TY - JOUR

T1 - Impacts of atmospheric turbulence on optic measurements over heterogeneous flat terrain

T2 - insights from large eddy simulations

AU - Kermarrec, Gaël

AU - Sühring, Matthias

AU - Al-Younis, Wardeh

N1 - Publisher Copyright: Journal © 2025.

PY - 2025/1/27

Y1 - 2025/1/27

N2 - Atmospheric refraction imposes a fundamental limitation on the accuracy and precision of geodetic measurements that utilize electromagnetic waves. For terrestrial observations at optical wavelengths recorded over flat terrain, the vertical temperature gradient controls the bending of the rays thus affecting mostly the vertical angle measurement. The rules of thumb for mitigating these effects (variation ranges and short-term fluctuations) are based on intuition and practitioner experience. To address the challenge of understanding the impact of refractive index inhomogeneities on the refraction angle without additional instruments, we introduce large eddy simulations (LES) in geodesy. We use the PALM software to simulate realistic atmospheric conditions and investigate first- and second-order variations of the refraction angle using virtual measurements over a flat terrain with surface heterogeneities. We analyze the optimal measurement times to minimize refraction effects, highlighting the potential of LES to help plan measurement campaigns. Additionally, the correlating influence of atmospheric turbulence on the measurements is quantified. We propose a correction model based on the variance inflation factor as a practical tool for incorporating turbulence into a geodetic uncertainty model.

AB - Atmospheric refraction imposes a fundamental limitation on the accuracy and precision of geodetic measurements that utilize electromagnetic waves. For terrestrial observations at optical wavelengths recorded over flat terrain, the vertical temperature gradient controls the bending of the rays thus affecting mostly the vertical angle measurement. The rules of thumb for mitigating these effects (variation ranges and short-term fluctuations) are based on intuition and practitioner experience. To address the challenge of understanding the impact of refractive index inhomogeneities on the refraction angle without additional instruments, we introduce large eddy simulations (LES) in geodesy. We use the PALM software to simulate realistic atmospheric conditions and investigate first- and second-order variations of the refraction angle using virtual measurements over a flat terrain with surface heterogeneities. We analyze the optimal measurement times to minimize refraction effects, highlighting the potential of LES to help plan measurement campaigns. Additionally, the correlating influence of atmospheric turbulence on the measurements is quantified. We propose a correction model based on the variance inflation factor as a practical tool for incorporating turbulence into a geodetic uncertainty model.

UR - http://www.scopus.com/inward/record.url?scp=85216377872&partnerID=8YFLogxK

U2 - 10.1364/OE.540584

DO - 10.1364/OE.540584

M3 - Article

AN - SCOPUS:85216377872

VL - 33

SP - 3522

EP - 3542

JO - Optics express

JF - Optics express

SN - 1094-4087

IS - 2

ER -