Also if $a_k, b_k >0, 0<m\le \frac{a_k}{b_k} \le M<\infty, k=1,..n$ and $A=\frac{m+M}{2}, G=\sqrt{mM}$, then we have a reverse to Cauchy-Schwarz given by: $(\Sigma{a_k}^2)(\Sigma{b_k}^2) \le (\frac{A}{G}\Sigma{a_kb_k})^2=\frac{A^2}{G^2}(\Sigma{a_kb_k})^2$ which follows from the trivial inequality $(M-\frac{a_k}{b_k})(\frac{a_k}{b_k}-m) \ge 0, k=1,...n$ by the usual manipulations (sum and the AG means inequality). Applying this for $\sqrt{a_k}, \frac{1}{\sqrt{a_k}}$ we recover indeed the inequality given in the earlier answer