When S is convex and closed and X is a Banach Space, then yes. Condition (2) is known as being in the "core" or "algebraic interior" of the set. There's a simple Baire Category Theorem ...

Choose a \delta which works in equation (2) for \epsilon_0=\frac{\epsilon}{3}>0. Then, by (1) (uniform convergence) we have an N such that |f_n(x)-f(x)|<\varepsilon and |f_n(y)-f(y)|<\varepsilon ...

Your proof has several potentially false inequalities. For example, suppose x_n = \pi + \frac{5}{n} and y_n = \pi for all n. Is it true that x_n < \left|\frac{1}{n} + y_n\right|? Is it true ...

I added the variance-decomposition tag to your question. Here is part of its tag wiki : One common method is to add regressors to the model one by one and record the increase in R^2 as each ...

There is a problem: you divide by y_n, and it is not guaranteed that y_n\ne0 for all n large enough if L=0. So it is better to use this definition of equivalent sequences, which requires no ...

I don't see logical flaws or gaps. Just small things: at the beginning there should be P ⊆ \{\frac{m}{n}: m ∈ ℤ\} instead of equality, and maybe add brackets: α = \inf\bigl(P ∩ (\frac mn, \frac {m + 1}n)\bigr) ...