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Neural-PDE-Solver

PDE: Partial Differentiable Equation

Neural Operators: Learning nonlinear mappings between function spaces.

Contributed by Chunyang Zhang.

1. Survey
2. Model
2.1 PINN 2.2 DeepONet
2.3 Fourier Operator 2.4 Graph Network
2.5 Green Function 2.6 Finite Element
2.7 Convolution 2.8 AutoEncoder
2.9 Neural Operator 2.10 Machine Learning
2.11 Identification 2.12 Inverse Design
2.13 Neural ODE 2.14 Large Model
3. Mechanism
3.1 Benchmark 3.2 Investigation
3.3 Domain Adaptation 3.4 Loss Function
3.5 Sampling 3.6 Mesh
3.7 Decomposition 3.8 Disentangle
3.9 Solver 3.10 AutoML
3.11 Neural Implicit Flow 3.12 Uncertainty Quantification
3.13 Generative Model 3.14 Transformer
3.15 Theory 3.16 Gaussian Process
3.17 Variation 3.18 Bayesian
3.19 Latent Space 3.20 Lagrangian
3.21 Multi Scale 3.22 Multi Fidelity
3.23 Multi Grid 3.24 Active Learning
3.25 Multi Task
4. Applications
4.1 Optimization 4.2 Fluid
4.3 Cybernetics 4.4 Climate
4.5 Mechanics 4.6 Robotics
4.7 Physics 4.8 Image
4.9 Chemistry 4.10 Materials
4.11 Molecules 4.12 Energy
4.13 Quantum 4.14 Game Theory
4.15 Industry 4.16 Economics
4.17 Reconstruction 4.18 Electromagnetism
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  3. A universal PINNs method for solving partial differential equations with a point source. IJCAI, 2022. paper

    Xiang Huang, Hongsheng Liu, Beiji Shi, Zidong Wang, Kang Yang, Yang Li, Min Wang, Haotian Chu, Jing Zhou, Fan Yu, Bei Hua, Bin Dong, and Lei Chen.

  4. Parallel physics-informed neural networks via domain decomposition. JCP, 2021. paper

    Khemraj Shukla, Ameya D.Jagtap, and George Em Karniadakis.

  5. Kolmogorov n–width and Lagrangian physics-informed neural networks: A causality-conforming manifold for convection-dominated PDEs. CMAME, 2023. paper

    Rambod Mojgani, Maciej Balajewicz, and Pedram Hassanzadeh.

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    Pao-Hsiung Chiu, Jian Cheng Wong, Chinchun Ooi, My Ha Dao, and Yew-Soon Ong.

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  14. Data-driven vector soliton solutions of coupled nonlinear Schrödinger equation using a deep learning algorithm. Physics Letters A, 2021. paper

    Yifan Mo, Liming Ling, and Delu Zeng.

  15. Solving Benjamin–Ono equation via gradient balanced PINNs approach. The European Physical Journal Plus, 2022. paper

    Xiangyu Yang and Zhen Wang.

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    Chandrajit Bajaj, Luke McLennan, Timothy Andeen, and Avik Roy.

  17. Learning physics-informed neural networks without stacked back-propagation. AISTATS, 2023. paper

    Di He, Wenlei Shi, Shanda Li, Xiaotian Gao, Jia Zhang, Jiang Bian, Liwei Wang, and Tieyan Liu.

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    Kirill Zubov, Zoe McCarthy, Yingbo Ma, Francesco Calisto, Valerio Pagliarino, Simone Azeglio, Luca Bottero, Emmanuel Luján, Valentin Sulzer, Ashutosh Bharambe, Nand Vinchhi, Kaushik Balakrishnan, Devesh Upadhyay, and Chris Rackauckas.

  19. Physics informed RNN-DCT networks for time-dependent partial differential equations. ICCS, 2022. paper

    Benjamin Wu, Oliver Hennigh, Jan Kautz, Sanjay Choudhry, and Wonmin Byeon.

  20. Theory-guided physics-informed neural networks for boundary layer problems with singular perturbation. JCP, 2022. paper

    Amirhossein Arzani, Kevin W.Cassel, and Roshan M.D'Souza.

  21. A-PINN: Auxiliary physics informed neural networks for forward and inverse problems of nonlinear integro-differential equations. JCP, 2022. paper

    Lei Yuan, Yiqing Ni, Xiangyun Deng, and Shuo Hao.

  22. A mixed formulation for physics-informed neural networks as a potential solver for engineering problems in heterogeneous domains: Comparison with finite element method. CMAME, 2022. paper

    Shahed Rezaei, Ali Harandi, Ahmad Moeineddin, Baixiang Xua, and Stefanie Reese.

  23. Physics-informed neural networks combined with polynomial interpolation to solve nonlinear partial differential equations. Computers & Mathematics with Applications, 2023. paper

    Siping Tang, Xinlong Feng, Wei Wu, and Hui Xu.

  24. A novel sequential method to train physics informed neural networks for Allen Cahn and Cahn Hilliard equations. CMAME, 2022. paper

    Revanth Mattey and Susanta Ghosh.

  25. RPINNs: Rectified-physics informed neural networks for solving stationary partial differential equations. Computers and Fluids, 2022. paper

    Pai Peng, Jiangong Pan, Hui Xu, and Xinlong Feng.

  26. A-WPINN algorithm for the data-driven vector-soliton solutions and parameter discovery of general coupled nonlinear equations. Physica D: Nonlinear Phenomena, 2022. paper

    Shumei Qin, Min Li, Tao Xu, and Shaoqun Dong.

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    E.J.R. Coutinho, M. Dall'Aqua, L. McClenny, M. Zhong, U. Braga-Neto, and E. Gildin.

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  29. Anisotropic, sparse and interpretable physics-informed neural networks for PDEs. arXiv, 2022. paper

    Amuthan A. Ramabathiran and Prabhu Ramachandran.

  30. Fast neural network based solving of partial differential equations. arXiv, 2022. paper

    Jaroslaw Rzepecki, Daniel Bates, and Chris Doran.

  31. Discontinuity computing using physics-informed neural network. arXiv, 2022. paper

    Li Liu, Shengping Liu, Hui Xie, Fansheng Xiong, Tengchao Yu, Mengjuan Xiao, Lufeng Liu, and Heng Yong.

  32. Learning differentiable solvers for systems with hard constraints. arXiv, 2022. paper

    Geoffrey Négiar, Michael W. Mahoney, and Aditi S. Krishnapriyan.

  33. Momentum diminishes the effect of spectral bias in physics-informed neural networks. arXiv, 2022. paper

    Ghazal Farhani, Alexander Kazachek, and Boyu Wang.

  34. Δ-PINNs: Physics-informed neural networks on complex geometries. arXiv, 2022. paper

    Francisco Sahli Costabal, Simone Pezzuto, and Paris Perdikaris.

  35. Replacing automatic differentiation by Sobolev Cubatures fastens physics informed neural nets and strengthens their approximation power. arXiv, 2022. paper

    Juan Esteban Suarez Cardona and Michael Hecht.

  36. FO-PINNs: A first-order formulation for physics informed neural networks. arXiv, 2022. paper

    Rini J. Gladstone, Mohammad A. Nabian, and Hadi Meidani.

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    Zheyuan Hu, Ameya D. Jagtap, George Em Karniadakis, and Kenji Kawaguchi.

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    Paul Escapil-Inchauspé and Gonzalo A. Ruz.

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    Kuangdai Leng and Jeyan Thiyagalingam.

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    Jiawei Guo, Yanzhong Yao, Han Wang, and Tongxiang Gu.

  42. L-HYDRA: Multi-head physics-informed neural networks. arXiv, 2023. paper

    Zongren Zou and George Em Karniadakis.

  43. PINN for dynamical partial differential equations is not training deeper networks rather learning advection and time variance. arXiv, 2023. paper

    Siddharth Rout.

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    Ziya Uddin, Sai Ganga, Rishi Asthana, and Wubshet Ibrahim.

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    Akarsh Pokkunuru, Pedram Rooshenas, Thilo Strauss, Anuj Abhishek, and Taufiquar Khan.

  46. Adaptive weighting of Bayesian physics informed neural networks for multitask and multiscale forward and inverse problems. arXiv, 2023. paper

    Sarah Perez, Suryanarayana Maddu, Ivo F. Sbalzarini, and Philippe Poncet.

  47. Efficient physics-informed neural networks using hash encoding. arXiv, 2023. paper

    Xinquan Huang and Tariq Alkhalifah.

  48. Ensemble learning for physics informed neural networks: A gradient boosting approach. arXiv, 2023. paper

    Zhiwei Fang, Sifan Wang, and Paris Perdikaris.

  49. On the limitations of physics-informed deep learning: Illustrations using first order hyperbolic conservation law-based traffic flow models. arXiv, 2023. paper

    Archie J. Huang and Shaurya Agarwal.

  50. Achieving high accuracy with PINNs via energy natural gradients. arXiv, 2023. paper

    Johannes Müller and Marius Zeinhofer.

  51. Implicit stochastic gradient descent for training physics-informed neural networks. arXiv, 2023. paper

    Ye Li, Songcan Chen, and Shengjun Huang.

  52. NSGA-PINN: A multi-objective optimization method for physics-informed neural network training. arXiv, 2023. paper

    Binghang Lu, Christian B. Moya, and Guang Lin.

  53. Improving physics-informed neural networks with meta-learned optimization. JMLR, 2024. paper

    Alex Bihlo.

  54. Separable physics-informed neural networks. NIPS, 2023. paper

    Junwoo Cho, Seungtae Nam, Hyunmo Yang, Seok-Bae Yun, Youngjoon Hong, and Eunbyung Park

  55. MetaPhysiCa: OOD robustness in physics-informed machine learning. arXiv, 2023. paper

    S Chandra Mouli, Muhammad Ashraful Alam, and Bruno Ribeiro.

  56. HomPINNs: Homotopy physics-informed neural networks for solving the inverse problems of nonlinear differential equations with multiple solutions. arXiv, 2023. paper

    Haoyang Zheng, Yao Huang, Ziyang Huang, Wenrui Hao, and Guang Lin.

  57. iPINNs: Incremental learning for physics-informed neural networks. arXiv, 2023. paper

    Aleksandr Dekhovich, Marcel H.F. Sluiter, David M.J. Tax, and Miguel A. Bessa.

  58. Global convergence of deep Galerkin and PINNs methods for solving partial differential equations. arXiv, 2023. paper

    Francisco Eiras, Adel Bibi, Rudy Bunel, Krishnamurthy Dj Dvijotham, Philip Torr, and M. Pawan Kumar.

  59. Provably correct physics-informed neural networks. arXiv, 2023. paper

    Deqing Jiang, Justin Sirignano, and Samuel N. Cohen.

  60. Predictive limitations of physics-informed neural networks in vortex shedding. arXiv, 2023. paper

    Pi-Yueh Chuang and Lorena A. Barba.

  61. Residual-based error bound for physics-informed neural networks. arXiv, 2023. paper

    Shuheng Liu, Xiyue Huang, and Pavlos Protopapas.

  62. Automatic boundary fitting framework of boundary dependent physics-informed neural network solving partial differential equation with complex boundary conditions. CMAME, 2023. paper

    Yuchen Xie, Yu Ma, and Yahui Wang.

  63. Solving a class of multi-scale elliptic PDEs by means of Fourier-based mixed physics informed neural networks. arXiv, 2023. paper

    Xi'an Li, Jinran Wu, Zhi-Qin John Xu, and You-Gan Wang.

  64. Separable physics informed neural networks. arXiv, 2023. paper

    Junwoo Cho, Seungtae Nam, Hyunmo Yang, Seok-Bae Yun, Youngjoon Hong, and Eunbyung Park.

  65. Achieving high accuracy with PINNs via energy natural gradient descent. ICML, 2023. paper

    Johannes Müller and Marius Zeinhofer.

  66. Gradient descent finds the global optima of two-layer physics-informed neural networks. ICML, 2023. paper

    Yihang Gao, Yiqi Gu, and Michael Ng.

  67. Residual-based attention in physics-informed neural networks. CMAME, 2024. paper

    Sokratis J. Anagnostopoulos, Juan Diego Toscano, Nikolaos Stergiopulos, and George Em Karniadakis.

  68. Auxiliary-tasks learning for physics-informed neural network-based partial differential equations solving. arXiv, 2023. paper

    Junjun Yan, Xinhai Chen, Zhichao Wang, Enqiang Zhou, and Jie Liu.

  69. Tackling the curse of dimensionality with physics-informed neural networks. arXiv, 2023. paper

    Zheyuan Hu, Khemraj Shukla, George Em Karniadakis, and Kenji Kawaguchi.

  70. Solving PDEs on spheres with physics-informed convolutional neural networks. arXiv, 2023. paper

    Guanhang Lei, Zhen Lei, Lei Shi, Chenyu Zeng, and Dingxuan Zhou.

  71. Solving PDEs on spheres with physics-informed convolutional neural networks. arXiv, 2023. paper

    Guanhang Lei, Zhen Lei, Lei Shi, Chenyu Zeng, and Dingxuan Zhou.

  72. Tensor-compressed back-propagation-free training for (physics-informed) neural networks. arXiv, 2023. paper

    Yequan Zhao, Xinling Yu, Zhixiong Chen, Ziyue Liu, Sijia Liu, and Zheng Zhang.

  73. How to select physics-informed neural networks in the absence of ground truth: A pareto front-based strategy. ICML, 2023. paper

    Zhao Wei, Jian Cheng Wong, Nicholas Wei Yong Sung, Abhishek Gupta, Chin Chun Ooi, Pao-Hsiung Chiu, My Ha Dao, and Yew-Soon Ong.

  74. A gradient-enhanced physics-informed neural network (gPINN) scheme for the coupled non-fickian/non-fourierian diffusion-thermoelasticity analysis: A novel gPINN structure. EAAI, 2023. paper

    Katayoun Eshkofti and Seyed Mahmoud Hosseini.

  75. Learning only on boundaries: A physics-informed neural operator for solving parametric partial differential equations in complex geometries. arXiv, 2023. paper

    Zhiwei Fang, Sifan Wang, and Paris Perdikaris.

  76. Exact and soft boundary conditions in physics-informed neural networks for the variable coefficient poisson equation. arXiv, 2023. paper

    Sebastian Barschkis.

  77. Investigating the ability of PINNs to solve burgers’ PDE near finite-time blowup. arXiv, 2023. paper

    Dibyakanti Kumar and Anirbit Mukherjee.

  78. Correcting model misspecification in physics-informed neural networks (PINNs). CMAME, 2024. paper

    Zongren Zou, Xuhui Meng, and George Em Karniadakis.

  79. On residual minimization for PDEs: Failure of PINN, modified equation, and implicit bias. arXiv, 2023. paper

    Tao Luo and Qixuan Zhou.

  80. Operator learning enhanced physics-informed neural networks for solving partial differential equations characterized by sharp solutions. arXiv, 2023. paper

    Bin Lin, Zhiping Mao, Zhicheng Wang, and George Em Karniadakis.

  81. PINNs-TF2: Fast and user-friendly physics-informed neural networks in TensorFlow V2. NIPS, 2023. paper

    Reza Akbarian Bafghi and Maziar Raissi.

  82. Filtered partial differential equations: A robust surrogate constraint in physics-informed deep learning framework. arXiv, 2023. paper

    Dashan Zhang, Yuntian Chen, and Shiyi Chen.

  83. Enhanced physics-informed neural networks with domain scaling and residual correction methods for multi-frequency elliptic problems. arXiv, 2023. paper

    Deok-Kyu Jang, Hyea Hyun Kim, and Kyungsoo Kim.

  84. Physics-informed neural networks for transformed geometries and manifolds. arXiv, 2023. paper

    Samuel Burbulla.

    Zheyuan Hu, Zhouhao Yang, Yezhen Wang, George Em Karniadakis, and Kenji Kawaguchi.

  85. Neuro-PINN: A hybrid framework for efficient nonlinear projection equation solutions. The International Journal for Numerical Methods in Engineering, 2023. paper

    Dawen Wu and Abdel Lisser.

  86. Exactly conservative physics-informed neural networks and deep operator networks for dynamical systems. arXiv, 2023. paper

    Elsa Cardoso-Bihlo and Alex Bihlo.

  87. Semi-analytic PINN methods for boundary layer problems in a rectangular domain. arXiv, 2023. paper

    Gungmin Gie, Youngjoon Hong, Chang-Yeol Jung, and Tselmuun Munkhjin.

  88. PICL: Physics informed contrastive learning for partial differential equations. arXiv, 2024. paper

    Cooper Lorsung and Amir Barati Farimani.

  89. Fourier warm start for physics-informed neural networks. EAAI, 2024. paper

    Ge Jin, Jian Cheng Wong, Abhishek Gupta, Shipeng Li, and Yew-Soon Ong.

  90. Preconditioning for physics-informed neural networks. ICML, 2024. paper

    Songming Liu, Chang Su, Jiachen Yao, Zhongkai Hao, Hang Su, Youjia Wu, and Jun Zhu.

  91. RBF-PINN: Non-Fourier positional embedding in physics-informed neural networks. arXiv, 2024. paper

    Chengxi Zeng, Tilo Burghardt, and Alberto M Gambaruto.

  92. Training dynamics in physics-informed neural networks with feature mapping. arXiv, 2024. paper

    Chengxi Zeng, Tilo Burghardt, and Alberto M Gambaruto.

  93. Score-based physics-informed neural networks for high-dimensional Fokker-Planck equations. arXiv, 2024. paper

    Zheyuan Hu, Zhongqiang Zhang, George Em Karniadakis, and Kenji Kawaguchi.

  94. Investigation of compressor cascade flow using physics-informed neural networks with adaptive learning strategy. AIAA Journal, 2024. paper

    Zhihui Li, Francesco Montomoli, and Sanjiv Sharma.

  95. Exact enforcement of temporal continuity in sequential physics-informed neural networks. arXiv, 2024. paper

    Pratanu Roy and Stephen Castonguay.

  96. Multiple scattering simulation via physics-informed neural networks. arXiv, 2024. paper

    Siddharth Nair, Timothy F. Walsh, Greg Pickrell, and Fabio Semperlotti.

  97. Toward a better understanding of Fourier neural operators: Analysis and improvement from a spectral perspective. arXiv, 2024. paper

    Shaoxiang Qin, Fuyuan Lyu, Wenhui Peng, Dingyang Geng, Ju Wang, Naiping Gao, Xue Liu, and Liangzhu Leon Wang.

  98. Anti-derivatives approximator for enhancing physics-informed neural networks. CMAME, 2024. paper

    Jeongsu Lee.

  99. GMC-PINNs: A new general Monte Carlo PINNs methodfor solving fractional partial differential equations on irregular domains. arXiv, 2024. paper

    Shupeng Wang and George Em Karniadakis.

  100. CEENs: Causality-enforced evolutional networks for solving time-dependent partial differential equations. CMAME, 2024. paper

    Jeahan Jung, Heechang Kim, Hyomin Shin, and Minseok Choi.

  101. PTPI-DL-ROMs: Pre-trained physics-informed deep learning-based reduced order models for nonlinear parametrized PDEs. arXiv, 2024. paper

    Simone Brivio, Stefania Fresca, and Andrea Manzoni.

  102. Closed-form symbolic solutions: A new perspective on solving partial differential equations. arXiv, 2024. paper

    Shu Wei, Yanjie Li, Lina Yu, Min Wu, Weijun Li, Meilan Hao, Wenqiang Li, Jingyi Liu, and Yusong Deng.

