Structural reliability analysis in randomic excitation signs applying linear-experimental and bioengineering statistical methods

Authors

DOI:

https://doi.org/10.33448/rsd-v9i9.8081

Keywords:

Vibration; Artificial immune system; Artificial intelligence; Wiener filter; SHM.

Abstract

This work demonstrates a study of linear-experimental statistical methods and the negative selection artificial immune system, applied to the random excitation of a structural dynamic system. In the development of this work, a two-storey shear building structure was randomly excited, and the failure was caused by a random external disturbance, whose noisy signal was treated by the Wiener filter and subsequently applied the linear-experimental statistical method and artificial immune system. negative selection. The result of both applications allowed a targeted and objective analysis, demonstrating that the signal spectrum contains qualitative and quantitative levels of great significance in engineering applications.

References

Bangash, M. Y. H. (2011). Earthquake resistant buindings: dynamic analyses, numerical, computations, codified methods, case studies and examples. London. Springer-verlag. 739p.

Beards, C. F. (1996). Structural vibration: analysis and damping. New York. Halsted press. 287p.

Bradley, D. W., & Tyrrell, A. M. (2002). In: Immunotronics-novel finite-state-machine architectures with built-in self-test using self-nonself differentiation. IEEE Transactions on Evolutionary Computation, New York, 6, 227-238.

Chopra, A. K. (2017). Dynamics of structures: theory and applications to earthquake engineering. Hoboken. Pearson education. 960p.

Daniele, V. G., & Zich, R. S. (2014). The wiener-hopf method in electromagnetics. Edison. Scitech publishing. 386p.

Dasgupta, D., & Niño, L. F. (2009). Immunological computation: theory and applications. Boca Raton. Taylor & francis group. 298p.

De Castro, L. N. (2007). Fundamentals of natural computing: basic concepts, algorithms, and applications. Boca Raton. CRC press. 674p.

Forrest, S., Perelson, A. S., Allen, L., & Cherukuri, R. (1994). Self-nonself discrimination in a computer. In: Proc. of the IEEE symposium on research in security and privacy. Oakland. p. 202-212. DOI: 10.1109/risp.1994.296580.

James, F. (2008). Statistical methods in experimental physics. Singapore. World scientific publishing. 362p.

Kailath, T. (1981). Lectures on wiener and kalman filtering. Wien. Springer-Verlag. 189p.

Khan, M. A., Akthar, K., Ahmad, N., Shah, F., & Khattak, N. (2020). Vibration analysis of damaged and undamaged steel structure systems: cantilever column and frame. Earthquake engineering and engineering vibration. 19(3), 725-737. DOI:10.1007/s11803-020-0591-9.

Kuo, H.L.(1980). A more generalized wiener filtering technique. IFAC proceedings volumes. 13(11), 539-542.

Lalanne, C. (2002). Mechanical vibration and shock: randon vibration (v.iii). London. Hermes penton science. 365p.

Mashayekhi, M., Estekanchi, H. E., & Vafai, H. (2020). A method for matching response spectra of endurance time excitations via the fourier transform. Earthquake engineering and engineering vibration. 19(3), 637-648. DOI:10.1007/s11803-020-0586-6.

Okamoto, S. (1984). Introduction to earthquake engineering. Tokyo. University of tokyo press. 640p.

Poularikas, A. D., & Ramadan, Z. M. (2006). Adaptive filtering primer with matlab. Boca Raton. CRC press. 202p.

Rajasekaran, S. (2009). Structural dynamics of earthquake engineering: theory and application using mathematica and matlab. Boca Raton. Woodhead publishing. 902p.

Tan, Y. (2016). Anti-spam techniques based on artificial immune system. Boca Raton. CRC press. 264p.

Wolstenholme, L. C. Reliability modelling: a statistical approach, boca raton, chapman & hall, 1999. 273p.

Zheng, Z., Yufeng, G., Zhang, F., Jian, S., & Degao, Z. (2020). Effects of soil dynamic response on post-earthquake deformation of slopes based on nested newmark model. Earthquake engineering and engineering vibration. 19(3), 573-582. DOI:10.1007/s11803-020-0581-y.

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Published

08/09/2020

How to Cite

SHIINO, D. K. .; OUTA, R.; CHAVARETTE, F. R. .; GONÇALVES, A. C. .; SANTOS, L. H. dos . Structural reliability analysis in randomic excitation signs applying linear-experimental and bioengineering statistical methods. Research, Society and Development, [S. l.], v. 9, n. 9, p. e831998081, 2020. DOI: 10.33448/rsd-v9i9.8081. Disponível em: https://rsdjournal.org/index.php/rsd/article/view/8081. Acesso em: 23 apr. 2024.

Issue

Vol. 9 No. 9

Section

Engineerings

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Copyright (c) 2020 Dayene Kaori Shiino; Roberto Outa; Fabio Roberto Chavarette; Aparecido Carlos Gonçalves; Lucas Henrique dos Santos

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