D2NO: Efficient Handling of Heterogeneous Input Function Spaces with
Distributed Deep Neural Operators
- URL: http://arxiv.org/abs/2310.18888v1
- Date: Sun, 29 Oct 2023 03:29:59 GMT
- Title: D2NO: Efficient Handling of Heterogeneous Input Function Spaces with
Distributed Deep Neural Operators
- Authors: Zecheng Zhang, Christian Moya, Lu Lu, Guang Lin, Hayden Schaeffer
- Abstract summary: We propose a novel distributed approach to deal with input functions that exhibit heterogeneous properties.
A central neural network is used to handle shared information across all output functions.
We demonstrate that the corresponding neural network is a universal approximator of continuous nonlinear operators.
- Score: 7.119066725173193
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Neural operators have been applied in various scientific fields, such as
solving parametric partial differential equations, dynamical systems with
control, and inverse problems. However, challenges arise when dealing with
input functions that exhibit heterogeneous properties, requiring multiple
sensors to handle functions with minimal regularity. To address this issue,
discretization-invariant neural operators have been used, allowing the sampling
of diverse input functions with different sensor locations. However, existing
frameworks still require an equal number of sensors for all functions. In our
study, we propose a novel distributed approach to further relax the
discretization requirements and solve the heterogeneous dataset challenges. Our
method involves partitioning the input function space and processing individual
input functions using independent and separate neural networks. A centralized
neural network is used to handle shared information across all output
functions. This distributed methodology reduces the number of gradient descent
back-propagation steps, improving efficiency while maintaining accuracy. We
demonstrate that the corresponding neural network is a universal approximator
of continuous nonlinear operators and present four numerical examples to
validate its performance.
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