A micro-pulse LiDAR and a method for detecting water vapor, temperature, and pressure of the atmosphere are provided. The micro-pulse LiDAR includes a first transmitter, a second transmitter, a third transmitter, an optical path transmission module, a water vapor channel detection module, a pressure channel detection module, a temperature channel detection module, a multi-channel data accumulator, a processing device, and a pulse generator. The method for detecting the water vapor, the temperature, and the pressure of the atmosphere comprises: chopping, via the processing device, multi-wavelength continuous lasers emitted by the transmitters to obtain multi-wavelength pulsed lasers; transmitting the multi-wavelength pulsed lasers according to established optical paths, and comprehensively detecting the water vapor, the temperature, and the pressure of the atmosphere, so that the three parameters can be input conditions for each other in an inversion process, which improves an iteration speed and inversion accuracy.

An optical device includes a first substrate with a first surface spreading in a first direction and a second direction intersecting the first direction, a second substrate with a second surface facing the first surface, a film bonded to the first surface and/or the second surface through a siloxane bond, and at least one optical guide layer positioned between the first substrate and the second substrate, the optical guide layer including a dielectric member in contact with the film and guiding light in the first direction and/or the second direction.

A system comprises at a first interface, a first optical guide, a second interface, and a second optical guide. A portion of the first interface is configured to receive a first pulse of light emitted by a lidar device and a portion of the second interface is configured to receive a second pulse of light emitted by the lidar device. The first optical guide is configured to propagate the received first pulse of light, wherein at least a portion of the first interface is configured to emit towards the lidar device a version of the received first pulse that propagated through the first optical guide. The second optical guide is configured to propagate the received second pulse of light, wherein at least a portion of the second interface is configured to emit towards the lidar device a version of the received second pulse that propagated through the second optical guide.

A LIDAR measuring device and a method for determining the speed of particles in a measuring volume includes a narrowband continuous wave laser light source (1), which emits light which is coupled into a measuring branch (3) and a reference branch (4). The light coupled into the measuring branch (3) is at least partially emitted by a transmitting device in the direction of the measuring volume such that the emitted light is at least partially scattered and/or reflected by the particles in the measuring volume. A part of the scattered and/or reflected light is then received by a receiver device and is coherently superimposed with the light leaving the reference branch (4), and the resulting light beam is directed onto a detector (6) to generate a detector signal characteristic for the resulting light beam. Finally, the speed of the particles in the measuring volume is determined in an evaluation unit (11) by taking into account the detector signal.

A LIDAR-type device for a remote spectroscopy of a matter includes an optical emission channel that includes a laser source and an optical waves frequency generator to generate a first comb, a second comb, and a local comb. Each comb includes at least one stripe. A transmit telescope emits an emission signal. A reception channel includes a receive telescope that receives a signal reflected by the matter traversed by the emission signal and a detection system that detects a first beat signal of the at least one stripe of the local comb with the corresponding first stripe of the first reflected comb, a second beat signal of the at least one stripe of the local comb with the corresponding second stripe of the second reflected comb, and a third beat signal of the at least one first beat signal with the at least one second beat signal.

Systems and methods for a silicon photonics integrated optical velocimeter are provided herein. In some embodiments, a method includes producing a laser output at a laser source; emitting the laser output from a plurality of emitters formed in an optical chip; receiving a plurality of reflected portions of the emitted laser output at an optical collector formed in the optical chip, wherein the plurality of reflected portions are reflected off of at least one surface; beating the laser output against the reflected portions of the emitted laser output, wherein one of the laser output or the reflected portions of the emitted laser output are modulated by at least one modulation frequency; and calculating a doppler shift for each of the plurality of reflected portions of the emitted laser output based on an output of the beating and the at least one modulation frequency.

A method includes generating, using a transmitter, an optical signal for each fiber incoherently combined in a fiber bundle. The method also includes transmitting the optical signal from each fiber as pulses at a target. The method further includes receiving, using a receiver array, the pulses of the optical signals and identifying one or more parameters of the target based on the pulses of the optical signals.

A transmitting optical system for a LIDAR system is described for illuminating a field of view with light, having a linear light source for generating and outputting primary light in linear form; and having a deflecting optical system that has a lens assemblage in an intermediate image plane of the deflecting optical system for outputting received primary light into the field of view, and has a deflecting mirror, pivotable one-dimensionally around an axis, for receiving primary light from the linear light source and for directing the primary light onto the lens assemblage and, in that context, imaging the linear light source onto the lens assemblage in such a way that the image of the linear light source sweeps over the lens assemblage, or over a part thereof, upon a pivoting motion of the deflecting mirror.

A LIDAR system includes a demultiplexer that separates an outgoing LIDAR signal into multiple LIDAR output signals that each carries a different channel and the different channels are each at a different wavelength. The system also includes a beam distributor that receives each of the LIDAR output signals. The beam distributor directs the received LIDAR output signals such that different LIDAR output signals travel away from the beam distributor in different directions.

A laser system includes a resonant laser cavity configured to output a laser signal. The system also includes a utility waveguide configured to receive the laser signal from the laser cavity. The utility waveguide includes a perturbation region that is external to the laser cavity and receives the laser signal from the laser cavity and outputs a laser beam. The perturbation region includes one or more perturbation structures that each causes one or more perturbation(s) in the index of refraction of the utility waveguide. The perturbation structures are selected to provide optical feedback to the resonant laser cavity such that a power versus wavelength distribution in the laser beam is different from the power versus wavelength distribution that would be in the laser signal in the absence of the perturbation structures.