  103. RoPINN: Region optimized physics-informed neural networks. arXiv, 2024. paper

    Haixu Wu, Huakun Luo, Yuezhou Ma, Jianmin Wang, and Mingsheng Long.

  104. Interface PINNs (I-PINNs): A physics-informed neural networks framework for interface problems. CMAME, 2024. paper

    Antareep Kumar Sarma, Sumanta Roy, Chandrasekhar Annavarapu, Pratanu Roy, and Shriram Jagannathan.

  105. Parameterized physics-informed neural networks for parameterized PDEs. ICML, 2024. paper

    Woojin Cho, Minju Jo, Haksoo Lim, Kookjin Lee, Dongeun Lee, Sanghyun Hong, and Noseong Park.

  106. Development of backward compatible physics-informed neural networks to reduce error accumulation based on a nested framework. PoF, 2024. paper

    Lei Gao, Yaoran Chen, Guohui Hu, Dan Zhang, Xiangyu Zhang, and Xiaowei Li.

  107. Improved physics-informed neural networks for the reinterpreted discrete fracture model. JCP, 2024. paper

    Chao Wang, Hui Guo, Xia Yan, Zhanglei Shi, and Yang Yang.

  108. How does PDE order affect the convergence of PINNs? NIPS, 2024. paper

    Chang hoon Song, Yesom Park, and Myungjoo Kang.

  1. Learning nonlinear operators via DeepONet based on the universal approximation theorem of operators. NMI, 2021. paper

    Lu Lu, Pengzhan Jin, Guofei Pang, Zhongqiang Zhang, and George Em Karniadakis.

  2. Learning the solution operator of parametric partial differential equations with physics-informed DeepONets. SA, 2021. paper

    Wang Sifan, Hanwen Wang, and Paris Perdikaris.

  3. Deep transfer operator learning for partial differential equations under conditional shift. NMI, 2022. paper

    Somdatta Goswami, Katiana Kontolati, Michael D. Shields, and George Em Karniadakis.

  4. Variable-input deep operator networks. arXiv, 2022. paper

    Michael Prasthofer, Tim De Ryck, and Siddhartha Mishra.

  5. MIONet: Learning multiple-input operators via tensor product. arXiv, 2022. paper

    Jeremy Yu, Lu Lu, Xuhui Meng, and George Em Karniadakis.

  6. Long-time integration of parametric evolution equations with physics-informed DeepONets. arXiv, 2021. paper

    Sifan Wang and Paris Perdikaris.

  7. Improved architectures and training algorithms for deep operator networks. Journal of Scientific Computing, 2022. paper

    Sifan Wang, Hanwen Wang, and Paris Perdikaris.

  8. SVD perspectives for augmenting DeepONet flexibility and interpretability. arXiv, 2022. paper

    Simone Venturi and Tiernan Casey.

  9. Accelerated replica exchange stochastic gradient Langevin diffusion enhanced Bayesian DeepONet for solving noisy parametric PDEs. arXiv, 2021. paper

    Guang Lin, Christian Moya, and Zecheng Zhang.

  10. Bi-fidelity modeling of uncertain and partially unknown systems using DeepONet. arXiv, 2022. paper

    Subhayan De, Matthew Reynolds, Malik Hassanaly, Ryan N. King, and Alireza Doostan.

  11. MultiAuto-DeepONet: A multi-resolution autoencoder DeepONet for nonlinear dimension reduction, uncertainty quantification and operator learning of forward and inverse stochastic problems. arXiv, 2022. paper

    Jiahao Zhang, Shiqi Zhang, and Guang Lin.

  12. Transfer learning enhanced DeepONet for long-time prediction of evolution equations. AAAI, 2023. paper

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  15. Sequential deep learning operator network (S-DeepONet) for time-dependent loads. arXiv, 2023. paper

    Jaewan Park, Shashank Kushwaha, Junyan He, Seid Koric, Diab Abueidda, and Iwona Jasiuk.

  16. Asymptotic-preserving convolutional DeepONets capture the diffusive behavior of the multiscale linear transport equations. arXiv, 2023. paper

    Keke Wu, Xiong-bin Yan, Shi Jin, and Zheng Ma.

  17. A hybrid decoder-DeepONet operator regression framework for unaligned observation data. arXiv, 2023. paper

    Bo Chen, Chenyu Wang, Weipeng Li, and Haiyang Fu.

  18. Improving physics-informed DeepONets with hard constraints. arXiv, 2023. paper

    Rüdiger Brecht, Dmytro R. Popovych, Alex Bihlo, and Roman O. Popovych.

  19. Capturing the diffusive behavior of the multiscale linear transport equations by asymptotic-preserving convolutional DeepONets. CMAME, 2023. paper

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  20. DON-LSTM: Multi-resolution learning with DeepONets and long short-term memory neural networks. arXiv, 2023. paper

    Katarzyna Michałowska, Somdatta Goswami, George Em Karniadakis, and Signe Riemer-Sørensen.

  21. DeepOnet based preconditioning strategies for solving parametric linear systems of equations. arXiv, 2024. paper

    Alena Kopaničáková and George Em Karniadakis.

  22. Derivative-enhanced deep operator network. arXiv, 2024. paper

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  24. Learning nonlinear operators in latent spaces for real-time predictions of complex dynamics in physical systems. NC, 2024. paper

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  1. Fourier neural operator for parametric partial differential equations. ICLR, 2021. paper

    Zongyi Li, Nikola Borislavov Kovachki, Kamyar Azizzadenesheli, Burigede liu, Kaushik Bhattacharya, Andrew Stuart, and Anima Anandkumar.

  2. On universal approximation and error bounds for Fourier neural operators. JMLR, 2021. paper

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  4. Neural operator: Graph kernel network for partial Differential equations. arXiv, 2020. paper

    Zongyi Li, Nikola Kovachki, Kamyar Azizzadenesheli, Burigede Liu, Kaushik Bhattacharya, Andrew Stuart, and Anima Anandkumar.

  5. Fourier neural operator with learned deformations for PDEs on general geometries. arXiv, 2022. paper

    Zongyi Li, Daniel Zhengyu Huang, Burigede Liu, and Anima Anandkumar.

  6. Multipole graph neural operator for parametric partial differential equations. NIPS, 2020. paper

    Zongyi Li, Nikola Kovachki, Kamyar Azizzadenesheli, Burigede Liu, Kaushik Bhattacharya, Andrew Stuart, and Anima Anandkumar.

  7. Fast sampling of diffusion models via operator learning. ICML, 2023. paper

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  8. Factorized Fourier neural operators. ICLR, 2023. paper

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  9. Model inversion for spatio-temporal processes using the Fourier neural operator. NIPS, 2023. paper

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  10. Learning deep implicit Fourier neural operators (IFNOs) with applications to heterogeneous material modeling. CMAME, 2022. paper

    Huaiqian You, Quinn Zhang, Colton J. Ross, Chung-Hao Lee, and Yue Yu.

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  12. Semi-supervised learning of partial differential operators and dynamical flows. arXiv, 2022. paper

    Michael Rotman, Amit Dekel, Ran Ilan Ber, Lior Wolf, and Yaron Oz.

  13. Non-equispaced Fourier neural solvers for PDEs. arXiv, 2022. paper

    Haitao Lin, Lirong Wu, Yongjie Xu, Yufei Huang, Siyuan Li, Guojiang Zhao, Stan Z, and Li Cari.

  14. Incremental spectral learning Fourier neural operator. arXiv, 2022. paper

    Jiawei Zhao, Robert Joseph George, Yifei Zhang, Zongyi Li, and Anima Anandkumar.

  15. Fourier continuation for exact derivative computation in physics-informed neural operators. arXiv, 2022. paper

    Haydn Maust, Zongyi Li, Yixuan Wang, Daniel Leibovici, Oscar Bruno, Thomas Hou, and Anima Anandkumar.

  16. Non-equispaced Fourier neural solvers for PDEs. arXiv, 2023. paper

    Haitao Lin, Lirong Wu, Yongjie Xu, Yufei Huang, Siyuan Li, Guojiang Zhao, Stan Z, and Li Cari.

  17. Learning-based solutions to nonlinear hyperbolic PDEs: Empirical insights on generalization errors. arXiv, 2023. paper

    Bilal Thonnam Thodi, Sai Venkata Ramana Ambadipudi, and Saif Eddin Jabari.

  18. Domain agnostic Fourier neural operators. arXiv, 2023. paper

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  19. Spherical Fourier neural operators: Learning stable dynamics on the sphere. ICML, 2023. paper

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  20. Group equivariant Fourier neural operators for partial differential equations. ICML, 2023. paper

    Jacob Helwig, Xuan Zhang, Cong Fu, Jerry Kurtin, Stephan Wojtowytsch, and Shuiwang Ji.

  21. Speeding up Fourier neural operators via mixed precision. arXiv, 2023. paper

    Colin White, Renbo Tu, Jean Kossaifi, Gennady Pekhimenko, Kamyar Azizzadenesheli, and Anima Anandkumar.

  22. Geometry-informed neural operator for large-scale 3D PDEs. arXiv, 2023. paper

    Zongyi Li, Nikola Borislavov Kovachki, Chris Choy, Boyi Li, Jean Kossaifi, Shourya Prakash Otta, Mohammad Amin Nabian, Maximilian Stadler, Christian Hundt, Kamyar Azizzadenesheli, and Anima Anandkumar.

  23. Deep equilibrium based neural operators for steady-state PDEs. NIPS, 2023. paper

    Tanya Marwah, Ashwini Pokle, J Zico Kolter, Zachary Chase Lipton, Jianfeng Lu, and Andrej Risteski.

  24. A born fourier neural operator for solving Poisson’s equation with limited data and arbitrary domain deformation. TAP, 2023. paper

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  25. Approximating numerical flux by Fourier neural operators for the hyperbolic conservation laws. arXiv, 2024. paper

    Taeyoung Kim and Myungjoo Sang.

  26. Invertible Fourier neural operators for tackling both forward and inverse problems. arXiv, 2024. paper

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  27. An operator learning perspective on parameter-to-observable maps. arXiv, 2024. paper

    Daniel Zhengyu Huang, Nicholas H. Nelsen, and Margaret Trautner.

  28. Learning the boundary-to-domain mapping using lifting product Fourier neural operators for partial differential equations. ICML, 2024. paper

    Aditya Kashi, Arka Daw, Muralikrishnan Gopalakrishnan Meena, and Hao Lu.

  29. Accelerating phase field simulations through a hybrid adaptive fourier neural operator with U-net backbone. arXiv, 2024. paper

    Christophe Bonneville, Nathan Bieberdorf, Arun Hegde, Mark Asta, Habib N. Najm, Laurent Capolungo, and Cosmin Safta.

  30. Gabor-filtered Fourier neural operator for solving partial differential equations. Computers & Fluids, 2024. paper

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  31. Component Fourier neural operator for singularly perturbed differential equations. AAAI, 2024. paper

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    Qingsong Xu, Nils Thuerey, Yilei Shi, Jonathan Bamber, Chaojun Ouyang, and Xiaoxiang Zhu.

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    Zongyi Li, Hongkai Zheng, Nikola Kovachki, David Jin, Haoxuan Chen, Burigede Liu, Kamyar Azizzadenesheli, and Anima Anandkumar.

  34. Liquid Fourier latent dynamics networks for fast GPU-based numerical simulations in computational cardiology. arXiv, 2024. paper

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  35. Graph Fourier neural kernels (G-FUNK): Learning solutions of nonlinear diffusive parametric PDEs on multiple domains. arXiv, 2024. paper

    Shane E. Loeffler, Zan Ahmad, Syed Yusuf Ali, Carolyna Yamamoto, Dan M. Popescu, Alana Yee, Yash Lal, Natalia Trayanova, and Mauro Maggioni.

  1. Message passing neural PDE solvers. ICLR, 2022. paper

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  2. Predicting physics in mesh-reduced space with temporal attention. ICLR, 2022. paper

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  6. Learning the solution operator of boundary value problems using graph neural networks. ICML, 2022. paper

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  7. Physics-informed graph neural Galerkin networks: A unified framework for solving PDE-governed forward and inverse problems. CMAME, 2022. paper

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  8. Modular flows: Differential molecular generation. NIPS, 2022. paper

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  9. Learning to solve PDE-constrained inverse problems with graph networks. ICML, 2022. paper

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  24. Neural PDE solvers for irregular domains. arXiv, 2022. paper

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  27. On the robustness of graph neural diffusion to topology perturbations. arXiv, 2022. paper

    Yang Song, Qiyu Kang, Sijie Wang, Zhao Kai, and Wee Peng Tay.

  28. STONet: A neural-operator-driven spatio-temporal network. arXiv, 2022. paper

    Haitao Lin, Guojiang Zhao, Lirong Wu, and Stan Z. Li.

  29. PhyGNNet: Solving spatiotemporal PDEs with physics-informed graph neural network. arXiv, 2022. paper

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  30. Differentiable physics-informed graph networks. arXiv, 2019. paper

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  31. MG-GNN: Multigrid graph neural networks for learning multilevel domain decomposition methods. ICML, 2023. paper

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    Léonard Equer, T. Konstantin Rusch, and Siddhartha Mishra.

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    Rini Jasmine Gladstone, Helia Rahmani, Vishvas Suryakumar, Hadi Meidani, Marta D'Elia, and Ahmad Zareei.

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    Artur P. Toshev, Gianluca Galletti, Johannes Brandstetter, Stefan Adami, and Nikolaus A. Adams.

  36. Long-short-range message-passing: A physics-informed framework to capture non-local interaction for scalable molecular dynamics simulation. arXiv, 2023. paper

    Yunyang Li, Yusong Wang, Lin Huang, Han Yang, Xinran Wei, Jia Zhang, Tong Wang, Zun Wang, Bin Shao, and Tieyan Liu.

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    Federico Pichi, Beatriz Moya, and Jan S. Hesthaven.

  38. GAD-NR: Graph anomaly detection via neighborhood reconstruction. arXiv, 2023. paper

    Amit Roy, Juan Shu, Jia Li, Carl Yang, Olivier Elshocht, Jeroen Smeets, and Pan Li.

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    Yuyang Miao and Haolin Li.

  40. GNRK: Graph Neural Runge-Kutta method for solving partial differential equations. arXiv, 2023. paper

    Hoyun Choi, Sungyeop Lee, B. Kahng, and Junghyo Jo.

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    Minkai Xu, Jiaqi Han, Aaron Lou, Jean Kossaifi, Arvind Ramanathan, Kamyar Azizzadenesheli, Jure Leskovec, Stefano Ermon, and Anima Anandkumar.

  42. HAMLET: Graph transformer neural operator for partial differential equations. arXiv, 2024. paper

    Andrey Bryutkin, Jiahao Huang, Zhongying Deng, Guang Yang, Carola-Bibiane Schönlieb, and Angelica Aviles-Rivero.

  43. Learning time-dependent PDE via graph neural networks and deep operator network for robust accuracy on irregular grids. arXiv, 2024. paper

    Sung Woong Cho, Jae Yong Lee, and Hyung Ju Hwang.

  44. Towards general neural surrogate solvers with specialized neural accelerators. ICML, 2024. paper

    Chenkai Mao, Robert Lupoiu, Tianxiang Dai, Mingkun Chen, and Jonathan A. Fan.

  45. Graph neural PDE solvers with conservation and similarity-equivariance. ICML, 2024. paper

    Masanobu Horie and Naoto Mitsume.

  46. Spectral-refiner: Fine-tuning of accurate spatiotemporal neural operator for turbulent flows. arXiv, 2024. paper

    Shuhao Cao, Francesco Brarda, Ruipeng Li, and Yuanzhe Xi.

  47. Accelerating simulation of two-phase flows with neural PDE surrogates. arXiv, 2024. paper

    Yoeri Poels, Koen Minartz, Harshit Bansal, and Vlado Menkovski.

  48. PhymPGN: Physics-encoded message passing graph network for spatiotemporal PDE systems. arXiv, 2024. paper

    Bocheng Zeng, Qi Wang, Mengtao Yan, Yang Liu, Ruizhi Chengze, Yi Zhang, Hongsheng Liu, Zidong Wang, and Hao Sun.

  49. IGA-Graph-Net: Isogeometric analysis-reuse method based on graph neural networks for topology-consistent models. JCP, 2024. paper

    Gang Xu, Jin Xie, Weizhen Zhong, Masahiro Toyoura, Ran Ling, Jinlan Xu, Renshu Gu, Charlie C.L. Wang, and Timon Rabczuk.

  1. Learning Green's functions associated with time-dependent partial differential equations. JMLR, 2022. paper

    Nicolas Boullé, Seick Kim, Tianyi Shi, and Alex Townsend.

  2. BI-GreenNet: Learning Green's functions by boundary integral network. arXiv, 2022. paper

    Guochang Lin, Fukai Chen, Pipi Hu, Xiang Chen, Junqing Chen, Jun Wang, and Zuoqiang Shi.

  3. DeepGreen: Deep learning of Green’s functions for nonlinear boundary value problems. Scientific Reports, 2021. paper

    Craig R. Gin, Daniel E. Shea, Steven L. Brunton, and J. Nathan Kutz.

  4. Data-driven discovery of Green’s functions with human-understandable deep learning. Scientific Reports, 2022. paper

    Nicolas Boullé, Christopher J. Earls, and Alex Townsend.

  5. Data-driven discovery of Green's functions. Doctoral Dissertation, 2022. Ph.D.

    Nicolas Boullé.

  6. Principled interpolation of Green's functions learned from data. arXiv, 2022. paper

    Harshwardhan Praveen, Nicolas Boulle, and Christopher Earls.

  7. Deep generalized Green's functions. arXiv, 2023. paper

    Rixi Peng, Juncheng Dong, Jordan Malof, Willie J. Padilla, Vahid Tarokh.

  8. Operator approximation of the wave equation based on deep learning of Green’s function. arXiv, 2023. paper

    Ziad Aldirany, R´egis Cottereau, Marc Laforest, and Serge Prudhomme.

  9. Deep surrogate model for learning Green's function associated with linear reaction-diffusion operator. arXiv, 2023. paper

    Junqing Ji, Lili Ju, and Xiaoping Zhang.

  10. Numerical solutions of boundary problems in partial differential equations: A deep learning framework with Green's function. JCP, 2024. paper

    Yuanjun Dai, Zhi Li, Yiran An, and Wanru Deng.

  11. Multiscale neural networks for approximating Green's functions. arXiv, 2024. paper

    Wenrui Hao, Rui Peng Li, Yuanzhe Xi, Tianshi Xu, and Yahong Yang.

  12. A physics-informed neural network based method for the nonlinear Poisson-Boltzmann equation and its error analysis. JCP, 2024. paper

    Hyeokjoo Park and Gwanghyun Jo.

  1. Composing partial differential equations with physics-aware neural networks. ICML, 2022. paper

    Matthias Karlbauer, Timothy Praditia, Sebastian Otte, Sergey Oladyshkin, and Wolfgang Nowak.

  2. Learning the dynamics of physical systems from sparse observations with finite element networks. ICLR, 2022. paper

    Marten Lienen and Stephan Günnemann.

  3. A unified hard-constraint framework for solving geometrically complex PDEs. NIPS, 2022. paper

    Songming Liu, Zhongkai Hao, Chengyang Ying, Hang Su, Jun Zhu, and Ze Cheng.

