In what follows I will assume that $p$ is an odd prime. Let $\zeta$ be a primitive $p$-th root of unity and denote its conjugates by $\zeta_1,\ldots,\zeta_{p-1}$, so we have $\Phi_p(X) = \frac{X^p-1}{X-1} = \prod_{i=1}^{p-1} (X-\zeta_i).$ The discriminant of $\Phi_p$ then can be computed as $\Delta = \prod_{i Note that $\Phi_p'(X) = \sum_i \prod_{j\neq i} (X-\zeta_j),$ so $\prod_{i\neq j} (\zeta_i - \zeta_j) = \prod_i \Phi_p'(\zeta_i) = N_{\mathbb Q(\zeta)/\mathbb Q}(\Phi_p'(\zeta)).$ To compute this norm, we take the derivative on both sides of $(X-1)\Phi_p(X) = X^p-1,$ plug in $\zeta$ and take norms to get $N(\zeta-1) N(\Phi_p'(\zeta)) = N(p \zeta^{-1}) = p^{p-1}.$ The norm $N(\zeta-1)$ is given by $N(\zeta-1) = \prod_i (\zeta_i - 1) = \prod_i (1 -\zeta_i) = p$ as we see by setting $X = 1$ in $\Phi_p(X) = \prod_i (X-\zeta_i) = 1 + X + \ldots + X^{p-1}.$ Altogether, this shows $\Delta = (-1)^{(p-1)/2} p^{p-2}.$