Abstract: Embodiments of the present disclosure provide stray light filter structures in light detection and ranging (LiDAR) systems to attenuate stray light and reduce unwanted scattering. In some embodiments, a micro lens array is used together with a pinhole array to block stray light in the optical path just prior to the photodetector. In some embodiments, a bandpass optical filter is used in the optical path prior to the microlens array. In other embodiments, a slit filter is used further upstream in the optical path to block unwanted stray light and allow returning signal light to pass to imaging optics that provide a returning signal light image at a photodetector. In some embodiments, the imaging optics include a collimating lens and a focusing lens. In some embodiments, an optical bandpass filter is positioned on the optical path between the collimating lens and the focusing lens to reject light that is outside of a an expected wavelength range for returning signal light.

Abstract: An electromagnetically-moveable scanner device for performing light scan used in a light ranging and detection (LiDAR) system is provided. The device comprises a platform, which comprises a film substrate. The platform is pivotable about an axis. The device further comprises a reflector disposed on the platform, a plurality of magnets disposed in proximity to one or more edges of the film substrate and detached therefrom, and one or more electrical windings installed on the platform. At least a part of the electrical windings is disposed underneath the reflector. When the one or more electrical windings carry electric current, an interaction between magnetic fields formed by the plurality of the magnets and the electrical windings is operative to move the reflector electromagnetically to scan a field-of-view along at least one direction.

Abstract: Methods and systems for image analysis are provided, and in particular for identifying a set of base-calling locations in a flow cell for DNA sequencing. These include capturing flow cell images after each sequencing step performed on the flow cell, and identifying candidate cluster centers in at least one of the flow cell images. Intensities are determined for each candidate cluster center in a set of flow cell images. Purities are determined for each candidate cluster center based on the intensities. Each candidate cluster center with a purity greater than the purity of the surrounding candidate cluster centers within a distance threshold is added to a template set of base-calling locations.

Abstract: A compact perception device for an autonomous driving system is disclosed. The compact perception device includes a lens configured to collect both visible light and near infrared (NIR) light to obtain collected light including collected visible light and collected NIR light. The device further includes a first optical reflector optically coupled to the lens. The first optical reflector is configured to reflect one of the collected visible light or the collected NIR light, and pass the collected light that is not reflected by the first optical reflector. The device further includes an image sensor configured to detect the collected visible light directed by the first optical reflector to form image data; and a depth sensor configured to detect the collected NIR light directed by the first optical reflector to form depth data.

Abstract: A dual emitting co-axial light detection and ranging (LiDAR) system is provided. The LiDAR system comprises a first light source configured to provide a first light beam, a second light source configured to provide a second light beam, a light detector configured to detect return light, one or more optical elements configured to transmit the first light beam to a target in a field of view and to direct return light to the light detector, a first light detector configured to detect the return light and internally-reflected light, a second light detector configured to detect return light formed from the second light beam, and control circuitry configured to mitigate a blind-zone effect based on the detected return light formed from the second light beam. The one or more optical elements are disposed outside of a light path of the second light beam from the second light source.

Abstract: Image data analysis, particularly identifying cluster locations for performing base-calling in a digital flow cell image during DNA sequencing, is described. Each nucleic acid template molecule immobilized on a support may include an insert sequence and a sample index sequence. The sample index sequence may include a k-mer sequence. A sequencing system may conduct k cycles of sequencing reactions of the k-mer sequence before conducting one or more cycles of the insert sequence sequencing reactions and generate a first plurality of flow cell images. Pixel intensities may be determined for pixels of the first plurality of flow cell images. A base calling template may be determined and include base calling locations based on the pixel intensities and respective color purities of the pixel intensities. The base calling template may register a second plurality of flow cell images of the support in one or more cycles subsequent to the k cycles.

Abstract: A compact perception device for an autonomous driving system is disclosed. The compact perception device includes a lens configured to collect both visible light and near infrared (NIR) light to obtain collected light including collected visible light and collected NIR light. The device further includes a first optical reflector optically coupled to the lens. The first optical reflector is configured to reflect one of the collected visible light or the collected NIR light, and pass the collected light that is not reflected by the first optical reflector. The device further includes an image sensor configured to detect the collected visible light directed by the first optical reflector to form image data; and a depth sensor configured to detect the collected NIR light directed by the first optical reflector to form depth data.

Abstract: A system for multimodal detection is provided. The system comprises a light collection and distribution device configured to perform at least one of collecting light signals from a field-of-view (FOV) and distributing the light signals to a plurality of detectors. The light signals have a plurality of wavelengths comprising at least a first wavelength and a second wavelength. The system further comprises a multimodal sensor comprising the plurality of detectors. The plurality of detectors comprises at least a light detector of a first type and a light detector of a second type. The light detector of the first type is configured to detect light signals having a first light characteristic. The light detector of the first type is configured to perform distance measuring based on light signals having the first wavelength. The light detector of the second type is configured to detect light signals having a second light characteristic.

Abstract: Light detection and ranging (LiDAR) systems use light pulses to create an image or point cloud of an environment. This LiDAR system and method having data encoding and compression improves the efficiency and communication reliability of point cloud data using data encoding and compression. After receiving return light pulse reflected by an object in the FOV, the system converts the detected optical signal data into raw data for the purpose of generating trigger data, encoder data, and time synchronization data from the raw data. The system further configures output data in a compressed format using the least amount of bits to carry the same amount of information defining point cloud data describing an external environment and the computational load is reduced. The compressed format comprises a data set for one baseline channel and differential channel data for one or more channels based upon the baseline channel.

