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STACS
2010
Springer
2010
Springer
Collapsing and Separating Completeness Notions under Average-Case and Worst-Case Hypotheses
This paper presents the following results on sets that are complete for NP. (i) If there is a problem in NP that requires 2nΩ(1) time at almost all lengths, then every many-one NP-complete set is complete under length-increasing reductions that are computed by polynomial-size circuits. (ii) If there is a problem in co-NP that cannot be solved by polynomial-size nondeterministic circuits, then every many-one complete set is complete under length-increasing reductions that are computed by polynomial-size circuits. (iii) If there exist a one-way permutation that is secure against subexponential-size circuits and there is a hard tally language in NP∩co-NP, then there is a Turing complete language for NP that is not many-one complete. Our first two results use worst-case hardness hypotheses whereas earlier work that showed similar results relied on average-case or almost-everywhere hardness assumptions. The use of average-case and worst-case hypotheses in the last result is unique as p...
Real-time TrafficAlmost-everywhere Hardness | Length-increasing Reductions | Polynomial-size Circuits | STACS 2010 | Theoretical Computer Science |
| Added | 28 May 2010 |
| Updated | 28 May 2010 |
| Type | Conference |
| Year | 2010 |
| Where | STACS |
| Authors | Xiaoyang Gu, John M. Hitchcock, Aduri Pavan |
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