Abstract
In a nonlinear oscillatory system, spectral submanifolds (SSMs) are the smoothest invariant manifolds tangent to linear modal subspaces of an equilibrium. Amplitude–frequency plots of the dynamics on SSMs provide the classic backbone curves sought in experimental nonlinear model identification. We develop here, a methodology to compute analytically both the shape of SSMs and their corresponding backbone curves from a data-assimilating model fitted to experimental vibration signals. This model identification utilizes Taken’s delay-embedding theorem, as well as a least square fit to the Taylor expansion of the sampling map associated with that embedding. The SSMs are then constructed for the sampling map using the parametrization method for invariant manifolds, which assumes that the manifold is an embedding of, rather than a graph over, a spectral subspace. Using examples of both synthetic and real experimental data, we demonstrate that this approach reproduces backbone curves with high accuracy.
Highlights
Modal decomposition into normal modes is a powerful tool in linear system identification [1], but remains2017 The Authors
Amplitude–frequency plots of the dynamics on spectral submanifolds (SSMs) provide the classic backbone curves sought in experimental nonlinear model identification
We briefly summarize the steps in the approach, we have developed in the preceding sections: 1. Fix a generic scalar observable φ(q, q ) and a sampling time T > 0 for the mechanical system (2.1)
Summary
Modal decomposition into normal modes is a powerful tool in linear system identification [1], but remains. We adopt the above distinction between NNMs and SSMs and restrict our attention to SSMs of trivial NNMs (i.e. zero-amplitude periodic orbits) Even in this simplest setting, it is not immediate that a single smoothest invariant manifold tangent to a modal subspace of the fixed point exists. A third approach to backbone-curve construction uses time-dependent normal forms to construct approximate reduced-order nonlinear models of the system near each natural frequency. Several methods for numerical or experimental backbone-curve construction are available, but all make assumptions limiting their range of applicability These assumptions include small, position-independent and linear viscous damping; small enough oscillation amplitudes; an accurate initial knowledge of the SSM; and yet unproven results on the smooth persistence of Lyapunov subcentre manifolds as SSMs under non-zero damping. Our second example is a clamped–clamped beam experiment [21], in which we determine the first three SSMs simultaneously from measurements of decaying vibration signals
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