Difference between revisions of "Graphs of Polynomials"

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In mathematics, a '''graph polynomial''' is a [[Graph property|graph invariant]] whose values are [[polynomial]]s. Invariants of this type are studied in [[algebraic graph theory]].{{r|sdlg}}
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In mathematics, a graph polynomial is a graph invariant whose values are polynomials. Invariants of this type are studied in algebraic graph theory.[1] Important graph polynomials include:
Important graph polynomials include:
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*The [[characteristic polynomial]], based on the graph's [[adjacency matrix]].
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* The characteristic polynomial, based on the graph's adjacency matrix.
*The [[chromatic polynomial]], a polynomial whose values at integer arguments give the number of colorings of the graph with that many colors.
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* The chromatic polynomial, a polynomial whose values at integer arguments give the number of colorings of the graph with that many colors.
*The [[dichromatic polynomial]], a 2-variable generalization of the chromatic polynomial
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* The dichromatic polynomial, a 2-variable generalization of the chromatic polynomial
*The [[flow polynomial]], a polynomial whose values at integer arguments give the number of [[nowhere-zero flow]]s with integer flow amounts modulo the argument.
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* The flow polynomial, a polynomial whose values at integer arguments give the number of nowhere-zero flows with integer flow amounts modulo the argument.
*The (inverse of the) [[Ihara zeta function]], defined as a product of binomial terms corresponding to certain closed walks in a graph.
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* The (inverse of the) Ihara zeta function, defined as a product of binomial terms corresponding to certain closed walks in a graph.
*The [[Martin polynomial]], used by Pierre Martin to study [[Euler tour]]s
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* The Martin polynomial, used by Pierre Martin to study Euler tours
*The [[matching polynomial]]s, several different polynomials defined as the [[generating function]] of the [[Matching (graph theory)|matchings]] of a graph.
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* The matching polynomials, several different polynomials defined as the generating function of the matchings of a graph.
*The [[reliability polynomial]], a polynomial that describes the probability of remaining connected after independent edge failures
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* The reliability polynomial, a polynomial that describes the probability of remaining connected after independent edge failures
*The [[Tutte polynomial]], a polynomial in two variables that can be defined (after a small change of variables) as the generating function of the numbers of connected components of [[induced subgraph]]s of the given graph, parameterized by the number of vertices in the subgraph.
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* The Tutte polynomial, a polynomial in two variables that can be defined (after a small change of variables) as the generating function of the numbers of connected components of induced subgraphs of the given graph, parameterized by the number of vertices in the subgraph.
  
==See also==
 
*[[Knot polynomial]]
 
  
 
==References==
 
==References==
# Shi, Yongtang, et al. Graph Polynomials. CRC Press, Taylor Et Francis Group, 2017.  
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# Shi, Yongtang, et al. Graph Polynomials. CRC Press, Taylor Et Francis Group, 2017.
 
 
[[Category:Polynomials]]
 
[[Category:Graph invariants]]
 
 
 
{{sia}}
 

Revision as of 19:58, 15 September 2021

In mathematics, a graph polynomial is a graph invariant whose values are polynomials. Invariants of this type are studied in algebraic graph theory.[1] Important graph polynomials include:

  • The characteristic polynomial, based on the graph's adjacency matrix.
  • The chromatic polynomial, a polynomial whose values at integer arguments give the number of colorings of the graph with that many colors.
  • The dichromatic polynomial, a 2-variable generalization of the chromatic polynomial
  • The flow polynomial, a polynomial whose values at integer arguments give the number of nowhere-zero flows with integer flow amounts modulo the argument.
  • The (inverse of the) Ihara zeta function, defined as a product of binomial terms corresponding to certain closed walks in a graph.
  • The Martin polynomial, used by Pierre Martin to study Euler tours
  • The matching polynomials, several different polynomials defined as the generating function of the matchings of a graph.
  • The reliability polynomial, a polynomial that describes the probability of remaining connected after independent edge failures
  • The Tutte polynomial, a polynomial in two variables that can be defined (after a small change of variables) as the generating function of the numbers of connected components of induced subgraphs of the given graph, parameterized by the number of vertices in the subgraph.


References

  1. Shi, Yongtang, et al. Graph Polynomials. CRC Press, Taylor Et Francis Group, 2017.