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Classical-Quantum Separations in Certain Classes of Boolean Functions-- Analysis using the Parity Decision Trees

Quantum Physics 2020-09-07 v3 Computational Complexity

Abstract

In this paper we study the separation between the deterministic (classical) query complexity (DD) and the exact quantum query complexity (QEQ_E) of several Boolean function classes using the parity decision tree method. We first define the Query Friendly (QF) functions on nn variables as the ones with minimum deterministic query complexity (D(f))(D(f)). We observe that for each nn, there exists a non-separable class of QF functions such that D(f)=QE(f)D(f)=Q_E(f). Further, we show that for some values of nn, all the QF functions are non-separable. Then we present QF functions for certain other values of nn where separation can be demonstrated, in particular, QE(f)=D(f)1Q_E(f)=D(f)-1. In a related effort, we also study the Maiorana McFarland (M-M) type Bent functions. We show that while for any M-M Bent function ff on nn variables D(f)=nD(f) = n, separation can be achieved as n2QE(f)3n4\frac{n}{2} \leq Q_E(f) \leq \lceil \frac{3n}{4} \rceil. Our results highlight how different classes of Boolean functions can be analyzed for classical-quantum separation exploiting the parity decision tree method.

Cite

@article{arxiv.2004.12942,
  title  = {Classical-Quantum Separations in Certain Classes of Boolean Functions-- Analysis using the Parity Decision Trees},
  author = {Chandra Sekhar Mukherjee and Subhamoy Maitra},
  journal= {arXiv preprint arXiv:2004.12942},
  year   = {2020}
}

Comments

Fixed Typographical error in Lemma-8

R2 v1 2026-06-23T15:07:43.498Z