Starcraftmazter
Member
Question:
a) Use De Moivre's theorem to express cos 3theta in terms of cos theta and sin 3theta in terms of sin theta.
b) Use the result to solve the question 8x^3 - 6x+1=0
c) Deduce that
i) Cos (2pi/9) + cos (4pi/9) = cos (pi/9)
ii) cos (pi/8) . cos (3pi/8) . cos (5pi/8) . cos (7pi/8) = 1/8
Now I can do (a) and (b) easily (so don't waste time posting solutions to them!), but rather lost when I came to part (c). We did one example on that type of question with tan 5th, and after looking back at it briefly I understood the process fairly well, but maybe not because I couldn't do part (c) of that question. I ended up with something like this from memory:
Letting c = cos th,
cos 3th = 4c^3 - 3c = -1
And let th = pi/3, and hence th = pi/3 +- kpi/3
And then I didn't know how to get from there to what I should get at, so clearly I must be doing something wrong.
So, can someone post a solution that part (c) of the question above please? And if you understand what I did, maybe tell me where I went wrong (though I'm assuming everywhere
)
a) Use De Moivre's theorem to express cos 3theta in terms of cos theta and sin 3theta in terms of sin theta.
b) Use the result to solve the question 8x^3 - 6x+1=0
c) Deduce that
i) Cos (2pi/9) + cos (4pi/9) = cos (pi/9)
ii) cos (pi/8) . cos (3pi/8) . cos (5pi/8) . cos (7pi/8) = 1/8
Now I can do (a) and (b) easily (so don't waste time posting solutions to them!), but rather lost when I came to part (c). We did one example on that type of question with tan 5th, and after looking back at it briefly I understood the process fairly well, but maybe not because I couldn't do part (c) of that question. I ended up with something like this from memory:
Letting c = cos th,
cos 3th = 4c^3 - 3c = -1
And let th = pi/3, and hence th = pi/3 +- kpi/3
And then I didn't know how to get from there to what I should get at, so clearly I must be doing something wrong.
So, can someone post a solution that part (c) of the question above please? And if you understand what I did, maybe tell me where I went wrong (though I'm assuming everywhere
)