Mean Values at Hopf Points and Oscillation-Induced Gain Modulation

Abstract

We present a result concerning the mean value of orbits emerging from Hopf bifurcations. We then apply this result to identify a new phenomenon termed oscillation-induced gain modulation. A Hopf bifurcation of a system x = f(x; α) with parameter α is characterized by the emergence of a limit cycle with an amplitude increasing from zero, coinciding with a stability change of an equilibrium x0(α) when α passes a critical value α*. This bifurcation is associated with the real part of a single eigenpair λ = μ(α) i ω(α) of the linearized system crossing zero: μ(α*) = 0, μ'(α*) ≠ 0. We establish a result concerning the temporal mean of the oscillation cycle over the period T of oscillation: x α = 1T ∫0T x(t; α) dt . We set the mean to be x α = x0(α) when the equilibrium has no surrounding limit cycle. However, when a limit cycle exists, we show that that the deviation of the mean from the equilibrium is expressible as x α - x0(α) = K μ(α) + O(μ(α)2). That is, the mean value deviates from the equilibrium's location in proportion to μ(α), with a mean deviation determined by the vector quantity K(α) μ(α) that depends on the tensors of f up to third-order. If we consider α to be an input to the model, and the mean x α as the output, then the mean deviation K μ(α) introduces a discontinuity to the cycle mean gain d x αdα at the bifurcation, which we term oscillation-induced gain modulation (OIGM). We the cycle mean deviation result for general Hopf points in two-dimensional and n-dimensional systems, as well as showcase several examples of OIGM.

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