Link (simplicial complex) explained

The link in a simplicial complex is a generalization of the neighborhood of a vertex in a graph. The link of a vertex encodes information about the local structure of the complex at the vertex.

Link of a vertex

Given an abstract simplicial complex and v a vertex in V(X), its link \operatorname(v,X) is a set containing every face \tau \in X such that v\not\in \tau and \tau\cup \ is a face of .

Given a geometric simplicial complex and v\in V(X), its link \operatorname(v,X) is a set containing every face \tau \in X such that v\not\in \tau and there is a simplex in X that has v as a vertex and \tau as a face. Equivalently, the join v \star \tau is a face in X.[1]

An alternative definition is: the link of a vertex v\in V(X) is the graph constructed as follows. The vertices of are the edges of incident to . Two such edges are adjacent in iff they are incident to a common 2-cell at .

Link of a face

The definition of a link can be extended from a single vertex to any face.

Given an abstract simplicial complex and any face \sigma of, its link \operatorname(\sigma,X) is a set containing every face \tau \in X such that \sigma, \tau are disjoint and \tau\cup \sigma is a face of : \operatorname(\sigma,X) := \.

Given a geometric simplicial complex and any face \sigma \in X, its link \operatorname(\sigma,X) is a set containing every face \tau \in X such that \sigma, \tau are disjoint and there is a simplex in X that has both \sigma and \tau as faces.

Examples

The link of a vertex of a tetrahedron is a triangle – the three vertices of the link corresponds to the three edges incident to the vertex, and the three edges of the link correspond to the faces incident to the vertex. In this example, the link can be visualized by cutting off the vertex with a plane; formally, intersecting the tetrahedron with a plane near the vertex – the resulting cross-section is the link.

Another example is illustrated below. There is a two-dimensional simplicial complex. At the left, a vertex is marked in yellow. At the right, the link of that vertex is marked in green.

Properties

X\sigma:=\{\rho\inXsuchthat\sigma\subseteq\rho\}

: every \tau\in \operatorname(\sigma,X) corresponds to \tau \cup \sigma, which is in

X\sigma

.

Link and star

A concept closely related to the link is the star.

Given an abstract simplicial complex and any face \sigma \in X,V(X), its star \operatorname(\sigma,X) is a set containing every face \tau \in X such that \tau\cup \sigma is a face of . In the special case in which is a 1-dimensional complex (that is: a graph), \operatorname(v,X) contains all edges \ for all vertices u that are neighbors of v. That is, it is a graph-theoretic star centered at u.

Given a geometric simplicial complex and any face \sigma \in X, its star \operatorname(\sigma,X) is a set containing every face \tau \in X such that there is a simplex in X having both \sigma and \tau as faces: \operatorname(\sigma,X) := \. In other words, it is the closure of the set \ -- the set of simplices having \sigma as a face.

So the link is a subset of the star. The star and link are related as follows:

An example is illustrated below. There is a two-dimensional simplicial complex. At the left, a vertex is marked in yellow. At the right, the star of that vertex is marked in green.

See also

Notes and References

  1. Book: Colin P.. Rourke . Colin P. Rourke. Brian J.. Sanderson . Introduction to Piecewise-Linear Topology . 1972 . en . 10.1007/978-3-642-81735-9. 978-3-540-11102-3 .