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Autores principales: Matei, Ion, Zhenirovskyy, Maksym
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2604.12073
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author Matei, Ion
Zhenirovskyy, Maksym
author_facet Matei, Ion
Zhenirovskyy, Maksym
contents We present a method to quantify a system's resilience capacity, i.e., the set of degradation magnitudes for which all functional requirements remain satisfied. These requirements come from human stakeholders (e.g., operators, planners) who define the acceptable performance envelope. By representing the resilience capacity in degradation space, we obtain an application -- agnostic resilience metric (e.g., capacity volume). To approximate the capacity efficiently in high-dimensional spaces, we pair machine-learning classifiers with entropy-based active sampling, reducing costly feasibility tests. The learned model then drives diagnosis (current health estimation) and prognostics (health-state forecasting) that estimates useful life. These two steps can be complemented by a reconfiguration step implemented by human operators to prolong the system's functionality. An illustrative case study, i.e., a manufacturing production line meeting weekly human set part demand, demonstrates the proposed workflow.
format Preprint
id arxiv_https___arxiv_org_abs_2604_12073
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Resilience Quantification and its Support for Operational Resilience
Matei, Ion
Zhenirovskyy, Maksym
Optimization and Control
We present a method to quantify a system's resilience capacity, i.e., the set of degradation magnitudes for which all functional requirements remain satisfied. These requirements come from human stakeholders (e.g., operators, planners) who define the acceptable performance envelope. By representing the resilience capacity in degradation space, we obtain an application -- agnostic resilience metric (e.g., capacity volume). To approximate the capacity efficiently in high-dimensional spaces, we pair machine-learning classifiers with entropy-based active sampling, reducing costly feasibility tests. The learned model then drives diagnosis (current health estimation) and prognostics (health-state forecasting) that estimates useful life. These two steps can be complemented by a reconfiguration step implemented by human operators to prolong the system's functionality. An illustrative case study, i.e., a manufacturing production line meeting weekly human set part demand, demonstrates the proposed workflow.
title Resilience Quantification and its Support for Operational Resilience
topic Optimization and Control
url https://arxiv.org/abs/2604.12073