AC Electrical Circuit Analysis: Series RLC Simulation
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- เผยแพร่เมื่อ 7 ก.ย. 2024
- In this video we explore series RLC circuits via simulation with TINA V12 Student Edition. This version of TINA has a phasor diagram generator, unlike TINA-TI.
References: AC Electrical Circuit Analysis: A Practical Approach; Chapter 2.
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Good video....Why capacitor is used in DC circuits (where there is no voltage frequency is involved)?
Thanks.
It might be used to create a delay, for example, the rising voltage across it could energize a relay that connects a power amp to a loudspeaker. This way, the loudspeaker doesn't produce a "thump" when the amp is turned on.
@@ElectronicswithProfessorFiore Thanks for the kind explanation...It makes sense.
Hi sir,
Is it possible to get two different answers when calculating voltage of a component? For instance, using ohms law (i*Z) for resistor, or voltage divider rule (v*(X/Z))?
Not if you do it correctly. In AC circuits, a common beginner's error is to ignore the phase angles. In such a case, you can come up with different (incorrect) values.
Consider it this way: ultimately, the voltage divider rule is just a convenient form of Ohm's law. To keep it simple, consider two resistors, R1 and R2, in series with source E. The "long way" using Ohm's law is to find the current (I=E/Rtotal), and then multiply that result by the resistor of interest (e.g., VR1=I*R1). If you substitute the original expression for I in that second equation, you get VR1 = (E/Rtotal)*R1, which can rewritten as VR1 = E*(R1/Rtotal) (voltage divider rule).