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Definition

In analysis, uniform convergence refers to a type of convergence of sequences $(f_n)_{n \in \mathbb{N}}$ of functions $f_n \colon X \to \mathbb{R}$ into the real numbers. In terms of epsilontic analysis such a sequence converges uniformly to some function $f \colon X \to \mathbb{R}$ if for each positive real number $\epsilon \gt 0$ there exists a natural number $N_\epsilon \in \mathbb{N}$ such that if $n \geq N(\epsilon)$ then for all points $x \in X$ the difference (in absolute value) between the value of $f_n$ at that point and that of $f$ at that point is smaller than $\epsilon$:

What is uniform about this convergence is that the bound $N(\epsilon)$ is required to work for all $x \in X$ (hence uniformly over $x$). This is in contrast to pointwise convergence where one allows a different bound $N$ to exist for each $\epsilon$ and each point $x \in X$ separately. Since for non-finite $X$ the maximum of all such local choices of $N$ in general does not exist, uniform convergence is a stronger condition than pointwise convergence.

Examples

(e.g. Gamelin-Greene 83, theorem I 2.5 and II 3.5)

Related concepts

• pointwise convergence

• uniformly continuous map

• uniform property

• topology of uniform convergence

References

• Wikipedia, Uniform convergence

References

• Theodore Gamelin, Robert Greene, Introduction to Topology, Dover (1983, 199)