  4. LSH-SMILE: Locality sensitive Hashing accelerated simulation and learning. NIPS, 2021. paper

    Chonghao Sima and Yexiang Xue.

  5. Amortized finite element analysis for fast PDE-constrained optimization. ICML, 2020. paper

    Tianju Xue, Alex Beatson, Sigrid Adriaenssens, and Ryan Adams.

  6. Learning neural PDE solvers with convergence guarantees. ICLR, 2019. paper

    Jun-Ting Hsieh, Shengjia Zhao, Stephan Eismann, Lucia Mirabella, and Stefano Ermon.

  7. Hybrid finite difference with the physics-informed neural network for solving PDE in complex geometries. arXiv, 2022. paper

    Zixue Xiang, Wei Peng, Weien Zhou, and Wen Yao.

  8. Multilayer perceptron-based surrogate models for finite element analysis. arXiv, 2022. paper

    Lawson Oliveira Lima, Julien Rosenberger, Esteban Antier, and Frederic Magoules.

  9. Integration of physics-informed operator learning and finite element method for parametric learning of partial differential equations. arXiv, 2024. paper

    Shahed Rezaei, Ahmad Moeineddin, Michael Kaliske, and Markus Apel.

  10. Error assessment of an adaptive finite elements—neural networks method for an elliptic parametric PDE. CMAME, 2024. paper

    Alexandre Caboussat, Maude Girardin, and Marco Picasso.

  11. Predicting unsteady incompressible fluid dynamics with finite volume informed neural network. PoF, 2024. paper

    Tianyu Li, Shufan Zou, Xinghua Chang, Laiping Zhang, and Xiaogang Deng.

  12. Unified finite-volume physics informed neural networks to solve the heterogeneous partial differential equations. KBS, 2024. paper

    Di Mei, Kangcheng Zhou, and Chun-Ho Liu.

  1. PDE-Net: Learning PDEs from data. ICML, 2018. paper

    Zichao Long, Yiping Lu, Xianzhong Ma, and Bin Dong.

  2. PDE-Net 2.0: Learning PDEs from data with a numeric-symbolic hybrid deep network. JCP, 2019. paper

    Zichao Long, Yiping Lu, and Bin Dong.

  3. Physics-informed CNNs for super-resolution of sparse observations on dynamical systems. NIPS, 2022. paper

    Daniel Kelshaw, Georgios Rigas, and Luca Magri.

  4. Deep-pretrained-FWI: Combining supervised learning with physics-informed neural network. NIPS, 2022. paper

    Ana Paula O. Muller, Clecio R. Bom, Jessé C. Costa, Matheus Klatt, Elisângela L. Faria, Marcelo P. de Albuquerque, and Márcio P. de Albuquerque.

  5. Learning time-dependent PDEs with a linear and nonlinear separate convolutional neural network. JCP, 2022. paper

    Jiagang Qu, Weihua Cai, and YijunZhao.

  6. PhyCRNet: Physics-informed convolutional-recurrent network for solving spatiotemporal PDEs. JCP, 2022. paper

    Pu Ren, Chengping Rao, Yang Liu, Jianxun Wang, and Hao Sun.

  7. Spline-PINN: Approaching PDEs without data using fast, physics-informed Hermite-Spline CNNs. AAAI, 2019. paper

    Nils Wandel, Michael Weinmann, Michael Neidlin, and Reinhard Klein.

  8. Deep convolutional Ritz method: Parametric PDE surrogates without labeled data. arXiv, 2022. paper

    Jan Niklas Fuhg, Arnav Karmarkar, Teeratorn Kadeethum, Hongkyu Yoon, and Nikolaos Bouklas.

  9. Deep convolutional architectures for extrapolative forecasts in time-dependent flow problems. arXiv, 2022. paper

    Pratyush Bhatt, Yash Kumar, and Azzeddine Soulaimani.

  10. Phase2Vec: Dynamical systems embedding with a physics-informed convolutional network. arXiv, 2022. paper

    Matthew Ricci, Noa Moriel, Zoe Piran, and Mor Nitzan.

  11. Numerical approximation based on deep convolutional neural network for high-dimensional fully nonlinear merged PDEs and 2BSDEs. arXiv, 2022. paper

    Xu Xiao and Wenlin Qiu.

  12. SplineCNN: Fast geometric deep learning with continuous B-spline kernels. CVPR, 2018. paper

    Matthias Fey, Jan Eric Lenssen, Frank Weichert, and Heinrich Muller.

  13. Physics-informed deep super-resolution for spatiotemporal data. arXiv, 2022. paper

    Pu Ren, Chengping Rao, Yang Liu, Zihan Ma, Qi Wang, Jianxun Wang, and Hao Sun.

  14. MeshFreeFLowNet: A physics-constrained deep continuous space-time super-resolution framework. SC20, 2020. paper

    Chiyu Max Jiang, Soheil Esmaeilzadeh, Kamyar Azizzadenesheli, Karthik Kashinath, Mustafa Mustafa, Hamdi A. Tchelepi, Philip Marcus Prabhat, and Anima Anandkumar.

  15. Convolutional neural operators. arXiv, 2023. paper

    Bogdan Raonić, Roberto Molinaro, Tobias Rohner, Siddhartha Mishra, and Emmanuel de Bezenac.

  16. An unsupervised latent/output physics-informed convolutional-LSTM network for solving partial differential equations using peridynamic differential operator. CMAME, 2023. paper

    Arda Mavi, Ali Can Bekar, Ehsan Haghigh, and Erdogan Madenci.

  17. Clifford neural layers for PDE modeling. ICLR, 2023. paper

    Johannes Brandstetter, Rianne van den Berg, Max Welling, and Jayesh K Gupta.

  18. Neural partial differential equations with functional convolution. arXiv, 2023. paper

    Ziqian Wu, Xingzhe He, Yijun Li, Cheng Yang, Rui Liu, Shiying Xiong, and Bo Zhu.

  19. Multilevel CNNs for parametric PDEs. arXiv, 2023. paper

    Cosmas Heiß, Ingo Gühring, and Martin Eigel.

  20. Encoding physics to learn reaction–diffusion processes. NMI, 2023. paper

    Chengping Rao, Pu Ren, Qi Wang, Oral Buyukozturk, Hao Sun, and Yang Liu.

  21. PhySR: Physics-informed deep super-resolution for spatiotemporal data. JCP, 2023. paper

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  15. Nonlinear reconstruction for operator learning of PDEs with discontinuities. arXiv, 2022. paper

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    Andrew Gracyk and Xiaohui Chen.

  17. Render unto numerics: Orthogonal polynomial neural operator for PDEs with non-periodic boundary conditions. arXiv, 2022. paper

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  19. Guiding continuous operator learning through physics-based boundary constraints. arXiv, 2022. paper

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  20. BelNet: Basis enhanced learning, a mesh-free neural operator. arXiv, 2022. paper

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  21. INO: Invariant neural operators for learning complex physical systems with momentum conservation. arXiv, 2022. paper

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  22. BINN: A deep learning approach for computational mechanics problems based on boundary integral equations. arXiv, 2023. paper

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  1. Prompting in-context operator learning with sensor data, equations, and natural language. arXiv, 2023. paper

    Liu Yang, Tingwei Meng, Siting Liu, and Stanley J. Osher.

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    Wuyang Chen, Jialin Song, Pu Ren, Shashank Subramanian, Dmitriy Morozov, and Michael W. Mahoney.

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  1. PDEBench: An extensive benchmark for scientific machine learning. NIPS, 2022. paper

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  20. Differentiable programming across the PDE and machine learning barrier. arXiv, 2024. paper

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  21. FlowBench: A large scale benchmark for flow simulation over complex geometries. arXiv, 2024. paper

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  1. Characterizing possible failure modes in physics-informed neural networks. NIPS, 2021. paper

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  22. Meta learning of interface conditions for multi-domain physics-informed neural networks. ICML, 2023. paper

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  1. Adaptive activation functions accelerate convergence in deep and physics-informed neural networks. JCP, 2021. paper

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  3. Self-adaptive loss balanced Physics-informed neural networks. Neurocomputing, 2022. paper

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    Rafael Bischof and Michael Kraus.

  5. Self-scalable Tanh (Stan): Faster convergence and better generalization in physics-informed neural networks. arXiv, 2022. paper

    Raghav Gnanasambandam, Bo Shen, Jihoon Chung, Xubo Yue, and Zhenyu (James) Kong.

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    Chuwei Wang, Shanda Li, Di He, and Liwei Wang.

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    Vignesh Gopakumar, Stanislas Pamela, and Debasmita Samaddar.

  8. Implicit stochastic gradient descent for training physics-informed neural networks. AAAI, 2023. paper

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    Vasiliy A. Es'kin, Danil V. Davydov, Ekaterina D. Egorova, Alexey O. Malkhanov, Mikhail A. Akhukov, and Mikhail E. Smorkalov.

  10. Fourier-MIONet: Fourier-enhanced multiple-input neural operators for multiphase modeling of geological carbon sequestration. arXiv, 2023. paper

    Zhongyi Jiang, Min Zhu, Dongzhuo Li, Qiuzi Li, Yanhua O. Yuan, and Lu Lu.

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    Ehsan Saleh, Saba Ghaffari, Timothy Bretl, Luke Olson, and Matthew West.

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    Zhiwei Wang, Lulu Zhang, Zhongwang Zhang, and Zhi-Qin John Xu.

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  18. A practical PINN framework for multi-scale problems with multi-magnitude loss terms. CMAME, 2024. paper

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  1. ADLGM: An efficient adaptive sampling deep learning Galerkin method. JCP, 2023. paper

    Andreas C.Aristotelous, Edward C.Mitchell, and Vasileios Maroulasb.

  2. DMIS: Dynamic mesh-based importance sampling for training physics-informed neural networks. AAAI, 2023. paper

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  3. A comprehensive study of non-adaptive and residual-based adaptive sampling for physics-informed neural networks. CMAME, 2023. paper

    Chenxi Wua, Min Zhua, Qinyang Tan, YadhKartha, and Lu Lu.

  4. Mitigating propagation failures in PINNs using evolutionary sampling. arXiv, 2022. paper

    Arka Daw, Jie Bu, Sifan Wang, Paris Perdikaris, and Anuj Karpatne.

  5. Residual-quantile adjustment for adaptive training of physics-informed neural network. arXiv, 2022. paper

    Jiayue Han, Zhiqiang Cai, Zhiyou Wu, and Xiang Zhou.

  6. Adversarial sampling for solving differential equations with neural networks. NIPS, 2021. paper

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  7. A novel adaptive causal sampling method for physics-informed neural networks. arXiv, 2022. paper

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  8. Physics-informed neural networks with residual/gradient-based adaptive sampling methods for solving PDEs with sharp solutions. arXiv, 2023. paper

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  9. Active learning based sampling for high-dimensional nonlinear partial differential equations. JCP, 2023. paper

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  10. Adversarial adaptive sampling: Unify PINN and optimal yransport for the approximation of PDEs. ICLR, 2024. paper

    Kejun Tang, Jiayu Zhai, Xiaoliang Wan, and Chao Yang.

  11. Coupling parameter and particle dynamics for adaptive sampling in neural Galerkin schemes. arXiv, 2023. paper

    Yuxiao Wen, Eric Vanden-Eijnden, and Benjamin Peherstorfer.

  12. Mitigating propagation failures in physics-informed neural networks using retain-resample-release (R3) sampling. ICML, 2023. paper

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  13. Good lattice training: Physics-informed neural networks accelerated by number theory. arXiv, 2023. paper

    Takashi Matsubara and Takaharu Yaguchi.

  14. Adaptive importance sampling for Deep Ritz. arXiv, 2023. paper

    Xiaoliang Wan, Tao Zhou, and Yuancheng Zhou.

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  1. MeshingNet: A new mesh generation method based on deep learning. ICCS, 2022. paper

    Zheyan Zhang, Yongxing Wang, Peter K. Jimack, and He Wang.

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    Wenbin Song, Mingrui Zhang, Joseph G. Wallwork, Junpeng Gao, Zheng Tian, Fanglei Sun, Matthew D. Piggott, Junqing Chen, Zuoqiang Shi, Xiang Chen, and Jun Wang.

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    Johannes Haubne and Miroslav Kuchta.

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  6. An improved structured mesh generation method based on physics-informed neural networks. arXiv, 2022. paper

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    Fabricio Arend Torres, Marcello Massimo Negri, Monika Nagy-Huber, Maxim Samarin, and Volker Roth.

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    Thi Nguyen Khoa Nguyen, Thibault Dairay, Raphaël Meunier, Christophe Millet, and Mathilde Mougeot.

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  10. A closest point method for surface PDEs with interior boundary conditions for geometry processing. arXiv, 2023. paper

    Nathan King, Haozhe Su, Mridul Aanjaneya, Steven Ruuth, and Christopher Batty.

  11. Efficient training of physics-informed neural networks with direct grid refinement algorithm. arXiv, 2023. paper

    Shikhar Nilabh and Fidel Grandia.

  12. Redefining Super-Resolution: Fine-mesh PDE predictions without classical simulations. arXiv, 2023. paper

    Rajat Kumar Sarkar, Ritam Majumdar, Vishal Jadhav, Sagar Srinivas Sakhinana, and Venkataramana Runkana.

  13. MMPDE-Net and moving sampling physics-informed neural networks based on moving mesh method. arXiv, 2023. paper

    Yu Yang, Qihong Yang, Yangtao Deng, and Qiaolin He.

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    Jiachen Yang, Tarik Dzanic, Brenden Petersen, Jun Kudo, Ketan Mittal, Vladimir Tomov, Jean-Sylvain Camier, Tuo Zhao, Hongyuan Zha, Tzanio Kolev, Robert Anderson, and Daniel Faissol.

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    Roberto Perera and Vinamra Agrawal.

  16. Learning mesh motion techniques with application to fluid–structure interaction. CMAME, 2024. paper

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  17. Learning time-dependent PDE via graph neural networks and deep operator network for robust accuracy on irregular grids. arXiv, 2024. paper

    Sung Woong Cho, Jae Yong Lee, and Hyung Ju Hwang.

  18. Physics-informed mesh-independent deep compositional operator network. arXiv, 2024. paper

    Weiheng Zhong and Hadi Meidani.

  19. End-to-end mesh optimization of a hybrid deep learning black-box PDE solver. arXiv, 2024. paper

    Shaocong Ma, James Diffenderfer, Bhavya Kailkhura, and Yi Zhou.

  20. RoPINN: Region optimized physics-informed neural networks. arXiv, 2024. paper

    Haixu Wu, Huakun Luo, Yuezhou Ma, Jianmin Wang, and Mingsheng Long.

  21. UM2N: Towards universal mesh movement networks. arXiv, 2024. paper

    Mingrui Zhang, Chunyang Wang, Stephan Kramer, Joseph G. Wallwork, Siyi Li, Jiancheng Liu, Xiang Chen, and Matthew D. Piggott.

  1. Composing partial differential equations with physics-aware neural networks. ICLR, 2022. paper

    Matthias Karlbauer, Timothy Praditia, Sebastian Otte, Sergey Oladyshkin, Wolfgang Nowak, and Martin V. Butz.

  2. Learning composable energy surrogates for PDE order reduction. NIPS, 2020. paper

    Alex Beatson, Jordan T. Ash, Geoffrey Roeder, Tianju Xue, and Ryan P. Adams.

  3. Neural basis functions for accelerating solutions to high mach euler equations. ICML, 2022. paper

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  4. PFNN-2: A domain decomposed penalty-free neural network method for solving partial differential equations. arXiv, 2022. paper

    Hailong Shen and Chao Yang.

  5. Finite basis physics-informed neural networks (FBPINNs): A scalable domain decomposition approach for solving differential equations. arXiv, 2021. paper

    Ben Moseley, Andrew Markham, and Tarje Nissen-Meyer.

  6. Finite basis physics-informed neural networks as a Schwarz domain decomposition method. arXiv, 2022. paper

    Victorita Dolean, Alexander Heinlein, Siddhartha Mishra, and Ben Moseley.

  7. NeuralStagger: Accelerating physics constrained neural PDE solver with spatial-temporal decomposition. ICML, 2023. paper

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  9. LordNet: Learning to solve parametric partial differential equations without simulated data. arXiv, 2022. paper

    Wenlei Shi, Xinquan Huang, Xiaotian Gao, Xinran Wei, Jia Zhang, Jiang Bian, Mao Yang, and Tieyan Liu.

  10. An optimisation–based domain–decomposition reduced order model for the incompressible Navier-Stokes equations. arXiv, 2022. paper

    Ivan Prusak, Monica Nonino, Davide Torlo, Francesco Ballarin, and Gianluigi Rozza.

  11. NUNO: A general gramework for learning parametric PDEs with non-uniform data. ICML, 2023. paper

    Songming Liu, Zhongkai Hao, Chengyang Ying, Hang Su, Ze Cheng, and Jun Zhu.

  12. Enhancing training of physics-informed neural networks using domain-decomposition based preconditioning strategies. arXiv, 2023. paper

    Alena Kopaničáková, Hardik Kothari, George Em Karniadakis, and Rolf Krause.

  13. Multilevel domain decomposition-based architectures for physics-informed neural networks. arXiv, 2023. paper

    Victorita Dolean, Alexander Heinlein, Siddhartha Mishra, and Ben Moseley.

  14. Friedrichs' systems discretized with the Discontinuous Galerkin method: Domain decomposable model order reduction and Graph Neural Networks approximating vanishing viscosity solutions. arXiv, 2023. paper

    Francesco Romor, Davide Torlo, and Gianluigi Rozza.

  15. A deep domain decomposition method based on Fourier features. Journal of Computational and Applied Mathematics, 2023. paper

    Sen Li, Yingzhi Xia, Yu Liu, and Qifeng Liao.

  16. A unified scalable framework for causal sweeping strategies for physics-informed neural networks (PINNs) and their temporal decompositions. arXiv, 2023. paper

    Michael Penwarden, Ameya D. Jagtap, Shandian Zhe, George Em Karniadakis, and Robert M. Kirby.

  17. A generalized Schwarz-type non-overlapping domain decomposition method using physics-constrained neural networks. arXiv, 2023. paper

    Shamsulhaq Basir and Inanc Senocak.

  18. Breaking boundaries: Distributed domain decomposition with scalable physics-informed neural PDE solvers. arXiv, 2023. paper

    Arthur Feeney, Zitong Li, Ramin Bostanabad, and Aparna Chandramowlishwaran.

  19. Efficient learning of PDEs via Taylor expansion and sparse decomposition into value and Fourier domains. arXiv, 2023. paper

    Md Nasim and Yexiang Xue.

  20. Adaptive task decomposition physics-informed neural networks. CMAME, 2023. paper

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  21. PF-DMD: Physics-fusion dynamic mode decomposition for accurate and robust forecasting of dynamical systems with imperfect data and physics. arXiv, 2023. paper

    Yuhui Yin, Chenhui Kou, Shengkun Jia, Lu Lu, Xigang Yuan, and Yiqing Luo.

  22. Subspace decomposition based DNN algorithm for elliptic type multi-scale PDEs. JCP, 2023. paper

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  23. Adaptive deep Fourier residual method via overlapping domain decomposition. arXiv, 2024. paper

    Jamie M. Taylor, Manuela Bastidas, Victor M. Calo, and David Pardo.

  1. PDE-driven spatiotemporal disentanglement. ICLR, 2021. paper

    Jérémie Donà, Jean-Yves Franceschi, Sylvain Lamprier, and Patrick Gallinari.

