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I am using the FFT to evaluate a polynomial at certain points so that it can be represented using value representation. (representation as a number of points equal to its degree)

However to multiply two polynomials of degree d, I need to evaluate both at 2d + 1 points. However using the FFT for evaluation (multiplying by the dth roots of unity) only evaluates the polynomial at d points. Therefore how can the FFT be used for evaluation for polynomial evaluation if it only evaluates a polynomial at d points? (as opposed to 2d + 1)

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Are you trying to multiply two polynomials together? Or are you trying to evaluate a polynomial at a bunch of points. Can you clarify? Your question seems to contradict itself. – Mysticial Jul 6 '12 at 4:11
I am multiplying two polynomials. However to multiply the polynomials, I need to evaluate them at a certain number of points, multiply them in value representations and the use interpolation to transform the points back to coefficients. Therefore my question is among about multiplication AND evaluation. – fdh Jul 6 '12 at 4:13
You don't need to evaluate the polynomial at any points to multiply them together. Just FFT the coefficients directly. – Mysticial Jul 6 '12 at 4:14
I know- that would be a simpler solution. However I'm in a situation where I need to FFT points not coeffcients. Sorry, I am not allowed to share exactly why I have this restraint. – fdh Jul 6 '12 at 4:21
Oh ok. I'm not familiar with the topic of FFT polynomial evaluation. – Mysticial Jul 6 '12 at 4:24

1 Answer 1

up vote 3 down vote accepted

You get to choose which n-th roots of -1 you evaluate at. If you need 2d-1 points (as I suspect you do) just use the (2d-1)-th roots of -1. In fact, you would normally use the 2^k-th roots of -1, where 2^k is the first power of 2 >= 2d-1, because it is much easier to get fast FFT for powers of 2. The complexity is still O(d log d) because the definition of O allows for constant factors.

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Perfect, thank you! – fdh Jul 6 '12 at 4:56

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