Relative fluid stretching and rotation for sparse trajectory observations
Permanent lenke
https://hdl.handle.net/10037/35635Dato
2024-10-03Type
Journal articleTidsskriftartikkel
Peer reviewed
Sammendrag
As most mathematically justifiable Lagrangian coherent structure detection methods
rely on spatial derivatives, their applicability to sparse trajectory data has been limited.
For experimental fluid dynamicists and natural scientists working with Lagrangian
trajectory data via passive tracers in unsteady flows (e.g. Lagrangian particle tracking
or ocean buoys), obtaining material measures of fluid rotation or stretching is an active
topic of research. To facilitate frame-indifferent investigations in unsteady and sparsely
sampled flows, we present a novel approach to quantify fluid stretching and rotation via
relative Lagrangian velocities. This technique provides a formal objective extension of
quasi-objective metrics to unsteady flows by accounting for mean flow behaviour. For
extremely sparse experimental data, fluid structures may be significantly undersampled
and the mean flow behaviour becomes difficult to quantify. We provide a means to maintain
the accuracy of our novel sparse flow diagnostics in extremely sparse sampling scenarios,
such as ocean buoy data and Lagrangian particle tracking. We use data from multiple
numerical and experimental flows to show that our methods can identify structures
beyond existing limits of sparse, frame-indifferent diagnostics and exhibit improved
interpretability over common frame-dependent diagnostics.
Forlag
Cambridge University PressSitering
Aksamit, Encinas-Bartos, Haller, Rival. Relative fluid stretching and rotation for sparse trajectory observations. Journal of Fluid Mechanics. 2024;996Metadata
Vis full innførselSamlinger
Copyright 2024 The Author(s)