Crossref Citations
This Book has been
cited by the following publications. This list is generated based on data provided by Crossref.
Stavrogiannis, Christos
Sofos, Filippos
Sagri, Maria
Vavougios, Denis
and
Karakasidis, Theodoros E.
2023.
Twofold Machine-Learning and Molecular Dynamics: A Computational Framework.
Computers,
Vol. 13,
Issue. 1,
p.
2.
Teutsch, Philipp
Käufer, Theo
Mäder, Patrick
and
Cierpka, Christian
2023.
Data-driven estimation of scalar quantities from planar velocity measurements by deep learning applied to temperature in thermal convection.
Experiments in Fluids,
Vol. 64,
Issue. 12,
Alam, Jahrul M
2023.
Wavelet Transforms and Machine Learning Methods for the Study of Turbulence.
Fluids,
Vol. 8,
Issue. 8,
p.
224.
Vignon, Colin
Rabault, Jean
Vasanth, Joel
Alcántara-Ávila, Francisco
Mortensen, Mikael
and
Vinuesa, Ricardo
2023.
Effective control of two-dimensional Rayleigh–Bénard convection: Invariant multi-agent reinforcement learning is all you need.
Physics of Fluids,
Vol. 35,
Issue. 6,
Liao, Zi-Mo
Zhao, Zhiye
Chen, Liang-Bing
Wan, Zhen-Hua
Liu, Nan-Sheng
and
Lu, Xi-Yun
2023.
Reduced-order variational mode decomposition to reveal transient and non-stationary dynamics in fluid flows.
Journal of Fluid Mechanics,
Vol. 966,
Issue. ,
Basu, Ankan
Saha, Aritra
Banerjee, Sumanta
Roy, Prokash C.
and
Kundu, Balaram
2024.
A Review of Artificial Intelligence Methods in Predicting Thermophysical Properties of Nanofluids for Heat Transfer Applications.
Energies,
Vol. 17,
Issue. 6,
p.
1351.
Jia, Wang
and
Xu, Hang
2024.
Robust and adaptive deep reinforcement learning for enhancing flow control around a square cylinder with varying Reynolds numbers.
Physics of Fluids,
Vol. 36,
Issue. 5,
Cuéllar, Antonio
Güemes, Alejandro
Ianiro, Andrea
Flores, Óscar
Vinuesa, Ricardo
and
Discetti, Stefano
2024.
Three-dimensional generative adversarial networks for turbulent flow estimation from wall measurements.
Journal of Fluid Mechanics,
Vol. 991,
Issue. ,
Skilskyy, Vladyslav
Rossano, Viola
and
De Stefano, Giuliano
2024.
Computational Science and Its Applications – ICCSA 2024.
Vol. 14814,
Issue. ,
p.
355.
Sun, Xianhu
Kong, Haohao
Tian, Hongyan
Song, Zhongling
and
Ma, Chicheng
2025.
Deep reinforcement learning control strategy for synthetic jets on airfoils.
Physics of Fluids,
Vol. 37,
Issue. 5,
Patel, Rushil Samir
and
Xi, Li
2025.
Proceedings of Fluid Mechanics and Fluid Power (FMFP) 2023, Vol. 5.
p.
703.
Zapata Usandivaras, Jose Felix
Bauerheim, Michael
Cuenot, Bénédicte
and
Urbano, Annafederica
2025.
Data-driven multifidelity surrogate models for rocket engines injector design.
Data-Centric Engineering,
Vol. 6,
Issue. ,
Ong, Muk Chen
and
Yin, Guang
2025.
Synergizing machine learning with fluid–structure interaction research: An overview of trends and challenges.
Ocean,
Vol. 1,
Issue. 1,
p.
9470002.
Wang, Ping
Bai, Huisong
Peng, Yong
Zhou, Jianguo
Xu, Guangyao
and
Peng, Yuji
2025.
Analysis of high-Reynolds-number lid-driven cavity flow using enhanced dynamic mode decomposition.
Physics of Fluids,
Vol. 37,
Issue. 7,
Naser, M.Z.
2025.
Intuitive tests to validate machine learning models against physics and domain knowledge.
Digital Engineering,
Vol. 7,
Issue. ,
p.
100057.
Rahman, S. M. Mahbobur
Untaroiu, Alexandrina
and
Martin, Christopher R.
2026.
Predicting the Electrical Characteristics of Oxyfuel Cutting Flame Based on Machine Learning Algorithms.
Journal of Fluids Engineering,
Vol. 148,
Issue. 1,
