Evaluating complex multiplication?

AI Thread Summary
The discussion focuses on understanding the multiplication of complex numbers, particularly through their representation in polar form as R and theta. It emphasizes that when multiplying two complex numbers, the magnitudes multiply while the angles add. Participants seek clarification on the mathematical transformations involved, specifically how to calculate the real part of the product of complex numbers. There is also a request for identities related to arithmetic and geometric series in the context of complex multiplication. The conversation highlights the importance of correctly determining the angle's quadrant when using trigonometric functions.
Loren Booda
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How might one comprehend the product of complex numbers

N
[pi](an+ibn)=C
n=1

such as by representation with vectors in the complex plane, or algebraic simplification? Specifically, I would like to know the value Re(C).
 
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Hi

Any complex number a+ib can be represented as R(& theta). Where R is the magnitude and & theta is the phase. So convert the complex number into R(& theta) form and multiply. The R parts multiply while the angle parts add up.

e.g. R(& theta)* P(& Theta) = R*P(& theta + & Theta)

Got it?


Sridhar
 
A bit rough, sridhar, but helpful in jogging my memory.

Can you or another be more mathematical in regard to the transform involved?

Is it tan-1(b/a)=[the] and r=(a2+b2)1/2?
 
Right...ish

if (a + bi) = r exp(iθ), then it is true that

r = (a^2 + b^2)^(1/2)
and
tan θ = b/a

But you have to make sure that θ is in the correct quadrant. (iow you might have to add π).
 
Hurkyl,

Is there a simplifying (exact) identity for the arithmetic series

N
[sum]tan-1(bn/an)
n=1

and for the geometric series

N
[pi](an2+bn2)1/2
n=1

or, more importantly, for my original statement concerning Re(C)?
 

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