Add to ORKGA procedure is developed to determine approximate periodic solutions of autonomous and non-autonomous systems. The trignometric collocation method (TCM) is formalized to allow for the analysis of relatively small order systems directly in physical coordinates. The TCM is extended to large order systems by utilizing modal analysis in a component mode synthesis strategy. The procedure was coded and verified by several check cases. Numerical results for two small order mechanical systems and one large order rotor dynamic system are presented. The method allows for the possibility of approximating periodic responses for large order forced and self-excited nonlinear systems
In the article, based on the application of a continuous-discrete approach to the description of per...
Stroboscopic method for solving perturbed periodic systems of differential equation
This paper describes analytical and numerical methods to analyze the steady state periodic response ...
AbstractLong term dynamics of a class of mechanical systems is investigated in a computationally eff...
Method is modification of generalized Newton-Ralphson algorithm for analyzing two-point boundary pro...
A frequency domain based algorithm using Fourier approximation and Galerkin error minimization has b...
AbstractThis paper presents a general numerical method for the determination of periodic response an...
Asymptotic and periodic behavior prediction for nonlinear control system with mathematical model of ...
Periodic steady-state analysis plays an important role in both theoretical topics and numerical simu...
Coordinated Science Laboratory was formerly known as Control Systems LaboratoryJoint Services Electr...
Computational Analysis of Non-Periodic Oscillations Using the Harmonic Balance Method Payam Azadi...
ii This work presents a new nonlinear, experimental system identification technique, dubbed the Nonl...
In this paper, an efficient algorithm is developed for the identification of stable steady-state sol...
This work is the second in a series of articles that deal with analytical solutions of nonlinear dyn...
Nonlinear effects may play a crucial role, and therefore cannot be ignored in determining forced res...
In the article, based on the application of a continuous-discrete approach to the description of per...
Stroboscopic method for solving perturbed periodic systems of differential equation
This paper describes analytical and numerical methods to analyze the steady state periodic response ...
AbstractLong term dynamics of a class of mechanical systems is investigated in a computationally eff...
Method is modification of generalized Newton-Ralphson algorithm for analyzing two-point boundary pro...
A frequency domain based algorithm using Fourier approximation and Galerkin error minimization has b...
AbstractThis paper presents a general numerical method for the determination of periodic response an...
Asymptotic and periodic behavior prediction for nonlinear control system with mathematical model of ...
Periodic steady-state analysis plays an important role in both theoretical topics and numerical simu...
Coordinated Science Laboratory was formerly known as Control Systems LaboratoryJoint Services Electr...
Computational Analysis of Non-Periodic Oscillations Using the Harmonic Balance Method Payam Azadi...
ii This work presents a new nonlinear, experimental system identification technique, dubbed the Nonl...
In this paper, an efficient algorithm is developed for the identification of stable steady-state sol...
This work is the second in a series of articles that deal with analytical solutions of nonlinear dyn...
Nonlinear effects may play a crucial role, and therefore cannot be ignored in determining forced res...
In the article, based on the application of a continuous-discrete approach to the description of per...
Stroboscopic method for solving perturbed periodic systems of differential equation
This paper describes analytical and numerical methods to analyze the steady state periodic response ...