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PhD Final Defense – Rini Jasmine Gladstone

Event Type
Conference/Workshop
Sponsor
Civil and Environmental Engineering
Location
CEEB 1017
Date
Dec 10, 2024   12:00 pm  
Views
237
Originating Calendar
CEE Seminars and Conferences

Efficient Deep Learning-Based Models for Physics Simulation and Computational

Design

Advisor: Dr. Hadi Meidani

Scientific computing problems are widely used in an array of problems with applications

ranging from micro- to macro-world in the field of physics, biology, material science, and civil

and mechanical engineering. Many scientific computing problems such as design optimization,

and design space exploration require resource-intensive repetitive simulation runs of a model

with different input values. For systems characterized by numerous input parameters, the

response calculation is particularly challenging as one also has to deal with the curse of

dimensionality, which is the exponential increase in the volume of the input space, as the

number of parameters increases linearly. Many real-world computational problems, governed

by partial differential equations, require running high-fidelity simulations of physical systems,

using numerical methods such as finite element, and thus are often limited by the available

computational resources. While data-driven and physics-informed deep learning based

surrogate models have demonstrated success in tackling many of these problems, they still

grapple with limitations in generalizability across problems, ability to handle complex domains

and dependence on high data quality (for supervised models).

The overarching objective of this research is to take a step toward addressing these

computational challenges and contribute to the promotion of efficient computational

approaches based on deep learning for scientific computing problems such as physics

simulations and computational design. In particular, and in moving toward this objective, we

introduce various deep learning approaches, both data-driven and physics-informed, for fast

and efficient modeling of physical systems. First, we tackle supervised deep learning

algorithms, primarily Variational Autoencoders (VAEs) and Graph Neural Networks (GNNs)

and their applications for various array of problems such as Robust Topology Optimization

(RTO), time-independent physics simulations and multi-fidelity methods. In particular, we

introduce multi-fidelity architectures for VAE and GNN for improving the computational

efficiency of the models. We also propose novel GNN architectures for accurate evaluation of

time-independent physical systems. Then, we introduce two variants of physics-informed

neural network (PINN), an unsupervised model, namely FO-PINN and PINN-FEM, to tackle

some of the challenges of PINNs, including strong imposition of boundary conditions, and

solving higher-order PDEs and parameterized systems. We verify the accuracy and efficiency

of the proposed methods through a variety of engineering applications. The performance of the

proposed approaches in this research, thus, significantly extend the application of scientific

deep learning models for simulating complex systems in science and engineering.

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