A Note on a Quantitative Form of the Solovay-Kitaev Theorem

Abstract

The problem of finding good approximations of arbitrary 1-qubit gates is identical to that of finding a dense group generated by a universal subset of SU(2) to approximate an arbitrary element of SU(2). The Solovay-Kitaev Theorem is a well-known theorem that guarantees the existence of a finite sequence of 1-qubit quantum gates approximating an arbitrary unitary matrix in SU(2) within specified accuracy > 0. In this note we study a quantitative description of this theorem in the following sense. We will work with a universal gate set T, a subset of SU(2) such that the group generated by the elements of T is dense in SU(2). For > 0 small enough, we define t as the minimum reduced word length such that every point of SU(2) lies within a ball of radius centered at the points in the dense subgroup generated by T. For a measure of efficiency on T, which we denote K(T), we prove the following theorem: Fix a δ in [0, 23]. Choose f: (0, ∞) → (1, ∞) satisfying 0+(f(t))t exists with value 0. Assume that the inequality ≤slant f(t)· 5-t6-3δ holds. Then K(T) ≤slant 2-δ. Our conjecture implies the following: Let (5t) denote the set of integer solutions of the quadratic form: x12+x22+x32+x42=5t. Let M MS3(N) denote the covering radius of the points N=(5t)(5t-1) on the sphere S3 in R4. Then M f( N)N-16-3δ. Here N N()=6·5t-2.