TY - JOUR
T1 - Physics-Aware Neural Implicit Solvers for multiscale, parametric PDEs with applications in heterogeneous media
AU - Chatzopoulos, Matthaios
AU - Koutsourelakis, Phaedon Stelios
N1 - Publisher Copyright:
© 2024 The Author(s)
PY - 2024/12/1
Y1 - 2024/12/1
N2 - We propose Physics-Aware Neural Implicit Solvers (PANIS), a novel, data-driven framework for learning surrogates for parametrized Partial Differential Equations (PDEs). It consists of a probabilistic, learning objective in which weighted residuals are used to probe the PDE and provide a source of virtual data i.e. the actual PDE never needs to be solved. This is combined with a physics-aware implicit solver that consists of a much coarser, discretized version of the original PDE, which provides the requisite information bottleneck for high-dimensional problems and enables generalization in out-of-distribution settings (e.g. different boundary conditions). We demonstrate its capability in the context of random heterogeneous materials where the input parameters represent the material microstructure. We extend the framework to multiscale problems and show that a surrogate can be learned for the effective (homogenized) solution without ever solving the reference problem. We further demonstrate how the proposed framework can accommodate and generalize several existing learning objectives and architectures while yielding probabilistic surrogates that can quantify predictive uncertainty.
AB - We propose Physics-Aware Neural Implicit Solvers (PANIS), a novel, data-driven framework for learning surrogates for parametrized Partial Differential Equations (PDEs). It consists of a probabilistic, learning objective in which weighted residuals are used to probe the PDE and provide a source of virtual data i.e. the actual PDE never needs to be solved. This is combined with a physics-aware implicit solver that consists of a much coarser, discretized version of the original PDE, which provides the requisite information bottleneck for high-dimensional problems and enables generalization in out-of-distribution settings (e.g. different boundary conditions). We demonstrate its capability in the context of random heterogeneous materials where the input parameters represent the material microstructure. We extend the framework to multiscale problems and show that a surrogate can be learned for the effective (homogenized) solution without ever solving the reference problem. We further demonstrate how the proposed framework can accommodate and generalize several existing learning objectives and architectures while yielding probabilistic surrogates that can quantify predictive uncertainty.
KW - Data-driven
KW - Deep learning
KW - High-dimensional surrogates
KW - Machine learning
KW - Probabilistic surrogate
KW - Random heterogeneous materials
KW - Virtual observables
UR - http://www.scopus.com/inward/record.url?scp=85203013942&partnerID=8YFLogxK
U2 - 10.1016/j.cma.2024.117342
DO - 10.1016/j.cma.2024.117342
M3 - Article
AN - SCOPUS:85203013942
SN - 0045-7825
VL - 432
JO - Computer Methods in Applied Mechanics and Engineering
JF - Computer Methods in Applied Mechanics and Engineering
M1 - 117342
ER -