6533b829fe1ef96bd128ad7d

RESEARCH PRODUCT

All Classical Adversary Methods Are Equivalent for Total Functions

Jevgēnijs VihrovsAndris AmbainisMartins KokainisKrišjānis PrūsisAleksejs Zajakins

subject

FOS: Computer and information sciencesKolmogorov complexity010102 general mathematicsBlock (permutation group theory)0102 computer and information sciencesFunction (mathematics)Computational Complexity (cs.CC)Adversary01 natural sciencesUpper and lower boundsTheoretical Computer ScienceCombinatoricsComputer Science - Computational ComplexityComputational Theory and Mathematics010201 computation theory & mathematicsPartial functionSensitivity (control systems)0101 mathematicsEquivalence (measure theory)Mathematics

description

We show that all known classical adversary lower bounds on randomized query complexity are equivalent for total functions and are equal to the fractional block sensitivity fbs( f ). That includes the Kolmogorov complexity bound of Laplante and Magniez and the earlier relational adversary bound of Aaronson. This equivalence also implies that for total functions, the relational adversary is equivalent to a simpler lower bound, which we call rank-1 relational adversary. For partial functions, we show unbounded separations between fbs( f ) and other adversary bounds, as well as between the adversary bounds themselves. We also show that, for partial functions, fractional block sensitivity cannot give lower bounds larger than √ n ⋅ bs( f ), where n is the number of variables and bs( f ) is the block sensitivity. Then, we exhibit a partial function f that matches this upper bound, fbs( f ) = Ω (√ n ⋅ bs( f )).

yearjournalcountryeditionlanguage
2017-09-26ACM Transactions on Computation Theory
https://doi.org/10.1145/3442357