| Title |
UAV-based river velocity estimation using optical flow and FEM-supported multiframe RAFT extension |
| Authors |
Kriščiūnas, Andrius ; Akstinas, Vytautas ; Čalnerytė, Dalia ; Meilutytė-Lukauskienė, Diana ; Gurjazkaitė, Karolina ; Fyleris, Tautvydas ; Barauskas, Rimantas |
| DOI |
10.3390/drones10030221 |
| Full Text |
|
| Is Part of |
Drones.. Basel : MDPI. 2026, vol. 10, iss. 3, art. no. 221, p. 1-24.. ISSN 2504-446X |
| Keywords [eng] |
multiframe deep learning ; physics-informed modeling ; river surface velocity ; optical flow |
| Abstract [eng] |
Quantifying river surface flow velocity is essential for hydrodynamic modelling, flood forecasting, and water resource management. Traditional in situ methods provide accurate point measurements but are costly and limited in spatial coverage. Unmanned aerial vehicles (UAVs) offer a flexible, non-contact alternative for high-resolution monitoring. Optical flow is a tracer-independent technique for deriving velocity fields from RGB video, making it well suited to UAV-based surveys. However, its operational use is hindered by the limited availability of annotated datasets and by instability under low-texture or noisy conditions. This study combines a Finite element method (FEM)-based physical flow model with UAV video to generate reference datasets and introduces a modified Recurrent All-Pairs Field Transforms (RAFT) architecture based on multiframe sequences. A Gated Recurrent Unit fusion module (Fuse-GRU) is incorporated prior to correlation computation, improving robustness to illumination changes and surface homogeneity while maintaining computational efficiency. The proposed model delivers stable, physically consistent velocity estimates across multiple rivers and flow conditions. Accuracy improves with higher spatial resolution and moderate temporal spacing. Compared to field measurements, the average angular difference ranged from 8 to 15°. The high error values were mainly caused by inaccuracies in the physical model and by complex river features. These findings confirm that multiframe optical flow can reproduce realistic river flow patterns with accuracy comparable to physically-based simulations, thereby supporting UAV-based hydrometric monitoring and model validation. |
| Published |
Basel : MDPI |
| Type |
Journal article |
| Language |
English |
| Publication date |
2026 |
| CC license |
|
