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Inferring surface energy fluxes using drone data assimilation in large eddy simulations

Publication ,  Journal Article
Pirk, N; Aalstad, K; Westermann, S; Vatne, A; Van Hove, A; Tallaksen, LM; Cassiani, M; Katul, G
Published in: Atmospheric Measurement Techniques
December 20, 2022

Spatially representative estimates of surface energy exchange from field measurements are required for improving and validating Earth system models and satellite remote sensing algorithms. The scarcity of flux measurements can limit understanding of ecohydrological responses to climate warming, especially in remote regions with limited infrastructure. Direct field measurements often apply the eddy covariance method on stationary towers, but recently, drone-based measurements of temperature, humidity, and wind speed have been suggested as a viable alternative to quantify the turbulent fluxes of sensible (H) and latent heat (LE). A data assimilation framework to infer uncertainty-aware surface flux estimates from sparse and noisy drone-based observations is developed and tested using a turbulence-resolving large eddy simulation (LES) as a forward model to connect surface fluxes to drone observations. The proposed framework explicitly represents the sequential collection of drone data, accounts for sensor noise, includes uncertainty in boundary and initial conditions, and jointly estimates the posterior distribution of a multivariate parameter space. Assuming typical flight times and observational errors of light-weight, multi-rotor drone systems, we first evaluate the information gain and performance of different ensemble-based data assimilation schemes in experiments with synthetically generated observations. It is shown that an iterative ensemble smoother outperforms both the non-iterative ensemble smoother and the particle batch smoother in the given problem, yielding well-calibrated posterior uncertainty with continuous ranked probability scores of 12Wm-2 for both H and LE, with standard deviations of 37Wm-2 (H) and 46Wm-2 (LE) for a 12min vertical step profile by a single drone. Increasing flight times, using observations from multiple drones, and further narrowing the prior distributions of the initial conditions are viable for reducing the posterior spread. Sampling strategies prioritizing space-time exploration without temporal averaging, instead of hovering at fixed locations while averaging, enhance the non-linearities in the forward model and can lead to biased flux results with ensemble-based assimilation schemes. In a set of 18 real-world field experiments at two wetland sites in Norway, drone data assimilation estimates agree with independent eddy covariance estimates, with root mean square error values of 37Wm-2 (H), 52Wm-2 (LE), and 58Wm-2 (H+LE) and correlation coefficients of 0.90 (H), 0.40 (LE), and 0.83 (H+LE). While this comparison uses the simplifying assumptions of flux homogeneity, stationarity, and flat terrain, it is emphasized that the drone data assimilation framework is not confined to these assumptions and can thus readily be extended to more complex cases and other scalar fluxes, such as for trace gases in future studies.

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Published In

Atmospheric Measurement Techniques

DOI

EISSN

1867-8548

ISSN

1867-1381

Publication Date

December 20, 2022

Volume

15

Issue

24

Start / End Page

7293 / 7314

Related Subject Headings

  • Meteorology & Atmospheric Sciences
  • 3701 Atmospheric sciences
  • 0401 Atmospheric Sciences
 

Citation

APA
Chicago
ICMJE
MLA
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Pirk, N., Aalstad, K., Westermann, S., Vatne, A., Van Hove, A., Tallaksen, L. M., … Katul, G. (2022). Inferring surface energy fluxes using drone data assimilation in large eddy simulations. Atmospheric Measurement Techniques, 15(24), 7293–7314. https://doi.org/10.5194/amt-15-7293-2022
Pirk, N., K. Aalstad, S. Westermann, A. Vatne, A. Van Hove, L. M. Tallaksen, M. Cassiani, and G. Katul. “Inferring surface energy fluxes using drone data assimilation in large eddy simulations.” Atmospheric Measurement Techniques 15, no. 24 (December 20, 2022): 7293–7314. https://doi.org/10.5194/amt-15-7293-2022.
Pirk N, Aalstad K, Westermann S, Vatne A, Van Hove A, Tallaksen LM, et al. Inferring surface energy fluxes using drone data assimilation in large eddy simulations. Atmospheric Measurement Techniques. 2022 Dec 20;15(24):7293–314.
Pirk, N., et al. “Inferring surface energy fluxes using drone data assimilation in large eddy simulations.” Atmospheric Measurement Techniques, vol. 15, no. 24, Dec. 2022, pp. 7293–314. Scopus, doi:10.5194/amt-15-7293-2022.
Pirk N, Aalstad K, Westermann S, Vatne A, Van Hove A, Tallaksen LM, Cassiani M, Katul G. Inferring surface energy fluxes using drone data assimilation in large eddy simulations. Atmospheric Measurement Techniques. 2022 Dec 20;15(24):7293–7314.

Published In

Atmospheric Measurement Techniques

DOI

EISSN

1867-8548

ISSN

1867-1381

Publication Date

December 20, 2022

Volume

15

Issue

24

Start / End Page

7293 / 7314

Related Subject Headings

  • Meteorology & Atmospheric Sciences
  • 3701 Atmospheric sciences
  • 0401 Atmospheric Sciences