Disjoint union (topology)

Definition

Let {X_i : i ∈ I} be a family of topological spaces indexed by I. Let

be the disjoint union of the underlying sets. For each i in I, let

be the canonical injection (defined by φ i ( x ) = ( x , i ) ). The disjoint union topology on X is defined as the finest topology on X for which the canonical injections {φ_i} are continuous.

Explicitly, the disjoint union topology can be described as follows. A subset U of X is open in X if and only if its preimage φ i − 1 ( U ) is open in X_i for each i ∈ I.

Yet another formulation is that a subset V of X is open relative to X iff its intersection with X_i is open relative to X_i for each i.

Properties

The disjoint union space X, together with the canonical injections, can be characterized by the following universal property: If Y is a topological space, and f_i : X_i → Y is a continuous map for each i ∈ I, then there exists precisely one continuous map f : X → Y such that the following set of diagrams commute:

This shows that the disjoint union is the coproduct in the category of topological spaces. It follows from the above universal property that a map f : X → Y is continuous iff f_i = f o φ_i is continuous for all i in I.

In addition to being continuous, the canonical injections φ_i : X_i → X are open and closed maps. It follows that the injections are topological embeddings so that each X_i may be canonically thought of as a subspace of X.

Examples

If each X_i is homeomorphic to a fixed space A, then the disjoint union X will be homeomorphic to A × I where I is given the discrete topology.

Preservation of topological properties