Abstract: A two-dimensional VCSEL array may include a VCSEL array including a VCSELs arranged in a two dimensional matrix forming a monolithic structure, a light-emitting surface, and a rear surface, first metal contacts provided on the light-emitting surface; and second metal contacts provided on the rear surface. The VCSELs may be arranged in first lines in a first direction and second lines in a second direction non-parallel to the first direction. Each of the first metal contacts may be electrically connected to each VCSEL of a corresponding first line. Each of the plurality of second metal contacts may be electrically connected to each VCSEL of a corresponding second line. The first metal contacts and second metal contacts may be arranged such that each combination of a first metal contact and a second metal contact is electrically connected to one VSCEL.

Abstract: A user-centric driving-support system for implementation at a vehicle of transportation. The system in various embodiments includes one or more vehicle sensors, such as a camera, a RADAR, and a LiDAR, and a hardware-based processing unit. The system further includes a non-transitory computer-readable storage device including an activity unit and an output-structuring unit. The activity unit, when executed by the hardware-based processing unit, determines, based on contextual input information, at least one of an alert-assessment output and a scene-awareness output, wherein the contextual input information includes output of the vehicle sensor. The output-structuring unit, when executed by the hardware-based processing unit, determines an action to be performed at the vehicle based on at least one of the alert-assessment output and the scene-awareness output determined by the activity unit.

Abstract: A MEMS auto focus miniature camera module includes an image sensor and an optical train including at least one movable lens and one or more fixed lenses or fixed lens groups on either side of the movable lens. The movable lens provides an auto focus feature of the camera module. A MEMS actuator translates the movable lens through an auto focus range to adjust focus.

Abstract: A light sensor includes a primary lens, and a light device spaced from the primary lens. A control structure is disposed between the primary lens and the light device. An actuator is coupled to the control device to move the control device relative to the primary lens and the light device to control the passage of light between the primary lens and the light device. The light sensor may include a light emitting sensor having an array of individual light emitters, or a light detecting sensor having a light detector. The control structure may include an array of secondary bi-telecentric lenses for use with the light emitting sensor, or a plate having an aperture extending therethrough for use with the light detecting sensor.

Abstract: A two-dimensional VCSEL array may include a VCSEL array including a VCSELs arranged in a two dimensional matrix forming a monolithic structure, a light-emitting surface, and a rear surface, first metal contacts provided on the light-emitting surface; and second metal contacts provided on the rear surface. The VCSELs may be arranged in first lines in a first direction and second lines in a second direction non-parallel to the first direction. Each of the first metal contacts may be electrically connected to each VCSEL of a corresponding first line. Each of the plurality of second metal contacts may be electrically connected to each VCSEL of a corresponding second line. The first metal contacts and second metal contacts may be arranged such that each combination of a first metal contact and a second metal contact is electrically connected to one VSCEL.

Abstract: A multi-wavelength array lidar system and a method of designing an array lidar system include arranging a plurality of lasers in an array to transmit a respective plurality of beams, arranging a lens to disperse the plurality of beams at a respective plurality of angles, and arranging a band pass filter to filter a plurality of reflections received at a respective plurality of incident angles resulting from the plurality of beams transmitted by the plurality of lasers at a respective plurality of transmit angles. Selecting a transmit wavelength of each of the plurality of beams is based on the respective plurality of transmit angles to ensure that a receive wavelength of each of the plurality of reflections is within a narrower range than a range of the transmit wavelengths.

Abstract: A LiDAR sensor having particular application for use on a vehicle. The LiDAR sensor includes a plurality of spaced apart VCSEL arrays each including a single lens, where the lens for each VCSEL array directs the beam of the particular laser in the array that is illuminated in a desired direction so that turning on and off of the lasers in each array creates a scanning effect. The number and the size of the VCSEL arrays are selected to provide the desired FOV for the sensor, where the VCSEL arrays can be positioned on a curved platform to provide that FOV. The sensor also includes one or more detectors for detecting reflections of the laser beams emitted by the lasers. Control electronics are provided to scan the laser beams and generate a three-dimensional point cloud of return image points.

Abstract: A MEMS auto focus miniature camera module includes an image sensor and an optical train including at least one movable lens and one or more fixed lenses or fixed lens groups on either side of the movable lens. The movable lens provides an auto focus feature of the camera module. A MEMS actuator translates the movable lens through an auto focus range to adjust focus.

Abstract: A method of performing ranging and detection with an array lidar system and the array lidar system include a first illuminator to transmit a first pseudorandom binary sequence of pulses, the first pseudorandom sequence of pulses resulting in first reflections, and a second illuminator to transmit a second pseudorandom sequence of pulses, the second pseudorandom sequence of pulses being transmitted at least partly concurrently with transmission of the first pseudorandom sequence of pulses, the second pseudorandom sequence of pulses resulting in second reflections. A receiver receives the first reflections and the second reflections and associates the first reflections with the first illuminator based on a result of correlating the first reflections with the first pseudorandom sequence of pulses and a result of correlating the first reflections with the second pseudorandom sequence of pulses, the receiver includes an optical detector array and a processor.

