This paper investigates the combined effects of mechanical vibrations and high temperatures on an electric component of an electric vehicle. This study investigates the reliability and ergonomics of a printed circuit board (PCB) component subjected to random vibrations and high temperatures. The component, an important element in the electric vehicle, is designed to operate in harsh environments characterized by mechanical stress, thermal fluctuations, and random vibrations. The study highlights the importance of considering the interplay between mechanical, thermal, and vibrational stressors in the design and testing of PCB components for electric vehicles.

Lall, P., Thomas, T., Suhling, J., Prognostication of Damage in Automotive Underhood Electronics Subjected to Temperature and Vibration, In 2018 IEEE 68th Electronic Components and Technology Conference (ECTC) (pp. 1330-1341). IEEE, 2018.

Basaran, C., Chandaroy, R., Thermomechanical analysis of solder joints under thermal and vibrational loading. J. Electron. Packag., 124(1), 60-66. 2002.

Barker, J. Vodzak, A. Dasgupta, M. Pecht, Combined vibrational and thermal solder joint fatigue a generalized strain versus life approach, ASME J. Electron. Package vol. 112(2), pp. 129–134, 1990.

Wu, J., Zhang, R. R., Radons, S., Long, X., Stevens, K. K., Vibration analysis of medical devices with a calibrated FEA model, Computers & structures, 80(12), 1081-1086, 2002.

Pitarresi, J. M., Modeling of printed circuit cards subject to vibration, In IEEE international symposium on circuits and systems (pp. 2104-2107). IEEE, 1999.

Pitarresi, J. M., Celetka, D., Coldwel, R., Smith, D., The smeared properties approach to FE vibration modeling of printed circuit cards, ASME Journal of Electronics Packaging, 113(3), 250-257, 1991.

Pitarresi, J. M., Akanda, A., Random vibration response of a surface mount lead/solder joint, Advances in electronic packaging, 4(1), 1993.

Lall, P., Lowe, R., Goebel, K., Resistance spectroscopy-based condition monitoring for prognostication of high reliability electronics under shock-impact, In 2009 59th Electronic Components and Technology Conference (pp. 1245-1255). IEEE, 2009.

Lall, P., Lowe, R., Goebel, K., Extended Kalman filter models and resistance spectroscopy for prognostication and health monitoring of leadfree electronics under vibration. IEEE Transactions on Reliability, 61(4), 858-871, 2012.

Lall, P., Lowe, R., Goebel, K., Prognostics health management of electronic systems under mechanical shock and vibration using Kalman filter models and metrics. IEEE Transactions on Industrial Electronics, 59(11), 4301-4314, 2012.

Lall, P., Yadav, V., Locker, D., Sustained high-temperature vibration reliability of thermally aged leadfree assemblies in automotive environments, In 2020 Pan Pacific Microelectronics Symposium (Pan Pacific) (pp. 1-18). IEEE, 2020.

https://en.wikipedia.org/wiki/IEC_60068

nhttps://cdn.standards.iteh.ai/samples/702/7fdf248fa8414d5ebf6ef38068f63646/IEC-60068-2-14-2009.pdf

nhttps://cdn.standards.iteh.ai/samples/23817/6c23bbe60f7340d8bb148d794ef3f40c/IEC-60068-2-64-2008-AMD1-2019.pdf

.https://rms-testsystems.de/electrodynamic-vibration-test-systems-motion-simulator-2/electrodynamic-vibration-test-systems-shaker/electrodynamic-vibration-test-system-up-to-45kn-water-cooled/?lang=en

.https://www.weiss-technik.com/environmental-simulation /en/products/detail/shakeevent-environmental-test-chamber-for-vibration-testing~p3843