Abstract
The partial coloring method is one of the most powerful and widely used method in combinatorial discrepancy problems. However, in many cases it leads to sub-optimal bounds as the partial coloring step must be iterated a logarithmic number of times, and the errors can add up in an adversarial way. We give a new and general algorithmic framework that overcomes the limitations of the partial coloring method and can be applied in a black-box manner to various problems. Using this framework, we give new improved bounds and algorithms for several classic problems in discrepancy. In particular, for Tusnady's problem, we give an improved O(log2 n) bound for discrepancy of axis-parallel rectangles and more generally an Od(logd n) bound for d-dimensional boxes in ℝd. Previously, even non-constructively, the best bounds were O(log2.5 n) and Od(logd+0.5 n) respectively. Similarly, for the Steinitz problem we give the first algorithm that matches the best known non-constructive bounds due to Ba-naszczyk in the l∞ case, and improves the previous algorithmic bounds substantially in the l2 case. Our framework is based upon a substantial generalization of the techniques developed recently in the context of the Komlós discrepancy problem.
Original language | English |
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Title of host publication | STOC 2017 Proceedings of the 49th Annual ACM SIGACT Symposium on Theory of Computing, 19-23 June 2017, Montreal, Canada |
Place of Publication | New York |
Publisher | Association for Computing Machinery, Inc |
Pages | 914-926 |
Number of pages | 13 |
ISBN (Print) | 978-1-4503-4528-6 |
DOIs | |
Publication status | Published - 19 Jun 2017 |
Event | 49th Annual ACM SIGACT Symposium on Theory of Computing (STOC 2017) - Montreal, Canada Duration: 19 Jun 2017 → 23 Jun 2017 Conference number: 49 |
Conference
Conference | 49th Annual ACM SIGACT Symposium on Theory of Computing (STOC 2017) |
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Abbreviated title | STOC 2017 |
Country/Territory | Canada |
City | Montreal |
Period | 19/06/17 → 23/06/17 |
Keywords
- Discrepancy
- Random walks
- Rounding techniques
- Semidefinite programming