Abstract: An optoelectronic semiconductor chip is disclosed. In an embodiment the optoelectronic semiconductor chip includes a semiconductor body of semiconductor material, a p-contact layer and an n-contact layer. The semiconductor body includes an active layer intended for generating radiation. The semiconductor body includes a p-side and an n-side, between which the active layer is arranged. The p-contact layer is intended for electrical contacting the p-side. The n-contact layer is intended for electrical contacting the n-side 1b. The n-contact layer contains a TCO layer and a mirror layer, the TCO-layer being arranged between the n-side of the semiconductor body and the mirror layer.

Abstract: An optoelectronic semiconductor component and a method for producing the same are disclosed. In an embodiment the semiconductor component includes a semiconductor chip, which emits electromagnetic radiation of a first wavelength range from a radiation emission surface. The semiconductor component further includes a first conversion layer located on a lateral flank of the semiconductor chip, wherein the first conversion layer is suitable for converting electromagnetic radiation of the first wavelength range into electromagnetic radiation of a second wavelength range, and a second conversion layer located on the radiation emission surface of the semiconductor chip, wherein the second conversion layer is suitable for converting electromagnetic radiation of the first wavelength range into electromagnetic radiation of the second or of a third wavelength range. The first conversion layer is different from the second conversion layer.

Abstract: An optoelectronic assembly includes at least one first component that emits first electromagnetic radiation and at least one first photosensitive component that controls the first component. The first photosensitive component connects in parallel to the first component and has a first radiation-sensitive region in a beam path of the first electromagnetic radiation.

Abstract: An optoelectronic semiconductor chip includes a carrier and a semiconductor body having an active layer that generates electromagnetic radiation, wherein the semiconductor body is arranged on the carrier, the semiconductor body has a first main surface facing away from the carrier and a second main surface facing the carrier, the semiconductor chip has a side surface having an anchoring structure, and the second main surface is arranged between the first main surface and the anchoring structure.

Abstract: Aspects of the present disclosure include methods and systems for commissioning and authenticating devices for joining a local network that improve the security of the network and make it more difficult for unauthorized devices to gain access to the network. In some examples, communication channels that have a more limited range and direction as compared to radio frequency communication are employed for exchanging information to join the network, such as cryptographic keys. The communication channels may include acoustic or optical channels. In some examples, techniques for deriving temporary and/or dynamic keys are disclosed.

Abstract: An optical sensor that captures a heart rate and/or a blood oxygen content includes a light source including a light emittor that emits electromagnetic radiation with a first wavelength range including green light, a second wavelength range including red light and a third wave-length range including infrared radiation, and three light detectors, each including a filter for electromagnetic radiation, wherein a first filter is transmissive for light of the first wavelength range and non-transmissive for light of the second wavelength range and the infrared radiation of the third wavelength range, a second filter is transmissive for light of the second wavelength range and non-transmissive for light of the first wavelength range and the infrared radiation of the third wavelength range and a third filter is transmissive for the infrared radiation of the third wavelength range and non-transmissive for light of the first and the second wavelength range.

Abstract: A light-emitting diode includes an optoelectronic semiconductor chip that emits electromagnetic radiation through a radiation side along a main direction of emission running transversely to the radiation side during operation, the semiconductor chip is embedded in a solid body, wherein side surfaces and the radiation side are covered by the solid body in a form-fit manner, the solid body widens along the main direction of emission, a cover element is arranged downstream of the solid body in the main direction of emission and is applied directly onto the solid body, a side of a cover element facing away from the solid body is formed as a radiation exit surface of the light-emitting diode, and a first contact element is exposed in an unmounted and/or non-contacted state of the light-emitting diode.

Abstract: An irradiation apparatus includes a radiation unit for the emission of radiation in the form of a beam, a first microlens arrangement, downstream of the radiation unit, having a multiplicity of convergent microlenses, for dividing the beam into one partial beam per convergent microlens, and a convergent lens, downstream of the microlens arrangement, that overlays the partial beams, in an irradiated area. The microlenses have a first group and a second group. The microlenses in each group are identical, but the microlenses in the first group differ from the microlenses in the second group from their shape, size and/or focal length, so that a first region of the irradiated area, which is irradiated via the microlenses in the first group, differs from a second region of the irradiated area, which is irradiated by the microlenses in the second group, from its shape and/or its size.

Abstract: What is specified is: an optoelectronic semiconductor component (1) comprising a carrier (5) and a semiconductor body (2), wherein the semiconductor body is fastened on the carrier and has a semiconductor layer sequence having an active region (20) provided for generating and/or receiving radiation, a first semiconductor layer (21) and a second semiconductor layer (22). The active region is arranged between the first semiconductor layer and the second semiconductor layer. The carrier is electrically conductive and is divided into a first carrier body (51) and a second carrier body (52), wherein the first carrier body and the second carrier body are electrically insulated from one another. The first carrier body has a first external contact (61) of the semiconductor component on the side remote from the semiconductor body, wherein the first contact is electrically conductively connected to the first semiconductor layer via the first carrier body.

Abstract: A quantum dot includes a nanocrystalline core and an alloyed nanocrystalline shell made of a semiconductor material composition different from the nanocrystalline core. The alloyed nanocrystalline shell is bonded to and completely surrounds the nanocrystalline core.

Abstract: A leadframe includes first and second parts separated from each other, and each comprises at least one anchoring hole. The first part comprises a mounting area, the second part comprises an edge line facing the first part which is curved, and the first part comprises first, second and third portions each having a maximum width, wherein the mounting area is arranged at the third portion, and the third portion follows the second portion and the second portion follows the first portion in a direction of a longitudinal extent of the first part such that the third portion faces the second part.

