Mitchell Daneker scite author profile

Mitchell Daneker

3Publications

8Citation Statements Received

85Citation Statements Given

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Affiliations

University of Pennsylvania

Publications

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Systems Biology: Identifiability analysis and parameter identification via systems-biology informed neural networks

Daneker¹,

Zhang²,

Karniadakis³

et al. 2022

Preprint

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The dynamics of systems biological processes are usually modeled by a system of ordinary differential equations (ODEs) with many unknown parameters that need to be inferred from noisy and sparse measurements. Here, we introduce systems-biology informed neural networks for parameter estimation by incorporating the system of ODEs into the neural networks. To complete the workflow of system identification, we also describe structural and practical identifiability analysis to analyze the identifiability of parameters. We use the ultridian endocrine model for glucose-insulin interaction as the example to demonstrate all these methods and their implementation.

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Systems Biology: Identifiability Analysis and Parameter Identification via Systems-Biology-Informed Neural Networks

Daneker

Zhang

Karniadakis

et al. 2023

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Effective data sampling strategies and boundary condition constraints of physics-informed neural networks for identifying material properties in solid mechanics

Daneker

Jolley

et al. 2023

Appl. Math. Mech.-Engl. Ed.

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Material identification is critical for understanding the relationship between mechanical properties and the associated mechanical functions. However, material identification is a challenging task, especially when the characteristic of the material is highly nonlinear in nature, as is common in biological tissue. In this work, we identify unknown material properties in continuum solid mechanics via physics-informed neural networks (PINNs). To improve the accuracy and efficiency of PINNs, we develop efficient strategies to nonuniformly sample observational data. We also investigate different approaches to enforce Dirichlet-type boundary conditions (BCs) as soft or hard constraints. Finally, we apply the proposed methods to a diverse set of time-dependent and time-independent solid mechanic examples that span linear elastic and hyperelastic material space. The estimated material parameters achieve relative errors of less than 1%. As such, this work is relevant to diverse applications, including optimizing structural integrity and developing novel materials.

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