Spectral Normalization and Voigt-Reuss net: A universal approach to microstructure-property forecasting with physical guarantees
- URL: http://arxiv.org/abs/2504.00712v1
- Date: Tue, 01 Apr 2025 12:21:57 GMT
- Title: Spectral Normalization and Voigt-Reuss net: A universal approach to microstructure-property forecasting with physical guarantees
- Authors: Sanath Keshav, Julius Herb, Felix Fritzen,
- Abstract summary: A crucial step in the design process is the rapid evaluation of effective mechanical, thermal, or, in general, elasticity properties.<n>The classical simulation-based approach, which uses, e.g., finite elements and FFT-based solvers, can require substantial computational resources.<n>We propose a novel spectral normalization scheme that a priori enforces these bounds.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Heterogeneous materials are crucial to producing lightweight components, functional components, and structures composed of them. A crucial step in the design process is the rapid evaluation of their effective mechanical, thermal, or, in general, constitutive properties. The established procedure is to use forward models that accept microstructure geometry and local constitutive properties as inputs. The classical simulation-based approach, which uses, e.g., finite elements and FFT-based solvers, can require substantial computational resources. At the same time, simulation-based models struggle to provide gradients with respect to the microstructure and the constitutive parameters. Such gradients are, however, of paramount importance for microstructure design and for inverting the microstructure-property mapping. Machine learning surrogates can excel in these situations. However, they can lead to unphysical predictions that violate essential bounds on the constitutive response, such as the upper (Voigt-like) or the lower (Reuss-like) bound in linear elasticity. Therefore, we propose a novel spectral normalization scheme that a priori enforces these bounds. The approach is fully agnostic with respect to the chosen microstructural features and the utilized surrogate model. All of these will automatically and strictly predict outputs that obey the upper and lower bounds by construction. The technique can be used for any constitutive tensor that is symmetric and where upper and lower bounds (in the L\"owner sense) exist, i.e., for permeability, thermal conductivity, linear elasticity, and many more. We demonstrate the use of spectral normalization in the Voigt-Reuss net using a simple neural network. Numerical examples on truly extensive datasets illustrate the improved accuracy, robustness, and independence of the type of input features in comparison to much-used neural networks.
Related papers
- Statistical learning of structure-property relationships for transport in porous media, using hybrid AI modeling [0.0]
The 3D microstructure of porous media significantly impacts the resulting macroscopic properties, including effective diffusivity or permeability.<n> quantitative structure-property relationships are crucial for further optimizing the performance of porous media.<n>The present paper uses 90,000 virtually generated 3D microstructures of porous media derived from literature.<n>The paper extends these findings by applying a hybrid AI framework to this data set.
arXiv Detail & Related papers (2025-03-27T14:46:40Z) - Similarity Equivariant Graph Neural Networks for Homogenization of Metamaterials [3.6443770850509423]
Soft, porous mechanical metamaterials exhibit pattern transformations that may have important applications in soft robotics, sound reduction and biomedicine.<n>We develop a machine learning-based approach that scales favorably to serve as a surrogate model.<n>We show that this network is more accurate and data-efficient than graph neural networks with fewer symmetries.
arXiv Detail & Related papers (2024-04-26T12:30:32Z) - Molecule Design by Latent Prompt Transformer [76.2112075557233]
This work explores the challenging problem of molecule design by framing it as a conditional generative modeling task.
We propose a novel generative model comprising three components: (1) a latent vector with a learnable prior distribution; (2) a molecule generation model based on a causal Transformer, which uses the latent vector as a prompt; and (3) a property prediction model that predicts a molecule's target properties and/or constraint values using the latent prompt.
arXiv Detail & Related papers (2024-02-27T03:33:23Z) - Symmetry-enforcing neural networks with applications to constitutive modeling [0.0]
We show how to combine state-of-the-art micromechanical modeling and advanced machine learning techniques to homogenize complex microstructures exhibiting non-linear and history dependent behaviors.
