A lower bound for bounded round quantum communication complexity of set disjointness
Abstract
We consider the class of functions whose value depends only on the intersection of the input X1,X2, ..., Xt; that is, for each F in this class there is an fF: 2[n] 0,1, such that F(X1,X2, ..., Xt) = fF(X1 X2 ... Xt). We show that the t-party k-round communication complexity of F is Omega(sm(fF)/(k2)), where sm(fF) stands for the `monotone sensitivity of fF' and is defined by sm(fF) maxS⊂eq [n] |i: fF(S i) ≠ fF(S)|. For two-party quantum communication protocols for the set disjointness problem, this implies that the two parties must exchange Omega(n/k2) qubits. For k=1, our lower bound matches the Omega(n) lower bound observed by Buhrman and de Wolf (based on a result of Nayak, and for 2 <= k <= n1/4, improves the lower bound of Omega(sqrtn) shown by Razborov. (For protocols with no restrictions on the number of rounds, we can conclude that the two parties must exchange Omega(n1/3) qubits. This, however, falls short of the optimal Omega(sqrtn) lower bound shown by Razborov.)
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