This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
BS 6472-1:2008. Guide to evaluation of human exposure to vibration in buildings, Part 1: Vibration sources other than blasting.BS 6472-1:2008. Guide to evaluation of human exposure to vibration in buildingsSearch in Google Scholar
Chae, J. Y., Park, S. K., & Heo, B. W. (2016). Comparison of the Vibration and Acoustic Characteristics of Floor Structural System for Multi-Family Housing. Journal of The Korean Society of Living Environmental System, 23(4), 527–535.ChaeJ. Y.ParkS. K.HeoB. W.2016Comparison of the Vibration and Acoustic Characteristics of Floor Structural System for Multi-Family Housing23452753510.21086/ksles.2016.08.23.4.527Search in Google Scholar
Gonçalves, M. S., Pavic, A., & Pimentel, R. L. (2020). Vibration serviceability assessment of office floors for realistic walking and floor layout scenarios: Literature review. Advances in Structural Engineering, 23(6), 1238–1255.GonçalvesM. S.PavicA.PimentelR. L.2020Vibration serviceability assessment of office floors for realistic walking and floor layout scenarios: Literature review2361238125510.1177/1369433219888753Search in Google Scholar
Nguyen, T., Gad, E., Wilson, J., & Haritos, N. (2014). Mitigating footfall-induced vibration in long-span floors. Australian Journal of Structural Engineering, 15(1), 97–109.NguyenT.GadE.WilsonJ.HaritosN.2014Mitigating footfall-induced vibration in long-span floors1519710910.7158/S12-061.2014.15.1Search in Google Scholar
Nguyen, T., Saidi, I., Gad, E., Wilson, J., & Haritos, N. (2012). Performance of Distributed Multiple Viscoelastic Tuned Mass Dampers for Floor Vibration Applications. Advances in Structural Engineering, 15(3), 547–562.NguyenT.SaidiI.GadE.WilsonJ.HaritosN.2012Performance of Distributed Multiple Viscoelastic Tuned Mass Dampers for Floor Vibration Applications15354756210.1260/1369-4332.15.3.547Search in Google Scholar
Smith, A., Hick, S., & Devine, P. (2009). Design of Floors for Vibration: A New Approach – SCI Publication P354. Ascot: The Steel Construction Institute.SmithA.HickS.DevineP.2009AscotThe Steel Construction InstituteSearch in Google Scholar
Murray, T. M., Allen, D., Ungar, E. E., & Davis, D. B. (2016). Design Guide 11: Vibrations of steel-framed structural systems due to human activity. Chicago: American Institute of Steel Construction AISC.MurrayT. M.AllenD.UngarE. E.DavisD. B.2016ChicagoAmerican Institute of Steel Construction AISCSearch in Google Scholar
Zivanovic, S., & Pavic, A. (2009). Probabilistic Modeling of Walking Excitation for Building Floors. Journal of Performance of Constructed Facilities, 23, 132–143.ZivanovicS.PavicA.2009Probabilistic Modeling of Walking Excitation for Building Floors2313214310.1061/(ASCE)CF.1943-5509.0000005Search in Google Scholar
Willford, M. R., & Young, P. (2006). A design guide for footfall induced vibration of structures (CCIP 016). London: The Concrete Centre.WillfordM. R.YoungP.2006LondonThe Concrete CentreSearch in Google Scholar
European Commission. (2006). Generalisation of criteria for floor vibrations for industrial, office, residential and public building and gymnastic halls, RFCS Report EUR 21972 EN (E. Commission, Ed.).European Commission2006Search in Google Scholar
ISO 10137:2007. Bases for design of structures – Serviceability of buildings and walkways against vibrations (2nd ed.).ISO 10137:2007Search in Google Scholar
