Efficient Quantum Fourier Transforms For Semisimple Algebras

Abstract

The quantum Fourier transform (QFT) is a fundamental primitive in quantum computation and quantum information. In this work, we generalize the QFT for finite groups to a QFT for finite-dimensional semisimple algebras, and give efficient quantum Fourier transforms for the partition algebra Pn(d), Brauer algebra Bn(d), and walled Brauer algebra Br,s(d). These algebras play important roles in generalized Schur-Weyl duality, statistical physics and many-body systems, and have recently found several applications in quantum algorithms. Unlike the group case, the Fourier transform over a semisimple algebra can be non-unitary. Nevertheless, we show that when the parameter d is sufficiently large, the Fourier transform is well approximated by a unitary operator. Furthermore, we show that for each of the algebras A from above, such an approximate Fourier transform can be implemented efficiently: we give a quantum algorithm with gate complexity poly(n, d,(1/)) for approximating the Fourier transform to error (d-1/2 + ) · poly(|A|). Along the way, we establish several properties of the Fourier basis of semisimple algebras that may be of independent interest.