An Adaptive Time-Step Control Method in Damped Pseudo-Transient Analysis for Solving Nonlinear DC Circuit Equations

An Adaptive Time-Step Control Method in Damped Pseudo-Transient Analysis for Solving Nonlinear DC Circuit Equations

An adaptive time-step control method is proposed for the damped pseudo-transient analysis (DPTA) method. The new method is based on the idea of switched evolution/relaxation (SER), which can automatically adapt the step size for different circuit states. Considering the number of iterations needed f...

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Veröffentlicht in:IEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences Communications and Computer Sciences, 2017/02/01, Vol.E100.A(2), pp.619-628
Hauptverfasser: WU, Xiao, JIN, Zhou, NIU, Dan, INOUE, Yasuaki
Format: Artikel
Sprache:eng
Schlagworte:
Adaptive control
Adaptive control systems
Biological evolution
Circuits
Computer simulation
Convergence
DC operating points
Efficiency
Mathematical analysis
Mathematical models
Nonlinear analysis
Nonlinear equations
Nonlinearity
pseudo transient analysis
Robustness (mathematics)
State (computer science)
step-control
switched evolution/relaxation
Transient analysis
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Zusammenfassung:An adaptive time-step control method is proposed for the damped pseudo-transient analysis (DPTA) method. The new method is based on the idea of switched evolution/relaxation (SER), which can automatically adapt the step size for different circuit states. Considering the number of iterations needed for the convergence of Newton-Raphson (NR) method and the states in previous steps, the proposed method can automatically optimize the time-step size. Using numerical examples, the new method is proven to improve robustness, simulation efficiency, and the convergence of DPTA for solving nonlinear DC circuit equations.
ISSN:0916-8508
1745-1337
DOI:10.1587/transfun.E100.A.619