[1] W. Zhai, Z. Han, Z. Chen, L. Ling, and S. Zhu, “Train–track–bridge dynamic interaction: A state-of-the-art review,” Vehicle System Dynamics, vol. 57, no. 7, pp. 984–1027, 2019.

[2] D. Canteroa and A. Rønnquista, “Numerical evaluation of modal properties change of railway bridges during train passage,” Procedia Engineering, vol. 199, pp. 2931–2936, 2017.

[3] V. N. Dinh, K. D. Kim, and P. Warnitchai, “Dynamic analysis of three-dimensional bridge–high-speed train interactions using a wheel–rail contact model,” Engineering Structures, vol. 31, no. 12, pp. 3090–3106, 2009.

[4] K. Grębowski and M. Zielińska, “Dynamic analysis of historic railway bridges in Poland in the context of adjusting them to Pendolino trains,” International Journal of Applied Mechanics and Engineering, vol. 20, no. 2, pp. 283–297, 2015.

[5] H. Li, H. Xia, M. Soliman, and D. Frangopol, “Bridge stress calculation based on the dynamic response of coupled train–bridge system,” Engineering Structures, vol. 99, pp. 334–345, 2015.

[6] N. Zhang, Y. Tian, and H. Xia, “A train-bridge dynamic interaction analysis method and its experimental validation,” Engineering, vol. 2, no. 4, pp. 528–536, 2016.

[7] S. Schneider and S. Marx, “Design of railway bridges for dynamic loads due to high-speed traffic,” Engineering Structures, vol. 174, pp. 396–406, 2018.

[8] H. Zhao, Y. Ding, and A. Li, “Dynamic performance evaluation of a high-speed fourtrack railway bridge traversed by multiple trains,” Journal of Performance of Constructed Facilities, vol. 32, no. 1, pp. 04017130, 2018.

[9] Y. Shan, Y. Shu, and S. Zhou, “Finite-infinite element coupled analysis on the influence of material parameters on the dynamic properties of transition zones,” Construction and Building Materials, vol. 148, pp. 548–558, 2017.

[10] H. Wang and V. Markine, “Corrective countermeasure for track transition zones in railways: Adjustable fastener,” Engineering Structures, vol. 169, pp. 1–14, 2018.

[11] K. Giannakos and S. Tsoukantas, “Transition zone between ballastless and ballasted track: Influence of changing stiffness on acting forces,” Procedia - Social and Behavioral Sciences, vol. 48, pp. 3548-3557, 2012.

[12] J. M. Olmos and M. Á. Astiz, “Non-linear vehiclebridge- wind interaction model for running safety assessment of high-speed trains over a high-pier viaduct,” Journal of Sound and Vibration, vol. 419, pp. 63–89, 2018.

[13] D. P. Connolly, P. Galvín, B. Olivier, A. Romero, and G. Kouroussis, “A 2.5D time-frequency domain model for railway induced soil-building vibration due to railway defects,” Soil Dynamics and Earthquake Engineering, vol. 120, pp. 332– 344, 2019.

[14] J. Hu, Y. Luo, Z. Ke, P. Liu, and J. Xu., “Experimental study on ground vibration attenuation induced by heavy freight wagons on a railway viaduct,” Journal of Low Frequency Noise, Vibration and Active Control, vol. 37, no. 4, pp. 881–895, 2018.

[15] J. Luo, S. Zhu, and W. Zhai, “An efficient model for vehicle-slab track coupled dynamic analysis considering multiple slab cracks,” Construction and Building Materials, vol. 215, pp. 557–568, 2019.

[16] D. Gorbatjuk, G. Brandstetter, and J. Fink, “Investigations for simplified consideration of train-bridge-interaction based on railjet highspeed train,” Procedia Engineering, vol. 156, pp. 116-123, 2016.

[17] F. Ribes-Llario, C. Zamorano-Martín, S. Morales- Ivorra, and J. Real-Herráiz., “Study of vibrations in a short-span bridge under resonance conditions,” Journal of Vibroengineering, vol. 18, no. 5, pp. 3186–3196, 2016.

[18] C. Mellier, “Optimal design of bridges for high-speed trains: Single and double-span bridges,” M.S. thesis, Department of Civil and Architectural Engineering, Division of Structural Design and Bridges, Royal Institute of Technology, Stockholm, Sweden, 2010.

[19] Y. Song, Y. Du, X. Zhang, and B. Sun, “Evaluating the effect of wheel polygons on dynamic track performance in high-speed railway systems using Co-simulation analysis,” Applied Sciences, vol 9, no. 19, pp. 4165, 2019.

[20] Union Internationale des Chemins de fer (UIC), UIC 776-2R: Design requirements for rail-bridges based on interaction phenomena between train, track and bridge”, Attribution Non-Commercial (BY-NC) 2nd edition, June 2009.

[21] J. J. Kalker, “A fast algorithm for the simplified theory of rolling contact,” Vehicle System Dynamics,” vol. 11, pp. 1–13, 1982.

[22] T. Arvidsson and A. Andersson, “Train–track– bridge interaction for non-ballasted railway bridges on high-speed lines,” Structural Engineering and Bridges, 2017.

[23] D. Gong, J. Zhou, W. Sun, Y. Sun, and Z. Xia, “Method of multi-mode vibration control for the carbody of high-speed electric multiple unit trains,” Journal of Sound and Vibration, vol. 409, pp. 94–111, 2017.