Deletion–contraction formula
In graph theory, a deletion-contraction formula / recursion is any formula of the following recursive form:
- [math]\displaystyle{ f(G) = f(G \setminus e) + f(G / e). }[/math]
Here G is a graph, f is a function on graphs, e is any edge of G, G \ e denotes edge deletion, and G / e denotes contraction. Tutte refers to such a function as a W-function.[1] The formula is sometimes referred to as the fundamental reduction theorem.[2] In this article we abbreviate to DC.
R. M. Foster had already observed that the chromatic polynomial is one such function, and Tutte began to discover more, including a function f = t(G) counting the number of spanning trees of a graph (also see Kirchhoff's theorem). It was later found that the flow polynomial is yet another; and soon Tutte discovered an entire class of functions called Tutte polynomials (originally referred to as dichromates) that satisfy DC.[1]
Examples
Spanning trees
The number of spanning trees [math]\displaystyle{ t(G) }[/math] satisfies DC.[3]
Proof. [math]\displaystyle{ t(G \setminus e) }[/math] denotes the number of spanning trees not including e, whereas [math]\displaystyle{ t(G/e) }[/math] the number including e. To see the second, if T is a spanning tree of G then contracting e produces another spanning tree of [math]\displaystyle{ G/e }[/math]. Conversely, if we have a spanning tree T of [math]\displaystyle{ G/e }[/math], then expanding the edge e gives two disconnected trees; adding e connects the two and gives a spanning tree of G.
Chromatic polynomials
The chromatic polynomial [math]\displaystyle{ \chi_G(k) }[/math] counting the number of k-colorings of G does not satisfy DC, but a slightly modified formula (which can be made equivalent):[1]
- [math]\displaystyle{ \chi_G(k) = \chi_{G\setminus e}(k) - \chi_{G / e}(k). }[/math]
Proof. If e = uv, then a k-coloring of G is the same as a k-coloring of G \ e where u and v have different colors. There are [math]\displaystyle{ \chi_{G\setminus e}(k) }[/math] total G \ e colorings. We need now subtract the ones where u and v are colored similarly. But such colorings correspond to the k-colorings of [math]\displaystyle{ \chi_{G/e}(k) }[/math] where u and v are merged.
This above property can be used to show that the chromatic polynomial [math]\displaystyle{ \chi_G(k) }[/math] is indeed a polynomial in k. We can do this via induction on the number of edges and noting that in the base case where there are no edges, there are [math]\displaystyle{ k^{|V(G)|} }[/math] possible colorings (which is a polynomial in k).
Deletion-contraction algorithm
See also
- Inclusion–exclusion principle
- Tutte polynomial
- Chromatic polynomial
- Nowhere-zero flow
Citations
- ↑ 1.0 1.1 1.2 Tutte, W.T. (January 2004). "Graph-polynomials". Advances in Applied Mathematics 32 (1–2): 5–9. doi:10.1016/S0196-8858(03)00041-1.
- ↑ (Dong Koh)
- ↑ "Deletion-contraction and chromatic polynomials". https://www.math.wisc.edu/~svs/475/chromatic.pdf.
Works cited
- Dong, F M; Koh, K M; Teo, K L (June 2005) (in en). Chromatic Polynomials and Chromaticity of Graphs. World Scientific. doi:10.1142/5814. ISBN 978-981-256-317-0.
 |  |
