Physics:Synchronous lateral excitation

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Short description: Pedestrian-induced oscillation phenomenon in footbridges


When a pedestrian walks in sync with a ground oscillation, the lateral foot forces exacerbate already existing oscillations, leading to a positive feedback loop known as synchronous lateral excitation. Adapted from Figure 5-15 of Butz, C., et al. "Advanced load models for synchronous pedestrian excitation and optimized design guidelines for steel footbridges (SYNPEX)." RFCS-Research Project RFS-CR-03019 (2007).[1]

Synchronous lateral excitation is a dynamic phenomenon where pedestrians walking on a footbridge subconsciously synchronize their lateral footsteps with the bridge’s natural swaying motion, amplifying lateral vibrations.[2][3] First widely recognized during the 2000 opening of the London Millennium Bridge, synchronous lateral excitation has since become a critical consideration in the design of lightweight pedestrian structures.[4][5][6]

Mechanism

As the number of pedestrians on a footbridge increases (black line in steps), the lateral oscillations increase (gray area). After a critical number of pedestrians is reached (166 in this example), the bridge enters a stage of synchronous lateral excitation. Simplified graph based on page 37 of Parker, Matt. Humble Pi: A Comedy of Maths Errors. Penguin UK, 2019.[3]

Synchronous lateral excitation arises from two interrelated synchronization processes. The first is the pedestrian-structure synchronization, where slight lateral bridge movements (e.g., from wind or random pedestrian steps) prompt walkers to adjust their gait to match the bridge’s oscillation frequency, increasing lateral forces.[7] The second is pedestrian-pedestrian synchronization, where individuals unconsciously align their stepping patterns, further reinforcing the resonant force.[8][9]

Key cases

  • The London Millennium Bridge experienced lateral vibrations up to 70 mm due to synchronous lateral excitation, requiring a £5M retrofit with dampers.[2][4]
  • The Auckland Harbour Bridge experienced a lateral frequency of 0.67 Hz during a 1975 demonstration.[10]
  • The Birmingham NEC Link bridge experienced a lateral frequency of 0.7 Hz.
  • The Toda Park Bridge in Japan is an early documented case (1990s) studied by Fujino et al., informing later synchronous lateral excitation models.[7]

Mitigation strategies

Some ways to avoid synchronous lateral excitation are the implementation of tuned mass dampers, which were used in the Millennium Bridge to increase damping from 0.5% to 20% critical.[4] Other strategies involve designing bridges with lateral frequencies outside the 0.5–1.1 Hz range as well as managing crows by limiting pedestrian density during events.[5]

References

  1. "Advanced load models for synchronous pedestrian excitation and optimised design guidelines for steel footbridges". 2007. https://op.europa.eu/en/publication-detail/-/publication/432f1d42-ed71-47db-9087-c5b74b4bb0fe. 
  2. 2.0 2.1 Josephson, Brian (14 June 2000). "Out of step on the bridge". The Guardian. https://www.theguardian.com/theguardian/2000/jun/14/guardianletters3. 
  3. 3.0 3.1 Parker, Matt (2019) (in English). Humble Pi: A Comedy of Maths Errors. Penguin UK. 
  4. 4.0 4.1 4.2 "Stabilising the London Millennium Bridge". 2000-06-10. https://www.ingenia.org.uk/articles/stabilising-the-london-millennium-bridge/. 
  5. 5.0 5.1 Venuti, Fiammetta; Bruno, Luca (2017). "Footbridge lateral vibrations induced by pedestrians". Procedia Engineering 199: 179–184. https://congress.cimne.com/eccomas/proceedings/compdyn2011/compdyn2011_full/179.pdf. Retrieved 2025-04-21. 
  6. Strogatz, Steven et al. (2005). "Theoretical mechanics: Crowd synchrony on the Millennium Bridge", Nature, Vol. 438, pp. 43–44.
  7. 7.0 7.1 Venuti, Fiammetta; Bruno, Luca (2008). "The synchronous lateral excitation phenomenon: modelling framework and application". Comptes Rendus Mécanique 336 (1–2): 194–199. https://staff.polito.it/luca.bruno/2007b_CRM_Venuti_Bruno.pdf. Retrieved 2025-04-21. 
  8. "Modelling of lateral forces generated by pedestrians walking across footbridges". Journal of Sound and Vibration 528: 116938. 2022. https://research.manchester.ac.uk/files/176996071/submitted_version_of_lateral_forces.pdf. Retrieved 2025-04-21. 
  9. Julavitz, Robert. "Point of Collapse", Village Voice, 26 August 2003.
  10. Dallard, P. et al. "The London Millennium Footbridge," Structural Engineer, 20 November 2001. 79:22, pp. 17–35.



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