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Smaller Circuits for Arbitrary n-qubit Diagonal Computations

Quantum Physics 2007-05-23 v4

Abstract

A unitary operator U=\sum u_{j,k} |k><j| is called diagonal when u_{j,k}=0 unless j=k. The definition extends to quantum computations, where j and k vary over the 2^n binary expressions for integers 0,1 ..., 2^n-1, given n qubits. Such operators do not affect outcomes of the projective measurement {<j| ; 0 <= j <= 2^n-1} but rather create arbitrary relative phases among the computational basis states {|j> ; 0 <= j <= 2^n-1}. These relative phases are often required in applications. Constructing quantum circuits for diagonal computations using standard techniques requires either O(n^2 2^n) controlled-not gates and one-qubit Bloch sphere rotations or else O (n 2^n) such gates and a work qubit. This work provides a recursive, constructive procedure which inputs the matrix coefficients of U and outputs such a diagram containing 2^{n+1}-3 alternating controlled-not gates and one-qubit z-axis Bloch sphere rotations. Up to a factor of two, these circuits are the smallest possible. Moreover, should the computation U be a tensor of diagonal one-qubit computations of the form R_z(\alpha)=e^{-i \alpha/2}|0><0|+ e^{i \alpha/2} |1><1|, then a cancellation of controlled-not gates reduces our circuit to that of an n-qubit tensor.

Keywords

Cite

@article{arxiv.quant-ph/0303039,
  title  = {Smaller Circuits for Arbitrary n-qubit Diagonal Computations},
  author = {Stephen S. Bullock and Igor L. Markov},
  journal= {arXiv preprint arXiv:quant-ph/0303039},
  year   = {2007}
}

Comments

v3 improves the results in v1 and achieves asymptotically optimal gate counts v4 makes dimension counting argument rigorous