Exponential sums and congruences

[mhill]

let be the exponential sum

[tex] S= \sum_{n=1}^{N}e( \frac{f(x)}{p}) [/tex]

[tex] e(x)= exp( 2i \pi x) [/tex]

my conjecture is that since the complex exponential takes its maximum value '1' when x is equal to an integer then

[tex] Re(S)= \Pi (f,N) [/tex] with [tex]\Pi (f,N) [/tex] is the number of solutions on the interval (1,N) of the congruence

[tex] f(x) =0 mod(p) [/tex] and f(x) is a Polynomial.

 

[yasiru89]

Forgive me if this is a stupid question- but what's [itex]p[/tex]? Or did you mean [itex]n[/tex] instead or [itex]p[/tex] as the number of prime factors of [itex]n[/tex] or something?

 

[soandos]

any prime

 

[yasiru89]

any prime

I still don't get over what exactly that summation for [itex]S[/tex] is done. A clarification please?

 

[mhill]

o sorry.. i should have written


[tex] S= \sum_{n=1}^{N}e( \frac{f(n)}{p}) [/tex]


the sum is taken over 'n' but if the prime 'p' divides f(n) then the complex exponential is equal to '1'

 

[yasiru89]

Okay then [itex]p[/tex] is a prime of one's choosing.

We have,

[tex]S = \sum_{n = 1}^{N} \exp{\left(\frac{2\pi i}{p}f(n)\right)}[/tex]

Then,
[tex]\Re(S) = \sum_{n = 1}^{N} \cos{\left(\frac{2\pi}{p}f(n)\right)}[/tex]

If [itex]f(n)[/tex] is a multiple of [itex]p[/tex], then the the real part of [itex]S[/tex] will 'count' each solution of that congruence, but what about certain [itex]f(n)[/tex] values that don't and hence give rise to non-zero real and imaginary components? They won't be 1 in a single go, but they can possibly accumulate to values greater than 1 I think. So some bounds for such a theorem also become necessary if I haven't missed anything.