Bachmann, H., & Ammann, W. (1987). Vibrations in structures: induced by man and machines. Zurich: IABSE-AIPC-IVBH.BachmannH.AmmannW.1987ZurichIABSE-AIPC-IVBH10.2749/sed003eSearch in Google Scholar
Kerr, S., & Bishop, N. (2001). Human induced loading on flexible staircases. Engineering structures, 23(1), 37–45.KerrS.BishopN.2001Human induced loading on flexible staircases231374510.1016/S0141-0296(00)00020-1Search in Google Scholar
Kasperski, M., & Sahnaci, C. (2007). Serviceability of pedestrian structures. Proceedings of the International Modal Analysis Conference (IMAC XXV), Orlando, USA.KasperskiM.SahnaciC.2007Serviceability of pedestrian structuresOrlando, USASearch in Google Scholar
Ji, T., & Pachi, A. (2005). Frequency and velocity of people walking. Structural Engineer, 84(3), 36–40.JiT.PachiA.2005Frequency and velocity of people walking8433640Search in Google Scholar
Toso, M. A., Gomes, H. M., da Silva, F. T., & Pimentel, R. L. (2016). Experimentally fitted biodynamic models for pedestrian-structure interaction in walking situations. Mechanical Systems and Signal Processing, 72, 590–606.TosoM. A.GomesH. M.da SilvaF. T.PimentelR. L.2016Experimentally fitted biodynamic models for pedestrian-structure interaction in walking situations7259060610.1016/j.ymssp.2015.10.029Search in Google Scholar
Brownjohn, J., Pavic, A., & Omenzetter, P. (2004). A spectral density approach for modelling continuous vertical forces on pedestrian structures due to walking. Canadian Journal of Civil Engineering, 31(1), 65–77.BrownjohnJ.PavicA.OmenzetterP.2004A spectral density approach for modelling continuous vertical forces on pedestrian structures due to walking311657710.1139/l03-072Search in Google Scholar
Racic, V., & Brownjohn, J. M. W. (2011). Stochastic model of near-periodic vertical loads due to humans walking. Advanced Engineering Informatics, 25(2), 259–275.RacicV.BrownjohnJ. M. W.2011Stochastic model of near-periodic vertical loads due to humans walking25225927510.1016/j.aei.2010.07.004Search in Google Scholar
Hudson, E. J., & Reynolds, P. (2014). Implications of structural design on the effectiveness of active vibration control of floor structures. Structural Control and Health Monitoring, 21(5), 685–704.HudsonE. J.ReynoldsP.2014Implications of structural design on the effectiveness of active vibration control of floor structures215685704Search in Google Scholar
Chen, J., Wang, J., & Brownjohn, J. M. (2019). Power spectral-density model for pedestrian walking load. Journal of Structural Engineering, 145(2), 04018239.ChenJ.WangJ.BrownjohnJ. M.2019Power spectral-density model for pedestrian walking load14520401823910.1061/(ASCE)ST.1943-541X.0002248Search in Google Scholar
Mohammed, A. S., & Pavic, A. (2017). Effect of walking people on dynamic properties of floors. Procedia engineering, 199, 2856–2863.MohammedA. S.PavicA.2017Effect of walking people on dynamic properties of floors1992856286310.1016/j.proeng.2017.09.561Search in Google Scholar
Wei, X., Van den Broeck, P., De Roeck, G., & Van Nimmen, K. (2017). A simplified method to account for the effect of human-human interaction on the pedestrian-induced vibrations of footbridges. Procedia engineering, 199, 2907–2912.WeiX.Van den BroeckP.De RoeckG.Van NimmenK.2017A simplified method to account for the effect of human-human interaction on the pedestrian-induced vibrations of footbridges1992907291210.1016/j.proeng.2017.09.331Search in Google Scholar
