For $n > 1$ an integer, there are well-known formulas for volume of the balls.
What is the analogous statement in a Banach space/Hilbert Space?
For $n > 1$ an integer, there are well-known formulas for volume of the balls.
What is the analogous statement in a Banach space/Hilbert Space?
A finite measure $\mu$ on a separable complete metric space has the property of tightness; i.e. for any $\epsilon > 0$ there is some compact subset $K$ so that $\mu(K^c) < \epsilon$. A Banach space that is locally compact is necessarily finite dimensional. Hence, a compact subset is a very small subset that must have a void interior.
In an infinite-dimensional normed space with a translation-invariant measure, the measure of a ball must be either $0$ or $\infty$. This fact is sometimes summarized as "there is no infinite-dimensional Lebesgue measure." So unless you have some other notion of "volume" in mind, only the finite-dimensional case (i.e. $\mathbb{R}^n$ with some other norm) has any content. And with regard to Hilbert spaces, the only finite-dimensional Hilbert spaces are $\mathbb{R}^n$ with the Euclidean inner product, so of course we know about this.
Maybe this is helpful, a formula for the volume of Lp balls in R^n.