English

Frames and Factorization of Graph Laplacians

Functional Analysis 2014-04-08 v1

Abstract

Using functions from electrical networks (graphs with resistors assigned to edges), we prove existence (with explicit formulas) of a canonical Parseval frame in the energy Hilbert space HE\mathscr{H}_{E} of a prescribed infinite (or finite) network. Outside degenerate cases, our Parseval frame is not an orthonormal basis. We apply our frame to prove a number of explicit results: With our Parseval frame and related closable operators in HE\mathscr{H}_{E} we characterize the Friedrichs extension of the HE\mathscr{H}_{E}-graph Laplacian. We consider infinite connected network-graphs G=(V,E)G=\left(V,E\right), VV for vertices, and \emph{E} for edges. To every conductance function cc on the edges EE of GG, there is an associated pair (HE,Δ)\left(\mathscr{H}_{E},\Delta\right) where HE\mathscr{H}_{E} in an energy Hilbert space, and Δ(=Δc)\Delta\left(=\Delta_{c}\right) is the cc-Graph Laplacian; both depending on the choice of conductance function cc. When a conductance function is given, there is a current-induced orientation on the set of edges and an associated natural Parseval frame in HE\mathscr{H}_{E} consisting of dipoles. Now Δ\Delta is a well-defined semibounded Hermitian operator in both of the Hilbert l2(V)l^{2}\left(V\right) and HE\mathscr{H}_{E}. It is known to automatically be essentially selfadjoint as an l2(V)l^{2}\left(V\right)-operator, but generally not as an HE\mathscr{H}_{E} operator. Hence as an HE\mathscr{H}_{E} operator it has a Friedrichs extension. In this paper we offer two results for the Friedrichs extension: a characterization and a factorization. The latter is via l2(V)l^{2}\left(V\right).

Keywords

Cite

@article{arxiv.1404.1424,
  title  = {Frames and Factorization of Graph Laplacians},
  author = {Palle Jorgensen and Feng Tian},
  journal= {arXiv preprint arXiv:1404.1424},
  year   = {2014}
}

Comments

39 pages, 12 figures

R2 v1 2026-06-22T03:43:37.987Z