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Bibliographic Details
Main Authors: Neefjes, Erik Garcia, Hawkins, Stuart C., Ganesh, Mahadevan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.21512
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author Neefjes, Erik Garcia
Hawkins, Stuart C.
Ganesh, Mahadevan
author_facet Neefjes, Erik Garcia
Hawkins, Stuart C.
Ganesh, Mahadevan
contents This work addresses the reconstruction of a scatterer's shape from phaseless far field-intensity data arising from multiple incident waves interacting with the scatterer. We formulate the reconstruction as a statistical inverse scattering problem and adopt a Bayesian inference framework, which can readily be used to compute statistical moments for quantification of uncertainties in the shape reconstruction that arise from noise in the data due to measurement constraints. The shape of the scatterer is represented by a spline-based prior, with Bayesian parameters defined at the spline's knots. To efficiently evaluate the Bayesian likelihood across thousands of sampling points, we develop the intensity property inspired neural network (IPINN) surrogate. This surrogate incorporates the Helmholtz equation in the unbounded domain, exterior to each sampled scatterer, along with the radiation condition at infinity, enabling fast and accurate simulation of the acoustic far-field intensity. Importantly, the IPINN surrogate is trained independently of the observed data and requires only a single incident wave for training. We demonstrate that this surrogate approach yields a speed-up of several orders of magnitude. The resulting IPINN-Bayesian framework offers an efficient solution for shape reconstruction in unbounded domains with multiple incident wave boundary conditions, while exactly enforcing the radiation condition. Numerical experiments confirm the efficiency and effectiveness of the proposed algorithm.
format Preprint
id arxiv_https___arxiv_org_abs_2603_21512
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A surrogate-Bayesian algorithm for scatterer shape identification from phaseless data
Neefjes, Erik Garcia
Hawkins, Stuart C.
Ganesh, Mahadevan
Numerical Analysis
65N21
This work addresses the reconstruction of a scatterer's shape from phaseless far field-intensity data arising from multiple incident waves interacting with the scatterer. We formulate the reconstruction as a statistical inverse scattering problem and adopt a Bayesian inference framework, which can readily be used to compute statistical moments for quantification of uncertainties in the shape reconstruction that arise from noise in the data due to measurement constraints. The shape of the scatterer is represented by a spline-based prior, with Bayesian parameters defined at the spline's knots. To efficiently evaluate the Bayesian likelihood across thousands of sampling points, we develop the intensity property inspired neural network (IPINN) surrogate. This surrogate incorporates the Helmholtz equation in the unbounded domain, exterior to each sampled scatterer, along with the radiation condition at infinity, enabling fast and accurate simulation of the acoustic far-field intensity. Importantly, the IPINN surrogate is trained independently of the observed data and requires only a single incident wave for training. We demonstrate that this surrogate approach yields a speed-up of several orders of magnitude. The resulting IPINN-Bayesian framework offers an efficient solution for shape reconstruction in unbounded domains with multiple incident wave boundary conditions, while exactly enforcing the radiation condition. Numerical experiments confirm the efficiency and effectiveness of the proposed algorithm.
title A surrogate-Bayesian algorithm for scatterer shape identification from phaseless data
topic Numerical Analysis
65N21
url https://arxiv.org/abs/2603.21512