Deep neural nets with fixed bias configuration-Reference-Cited by-同舟云学术

Deep neural nets with fixed bias configuration

Published:2022 Issue:0 Volume:0 Page:0
ISSN:2155-3289
Container-title:Numerical Algebra, Control and Optimization
language:
Short-container-title:NACO

Author:

Antil Harbir¹,Brown Thomas S.¹,Löhner Rainald²,Togashi Fumiya³,Verma Deepanshu⁴

Affiliation:

1. Center for Mathematics and Artificial Intelligence (CMAI), College of Science, George Mason University, Fairfax, VA 22030-4444, USA

2. Center for Computational Fluid Dynamics, College of Science, George Mason University, Fairfax, VA 22030-4444, USA

3. Applied Simulations, Inc., 1211 Pine Hill Road, McLean, VA 22101, USA

4. Department of Mathematics, Emory University, Atlanta, GA 30322, USA

Abstract

<p style='text-indent:20px;'>For any given neural network architecture a permutation of weights and biases results in the same functional network. This implies that optimization algorithms used to 'train' or 'learn' the network are faced with a very large number (in the millions even for small networks) of equivalent optimal solutions in the parameter space. To the best of our knowledge, this observation is absent in the literature. In order to narrow down the parameter search space, a novel technique is introduced in order to fix the bias vector configurations to be monotonically increasing. This is achieved by augmenting a typical learning problem with inequality constraints on the bias vectors in each layer. A Moreau-Yosida regularization based algorithm is proposed to handle these inequality constraints and a theoretical convergence of this algorithm is established. Applications of the proposed approach to standard trigonometric functions and more challenging stiff ordinary differential equations arising in chemically reacting flows clearly illustrate the benefits of the proposed approach. Further application of the approach on the MNIST dataset within TensorFlow, illustrate that the presented approach can be incorporated in any of the existing machine learning libraries.</p>

Publisher

American Institute of Mathematical Sciences (AIMS)

Subject

Applied Mathematics,Control and Optimization,Algebra and Number Theory,Applied Mathematics,Control and Optimization,Algebra and Number Theory

Reference18 articles.

1. Harbir Antil, Thomas S. Brown, Deepanshu Verma and Mahamadi Warma, Optimal control of fractional PDEs with state and control constraints, To appear in Pure and Applied Functional Analysis, 2021.

2. Harbir Antil, Howard C Elman, Akwum Onwunta and Deepanshu Verma, Novel deep neural networks for solving bayesian statistical inverse, arXiv: 2102.03974, 2021.

3. Harbir Antil, Ratna Khatri, Rainald L Lohner and Deepanshu Verma, Fractional deep neural network via constrained optimization, Machine Learning: Science and Technology, 2020.

4. Martin Benning, Elena Celledoni, Matthias J. Ehrhardt, Brynjulf Owren, Carola-Bibiane Schönlieb.Deep learning as optimal control problems: models and numerical methods, J. Comput. Dyn., 6 (2019), 171-198.

5. Thomas S Brown, Harbir Antil, Rainald Löhner, Fumiya Togashi and Deepanshu Verma, Novel dnns for stiff odes with applications to chemically reacting flows, In High Performance Computing (eds. H. Jagode, H. Anzt, H. Ltaief, P. Luszczek), ISC High Performance 2021, Lecture Notes in Computer Science, 12761, 2021.

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