During the transient response of an electronic circuit, its behavior changes as it transitions from one stable state to another in response to a sudden change in its input or operating conditions. This transition can occur when a circuit is turned on, off, or experiences a sudden change in its input signal. The transient response is a temporary phenomenon that settles over time until the circuit reaches a new steady-state condition.
Let's break down the transient response behavior into key stages:
Initial conditions: At the beginning of the transient response, the circuit is assumed to be in a stable state. The voltage and current levels across all elements in the circuit have reached equilibrium based on previous inputs.
Change in input: The transient response is triggered by a sudden change in the circuit's input, which could be a step change, a pulse, or any other abrupt variation in the input signal.
Capacitor charging and discharging: In circuits with capacitors, during the transient response, capacitors may charge or discharge depending on the nature of the input change. If the input increases, capacitors may charge towards the new voltage level. Conversely, if the input decreases, capacitors may discharge to reach the new lower voltage level.
Inductor behavior: In circuits with inductors, they generate a back electromotive force (EMF) that opposes any change in current. During the transient response, the inductor's current may rise or fall depending on the change in input. The rate of change of current in an inductor is proportional to the applied voltage and the