Definition

(uniform continuous map between uniform spaces)

Let $X$ and $Y$ be uniform spaces, each defined as a set equipped with a collection of entourages. A uniformly continuous map from $X$ to $Y$ is a function between their underlying sets such that, given any entourage $E$ on $Y$, there is an entourage $D$ on $X$ such that $f(a)$ and $f(b)$ are $E$-close in $Y$ whenever $a$ and $b$ are $D$-close in $X$:

Definition

(uniformly continuous map between quasiuniform spaces)

The definition in terms of entourages extends immediately to quasiuniform spaces, in which case we may speak of quasiuniformly continuous maps since some authors use ‘uniformly continuous’ for a map which is uniformly continuous between the spaces' symmetrisations.

Definition

(antiuniformly continuous map)

An antiuniformly continuous map, is defined as a uniform map, but such that the order in which the points are compared is reversed:

Definition

(uniformly continuous map between metric spaces)

Given metric spaces $X$ and $Y$, a uniformly continuous map from $X$ to $Y$ is a function $f\colon X\to Y$ between their underlying sets such that, given any positive real number $\epsilon$, there is a positive number $\delta$ such that the distance in $Y$ between $f(a)$ and $f(b)$ is less than $\epsilon$ whenever the distance in $X$ between $a$ and $b$ is less than $\delta$:

Again, this is exactly like the definition of continuous map between metric spaces, except for the order of the quantifiers $\exists\, \delta$ and $\forall\, a$.

Definition

(uniformly continuous map between Archimedean fields)

Given Archimedean fields $X$ and $Y$, a uniformly continuous map from $X$ to $Y$ is a function between their underlying sets such that, given any positive element $\epsilon \gt 0$, there is a positive element $\delta \gt 0$ such that the maximum of $f(a) - f(b)$ and $f(b) - f(a)$ is less than $\epsilon$ whenever the maximum of $a - b$ and $b - a$ is less than $\delta$:

Again, this is exactly like the definition of continuous map between Archimedean fields, except for the order of the quantifiers $\exists\, \delta$ and $\forall\, a$.

Definition

A uniform homeomorphism is a uniformly continuous bijection whose inverse is also uniformly continuous (which is not automatic). Two (quasi)uniform spaces are uniformly homeomorphic if there exists a uniform homeomorphism between them. We may also speak of antiuniform homeomorphisms between antiuniformly homeomorphic quasiuniform spaces.

Definition

Let $\mathrm{R}_+ \coloneqq \sum_{x:\mathbb{R}} \epsilon \gt 0$ denote the positive real numbers. Given metric spaces $(X, d_X)$ and $(Y, d_Y)$, a uniformly continuous function between $X$ and $Y$ is a function $f:X \to Y$ between their underlying sets with a dependent function which says:

Given any positive real number $\epsilon \gt 0$, there is as structure a positive real number $\delta \gt 0$ such that for all elements $a:X$ and $b:X$, $\delta_Y(f(a), f(b))$ is less than $\epsilon$ whenever $\delta_X(a, b)$ is less than $\delta$

By the type theoretic axiom of choice, which is simply the distributivity of dependent function types over dependent sum types, this is the same as saying that

There exists as structure a function on the positive real numbers $\omega:\mathrm{R}_+ \to \mathrm{R}_+$ such that for all positive real numbers $\epsilon \gt 0$ and for all elements $a:X$ and $b:X$, $\delta_Y(f(a), f(b))$ is less than $\epsilon$ whenever $\delta_X(a, b)$ is less than $\omega(\epsilon)$

Definition

Given uniform spaces $(X, \mathcal{U}(X), \approx)$ and $(Y, \mathcal{U}(Y), \approx)$, a uniformly continuous function between $X$ and $Y$ is a function $f:X \to Y$ with a dependent function which says:

Given any entourage $E:\mathcal{U}(Y)$, there is as structure an entourage $D:\mathcal{U}(X)$ such that for all elements $a:X$ and $b:X$, $f(a) \approx_{E} f(b)$ whenever $a \approx_{D} b$

By the type theoretic axiom of choice, which is simply the distributivity of dependent function types over dependent sum types, this is the same as saying that

There exists as structure a function $\omega:\mathcal{U}(Y) \to \mathcal{U}(X)$ between the sets of entourages such that for all entourages $E:\mathcal{U}(Y)$ and for all elements $a:X$ and $b:X$, $f(a) \approx_{E} f(b)$ whenever $a \approx_{\omega(E)} b$