Quantum Circuits for the Unitary Permutation Problem

Abstract

We consider the Unitary Permutation problem which consists, given n unitary gates U1, …, Un and a permutation σ of \1,…, n\, in applying the unitary gates in the order specified by σ, i.e. in performing Uσ(n)… Uσ(1). This problem has been introduced and investigated by Colnaghi et al. where two models of computations are considered. This first is the (standard) model of query complexity: the complexity measure is the number of calls to any of the unitary gates Ui in a quantum circuit which solves the problem. The second model provides quantum switches and treats unitary transformations as inputs of second order. In that case the complexity measure is the number of quantum switches. In their paper, Colnaghi et al. have shown that the problem can be solved within n2 calls in the query model and n(n-1)2 quantum switches in the new model. We refine these results by proving that n2(n) +(n) quantum switches are necessary and sufficient to solve this problem, whereas n2-2n+4 calls are sufficient to solve this problem in the standard quantum circuit model. We prove, with an additional assumption on the family of gates used in the circuits, that n2-o(n7/4+ε) queries are required, for any ε >0. The upper and lower bounds for the standard quantum circuit model are established by pointing out connections with the permutation as substring problem introduced by Karp.