This question has several parts, many of which i have done.
If w = x + x-1 prove that,
i) x2 + x-2 = w2 - 2
ii) x4 + x3 + x2 + x + 1
= x2(w2 + w - 1)
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
Show that the roots of x4 + x3 + x2 + x + 1 = 0 are the four complex roots of x5 = 1.
Deduce that cos 72 = (1/4)(√5 -1), cos 36 = (1/4)(√5 + 1).
I can do all the parts except for the deducing the cos angle bits. Could any body help. Ill post up my working for the first bits so that anyone trying to help can continue from.
i) Prove: x2 + x-2 = w2 - 2
RHS = (x + x-1)2 -2
=x2 + 2 + x-2 -2
= x2 + x-2
= LHS
ii) Prove: x4 + x3 + x2 + x + 1
= x2(w2 + w - 1)
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
w2 + w - 1 = 0
w = [-1 ± √(1 - 4(1)(-1))] / 2
= -1/2 ± √5/2
.:. w2 + w - 1 = (w + 1/2 + √5/2)(w + 1/2 - √5/2)
= (x + x-1 + 1/2 + √5/2)(x + x-1 + 1/2 - √5/2)
and x2(w2 + w - 1)
= x2(x + x-1 + 1/2 + √5/2)(x + x-1 + 1/2 - √5/2)
=[x2 + 1 + (1/2)x + (√5/2)x][x2 + 1 + (1/2)x - (√5/2)x]
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
-----------------------
Now to Show that the roots of x4 + x3 + x2 + x + 1 = 0 are the four complex roots of x5 = 1:
x5 = 1
r5cis5θ = 1cis0
r = 1, 5θ = 2π k
.:. θ = (2π k) / 5
x1 = 1
x2 = cis(2π/5)
x3 = cis(-2π/5)
x4 = cis(4π/5)
x5 = cis(-4π/5)
x5 - 1 = 0, where (x - 1) is a factor.
hence by polynomial division... (i cant really show this bit)
x5 - 1= (x-1)(x4 + x3 + x2 + x + 1)
.:. x4 + x3 + x2 + x + 1 = 0 holds the complex roots of x5 = 0.
--------------
Now to prove that cos crap:
x4 + x3 + x2 + x + 1
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
= [x - cis(2π/5)][x - cis(-2π/5)][x - cis(4π/5)][x - cis(-4π/5)]
= [x2 - 2xcos(2π/5) + 1][x2 - 2xcos(4π/5) + 1]
(I Skipped a few steps cuz its too long)..
Now if i equate... i can no way prove the results the question asks me.. so this is where im stuck and i hope somebody can help...
If w = x + x-1 prove that,
i) x2 + x-2 = w2 - 2
ii) x4 + x3 + x2 + x + 1
= x2(w2 + w - 1)
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
Show that the roots of x4 + x3 + x2 + x + 1 = 0 are the four complex roots of x5 = 1.
Deduce that cos 72 = (1/4)(√5 -1), cos 36 = (1/4)(√5 + 1).
I can do all the parts except for the deducing the cos angle bits. Could any body help. Ill post up my working for the first bits so that anyone trying to help can continue from.
i) Prove: x2 + x-2 = w2 - 2
RHS = (x + x-1)2 -2
=x2 + 2 + x-2 -2
= x2 + x-2
= LHS
ii) Prove: x4 + x3 + x2 + x + 1
= x2(w2 + w - 1)
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
w2 + w - 1 = 0
w = [-1 ± √(1 - 4(1)(-1))] / 2
= -1/2 ± √5/2
.:. w2 + w - 1 = (w + 1/2 + √5/2)(w + 1/2 - √5/2)
= (x + x-1 + 1/2 + √5/2)(x + x-1 + 1/2 - √5/2)
and x2(w2 + w - 1)
= x2(x + x-1 + 1/2 + √5/2)(x + x-1 + 1/2 - √5/2)
=[x2 + 1 + (1/2)x + (√5/2)x][x2 + 1 + (1/2)x - (√5/2)x]
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
-----------------------
Now to Show that the roots of x4 + x3 + x2 + x + 1 = 0 are the four complex roots of x5 = 1:
x5 = 1
r5cis5θ = 1cis0
r = 1, 5θ = 2π k
.:. θ = (2π k) / 5
x1 = 1
x2 = cis(2π/5)
x3 = cis(-2π/5)
x4 = cis(4π/5)
x5 = cis(-4π/5)
x5 - 1 = 0, where (x - 1) is a factor.
hence by polynomial division... (i cant really show this bit)
x5 - 1= (x-1)(x4 + x3 + x2 + x + 1)
.:. x4 + x3 + x2 + x + 1 = 0 holds the complex roots of x5 = 0.
--------------
Now to prove that cos crap:
x4 + x3 + x2 + x + 1
= [x2 + (1/2)x(1 + √5) + 1][x2 + (1/2)x(1 - √5) + 1]
= [x - cis(2π/5)][x - cis(-2π/5)][x - cis(4π/5)][x - cis(-4π/5)]
= [x2 - 2xcos(2π/5) + 1][x2 - 2xcos(4π/5) + 1]
(I Skipped a few steps cuz its too long)..
Now if i equate... i can no way prove the results the question asks me.. so this is where im stuck and i hope somebody can help...
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