In this paper we consider a complex-order forced van der Pol oscillator. The complex
derivative ,
with α, β ∈ ℝ+, is a generalization of the
concept of an integer derivative, where α = 1, β = 0.
The Fourier transforms of the periodic solutions of the complex-order forced van der Pol
oscillator are computed for various values of parameters such as frequency ω and amplitude
b of the external forcing, the damping μ, and parameters
α and β. Moreover, we consider two cases: (i)
b = 1, μ = {1.0, 5.0, 10.0}, and ω = {0.5, 2.46, 5.0,
20.0}; (ii) ω = 20.0, μ = {1.0, 5.0, 10.0}, and
b = {1.0, 5.0, 10.0}. We verified that most of the signal energy is
concentrated in the fundamental harmonic ω0. We also observed
that the fundamental frequency of the oscillations ω0 varies
with α and μ. For the range of tested values, the numerical fitting led to logarithmic
approximations for system (7) in the two cases (i) and (ii). In
conclusion, we verify that by varying the parameter values α and
β of the complex-order derivative in expression (7), we accomplished
a very effective way of perturbing the dynamical behavior of the forced van der Pol
oscillator, which is no longer limited to parameters b and
ω.
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