\sin\theta=\frac{\sqrt3}2=\sin\frac\pi3\implies\theta=n\pi+(-1)^n\frac\pi3 where n is any integer Set n=2s+1,(odd) =2s(even) one by one Again, \cos\theta=-\frac12=-\cos\frac\pi3=\cos\left(\pi-\frac\pi3\right) ...

The so-called delta-method stems from two basic results: By the usual CLT, \sqrt{n}(\bar X_n-\theta)\to\sigma_\theta Z in distribution, where Z is standard normal and \sigma_\theta^2=\mathrm{var}(X_1) ...

I give here both if part and only if part. Let \{\overrightarrow a_k\}_k converges to \overrightarrow a in R^n . Then using norm ||.|| of R^n we can say that given any \epsilon > 0 ...

This is a very interesting problem. Throughout this proof, let \rho(x,z)=\sum_{n=1}^{x}(-1)^{\left\lfloor\frac{n}{\varphi}+z\right\rfloor}, where x \in \mathbb{N} and z\in \mathbb{R} , ...

Let \hat{\beta}=\frac{1-\hat \theta}{\sqrt{3n}}. Then as you have shown E\hat{\beta}=\frac{1-\theta}{\sqrt{3n}}. Hence \hat{\beta} is an unbiased estimator of \frac{1-\theta}{\sqrt{3n}} ...

No. If \varphi = (\sqrt{5}+1)/2 (which is a root of x^2 - x - 1) and F_n are the Fibonacci numbers, |F_n - \varphi F_{n-1}| goes to 0 exponentially. Take a_n = F_{n+k} for sufficiently ...