Geometry-Informed Neural Networks

Arturs Berzins; Andreas Radler; Sebastian Sanokowski; Sepp Hochreiter; Johannes Brandstetter

Geometry-Informed Neural Networks

Arturs Berzins, Andreas Radler, Sebastian Sanokowski, Sepp Hochreiter, Johannes Brandstetter

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

We introduce the concept of geometry-informed neural networks (GINNs), which encompass (i) learning under geometric constraints, (ii) neural fields as a suitable representation, and (iii) generating diverse solutions to under-determined systems often encountered in geometric tasks. Notably, the GINN formulation does not require training data, and as such can be considered generative modeling driven purely by constraints. We add an explicit diversity loss to mitigate mode collapse. We consider several constraints, in particular, the connectedness of components which we convert to a differentiable loss through Morse theory. Experimentally, we demonstrate the efficacy of the GINN learning paradigm across a range of two and three-dimensional scenarios with increasing levels of complexity.

Original language	English
Title of host publication	International Conference on Machine Learning (ICML 2024)
Number of pages	21
Publication status	Published - 2024

Publication series

Name	arXiv.org

Fields of science

305907 Medical statistics
202017 Embedded systems
202036 Sensor systems
101004 Biomathematics
101014 Numerical mathematics
101015 Operations research
101016 Optimisation
101017 Game theory
101018 Statistics
101019 Stochastics
101024 Probability theory
101026 Time series analysis
101027 Dynamical systems
101028 Mathematical modelling
101029 Mathematical statistics
101031 Approximation theory
102 Computer Sciences
102001 Artificial intelligence
102003 Image processing
102004 Bioinformatics
102013 Human-computer interaction
102018 Artificial neural networks
102019 Machine learning
102032 Computational intelligence
102033 Data mining
305901 Computer-aided diagnosis and therapy
305905 Medical informatics
202035 Robotics
202037 Signal processing
103029 Statistical physics
106005 Bioinformatics
106007 Biostatistics

JKU Focus areas

Digital Transformation

Cite this

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title = "Geometry-Informed Neural Networks",

abstract = "We introduce the concept of geometry-informed neural networks (GINNs), which encompass (i) learning under geometric constraints, (ii) neural fields as a suitable representation, and (iii) generating diverse solutions to under-determined systems often encountered in geometric tasks. Notably, the GINN formulation does not require training data, and as such can be considered generative modeling driven purely by constraints. We add an explicit diversity loss to mitigate mode collapse. We consider several constraints, in particular, the connectedness of components which we convert to a differentiable loss through Morse theory. Experimentally, we demonstrate the efficacy of the GINN learning paradigm across a range of two and three-dimensional scenarios with increasing levels of complexity.",

author = "Arturs Berzins and Andreas Radler and Sebastian Sanokowski and Sepp Hochreiter and Johannes Brandstetter",

year = "2024",

language = "English",

series = "arXiv.org",

booktitle = "International Conference on Machine Learning (ICML 2024)",

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T1 - Geometry-Informed Neural Networks

AU - Berzins, Arturs

AU - Radler, Andreas

AU - Sanokowski, Sebastian

AU - Hochreiter, Sepp

AU - Brandstetter, Johannes

PY - 2024

Y1 - 2024

N2 - We introduce the concept of geometry-informed neural networks (GINNs), which encompass (i) learning under geometric constraints, (ii) neural fields as a suitable representation, and (iii) generating diverse solutions to under-determined systems often encountered in geometric tasks. Notably, the GINN formulation does not require training data, and as such can be considered generative modeling driven purely by constraints. We add an explicit diversity loss to mitigate mode collapse. We consider several constraints, in particular, the connectedness of components which we convert to a differentiable loss through Morse theory. Experimentally, we demonstrate the efficacy of the GINN learning paradigm across a range of two and three-dimensional scenarios with increasing levels of complexity.

AB - We introduce the concept of geometry-informed neural networks (GINNs), which encompass (i) learning under geometric constraints, (ii) neural fields as a suitable representation, and (iii) generating diverse solutions to under-determined systems often encountered in geometric tasks. Notably, the GINN formulation does not require training data, and as such can be considered generative modeling driven purely by constraints. We add an explicit diversity loss to mitigate mode collapse. We consider several constraints, in particular, the connectedness of components which we convert to a differentiable loss through Morse theory. Experimentally, we demonstrate the efficacy of the GINN learning paradigm across a range of two and three-dimensional scenarios with increasing levels of complexity.

UR - https://openreview.net/forum?id=ow4L0VlHMQ&referrer=%5BAuthor%20Console%5D(%2Fgroup%3Fid%3DICML.cc%2F2024%2FWorkshop%2FGRaM%2FAuthors%23your-submissions)

M3 - Conference proceedings

T3 - arXiv.org

BT - International Conference on Machine Learning (ICML 2024)

ER -

Geometry-Informed Neural Networks

Abstract

Publication series

Fields of science

JKU Focus areas

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Cite this