Transportation plays a crucial role in daily life, supporting the mobility of people, goods, and services. With efficient and well-developed transportation infrastructure, travel time, vehicle wear, and traffic congestion can be significantly reduced, while also fostering local and regional economic development. However, alongside these benefits, transportation also has negative impacts, particularly in the form of vibrations that can affect the surrounding environment. These vibrations can disrupt the comfort and health of the community and cause damage to nearby infrastructure. This underscores the importance of mitigating the effects of vibrations, especially those generated by railway and road transportation. Effective mitigation strategies must begin with understanding of the causes and impacts of these vibrations. This Systematic Literature Review aims to identify the factors that cause vibrations from transportation activities and their effects on both the surrounding environment and the transportation infrastructure itself. The findings are expected to serve as a valuable reference for future research on mitigating transportation-induced vibrations.

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Agustina, D., Sopang, A. S., Deviyanti, D., & Simanullang, S. M. (2023). Analisis Faktor yang Mempengaruhi Efektivitas Pelayanan Kesehatan di Puskesmas. ARRAZI: Scientific Journal of Health, 1(1), 18-26.

Alfira, F. A., Khambali, K., Suprijandani, S., & Sari, E. (2023). Analysis of train vibration and noise on population subjective complaints. Jurnal Kesehatan Masyarakat, 11(1), 96-101.

Aritonang, S., Imastuti, I., & Wulanuari, P. H. (2018). Analisis Kerusakan Yang Disebabkan Oleh Vibrasi Pada Sistem Suspensi Kendaraan Roda Empat. Jurnal Teknologi Daya Gerak, 1(1).

Arnberg, P. W., Bennerhult, O., & Eberhardt, J. L. (1990). Sleep disturbances caused by vibrations from heavy road traffic. The Journal of the Acoustical Society of America, 88(3), 1486-1493.

Astrauskas, T., Januševičius, T., & Grubliauskas, R. (2020). Vehicle speed influence on ground-borne vibrations caused by road transport when passing vertical traffic calming measures. Promet-Traffic&Transportation, 32(2), 247-253.

Beretta, S., Carboni, M., & Cervello, S. (2011). Design review of a freight railway axle: fatigue damage versus damage tolerance. Materialwissenschaft und Werkstofftechnik, 42(12), 1099-1104.

Camara, A., Vázquez, V. F., Ruiz-Teran, A. M., & Paje, S. E. (2017). Influence of the pavement surface on the vibrations induced by heavy traffic in road bridges. Canadian Journal of Civil Engineering, 44(12), 1099-1111.

Dong, J., Yang, Y., & Wu, Z. H. (2019). Propagation characteristics of vibrations induced by heavy-haul trains in a loess area of the North China Plains. Journal of Vibration and Control, 25(4), 882-894.

Erkal, A. (2019). Impact of traffic-induced vibrations on residential buildings and their occupants in metropolitan cities. Promet-Traffic&Transportation, 31(3), 271-285.

Esmaeili, M., Zakeri, J. A., & Mosayebi, S. A. (2014). Effect of sand-fouled ballast on train-induced vibration. International Journal of Pavement Engineering, 15(7), 635-644.

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Hegde, A., & Venkateswarlu, H. (2019). Mitigation of traffic induced vibration using geocell inclusions. Frontiers in Built Environment, 5, 136.

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Hua, X., & Gandee, E. (2021). Vibration and dynamics analysis of electric vehicle drivetrains. Journal of Low Frequency Noise, Vibration and Active Control, 40(3), 1241-1251.

Hu, P., Wang, H., Zhang, C., Hua, L., & Tian, G. (2022). Wheel-rail contact-induced impact vibration analysis for switch rails based on the VMD-SS method. Sensors, 22(18), 6872.

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Makovi, D. (2005). Response Analysis Of A Building Loaded By Technical Seismicity Propagating From A Tube Railway Structure. WIT Transactions on The Built Environment, 81.

Mangharam, R., Reyerson, M., Viscelli, S., Balakrishanan, H., Bayen, A., Amin, S., ... & Pappas, G. (2017). MOBILITY21: Strategic investments for transportation infrastructure & technology. arXiv preprint arXiv:1705.01923.

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Yin, J., Zhou, Q., Fang, X., Liu, Z., Liu, Y., Zhang, S., & Sha, Z. (2023). Study on service vibration characteristics of high-speed train disc brake under thermo-solid coupling. Applied Sciences, 13(22), 12361.