The resulting homogenized model, termed smart law (SCL), enables the adoption of microly informed laws into finite element solvers at a fraction of the computational cost required by traditional concurrent multiscale approaches.
In this work, the capabilities of SCLs are expanded via the introduction of a novel methodology that enforces material symmetries at the neuron level.
arXiv Detail & Related papers (2023-12-21T01:12:44Z) - Robust Model-Based Optimization for Challenging Fitness Landscapes [96.63655543085258]
Protein design involves optimization on a fitness landscape.
Leading methods are challenged by sparsity of high-fitness samples in the training set.
We show that this problem of "separation" in the design space is a significant bottleneck in existing model-based optimization tools.
We propose a new approach that uses a novel VAE as its search model to overcome the problem.
arXiv Detail & Related papers (2023-05-23T03:47:32Z) - A Neural Network Transformer Model for Composite Microstructure Homogenization [1.2277343096128712]
Homogenization methods, such as the Mori-Tanaka method, offer rapid homogenization for a wide range of constituent properties.
This paper illustrates a transformer neural network architecture that captures the knowledge of various microstructures.
The network predicts the history-dependent, non-linear, and homogenized stress-strain response.
arXiv Detail & Related papers (2023-04-16T19:57:52Z) - Three-dimensional microstructure generation using generative adversarial
neural networks in the context of continuum micromechanics [77.34726150561087]
This work proposes a generative adversarial network tailored towards three-dimensional microstructure generation.
The lightweight algorithm is able to learn the underlying properties of the material from a single microCT-scan without the need of explicit descriptors.
arXiv Detail & Related papers (2022-05-31T13:26:51Z) - Privacy-preserving machine learning with tensor networks [37.01494003138908]
We show that tensor network architectures have especially prospective properties for privacy-preserving machine learning.
First, we describe a new privacy vulnerability that is present in feedforward neural networks, illustrating it in synthetic and real-world datasets.
We rigorously prove that such conditions are satisfied by tensor-network architectures.
arXiv Detail & Related papers (2022-02-24T19:04:35Z) - A deep learning driven pseudospectral PCE based FFT homogenization
algorithm for complex microstructures [68.8204255655161]
It is shown that the proposed method is able to predict central moments of interest while being magnitudes faster to evaluate than traditional approaches.
It is shown, that the proposed method is able to predict central moments of interest while being magnitudes faster to evaluate than traditional approaches.
arXiv Detail & Related papers (2021-10-26T07:02:14Z) - Efficient Micro-Structured Weight Unification and Pruning for Neural
Network Compression [56.83861738731913]
Deep Neural Network (DNN) models are essential for practical applications, especially for resource limited devices.
Previous unstructured or structured weight pruning methods can hardly truly accelerate inference.
We propose a generalized weight unification framework at a hardware compatible micro-structured level to achieve high amount of compression and acceleration.
arXiv Detail & Related papers (2021-06-15T17:22:59Z) - EBM-Fold: Fully-Differentiable Protein Folding Powered by Energy-based
Models [53.17320541056843]
We propose a fully-differentiable approach for protein structure optimization, guided by a data-driven generative network.
Our EBM-Fold approach can efficiently produce high-quality decoys, compared against traditional Rosetta-based structure optimization routines.
arXiv Detail & Related papers (2021-05-11T03:40:29Z) - Goal-directed Generation of Discrete Structures with Conditional
Generative Models [85.51463588099556]
We introduce a novel approach to directly optimize a reinforcement learning objective, maximizing an expected reward.
We test our methodology on two tasks: generating molecules with user-defined properties and identifying short python expressions which evaluate to a given target value.
arXiv Detail & Related papers (2020-10-05T20:03:13Z) - Learning Composable Energy Surrogates for PDE Order Reduction [28.93892833892805]
We use parametric modular structure to learn component-level surrogates, enabling cheaper high-fidelity simulation.
We use a neural network to model the stored potential energy in a component given boundary conditions.
Composable energy surrogates permit simulation in the reduced basis of component boundaries.
arXiv Detail & Related papers (2020-05-13T19:41:24Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.