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Main Author: Vaiapury, Karthikeyan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.02415
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author Vaiapury, Karthikeyan
author_facet Vaiapury, Karthikeyan
contents Optimization remains a fundamental pillar of machine learning, yet existing methods often struggle to maintain stability and adaptability in dynamic, non linear systems, especially under uncertainty. We introduce AERO (Adversarial Energy-based Redirection Optimization), a novel framework inspired by the redirection principle in Judo, where external disturbances are leveraged rather than resisted. AERO reimagines optimization as a redirection process guided by 15 interrelated axioms encompassing adversarial correction, energy conservation, and disturbance-aware learning. By projecting gradients, integrating uncertainty driven dynamics, and managing learning energy, AERO offers a principled approach to stable and robust model updates. Applied to probabilistic solar energy forecasting, AERO demonstrates substantial gains in predictive accuracy, reliability, and adaptability, especially in noisy and uncertain environments. Our findings highlight AERO as a compelling new direction in the theoretical and practical landscape of optimization.
format Preprint
id arxiv_https___arxiv_org_abs_2506_02415
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle AERO: A Redirection-Based Optimization Framework Inspired by Judo for Robust Probabilistic Forecasting
Vaiapury, Karthikeyan
Machine Learning
Artificial Intelligence
62M10, 60G25, 62P30
I.2.6; I.5.1; G.3; J.2
Optimization remains a fundamental pillar of machine learning, yet existing methods often struggle to maintain stability and adaptability in dynamic, non linear systems, especially under uncertainty. We introduce AERO (Adversarial Energy-based Redirection Optimization), a novel framework inspired by the redirection principle in Judo, where external disturbances are leveraged rather than resisted. AERO reimagines optimization as a redirection process guided by 15 interrelated axioms encompassing adversarial correction, energy conservation, and disturbance-aware learning. By projecting gradients, integrating uncertainty driven dynamics, and managing learning energy, AERO offers a principled approach to stable and robust model updates. Applied to probabilistic solar energy forecasting, AERO demonstrates substantial gains in predictive accuracy, reliability, and adaptability, especially in noisy and uncertain environments. Our findings highlight AERO as a compelling new direction in the theoretical and practical landscape of optimization.
title AERO: A Redirection-Based Optimization Framework Inspired by Judo for Robust Probabilistic Forecasting
topic Machine Learning
Artificial Intelligence
62M10, 60G25, 62P30
I.2.6; I.5.1; G.3; J.2
url https://arxiv.org/abs/2506.02415