TY - JOUR
T1 - Physics-Informed Neural Networks for 1-D Steady-State Diffusion-Advection-Reaction Equations
AU - Laghi, Laura
AU - Schiassi, Enrico
AU - De Florio, Mario
AU - Furfaro, Roberto
AU - Mostacci, Domiziano
N1 - Publisher Copyright: © 2023 American Nuclear Society.
PY - 2023
Y1 - 2023
N2 - This work aims to solve six problems with four different physics-informed machine learning frameworks and compare the results in terms of accuracy and computational cost. First, we considered the diffusion-advection-reaction equations, which are second-order linear differential equations with two boundary conditions. The first algorithm is the classic Physics-Informed Neural Networks. The second one is Physics-Informed Extreme Learning Machine. The third framework is Deep Theory of Functional Connections, a multilayer neural network based on the solution approximation via a constrained expression that always analytically satisfies the boundary conditions. The last algorithm is the Extreme Theory of Functional Connections (X-TFC), which combines Theory of Functional Connections and shallow neural network with random features [e.g., Extreme Learning Machine (ELM)]. The results show that for these kinds of problems, ELM-based frameworks, especially X-TFC, overcome those using deep neural networks both in terms of accuracy and computational time.
AB - This work aims to solve six problems with four different physics-informed machine learning frameworks and compare the results in terms of accuracy and computational cost. First, we considered the diffusion-advection-reaction equations, which are second-order linear differential equations with two boundary conditions. The first algorithm is the classic Physics-Informed Neural Networks. The second one is Physics-Informed Extreme Learning Machine. The third framework is Deep Theory of Functional Connections, a multilayer neural network based on the solution approximation via a constrained expression that always analytically satisfies the boundary conditions. The last algorithm is the Extreme Theory of Functional Connections (X-TFC), which combines Theory of Functional Connections and shallow neural network with random features [e.g., Extreme Learning Machine (ELM)]. The results show that for these kinds of problems, ELM-based frameworks, especially X-TFC, overcome those using deep neural networks both in terms of accuracy and computational time.
KW - Extreme Learning Machine
KW - Physics-Informed Neural Networks
KW - functional interpolation
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U2 - 10.1080/00295639.2022.2160604
DO - 10.1080/00295639.2022.2160604
M3 - Article
SN - 0029-5639
VL - 197
SP - 2373
EP - 2403
JO - Nuclear Science and Engineering
JF - Nuclear Science and Engineering
IS - 9
ER -