Many construction activities such as pile driving, drilling, roadbed compaction, drilling and blasting tunnels can cause ground vibration, which affects buildings and people nearby. If the wave intensity is high while the distance to neighboring buildings is close, the presence of damage in buildings is inevitable. Determination of the vibration radius which can cause damage in surrounding structures regarding each source of vibration is a necessary requirement for planning, construction technology selection and design method. It can minimize risks to surrounding buildings. The content of this article presents the measurement method to accurately estimate the vibration level of the construction activities of Hanoi pilot urban railway line 3 passing the busy Kim Ma street, Hanoi. High sensitivity vibration accelerometers are gathered in lines from the vibration source. It is shown that predicting the radius of the impact of construction site vibrations to neighboring buildings is possible. If the level of vibration is high then measures can be taken to prevent damage caused by the construction of the Hanoi pilot urban railway line. From obtained results, some solutions are proposed to minimize and avoid possible negative impacts.

- M. Villot, P. Ropars, P. Jean, E. Bongini, F. Poisson, Modeling the influence of structural modifications on the response of a building to railway vibration. Noise Control Eng. J., 59(6) (2011) 641-651. doi:10.3397/1.3633330.

- K.A. Kuo, M.F.M. Hussein, H.E.M. Hunt. The Effects of a Second Tunnel on the Propagation of Ground-Borne Vibration from an Underground Railway. Tokyo: Springer Japan. (2012) 307-314. doi:10.1007/978-4-431-53927-8_36.

- G. Standards, DIN 4150-3: vibration in buildings - part 3: effects on structures, German Institute for Standardisation: German, 1999.

- BSI, BS 7385-2: Evaluation and Measurement for Vibration in Buildings: Guide to damage levels from groundborne vibration. Vol. 7385. British Standards Institution, 1993.

- MST, TCVN 7378 - Vibration and shock - Vibration of buildings - Limits of vibration levels and method for evaluation. , Ministry of Science and Technology: Vietnam. (2004).

- P.D. Cenek, A.J. Sutherland, I.R. McIver, Ground vibration from road construction, NZ Transport Agency: Wellington, N.Z., 2012.

- P. Elias, M. Villot, Review of existing standards, regulations and guidelines, as well as laboratory and field studies concerning human exposure to vibration. Deliverable D1, 4, 2011.

- G. Lombaert, G. Degrande, J. Kogut, S. François, The experimental validation of a numerical model for the prediction of railway induced vibrations. J. Sound Vibrat., 297(3) (2006) 512-535. doi:10.1016/j.jsv.2006.03.048.

- N. Lan, Ground earth vibrations, Construction Publishing.

- H.J. Van Leeuwen. The determination of railway vibrations levels in practice. In: Inter-noise and Noise-con Congress and Conference Proceedings. Institute of Noise Control Engineering, 2016, pp. 4442-4450.

- M. Schevenels, G. Degrande, Site vibration evaluation on the Arenberg campus for the planning of a nanotechnology laboratory: a comparison of three sites, Tech. Rep. BWM-2009-10, Department of Civil Engineering, KU Leuven, 2009.

- M. Schevenels, G. Degrande, Site vibration evaluation on the Arenberg III campus for the planning of a nanotechnology laboratory, Tech. Rep. BWM-2009-04, Department of Civil Engineering, KU Leuven, 2009.

- M.R. Svinkin, Soil and structure vibrations from construction and industrial sources, in 6th Conference of the International Conference on Case Histories in Geotechnical Engineering, Missouri University of Science and Technology, 2008.

- M.A. Lak, S. François, G. Degrande, G. Lombaert, Development and experimental validation of a numerical model for the prediction of ground vibration generated by pavement breaking. Soil Dyn. Earthquake Eng. 79 (2015) 199-210. doi:10.1016/j.soildyn.2015.09.015.

- S. François. Nonlinear modelling of the response of structures due to ground vibrations. PhD thesis. KU Leuven, Department of Civil Engineering, 2008.