English

Cyclic permutations for qudits in $d$ dimensions

Quantum Physics 2019-04-22 v2

Abstract

One of the main challenges in quantum technologies is the ability to control individual quantum systems. This task becomes increasingly difficult as the dimension of the system grows. Here we propose a general setup for cyclic permutations XdX_d in dd dimensions, a major primitive for constructing arbitrary qudit gates. Using orbital angular momentum states as a qudit, the simplest implementation of the XdX_d gate in dd dimensions requires a single quantum sorter SdS_d and two spiral phase plates. We then extend this construction to a generalised Xd(p)X_d(p) gate to perform a cyclic permutation of a set of dd, equally spaced values {0,0+p,,0+(d1)p}{0+p,0+2p,,0}\{ \ket{\ell_0}, \ket{\ell_0+p},\ldots, \ket{\ell_0+(d-1)p} \} \mapsto \{ \ket{\ell_0+p}, \ket {\ell_0+2p},\ldots, \ket{\ell_0} \}. We find compact implementations for the generalised Xd(p)X_d(p) gate in both Michelson (one sorter SdS_d, two spiral phase plates) and Mach-Zehnder configurations (two sorters SdS_d, two spiral phase plates). Remarkably, the number of spiral phase plates is independent of the qudit dimension dd. Our architecture for XdX_d and generalised Xd(p)X_d(p) gate will enable complex quantum algorithms for qudits, for example quantum protocols using photonic OAM states.

Cite

@article{arxiv.1811.09059,
  title  = {Cyclic permutations for qudits in $d$ dimensions},
  author = {Tudor-Alexandru Isdraila and Cristian Kusko and Radu Ionicioiu},
  journal= {arXiv preprint arXiv:1811.09059},
  year   = {2019}
}
R2 v1 2026-06-23T05:24:17.456Z