Capacitor/Inductor Imaginary Numbers

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Discussion Overview

The discussion revolves around the use of complex numbers in analyzing the voltage behavior through capacitors and inductors, particularly in the context of alternating current (AC) signals and their phase relationships.

Discussion Character

  • Technical explanation, Conceptual clarification

Main Points Raised

  • One participant notes that complex numbers represent a 90-degree phase shift between voltage and current signals in reactive components like capacitors and inductors.
  • Another participant explains that using complex notation allows for the representation of AC signals through both amplitude and phase, or real and imaginary components, which are alternative but equivalent representations.
  • A different contribution highlights that complex numbers simplify the manipulation of equations involving periodic signals, such as sine and cosine functions, by combining them into a single function.

Areas of Agreement / Disagreement

Participants generally agree on the utility of complex numbers in representing AC signals and their phase relationships, but there are multiple perspectives on how best to conceptualize and apply these representations.

Contextual Notes

Some assumptions about the familiarity with AC signal behavior and the mathematical properties of complex numbers may not be explicitly stated, which could affect understanding for those less experienced in the topic.

Adder_Noir
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Dear All,

Why do we introduce complex numbers when talking about the voltage behaviour through capacitors and inductors. Any help would be appreciated,

Thanks
 
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because the components induce a 90 degree phase shift between the voltage and current signal, J simply represents a 90 degree phase shift.
for example is a sin wave was aplpied to a capacitor then the voltage would be V=Va*Sin(a) whereas the current would follow I = Ia*Sin(a + 90).
when analysing filters with reactive components the complex and real parts of the transfer function help to find the magnitude and phase at various frequencies.
 
Simply put, it takes 2 numbers to specify the instantaneous value of an AC signal. You can use the vactor/phasor representation, and specify amplitude and phase, or you can use the complex notation and specify real and imaginary components. The two systems are alternative representations of the same idea, and you can easily switch from one to the other.
 
Complex numbers are an easy way to manipulate equations which
involve periodic signals, like sin(wt).

Because exp(jwt) = sin(wt) + jcos(wt), you can work with the
amplitude and phase in a single convenient function.
 

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