Understanding Complex Number Equations: An Exploration

On adding the two equations, you will get the desired result in terms of x and y.I think this is the only other way to solve the problem. You will need the fact that ##\cos^2 \theta + \sin^2 \theta = 1## and ##2 \cos \theta \sin \theta = \sin 2 \theta##.
  • #36
Ray Vickson said:
I did allow for that possibility in the last sentence. I have not tried to follow all the interweaving of this convoluted thread.
Thankyou, didn't know you couldn't post solutions before OP.
 
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  • #37
Mark44 said:
I don't think there's a problem here. The OP posted a solution many posts back.
See post #36.
 
  • #38
Somali_Physicist said:
Thankyou, didn't know you couldn't post solutions before OP.
I posted a solution in post (17) and there was another solution in post (31). There is also another way of doing it using modulus, if given time i will post it here for research. In my opinion, solution (31) gives us the quickest and most friendliest of solutions.
 
  • #39
chwala said:
I posted a solution in post (17) and there was another solution in post (31). There is also another way of doing it using modulus, if given time i will post it here for research. In my opinion, solution (31) gives us the quickest and most friendliest of solutions.

I think you are right, unless there is some "geometric" method that helped the person who proposed the problem to "invent" it. After all, how on Earth would one ever guess that such a relationship could hold?
 
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  • #40
i would start by setting the absolute values of both sides equal.
 
  • #41
Ray Vickson said:
I think you are right, unless there is some "geometric" method that helped the person who proposed the problem to "invent" it. After all, how on Earth would one ever guess that such a relationship could hold?
This is from the pure maths textbook by Prof. C. J Tranter, 1964 1st edition. i find the old maths texts quite intriguing in terms of approach to tackling problems.
 
  • #42
Let'sthink said:
The operation of complex conjugation is very powerful. We know that complex conjugate of sum or product or even division of two complex numbers is the sum, or product or division of their conjugates. So you can immediately write

x-iy = a/(b+cos φ -i sinφ) ... 1 add to this what is given and you can get x immediately. Pursue this method as another method.
given x+iy = a/(b+cos φ +i sinφ)----- 2

Multiply 1 and 2
x^2 +y^2 = [(a^2 )/{(1+b^2+2b*cosφ)}]-------- 3
Add 1 and 2
2x = [{2a(b+cosφ)}/(1+b^2+2b*cosφ)] or
x = [{a(b+cosφ)}/(1+b^2+2b*cosφ)] ------------- 4
Let'sthink said:
(x+iy)(b+cosφ+i sinφ) = a-----(1), taking complex conjugate on both sides we get
(x-iy)(b+cosφ-i sinφ) = a -------(2) multiplying LHSs and RHSs we get
(x² +y²) (b² +1 +2bcosφ) = a² ---------------------- (3), we need to eliminate cosφ and bring in x
For that
Writing original expression
(x+iy) = [a/(b+cosφ+i sinφ)] ----------------------(4) Taking complex conjugate
(x-iy) = [a/(b+cosφ-i sinφ)] -----------------------(5); adding (4) and (5) we get
[2a(b+cosφ)/(b² +1 +2bcosφ)] = 2x --------------(6) multiplying (3) and (6) we get
[2a(b+cosφ)(x² +y²)] = 2xa² or
[2(b+cosφ)(x² +y²)] = 2xa ------ (7)
Eliminating cosφ between (3) and (7) should give you the result.
They are all equivalent methods because you said complex conjugate will not work I did this all work
Hope it helps
Rewriting 3 gives us
(x² +y²) (b²-1 +1 +1 +2bcosφ) = a² or
{(b²-1) +2*(1 +bcosφ)] = a²/((x² +y²))
From 7 we have
(b+cosφ) =[ (xa)/(x² +y²)] ------ (7)multiplying by b gives
(b²+bcosφ) =[ (abx)/(x² +y²)] or
bcosφ =[ (xa)/(x² +y²)] - b² ---------- 8
Substituting 8 in 3 we get
(x² +y²) [(b² +1 +[ (2abx)/(x² +y²)] - 2b² ] = a² simplifying we get
(x² +y²) [(-b² +1 +[ (2abx)/(x² +y²)] = a² or
(x² +y²) (-b² +1) +2abx = a² or
2abx = a² + (x² +y²) (b² -1)

I think this was what was to be proved
 
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  • #43
Let'sthink said:
given x+iy = a/(b+cos φ +i sinφ)----- 2

Multiply 1 and 2
x^2 +y^2 = [(a^2 )/{(1+b^2+2b*cosφ)}]-------- 3
Add 1 and 2
2x = [{2a(b+cosφ)}/(1+b^2+2b*cosφ)] or
x = [{a(b+cosφ)}/(1+b^2+2b*cosφ)] ------------- 4

Rewriting 3 gives us
(x² +y²) (b²-1 +1 +1 +2bcosφ) = a² or
{(b²-1) +2*(1 +bcosφ)] = a²/((x² +y²))
From 7 we have
(b+cosφ) =[ (xa)/(x² +y²)] ------ (7)multiplying by b gives
(b²+bcosφ) =[ (abx)/(x² +y²)] or
bcosφ =[ (xa)/(x² +y²)] - b² ---------- 8
Substituting 8 in 3 we get
(x² +y²) [(b² +1 +[ (2abx)/(x² +y²)] - 2b² ] = a² simplifying we get
(x² +y²) [(-b² +1 +[ (2abx)/(x² +y²)] = a² or
(x² +y²) (-b² +1) +2abx = a² or
2abx = a² + (x² +y²) (b² -1)

I think this was what was to be proved

is this different from your post 31?
 
  • #44
chwala said:
is this different from your post 31?
No. Just different elimination process.
 
  • #45
ok ...
 

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