SWaP-efficient, fast-wavelength-steering and time-division-multiplexing lidar technology capable of multi-beam ranging and concurrent hyper-spectral imaging (CASALS)

These radical innovations in integrated lidar/spectral/AI SWaP and performance will significantly enhance Goddard’s technical and scientific advantages when competing for eight of the fourteen Observing System Priorities identified in the Second National Academy Earth Science Decadal Survey released in 2017. Following the Academy recommendation to consider using a multi-function lidar to address two or more of the Observables, our 60-beam, configurable instrument would be well suited to acquire the measurements for the three near-term surface observables as well as aerosol and cloud profiling. Our hyperspectral imaging directly applies to the Surface Biology and Geology observable and the lidar/hyperspectral integration will, in fact, advance capabilities for all five of the Earth surface observables by providing compositional and functional information directly associated with the elevation data. This is especially the case for Terrestrial Ecosystem Structure objectives of ecosystem dynamics, rates of primary production, evapotranspiration, carbon uptake and changing land use which need both structure and function information. Funding is needed at this time to demonstrate the capabilities over the next three years, with the intent to acquire additional funding to raise TRLs to 5-6 in preparation for mission proposal opportunities starting in 2021-22. The longer-term goal of global lidar mapping can be accomplished using multiple 60-beam modules, sharing the same seed laser and grating, and imaging the footprints onto groups of pixels in larger linear-mode HgCdTe arrays. Because of lowered cost and SWaP, instrument copies could be distributed in a constellation of SmallSats to accelerate mapping, point at rapidly changing natural hazards and acquire diurnal sampling needed to fully characterize ecosystem processes.