Nerve complex

In topology, the nerve complex of a set family is an abstract complex that records the pattern of intersections between the sets in the family. It was introduced by Pavel Alexandrov^[1] and now has many variants and generalisations, among them the Čech nerve of a cover, which in turn is generalised by hypercoverings. It captures many of the interesting topological properties in an algorithmic or combinatorial way.^[2]

Basic definition

Let $I$ be a set of indices and $C$ be a family of sets $(U_{i})_{i\in I}$ . The nerve of $C$ is a set of finite subsets of the index set $I$ . It contains all finite subsets $J\subseteq I$ such that the intersection of the $U_{i}$ whose subindices are in $J$ is non-empty:^[3]^: 81

N(C):={\bigg \{}J\subseteq I:\bigcap _{j\in J}U_{j}\neq \varnothing ,J{\text{ finite set}}{\bigg \}}.

In Alexandrov's original definition, the sets $(U_{i})_{i\in I}$ are open subsets of some topological space $X$ .

The set $N(C)$ may contain singletons (elements $i\in I$ such that $U_{i}$ is non-empty), pairs (pairs of elements $i,j\in I$ such that $U_{i}\cap U_{j}\neq \emptyset$ ), triplets, and so on. If $J\in N(C)$ , then any subset of $J$ is also in $N(C)$ , making $N(C)$ an abstract simplicial complex. Hence N(C) is often called the nerve complex of $C$ .

Examples

Let X be the circle $S^{1}$ and $C=\{U_{1},U_{2}\}$ , where $U_{1}$ is an arc covering the upper half of $S^{1}$ and $U_{2}$ is an arc covering its lower half, with some overlap at both sides (they must overlap at both sides in order to cover all of $S^{1}$ ). Then $N(C)=\{\{1\},\{2\},\{1,2\}\}$ , which is an abstract 1-simplex.
Let X be the circle $S^{1}$ and $C=\{U_{1},U_{2},U_{3}\}$ , where each $U_{i}$ is an arc covering one third of $S^{1}$ , with some overlap with the adjacent $U_{i}$ . Then $N(C)=\{\{1\},\{2\},\{3\},\{1,2\},\{2,3\},\{3,1\}\}$ . Note that {1,2,3} is not in $N(C)$ since the common intersection of all three sets is empty; so $N(C)$ is an unfilled triangle.

The Čech nerve

Given an open cover $C=\{U_{i}:i\in I\}$ of a topological space $X$ , or more generally a cover in a site, we can consider the pairwise fibre products $U_{ij}=U_{i}\times _{X}U_{j}$ , which in the case of a topological space are precisely the intersections $U_{i}\cap U_{j}$ . The collection of all such intersections can be referred to as $C\times _{X}C$ and the triple intersections as $C\times _{X}C\times _{X}C$ .

By considering the natural maps $U_{ij}\to U_{i}$ and $U_{i}\to U_{ii}$ , we can construct a simplicial object $S(C)_{\bullet }$ defined by $S(C)_{n}=C\times _{X}\cdots \times _{X}C$ , n-fold fibre product. This is the Čech nerve.^[4]

By taking connected components we get a simplicial set, which we can realise topologically: $|S(\pi _{0}(C))|$ .

Nerve theorems

The nerve complex $N(C)$ is a simple combinatorial object. Often, it is much simpler than the underlying topological space (the union of the sets in $C$ ). Therefore, a natural question is whether the topology of $N(C)$ is equivalent to the topology of $\bigcup C$ .

In general, this need not be the case. For example, one can cover any n-sphere with two contractible sets $U_{1}$ and $U_{2}$ that have a non-empty intersection, as in example 1 above. In this case, $N(C)$ is an abstract 1-simplex, which is similar to a line but not to a sphere.

However, in some cases $N(C)$ does reflect the topology of X. For example, if a circle is covered by three open arcs, intersecting in pairs as in Example 2 above, then $N(C)$ is a 2-simplex (without its interior) and it is homotopy-equivalent to the original circle.^[5]

A nerve theorem (or nerve lemma) is a theorem that gives sufficient conditions on C guaranteeing that $N(C)$ reflects, in some sense, the topology of $\bigcup C$ . A functorial nerve theorem is a nerve theorem that is functorial in an approriate sense, which is, for example, crucial in topological data analysis.^[6]

Leray's nerve theorem

The basic nerve theorem of Jean Leray says that, if any intersection of sets in $N(C)$ is contractible (equivalently: for each finite $J\subset I$ the set $\bigcap _{i\in J}U_{i}$ is either empty or contractible; equivalently: C is a good open cover), then $N(C)$ is homotopy-equivalent to $\bigcup C$ .

Borsuk's nerve theorem

There is a discrete version, which is attributed to Borsuk.^[7]^[3]^{: 81, Thm.4.4.4} Let K₁,...,K_n be abstract simplicial complexes, and denote their union by K. Let U_i = ||K_i|| = the geometric realization of K_i, and denote the nerve of {U₁, ... , U_n } by N.

If, for each nonempty $J\subset I$ , the intersection $\bigcap _{i\in J}U_{i}$ is either empty or contractible, then N is homotopy-equivalent to K.

A stronger theorem was proved by Anders Bjorner.^[8] if, for each nonempty $J\subset I$ , the intersection $\bigcap _{i\in J}U_{i}$ is either empty or (k-|J|+1)-connected, then for every j ≤ k, the j-th homotopy group of N is isomorphic to the j-th homotopy group of K. In particular, N is k-connected if-and-only-if K is k-connected.

Čech nerve theorem

Another nerve theorem relates to the Čech nerve above: if $X$ is compact and all intersections of sets in C are contractible or empty, then the space $|S(\pi _{0}(C))|$ is homotopy-equivalent to $X$ .^[9]

Homological nerve theorem

The following nerve theorem uses the homology groups of intersections of sets in the cover.^[10] For each finite $J\subset I$ , denote $H_{J,j}:={\tilde {H}}_{j}(\bigcap _{i\in J}U_{i})=$ the j-th reduced homology group of $\bigcap _{i\in J}U_{i}$ .

If H_J,j is the trivial group for all J in the k-skeleton of N(C) and for all j in {0, ..., k-dim(J)}, then N(C) is "homology-equivalent" to X in the following sense:

${\tilde {H}}_{j}(N(C))\cong {\tilde {H}}_{j}(X)$ for all j in {0, ..., k};
if ${\tilde {H}}_{k+1}(N(C))\not \cong 0$ then ${\tilde {H}}_{k+1}(X)\not \cong 0$ .