  2. Disentangling physical dynamics from unknown factors for unsupervised video prediction. CVPR, 2020. paper

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  1. Solver-in-the-loop: Learning from differentiable physics to interact with iterative PDE-solvers. NIPS, 2020. paper

    Kiwon Um, Robert Brand, Yun (Raymond) Fei, Philipp Holl, and Nils Thuerey.

  2. Lie point symmetry data augmentation for neural PDE solvers. ICML, 2022. paper

    Johannes Brandstetter, Max Welling, and Daniel E. Worrall.

  3. Incorporating symmetry into deep dynamics models for improved generalization. ICLR, 2021. paper

    Rui Wang, Robin Walters, and Rose Yu.

  4. HyperSolvers: Toward fast continuous-depth models. NIPS, 2020. paper

    Michael Poli, Stefano Massaroli, Atsushi Yamashita, Hajime Asama, and Jinkyoo Park.

  5. PIXEL: Physics-informed cell representations for fast and accurate PDE solvers. NIPS, 2022. paper

    Namgyu Kang, Byeonghyeon Lee, Youngjoon Hong, Seok-Bae Yun, and Eunbyung Park.

  6. NeuralSim: Augmenting differentiable simulators with neural networks. ICRA, 2021. paper

    Eric Heiden, David Millard, Erwin Coumans, Yizhou Sheng, and Gaurav S. Sukhatme.

  7. DPM: A deep learning PDE augmentation method with application to large-eddy simulation. JCP, 2020. paper

    Justin Sirignano, Jonathan F.MacArt, and Jonathan B.Freund.

  8. General covariance data augmentation for neural PDE solvers. ICML, 2023. paper

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  9. Learning preconditioners for conjugate gradient PDE solvers. ICML, 2023. paper

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  10. Autoregressive Renaissance in neural PDE solvers. ICLR, 2023. paper

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  11. Stability of implicit neural networks for long-term forecasting in dynamical systems. ICLR, 2023. paper

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  12. Training deep surrogate models with large scale online learning. ICML, 2023. paper

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  13. Self-supervised learning with Lie symmetries for partial differential equations. arXiv, 2023. paper

    Grégoire Mialon, Quentin Garrido, Hannah Lawrence, Danyal Rehman, Yann LeCun, and Bobak T. Kiani.

  14. Interpretable neural PDE solvers using symbolic frameworks. arXiv, 2023. paper

    Yolanne Yi Ran Lee.

  15. Modeling accurate long rollouts with temporal neural PDE solvers. ICML, 2023. paper

    Phillip Lippe, Bastiaan S. Veeling, Paris Perdikaris, Richard E. Turner, and Johannes Brandstetter.

  16. Neural-integrated meshfree (NIM) method: A differentiable programming-based hybrid solver for computational mechanics. arXiv, 2023. paper

    Honghui Du and Qizhi He.

  17. A deep-genetic algorithm (deep-GA) approach for high-dimensional nonlinear parabolic partial differential equations. Computers & Mathematics with Applications, 2023. paper

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  18. Physics-enhanced deep surrogates for partial differential equations. NMI, 2023. paper

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  19. Better neural PDE solvers through data-free mesh movers. ICLR, 2024. paper

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  20. Generating synthetic data for neural operators. arXiv, 2024. paper

    Erisa Hasani and Rachel A. Ward.

  21. A deep branching solver for fully nonlinear partial differential equations. JCP, 2024. paper

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  22. Accelerating data generation for neural operators via Krylov subspace recycling. ICLR, 2024. paper

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  23. Space and time continuous physics simulation from partial observations. ICLR, 2024. paper

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  24. Speeding up and reducing memory usage for scientific machine learning via mixed precision. arXiv, 2024. paper

    Joel Hayford, Jacob Goldman-Wetzler, Eric Wang, and Lu Lu.

  25. Neural operators meet conjugate gradients: The FCG-NO method for efficient PDE solving. arXiv, 2024. paper

    Alexander Rudikov, Vladimir Fanaskov, Ekaterina Muravleva, Yuri M. Laevsky, and Ivan Oseledets.

  26. Learning operators with stochastic gradient descent in general Hilbert spaces. arXiv, 2024. paper

    Lei Shi and Jiaqi Yang.

  27. Accelerating PDE data generation via differential operator action in solution space. ICML, 2024. paper

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  28. Correctness verification of neural networks approximating differential equations. arXiv, 2024. paper

    Petros Ellinas, Rahul Nellikath, Ignasi Ventura, Jochen Stiasny, and Spyros Chatzivasileiadis.

  29. DOF: Accelerating high-order differential operators with forward propagation. arXiv, 2024. paper

    Ruichen Li, Chuwei Wang, Haotian Ye, Di He, and Liwei Wang.

  30. Sobolev training for operator learning. arXiv, 2024. paper

    Namkyeong Cho, Junseung Ryu, and Hyung Ju Hwang.

  31. Scaling physics-informed hard constraints with mixture-of-experts. ICLR, 2024. paper

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  32. Learning semilinear neural operators: A unified recursive framework for prediction and data assimilation. ICLR, 2024. paper

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  33. Efficient and stable SAV-based methods for gradient flows arising from deep learning. JCP, 2024. paper

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  34. Generative downscaling of PDE solvers with physics-guided diffusion models. arXiv, 2024. paper

    Yulong Lu and Wuzhe Xu.

  35. Nearest neighbors GParareal: Improving scalability of Gaussian processes for parallel-in-Time solvers. arXiv, 2024. paper

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  36. Large scale scattering using fast solvers based on neural operators. arXiv, 2024. paper

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  39. Optical neural engine for solving scientific partial differential equations. arXiv, 2024. paper

    Yingheng Tang, Ruiyang Chen, Minhan Lou, Jichao Fan, Cunxi Yu, Andy Nonaka, Zhi Yao, and Weilu Gao.

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  41. RandNet-Parareal: A time-parallel PDE solver using random neural networks. NIPS, 2024. paper

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  1. Auto-PINN: Understanding and optimizing physics-informed neural architecture. arXiv, 2022. paper

    Yicheng Wang, Xiaotian Han, Chiayuan Chang, Daochen Zha, Ulisses Braga-Neto, and Xia Hu.

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  3. Learning operations for neural PDE solvers. ICLR, 2019. paper

    Nicholas Roberts, Mikhail Khodak, Tri Dao, Liam Li, Christopher Re, and Ameet Talwalkar.

  4. AutoPINN: When AutoML meets physics-informed neural networks. arXiv, 2022. paper

    Xinle Wu, Dalin Zhang, Miao Zhang, Chenjuan Guo, Shuai Zhao, Yi Zhang, Huai Wang, and Bin Yang.

  5. NAS-PINN: Neural architecture search-guided physics-informed neural network for solving PDEs. arXiv, 2023. paper

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  1. Neural implicit flow: A mesh-agnostic dimensionality reduction paradigm of spatio-temporal data. arXiv, 2022. paper

    Shaowu Pan, Steven L. Brunton, and J. Nathan Kutz.

  2. CROM: Continuous reduced-order modeling of PDEs using implicit neural representations. ICLR, 2023. paper

    Peter Yichen Chen, Jinxu Xiang, Dong Heon Cho, Yue Chang, G A Pershing, Henrique Teles Maia, Maurizio Chiaramonte, Kevin Carlberg, and Eitan Grinspun.

  3. MAgNet: Mesh agnostic neural PDE solver. NIPS, 2022. paper

    Oussama Boussif, Dan Assouline, Loubna Benabbou, and Yoshua Bengio.

  4. NTopo: Mesh-free topology optimization using implicit neural representations. NIPS, 2021. paper

    Jonas Zehnder, Yue Li, Stelian Coros, and Bernhard Thomaszewski.

  5. ContactNets: Learning discontinuous contact dynamics with smooth, implicit representations. ICLR, 2020. paper

    Samuel Pfrommer, Mathew Halm, and Michael Posa.

  6. Continuous PDE dynamics forecasting with implicit neural representations. ICLR, 2023. paper

    Yuan Yin, Matthieu Kirchmeyer, Jean-Yves Franceschi, Alain Rakotomamonjy, and Patrick Gallinari.

  7. Stability of implicit neural networks for long-term forecasting in dynamical systems. ICLR, 2023. paper

    Leon Migus, Julien Salomon, and Patrick Gallinari.

  8. Operator learning with neural fields: Tackling PDEs on general geometries. arXiv, 2023. paper

    Louis Serrano, Lise Le Boudec, Armand Kassaï Koupaï, Thomas X Wang, Yuan Yin, Jean-Noël Vittaut, and Patrick Gallinari.

  9. Accelerated solutions of convection-dominated partial differential equations using implicit feature tracking and empirical quadrature. arXiv, 2023. paper

    Marzieh Alireza Mirhoseini and Matthew J. Zahr.

  10. Implicit neural spatial representations for time-dependent PDEs. ICML, 2023. paper

    Honglin Chen, Rundi Wu, Eitan Grinspun, Changxi Zheng, and Peter Yichen Chen.

  11. Reduced-order modeling for parameterized PDEs via implicit neural representations. NIPS, 2023. paper

    Tianshu Wen, Kookjin Lee, and Youngsoo Choi.

  12. Geom-DeepONet: A point-cloud-based deep operator network for field predictions on 3D parameterized geometries. arXiv, 2024. paper

    Junyan He, Seid Koric, Diab Abueidda, Ali Najafi, and Iwona Jasiuk.

  13. Physics-aware neural implicit solvers for multiscale, parametric PDEs with applications in heterogeneous media. arXiv, 2024. paper

    Matthaios Chatzopoulos and Phaedon-Stelios Koutsourelakis.

  14. A resolution independent neural operator. arXiv, 2024. paper

    Bahador Bahmani, Somdatta Goswami, Ioannis G. Kevrekidis, and Michael D. Shields

  1. Quantifying total uncertainty in physics-informed neural networks for solving forward and inverse stochastic problems. arXiv, 2021. paper

    Dongkun Zhang, Lu Lu, Ling Guo, and George Em Karniadakis.

  2. Adversarial uncertainty quantification in physics-informed neural networks. JCP, 2021. paper

    Yibo Yang and Paris Perdikaris.

  3. Conditional Karhunen-Loève expansion for uncertainty quantification and active learning in partial differential equation models. JCP, 2020. paper

    Ramakrishna Tipireddy, David A.Barajas-Solano, and Alexandre M.Tartakovsky.

  4. Physics-constrained deep learning for high-dimensional surrogate modeling and uncertainty quantification without labeled data. JCP, 2019. paper

    Yinhao Zhu, Nicholas Zabarasa, Phaedon-Stelios Koutsourelakisb, and Paris Perdikaris.

  5. Error-aware B-PINNs: Improving uncertainty quantification in Bayesian physics-informed neural networks. arXiv, 2022. paper

    Olga Graf, Pablo Flores, Pavlos Protopapas, and Karim Pichara.

  6. Physics-informed information field theory for modeling physical systems with uncertainty quantification. arXiv, 2023. paper

    Alex Alberts and Ilias Bilionis.

  7. Quantifying uncertainty for deep learning based forecasting and flow-reconstruction using neural architecture search ensembles. arXiv, 2023. paper

    Romit Maulik, Romain Egele, Krishnan Raghavan, and Prasanna Balaprakash.

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    Hyomin Shin and Minseok Choi.

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    Apostolos F. Psaros, Xuhui Meng, Zongren Zou, Ling Guo, and George Em Karniadakis.

  10. Auto-weighted Bayesian physics-informed neural networks and robust estimations for multitask inverse problems in pore-scale imaging of dissolution. arXiv, 2023. paper

    Sarah Perez and Philippe Poncet.

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    Maxime Beauchamp, Hugo Georgenthum, and Ronan Fablet.

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    Victor J. Leon, Noah Ford, Honest Mrema, Jeffrey Gilbert, and Alexander New.

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    Vardhan Dongre and Gurpreet Singh Hora.

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    Zongren Zou, Xuhui Meng, and George Em Karniadakis.

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    Christophe Bonneville, Youngsoo Choi, Debojyoti Ghosh, and Jonathan L. Belof.

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    Yifei Zong, David Barajas-Solano, and Alexandre M. Tartakovsky.

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  19. Physics-constrained polynomial chaos expansion for scientific machine learning and uncertainty quantification. arXiv, 2024. paper

    Himanshu Sharma, Lukáš Novák, and Michael D. Shields.

  20. Physics-constrained polynomial chaos expansion for scientific machine learning and uncertainty quantification. arXiv, 2024. paper

    Himanshu Sharma, Lukáš Novák, and Michael D. Shields.

  21. Conformalized-DeepOnet: A distribution-free framework for uncertainty quantification in deep operator networks. arXiv, 2024. paper

    Christian Moya, Amirhossein Mollaali, Zecheng Zhang, Lu Lu, and Guang Lin.

  22. Leveraging viscous Hamilton-Jacobi PDEs for uncertainty quantification in scientific machine learning. arXiv, 2024. paper

    Zongren Zou, Tingwei Meng, Paula Chen, Jérôme Darbon, and George Em Karniadakis.

  1. A framework for data-driven solution and parameter estimation of PDEs using conditional generative adversarial networks. NCS, 2021. paper

    Teeratorn Kadeethum, Daniel O’Malley, Jan Niklas Fuhg, Youngsoo Choi, Jonghyun Lee, Hari S. Viswanathan, and Nikolaos Bouklas.

  2. Neural SDEs as infinite-dimensional GANs. ICML, 2021. paper

    Patrick Kidger, James Foster, Xuechen Li, and Terry J Lyons.

  3. PID-GAN: A GAN framework based on a physics-informed discriminator for uncertainty quantification with physics. KDD, 2021. paper

    Arka Daw, M. Maruf, and Anuj Karpatne.

  4. Generative adversarial neural operators. Transactions on Machine Learning Research, 2022. paper

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  5. Weak adversarial networks for high-dimensional partial differential equations. JCP, 2020. paper

    Yaohua Zang, Gang Bao, Xiaojing Ye, and Haomin Zhou.

  6. Wasserstein generative adversarial uncertainty quantification in physics-informed neural networks. JCP, 2022. paper

    Yihang Gao and Michael K. Ng.

  7. Competitive physics informed networks. ICLR, 2023. paper

    Qi Zeng, Yash Kothari, Spencer H Bryngelson, and Florian Tobias Schaefer.

  8. Learning generative neural networks with physics knowledge. Research in the Mathematical Sciences, 2022. paper

    Kailai Xu, Weiqiang Zhu, and Eric Darve.

  9. Diffusion generative models in infinite dimensions. arXiv, 2022. paper

    Gavin Kerrigan, Justin Ley, and Padhraic Smyth.

  10. Revisiting PINNs: Generative adversarial physics-informed neural networks and point-weighting method. arXiv, 2022. paper

    Wensheng Li, Chao Zhang, Chuncheng Wang, Hanting Guan, and Dacheng Tao.

  11. PIAT: Physics informed adversarial training for solving partial differential equations. arXiv, 2022. paper

    Simin Shekarpaz, Mohammad Azizmalayeri, and Mohammad Hossein Rohban.

  12. Physics-constrained generative adversarial networks for 3D turbulence. arXiv, 2022. paper

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  1. Convergence analysis of a quasi-Monte Carlo-based deep learning algorithm for solving partial differential equations. arXiv, 2022. paper

    Fengjiang Fu and Xiaoqun Wang.

  2. Solving PDEs by variational physics-informed neural networks: A posteriori error analysis. arXiv, 2022. paper

    Stefano Berrone, Claudio Canuto, and Moreno Pintore.

  3. A unified framework for the error analysis of physics-informed neural networks. arXiv, 2023. paper

    Marius Zeinhofer, Rami Masri, and Kent-André Mardal.

  4. Neural tangent kernel analysis of PINN for advection-diffusion equation. arXiv, 2022. paper

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    Zheyuan Hu, Zekun Shi, George Em Karniadakis, and Kenji Kawaguchi.

  7. An analysis of universal differential equations for data-driven discovery of ordinary differential equations. arXiv, 2023. paper

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  15. Error estimation for physics-informed neural networks with implicit Runge-Kutta methods. arXiv, 2023. paper

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  16. Approximation of solution operators for high-dimensional PDEs. arXiv, 2024. paper

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  17. Accuracy analysis of physics-informed neural networks for approximating the critical SQG equation. arXiv, 2024. paper

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  18. Deep Ritz method for elliptical multiple eigenvalue problems. Journal of Scientific Computing, 2024. paper

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  19. Inf-Sup neural networks for high-dimensional elliptic PDE problems. arXiv, 2024. paper

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  20. The challenges of the nonlinear regime for physics-informed neural networks. arXiv, 2024. paper

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  21. A hybrid iterative method based on MIONet for PDEs: Theory and numerical examples. arXiv, 2024. paper

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  22. A priori error estimation of physics-informed neural networks solving Allen--Cahn and Cahn--Hilliard equations. arXiv, 2024. paper

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  24. Data complexity estimates for operator learning. arXiv, 2024. paper

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  25. Bengining overfitting in fixed dimension via physics-informed learning with smooth iductive bias. arXiv, 2024. paper

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  29. A deep BSDE approximation of nonlinear integro-PDEs with unbounded nonlocal operators. arXiv, 2024. paper

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  1. PAGP: A physics-assisted Gaussian process framework with active learning for forward and inverse problems of partial differential equations. arXiv, 2022. paper

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  2. Solving and learning nonlinear PDEs with Gaussian processes. JCP, 2021. paper

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  4. Learning neural optimal interpolation models and solvers. arXiv, 2022. paper

    Maxime Beauchamp, Joseph Thompson, Hugo Georgenthum, Quentin Febvre, and Ronan Fablet.

  5. Inference of nonlinear partial differential equations via constrained Gaussian processes. arXiv, 2022. paper

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  6. Gaussian process priors for systems of linear partial differential equations with constant coefficients. arXiv, 2022. paper

    Marc Härkönen, Markus Lange-Hegermann, and Bogdan Raiţă.

  7. Sparse Cholesky factorization for solving nonlinear PDEs via Gaussian processes. arXiv, 2023. paper

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  8. A mini-batch method for solving nonlinear PDEs with Gaussian processes. arXiv, 2023. paper

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  9. Random grid neural processes for parametric partial differential equations. ICML, 2023. paper

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  10. Gaussian process priors for systems of linear partial differential equations with constant coefficients. ICML, 2023. paper

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  11. GPLaSDI: Gaussian process-based interpretable latent space dynamics identification through deep autoencoder. arXiv, 2023. paper

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  12. Solving high frequency and multi-scale PDEs with Gaussian processes. ICLR, 2024. paper

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  13. Physics-constrained convolutional neural networks for inverse problems in spatiotemporal partial differential equations. arXiv, 2024. paper

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  1. PI-VAE: Physics-informed variational auto-encoder for stochastic differential equations. CMAME, 2022. paper

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  2. Robust SDE-based variational formulations for solving linear PDEs via deep learning. ICML, 2022. paper

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  3. HP-VPINNs: Variational physics-informed neural networks with domain decomposition. CMAME, 2021. paper

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  4. Variational onsager neural networks (VONNs): A thermodynamics-based variational learning strategy for non-equilibrium PDEs. Journal of the Mechanics and Physics of Solids, 2022. paper

    Shenglin Huang, Zequn He, Bryan Chem, and Celia Reina.

  5. Variational Monte Carlo approach to partial differential equations with neural networks. arXiv, 2022. paper

    Moritz Reh and Martin Gärttner.

