A light-emitting device includes a wiring substrate, a base member provided on the wiring substrate, a light-emitting element array that has a first side surface and a second side surface facing each other, that has a third side surface and a fourth side surface facing each other and connecting the first side surface and the second side surface, and that is provided on the base member, a drive unit that is provided on the wiring substrate at a side of the first side surface and drives the light-emitting element array, a first circuit element that is provided on the base member at the side of the first side surface, a second circuit element that is provided on the base member at a side of the second side surface and has a larger occupation area on the base member than the first circuit element, and wiring members that are provided at a side of the third side surface and at a side of the fourth side surface and extend from an upper surface electrode of the light-emitting element array toward an outer side of the light-emitting element array.

Disclosed herein are examples of ladar systems and methods where data about a plurality of ladar returns from prior ladar pulse shots gets stored in a spatial index that associates ladar return data with corresponding locations in a coordinate space to which the ladar return data pertain. This spatial index can then be accessed by a processor to retrieve ladar return data for locations in the coordinate space that are near a range point to be targeted by the ladar system with a new ladar pulse shot. This nearby prior ladar return data can then be analyzed by the ladar system to help define a shot energy for use by the ladar system with respect to the new ladar pulse shot.

A roof module for forming a vehicle roof on a motor vehicle, the roof module having a panel component, which at least partially forms a roof skin of the vehicle roof, the roof skin serving as an outer sealing surface of the roof module, at least one electrical and/or electronic and/or electromagnetic component, in particular an environment sensor and/or a light feature, configured to send and/or receive electromagnetic signals through a see-through area, and at least one cleaning feature having at least one cleaning nozzle configured to spray a cleaning fluid by means of which the see-through area is cleanable. The at least one component is in heat-transferring connection with the cleaning feature in such a manner that waste heat of the at least one component can be transferred to the cleaning fluid and/or the at least one cleaning nozzle.

Embodiments describe a solid state electronic scanning LIDAR system that includes a scanning focal plane transmitting element and a scanning focal plane receiving element whose operations are synchronized so that the firing sequence of an emitter array in the transmitting element corresponds to a capturing sequence of a photosensor array in the receiving element. During operation, the emitter array can sequentially fire one or more light emitters into a scene and the reflected light can be received by a corresponding set of one or more photosensors through an aperture layer positioned in front of the photosensors. Each light emitter can correspond with an aperture in the aperture layer, and each aperture can correspond to a photosensor in the receiving element such that each light emitter corresponds with a specific photosensor in the receiving element.

Systems and methods are provided to analyze at least one sensor of a computing device to determine that the computing device is in a substantially flat position on the first surface, activate a camera comprising a depth sensor, and detect a second surface in a camera view of the camera. The computing device further analyzes pixel measurements from the depth sensor in a predefined area of the detected second surface to determine a minimum measurement of all of the pixel measurements in the predefined area of the detected surface, causes display of the minimum measurement from the first surface to the second surface overlaid on an image of the first and second surface in the camera view on a user interface of the computing device, and captures an image of the display.

An image sensing device includes a substrate including a back side structured to receive incident light and a front side opposite to the back side; imaging pixels to receive the incident light from the back side and each imaging pixel structured to produce photocharge in response to received incident light; a plurality of conductive contact structures configured to generate a potential gradient in the substrate and to capture photocharges that are generated in response to the incident light and move by the potential gradient; and a well region disposed between the plurality of conductive contact structures.

Embodiments are directed toward measuring a three dimensional range to a target. A transmitter emits light toward the target. An aperture may receive light reflections from the target. The aperture may direct the reflections toward a sensor that comprises rows of pixels that have columns. The sensor is offset a predetermined distance from the transmitter. Anticipated arrival times of the reflections on the sensor are based on the departure times and the predetermined offset distance. A portion of the pixels are sequentially activated based on the anticipated arrival times. The target's three dimensional range measurement is based on the reflections detected by the portion of the pixels.

The present disclosure relates to limitation of noise on light detectors using an aperture. One example implementation includes a system. The system includes a lens that focuses light from a scene toward a focal plane. The system also includes an aperture defined within an opaque material. The system also includes a plurality of waveguides. A given waveguide of the plurality has an input end that receives a portion of light transmitted through the aperture, and guides the received portion toward an output end of the given waveguide. A cross-sectional area of the guided portion at the output end is greater than a cross-sectional area of the received portion at the input end. The system also includes an array of light detectors that detects the guided light transmitted through the output end.

The present disclosure relates to limitation of noise on light detectors using an aperture. One example implementation includes a system. The system includes a lens that focuses light from a scene toward a focal plane. The system also includes an aperture defined within an opaque material. The system also includes a plurality of waveguides. A given waveguide of the plurality has an input end that receives a portion of light transmitted through the aperture, and guides the received portion toward an output end of the given waveguide. A cross-sectional area of the guided portion at the output end is greater than a cross-sectional area of the received portion at the input end. The system also includes an array of light detectors that detects the guided light transmitted through the output end.

A method of establishing a communication channel includes receiving sensor data characterizing measurements associated with a target object. The method includes determining, based on the sensor data, an objective from a plurality of predefined objectives for monitoring the target object. The method includes computing, based on the determined objective, a communication channel associated with the target object. The method includes providing the communication channel. Related apparatus, systems, techniques, and articles are also described.