Shahabpoor, E., Pavic, A., Racic, V., & Zivanovic, S. (2017). Effect of group walking traffic on dynamic properties of pedestrian structures. Journal of Sound and Vibration, 387, 207–225.ShahabpoorE.PavicA.RacicV.ZivanovicS.2017Effect of group walking traffic on dynamic properties of pedestrian structures38720722510.1016/j.jsv.2016.10.017Search in Google Scholar
Bassoli, E., Van Nimmen, K., Vincenzi, L., & Van den Broeck, P. (2018). A spectral load model for pedestrian excitation including vertical human-structure interaction. Engineering structures, 156, 537–547.BassoliE.Van NimmenK.VincenziL.Van den BroeckP.2018A spectral load model for pedestrian excitation including vertical human-structure interaction15653754710.1016/j.engstruct.2017.11.050Search in Google Scholar
Zivanovic, S., Pavic, A., & Reynolds, P. (2005). Vibration serviceability of footbridges under human-induced excitation: a literature review. Journal of Sound and Vibration, 279(1–2), 1–74.ZivanovicS.PavicA.ReynoldsP.2005Vibration serviceability of footbridges under human-induced excitation: a literature review2791–217410.1016/j.jsv.2004.01.019Search in Google Scholar
Pernica, G. (1990). Dynamic load factors for pedestrian movements and rhythmic exercises. Canadian Acoustics, 18(2), 3–18.PernicaG.1990Dynamic load factors for pedestrian movements and rhythmic exercises182318Search in Google Scholar
Ebrahimpour, A., Hamam, A., Sack, R., & Patten, W. (1996). Measuring and modeling dynamic loads imposed by moving crowds. Journal of Structural Engineering-Asce, 122(12), 1468–1474.EbrahimpourA.HamamA.SackR.PattenW.1996Measuring and modeling dynamic loads imposed by moving crowds122121468147410.1061/(ASCE)0733-9445(1996)122:12(1468)Search in Google Scholar
Ellis, B. (2003). The influence of crowd size on floor vibrations induced by walking. Structural Engineer, 81(6), 20–27.EllisB.2003The influence of crowd size on floor vibrations induced by walking8162027Search in Google Scholar
Pan, T. C., XUTING, Y., & CHEE, L. L. I. M. (2008). Evaluation of Floor Vibration in a Biotechnology Laboratory Caused by Human Walking. Journal of Performance of Constructed Facilities, 22(3), 122–130.PanT. C.XUTINGY.CHEEL. L. I. M.2008Evaluation of Floor Vibration in a Biotechnology Laboratory Caused by Human Walking22312213010.1061/(ASCE)0887-3828(2008)22:3(122)Search in Google Scholar
Sétra (2006). Assessment of vibrational behaviour of footbridges under pedestrian loading. Paris: The French Sétra.Sétra2006ParisThe French SétraSearch in Google Scholar
Chopra, A. K. (2007). Dynamics of structures. New Jersey: Pearson Education.ChopraA. K.2007New JerseyPearson EducationSearch in Google Scholar
De Silva, C. W. (2006). Vibration: fundamentals and practice. Florida: CRC press.De SilvaC. W.2006FloridaCRC press10.1201/b18521Search in Google Scholar
ISO 2631-1:1997(en). Mechanical vibration and shock -- Evaluation of human exposure to whole-body vibration: Part 1: General requirements.ISO 2631-1:1997(en)Search in Google Scholar
CSI (2017). Analysis Reference Manual for SAP2000, ETABS, SAFE and CSiBridge. Berkeley, CA: Computers and Structures, Inc.CSI2017Berkeley, CAComputers and Structures, IncSearch in Google Scholar
Kharab, A., & Guenther, R. (2018). An introduction to numerical methods: a MATLAB® approach. CRC press.KharabA.GuentherR.2018CRC pressSearch in Google Scholar
Rubinstein, R. Y., & Kroese, D. P. (2016). Simulation and the Monte Carlo method (Vol. 10). New Jersey: John Wiley & Sons.RubinsteinR. Y.KroeseD. P.2016New JerseyJohn Wiley & Sons10.1002/9781118631980Search in Google Scholar