  6. Energetic variational neural network discretizations to gradient flows. arXiv, 2022. paper

    Ziqing Hu, Chun Liu, Yiwei Wang, and Zhiliang Xu.

  7. Variational Bayes deep operator network: A data-driven Bayesian solver for parametric differential equations. arXiv, 2022. paper

    Shailesh Garg and Souvik Chakraborty.

  8. Variational inference in neural functional prior using normalizing flows: Application to differential equation and operator learning problems. arXiv, 2023. paper

    Xuhui Meng.

  9. Neural network approximations of PDEs beyond linearity: A representational perspective. ICML, 2023. paper

    Tanya Marwah, Zachary Chase Lipton, Jianfeng Lu, and Andrej Risteski.

  1. Bayesian deep learning for partial differential equation parameter discovery with sparse and noisy data. JCP: X, 2022. paper

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  2. B-PINNs: Bayesian physics-informed neural networks for forward and inverse PDE problems with noisy data. JCP, 2021. paper

    Liu Yang, Xuhui Meng, and George Em Karniadakis.

  3. Approximate Bayesian neural operators: Uncertainty quantification for parametric PDEs. arXiv, 2022. paper

    Emilia Magnani, Nicholas Krämer, Runa Eschenhagen, Lorenzo Rosasco, and Philipp Hennig.

  4. Bayesian autoencoders for data-driven discovery of coordinates, governing equations and fundamental constants. arXiv, 2022. paper

    L. Mars Gao and J. Nathan Kutz.

  5. Bayesian physics informed neural networks for data assimilation and spatio-temporal modelling of wildfires. arXiv, 2022. paper

    Joel Janek Dabrowski, Daniel Edward Pagendam, James Hilton, Conrad Sanderson, Daniel MacKinlay, Carolyn Huston, Andrew Bolt, and Petra Kuhnert.

  6. Bayesian deep operator learning for homogenized to fine-scale maps for multiscale PDE. arXiv, 2023. paper

    Zecheng Zhang, Christian Moya, Wing Tat Leung, Guang Lin, and Hayden Schaeffer.

  7. Bayesian deep learning framework for uncertainty quantification in stochastic partial differential equations. SIAM Journal on Scientific Computing, 2024. paper

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  1. Multiscale simulations of complex systems by learning their effective dynamics. NMI, 2022. paper

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  2. A latent space solver for PDE generalization. ICLR, 2021. paper

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  3. Approximate latent force model inference. AAAI, 2021. paper

    Jacob D. Moss, Felix L. Opolka, Bianca Dumitrascu, and Pietro Lió.

  4. Learning to accelerate partial differential equations via latent global evolution. NIPS, 2022. paper

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  5. Exploring physical latent spaces for deep learning. arXiv, 2022. paper

    Chloe Paliard, Nils Thuerey, and Kiwon Um.

  6. Certified data-driven physics-informed greedy auto-encoder simulator. arXiv, 2022. paper

    Xiaolong He, Youngsoo Choi, William D. Fries, Jonathan L. Belof, and Jiun-Shyan Chen.

  7. Deep latent regularity network for modeling stochastic partial differential equations. AAAI, 2023. paper

    Shiqi Gong, Peiyan Hu, Qi Meng, Yue Wang, Rongchan Zhu, Bingguang Chen, Zhiming Ma, Hao Ni, and Tieyan Liu.

  8. Learning in latent spaces improves the predictive accuracy of deep neural operators. arXiv, 2023. paper

    Katiana Kontolati, Somdatta Goswami, George Em Karniadakis, and Michael D. Shields.

  9. Solving high-dimensional PDEs with latent spectral models. ICML, 2023. paper

    Haixu Wu, Tengge Hu, Huakun Luo, Jianmin Wang, and Mingsheng Long.

  10. Physics-informed generator-encoder adversarial networks with latent space matching for stochastic differential equations. arXiv, 2023. paper

    Ruisong Gao, Min Yang, and Jin Zhang.

  11. Smooth and sparse latent dynamics in operator learning with Jerk regularization arXiv, 2024. paper

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  13. WaveDiffusion: Exploring full waveform inversion via joint diffusion in the latent space. arXiv, 2024. paper

    Hanchen Wang, Yinpeng Chen, Jeeun Kang, Yixuan Wu, Young Jin Kim, and Youzuo Lin

  1. Lagrangian PINNs: A causality–conforming solution to failure modes of physics-informed neural networks. arXiv, 2022. paper

    Rambod Mojgani, Maciej Balajewicz, and Pedram Hassanzadeh.

  2. AL-PINNs: Augmented Lagrangian relaxation method for physics-informed neural networks. arXiv, 2022. paper

    Hwijae Son, Sung Woong Cho, and Hyung Ju Hwang.

  3. Lagrangian flow networks for conservation laws. ICLR, 2024. paper

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  4. An adaptive augmented Lagrangian method for training physics and equality constrained artificial neural networks. arXiv, 2023. paper

    Shamsulhaq Basir and Inanc Senocak.

  5. Constrained optimization via exact augmented Lagrangian and randomized iterative sketching. ICML, 2023. paper

    Ilgee Hong, Sen Na, Michael W. Mahoney, and Mladen Kolar.

  6. An adaptive augmented Lagrangian method for training physics and equality constrained artificial neural networks. arXiv, 2023. paper

    Shamsulhaq Basir and Inanc Senocak.

  7. Partitioned neural network approximation for partial differential equations enhanced with Lagrange multipliers and localized loss functions. arXiv, 2023. paper

    Deok-Kyu Jang, Kyungsoo Kim, and Hyea Hyun Kim.

  1. Hierarchical deep learning of multiscale differential equation time-steppers. Philosophical Transactions of the Royal Society A, 2022. paper

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  2. NH-PINN: Neural homogenization-based physics-informed neural network for multiscale problems. JCP, 2022. paper

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  3. Deep multiscale model learning. JCP, 2020. paper

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  4. Multi-scale deep neural networks for solving high dimensional PDEs. arXiv, 2019. paper

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  5. Towards multi-spatiotemporal-scale generalized PDE modeling. arXiv, 2022. paper

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  6. MultiAdam: Parameter-wise scale-invariant optimizer for multiscale training of physics-informed neural networks. ICML, 2023. paper

    Jiachen Yao, Chang Su, Zhongkai Hao, Songming Liu, Hang Su, and Jun Zhu.

  7. Learning homogenization for elliptic operators. arXiv, 2023. paper

    Kaushik Bhattacharya, Nikola Kovachki, Aakila Rajan, Andrew M. Stuart, and Margaret Trautner.

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  10. Multilevel scalable solvers for stochastic linear and nonlinear problems. arXiv, 2023. paper

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  1. Multifidelity deep operator networks. arXiv, 2022. paper

    Amanda A. Howard, Mauro Perego, George Em Karniadakis, and Panos Stinis.

  2. Physics and equality constrained artificial neural networks: Application to forward and inverse problems with multi-fidelity data fusion. JCP, 2022. paper

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  3. A composite neural network that learns from multi-fidelity data: Application to function approximation and inverse PDE problems. JCP, 2020. paper

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  4. Multifidelity deep neural operators for efficient learning of partial differential equations with application to fast inverse design of nanoscale heat transport. Physical Review Research, 2022. paper

    Lu Lu, Raphaël Pestourie, Steven G. Johnson, and Giuseppe Romano.

  5. Multi-fidelity reduced-order surrogate modeling. arXiv, 2023. paper

    Paolo Conti, Mengwu Guo, Andrea Manzoni, Attilio Frangi, Steven L. Brunton, and J. Nathan Kutz.

  6. Multifidelity deep operator networks for data-driven and physics-informed problems. JCP, 2023. paper

    Amanda A. Howard, Mauro Perego, George Em Karniadakis, and Panos Stinis.

  7. A multi-fidelity machine learning based semi-Lagrangian finite volume scheme for linear transport equations and the nonlinear Vlasov-Poisson system. arXiv, 2023. paper

    Yongsheng Chen, Wei Guo, and Xinghui Zhong.

  8. Neural operator-based super-fidelity: A warm-start approach for accelerating steady-state simulations. arXiv, 2023. paper

    Xuhui Zhou, Jiequn Han, Muhammad I. Zafar, Christopher J. Roy, Heng Xiao.

  9. Multi-resolution partial differential equations preserved learning framework for spatiotemporal dynamics. AAAI, 2024. paper

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    Wenqian Chen and Panos Stinis.

  11. Data-driven constitutive meta-modeling of nonlinear rheology via multifidelity neural networks. JCP, 2024. paper

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  1. Learning to optimize multigrid PDE solvers. ICML, 2019. paper

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  2. Reducing operator complexity in algebraic multigrid with machine learning approaches. arXiv, 2023. paper

    Ru Huang, Kai Chang, Huan He, Ruipeng Li, and Yuanzhe Xi.

  3. Multi-grid tensorized Fourier neural operator for high-resolution PDEs. arXiv, 2023. paper

    Jean Kossaifi, Nikola Kovachki, Kamyar Azizzadenesheli, and Anima Anandkumar.

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  6. Neural physical simulation with multi-resolution hash grid encoding. AAAI, 2024. paper

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  8. Ugrid: An efficient-and-rigorous neural multigrid solver for linear PDEs. ICML, 2024. paper

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  1. Neural Galerkin scheme with active learning for high-dimensional evolution equations. arXiv, 2022. paper

    Joan Bruna, Benjamin Peherstorfer, and Eric Vanden-Eijnden.

  2. Discovering and forecasting extreme events via active learning in neural operators. arXiv, 2022. paper

    Ethan Pickering, Stephen Guth, George Em Karniadakis, and Themistoklis P. Sapsis.

  3. Active learning based sampling for high-dimensional nonlinear partial differential equations. JCP, 2023. paper

    Wenhan Gao and Chunmei Wang.

  4. An extreme learning machine-based method for computational PDEs in higher dimensions. arXiv, 2023. paper

    Yiran Wang and Suchuan Dong.

  5. Multi-resolution active learning of Fourier neural operators. arXiv, 2023. paper

    Shibo Li, Xin Yu, Wei Xing, Mike Kirby, Akil Narayan, and Shandian Zhe.

  6. A foundational neural operator that continuously learns without forgetting. arXiv, 2023. paper

    Tapas Tripura and Souvik Chakraborty.

  7. Neural Galerkin schemes with active learning for high-dimensional evolution equations. JCP, 2023. paper

    Joan Bruna, Benjamin Peherstorfer, and Eric Vanden-Eijnden.

  8. Active learning for neural PDE solvers. arXiv, 2024. paper

    Daniel Musekamp, Marimuthu Kalimuthu, David Holzmüller, Makoto Takamoto, and Mathias Niepert.

  1. Adversarial multi-task learning enhanced physics-informed neural networks for solving partial differential equations. IJCNN, 2022. paper

    Pongpisit Thanasutives, Masayuki Numao, and Ken-ichi Fukui.

  2. Synergistic learning with multi-task DeepONet for efficient pde problem solving. arXiv, 2024. paper

    Varun Kumar, Somdatta Goswami, Katiana Kontolati, Michael D. Shields, and George Em Karniadakis.

  1. Fast PDE-constrained optimization via self-supervised operator learning. arXiv, 2021. paper

    Sifan Wang, Mohamed Aziz Bhouri, and Paris Perdikaris.

  2. An extended physics informed neural network for preliminary analysis of parametric optimal control problems. arXiv, 2021. paper

    Nicola Demo, Maria Strazzullo, and Gianluigi Rozza.

  3. Optimal control of PDEs using physics-informed neural networks. JCP, 2023. paper

    Saviz Mowlavi and Saleh Nabi.

  4. Solving PDE-constrained control problems using operator learning. AAAI, 2022. paper

    Rakhoon Hwang, Jae Yong Lee, Jin Young Shin, and Hyung Ju Hwang.

  5. PDE-based optimal strategy for unconstrained online learning. ICML, 2022. paper

    Zhiyu Zhang, Ashok Cutkosky, and Ioannis Paschalidis.

  6. Control of partial differential equations via physics-informed neural networks. Journal of Optimization Theory and Applications, 2022. paper

    Carlos J. García-Cervera, Mathieu Kessler, and Francisco Periago.

  7. A machine learning framework for solving high-dimensional mean field game and mean field control problems. PNAS, 2020. paper

    Lars Ruthottoa, Stanley J. Osherc, Wuchen Lic, Levon Nurbekyanc, and Samy Wu Fung.

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    Zhongkai Hao, Chengyang Ying, Hang Su, Jun Zhu, Jian Song, and Ze Cheng.

  9. A combination technique for optimal control problems constrained by random PDEs. arXiv, 2022. paper

    Fabio Nobile and Tommaso Vanzan.

  10. A multilevel reinforcement learning framework for PDE-based control. arXiv, 2022. paper

    Atish Dixit and Ahmed H. Elsheikh.

  11. Optimal learning of high-dimensional classification problems using deep neural networks. arXiv, 2022. paper

    Philipp Petersen and Felix Voigtlaender.

  12. The ADMM-PINNs algorithmic framework for nonsmooth PDE-constrained optimization: A deep learning approach. arXiv, 2023. paper

    Yongcun Song, Xiaoming Yuan, and Hangrui Yue.

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    Na Lei, DONGSHENG An, Min Zhang, Xiaoyin Xu, and David Gu.

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    Zhiyu Zhang, Ashok Cutkosky, and Ioannis Paschalidis.

  16. PDE-constrained models with neural network terms: Optimization and global convergence. JCP, 2023. paper

    Justin Sirignano, Jonathan MacArt, and Konstantinos Spiliopoulos.

  17. Topology optimization using neural networks with conditioning field initialization for improved efficiency. arXiv, 2023. paper

    Hongrui Chen, Aditya Joglekar, and Levent Burak Kara.

  18. Deep reinforcement learning for optimal well control in subsurface systems with uncertain geology. JCP, 2023. paper

    Yusuf Nasir and Louis J. Durlofsky.

  19. Constrained optimization via exact augmented lagrangian and randomized iterative sketching. ICML, 2023. paper

    Ilgee Hong, Sen Na, Michael W. Mahoney, and Mladen Kolar.

  20. Efficient PDE-constrained optimization under high-dimensional uncertainty using derivative-informed neural operators. arXiv, 2023. paper

    Dingcheng Luo, Thomas O'Leary-Roseberry, Peng Chen, and Omar Ghattas.

  21. Dimension-independent certified neural network watermarks via mollifier smoothing. ICML, 2023. paper

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  22. Accelerated primal-dual methods with enlarged step sizes and operator learning for nonsmooth optimal control problems. arXiv, 2023. paper

    Yongcun Song, Xiaoming Yuan, and Hangrui Yue.

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  24. Operator learning for continuous spatial-temporal model with a hybrid optimization scheme. arXiv, 2023. paper

    Chuanqi Chen and Jinlong Wu.

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  26. Accelerating Bayesian optimal experimental design with derivative-informed neural operators. arXiv, 2023. paper

    Jinwoo Go and Peng Chen.

  27. A supervised learning scheme for computing Hamilton-Jacobi equation via density coupling. arXiv, 2024. paper

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  29. Inverse design method for horn antennas based on knowledge-embedded physics-informed neural networks. IEEE Antennas and Wireless Propagation Letters, 2024. paper

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  1. Physics-informed neural networks (PINNs) for fluid mechanics: A review. Acta Mechanica Sinica, 2021. paper

    Shengze Cai, Zhiping Mao, Zhicheng Wang, Minglang Yin, and George Em Karniadakis.

  2. Neural operator prediction of linear instability waves in high-speed boundary layers. JCP, 2022. paper

    Patricio Clark Di Leoni, Lu Lu, Charles Meneveau, George Karniadakis, and Tamer A. Zaki.

  3. A physics-informed convolutional neural network for the simulation and prediction of two-phase darcy flows in heterogeneous porous media. JCP, 2023. paper

    Zhao Zhang, Xia Yan, Piyang Liu, Kai Zhang, Renmin Han, and Sheng Wang.

  4. DiscretizationNet: A machine-learning based solver for Navier–Stokes equations using finite volume discretization. CMAME, 2021. paper

    Rishikesh Ranade, Chris Hillb, and Jay Pathak.

  5. Surrogate modeling for fluid flows based on physics-constrained deep learning without simulation data. CMAME, 2020. paper

    Luning Sun, Han Gao, Shaowu Pan, and Jianxun Wang.

  6. Towards physics-informed deep learning for turbulent flow prediction. KDD, 2020. paper

    Rui Wang, Karthik Kashinath, Mustafa Mustafa, Adrian Albert, and Rose Yu.

  7. Learning to estimate and refine fluid motion with physical dynamics. ICML, 2022. paper

    Mingrui Zhang, Jianhong Wang, James Tlhomole, and Matthew D. Piggott.

  8. Physics informed neural fields for smoke reconstruction with sparse data. ACM Transactions on Graphics, 2022. paper

    Mengyu Chu, Lingjie Liu, Quan Zheng, Erik Franz, Hans-Peter Seidel, Christian Theobalt, and Rhaleb Zayer.

  9. Physics-informed deep learning for traffic state estimation: A hybrid paradigm informed by second-order traffic models. AAAI, 2021. paper

    Rongye Shi, Zhaobin Mo, and Xuan Di.

  10. Residual-based adaptivity for two-phase flow simulation in porous media using physics-informed neural networks. CMAME, 2022. paper

    John M.Hanna, José V.Aguado, Sebastien Comas-Cardona, Ramz Askri, and Domenico Borzacchiello.

  11. Learned turbulence modelling with differentiable fluid solvers: Physics-based loss-functions and optimisation horizons. JFM, 2022. paper

    Björn List, Liwei Chen, and Nils Thuerey.

  12. Learning hydrodynamic equations for active matter from particle simulations and experiments. PNAS, 2023. paper

    Rohit Supekar, Boya Song, Alasdair Hastewell, Gary P. T. Choi, Alexander Mietke, and Jörn Dunkel.

  13. Physics informed neural networks: A case study for gas transport problems. JCP, 2023. paper

    Erik Laurin Strelow, Alf Gerisch, Jens Lang, and Marc E. Pfetsch.

  14. Turbulence model augmented physics informed neural networks for mean flow reconstruction. arXiv, 2023. paper

    Yusuf Patel, Vincent Mons, Olivier Marquet, and Georgios Rigas.

  15. RANS-PINN based simulation surrogates for predicting turbulent flows. arXiv, 2023. paper

    Shinjan Ghosh, Amit Chakraborty, Georgia Olympia Brikis, and Biswadip Dey.

  16. Meta-learning for airflow simulations with graph neural networks. arXiv, 2023. paper

    Wenzhuo Liu, Mouadh Yagoubi, and Marc Schoenauer.

  17. Learning operators for identifying weak solutions to the Navier-Stokes equations. arXiv, 2023. paper

    Dixi Wang and Cheng Yu.

  18. Physics-informed neural networks modeling for systems with moving immersed boundaries: Application to an unsteady flow past a plunging foil. arXiv, 2023. paper

    Rahul Sundar, Dipanjan Majumdar, Didier Lucor, and Sunetra Sarkar.

  19. A machine learning pressure emulator for hydrogen embrittlement. ICML, 2023. paper

    Minh Triet Chau, João Lucas de Sousa Almeida, Elie Alhajjar, and Alberto Costa Nogueira Junior.

  20. A probabilistic, data-driven closure model for RANS simulations with aleatoric, model uncertainty. arXiv, 2023. paper

    Atul Agrawal and Phaedon-Stelios Koutsourelakis.

