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Abstract

In this paper we present a systematic experimental study of two one-degree-of-freedom nonlinear devices using the newly introduced control-based continuation method of Sieber and Krauskopf. By considering hardening, softening and bistable spring characteristics, we demonstrate the versatility and power of the control-based continuation method for investigating nonlinear experiments. We show that, using this method, it is possible to track the stable orbits of the devices through a saddle-node bifurcation (fold) where they lose stability and continue them up to the resonance peak where they undergo a second saddle-node bifurcation. For the bistable case, a bifurcation diagram is produced that is strongly reminiscent of the bifurcation diagram produced using the classical harmonic balance solution. A detailed introduction to general continuation methods is included to enable implementation by other experimentalists.

Keywords

Experimental continuation energy harvesting bifurcation saddle node

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References

Barkley

Kevrekidis

Stuart

(2006) The moment map: nonlinear dynamics of density evolution via a few moments. SIAM Journal on Applied Dynamical Systems 5: 403–434.

Barton

Burrow

(2009) Numerical continuation in a physical experiment: investigation of a nonlinear energy harvester. In: ASME 2009 International Design Engineering Technical Conferences, San Diego, CA.

Barton

Burrow

Clare

(2010) Energy harvesting from vibrations with a nonlinear oscillator. ASME Journal of Vibration and Acoustics 132: 021009–021009.

Breakspear

Roberts

Terry

Rodrigues

Mahant

Robinson

(2006) A unifying explanation of primary generalized seizures through nonlinear brain modeling and bifurcation analysis. Cerebral Cortex 16: 1296–1313.

Doedel

Keller

Kernevez

(1991a) Numerical analysis and control of bifurcation problems, part I. International Journal of Bifurcation and Chaos 1: 493–520.

Doedel

Keller

Kernevez

(1991b) Numerical analysis and control of bifurcation problems, part II. International Journal of Bifurcation and Chaos 1: 745–772.

Eyert

(1996) A comparative study on methods for convergence acceleration of iterative vector sequences. Journal of Computational Physics 124: 271–285.

Krauskopf

(2005) Bifurcation analysis of lasers with delay. Unlocking Dynamical Diversity: Optical Feedback Effects on Semiconductor Lasers. Hoboken, NJ: John Wiley & Sons, Inc., pp.147–183.

Krauskopf

Osinga

Galán-Vioque

(eds) (2007) Numerical Continuation Methods for Dynamical Systems: Path Following and Boundary Value Problems (Lecture Notes on Numerical Analysis of Nonlinear Equations. Vol. ). Dordrecht: Springer-Verlag, pp.1–49.

10.

Misra

Dankowicz

Paul

(2008) Event-driven feedback tracking and control of tapping-mode atomic force microscopy. Proceedings of the Royal Society A 464: 2113–2133.

11.

Moon

Holmes

(1979) A magnetoelastic strange attractor. Journal of Sound and Vibration 65: 275–296.

12.

Nayfeh

(1973) Perturbation methods. New York: Wiley.

13.

Ott

Grebogi

Yorke

(1990) Controlling chaos. Physical Review Letters 64: 1196–1199.

14.

Pyragas

(1992) Continuous control of chaos by self-controlling feedback. Physics Letters A 170: 421–428.

15.

Pyragas

(2001) Control of chaos via an unstable delayed feedback controller. Physical Review Letters 86: 2265–2268.

16.

Seydel

(2010) Practical Bifurcation and Stability Analysis. (Interdisciplinary Applied Mathematics. Vol. 5) 3rd ed. New York: Springer.

17.

Sieber

Gonzalez-Buelga

Neil

Wagg

Krauskopf

(2008) Experimental continuation of periodic orbits through a fold. Physical Review Letters 100: 244101–244101.

18.

Sieber

Krauskopf

(2008) Control based bifurcation analysis for experiments. Nonlinear Dynamics 51: 365–377.

19.

Siettos

Kevrekidis

Maroudas

(2004) Coarse bifurcation diagrams via microscopic simulators: a state-feedback control-based approach. International Journal of Bifurcation and Chaos 14: 207–220.

20.

Stanton

McGehee

Mann

(2010) Nonlinear dynamics for broadband energy harvesting: Investigation of a bistable piezoelectric inertial generator. Physica D 239: 640–653.

21.

Stépán

(2001) Modelling nonlinear regenerative effects in metal cutting. Philosophical Transactions of the Royal Society 359: 739–757.

Control-based continuation for investigating nonlinear experiments

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