The second exercise in "Statistical Independence in Probability, Analysis and Number Theory," by Mark Kac is to prove that $$ {\sin x\over x}=\prod_{k=1}^{\infty}\frac13\left(1+2\cos{2x\over3^k}\right)\tag{1} $$ and generalize it. This is a generalization of Vieta's formula $$ {\sin x\over x}=\prod_{k=1}^{\infty}\cos{x\over 2^k}\tag{2} $$ which is proved in the text.
It's not hard to prove $(1)$. You just write $\sin x = \sin({x\over3}+{2x\over3})$ and plug away, but I'm having trouble seeing what the generalization is supposed to be. The only thing I've been able to come up with for the next case is $$ {\sin x\over x}=\prod_{k=1}^{\infty} \frac12\left(\cos{x\over4^k}+\cos{3x\over4^k}\right)\tag{3} $$ Again, this isn't hard to prove, but I'm having trouble seeing a pattern in $(1),\ (2),\ \text{and } (3).$ To derive $(3)$ I used the triple angle formula for cosine, and it seems to me that as you go forward you'll need multiple angle formulas for increasing large multiples, so I foresee a lot of complication.
Can you see a formula for the $n=4$ case that is more clearly a generalization of $(1)$ than $(3)$ is? Or do you know what generalization Kac had in mind? I'm assuming that he intends for you to come up with a formula for general $n$.
