A Universal Error Measure for Input Predictions Applied to Online Graph Problems
A Universal Error Measure for Input Predictions Applied to Online Graph Problems
We introduce a novel measure for quantifying the error in input predictions. The error is based on a minimum-cost hyperedge cover in a suitably defined hypergraph and provides a general template which we apply to online graph problems. The measure captures errors due to absent predicted requests as well as unpredicted actual requests; hence, predicted and actual inputs can be of arbitrary size. We achieve refined performance guarantees for previously studied network design problems in the online-list model, such as Steiner tree and facility location. Further, we initiate the study of learning-augmented algorithms for online routing problems, such as the online traveling salesperson problem and the online dial-a-ride problem, where (transportation) requests arrive over time (online-time model). We provide a general algorithmic framework and we give error-dependent performance bounds that improve upon known worst-case barriers, when given accurate predictions, at the cost of slightly increased worst-case bounds when given predictions of arbitrary quality.
To appear in NeurIPS 2022
- Sapienza University of Rome Italy
- University of Trieste Italy
- University of Milan Italy
- Vrije Universiteit Amsterdam Netherlands
Network design problems, FOS: Computer and information sciences, Computer Science - Machine Learning, Routing problem, Online graph problem, Algorithms with prediction, Learning-augmented algorithms; Algorithms with predictions; Error measures; Online graph problems; Routing problems; Network design problems, Algorithms with predictions; Capture error; Error measures; Graph problems; Hyper graph; Hyperedges; Minimum cost; Network design problems; Performance guarantees; Steiner trees; Tree location, Machine Learning (cs.LG), Capture error; Error measures; Graph problems; Hyper graph; Hyperedges; Minimum cost; Network design problems; Performance guarantees; Steiner trees; Tree location, Computer Science - Data Structures and Algorithms, Learning-augmented algorithm, Data Structures and Algorithms (cs.DS), Error measure
Network design problems, FOS: Computer and information sciences, Computer Science - Machine Learning, Routing problem, Online graph problem, Algorithms with prediction, Learning-augmented algorithms; Algorithms with predictions; Error measures; Online graph problems; Routing problems; Network design problems, Algorithms with predictions; Capture error; Error measures; Graph problems; Hyper graph; Hyperedges; Minimum cost; Network design problems; Performance guarantees; Steiner trees; Tree location, Machine Learning (cs.LG), Capture error; Error measures; Graph problems; Hyper graph; Hyperedges; Minimum cost; Network design problems; Performance guarantees; Steiner trees; Tree location, Computer Science - Data Structures and Algorithms, Learning-augmented algorithm, Data Structures and Algorithms (cs.DS), Error measure
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