An optical micro-electromechanical system (MEMS) system is disclosed. The optical MEMS system includes a printed circuit board (PCB), and a MEMS optical integrated circuit (IC) package mounted to the PCB. The IC package includes a MEMS optical die, and a plurality of leads electrically and mechanically connected to the MEMS optical die and to the PCB. The optical MEMS system also includes one or more elastomeric grommets contacting one or more of the leads, where the grommets are configured to absorb mechanical vibration energy from the contacted leads.

A system and method detects an obstruction in the path of a vehicle access control member moving from an open position to a closed position. The method includes transmitting a detection signal along an edge of the member towards a reflective surface mounted on the member. The detection signal includes a sequence of pulses having different amplitudes with the amplitudes varying linearly moving from a first pulse to a final pulse of the sequence of pulses. The method further includes receiving a detection response signal corresponding to the detection signal following reflection of the detection signal by one of the reflective surface and the obstruction. The detection response signal includes another sequence of pulses and the method further includes generating an obstruction signal indicating whether the obstruction is in the path of the access control member responsive to differences in amplitude between adjacent pulses in the sequence of pulses.

A system and method using a single-minor micro-electro-mechanical system (MEMS) two-dimensional (2D) scanning mirror assembly, and/or a digital micromirror device (DMD having a plurality of independently steerable minors) for steering a plurality of light beams that include one or more light beam(s) for the headlight beam(s) of a vehicle and/or one or more light beam(s) for LiDAR purposes, along with highly effective associated devices for light-wavelength conversion, light dumping and heatsinking. Some embodiments include a digital camera, wherein image data from the digital camera and distance data from the LiDAR sensor are combined to provide information used to control the size, shape and direction of the smart headlight beam.

A method for detecting objects using a LIDAR system may include controlling a light emission assembly comprising a light source in a manner enabling spatial light modulation to a field of view (FOV) of the LIDAR system to vary during different flash light emissions of the light emission assembly. The method may also include controlling a sensor to detect first reflection signals indicative of reflections of first flash light emissions from objects in the FOV. The method may further include determining a nonuniform spatial light modulation for the light emission assembly based on at least one of the first reflection signals. The method may also include instructing the light emission assembly to emit to the FOV a second flash light emission in accordance with the nonuniform spatial light modulation, and detecting an object in the FOV based on second reflection signals of the second flash light emission.

A method for detecting objects using a LIDAR system may include controlling a light emission assembly comprising a light source in a manner enabling spatial light modulation to a field of view (FOV) of the LIDAR system to vary during different flash light emissions of the light emission assembly. The method may also include controlling a sensor to detect first reflection signals indicative of reflections of first flash light emissions from objects in the FOV. The method may further include determining a nonuniform spatial light modulation for the light emission assembly based on at least one of the first reflection signals. The method may also include instructing the light emission assembly to emit to the FOV a second flash light emission in accordance with the nonuniform spatial light modulation, and detecting an object in the FOV based on second reflection signals of the second flash light emission.

A sensor assembly including a sensor, a sensor housing that carries the sensor, a mounting member that pivotally engages with the sensor housing, an adjustment member for selecting an angular position of the sensor housing relative to the mounting member, and a locking mechanism for locking the sensor housing at the selected angular position relative to the mounting member. The adjustment member is moveable relative to the mounting member between a first location and a second location, and engages with the sensor housing to pivot the sensor housing about a pivot axis relative to the mounting member between a first angular position and a second angular position.

One example provides a method of operating a time-of-flight camera system comprising an illumination source and an image sensor. The method comprises operating the illumination source and the image sensor to control a plurality of integration cycles and a plurality of readout cycles. In each integration cycle, the method comprises performing a plurality of pulse width modulated (PWM) illumination cycles where each PWM illumination cycle is separated from one or more adjacent PWM illumination cycles by a non-illumination cycle. For each PWM illumination cycle, the method comprises directing photocharge to in-pixel memory for each pixel that is performing image integration and for each non-illumination cycle conducting photocharge away from the in-pixel memory for each pixel that is performing image integration. The readout cycle comprises, for each pixel that performed image integration, reading a charge stored in the in-pixel memory after the integration cycle.

Super resolution and color motion artifact correction in a pulsed hyperspectral, fluorescence, and laser mapping imaging system. A method includes actuating an emitter to emit pulses of electromagnetic radiation and sensing reflected electromagnetic radiation with a pixel array of an image sensor. The method includes detecting motion across two or more sequential exposure frames, compensating for the detected motion, and combining the two or more sequential exposure frames to generate an image frame. The method is such that at least a portion of the pulses of electromagnetic radiation emitted by the emitter comprises one or more of: electromagnetic radiation having a wavelength from about 513 nm to about 545 nm, from about 565 nm to about 585 nm, from about 900 nm to about 1000 nm, an excitation wavelength of electromagnetic radiation that causes a reagent to fluoresce, or a laser mapping pattern.

A time-of-flight imaging device comprises an image sensor comprising a pixel array including a plurality of pixel circuits, respective ones of the plurality of pixel circuits including a first tap output configured to output a first tap signal, and a second tap output configured to output a second tap signal; and a signal processing circuit including a time-of-flight processing circuit configured to perform at least one logical operation on the first tap signal and the second tap signal based on a mode of the signal processing circuit, and a counter configured to output a digital signal based on an output of the time-of-flight processing circuit.

Embodiments of the disclosure provide an interface module for a LiDAR assembly. The interface module includes a printed circuit board (PCB) and a first connector interface disposed on the PCB. The first connector interface is configured to be connectable to a laser emitter of the LiDAR assembly. The interface module further includes a second connector interface disposed on the PCB and a third connector interface disposed on the PCB. The second connector interface is configured to be connectable to a receiver of the LiDAR assembly and the third connector interface is configured to be connectable to a control module configured to control the operation of the laser emitter and the receiver. The interface module also includes a bracket where the PCB is affixed to. The interface module is positioned to a lateral face of the LiDAR assembly through the bracket.