Unifying Framework for Amplification Mechanisms: Criticality, Resonance and Non-Normality

Abstract

We bring together three key amplification mechanisms in linear dynamical systems: spectral criticality, resonance, and non-normality. We present a unified linear framework that both distinguishes and quantitatively links these effects through two fundamental parameters: (i) the spectral distance to a conventional bifurcation or to a resonance and (ii) a non-normal index K (or condition number ) that measures the obliqueness of the eigenvectors. Closed-form expressions for the system's response in the form of the variance v∞ of the observable responding to both Gaussian noise and periodic forcing reveal a general amplification law v∞ = v0 ( 1 + G(K) ) with non-normal gain G(K) K2 represented in universal phase diagrams. By reanalyzing a model of remote earthquake triggering based on breaking of Hamiltonian symmetry, we illustrate how our two-parameter framework significantly expands both the range of conditions under which amplification can occur and the magnitude of the resulting response, revealing a broad pseudo-critical regime associated with large that previous single-parameter approaches overlooked. Similarly, in the Non-Hermitian extensions of quantum optics provided by Forward Four-Wave Mixing (FFWM) experiments, we show the presence of a counterintuitive gain-from-loss effect that directly manifests non-normal amplification in a propagating-wave setting. This predicts the possibility to engineer transient optical energy amplification without the need for true lasing or exact PT-symmetry breaking. Our framework applies to many other physical, natural and social systems and offers new diagnostic tools to distinguish true critical behavior from transient amplification driven by non-normality.