Some properties of the distribution of the numbers of points on elliptic curves over a finite prime field

Abstract: Let $p \geq 5$ be a prime and for $a, b \in \mathbb{F}{p}$, let $E{a,b}$ denote the elliptic curve over $\mathbb{F}{p}$ with equation $y^2=x^3+a\,x + b$. As usual define the trace of Frobenius $a{p,\,a,\,b}$ by \begin{equation*} #E_{a,b}(\mathbb{F}{p}) = p+1 -a{p,\,a,\,b}. \end{equation*} We use elementary facts about exponential sums and known results about binary quadratic forms over finite fields to evaluate the sums $\sum_{t\in\mathbb{F}{p}} a{p,\, t,\, b}$, $\sum {t \in \mathbb{F}{p}} a_{p,\,a,\, t}$, $ \sum_{t=0}^{p-1}a_{p,\,t,\,b}^{2}$, $ \sum_{t=0}^{p-1}a_{p,\,a,\,t}^{2}$ and $ \sum_{t=0}^{p-1}a_{p,\,t,\,b}^{3}$ for primes $p$ in various congruence classes. As an example of our results, we prove the following: Let $p \equiv 5$ $($mod 6$)$ be prime and let $b \in \mathbb{F}{p}^{*}$. Then \begin{equation*} \sum{t=0}^{p-1}a_{p,\,t,\,b}^{3}= -p\left((p-2)\left(\frac{-2}{p}\right) +2p\right)\left(\frac{b}{p}\right). \end{equation*}