Abstract: A light detection and ranging (LIDAR) system includes optical sources to emit optical beams with synchronized chirp rates and chirp durations. The optical beams provide a comb of coherent optical beams with a fixed frequency separation between frequency adjacent optical beams. A first set of first optical components amplifies and combines the optical beams into a combined optical beam. A second set of optical components transmits the combined optical beam toward a target environment and receives a target return signal. A third set of optical components downconverts the target return signal to downconverted target return signals corresponding to the optical beams, and coherently combines the downconverted target return signals.

Abstract: A light detection and ranging (LIDAR) apparatus includes an optical source to emit an optical beam, and free-space optics coupled with the optical source. The free space optics include a photodetector and other optical components to direct a leaked portion of the optical beam or a reflected portion of the optical beam toward the photodetector as a local oscillator signal, and to transmit the optical beam toward a target environment. The local oscillator signal co-propagates with a like-polarized target return signal and mixes with the target return signal to generate target information.

Abstract: A LIDAR system includes an optical source and multiple waveguides at different positions within the LIDAR system to receive a return signal. A first waveguide receives a first portion of the return signal at a first angle relative to the scanning mirror and a second waveguide receives a second portion of the return signal at a second angle relative to the scanning mirror. The system further includes multiple optical detectors at different positions within the LIDAR system. A first optical detector receives the first portion of the return signal from the first waveguide and a second optical detector receives the second portion of the return signal from the second waveguide. The system further includes a signal processing system operatively coupled to the plurality of optical detectors to determine a distance and velocity of the target object based on the returned signal and corresponding positions of the plurality of waveguides.

Abstract: A light detection and ranging (LiDAR) system according to the present disclosure comprises an optical circulator and one or more photodetectors (PDs). The optical circulator is to receive an optical beam and transmit the optical beam to a target, to receive a target return signal from the target and to transmit the target return signal to the one or more PDs, where the one or more PDs are to mix the target return signal with an LO signal to generate a heterodyne signal to extract range and velocity information of the target.

Abstract: A method of operating a light detection and ranging (LIDAR) system is provided that includes generating a beam of co-propagating, cross-polarized light using a first polarizing beam splitter; and determining a material characteristic or orientation of a target using the co-propagating, cross-polarized light.

Abstract: A method of operating a light detection and ranging (LIDAR) system is provided that includes generating a beam of polarized light; and transforming a polarization state of the beam of polarized light at a rate faster than a rate of data collection at a plurality of detectors configured to detect light reflected from a target for the purpose of speckle-reduction.

Abstract: A light detection and ranging (LIDAR) system includes optical sources to emit optical beams with synchronized chirp rates and chirp durations. The optical beams provide a comb of coherent optical beams with a fixed frequency separation between frequency adjacent optical beams. A first set of first optical components amplifies and combines the optical beams into a combined optical beam. A second set of optical components transmits the combined optical beam toward a target environment and receives a target return signal. A third set of optical components downconverts the target return signal to downconverted target return signals corresponding to the optical beams, and coherently combines the downconverted target return signals.

Abstract: A light detection and ranging (LiDAR) system according to the present disclosure comprises an optical source to emit an optical beam, and an optical circulator to receive the optical beam and transmit the optical beam to a target, to receive a target return signal from the target and to transmit the target return signal to one or more photodetectors (PDs). The optical circulator is configured to collect all polarization states in the target return signal. The LiDAR system further comprises an optical element to generate a local oscillator (LO) signal, and the one or more PDs to mix the target return signal with the LO signal to generate a heterodyne signal to extract range and velocity information of the target.

Abstract: A light detection and ranging (LIDAR) system includes an optical source to emit an optical beam, and free-space optics coupled with the optical source to focus the optical beam at a first focal plane, where a local oscillator (LO) signal is generated from a partial reflection of the optical beam from a partially-reflecting surface proximate to the first focal plane, and where a transmitted portion of the optical beam is directed toward a scanned target environment. The free-space optics configured to focus the LO signal and a target return signal at a second focal plane comprising a conjugate focal plane to the first focal plane. The system also includes a photodetector with a photosensitive surface proximate to the conjugate focal plane to mix the LO signal with the target return signal to generate target information.

Abstract: A light detection and ranging (LIDAR) apparatus is provided that includes an optical source to emit a first optical beam having a first frequency and a second optical beam having a second frequency and a dispersive element to deflect the first optical beam having the first frequency at a first angle and the second optical beam having the second frequency at a second angle.

Abstract: A light detection and ranging (LIDAR) apparatus is provided that includes an optical source configured to emit an optical beam. The LIDAR apparatus further includes free space optics configured to receive a first portion of the optical beam as a target signal and a second portion of the optical beam as a local oscillator signal, and combine the target signal and the local oscillator signal. The LIDAR apparatus includes a multi-mode (MM) waveguide configured to receive the combined signal.

Abstract: A light detection and ranging (LIDAR) apparatus includes an optical circuit including a laser source configured to emit a laser beam, a beam separator operatively coupled to the laser source, the beam separator configured to separate the laser beam propagated towards a target, a first optical amplifier coupled to the beam separator, the first optical amplifier configured to receive a return laser beam reflected from the target in a return path and amplify the return laser beam to output an amplified return laser beam, and an optical component operatively coupled to the first optical amplifier, the optical component configured to output a current based on the amplified return laser beam.

Abstract: A light detection and ranging (LIDAR) apparatus is provided that includes an optical source to emit an optical beam towards a target. The LIDAR apparatus further includes a mode field expander operatively coupled to the optical source to expand a mode area of the optical beam.