Aquatic Ecosystems Science Using an Imaging Spectrometer

Authors

Ronald Lockwood, Lincoln Laboratory
Charles M. Bachmann, Rochester Institute of Technology
Michael Chrisp, Lincoln Laboratory
Corrie Smeaton, Lincoln Laboratory
Nima Pahlaven, NASA Goddard Space Flight Center
Eric Hochberg, Bermuda Institute of Ocean Sciences
Marcos J. Montes, U.S. Naval Research Laboratory
Bo Cai Gao, U.S. Naval Research Laboratory
Robert Frouin, Scripps Institution of Oceanography
Anthony Vodacek, Rochester Institute of Technology
Cedric Fichot, Boston University
Tom W. Bell, Woods Hole Oceanographic Institution
Roy A. Armstrong, Recinto Universitario de Mayagüez
Chunyan Li, Louisiana State University
Laura Kennedy, Lincoln Laboratory
Steve Gillmer, Lincoln Laboratory
Linda Fuhrman, Lincoln Laboratory
Derrick Brouhard, Lincoln Laboratory
Jade Wang, Lincoln Laboratory
Kurtis Thome, NASA Goddard Space Flight Center

Document Type

Conference Proceeding

Publication Date

1-1-2023

Abstract

The study of aquatic ecosystems is an important research area addressing diverse problems such as carbon sequestration in coastal margins and wetlands, kelp and seagrass studies, coral reefs, harmful algal blooms and hypoxia, and carbon cycling in this dynamic environment. The application of an imaging spectrometer to aquatic ecosystem study is particularly challenging due to low water-leaving radiance levels adjacent to the shore region with its higher values. The Committee on Earth Observation Satellites (CEOS) has established more stringent performance standards for the visible/near infrared wavelengths than are typically available in imaging spectrometer designs. We have recently developed a compact form imaging spectrometer, the Chrisp Compact VNIR/SWIR Imaging Spectrometer (CCVIS), that facilitates their modular usage with a wide field telescope without sacrificing performance. The CCVIS design and the operational concept have predicted performance that approaches the CEOS standards. The envisioned satellite implementation requires a pitchback maneuver where the imaging of the slit projected onto the surface is slowly scanned while recording focal plane array readouts at a higher rate thereby avoiding saturation over the land surface while obtaining a high signal-to-noise ratio over the water. The effective frame rate is determined by the time it takes to scan the projected slit one ground sample distance (GSD). This approach has the added benefit of measuring a range of angles during a single GSD acquisition, providing insight into the bidirectional reflectance distribution function (BRDF).

Publication Source (Journal or Book title)

Proceedings of SPIE the International Society for Optical Engineering

Recommended Citation

Lockwood, R., Bachmann, C., Chrisp, M., Smeaton, C., Pahlaven, N., Hochberg, E., Montes, M., Gao, B., Frouin, R., Vodacek, A., Fichot, C., Bell, T., Armstrong, R., Li, C., Kennedy, L., Gillmer, S., Fuhrman, L., Brouhard, D., Wang, J., & Thome, K. (2023). Aquatic Ecosystems Science Using an Imaging Spectrometer. Proceedings of SPIE the International Society for Optical Engineering, 12688 https://doi.org/10.1117/12.2676124