Abstract: Systems and methods are provided for the realistic simulation of distributed systems, such as vehicle-based processing systems. A statistical property of message timestamps of a plurality of prior messages from one or more recorded processes is determined. During a simulation, messages that are generated are associated with timing data based on the statistical property from the recorded processes.

Abstract: The present disclosure relates to systems and methods for autonomous driving. The systems may obtain driving information associated with a vehicle; determine a state of the vehicle; determine one or more candidate control signals and one or more evaluation values corresponding to the one or more candidate control signals based on the driving information and the state of the vehicle by using a trained control model; select a target control signal from the one or more candidate control signals based on the one or more evaluation values; and transmit the target control signal to a control component of the vehicle.

Abstract: Apparatuses and methods for controlling a micro-mirror are provided. In one example, a controller is coupled with a micro-mirror assembly comprising a micro-mirror, an actuator, and a sensor. The controller is configured to: receive a reference signal including information of a target oscillatory rotation of the micro-mirror; receive, from the sensor, the measurement signal of an oscillatory rotation of the micro-mirror; determine, based on the measurement signal and the information included in the reference signal, a difference between the oscillatory rotation of the micro-mirror and the target oscillatory rotation; receive an input control signal; generate, based on the difference and the input control signal, an output control signal to control at least one of a phase or an amplitude of the oscillatory rotation of the micro-mirror; and transmit the output control signal to the actuator.

Abstract: Embodiments of the disclosure provide a Light Detection and Ranging system. The system may include a light source configured to emit a light beam, a first apparatus configured to adjust the light beam and a second apparatus configured to adjust the light beam and receive the reflected light beam from a first rotatable mirror. The first apparatus may include the first rotatable mirror configured to receive and reflect the light beam, and a first actuator configured to rotate the first rotatable mirror. The second apparatus may include a second adjustable mirror configured to receive and propagate the light beam, a second actuator configured to adjust the second adjustable mirror, and a detector configured to receive the light beam reflected by the object. The first rotatable mirror is further configured to receive and reflect the light beam reflected by the object to the detector.

Abstract: Embodiments of the disclosure provide a packaged micro-mirror for an optical sensing system. In some embodiments, the packaged micro-mirror may include a package substrate. In some embodiments, the packaged micro-mirror may include a micro-mirror die attached to the package substrate through a first die attach material and a second die attach material. In some embodiments, the first die attach material may have a first Young’s modulus and the second die attach material may have a second Young’s modulus higher than the first Young’s modulus. In some embodiments, at least one of the first die attach material or the second die attach material may be a conductive adhesive forming an electrical connection between the micro-mirror die and package substrate.

Abstract: Embodiments of the disclosure provide a micromachined mirror assembly for controlling optical directions in an optical sensing system. The micromachined mirror assembly may include a micro mirror configured to direct an optical signal into a plurality of directions. The micromachined mirror assembly may also include at least one actuator coupled to the micro mirror and configured to drive the micro mirror to tilt around an axis. The micromachined mirror assembly may further include one or more objects attached to the micro mirror. The one or more objects may be asymmetrically disposed with respect to the axis to create an imbalanced state of the micro mirror when the micro mirror is not driven by the at least one actuator.

Abstract: Embodiments of the disclosure provide a receiver in an optical sensing system. The exemplary receiver includes a movable detector configured to receive optical signals reflected or scattered from an object scanned by the optical sensing system. The receiver further includes an actuator configured to move the movable detector. The receiver also includes a controller configured to determine a plurality of target positions of the movable detector for receiving the optical signals. The controller is further configured to control the actuator to move the movable detector to the plurality target positions according to a movement pattern.

Abstract: A light detection and ranging system include a chassis and a galvo mirror assembly. The galvo mirror assembly includes a mirror holder including a handle and a galvo mirror for receiving and reflecting a light beam; a galvo mirror mount detachably mounted on the chassis and including a recess for receiving the handle of the mirror holder; two elastic members coupled to the handle of the mirror holder and the galvo mirror mount; two set screws in contact with the handle of the mirror holder and at least partially in the galvo mirror mount; and a galvo motor in the galvo mirror mount and configured to rotate the mirror holder. The two set screws are individually adjustable to change a compression force applied to at least one of the two elastic members and a tilt angle of the mirror holder (and the galvo mirror) with respect to a vertical direction.

Abstract: A method of communicating messages between modules in a system on a vehicle, each module configured as a publisher node and/or subscriber node, the publisher nodes and the subscriber nodes collectively forming a plurality of nodes that communicate in the operation of the vehicle. One method includes communicating, by a subscriber node, with a registry for information to determine if a new message associated with a first topic is available for reading, determining, by each subscriber node, if a new message associated with the first topic is available for reading, in response to determining a new message associated with the first topic is available for reading, reading from the registry location information indicating where the first message is stored in a first message buffer, and reading, by each subscriber node the first message from the first message buffer using the location information.

Abstract: Embodiments of the disclosure provide systems and methods for incorporating an optical sensing system in a MEMS package for real-time sensing of angular position of a MEMS mirror. The system may include an optical source configured to emit an optical signal to a backside of the MEMS mirror. The system may also include an optical detector configured to receive a returning optical signal reflected by the backside of the MEMS mirror. The system may further include at least one controller. The at least one controller may be configured to determine a scanning angle of the MEMS mirror based on a position on the optical detector where the returning optical signal is received.

Abstract: A method for designing an optical scanning mirror is provided. The method may include receiving, by a communication interface, a set of design parameters of the scanning mirror. The method may also include simulating scanning mirror oscillation, by at least one processor, based on the set of design parameters using a computer model. In certain aspects, the computer model may include a lookup table that correlates electrostatic force applied to a sample scanning mirror and angular displacement in the sample scanning mirror caused by the electrostatic force. The method may further include generating, by the at least one processor, mirror oscillation data as an output of the computer model for designing the scanning mirror. The mirror oscillation data may include a correlation of drive frequency, angular displacement, and time.

