English

Sampling and Interpolation on Some Non-commutative Nilpotent Lie Groups

Representation Theory 2014-05-27 v9

Abstract

Let NN be a non-commutative, simply connected, connected, two-step nilpotent Lie group with Lie algebra n\mathfrak{n} such that n=abz\mathfrak{n=a\oplus b\oplus z}, [a,b]z,\left[ \mathfrak{a},\mathfrak{b}\right] \subseteq \mathfrak{z}, the algebras a,b,z\mathfrak{a},\mathfrak{b,z} are abelian, a=R-span{X1,X2,,Xd},\mathfrak{a}=\mathbb{R}\text{-span}\left\{ X_{1},X_{2},\cdots,X_{d}\right\} , and b=R-span{Y1,Y2,,Yd}.\mathfrak{b}=\mathbb{R}\text{-span}\left\{ Y_{1},Y_{2},\cdots ,Y_{d}\right\} . Also, we assume that \det\left[ \left[ X_{i}% ,Y_{j}\right] \right] _{1\leq i,j\leq d} is a non-vanishing homogeneous polynomial in the unknowns Z1,,Zn2dZ_{1},\cdots,Z_{n-2d} where {Z1,,Zn2d}\left\{ Z_{1},\cdots,Z_{n-2d}\right\} is a basis for the center of the Lie algebra. Using well-known facts from time-frequency analysis, we provide some precise sufficient conditions for the existence of sampling spaces with the interpolation property, with respect to some discrete subset of NN. The result obtained in this work can be seen as a direct application of time-frequency analysis to the theory of nilpotent Lie groups. Several explicit examples are computed. This work is a generalization of recent results obtained for the Heisenberg group by Currey, and Mayeli in \cite{Currey}.

Keywords

Cite

@article{arxiv.1210.3408,
  title  = {Sampling and Interpolation on Some Non-commutative Nilpotent Lie Groups},
  author = {Vignon Oussa},
  journal= {arXiv preprint arXiv:1210.3408},
  year   = {2014}
}

Comments

27 pages

R2 v1 2026-06-21T22:20:22.972Z