![]() Dense motion estimation of particle images via a convolutional neural network. Particle image velocimetry based on a deep learning motion estimator. PIV-DCNN: cascaded deep convolutional neural networks for particle image velocimetry. Performing particle image velocimetry using artificial neural networks: a proof-of-concept. ![]() In Advances in Neural Information Processing Systems 794–805 (NIPS, 2019). Volumetric correspondence networks for optical flow. IEEE Conference on Computer Vision and Pattern Recognition 5754–5763 (IEEE, 2019). Iterative residual refinement for joint optical flow and occlusion estimation. IEEE Conference on Computer Vision and Pattern Recognition 8934–8943 (IEEE, 2018). PWC-Net: CNNs for optical flow using pyramid, warping, and cost volume. IEEE Conference on Computer Vision and Pattern Recognition 8981–8989 (IEEE, 2018). Liteflownet: a lightweight convolutional neural network for optical flow estimation. IEEE Conference on Computer Vision and Pattern Recognition 2462–2470 (2017). Flownet 2.0: evolution of optical flow estimation with deep networks. IEEE International Conference on Computer Vision 2758–2766 (IEEE, 2015). Flownet: learning optical flow with convolutional networks. In European Conference on Computer Vision 402–419 (Springer, 2020).ĭosovitskiy, A. RAFT: recurrent all-pairs field transforms for optical flow. Robust wall gradient estimation using radial basis functions and proper orthogonal decomposition (POD) for particle image velocimetry (PIV) measured fields. ![]() Universal outlier detection for PIV data. Iterative multigrid approach in PIV image processing with discrete window offset. Two-dimensional gaussian regression for sub-pixel displacement estimation in particle image velocimetry or particle position estimation in particle tracking velocimetry. In 35th AIAA Applied Aerodynamics Conference 3748 (AIAA, 2017). Sd7003 airfoil in large-scale free stream turbulence. Analysis of a drag reduced flat plate turbulent boundary layer via uniform momentum zones. In Summer Biomechanics, Bioengineering and Biotransport Conference (SB3C, 2019). In vitro volumetric lagrangian particle tracking and 4D pressure field in a left ventricle model. Experimental investigation of the fluid–structure interaction in an elastic 180 curved vessel at laminar oscillating flow. Pielhop, K., Schmidt, C., Zholtovski, S., Klaas, M. Application of particle image velocimetry to combusting flows: design considerations and uncertainty assessment. Stella, A., Guj, G., Kompenhans, J., Raffel, M. High-speed tomographic PIV measurements in a DISI engine. Extensive experiments, including benchmark examples where true gold standards are available for comparison, demonstrate that the proposed approach achieves state-of-the-art accuracy and generalization to new data, relative to both classical approaches and previously proposed optical flow learning schemes.īraun, M., Schröder, W. ![]() By contrast, the deep learning-based approach introduced in this paper, which is based on a recent optical flow learning architecture known as recurrent all-pairs field transforms, is general, largely automated and provides high spatial resolution. The current state of the art in PIV data processing involves traditional handcrafted models that are subject to limitations including the substantial manual effort required and difficulties in generalizing across conditions. In this paper we propose a deep neural network-based approach for learning displacement fields in an end-to-end manner, focusing on the specific case of particle image velocimetry (PIV), a key approach in experimental fluid dynamics that is of crucial importance in diverse applications such as automotive, aerospace and biomedical engineering. A wide range of problems in applied physics and engineering involve learning physical displacement fields from data.
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