  21. Physics-informed machine learning for calibrating macroscopic traffic flow models. arXiv, 2023. paper

    Yu Tang, Li Jin, and Kaan Ozbay.

  22. Radial basis function-differential quadrature-based physics-informed neural network for steady incompressible flows. PoF, 2023. paper

    Yang Xiao, Liming Yang, Yinjie Du, Yuxin Song, and Chang Shu.

  23. Long-term predictions of turbulence by implicit U-Net enhanced Fourier neural operator. PoF, 2023. paper

    Zhijie Li, Wenhui Peng, Zelong Yuan, and Jianchun Wang.

  24. Physics-informed neural networks for parametric compressible Euler equations. arXiv, 2023. paper

    Simon Wassing, Stefan Langer, and Philipp Bekemeyer.

  25. Simulation of rarefied gas flows using physics-informed neural network combined with discrete velocity method. PoF, 2023. paper

    Linying Zhang, Wenjun Ma, Qin Lou, and Jun Zhang.

  26. Influence of adversarial training on super-resolution turbulence models. arXiv, 2023. paper

    Ludovico Nista, Christoph David Karl Schumann, Mathis Bode, Temistocle Grenga, Jonathan F. MacArt, Antonio Attili, and Heinz Pitsch.

  27. Turbulent flow simulation using autoregressive conditional diffusion models. arXiv, 2023. paper

    Georg Kohl, Liwei Chen, and Nils Thuerey.

  28. Physics-informed neural networks for studying heat transfer in porous media. International Journal of Heat and Mass Transfer, 2023. paper

    Jiaxuan Xu, Han Wei, and Hua Bao.

  29. Solution multiplicity and effects of data and eddy viscosity on Navier-Stokes solutions inferred by physics-informed neural networks. arXiv, 2023. paper

    Zhicheng Wang, Xuhui Meng, Xiaomo Jiang, Hui Xiang, and George Em Karniadakis.

  30. Towards real-time training of physics-informed neural networks: Applications in ultrafast ultrasound blood flow imaging. arXiv, 2023. paper

    Haotian Guan, Jinping Dong, and Weining Lee.

  31. Multi-physical predictions in electro-osmotic micromixer by auto-encoder physics-informed neural networks. PoF, 2023. paper

    Naiwen Chang, Ying Huai, Tingting Liu, Xi Chen, and Yuqi Jin.

  32. Studying turbulent flows with physics-informed neural networks and sparse data. International Journal of Heat and Fluid Flow, 2023. paper

    S. Hanrahan, M. Kozul, and R.D. Sandberg.

  33. Enhancing physics informed neural networks for solving Navier–Stokes equations. International Journal for Numerical Methods in Fluids, 2023. paper

    Ayoub Farkane, Mounir Ghogho, Mustapha Oudani, and Mohamed Boutayeb.

  34. Physics-informed tensor basis neural network for turbulence closure modeling. arXiv, 2023. paper

    Leon Riccius, Atul Agrawal, and Phaedon-Stelios Koutsourelakis.

  35. Investigation of low and high-speed fluid dynamics problems using physics-informed neural network. International Journal of Computational Fluid Dynamics, 2023. paper

    Anubhav Joshi,Alexandros Papados, and Rakesh Kumar.

  36. Singular layer physics informed neural network method for plane parallel flows. arXiv, 2023. paper

    Tengyuan Chang, Gungmin Gie, Youngjoon Hong, and Chang-Yeol Jung.

  37. Data-efficient operator learning for solving high Mach number fluid flow problems. arXiv, 2023. paper

    Noah Ford, Victor J. Leon, Honest Merman, Jeffrey Gilbert, and Alexander New.

  38. Three-dimensional laminar flow using physics informed deep neural networks featured. PoF, 2023. paper

    Saykat Kumar Biswas and N. K. Anand.

  39. Real-time prediction of gas flow dynamics in diesel engines using a deep neural operator framework. Applied Intelligence, 2023. paper

    Varun Kumar, Somdatta Goswami, Daniel Smith, and George Em Karniadakis.

  40. Semi-analytic physics informed neural network for convection-dominated boundary layer problems in 2D. arXiv, 2023. paper

    Gungmin Gie, Youngjoon Hong, Chang-Yeol Jung, and Dongseok Lee.

  41. The improved backward compatible physics-informed neural networks for reducing error accumulation and applications in data-driven higher-order rogue waves. arXiv, 2023. paper

    Shuning Lin and Yong Chen.

  42. Learning characteristic parameters and dynamics of centrifugal pumps under multi-phase flow using physics-informed neural networks. arXiv, 2023. paper

    Felipe de Castro Teixeira Carvalho, Kamaljyoti Nath, Alberto Luiz Serpa, and George Em Karniadakis.

  43. On the locality of local neural operator in learning fluid dynamics. arXiv, 2023. paper

    Ximeng Ye, Hongyu Li, Jingjie Huang, and Guoliang Qin.

  44. Multi-viscosity physics-informed neural networks for generating ultra high resolution flow field data. International Journal of Computational Fluid Dynamics, 2023. paper

    Sen Zhang, Xiaowei Guo, Chao Li, Ran Zhao, Canqun Yang, Wei Wang, and Yanxu Zhong.

  45. Towards high-accuracy deep learning inference of compressible flows over aerofoils. Computers & Fluids, 2023. paper

    Liwei Chen and Nils Thuerey.

  46. Data-driven and physics-informed deep learning operators for solution of heat conduction equation with parametric heat source. International Journal of Heat and Mass Transfer, 2023. paper

    Seid Koric and Diab W. Abueidda.

  47. Energy-preserving reduced operator inference for efficient design and control. arXiv, 2024. paper

    Tomoki Koike and Elizabeth Qian.

  48. Variable linear transformation improved physics-informed neural networks to solve thin-layer flow problems. JCP, 2024. paper

    Jiahao Wu, Yuxin Wu, Guihua Zhang, and Yang Zhang.

  49. Riemannonets: Interpretable neural operators for Riemann problems. arXiv, 2024. paper

    Ahmad Peyvan, Vivek Oommen, Ameya D. Jagtap, and George Em Karniadakis.

  50. Physics-informed neural networks for incompressible flows with moving boundaries. PoF, 2024. paper

    Yongzheng Zhu, Weizhen Kong, Jian Deng, and Xin Bian.

  51. Solving the one dimensional vertical suspended sediment mixing equation with arbitrary eddy diffusivity profiles using temporal normalized physics-informed neural networks. PoF, 2024. paper

    Shaotong Zhang, Jiaxin Deng, Xi'an Li, Zixi Zhao, Jinran Wu, Weide Li,Yougan Wang, and Dongsheng Jeng.

  52. Neural SPH: Improved neural modeling of Lagrangian fluid dynamics. arXiv, 2024. paper

    Artur P. Toshev, Jonas A. Erbesdobler, Nikolaus A. Adams, and Johannes Brandstetter.

  53. Continuous and discontinuous compressible flows in a converging–diverging channel solved by physics-informed neural networks without exogenous data. Scientific Reports, 2024. paper

    Hong Liang, Zilong Song, Chong Zhao, and Xin Bian.

  54. Gauss-Newton natural gradient descent for physics-informed computational fluid dynamics. arXiv, 2024. paper

    Anas Jnini, Flavio Vella, and Marius Zeinhofer.

  55. Residual-enhanced physics-guided machine learning with hard constraints for subsurface flow in reservoir engineering. TGRS, 2024. paper

    Haibo Cheng, Yunpeng He, Peng Zeng, and Valeriy Vyatkin.

  56. Discovering artificial viscosity models for discontinuous Galerkin approximation of conservation laws using physics-informed machine learning. arXiv, 2024. paper

    Matteo Caldana, Paola F. Antonietti, and Luca Dede'.

  57. EuLagNet: Eulerian fluid prediction with Lagrangian dynamics. arXiv, 2024. paper

    Qilong Ma, Haixu Wu, Lanxiang Xing, Jianmin Wang, and Mingsheng Long.

  58. Physics-informed neural networks with domain decomposition for the incompressible Navier–Stokes equations. PoF, 2024. paper

    Linyan Gu, Shanlin Qin, Lei Xu, and Rongliang Chen.

  59. Two-stage initial-value iterative physics-informed neural networks for simulating solitary waves of nonlinear wave equations. JCP, 2024. paper

    Jin Song, Ming Zhong, George Em Karniadakis, and Zhenya Yan.

  60. Continuous and discontinuous compressible flows in a converging–diverging channel solved by physics-informed neural networks without exogenous data. Scientific Reports, 2024. paper

    Hong Liang, Zilong Song, Chong Zhao, and Xin Bian.

  61. A fast general thermal simulation model based on multi-branch physics-informed deep operator neural network. PoF, 2024. paper

    Zibo Lu, Yuanye Zhou, Yanbo Zhang, Xiaoguang Hu, Qiao Zhao, and Xuyang Hu.

  62. Potential of physics-informed neural networks for solving fluid flow problems with parametric boundary conditions. PoF, 2024. paper

    F. Lorenzen, A. Zargaran, and U. Janoske.

  63. Physics-informed neural networks for transonic flow around a cylinder with high Reynolds number. PoF, 2024. paper

    Xiang Ren, Peng Hu, Hua Su, Feizhou Zhang, and Huahua Yu.

  64. Physics-informed neural networks enhanced particle tracking velocimetry: An example for turbulent Jet flow. TIM, 2024. paper

    Shengze Cai, Callum Gray, and George Em Karniadakis.

  65. Strategies for multi-case physics-informed neural networks for tube flows: A study using 2D flow scenarios. Scientific Reports, 2024. paper

    Hong Shen Wong, Wei Xuan Chan, Bing Huan Li, and Choon Hwai Yap.

  66. Physics-informed neural networks for fully non-linear free surface wave propagation. PoF, 2024. paper

    Haocheng Lu, Qian Wang, Wenhao Tang, and Hua Liu.

  67. HelmFluid: Learning Helmholtz dynamics for interpretable fluid prediction. ICML, 2024. paper

    Lanxiang Xing, Haixu Wu, Yuezhou Ma, Jianmin Wang, and Mingsheng Long.

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    Hong Shen Wong, Wei Xuan Chan, Bing Huan Li, and Choon Hwai Yap.

  69. From zero to turbulence: Generative modeling for 3D flow simulation. ICLR, 2024. paper

    Marten Lienen, David Lüdke, Jan Hansen-Palmus, and Stephan Günnemann.

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    Chi Zhang, Chih-Yung Wen, Yuan Jia, Yu-Hsuan Juan, Yee-Ting Lee, Zhengwei Chen, An-Shik Yang, and Zhengtong Li.

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    Haocheng Lu, Qian Wang, Wenhao Tang, and Hua Liu.

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    Weiming Ding, Haoxiang Huang, Tzu-Jung Lee, Yingjie Liu, and Vigor Yang.

  73. Flow field reconstruction from sparse sensor measurements with physics-informed neural networks. PoF, 2024. paper

    Mohammad Yasin Hosseini and Yousef Shiri.

  74. Weak baselines and reporting biases lead to overoptimism in machine learning for fluid-related partial differential equations. arXiv, 2024. paper

    Nick McGreivy and Ammar Hakim.

  75. Physics-informed machine learning of the correlation functions in bulk fluids. PoF, 2024. paper

    Wenqian Chen, Peiyuan Gao, and Panos Stinis.

  76. Groundwater inverse modeling: Physics-informed neural network with disentangled constraints and errors. Journal of Hydrology, 2024. paper

    Yuzhe Ji, Yuanyuan Zha, Tian-Chyi J. Yeh, Liangsheng Shi, and Yanling Wang.

  77. Inferring turbulent velocity and temperature fields and their statistics from Lagrangian velocity measurements using physics-informed Kolmogorov-Arnold networks. arXiv, 2024. paper

    Juan Diego Toscano, Theo Käufer, Zhibo Wang, Martin Maxey, Christian Cierpka, and George Em Karniadakis.

  78. Physics-informed neural networks for advection–diffusion–Langmuir adsorption processes. PoF, 2024. paper

    Bo Huang, Haobo Hua, Huan Han, Sensen He, Yuanye Zhou, Shuhong Liu, and Zhigang Zuo.

  79. A new method to compute the blood flow equations using the physics-informed neural operator. JCP, 2024. paper

    Lingfeng Li, Xuecheng Tai, and Raymond Hon-Fu Chan.

  80. Modeling two-phase flows with complicated interface evolution using parallel physics-informed neural networks. PoF, 2024. paper

    Rundi Qiu, Haosen Dong, Jingzhu Wang, Chun Fan, and Yiwei Wang.

  81. Assessing physics-informed neural network performance with sparse noisy velocity data PoF, 2024. paper

    Adhika Satyadharma, Ming-Jyh Chern, Heng-Chuan Kan, Harinaldi, and James Julian.

  82. Flow reconstruction with uncertainty quantification from noisy measurements based on Bayesian physics-informed neural networks. PoF, 2024. paper

    Hailong Liu, Zhi Wang, Rui Deng, Shipeng Wang, Xuhui Meng, Chao Xu, and Shengze Cai.

  83. Surrogate modeling of multi-dimensional premixed and non-premixed combustion using pseudo-time stepping physics-informed neural networks. PoF, 2024. paper

    Zhen Cao, Kai Liu, Kun Luo, Sifan Wang, Liang Jiang, and Jianren Fan.

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    Qilong Ma, Haixu Wu, Lanxiang Xing, Shangchen Miao, and Mingsheng Long.

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    Jiahao Liu, Supei Zheng, Xueli Song, and Doudou Xu.

  1. Machine learning accelerated PDE backstepping observers. arXiv, 2022. paper

    Yuanyuan Shi, Zongyi Li, Huan Yu, Drew Steeves, Anima Anandkumar, and Miroslav Krstic.

  2. Neural solvers for fast and accurate numerical optimal control. NIPS, 2021. paper

    Federico Berto, Stefano Massaroli, Michael Poli, and Jinkyoo Park.

  3. Bellman neural networks for the class of optimal control problems with integral quadratic cost. TAI, 2022. paper

    Enrico Schiassi, Andrea D'Ambrosio, and Roberto Furfaro.

  4. Offline supervised learning vs online direct policy optimization: A comparative study and a unifie training paradigm for neural network-based optimal feedback control. arXiv, 2022. paper

    Yue Zhao and Jiequn Han.

  5. Policy evaluation and temporal–difference learning in continuous time and space: A martingale approach. JMLR, 2022. paper

    Yanwei Jia and Xunyu Zhou.

  6. Physics-informed kernel embeddings: Integrating prior system knowledge with data-driven control. arXiv, 2023. paper

    Adam J. Thorpe, Cyrus Neary, Franck Djeumou, Meeko M. K. Oishi, and Ufuk Topcu.

  7. Distributed control of partial differential equations using convolutional reinforcement learning. arXiv, 2023. paper

    Sebastian Peitz, Jan Stenner, Vikas Chidananda, Oliver Wallscheid, Steven L. Brunton, and Kunihiko Taira.

  8. Neural control of parametric solutions for high-dimensional evolution PDEs. arXiv, 2023. paper

    Nathan Gaby, Xiaojing Ye, and Haomin Zhou.

  9. Bridging physics-informed neural networks with reinforcement learning: Hamilton-Jacobi-Bellman proximal policy optimization (HJBPPO). arXiv, 2023. paper

    Amartya Mukherjee and Jun Liu.

  10. AONN: An adjoint-oriented neural network method for all-at-once solutions of parametric optimal control problems. arXiv, 2023. paper

    Pengfei Yin, Guangqiang Xiao, Kejun Tang, and Chao Yang.

  11. Neural operators for bypassing gain and control computations in PDE backstepping. arXiv, 2023. paper

    Luke Bhan, Yuanyuan Shi, and Miroslav Krstic.

  12. Neural operators of backstepping controller and observer gain functions for reaction-diffusion PDEs. arXiv, 2023. paper

    Miroslav Krstic, Luke Bhan, and Yuanyuan Shi.

  13. Leveraging multi-time Hamilton-Jacobi PDEs for certain scientific machine learning problems. arXiv, 2023. paper

    Paula Chen, Tingwei Meng, Zongren Zou, Jérôme Darbon, and George Em Karniadakis.

  14. Learning to control PDEs with differentiable physics. ICLR, 2020. paper

    Philipp Holl, Nils Thuerey, and Vladlen Koltun.

  15. A generalizable physics-informed learning framework for risk probability estimation. L4DC, 2020. paper

    Zhuoyuan Wang and Yorie Nakahira.

  16. Operator learning for nonlinear adaptive control. L4DC, 2023. paper

    Luke Bhan, Yuanyuan Shi and Miroslav Krstic.

  17. Optimal temperature trajectory for tubular reactor using physics informed neural networks. JCP, 2023. paper

    Rahul Patel, Sharad Bhartiya, and Ravindra Gudi.

  18. Physics-informed recurrent neural network modeling for predictive control of nonlinear processes. Journal of Process Control, 2023. paper

    Yingzhe Zheng, Cheng Hu, Xiaonan Wang, and Zhe Wu.

  19. **Physics-guided neural networks for inversion-based feedforward control applied to hybrid stepper motors.**arXiv, 2023. paper

    Daiwei Fan, Max Bolderman, Sjirk Koekebakker, Hans Butler, and Mircea Lazar.

  20. Physics-informed recurrent neural network modeling for predictive control of nonlinear processes. JCP, 2023. paper

    Yingzhe Zheng, Cheng Hu, Xiaonan Wang, and Zhe Wu.

  21. Optimal Dirichlet boundary control by Fourier neural operators applied to nonlinear optics. arXiv, 2023. paper

    Nils Margenberg, Franz X. Kärtner, and Markus Bause.

  22. Neural operators for delay-compensating control of hyperbolic PIDEs. arXiv, 2023. paper

    Jie Qi, Jing Zhang, and Miroslav Krstic.

  23. Physics-informed online learning of gray-box models by moving horizon estimation. European Journal of Control, 2023. paper

    Kristoffer Fink Løwenstein, Daniele Bernardini, Lorenzo Fagiano, and Alberto Bemporad.

  24. Online identification and control of PDEs via reinforcement learning methods. arXiv, 2023. paper

    Alessandro Alla, Agnese Pacifico, Michele Palladino, and Andrea Pesare.

  25. The hard-constraint PINNs for interface optimal control problems. arXiv, 2023. paper

    Ming-Chih Lai, Yongcun Song, Xiaoming Yuan, Hangrui Yue, and Tianyou Zeng.

  26. Deep learning of delay-compensated backstepping for reaction-diffusion PDEs. arXiv, 2023. paper

    Shanshan Wang, Mamadou Diagne, and Miroslav Krstić.

  27. Computationally efficient data-driven discovery and linear representation of nonlinear systems for control. arXiv, 2023. paper

    Madhur Tiwari, George Nehma, and Bethany Lusch.

  28. Physics-informed state-space neural networks for transport phenomena. arXiv, 2023. paper

    Akshay J Dave and Richard B. Vilim.

  29. A comparison of mesh-free differentiable programming and data-driven strategies for optimal control under PDE constraints. arXiv, 2023. paper

    Roussel Desmond Nzoyem, David A.W. Barton, and Tom Deakin.

  30. A data-driven tracking control framework using physics-informed neural networks and deep reinforcement learning for dynamical systems. JCP, 2023. paper

    R.R. Faria, B.D.O. Capron, A.R. Secchi, and M.B. De Souza Jr.

