In electronics, steady state is an equilibrium condition of a circuit or network that occurs as the effects of transients are no longer important. Steady state is reached (attained) after transient (initial, oscillating or turbulent) state has subsided. During steady state, a system is in relative stability.
Steady state determination is an important topic, because many design specifications of electronic systems are given in terms of the steady-state characteristics. Periodic steady-state solution is also a prerequisite for small signal dynamic modeling. Steady-state analysis is therefore an indispensable component of the design process.
YouTube Encyclopedic
-
1/3Views:19 97285 4479 165
-
Circuits I: Example with Inductors and Capacitors at Steady State
-
Steady State Circuit Analysis with Phasors
-
AP Physics - Capacitors in Steady State
Transcription
Calculation methods
Steady state calculation methods can be sorted into time-domain algorithms (time domain sensitivities, shooting) and frequency-domain algorithms (harmonic balance) methods, are the best choice for most microwave circuits excited with sinusoidal signals (e.g. mixers, power amplifiers).
Time domain methods
Time domain methods can be further divided into one step methods (time domain sensitivities) and iterative methods (shooting methods). One step methods require derivatives to compute the steady state; whenever those are not readily available at hand, iterative methods come into focus.
See also
- Frequency response
- Stiff circuits
- Harmonic balance
- Time domain sensitivities
- Shooting method
- Transient response
Further reading
- Jan Ogrodsky - Circuit Simulation and Algorithms. CRC Press
 | This electricity-related article is a stub. You can help Wikipedia by expanding it. |
This page was last edited on 30 October 2022, at 07:34