Open-circuit time constant method

In functional analysis, a branch of mathematics, the Goldstine theorem, named after Herman Goldstine, asserts that the image of the closed unit ball $B_{X}$ of a Banach space $X$ under the canonical imbedding into the closed unit ball $B_{X^{* *}}$ of the bidual space $X^{* *}$ is weakly*-dense.

The conclusion of the theorem is not true for the norm topology, which can be seen by considering the Banach space of real sequences that converge to zero c₀, and its bi-dual space ℓ_∞.

Proof

Given an $x^{* *} \in B_{X^{* *}}$ , a tuple $(ϕ_{1}, \dots, ϕ_{n})$ of linearly independent elements of $X^{*}$ and a $δ > 0$ we shall find an $x \in (1 + δ) B_{X}$ such that $ϕ_{i} (x) = x^{* *} (ϕ_{i})$ for every $i = 1, \dots, n$ .

If the requirement $‖ x ‖ \leq 1 + δ$ is dropped, the existence of such an $x$ follows from the surjectivity of

Φ : X \to ℂ^{n}, x \mapsto (ϕ_{1} (x), \dots, ϕ_{n} (x)) .

Let now $Y : = ⋂_{i} \ker ϕ_{i} = \ker Φ$ . Every element of $(x + Y) \cap (1 + δ) B_{X}$ has the required property, so that it suffices to show that the latter set is not empty.

Assume that it is empty. Then $d i s t (x, Y) \geq 1 + δ$ and by the Hahn-Banach theorem there exists a linear form $ϕ \in X^{*}$ such that $ϕ |_{Y} = 0$ , $ϕ (x) \geq 1 + δ$ and $‖ ϕ ‖_{X^{*}} = 1$ . Then $ϕ \in s p a n (ϕ_{1}, \dots, ϕ_{n})$ and therefore

1 + δ \leq ϕ (x) = x^{* *} (ϕ) \leq ‖ ϕ ‖_{X^{*}} ‖ x^{* *} ‖_{X^{* *}} \leq 1,

which is a contradiction.

Open-circuit time constant method

Proof

See also

Navigation menu

Open-circuit time constant method

Proof

See also

Navigation menu

Search