  31. Leveraging Hamilton-Jacobi PDEs with time-dependent Hamiltonians for continual scientific machine learning. L4DC, 2023. paper

    Paula Chen, Tingwei Meng, Zongren Zou, Jérôme Darbon, and George Em Karniadakis.

  32. Physics-informed neural network Lyapunov functions: PDE characterization, learning, and verification. arXiv, 2023. paper

    Jun Liu, Yiming Meng, Maxwell Fitzsimmons, and Ruikun Zhou.

  33. Taming waves: A physically-interpretable machine learning framework for realizable control of wave dynamics. arXiv, 2023. paper

    Tristan Shah, Feruza Amirkulova, and Stas Tiomkin.

  34. Neural operators for boundary stabilization of stop-and-go traffic. arXiv, 2023. paper

    Yihuai Zhang, Ruiguo Zhong, and Huan Yu.

  35. Neural operator approximations of backstepping kernels for 2×2 hyperbolic PDEs. arXiv, 2023. paper

    Shanshan Wang, Mamadou Diagne, and Miroslav Krstić.

  36. Lyapunov-based physics-informed long short-term memory (LSTM) neural network-based adaptive control. IEEE Control Systems Letters, 2023. paper

    Rebecca G. Hart, Emily J. Griffis, Omkar Sudhir Patil, and Warren E. Dixon.

  37. Gain scheduling with a neural operator for a transport PDE with nonlinear recirculation. arXiv, 2024. paper

    Maxence Lamarque, Luke Bhan, Rafael Vazquez, and Miroslav Krstic.

  38. Physics-informed deep learning approach to solve optimal control problem. AIAA, 2024. paper

    Kyung-Mi Na and Chang-Hun Lee.

  39. Adaptive neural-operator backstepping control of a benchmark hyperbolic PDE. arXiv, 2024. paper

    Maxence Lamarque, Luke Bhan, Yuanyuan Shi, and Miroslav Krstic.

  40. Physical-informed neural network for MPC-based trajectory tracking of vehicles with noise considered. TIV, 2024. paper

    Long Jin, Longqi Liu, Xingxia Wang, Mingsheng Shang, and Feiyue Wang.

  41. Neural network approaches for parameterized optimal control. arXiv, 2024. paper

    Deepanshu Verma, Nick Winovich, Lars Ruthotto, and Bart van Bloemen Waanders.

  42. Physics-informed neural network policy iteration: Algorithms, convergence, and verification. arXiv, 2024. paper

    Yiming Meng, Ruikun Zhou, Amartya Mukherjee, Maxwell Fitzsimmons, Christopher Song, and Jun Liu.

  43. Nonlinear discrete-time observers with physics-informed neural networks. arXiv, 2024. paper

    Hector Vargas Alvarez, Gianluca Fabiani, Ioannis G. Kevrekidis, Nikolaos Kazantzis, and Constantinos Siettos.

  44. Pathwise relaxed optimal control of rough differential equations. arXiv, 2024. paper

    Prakash Chakraborty, Harsha Honnappa, and Samy Tindel.

  45. Parametric PDE control with deep reinforcement learning and differentiable L^0-sparse polynomial policies. arXiv, 2024. paper

    Nicolò Botteghi and Urban Fasel.

  46. PDE control gym: A benchmark for data-driven boundary control of partial differential equations. L4DC, 2024. paper

    Luke Bhan, Yuexin Bian, Miroslav Krstic, and Yuanyuan Shi.

  47. PhiBE: A PDE-based Bellman equation for continuous time policy evaluation. arXiv, 2024. paper

    Yuhua Zhu.

  48. Generalizable physics-informed learning for stochastic safety-critical systems. arXiv, 2024. paper

    Zhuoyuan Wang, Albert Chern, and Yorie Nakahira.

  49. Real-time optimal control of high-dimensional parametrized systems by deep learning-based reduced order models. arXiv, 2024. paper

    Matteo Tomasetto, Andrea Manzoni, and Francesco Braghin.

  50. An operator learning approach to nonsmooth optimal control of nonlinear PDEs. arXiv, 2024. paper

    Yongcun Song, Xiaoming Yuan, Hangrui Yue, and Tianyou Zeng.

  51. Is Pontryagin's maximum principle all you need? Solving optimal control problems with PMP-inspired neural networks. arXiv, 2024. paper

    Kawisorn Kamtue, Jose M.F. Moura, and Orathai Sangpetch.

  1. FourCastNet: A global data-driven high-resolution weather model using adaptive Fourier neural operators. arXiv, 2022. paper

    Jaideep Pathak, Shashank Subramanian, Peter Harrington, Sanjeev Raja, Ashesh Chattopadhyay, Morteza Mardani, Thorsten Kurth, David Hall, Zongyi Li, Kamyar Azizzadenesheli, Pedram Hassanzadeh, Karthik Kashinath, and Animashree Anandkumar.

  2. Fourier neural operators for arbitrary resolution climate data downscaling. JMLR, 2023. paper

    Qidong Yang, Alex Hernandez-Garcia, Paula Harder, Venkatesh Ramesh, Prasanna Sattegeri, Daniela Szwarcman, Campbell D. Watson, and David Rolnick.

  3. Modelling atmospheric dynamics with spherical Fourier neural operators. ICLR, 2023. paper

    Boris Bonev, Thorsten Kurth, Christian Hundt, Jaideep Pathak, Maximilian Baust, Karthik Kashinath, and Anima Anandkumar.

  4. Spatiotemporal modeling of European paleoclimate using doubly sparse Gaussian processes. NIPS, 2022. paper

    Seth D. Axen, Alexandra Gessner, Christian Sommer, Nils Weitzel, and Álvaro Tejero-Cantero.

  5. ClimSim: An open large-scale dataset for training high-resolution physics emulators in hybrid multi-scale climate simulators. arXiv, 2023. paper

    Sungduk Yu, Walter M. Hannah, Liran Peng, Mohamed Aziz Bhouri, Ritwik Gupta, Jerry Lin, Björn Lütjens, Justus C. Will, Tom Beucler, Bryce E. Harrop, Benjamin R. Hillman, Andrea M. Jenney, Savannah L. Ferretti, Nana Liu, Anima Anandkumar, Noah D. Brenowitz, Veronika Eyring, Pierre Gentine, Stephan Mandt, Jaideep Pathak, Carl Vondrick, Rose Yu, Laure Zanna, Ryan P. Abernathey, Fiaz Ahmed, David C. Bader, Pierre Baldi, Elizabeth A. Barnes, Gunnar Behrens, Christopher S. Bretherton, Julius J. M. Busecke, Peter M. Caldwell, Wayne Chuang, Yilun Han, Yu Huang, Fernando Iglesias-Suarez, Sanket Jantre, Karthik Kashinath, Marat Khairoutdinov, Thorsten Kurth, Nicholas J. Lutsko, Po-Lun Ma, Griffin Mooers, J. David Neelin, David A. Randall, Sara Shamekh, Akshay Subramaniam, Mark A. Taylor, Nathan M. Urban, Janni Yuval, Guang J. Zhang, Tian Zheng, and Michael S. Pritchard.

  6. Seismic traveltime simulation for variable velocity models using physics-informed Fourier neural operator. arXiv, 2023. paper

    Chao Song, Tianshuo Zhao, Umair bin Waheed, and Cai Liu.

  7. DeepPhysiNet: Bridging deep learning and atmospheric physics for accurate and continuous weather modeling. arXiv, 2024. paper

    Wenyuan Li, Zili Liu, Keyan Chen, Hao Chen, Shunlin Liang, Zhengxia Zou, and Zhenwei Shi.

  8. Residual-enhanced physics-guided machine learning with hard constraints for subsurface flow in reservoir engineering. TGRS, 2024. paper

    Haibo Cheng, Yunpeng He, Peng Zeng, and Valeriy Vyatkin.

  1. Wavelet neural operator for solving parametric partial differential equations in computational mechanics problems. CMAME, 2023. paper

    Tapas Tripura and Souvik Chakraborty.

  2. Graph neural networks for airfoil design. arXiv, 2023. paper

    Florent Bonnet.

  3. Exact Dirichlet boundary physics-informed neural network EPINN for solid mechanics. CMAME, 2023. paper

    Jiaji Wang, Y.L. Mo, Bassam Izzuddin, and Chul-Woo Kim.

  4. Solving multi-material problems in solid mechanics using physics-informed neural networks based on domain decomposition technology. CMAME, 2023. paper

    Yu Diao, Jianchuan Yang, Ying Zhang, Dawei Zhang, and Yiming Du.

  5. A novel key performance analysis method for permanent magnet coupler using physics-informed neural networks. Engineering with Computers, 2023. paper

    Huayan Pu, Bo Tan, Jin Yi, Shujin Yuan, Jinglei Zhao, Ruqing Bai, and Jun Luo.

  6. Mechanical characterization and inverse design of stochastic architected metamaterials using neural operators. arXiv, 2023. paper

    Hanxun Jin, Enrui Zhang, Boyu Zhang, Sridhar Krishnaswamy, George Em Karniadakis, and Horacio D. Espinosa.

  7. A deep learning energy-based method for classical elastoplasticity. International Journal of Plasticity, 2023. paper

    Junyan He, Diab Abueidda, Rashid Abu Al-Ru, Seid Koric, and Iwona Jasiuk.

  8. Physics-informed neural networks for magnetostatic problems on axisymmetric transformer geometries. IEEE Journal of Emerging and Selected Topics in Industrial Electronics, 2023. paper

    Philipp Brendel, Vlad Medvedev, and Andreas Rosskopf.

  9. Neural born series operator for biomedical ultrasound computed tomography. arXiv, 2023. paper

    Zhijun Zeng, Yihang Zheng, Youjia Zheng, Yubing Li, Zuoqiang Shi, and He Sun.

  10. Learning thermoacoustic interactions in combustors using a physics-informed neural network. arXiv, 2024. paper

    Sathesh Mariappan, Kamaljyoti Nath, and George Em Karniadakis.

  11. Flight dynamic uncertainty quantification modeling using physics-informed neural networks. AIAA, 2024. paper

    Nathaniel Michek, Piyush Mehta, and Wade Huebsch.

  12. Peridynamic neural operators: A data-driven nonlocal constitutive model for complex material responses. arXiv, 2024. paper

    Siavash Jafarzadeh, Stewart Silling, Ning Liu, Zhongqiang Zhang, and Yue Yu.

  13. Stochastic dynamics of aircraft ground taxiing via improved physics-informed neural networks. Nonlinear Dynamics, 2024. paper

    Ying Zhang, Zhengrong Jin, Long Wang, Kaixin Zheng, and Wantao Jia.

  14. Damage identification for plate structures using physics-informed neural networks. MSSP, 2024. paper

    Wei Zhou and Yongfeng Xu.

  15. Quantification of gradient energy coefficients using physics-informed neural networks. International Journal of Mechanical Sciences, 2024. paper

    Lan Shang, Yunhong Zhao, Sizheng Zheng, Jin Wang, Tongyi Zhang, and Jie Wang.

  16. MPIPN: A multi physics-informed PointNet for solving parametric acoustic-structure systems. arXiv, 2024. paper

    Chu Wang, Jinhong Wu, Yanzhi Wang, Zhijian Zha, and Qi Zhou.

  17. A hierarchically normalized physics-informed neural network for solving differential equations: Application for solid mechanics problems. EAAI, 2024. paper

    Thang Le-Duc, Seunghye Lee, H. Nguyen-Xuan, and Jaehong Lee.

  18. Physics-informed machine learning using low-fidelity flowfields for inverse airfoil shape design. AIAA, 2024. paper

    Benjamin Y. J. Wong, Murali Damodaran, and Boo Cheong Khoo.

  19. A hard constraint and domain decomposition based physics-informed neural network framework for nonhomogeneous transient thermal analysis. TCPMT, 2024. paper

    Zengkai Wu, Li Jun Jiang, Sheng Sun, and Ping Li.

  20. Boundary integrated neural networks for 2D elastostatic and piezoelectric problems. IJMS, 2024. paper

    Peijun Zhang, Longtao Xie, Yan Gu, Wenzhen Qu, Shengdong Zhao, and Chuanzeng Zhang.

  21. Transferable machine learning model for the aerodynamic prediction of swept wings. PoF, 2024. paper

    Yunjia Yang, Runze Li, Yufei Zhang, Lu Lu, and Haixin Chen.

  22. Data-driven methods for the inverse problem of suspension system excited by jump and diffusion stochastic track excitation. International Journal of Non-Linear Mechanics, 2024. paper

    Wantao Jia, Menglin Hu, Wanrong Zan, and Fei Ni.

  23. Real-time full-field inference of displacement and stress from sparse local measurements using physics-informed neural networks. MSSP, 2024. paper

    Myeong-Seok Go, Hong-Kyun Noh, and Jae Hyuk Lim.

  24. On physics-informed neural networks training for coupled hydro-poromechanical problems. JCP, 2024. paper

    Caterina Millevoi, Nicolò Spiezia, and Massimiliano Ferronato.

  1. Hybrid learning of time-series inverse dynamics models for locally isotropic robot motion. RAL, 2022. paper

    Tolga-Can Çallar and Sven Böttger.

  2. NTFields: Neural time fields for physics-informed robot motion planning. ICLR, 2023. paper

    Ruiqi Ni and Ahmed H Qureshi.

  3. Online parameter estimation using physics-informed deep learning for vehicle stability algorithms. arXiv, 2023. paper

    Kemal Koysuren, Ahmet Faruk Keles, and Melih Cakmakci.

  4. A locality-based neural solver for optical motion capture. SIGGRAPH, 2023. paper

    Xiaoyu Pan, Bowen Zheng, Xinwei Jiang, Guanglong Xu, Xianli Gu, Jingxiang Li, Qilong Kou, He Wang, Tianjia Shao, Kun Zhou, and Xiaogang Jin.

  5. Approximating high-dimensional minimal surfaces with physics-informed neural networks. arXiv, 2023. paper

    Steven Zhou and Xiaojing Ye.

  6. A spatial-temporally adaptive PINN framework for 3D bi-ventricular electrophysiological simulations and parameter inference. MICCAI, 2023. paper

    Yubo Ye, Huafeng Liu, Xiajun Jiang, Maryam Toloubidokhti, and Linwei Wang.

  7. Using the Transformer model for physical simulation: An application on transient thermal analysis for 3D printing process simulation. NIPS, 2023. paper

    Qian Chen, Luyang Kong, Florian Dugast, and Albert To.

  8. Physics-informed neural network for solution of forward and inverse kinematic wave problems. Journal of Hydrology, 2024. paper

    Qingzhi Hou, Yixin Li, Vijay P. Singh, Zewei Sun, and Jianguo Wei.

  9. PhyGrasp: Generalizing robotic grasping with physics-informed large multimodal models. arXiv, 2024. paper

    Dingkun Guo, Yuqi Xiang, Shuqi Zhao, Xinghao Zhu, Masayoshi Tomizuka, Mingyu Ding, and Wei Zhan.

  10. Structure-preserving operator learning: Modeling the collision operator of kinetic equations. arXiv, 2024. paper

    Jae Yong Lee, Steffen Schotthöfer, Tianbai Xiao, Sebastian Krumscheid, and Martin Frank.

  11. Neural inverse source problems. CoRL, 2024. paper

    Youngsun Wi, Miquel Oller, Jayjun Lee, and Nima Fazeli.

  12. One model to drift them all: Physics-informed conditional diffusion model for driving at the limits. CoRL, 2024. paper

    Franck Djeumou, Thomas Jonathan Lew, NAN DING, Michael Thompson, Makoto Suminaka, Marcus Greiff, and John Subosits.

  1. Dynamic weights enabled physics-informed neural network for simulating the mobility of engineered nano-particles in a contaminated aquifer. NIPS, 2022. paper

    Shikhar Nilabh and Fidel Grandia.

  2. Learning two-phase microstructure evolution using neural operators and autoencoder architectures. NPJ Computational Materials, 2022. paper

    Vivek Oommen, Khemraj Shukla, Somdatta Goswami, Rémi Dingreville, and George Em Karniadakis.

  3. Predicting glass structure by physics-informed machine learning. NPJ Computational Materials, 2022. paper

    Mikkel L. Bødker, Mathieu Bauchy, Tao Du, John C. Mauro, and Morten M. Smedskjaer.

  4. Physics-informed deep learning for solving phonon Boltzmann transport equation with large temperature non-equilibrium. NPJ Computational Materials, 2022. paper

    Ruiyang Li, Jianxun Wang, Eungkyu Lee, and Tengfei Luo.

  5. Design of Turing systems with physics-informed neural networks. arXiv, 2022. paper

    Jordon Kho, Winston Koh, Jian Cheng Wong, Pao-Hsiung Chiu, and Chin Chun Ooi.

  6. Spatio-temporal super-resolution of dynamical systems using physics-informed deep-learning. AAAI, 2023. paper

    Rajat Arora and Ankit Shrivastava.

  7. Rapid seismic waveform modeling and inversion with neural operators. TGRS, 2023. paper

    Yan Yang, Angela F. Gao, Kamyar Azizzadenesheli, Robert W. Clayton, and Zachary E. Ross.

  8. Accelerating heat exchanger design by combining Physics-Informed deep learning and transfer learning. Chemical Engineering Science, 2023. paper

    Zhiyong Wu, Bingjian Zhang, Haoshui Yu, Jingzheng Ren, Ming Pan, Chang He, and Qinglin Chen.

  9. Energy stable neural network for gradient flow equations. arXiv, 2023. paper

    Ganghua Fan, Tianyu Jin, Yuan Lan, Yang Xiang, and Luchan Zhang.

  10. Physics-informed neural network with transfer learning (TL-PINN) based on domain similarity measure for prediction of nuclear reactor transients. Scientific Reports, 2023. paper

    Konstantinos Prantikos, Stylianos Chatzidakis, Lefteri H. Tsoukalas, and Alexander Heifetz.

  11. Plasma surrogate modelling using Fourier neural operators. arXiv, 2023. paper

    Vignesh Gopakumar, Stanislas Pamela, Lorenzo Zanisi, Zongyi Li, Ander Gray, Daniel Brennand, Nitesh Bhatia, Gregory Stathopoulos, Matt Kusner, Marc Peter Deisenroth, Anima Anandkumar, JOREK Team, and MAST Team.

  12. Training a deep operator network as a surrogate solver for two-dimensional parabolic-equation models. Journal of the Acoustical Society of America, 2023. paper

    Liang Xu, Haigang Zhang, and Minghui Zhang.

  13. Grad-Shafranov equilibria via data-free physics informed neural networks. arXiv, 2023. paper

    Byoungchan Jang, Alan A. Kaptanoglu, Rahul Gaur, Shaw Pan, Matt Landreman, and William Dorland.

  14. Physics-informed deep learning of rate-and-state fault friction. arXiv, 2023. paper

    Cody Rucker and Brittany A. Erickson.

  15. Physics-informed neural networks with embedded analytical models: Inverse design of multilayer dielectric-loaded rectangular waveguide devices. IEEE Transactions on Microwave Theory and Techniques, 2023. paper

    Yinqing Pan, Ren Wang, and Bingzhong Wang.

  16. En-DeepONet: An enrichment approach for enhancing the expressivity of neural operators with applications to seismology. CMAME, 2023. paper

    Ehsan Haghighat, Umair bin Waheed, and George Karniadakis.

  17. Solving seismic wave equations on variable velocity models with Fourier neural operator. TGRS, 2023. paper

    Bian Li, Hanchen Wang, Shihang Feng, Xiu Yang, and Youzuo Lin.

