Receiver for Long-distance, Low-backscatter LiDAR

Sensors

Receiver for Long-distance, Low-backscatter LiDAR (LAR-TOPS-387)

Hybrid optic LiDAR receiver compatible with > 1mJ fiber lasers

Overview

Researchers at the NASA Langley Research Center have developed a new coherent LiDAR (light detection and ranging) receiver compatible with high-energy fiber lasers. The hybrid receiver incorporates robust bulk optics (i.e., dielectric, coated optics) to handle high pulse energy where needed and fiber optics where damage tolerance is not critical. Commercially available receivers leveraging fiber optic components for metrology and remote sensing are not compatible lasers above ~100 micro-J. This restriction limits measurement distances to only a few kilometers out and to the lower atmosphere where aerosols are abundant. The new NASA design allows full advantage to be taken of novel high-energy pulsed laser technology to enable Doppler LiDAR measurements out to longer distances (> 10 km) and/or in conditions of lower aerosol backscatter for applications in markets including wind energy, aerospace & defense, and meteorology & environmental sensing.

The Technology

The NASA receiver is specifically designed for use in coherent LiDAR systems that leverage high-energy (i.e., > 1mJ) fiber laser transmitters. Within the receiver, an outgoing laser pulse from the high-energy laser transmitter is precisely manipulated using robust dielectric and coated optics including mirrors, waveplates, a beamsplitter, and a beam expander. These components appropriately condition and direct the high-energy light out of the instrument to the atmosphere for measurement. Lower energy atmospheric backscatter that returns to the system is captured, manipulated, and directed using several of the previously noted high-energy compatible bulk optics. The beam splitter redirects the return signal to mirrors and a waveplate ahead of a mode-matching component that couples the signal to a fiber optic cable that is routed to a 50/50 coupler photodetector. The receiver’s hybrid optic design capitalizes on the advantages of both high-energy bulk optics and fiber optics, resulting in order-of-magnitude enhancement in performance, enhanced functionality, and increased flexibility that make it ideal for long-distance or low-backscatter LiDAR applications. The related patent is now available to license. Please note that NASA does not manufacturer products itself for commercial sale.

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Design of coherent LiDAR receiver for high-energy fiber lasers

Benefits

Compatible with Novel Laser Technology: Enables use of high-energy fiber lasers that significantly enhance coherent LiDAR performance
Longer-Distance Measurement: Enables wind measurement at distances beyond 10 kilometers from receiver
Lower-Backscatter Measurement: Enables collection of atmospheric data significantly higher into the atmosphere where aerosol particles are less abundant
High value: Optimized combination of bulk and fiber optics minimizes costs and maximizes performance
Versatility: Broadly enhances coherent LiDAR system capabilities regardless of application

Applications

Aerospace & Defense: Monitoring wind speed, direction, shear, and turbulence for aircraft navigation and safety; high-precision target acquisition and tracking; enhancing autonomous navigation and obstacle avoidance for advanced air mobility aircraft such as drones and eVTOLs
Wind Energy: Optimizing the placement, performance, and safe operation of wind turbines through detailed wind resource assessment and real-time wind monitoring.
Meteorology & Environmental Monitoring: Measuring atmospheric conditions to improve weather models and more generally build enhanced database of wind patterns, pollutants, and particulate matter in the atmosphere

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Technology Details

Category Sensors

Reference Number LAR-TOPS-387

Case Number(s) LAR-20317-1

Patent(s) (pop-up blockers must be disabled)

Papers

Tags:

LIDAR laser receiver remote sensing weather doppler coherent optics wind aerosol detector evtol meteorology AAM advanced air mobility climate change adaptation turbine

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