2010
NIPS
NeurIPS 2010
Decomposing Isotonic Regression for Efficiently Solving Large Problems
Abstract
A new algorithm for isotonic regression is presented based on recursively partitioning the solution space. We develop efficient methods for each partitioning subproblem through an equivalent representation as a network flow problem, and prove that this sequence of partitions converges to the global solution. These network flow problems can further be decomposed in order to solve very large problems. Success of isotonic regression in prediction and our algorithm's favorable computational properties are demonstrated through simulated examples as large as 2x10^5 variables and 10^7 constraints.
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Interdisciplinary Bridge
— Machine Learning and Mathematics & Optimization
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Keyword Pioneer
— network flow
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Cross-Pollinator
— Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy
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Trend Setter
— Optimization
Authors
Topics
Machine Learning > Core Methods > Regression
Machine Learning > Optimization & Theory > Optimization
Mathematics & Optimization > Optimization > Combinatorial Optimization
Mathematics & Optimization > Optimization > Continuous Optimization
Mathematics & Optimization > Optimization > Discrete Optimization
Mathematics & Optimization > Optimization > Optimization