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The design and optimization of quantum circuits is central to quantum computation. This paper presents new algorithms for compiling arbitrary 2ⁿ x 2ⁿ unitary matrices into efficient circuits of (n-1) -controlled single-qubit and (n-1) -controlled-NOT gates. We first present a general algebraic optimization technique, which we call the Palindrome Transform, that can be used to minimize the number of self-inverting gates in quantum circuits consisting of concatenations of palindromic subcircuits. For a fixed column ordering of two-level decomposition, we then give an numerative algorithm for minimal (n-1) -controlled-NOT circuit construction, which we call the Palindromic Optimization Algorithm. Our work dramatically reduces the number of gates generated by the conventional two-level decomposition method for constructing quantum circuits of (n-1) -controlled single-qubit and (n-1) -controlled-NOT gates.
Aho et al. (Mon,) studied this question.
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