Comparing the direct normal form and multiple scales methods through frequency detuning
Comparing the direct normal form and multiple scales methods through frequency detuning
Approximate analytical methods, such as the multiple scales (MS) and direct normal form (DNF) techniques, have been used extensively for investigating nonlinear mechanical structures, due to their ability to offer insight into the system dynamics. A comparison of their accuracy has not previously been undertaken, so is addressed in this paper. This is achieved by computing the backbone curves of two systems: the single-degree-of-freedom Duffing oscillator and a non-symmetric, two-degree-of-freedom oscillator. The DNF method includes an inherent detuning, which can be physically interpreted as a series expansion about the natural frequencies of the underlying linear system and has previously been shown to increase its accuracy. In contrast, there is no such inbuilt detuning for MS, although one may be, and usually is, included. This paper investigates the use of the DNF detuning as the chosen detuning in the MS method as a way of equating the two techniques, demonstrating that the two can be made to give identical results up to order. For the examples considered here, the resulting predictions are more accurate than those provided by the standard MS technique. Wolfram Mathematica scripts implementing these methods have been provided to be used in conjunction with this paper to illustrate their practicality.
2919–2935
Elliott, A.J.
5bfdbe77-b827-4094-b2e4-eb93acb26f89
Cammarano, A.
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Neild, S.A.
e11b68bb-ddff-4cac-a8a7-798cc3cc3891
Hill, T.L.
96922dda-e993-4889-a519-5f89fe6ebca8
Wagg, D.J.
7aa7d661-df7e-4ecc-86b1-823d4adaf05f
Elliott, A.J.
5bfdbe77-b827-4094-b2e4-eb93acb26f89
Cammarano, A.
c0c85f55-3dfc-4b97-9b79-e2554406a12b
Neild, S.A.
e11b68bb-ddff-4cac-a8a7-798cc3cc3891
Hill, T.L.
96922dda-e993-4889-a519-5f89fe6ebca8
Wagg, D.J.
7aa7d661-df7e-4ecc-86b1-823d4adaf05f
Elliott, A.J., Cammarano, A., Neild, S.A., Hill, T.L. and Wagg, D.J.
(2018)
Comparing the direct normal form and multiple scales methods through frequency detuning.
Nonlinear Dynamics, 94, .
(doi:10.1007/s11071-018-4534-1).
Abstract
Approximate analytical methods, such as the multiple scales (MS) and direct normal form (DNF) techniques, have been used extensively for investigating nonlinear mechanical structures, due to their ability to offer insight into the system dynamics. A comparison of their accuracy has not previously been undertaken, so is addressed in this paper. This is achieved by computing the backbone curves of two systems: the single-degree-of-freedom Duffing oscillator and a non-symmetric, two-degree-of-freedom oscillator. The DNF method includes an inherent detuning, which can be physically interpreted as a series expansion about the natural frequencies of the underlying linear system and has previously been shown to increase its accuracy. In contrast, there is no such inbuilt detuning for MS, although one may be, and usually is, included. This paper investigates the use of the DNF detuning as the chosen detuning in the MS method as a way of equating the two techniques, demonstrating that the two can be made to give identical results up to order. For the examples considered here, the resulting predictions are more accurate than those provided by the standard MS technique. Wolfram Mathematica scripts implementing these methods have been provided to be used in conjunction with this paper to illustrate their practicality.
Text
s11071-018-4534-1
- Version of Record
More information
Accepted/In Press date: 22 August 2018
e-pub ahead of print date: 14 September 2018
Identifiers
Local EPrints ID: 490789
URI: http://eprints.soton.ac.uk/id/eprint/490789
ISSN: 0924-090X
PURE UUID: 28a8ee52-123f-4601-ae2d-12bf507bc6cc
Catalogue record
Date deposited: 06 Jun 2024 16:46
Last modified: 07 Jun 2024 02:08
Export record
Altmetrics
Contributors
Author:
A.J. Elliott
Author:
A. Cammarano
Author:
S.A. Neild
Author:
T.L. Hill
Author:
D.J. Wagg
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics