This paper proposes a fast Fourier transforms (FFT)-based spectral analysis method for the dynamic analysis of linear discrete dynamic systems which have non-proportional viscous damping and are subjected to non-zero initial conditions. To evaluate the proposed FFT-based spectral analysis method, the forced vibration of a three degree-of-freedom (DOF) system is considered as an illustrative problem. The accuracy of the proposed FFT-based spectral analysis method is evaluated by comparing the forced vibration responses obtained by the present FFT-based spectral analysis method with those obtained by using the well-known Runge-Kutta method and modal analysis method
Twenty years ago, accurate harmonic response analysis of non-proportionally damped systems required ...
A new approximate methodology for nonstationary random vibration analysis of multi-degree-of-freedo...
This work presents a class of time-frequency methods for detecting and characterizing nonlinearity i...
The objectives of the studies reported in this dissertation are: (1) to develop improved techniques...
An analysis of a recent modified frequency-domain procedure for computing the response of linear sys...
In this paper, an FFT-based spectral element method (SEM) is introduced for the linear continuum dyn...
Although the frequency domain analysis using the standard Discrete Fourier Transform and the Fast Fo...
Frequency-domain methods are usually more efficient computationally than time-domain methods to comp...
Algorithms for system identification applying throughout Fast Fourier Transform (FFT) to the major c...
This paper presents a new frequency-domain method to analyze physically non-linear structural system...
It is more economic to compute the response of linear systems with Fourier methods using fast Fourie...
This paper seeks to examine some important outstanding theoretical issues of general nonviscously da...
The idea of the research is mainly to understand the application of DFT, windowing, zero padding, us...
The objective of the paper is to explain a modern Hilbert transform method for analysis and identifi...
A perturbation method for the eigenanalysis of nonclassically damped dynamic systems is derived and ...
Twenty years ago, accurate harmonic response analysis of non-proportionally damped systems required ...
A new approximate methodology for nonstationary random vibration analysis of multi-degree-of-freedo...
This work presents a class of time-frequency methods for detecting and characterizing nonlinearity i...
The objectives of the studies reported in this dissertation are: (1) to develop improved techniques...
An analysis of a recent modified frequency-domain procedure for computing the response of linear sys...
In this paper, an FFT-based spectral element method (SEM) is introduced for the linear continuum dyn...
Although the frequency domain analysis using the standard Discrete Fourier Transform and the Fast Fo...
Frequency-domain methods are usually more efficient computationally than time-domain methods to comp...
Algorithms for system identification applying throughout Fast Fourier Transform (FFT) to the major c...
This paper presents a new frequency-domain method to analyze physically non-linear structural system...
It is more economic to compute the response of linear systems with Fourier methods using fast Fourie...
This paper seeks to examine some important outstanding theoretical issues of general nonviscously da...
The idea of the research is mainly to understand the application of DFT, windowing, zero padding, us...
The objective of the paper is to explain a modern Hilbert transform method for analysis and identifi...
A perturbation method for the eigenanalysis of nonclassically damped dynamic systems is derived and ...
Twenty years ago, accurate harmonic response analysis of non-proportionally damped systems required ...
A new approximate methodology for nonstationary random vibration analysis of multi-degree-of-freedo...
This work presents a class of time-frequency methods for detecting and characterizing nonlinearity i...