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Necessary and Sufficient Conditions for a Subset of a Normed Space to be Bounded 📂Banach Space

Necessary and Sufficient Conditions for a Subset of a Normed Space to be Bounded

Definition

Diameter

Given a normed space $(X, \left\| \cdot \right\|)$, the diameter $\diam M$ of a non-empty subset $M \subset X$ is defined as follows. $$ \diam M =: \sup\limits_{x, y \in M} \left\| x - y \right\| $$

Bounded

If $\diam M \lt \infty$ is satisfied, then $M$ is said to be bounded.

Explanation

In a normed space, since the metric can be naturally induced as $d (x, y) =: \left\| x - y \right\|$, the above definition is, speaking in terms of metric spaces, as follows.

$$ \diam M =: \sup\limits_{x, y \in M} d(x, y) $$

From the following theorem, it can be understood that a subset of a normed space being bounded means that the set of norms of the elements is bounded.

Theorem

The necessary and sufficient condition for a subset $M \subset X$ of a normed space $X$ to be bounded is the existence of a positive number $c \gt 0$ such that for all $x \in M$, $\left\| x \right\| \le c$ holds.

Proof

$\text{\textcircled 1} \Longrightarrow \text{\textcircled 2}$

Assume that $M \subset X$ is bounded. That is, the following holds for some $C > 0$.

$$ \sup\limits_{x, y \in M} \left\| x - y \right\| \lt C \tag{1} $$

For a fixed $y \in M$, let $c$ be $c = C + \left\| y\right\|$. Then for all $x \in M$, the following holds.

$$ \begin{align*} \left\| x \right\| &= \left\| x - y + y \right\| \\ &\le \left\| x - y \right\| + \left \| y \right\| & \text{by triangle inequality} \\ &\lt C + \left\| y \right\| & \text{by } (1) \\ &= c \end{align*} $$

$\text{\textcircled 1} \Longleftarrow \text{\textcircled 2}$

Suppose a positive number $c \gt 0$ satisfies $\left\| x \right\| \le c$ for all $x \in M$. Then for all $x, y \in M$, $\left\| x \right\| + \left\| y \right\| \le 2c$ holds. Since $\left\| x - y \right\| \le \left\| x \right\| + \left\| y \right\|$,

$$ \sup \limits_{x, y \in M} \left\| x - y \right\| \lt \infty $$