English

From reversible computation to quantum computation by Lagrange interpolation

Quantum Physics 2015-02-04 v1 Group Theory

Abstract

Classical reversible circuits, acting on ww~bits, are represented by permutation matrices of size 2w×2w2^w \times 2^w. Those matrices form the group P(2w2^w), isomorphic to the symmetric group {\bf S}2w_{2^w}. The permutation group P(nn), isomorphic to {\bf S}n_n, contains cycles with length~pp, ranging from~1 to L(n)L(n), where L(n)L(n) is the so-called Landau function. By Lagrange interpolation between the pp~matrices of the cycle, we step from a finite cyclic group of order~pp to a 1-dimensional Lie group, subgroup of the unitary group U(nn). As U(2w2^w) is the group of all possible quantum circuits, acting on ww~qubits, such interpolation is a natural way to step from classical computation to quantum computation.

Keywords

Cite

@article{arxiv.1502.00819,
  title  = {From reversible computation to quantum computation by Lagrange interpolation},
  author = {Alexis De Vos and Stijn De Baerdemacker},
  journal= {arXiv preprint arXiv:1502.00819},
  year   = {2015}
}
R2 v1 2026-06-22T08:20:23.848Z