Metric map

The composite of metric maps is also metric map, and the identity map id_M : M → M on a metric space M is a metric map. Thus metric spaces together with metric maps form a category Met. Met is a subcategory of the category of metric spaces and Lipschitz functions. A map ƒ between metric spaces is an isometry if and only if it is a bijective metric map whose inverse is also a metric map. Thus the isomorphisms in Met are precisely the isometries.

One can say that ƒ is strictly metric if the inequality is strict for every two different points. Thus a contraction mapping is strictly metric, but not necessarily the other way around. Note that an isometry is never strictly metric, except in the degenerate case of the empty space or a single-point space.

A mapping ${\displaystyle T:X\to {\mathcal {N}}(X)}$ from a metric space X to the family of nonempty subsets of X is said to be Lipschitz if there exists ${\displaystyle L\geq 0}$ such that

${\displaystyle H(Tx,Ty)\leq Ld(x,y),}$

for all ${\displaystyle x,y\in X}$, where H is the Hausdorff distance. When ${\displaystyle L=1}$, T is called nonexpansive and when ${\displaystyle L<1}$, T is called a contraction.

• Stretch factor
• Subcontraction map

• Isbell, J. R. (1964). "Six theorems about injective metric spaces". Comment. Math. Helv. 39: 65–76. doi:10.1007/BF02566944.