Approximation of the Statistical Characteristics of Piecewise Linear Systems with Asymmetric Damping and Stiffness under Stationary Random Excitation

• Published in: Mathematics (Basel) Vol. 10; no. 22; p. 4275
• Main Authors: Sireteanu, Tudor, Mitu, Ana-Maria, Solomon, Ovidiu, Giuclea, Marius
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.11.2022
• Subjects: Approximation theory; asymmetric piecewise linear systems; Asymmetry; Damping; Damping (Mechanics); Dynamic response; Equilibrium; Excitation spectra; Linear systems; Lyapunov equation; Mathematical models; Mathematical research; Methods; Numerical integration; Random excitation; Stationary processes; Stiffness; transmissibility factors; Romania
• ISSN: 2227-7390; 2227-7390
• DOI: 10.3390/math10224275

In this paper, the dynamic response of piecewise linear systems with asymmetric damping and stiffness for random excitation is studied. In order to approximate the statistical characteristics for each significant output of piecewise linear system, a method based on transmissibility factors is applied. A stochastic linear system with the same transmissibility factor is attached, and the statistical parameters of the studied output corresponding to random excitation having rational spectral densities are determined by solving the associated Lyapunov equation. Using the attached linear systems for root mean square and for standard deviation of displacement, the shift of the sprung mass average position in a dynamic regime, due to damping or stiffness asymmetry, can be predicted with a good accuracy for stationary random input. The obtained results are compared with those determined by the Gaussian equivalent linearization method and by the numerical integration of asymmetric piecewise linear system equations. It is shown that the piecewise linear systems with asymmetrical damping and stiffness characteristics can provide a better vibration isolation (lower force transmissibility) than the linear system.