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Line 59: The notion of "bounded set" for a topological vector space is that of being a [[Bounded set (topological vector space)\|von Neumann bounded set]]. If the space happens to also be a [[normed space]] (or a [[seminormed space]]), such as the scalar field with the [[absolute value]] for instance, then a subset <math>S</math> is von Neumann bounded if and only if it is [[Norm (mathematics)\|norm]] bounded; that is, if and only if <math>\sup_{s \in S} \\|s\\| < \infty.</math> If <math>S \subseteq X</math> is a set then <math>F : X \to Y</math> is said to be {{em\|bounded on <math>S</math>}} if <math>F(S)</math> is a [[Bounded set (topological vector space)\|bounded subset]] of <math>Y,</math> ~~and~~which itif <math>(Y, \\|\cdot\\|)</math> is ~~said~~a tonormed be(or ~~{{em\|unbounded~~seminormed) onspace happens if and only if <math>\sup_{s \in S} \\|F(s)\\| < \infty.</math>~~}} otherwise.~~ ~~If <math>(Y, \\|\cdot\\|)</math> is a normed (or seminormed) space then <math>F</math> is bounded on <math>S</math> if and only if <math>\sup_{s \in S} \\|F(s)\\| < \infty.</math>~~ A linear map <math>F</math> is bounded on a set <math>S</math> if and only if it is bounded on <math>x + S</math> for every <math>x \in X</math> (because <math>F(x + S) = F(x) + F(S)</math>).

Continuous linear operator: Difference between revisions