  18. Calculating quasi-normal modes of Schwarzschild black holes with physics informed neural networks. arXiv, 2024. paper

    Nirmal Patel, Aycin Aykutalp, and Pablo Laguna.

  19. Deep neural operator-driven real-time inference to enable digital twin solutions for nuclear energy systems. Scientific Reports, 2024. paper

    Kazuma Kobayashi and Syed Bahauddin Alam.

  20. A physics-informed deep learning description of Knudsen layer reactivity reduction. arXiv, 2024. paper

    Christopher J. McDevitt and Xianzhu Tang.

  21. Inverse design method for horn antennas based on knowledge-embedded physics-informed neural networks. IEEE Antennas and Wireless Propagation Letters, 2024. paper

    Jinpin Liu, Bingzhong Wang, Chuan-Sheng Chen, and Ren Wang.

  22. Combined analysis of thermofluids and electromagnetism using physics-informed neural networks. EAAI, 2024. paper

    Yeonhwi Jeong, Junhyoung Jo, Tonghun Lee, and Jihyung Yoo.

  23. Fully convolutional network enhanced DeepONet-based surrogate of predicting the travel-time fields. TGRS, 2024. paper

    Yifan Mei, Yijie Zhang, Xueyu Zhu, Rongxi Gou, and Jinghuai Gao.

  24. Seismic wavefields modeling with variable horizontally-layered velocity models via velocity-encoded PINN. TGRS, 2024. paper

    Jingbo Zou, Cai Liu, Pengfei Zhao, and Chao Song.

  25. SPI-MIONet for surrogate modeling in phase-field hydraulic fracturing. CMAME, 2024. paper

    Xiaoqiang Wang, Peichao Li, Kaile Jia, Shaoqi Zhang, Chun Li, Bangchen Wu, Yilun Dong, and Detang Lu.

  26. A physics-informed neural networks modeling with coupled fluid flow and heat transfer – Revisit of natural convection in cavity. International Communications in Heat and Mass Transfer, 2024. paper

    Zahra Hashemi, Maysam Gholampour, Mingchang Wu, Tingya Liu, Chuanyi Liang, and Chichuan Wang.

  27. Thermal conductivity estimation using physics-informed neural networks with limited data. EAAI, 2024. paper

    Junhyoung Jo, Yeonhwi Jeong, Jinsu Kim, and Jihyung Yoo.

  28. STAResNet: A network in spacetime algebra to solve Maxwell's PDEs. arXiv, 2024. paper

    Alberto Pepe, Sven Buchholz, and Joan Lasenby.

  1. Learning to diffuse: A new perspective to design PDEs for visual analysis. TPAMI, 2016. paper

    Risheng Liu, Guangyu Zhong, Junjie Cao, Zhouchen Lin, Shiguang Shan, and Zhongxuan Luo.

  2. Reformulating optical flow to solve image-based inverse problems and quantify uncertainty. TPAMI, 2022. paper

    Aleix Boquet-Pujadas and Jean-Christophe Olivo-Marin.

  3. WarpPINN: Cine-MR image registration with physics-informed neural networks. arXiv, 2022. paper

    Pablo Arratia Lopez, Hernan Mella, Sergio Uribe, Daniel E. Hurtado, and Francisco Sahli Costabal.

  4. NODE-ImgNet: A PDE-informed effective and robust model for image denoising. arXiv, 2023. paper

    Xinheng Xie, Yue Wu, Hao Nib, and Cuiyu He.

  5. Microscopy image reconstruction with physics-informed denoising diffusion probabilistic model. arXiv, 2023. paper

    Rui Li, Gabriel della Maggiora, Vardan Andriasyan, Anthony Petkidis, Artsemi Yushkevich, Mikhail Kudryashev, and Artur Yakimovich.

  6. TGM-Nets: A deep learning framework for enhanced forecasting of tumor growth by integrating imaging and modeling. EAAI, 2023. paper

    Qijing Chen, Qi Ye, Weiqi Zhang, He Li, and Xiaoning Zheng.

  7. The use of physics-informed neural network approach to image restoration via nonlinear PDE tools. Computers & Mathematics with Applications, 2023. paper

    Neda Namaki, M.R. Eslahchi, and Rezvan Salehi.

  8. Personalized predictions of glioblastoma infiltration: Mathematical models, physics-informed neural networks and multimodal scans. arXiv, 2023. paper

    Ray Zirui Zhang, Ivan Ezhov, Michal Balcerak, Andy Zhu, Benedikt Wiestler, Bjoern Menze, and John Lowengrub.

  9. Real-time FJ/MAC PDE solvers via tensorized, back-propagation-free optical PINN training. arXiv, 2024. paper

    Yequan Zhao, Xian Xian, Xinling Yu, Ziyue Liu, Zhixiong Chen, Geza Kurczveil, Raymond G. Beausoleil, and Zheng Zhang.

  10. Performance of Fourier-based activation function in physics-informed neural networks for patient-specific cardiovascular flows. Computer Methods and Programs in Biomedicine, 2024. paper

    Arman Aghaee and M. Owais Khan.

  11. Effective medium properties of stealthy hyperuniform photonic structures using multiscale physics-informed neural networks. arXiv, 2024. paper

    Roberto Riganti, Yilin Zhu, Wei Cai, Salvatore Torquato, and Luca Dal Negro.

  1. Combustion chemistry acceleration with DeepONets. Fuel, 2024. paper

    Anuj Kumar and Tarek Echekki.

  1. Microstructure-sensitive deformation modeling and materials design with physics-informed neural networks. AIAA Journal, 2024. paper

    Mahmudul Hasan, Zekeriya Ender Eger, Arulmurugan Senthilnathan, and Pınar Acar.

  2. A novel Fourier neural operator framework for classification of multi-sized images: Application to three dimensional digital porous media. PoF, 2024. paper

    Ali Kashefi and Tapan Mukerji.

  3. A fast learning-based surrogate of electrical machines using a reduced basis. ICML, 2024. paper

    Alejandro Ribés, Nawfal Benchekroun, and Théo Delagnes.

  4. Discontinuous Galerkin method with a novel physics-informed flux for elastic wave simulations in heterogeneous media. TGRS, 2024. paper

    Xijun He, Xueyuan Huang, Dinghui Yang, Jiandong Huang, and Yanjie Zhou.

  5. Physics informed self-supervised segmentation of elastic composite materials. CMAME, 2024. paper

    Guilherme Basso Della Mea, Cristian Ovalle, Lucien Laiarinandrasana, Etienne Decencière, and Petr Dokládal.

  6. Micrometer: Micromechanics Transformer for predicting mechanical responses of heterogeneous materials. arXiv, 2024. paper

    Sifan Wang, Tongrui Liu, Shyam Sankaran, and Paris Perdikaris.

  7. A physics-informed composite network for modeling of electrochemical process of large-scale lithium-ion batteries. TII, 2024. paper

    Bingchuan Wang, Zhendong Ji, Yong Wang, Hanxiong Li, and Zhongmei Li.

  8. Adaptive fractional physics-informed neural networks for solving forward and inverse problems of anomalous heat conduction in functionally graded materials. IJHMS, 2024. paper

    Xingdan Ma, Lin Qiu, Benrong Zhang, Guozheng Wu, and Fajie Wang

  1. Symmetry-informed geometric representation for molecules, proteins, and crystalline materials. arXiv, 2023. paper

    Shengchao Liu, Weitao Du, Yanjing Li, Zhuoxinran Li, Zhiling Zheng, Chenru Duan, Zhiming Ma, Omar Yaghi, Anima Anandkumar, Christian Borgs, Jennifer Chayes, Hongyu Guo, and Jian Tang.

  2. Solving nonconvex energy minimization problems in martensitic phase transitions with a mesh-free deep learning approach. CMAME, 2023. paper

    Xiaoli Chen, Phoebus Rosakis, Zhizhang Wu, and Zhiwen Zhang.

  3. A physics-guided bi-fidelity Fourier-featured operator learning framework for predicting time evolution of drag and lift coefficients. arXiv, 2023. paper

    Amirhossein Mollaali, Izzet Sahin, Iqrar Raza, Christian Moya, Guillermo Paniagua, and Guang Lin.

  4. Mixed form based physics-informed neural networks for performance evaluation of two-phase random materials. EAAI, 2023. paper

    Xiaodan Ren and Xianrui Lyu.

  5. Deep learning based solution of nonlinear partial differential equations arising in the process of arterial blood flow. Mathematics and Computers in Simulation, 2023. paper

    Bivas Bhaumik, Soumen De, and Satyasaran Changdar.

  6. Physics-informed neural networks for solving dynamic two-phase interface problems. SIAM Journal on Scientific Computing, 2023. paper

    Xingwen Zhu, Xiaozhe Hu, and Pengtao Sun.

  7. Rethinking materials simulations: Blending direct numerical simulations with neural operators. arXiv, 2023. paper

    Vivek Oommen, Khemraj Shukla, Saaketh Desai, Remi Dingreville, and George Em Karniadakis.

  8. A conservative hybrid physics-informed neural network method for Maxwell-Ampère-Nernst-Planck equations. arXiv, 2023. paper

    Cheng Chang, Zhouping Xin, and Tieyong Zeng.

  9. A data-driven physics-constrained deep learning computational framework for solving von Mises plasticity. EAAI, 2023. paper

    Arunabha M. Roy and Suman Guha.

  10. Learning stiff chemical kinetics using extended deep neural operators. CMAME, 2024. paper

    Somdatta Goswami, Ameya D. Jagtap, Hessam Babaee, Bryan T. Susi, and George Em Karniadakis.

  11. Deep-learning based parameter identification enables rationalization of battery material evolution in complex electrochemical systems. Journal of Computational Science, 2023. paper

    Ivonne Sgura, Luca Mainetti, Francesco Negro, Maria Grazia Quarta, and Benedetto Bozzini.

  12. AI-aided geometric design of anti-infection catheters. Science Advances, 2023. paper

    Tingtao Zhou, Xuan Wan, Daniel Zhengyu Huang, Zongyi Li, Zhiwei Peng, Anima Anandkumar, John F. Brady, Paul W. Sternberg, and Chiara Daraio.

  13. Physics-informed deep learning to solve three-dimensional Terzaghi’s consolidation equation: Forward and inverse problems. arXiv, 2024. paper

    Biao Yuan, Ana Heitor, He Wang, and Xiaohui Chen.

  14. Solving the discretised multiphase flow equations with interface capturing on structured grids using machine learning libraries. arXiv, 2024. paper

    Boyang Chen, Claire E. Heaney, Jefferson L. M. A. Gomes, Omar K. Matar, and Christopher C. Pain.

  15. Combustion chemistry acceleration with DeepONets. Fuel, 2024. paper

    Anuj Kumar and Tarek Echekki.

  16. Identifying heterogeneous micromechanical properties of biological tissues via physics-informed neural networks. arXiv, 2024. paper

    Wensi Wu, Mitchell Daneker, Kevin T. Turner, Matthew A. Jolley, and Lu Lu.

  17. Adaptive data-driven deep-learning surrogate model for frontal polymerization in dicyclopentadiene. The Journal of Physical Chemistry B, 2024. paper

    Qibang Liu, Diab Abueidda, Sagar Vyas, Yuan Gao, Seid Koric, and Philippe H. Geubelle. Wensi Wu, Mitchell Daneker, Kevin T. Turner, Matthew A. Jolley, and Lu Lu.

  18. Understanding protein-DNA interactions by paying attention to protein and genomics foundation models. NIPS, 2024. paper

    Dhruva Rajwade, Erica Wang, Aryan Satpathy, Alexander Brace, Hongyu Guo, Arvind Ramanathan, Shengchao Liu, and Anima Anandkumar.

  19. Language models for text-guided protein evolution. NIPS, 2024. paper

    Zhanghan Ni, Shengchao Liu, and Anima Anandkumar

  1. Physics-informed neural network for lithium-ion battery degradation stable modeling and prognosis. NC, 2024. paper

    Fujin Wang, Zhi Zhai, Zhibin Zhao, Yi Di, and Xuefeng Chen.

  2. Residual-based attention physics-informed Neural Networks for spatio-temporal ageing assessment of transformers operated in renewable power plants. EAAI, 2024. paper

    Ibai Ramirez, Joel Pino, David Pardo, Mikel Sanz, Luis del Rio, Alvaro Ortiz, Kateryna Morozovska, and Jose I. Aizpurua.

  1. Physics-informed neural networks for quantum eigenvalue problems. IJCNN, 2022. paper

    Henry Jin, Marios Mattheakis, and Pavlos Protopapas.

  2. Quantum-inspired tensor neural networks for partial differential equations. arXiv, 2022. paper

    Raj Patel, Chia-Wei Hsing, Serkan Sahin, Saeed S. Jahromi, Samuel Palmer, Shivam Sharma, Christophe Michel, Vincent Porte, Mustafa Abid, Stephane Aubert, Pierre Castellani, Chi-Guhn Lee, Samuel Mugel, and Roman Orus.

  3. Quantum Fourier networks for solving parametric PDEs. arXiv, 2023. paper

    Nishant Jain, Jonas Landman, Natansh Mathur, and Iordanis Kerenidis.

  4. Q-Flow: Generative modeling for differential equations of open quantum dynamics with normalizing flows. ICML, 2023. paper

    Owen M Dugan, Peter Y. Lu, Rumen Dangovski, Di Luo, and Marin Soljacic.

  5. Physics-informed quantum machine learning: Solving nonlinear differential equations in latent spaces without costly grid evaluations. arXiv, 2023. paper

    Annie E. Paine, Vincent E. Elfving, and Oleksandr Kyriienko.

  6. Physics-informed quantum machine learning for solving partial differential equations. arXiv, 2023. paper

    Abhishek Setty, Rasul Abdusalamov, and Mikhail Itskov.

  1. Approximating discontinuous Nash equilibria values of two-player general-sum differential games. arXiv, 2022. paper

    Lei Zhang, Mukesh Ghimire, Wenlong Zhang, Zhe Xu, and Yi Ren.

  2. Solving two-player general-sum games between swarms. arXiv, 2023. paper

    Mukesh Ghimire, Lei Zhang, Wenlong Zhang, Yi Ren, and Zhe Xu.

  3. Value approximation for two-player general-sum differential games with state constraints. arXiv, 2023. paper

    Lei Zhang, Mukesh Ghimire, Wenlong Zhang, Zhe Xu, and Yi Ren.

  4. Unsupervised solution operator learning for mean-field games via sampling-invariant parametrizations. arXiv, 2024. paper

    Han Huang and Rongjie Lai.

  5. Pontryagin neural operator for solving general-sum differential games with parametric state constraints. L4DC, 2024. paper

    Lei Zhang, Mukesh Ghimire, Zhe Xu, Wenlong Zhang, and Yi Ren.

  1. Physics-aware machine learning surrogates for real-time manufacturing digital twin. Manufacturing Letters, 2022. paper

    Aditya Balu, Soumik Sarkar, Baskar Ganapathysubramanian, and Adarsh Krishnamurthy.

  2. Multi-scale digital twin: Developing a fast and physics-informed surrogate model for groundwater contamination with uncertain climate models. arXiv, 2022. paper

    Lijing Wang, Takuya Kurihana, Aurelien Meray, Ilijana Mastilovic, Satyarth Praveen, Zexuan Xu, Milad Memarzadeh, Alexander Lavin, and Haruko Wainwright.

  3. SciAI4Industry--Solving PDEs for industry-scale problems with deep learning. arXiv, 2022. paper

    Philipp A. Witte, Russell J. Hewett, Kumar Saurabh, AmirHossein Sojoodi, and Ranveer Chandra.

  4. Operator learning framework for digital twin and complex engineering systems. arXiv, 2023. paper

    Kazuma Kobayashi, James Daniell, and Syed B. Alam.

  5. Towards solving industry-grade surrogate modeling problems using physics informed machine learning. arXiv, 2023. paper

    Saakaar Bhatnagar, Andrew Comerford, and Araz Banaeizadeh.

  6. Data-driven physics-informed neural networks: A digital twin perspective. arXiv, 2024. paper

    Sunwoong Yang, Hojin Kim, Yoonpyo Hong, Kwanjung Yee, Romit Maulik, and Namwoo Kang.

  7. Physically informed synchronic-adaptive learning for industrial systems modeling in heterogeneous media with unavailable time-varying interface. arXiv, 2024. paper

    Aina Wang, Pan Qin, and Ximing Sun.

  8. Improved generalization with deep neural operators for engineering systems: Path towards digital twin. EAAI, 2024. paper

    Kazuma Kobayashi, James Daniell, and Syed Bahauddin Alam.

  9. A deep transfer operator learning method for temperature field reconstruction in a lithium-ion battery pack. TII, 2024. paper

    Yuchen Wang, Can Xiong, Changjiang Ju, Genke Yang, Yuwang Chen, and Xiaotian Yu.

  10. ro-PINN: A reduced order physics-informed neural network for solving the macroscopic model of pedestrian flows. Transportation Research Part C: Emerging Technologies, 2024. paper

    Renbin Pan, Feng Xiao, and Minyu Shen.

  1. A deep learning based numerical PDE method for option pricing. Computational Economics, 2023. paper

    Xiang Wang, Jessica Li, and Jichun Li.

  2. Enhancing fine-grained urban flow inference via incremental neural operator IJCAI, 2024. paper

    Qiang Gao, Xiaolong Song, Li Huang, Goce Trajcevski, Fan Zhou, and Xueqin Chen.

  1. Occupancy networks: Learning 3D reconstruction in function space. CVPR, 2019. paper

    Lars Mescheder, Michael Oechsle, Michael Niemeyer, Sebastian Nowozin, and Andreas Geiger.

  2. Transfer learning for flow reconstruction based on multifidelity data. AIAA Journal, 2022. paper

    Jiaqing Kou, Chenjia Ning, and Weiwei Zhang.

  3. Learning-based state reconstruction for a scalar hyperbolic PDE under noisy lagrangian sensing. L4DC, 2022. paper

    Matthieu Barreau, John Liu, and Karl Henrik Johansson.

  1. A novel physics-informed neural network for modeling electromagnetism of a permanent magnet synchronous motor. Advanced Engineering Informatics, 2023. paper

    Seho Son, Hyunseung Lee, Dayeon Jeong, Ki-Yong Oh, and Kyung Ho Sun.

  2. A novel key performance analysis method for permanent magnet coupler using physics informed neural networks. Engineering with Computer, 2023. paper

    Huayan Pu, Bo Tan, Jin Yi, Shujin Yuan, Jinglei Zhao, Ruqing Bai, and Jun Luo.

  3. Physics-informed neural networks for solving parametric magnetostatic problems. TEC, 2023. paper

    Andrés Beltrán-Pulido, Ilias Bilionis, and Dionysios Aliprantis.

  4. Physics-informed neural networks for solving 2-D magnetostatic fields. TMAG, 2023. paper

    Zhi Gong, Yang Chu, and Shiyou Yang.

  5. Physics-informed sparse neural network for permanent magnet eddy current device modeling and analysis. LMAG, 2023. paper

    Dazhi Wang, Sihan Wang, Deshan Kong, Jiaxing Wang, Wenhui Li, and Michael Pecht.

  6. PACE: Pacing operator learning to accurate optical field simulation for complicated photonic devices. NIPS, 2023. paper

    Hanqing Zhu, Wenyan Cong, Guojin Chen, Shupeng Ning, Ray Chen, Jiaqi Gu, and David Z. Pan.

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