# Physics-informed coherent motions to predict Lagrangian trajectories

**Authors:** Ali R Khojasteh, Dominique Heitz

arXiv: 2508.21191 · 2026-05-07

## TL;DR

This paper introduces a physics-informed coherent motion-based method to predict Lagrangian trajectories in turbulent flows, leveraging Lagrangian coherent structures and a novel cost function.

## Contribution

It develops a new trajectory prediction approach that integrates flow physics and sparse data, improving accuracy across different flow conditions.

## Key findings

- Lower prediction error and uncertainty compared to existing methods.
- Flow topology signatures are visible in the prediction error maps.
- The method is effective for both synthetic and experimental flow data.

## Abstract

Accurate prediction of Lagrangian trajectories in turbulent flow remains challenging due to limited temporal information in transport functions. This paper shows that surrounding coherent motions sharing the same dynamics carry enough information to provide highly probable trajectories even from sparse temporal observations. The proposed coherent predictor builds on Lagrangian coherent structures (LCSs), the advective transport barriers that govern the cohesive motion of neighbouring particles. Coherent trajectories are quantified using a local segmentation with the finite-time Lyapunov exponents (FTLE). The coherent predictor incorporates information from the particle's position history and neighbouring coherent velocity and acceleration into a novel cost function to predict its trajectory. The proposed cost function follows a physics-informed approach where the position history acts as a data fidelity term and the coherent velocity and acceleration act as physics-based regularisation constraints. We assess our proposed approach using both three-dimensional (3D) synthetic and experimental data of the wake behind a smooth cylinder and two-dimensional (2D) homogeneous isotropic turbulent (HIT) flow. The coherent predictor is deemed generic due to its consistent behaviour regardless of flow dimensions, Reynolds number, and flow topology. Our results show that the optimal cost function parameters can be modelled from the measurement uncertainties, giving lower prediction error and uncertainty than current methods. We see direct signatures of flow topology on the prediction error map, including the cylinder leading edge boundary layer, the sideward shear layers, and the vortex formation structures. These topologies are marked by high Lagrangian gradients and 3D directional motions.

## Full text

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## Figures

21 figures with captions in the complete paper: https://tomesphere.com/paper/2508.21191/full.md

## References

71 references — full list in the complete paper: https://tomesphere.com/paper/2508.21191/full.md

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Source: https://tomesphere.com/paper/2508.21191