Calculation of the modal parameters of a suspension bridge

Version 3.3 (161 KB) by E. Cheynet

The eigenfrequencies and modes shapes of a suspension bridge are calculated using a continuum model

https://windengineeringuis.github.io

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Updated 8 May 2020

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eigenBridge

Summary

The calculation of the eigenfrequencies and mode shapes of a suspension bridge using the present Matlab code is based on the theory of continuous beam and the theory of shallow cables. The mode shapes are obtained using Galerkin's method where a series expansion is used. The method was first applied by Sigbjörnsson & Hjorth-Hansen [1]. E. Strømmen [2] expanded their works to the vertical and torsional motion.

The bridge is represented as a horizontal streamlined beam, where the z-axis is the vertical axis, the y-axis is the along-beam axis and the x-axis is the cross-beam axis. The three motions of interests (lateral, vertical, and torsional) and both symmetric and asymmetric modes are computed.

Content:

eigenBridge is a function that computes the mode shapes and eigenfrequencies of the suspension bridge
Documentation.mlx: is an example of the application of this function

References:

[1] Sigbjönsson, R., Hjorth-Hansen, E.: Along wind response of suspension bridges with special reference to stiffening by horizontal cables. Engineering Structures 3, 27-37 (1981) [2] Structural Dynamics, Einar N Strømmen, Springer International Publishing, 2013. ISBN: 3319018019, 9783319018010 Characteristics of the single-span suspension bridge

Cite As

Cheynet, E. Calculation of the Modal Parameters of a Suspension Bridge. Zenodo, 2020, doi:10.5281/ZENODO.3817982.

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MATLAB Release Compatibility

Created with R2019b

Compatible with any release

Platform Compatibility

Windows macOS Linux

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Acknowledgements

Inspired: Automated vehicle identification using bridge vibrations, Static analysis - Suspension bridge - A benchmark solution, Mode shapes extraction by time domain decomposition (TDD), Flutter velocity of a suspension bridge, Dynamic response of a line-like structure to a random load, Buffeting response of a suspension bridge (frequency domain)

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eigenBridge

Documentation.mlx

Version	Published	Release Notes
3.3	8 May 2020	See release notes for this release on GitHub: https://github.com/ECheynet/eigenBridge/releases/tag/v3.3	Download
3.2.0.0	12 Dec 2022	See release notes for this release on GitHub: https://github.com/ECheynet/eigenBridge/releases/tag/v3.2	Download
3.1	3 Mar 2019	Added the project website	Download
3.0.0.0	31 Dec 2016	Title The lateral mode shapes of the deck include now properly the influence of the cable motion Title typo	Download
2.0.0.0	13 Dec 2015	-Example file provided + many simplifications	Download
1.2.0.0	2 Jul 2015	- possibility to use a different young modulus for main cables	Download
1.1.0.0	1 Jul 2015	- separation into more modules for sake of clarity (new matlab file "ExampleBridge.m" included) - For those interested only in one degree of freedom, the inputs have been sorted on a more visible way.	Download
1.0.0.0	1 Jul 2015	-- - typo and description --	Download

To view or report issues in this GitHub add-on, visit the GitHub Repository.

MLA	Cheynet, E. Calculation of the Modal Parameters of a Suspension Bridge. Zenodo, 2020, doi:10.5281/ZENODO.3817982.
APA	Cheynet, E. (2020). Calculation of the modal parameters of a suspension bridge. Zenodo. Retrieved from https://zenodo.org/record/3817982
BibTeX	@misc{https://doi.org/10.5281/zenodo.3817982, doi = {10.5281/ZENODO.3817982}, url = {https://zenodo.org/record/3817982}, author = {Cheynet, E.}, title = {Calculation of the modal parameters of a suspension bridge}, publisher = {Zenodo}, year = {2020}, copyright = {Open Access} }