Abstract: Embodiments of the disclosure provide a system for controlling an emission of laser beams using a plurality of scanning patterns by an optical sensing device. The plurality of scanning patterns interleavingly cover a field of view of the optical sensing device. The system includes a controller that is configured to detect an object within a functional distance range from the optical sensing device based on a reflected first laser beam received by the optical sensing device. The first laser beam is emitted towards a first scanning point in a first scanning pattern. The controller is also configured to determine an aperture extending from the first scanning point, and control the optical sensing device to emit a second laser beam towards a second scanning point in a second scanning pattern and skip the scanning points between the first scanning point and the second scanning point in the aperture.

Abstract: Embodiments of the disclosure provide an optical sensing device for a receiver in an optical sensing system. The optical sensing device includes a light concentrator configured to collect a light beam. The light concentrator includes an input aperture configured to collect the light beam, an output aperture configured to output the light beam, and a side surface in contact with the input aperture and the output aperture. The side surface is configured to reflect the collected light beam towards the output aperture. The optical sensing device also includes a photodetector placed behind the light concentrator. The photodetector is configured to receive the light beam collected through the output aperture and convert the light beam to an electrical current.

Abstract: Embodiments of the disclosure provide methods for microfabricating an omni-view peripheral scanning system. One exemplary method may include separately fabricating a reflector and a scanning MEMS mirror, and then bonding the microfabricated reflector with the scanning MEMS mirror to form the omni-view peripheral scanning system. The microfabricated reflector may include a cone-shaped bottom portion, and a via hole across the cone-shaped bottom portion. The microfabricated scanning MEMS mirror may include a MEMS actuation platform and a scanning mirror supported by the MEMS actuation platform. The scanning MEMS mirror may face the cone-shaped bottom portion of the reflector when forming the omni-view peripheral scanning system.

Abstract: Embodiments of the disclosure provide a transmitter containing an omni-view peripheral scanning system, an omni-view peripheral scanning system, and an optical sensing method. The optical sensing system includes an optical source configured to sequentially emit optical signals. The optical sensing system further includes an omni-view peripheral scanning system configured to receive the optical signals and sequentially direct the optical signals towards an environment following a peripheral scanning pattern. The peripheral scanning system may include a scanning mirror and a top reflector. Each optical signal may pass through the top reflector towards the scanning mirror, where the scanning mirror is configured to reflect the optical signal back onto the top reflector following a spiral pattern and the top reflector is configured to direct the optical signal towards the environment.

Abstract: Embodiments of the disclosure provide an optical sensing system containing a conical lens pair, and an optical sensing method using the same. For example, the optical sensing system includes a transmitter configured to emit an optical signal toward an environment surrounding the optical sensing system. The transmitter includes a laser emitter configured to emit the optical signal, a beam shaper configured to receive the optical signal emitted by the laser emitter and redistribute a light intensity of the received optical signal away from a center of the optical signal, and a steering device configured to receive the redistributed optical signal output from the beam shaper and direct the redistributed optical signal toward the environment. The optical sensing system further includes a receiver configured to receive the optical signal returning from the environment.

Abstract: Embodiments of the disclosure provide a method for forming an optical sensing device for a receiver in an optical sensing system. According to the method, a light concentrator is formed in a carrier wafer. The carrier wafer is bonded with a detector wafer. The detector wafer has a photodetector such that the light concentrator aligns with and covers the photodetector. A portion of the carrier wafer is removed to expose the light concentrator and the photodetector.

Abstract: Embodiments of the disclosure provide an optical sensing system for two-dimensional (2D) environmental sensing, an optical sensing method for the optical sensing system, and a transmitter. The optical sensing system includes a tunable laser source configured to emit optical signals with varying wavelengths. The optical sensing system further includes a one-dimensional (1D) grating scanner configured to rotate around a rotational axis to scan the optical signals with the varying wavelengths in a first dimension towards an environment surrounding the optical sensing system. The 1D grating scanner includes a grating structure configured to scan the optical signals with the varying wavelengths along different directions in a second dimension towards the environment at each rotation angle. The optical sensing system additionally includes a receiver configured to receive at least a portion of the optical signals with the varying wavelengths reflected from the environment.

Abstract: A light detection and ranging receiver includes a carrier frame, a lens assembly, a first set of screws, and a light sensor assembly mounted on the carrier frame. The lens assembly includes a lens holder mounted on the carrier frame by a first set of elastic connectors attached to the carrier frame and the lens holder, and a lens installed on the lens holder. The light sensor assembly is configured to both rotate and linearly move with respect to the carrier frame, and includes a board mount and a sensor board installed on the board mount. The first set of screws are in contact with the lens holder, and are adjustable to change a distance and/or an orientation of the lens holder with respect to the carrier frame such that the lens may form an image on a predetermined area on the sensor board.

Abstract: Embodiments of the disclosure provide a system for controlling an emission of laser beams by an optical sensing device. The system includes a controller configured to detect an object within a field of view based on a laser beam reflected by the object and received by the optical sensing device. The laser beam is emitted at a current scanning point according to a first laser emission scheme. The controller is also configured to determine a distance of the object from the optical sensing device. The controller is further configured to, in response to the distance being within a functional distance range, control the optical sensing device to emit laser beams according to a second laser emission scheme towards an aperture extending from the current scanning point. The second laser emission scheme reduces a number of scanning points in the aperture compared to the first laser emission scheme.