Abstract: Techniques are disclosed for projecting visible cues to assist with light-based communication (LCom), the visible cues referred to herein as visual hotspots. The visual hotspots can be projected, for example, using a luminaire that may be LCom-enabled. The visual hotspots may be projected onto the floor of an area including an LCom system. The visual hotspots can be used for numerous benefits, including alerting a potential user that LCom is available, educating the user about LCom technology, and assisting the user in using the LCom signals available in the area. The visual hotspots may include images, symbols, cues, characters (e.g., letters, words, numbers, etc.), indicators, logos, or any other suitable content. In some cases, the visual hotspots may be interactive, such that a user can scan the hotspot to cause an action to occur (e.g., launch an application or website).

Abstract: According to the present disclosure, a method for operating an illumination apparatus is provided. The method has at least two light-emitting devices, which are arranged next to one another separated by a gap and each have a multiplicity of light-emitting elements, by individually driving all light-emitting elements of each light-emitting device, measuring a gap width of the gap and/or a luminance in the gap, and controlling or regulating in each case a luminance of one or more of the light-emitting elements which are arranged directly at the gap in dependence on the gap width and/or on the luminance in the gap.

Abstract: Various embodiments relate to an irradiation device including a pump radiation source for emitting pump radiation, a conversion element for converting the pump radiation into conversion radiation of longer wavelength, and a reflection surface, which is reflective to the conversion radiation and on which backscattered conversion radiation emitted at a backscatter emission surface and thus counter to a useful direction is incident and is reflected therefrom back to the conversion element; said reflection surface is concavely curved relative to the conversion element in such a way that at least the backscattered conversion radiation emitted divergently from a surface centroid of the backscatter emission surface is incident on the reflection surface at an angle of incidence of at most 20° in terms of absolute value.

Abstract: A method for producing optoelectronic semiconductor devices and an optoelectronic semiconductor device are disclosed. In an embodiment, the method includes providing a plurality of semiconductor chips for producing electromagnetic radiation, arranging the plurality of semiconductor chips in a plane, forming a housing body composite, at least some regions of which are arranged between the semiconductor chips, forming a plurality of conversion elements, wherein each conversion element comprises a wavelength-converting conversion material and is arranged on one of the semiconductor chips, encapsulating the plurality of conversion elements at least on their lateral edges by an encapsulation material, and separating the housing body composite into a plurality of optoelectronic semiconductor components.

Abstract: Techniques are disclosed for enhancing indoor navigation using light-based communication (LCom). In some embodiments, an LCom-enabled luminaire configured as described herein may include access to a sensor configured to detect a given hazardous condition. In response to detection of a hazard, the LCom-enabled luminaire may adjust its light output, transmit an LCom signal, or both, in accordance with some embodiments. A given LCom signal may include data that may be utilized by a recipient computing device, for example, in providing emergency evacuation routing or other indoor navigation with hazard avoidance, emergency assistance, or both. In a network of such luminaires, data distribution via inter-luminaire communication may be provided, in accordance with some embodiments, via an optical interface or other wired or wireless communication means. In some cases, the network may include a luminaire that is not LCom-enabled yet still configured for inter-luminaire communication.

Abstract: Systems, methods, and software for determining whether or not a monitored space is occupied by one or more humans and/or animals. In some embodiments, one or more radio-frequency (RF) receivers monitor(s) one or more RF frequencies for changes in received signal strength that may be due to changes in occupancy of the space being monitored. The received signal strength is analyzed using nonparametric online change-point detection analysis to determine change-points in the received signal(s). One or more statistical measures of the received signal(s), such as mean and variance, are used in conjunction with the change-point detection to determine a probability that the occupancy of the monitored space has changed. In some embodiments, additional sensors and/or machine learning can be used to enhance the performance of the disclosed occupancy-detection methodologies.

Abstract: A lighting assembly, comprising: a casing having a bowl-like structure with a bottom wall defining a window opening; a radiation source board with a light radiation source situated opposite said opening so as direct said light radiation outside of the casing; and a driving circuit board for said radiation source, said boards being stacked together without air gaps in between, with said circuit board directed towards said casing.

Abstract: A circuit arrangement for operating at least a first and a second cascade of LEDs is provided including an input having a first and a second input connection for coupling to a rectified AC supply voltage, a voltage equalization series impedance, and at least a higher and a lower LED units which include cascades. The connection of the LED cascade that is not coupled to a first diode is a second node, and the second node of the lowest LED unit is coupled to a voltage equalization series impedance such that the impedance is coupled in series between the second node and the second input connection. In not-the-lowest LED unit, a fourth node is at any rate a node of the circuit arrangement that is at a lower potential, at least during a prescribable period during the circuit arrangement operation, than the second node.

Abstract: A support structure for lighting devices, the support structure includes a ribbon-like support member with electrically conductive lines with mounting locations for electrically powered light radiation sources. The structure includes a sequence of adjacent units having opposed end regions and is severable between mutually facing end regions of adjacent units in the sequence. The units include, at the end regions, at least one electrical connection formation. The electrical connection formation includes a proximal portion electrically coupled to the electrically conductive lines of the respective unit, and a distal portion electrically insulated from the proximal portion. The distal portion is electrically coupled to the distal portion of an electrical connection formation provided in an adjacent unit to the respective unit in the sequence of adjacent units and is separable therefrom by severing the support structure.