Abstract: In one embodiment, described herein is an apparatus for projecting linear illumination fanned out along the slow axis of a laser source array. In addition to the laser source array, the apparatus can include a number of fast axis collimators (FACs) to collimate the laser beams from the laser source array along the fast axis, a cylinder lens array for converting the collimated laser beams to parallel laser beams, and a prism array pair for reducing the pitch of the parallel laser beams. The system further includes a first cylinder lens for focusing the laser beams from the prism array pair onto a MEMS mirror, which redirects the laser beams as a linear laser beam towards a predetermined direction.

Abstract: Embodiments of the invention disclose devices, methods, and computer media for noise rejections in a remote sensing device, such as a LIDAR device. In an exemplary embodiment, a spatial filter includes an aperture dynamically created in synchronization with one or more directions in which emitted laser pulses from the LiDAR device are steered. Photons from all other directions except the one or more directions are blocked by the spatial filter. Reflected photons from the one or more directions pass through the spatial filter via the aperture, and are projected on one or more sets of photodetectors. Noises in the photons that pass through the spatial filter are further to be rejected based on one or more fixed temporal patterns identified in laser pulses emitted by the LiDAR device. The spatial filter can be implemented using an electrochromic display, an array of micromechanical (MEMS) mirrors, a liquid crystal display (LCD), or an electro-wetting display.

Abstract: In one embodiment, a chip-scale LiDAR device can include a chip with three layers. The first layer includes a number of micromechanical system (MEMS) mirrors. The second layer includes a laser source; a beam splitter connected to the laser source; a number of waveguides, each connected to the beam splitter; and a number of beam deflectors, each beam deflector coupled with one of the number of waveguides. The third layer includes a receiving unit for receiving and processing reflected laser signals of one or more laser beams from the laser source. The first layer, the second layer, and the third layer are vertically attached to each other using either wafer bonding and/or solder bonding.

Abstract: An imaging-assisted angular calibration method comprises receiving an image of a spatial resolution chart on a flat board, the image taken by a camera positioned at a predetermined distance from the spatial resolution chart; determining an angular resolution of the camera based on the image of the spatial resolution chart and the predetermined distance; and receiving an image of laser spots in a raster scan pattern incident on the flat board, the laser spots emitted from a LiDAR device positioned at the predetermined distance from the flat board, the raster scan pattern generated based on a group of preset values in the LiDAR device. A set of stepwise moving angles of the LiDAR device corresponding to the group of preset values are then calculated based on the image of the laser spots and the angular resolution of the camera for use in calibrating the LiDAR device.

Abstract: Embodiments of the invention disclose devices, methods, and computer media for noise rejections in a remote sensing device, such as a LIDAR device. In an exemplary embodiment, a spatial filter includes an aperture dynamically created in synchronization with one or more directions in which emitted laser pulses from the LiDAR device are steered. Photons from all other directions except the one or more directions are blocked by the spatial filter. Reflected photons from the one or more directions pass through the spatial filter via the aperture, and are projected on one or more sets of photodetectors. Noises in the photons that pass through the spatial filter are further to be rejected based on one or more fixed temporal patterns identified in laser pulses emitted by the LiDAR device. The spatial filter can be implemented using an electrochromic display, an array of micromechanical (MEMS) mirrors, a liquid crystal display (LCD), or an electro-wetting display.