The resistor is a linear device and is characterized by a “straight-line equation”. It dissipates power as heat, its value in ohms can vary as to the tolerance rating (ohms ± % of rated value). The resistor cannot store energy.
An inductor or capacitor is an energy storage device; a capacitor’s current or an inductor’s voltage does not change instantaneously. Initial conditions can apply to both of these devices.
The ideal capacitor has zero conductance or infinite resistance and the ideal inductor has zero resistance or infinite conductance. Ideally, neither device dissipates heat (power). The total power consumed or delivered in an RLC is presented as a complex variable (phasor) with a real (dissipated power by resistors) and imaginary (reactive power ) component.
It should be mentioned that, a capacitor’s conductance (or an inductor’s resistance) only approaches zero and the rated component value (Farads for capacitors or Henries for inductors) may also vary. These variants in addition to EMI and environmental effects would require you to alter your design or analysis somewhat, depending on how critical they are to your design or model.
The Ideal voltage vs. current characteristics for the resistor, inductor and capacitor are shown below in Table 1.
source : PDHengineer.com
Course No E-6002
First Order RLC Circuits: Time Domain
Analysis
An inductor or capacitor is an energy storage device; a capacitor’s current or an inductor’s voltage does not change instantaneously. Initial conditions can apply to both of these devices.
The ideal capacitor has zero conductance or infinite resistance and the ideal inductor has zero resistance or infinite conductance. Ideally, neither device dissipates heat (power). The total power consumed or delivered in an RLC is presented as a complex variable (phasor) with a real (dissipated power by resistors) and imaginary (reactive power ) component.
It should be mentioned that, a capacitor’s conductance (or an inductor’s resistance) only approaches zero and the rated component value (Farads for capacitors or Henries for inductors) may also vary. These variants in addition to EMI and environmental effects would require you to alter your design or analysis somewhat, depending on how critical they are to your design or model.
The Ideal voltage vs. current characteristics for the resistor, inductor and capacitor are shown below in Table 1.
source : PDHengineer.com
Course No E-6002
First Order RLC Circuits: Time Domain
Analysis
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