It's known that $$S_2={2\over\pi} = {\sqrt{2}\over 2}{\sqrt{2+\sqrt{2}}\over 2}{\sqrt{2+\sqrt{2+\sqrt{2}}}\over 2}\dots$$ The terms in the product approaches 1, the same holds for the following convergent series, with $\phi$ the golden ratio $$S_1 = {\sqrt{1}\over\phi}{\sqrt{1+\sqrt{1}}\over\phi}{\sqrt{1+\sqrt{1+\sqrt{1}}}\over\phi}\dots$$ Let $$S_n = {\sqrt{n}\over c_n}{\sqrt{n+\sqrt{n}}\over c_n}\dots$$ Where $c_n$ is the solution to the equation $x=\sqrt{n+x}$ Is there a simpler formula for $S_n$? What is the asymptotic behavior (Big-O) of $S_n$ as $n->\infty$?