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Autori principali: Zheng, Beichen, Chen, Ying, Wen, Lili, Wu, Xiaofei
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.04062
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author Zheng, Beichen
Chen, Ying
Wen, Lili
Wu, Xiaofei
author_facet Zheng, Beichen
Chen, Ying
Wen, Lili
Wu, Xiaofei
contents This paper presents an enhanced version of the subgroup method for resonance self-shielding treatment, termed the robust subgroup method, which integrates Robust Estimation (RE) with a Differential Evolution (DE) algorithm. The RE approach is employed to handle model misspecification and data contamination, while the DE algorithm serves as an optimization tool within the RE framework to obtain constrained solutions. Numerical validation against experimental benchmarks shows that the proposed method removes a systematic absorption bias in conventional subgroup fits that would otherwise depress reactivity. This bias appears only in benchmarks sensitive to U-238. Mechanistically, it reflects a threshold-like conditioning failure: strong self-shielding leverage dominates the loss and is magnified by dilution-induced multicollinearity. This adverse conditioning appears to be seeded by a narrow, sparse resonance structure at low energies in fertile even-even nuclides, thereby causing rapid self-shielding response saturation and a weak Doppler broadening. By bounding influence and enforcing feasibility within an RE-DE framework, the inferred subgroup parameters track the underlying physics more faithfully, improving the predictive fidelity of subsequent transport simulations.
format Preprint
id arxiv_https___arxiv_org_abs_2511_04062
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Robust Subgroup Method Using DE Algorithm for Resonance Self-Shielding Calculation
Zheng, Beichen
Chen, Ying
Wen, Lili
Wu, Xiaofei
Computational Physics
This paper presents an enhanced version of the subgroup method for resonance self-shielding treatment, termed the robust subgroup method, which integrates Robust Estimation (RE) with a Differential Evolution (DE) algorithm. The RE approach is employed to handle model misspecification and data contamination, while the DE algorithm serves as an optimization tool within the RE framework to obtain constrained solutions. Numerical validation against experimental benchmarks shows that the proposed method removes a systematic absorption bias in conventional subgroup fits that would otherwise depress reactivity. This bias appears only in benchmarks sensitive to U-238. Mechanistically, it reflects a threshold-like conditioning failure: strong self-shielding leverage dominates the loss and is magnified by dilution-induced multicollinearity. This adverse conditioning appears to be seeded by a narrow, sparse resonance structure at low energies in fertile even-even nuclides, thereby causing rapid self-shielding response saturation and a weak Doppler broadening. By bounding influence and enforcing feasibility within an RE-DE framework, the inferred subgroup parameters track the underlying physics more faithfully, improving the predictive fidelity of subsequent transport simulations.
title Robust Subgroup Method Using DE Algorithm for Resonance Self-Shielding Calculation
topic Computational Physics
url https://arxiv.org/abs/2511.04062