Abstract: An array lidar system on a platform and a method of operating an array lidar system on a platform including a plurality of illuminators in an array transmitting through a lens includes establishing an initial arrangement of the plurality of illuminators among each other and an initial arrangement of the plurality of illuminators relative to the lens to define an initial field of view of the array lidar system. The method also includes controllably changing the initial field of view to a second field of view.

Abstract: An array lidar system and a method of assembling an array lidar system comprising a plurality of illuminators and a plurality of detectors includes designing a plurality of hexagons of a same size such that no gaps remain between adjacent ones of the plurality of hexagons, and designing an arrangement of the plurality of illuminators or the plurality of detectors according to a hexagonal construct, the designing including arranging one or more illuminators of the plurality of illuminators or one or more detectors of the plurality of detectors within respective ones of the plurality of hexagons, wherein the one or more illuminators or the one or more detectors is at a same position within each of the respective ones of the plurality of hexagons. Implementing the design is done by disposing the plurality of illuminators or the plurality of detectors according to the arrangement.

Abstract: An array lidar system on a platform and a method of operating an array lidar system comprising a plurality of illuminators on a platform include controlling a first set of the plurality of illuminators to transmit for a first duration, and controlling a second set of the plurality of illuminators to transmit for a second duration. The method also includes receiving and processing reflections resulting from the first set of the plurality of illuminators and the second set of the plurality of illuminators.

Abstract: A communication system on a platform and a method of performing optical communication using an array lidar system comprising a plurality of illuminators on a platform include transmitting beams from a first set of the plurality of illuminators, receiving reflections resulting from the beams to perform target detection, and transmitting modulated optical signals from a second set of the plurality of illuminators. Receiving the modulated optical signals is done to perform the optical communication.

Abstract: A method of determining a surface condition of a road of travel. A light beam directed at a surface in the road of travel is transmitted utilizing a lidar system. A response is analyzed at a photodetector of the lidar system after transmitting the light beam. A determination is made whether a form of precipitation is present on the road of travel in response to analyzing the response at the photodetector. A precipitation indicating signal is generated in response to the determination that the ground surface includes a form of precipitation on the road of travel.

Abstract: A MEMS auto focus miniature camera module includes an image sensor and an optical train including at least one movable lens and one or more fixed lenses or fixed lens groups on either side of the movable lens. The movable lens provides an auto focus feature of the camera module. A MEMS actuator translates the movable lens through an auto focus range to adjust focus.

Abstract: A method of determining a surface condition of a road of travel. A light beam directed at a surface in the road of travel is transmitted utilizing a lidar system. A response is analyzed at a photodetector of the lidar system after transmitting the light beam. A determination is made whether a form of precipitation is present on the road of travel in response to analyzing the response at the photodetector. A precipitation indicating signal is generated in response to the determination that the ground surface includes a form of precipitation on the road of travel.

Abstract: A MEMS auto focus miniature camera module includes an image sensor and an optical train including at least one movable lens and one or more fixed lenses or fixed lens groups on either side of the movable lens. The movable lens provides an auto focus feature of the camera module. A MEMS actuator translates the movable lens through an auto focus range to adjust focus.

Abstract: A miniature MEMS autofocus camera module includes a MEMS actuated movable lens group and at least one fixed lens group defining an optical axis within a camera module housing. Objects disposed an arbitrary distance from the camera module are automatically focused at a determined zoom to an image sensor. MEMS actuation of the movable lens group is performed to accomplish autofocus functionality.

Abstract: Provided is a method for determining one or more kinetic parameters of binding between a first binding member and a second binding member. The method includes adsorbing the first binding member to a surface at a plurality of microspots. The second binding member is then presented to the first binding member at each of the microspots, there being a plurality of combinations of first binding member surface density and second binding member concentration among the plurality of microspots. Data indicative of a binding reaction between the first of microspots are then obtained and analyzed so as to obtain one or more kinetic parameters of the binding between the first and second binding members. Also provided is a system for carrying out the method. A method for localizing a molecular species at microspots on a surface, and a probe array produced by the method are also provided.

Abstract: A LiDAR sensor having particular application for use on a vehicle. The LiDAR sensor includes a plurality of spaced apart VCSEL arrays each including a single lens, where the lens for each VCSEL array directs the beam of the particular laser in the array that is illuminated in a desired direction so that turning on and off of the lasers in each array creates a scanning effect. The number and the size of the VCSEL arrays are selected to provide the desired FOV for the sensor, where the VCSEL arrays can be positioned on a curved platform to provide that FOV. The sensor also includes one or more detectors for detecting reflections of the laser beams emitted by the lasers. Control electronics are provided to scan the laser beams and generate a three-dimensional point cloud of return image points.