Can all the theorems are applicable in AC circuits?
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Can all the theorems are applicable in AC circuits?
Yes, the superposition theorem is applicable to AC circuits as well. The theorem is valid for any linear circuit.
How does the DC version of Thevenin’s theorem compare with the AC version?
Any combination of sinusoidal AC sources and impedances with two terminals can be replaced by a single voltage source e and a single series impedance z. The value of e is the open circuit voltage at the terminals, and the value of z is e divided by the current with the terminals short circuited.
Why maximum power transfer theorem is valid for both DC and AC circuits?
Maximum power transfer theorem can be applied to both DC and AC circuits, but the only difference is that the resistance is replaced with impedance in AC circuit.
Can we verify Thevenin’s theorem both on AC and DC circuits?
Thevenin’s Theorem Statement Similar to the DC circuits, this method can be applied to the AC circuits consisting of linear elements like resistors, inductors, capacitors. Like thevinin’s equivalent resistance, equivalent thevinin’s impedance is obtained by replacing all voltage sources by their internal impedances.
Is it possible to apply Norton’s theorem to AC as well as DC circuit?
For alternating current (AC) systems the theorem can be applied to reactive impedances as well as resistances. The Norton equivalent circuit is used to represent any network of linear sources and impedances at a given frequency. This voltage divided by the 1 A current is the Norton impedance Rno.
What is difference between Thevenin and Norton Theorem?
– Norton’s theorem uses a current source, whereas Thevenin’s theorem uses a voltage source. – Thevenin’s theorem uses a resistor in series, while Norton’s theorem uses a resister set in parallel with the source. – Norton’s theorem is actually a derivation of the Thevenin’s theorem.
What is difference between Thevenin and Norton theorem?
What are the limitations of Thevenin’s and Norton’s theorem?
Limitations of Norton’s Theorem It’s not for such modules which are not linear like diodes, the transistor. It also not operate for such circuitries which has magnetic locking. It also not work for such circuitries which has loaded in parallel with dependent supplies.