In mathematics, particularly topology, one describes a manifold using an **atlas**. An atlas consists of individual *charts* that, roughly speaking, describe individual regions of the manifold. If the manifold is the surface of the Earth, then an atlas has its more common meaning. In general, the notion of atlas underlies the formal definition of a manifold and related structures such as vector bundles and other fiber bundles.

"Coordinate patch" redirects here. Not to be confused with Surface patch. |

See also: Topological manifold § Coordinate charts |

The definition of an atlas depends on the notion of a *chart*. A **chart** for a topological space *M* (also called a **coordinate chart**, **coordinate patch**, **coordinate map**, or **local frame**) is a homeomorphism from an open subset *U* of *M* to an open subset of a Euclidean space. The chart is traditionally recorded as the ordered pair .

An **atlas** for a topological space is an indexed family of charts on which covers (that is, ). If the codomain of each chart is the *n*-dimensional Euclidean space, then is said to be an *n*-dimensional manifold.

The plural of atlas is *atlases*, although some authors use *atlantes*.^{[1]}^{[2]}

An atlas on an -dimensional manifold is called an **adequate atlas** if the image of each chart is either or , is a locally finite open cover of , and , where is the open ball of radius 1 centered at the origin and is the closed half space. Every second-countable manifold admits an adequate atlas.^{[3]} Moreover, if is an open covering of the second-countable manifold then there is an adequate atlas on such that is a refinement of .^{[3]}

A transition map provides a way of comparing two charts of an atlas. To make this comparison, we consider the composition of one chart with the inverse of the other. This composition is not well-defined unless we restrict both charts to the intersection of their domains of definition. (For example, if we have a chart of Europe and a chart of Russia, then we can compare these two charts on their overlap, namely the European part of Russia.)

To be more precise, suppose that and are two charts for a manifold *M* such that is non-empty.
The **transition map** is the map defined by

Note that since and are both homeomorphisms, the transition map is also a homeomorphism.

One often desires more structure on a manifold than simply the topological structure. For example, if one would like an unambiguous notion of differentiation of functions on a manifold, then it is necessary to construct an atlas whose transition functions are differentiable. Such a manifold is called differentiable. Given a differentiable manifold, one can unambiguously define the notion of tangent vectors and then directional derivatives.

If each transition function is a smooth map, then the atlas is called a smooth atlas, and the manifold itself is called smooth. Alternatively, one could require that the transition maps have only *k* continuous derivatives in which case the atlas is said to be .

Very generally, if each transition function belongs to a pseudogroup of homeomorphisms of Euclidean space, then the atlas is called a -atlas. If the transition maps between charts of an atlas preserve a local trivialization, then the atlas defines the structure of a fibre bundle.