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Asymmetry in Spectral Graph Theory: Harmonic Analysis on Directed Networks via Biorthogonal Bases (Random-Walk Laplacian Formulation)

Chandrasekhar Gokavarapu

Abstract

The operator-theoretic dichotomy underlying diffusion on directed networks is \emph{symmetry versus non-self-adjointness} of the Markov transition operator. In the reversible (detailed-balance) regime, a directed random walk $P$ is self-adjoint in a stationary $π$-weighted inner product and admits orthogonal spectral coordinates; outside reversibility, $P$ is genuinely non-self-adjoint (often non-normal), and stability is governed by biorthogonal geometry and eigenvector conditioning. In this paper we develop a harmonic-analysis framework for directed graphs anchored on the random-walk transition matrix $P=D_{\mathrm{out}}^{-1}A$ and the random-walk Laplacian $L_{\mathrm{rw}}=I-P$. Using biorthogonal left/right eigenvectors we define a \emph{Biorthogonal Graph Fourier Transform} (BGFT) adapted to directed diffusion, propose a diffusion-consistent frequency ordering based on decay rates $\Re(1-λ)$, and derive operator-norm stability bounds for iterated diffusion and for BGFT spectral filters. We prove sampling and reconstruction theorems for $P$-bandlimited (equivalently $L_{\mathrm{rw}}$-bandlimited) signals and quantify noise amplification through the conditioning of the biorthogonal eigenbasis. A simulation protocol on directed cycles and perturbed non-normal digraphs demonstrates that asymmetry alone does not dictate instability; rather, non-normality and eigenvector ill-conditioning drive reconstruction sensitivity, making BGFT a natural analytical language for directed diffusion processes.

Asymmetry in Spectral Graph Theory: Harmonic Analysis on Directed Networks via Biorthogonal Bases (Random-Walk Laplacian Formulation)

Abstract

The operator-theoretic dichotomy underlying diffusion on directed networks is \emph{symmetry versus non-self-adjointness} of the Markov transition operator. In the reversible (detailed-balance) regime, a directed random walk is self-adjoint in a stationary -weighted inner product and admits orthogonal spectral coordinates; outside reversibility, is genuinely non-self-adjoint (often non-normal), and stability is governed by biorthogonal geometry and eigenvector conditioning. In this paper we develop a harmonic-analysis framework for directed graphs anchored on the random-walk transition matrix and the random-walk Laplacian . Using biorthogonal left/right eigenvectors we define a \emph{Biorthogonal Graph Fourier Transform} (BGFT) adapted to directed diffusion, propose a diffusion-consistent frequency ordering based on decay rates , and derive operator-norm stability bounds for iterated diffusion and for BGFT spectral filters. We prove sampling and reconstruction theorems for -bandlimited (equivalently -bandlimited) signals and quantify noise amplification through the conditioning of the biorthogonal eigenbasis. A simulation protocol on directed cycles and perturbed non-normal digraphs demonstrates that asymmetry alone does not dictate instability; rather, non-normality and eigenvector ill-conditioning drive reconstruction sensitivity, making BGFT a natural analytical language for directed diffusion processes.
Paper Structure (26 sections, 12 theorems, 26 equations, 1 table, 2 algorithms)

This paper contains 26 sections, 12 theorems, 26 equations, 1 table, 2 algorithms.

Key Result

Proposition 2.3

(i) $P\mathbf{1}=\mathbf{1}$ and $L_{\mathrm{rw}}\mathbf{1}=0$. (ii) If $P$ is irreducible and aperiodic, then the diffusion $x_{t+1}=Px_t$ converges to the stationary component (Markov mixing perspective).

Theorems & Definitions (35)

  • Definition 2.1: Random-walk transition matrix
  • Definition 2.2: Random-walk Laplacian
  • Proposition 2.3: Basic properties
  • proof
  • Definition 2.4: Asymmetry index
  • Definition 2.5: Departure from normality
  • Definition 3.1: Reversibility / detailed balance
  • Theorem 3.2: Weighted symmetry equivalences
  • proof
  • Remark 3.3: Symmetry/asymmetry interpretation for this paper
  • ...and 25 more