the deep well doping regions with signals in phase with the corresponding clock signal.

Abstract: A Hall sensor has at least four sensor terminals for connecting the Hall sensor and a plurality of Hall sensing element shaving element terminals. The Hall sensing elements are interconnected with the element terminals in a connection grid in between the sensor terminals, the connection having more than one dimension. The Hall sensing elements are physically arranged in an arrangement grid having more than one dimension and being different from the connection grid. At least some of the Hall sensing elements are connected to at least two adjacent Hall sensing elements in the connection grid.

Abstract: The device comprises a bipolar transistor with emitter, base, collector, base-collector junction and base-emitter junction, a collector-to-base breakdown voltage, a quenching component electrically connected with the base or the collector, and a switching circuitry configured to apply a forward bias to the base-emitter junction. The bipolar transistor is configured for operation at a reverse collector-to-base voltage above the breakdown voltage.

Abstract: An apparatus for sensing particulate matter in a fluid includes a first substrate; and a sensing device electrically integrated with the first substrate, the sensing device having a receiving surface. The apparatus includes a second substrate separated from the first substrate by a gap. The apparatus includes a heating element disposed in the gap between the first substrate and the second substrate and connected to the second substrate by a post. The heating element is aligned with the receiving surface of the sensing device, and a microfluidic channel is defined between the first substrate and the heating element.

Abstract: The particle sensor device comprises a substrate, a photodetector, a dielectric on or above the substrate, a source of electromagnetic radiation, and a through-substrate via in the substrate. The through-substrate via is exposed to the environment, in particular to ambient air. A waveguide is arranged in or above the dielectric so that the electromagnetic radiation emitted by the source of electromagnetic radiation is coupled into a portion of the waveguide. A further portion of the waveguide is opposite the photodetector, so that said portions of the waveguide are on different sides of the through-substrate via, and the waveguide traverses the through-substrate via.

Abstract: An apparatus for sensing particulate matter in a fluid includes a substrate; and an integrated circuit electrically connected to the substrate, the integrated circuit including a photodetector. The apparatus includes a filter assembly including a particle filter aligned with the photodetector, and a filter housing for the particle filter, the filter housing defining a flow path for fluid through the particle filter. The apparatus includes a light source electrically connected to the substrate and positioned to illuminate the particle filter.

Abstract: A particulate matter sensor system for sensing particulate matter in a fluid includes a substrate and a cover disposed on the substrate. The cover defines at least a portion of a flow path through the microfluidic system. The sensor system includes a particulate matter sensor disposed in an interior space between the cover and the substrate. The particulate matter sensor includes an integrated sensor device electrically connected to the substrate. The flow path is defined through the particulate matter sensor. The sensor system includes a fluid circulation device disposed in the interior space between the cover and the substrate and configured to cause fluid to flow along the flow path through the microfluidic system.