Abstract: A fault-detection system for detecting fault in a LiDAR system mounted on a vehicle is provided. The LiDAR system is configured to provide point cloud data of an external environment of the vehicle in accordance with a LiDAR coordinate system. The fault-detection system includes processor-executable instructions which comprise instructions for: obtaining a vehicle speed; obtaining conversion parameters used for converting from the LiDAR coordinate system to a vehicle coordinate system; determining whether the vehicle speed exceeds a vehicle speed threshold; in accordance with a determination that the vehicle speed exceeds the vehicle speed threshold, obtaining a representation of a road surface plane expressed in the vehicle coordinate system; obtaining a representation of a native horizontal plane provided by the vehicle; and determining whether a fault in the LiDAR system has occurred based on the representation of the road surface plane and the representation of the native horizontal plane.

Abstract: An apparatus of a light detection and ranging (LiDAR) scanning system for at least partial integration with a vehicle is disclosed. The apparatus comprises an optical core assembly including an oscillating reflective element, an optical polygon element, and transmitting and collection optics. The apparatus includes a first exterior surface at least partially bounded by at least a first portion of a vehicle roof or at least a portion of a vehicle windshield. A surface profile of the first exterior surface aligns with a surface profile associated with at least one of the first portion of the vehicle roof or the portion of the vehicle windshield. A combination of the first exterior surface and the one or more additional exterior surfaces form a housing enclosing the optical core assembly including the oscillating reflective element, the optical polygon element, and the transmitting and collection optics.

Abstract: A compact LiDAR device is provided. The compact LiDAR device includes a first mirror disposed to receive one or more light beams and a polygon mirror optically coupled to the first mirror. The polygon mirror comprises a plurality of reflective facets. For at least two of the plurality of reflective facets, each reflective facet is arranged such that: a first edge, a second edge, and a third edge of the reflective facet correspond to a first line, a second line, and a third line; the first line and the second line intersect to form a first internal angle of a plane comprising the reflective facet; and the first line and the third line intersect to form a second internal angle of the plane comprising the reflective facet. The first internal angle is an acute angle; and the second internal angle is an obtuse angle.

Abstract: A light detection and ranging (LiDAR) scanning system is provided. The system comprises a light steering device; a galvanometer mirror controllable to oscillate between two angular positions; and a plurality of transmitter channels configured to direct light to the galvanometer mirror. The plurality of transmitter channels are separated by an angular channel spacing from one another. The system further comprises a control device. Inside an end-of-travel region, the control device controls the galvanometer mirror to move based on a first mirror movement profile. Outside the end-of-travel region, the control device controls the galvanometer mirror to move based on a second mirror movement profile. The second mirror movement profile is different from the first mirror-movement profile. Movement of the galvanometer mirror based on the first mirror movement profile facilitates minimizing instances of scanlines corresponding to the end-of-travel region having a pitch exceeding a first target pitch.

Abstract: A compact LiDAR device is provided. The compact LiDAR device includes a first mirror disposed to receive one or more light beams and a polygon mirror optically coupled to the first mirror. The polygon mirror comprises a plurality of reflective facets. For at least two of the plurality of reflective facets, each reflective facet is arranged such that: a first edge, a second edge, and a third edge of the reflective facet correspond to a first line, a second line, and a third line; the first line and the second line intersect to form a first internal angle of a plane comprising the reflective facet; and the first line and the third line intersect to form a second internal angle of the plane comprising the reflective facet. The first internal angle is an acute angle; and the second internal angle is an obtuse angle.

Abstract: A light detection and ranging (LiDAR) system for detecting objects in blind-spot areas is provided. The system comprises a housing, a scanning-based LiDAR assembly disposed in the housing, and a non-scanning-based LiDAR assembly also disposed in the housing. The scanning-based LiDAR assembly is configured to scan a plurality of light beams to illuminate a first field-of-view (FOV). The non-scanning-based LiDAR assembly is configured to transmit laser light to illuminate a second FOV without scanning. The scanning-based LiDAR assembly's detection distance range extends beyond the detection distance range of the non-scanning-based LiDAR assembly.

Abstract: A light detection and ranging (LiDAR) system for detecting objects in blind-spot areas is provided. The system comprises a housing and a scanning-based LiDAR assembly disposed in the housing. The scanning-based LiDAR assembly includes a first light source, a multi-facet polygon, collimation lenses, collection lenses, and a light detector. The first light source is configured to provide a plurality of light beams. The multi-facet polygon is rotatable to scan the plurality of light beams to illuminate an FOV. The multi-facet polygon and the first light source are vertically stacked. The collimation lenses are optically coupled to the first light source, and are configured to collimate the plurality of light beams provided by the first light source. The one or more collection lenses are configured to collect return light generated based on the illumination of the first FOV. The light detector is configured to receive the collected return light.

Abstract: Embodiments discussed herein refer to an integrated mirror motor galvanometer. The integrated mirror motor galvanometer repurposes a rotor of a motor to include at least one mirror face that redirects the light pulses interfacing therewith. This way, when the rotor oscillates along its range of rotation, the at least one mirror face also oscillates.

Abstract: A light detection and ranging system is provided. The system includes a Galvanometer mirror; a multiple-facet light steering device; and a controller device comprising one or more processors, memory, and processor-executable instructions stored in memory. The processor-executable instructions comprise instructions for receiving a first movement profile of the Galvanometer mirror of the LiDAR scanning system; receiving calibration data of the multiple-facet light steering device of the LiDAR scanning system; generating a second movement profile of the Galvanometer mirror based on the calibration data and the first movement profile; and providing one or more control signals to adjust movement of the Galvanometer mirror based on the second movement profile.