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In graph theory, an independent set, stable set, coclique or anticlique is a set of vertices in a graph, no two of which are adjacent. That is, it is a set S of vertices such that for every two vertices in S, there is no edge connecting the two. Equivalently, each edge in the graph has at most one endpoint in S. The size of an independent set is the number of vertices it contains. Independent sets have also been called internally stable sets.[1]

A maximal independent set is an independent set that is not a proper subset of any other independent set.

A maximum independent set is an independent set of largest possible size for a given graph G. This size is called the independence number of G, and denoted \( {\displaystyle \alpha (G)} \) .[2] The problem of finding such a set is called the maximum independent set problem and is an NP-hard optimization problem. As such, it is unlikely that there exists an efficient algorithm for finding a maximum independent set of a graph.

Every maximum independent set also is maximal, but the converse implication does not necessarily hold.

Properties

Covering/packing-problem pairs
Covering problems Packing problems
Minimum set cover Maximum set packing
Minimum vertex cover Maximum matching
Minimum edge cover Maximum independent set

Relationship to other graph parameters

A set is independent if and only if it is a clique in the graph’s complement, so the two concepts are complementary. In fact, sufficiently large graphs with no large cliques have large independent sets, a theme that is explored in Ramsey theory.

A set is independent if and only if its complement is a vertex cover.[3] Therefore, the sum of the size of the largest independent set \( {\displaystyle \alpha (G)} \) and the size of a minimum vertex cover \( {\displaystyle \beta (G)} \) is equal to the number of vertices in the graph.

A vertex coloring of a graph G corresponds to a partition of its vertex set into independent subsets. Hence the minimal number of colors needed in a vertex coloring, the chromatic number \( \chi (G) \), is at least the quotient of the number of vertices in G and the independent number \( {\displaystyle \alpha (G)}. \)

In a bipartite graph with no isolated vertices, the number of vertices in a maximum independent set equals the number of edges in a minimum edge covering; this is Kőnig's theorem.

Independent set graph

The nine blue vertices form a maximum independent set for the Generalized Petersen graph GP(12,4).

Maximal independent set
Main article: Maximal independent set

An independent set that is not a proper subset of another independent set is called maximal. Such sets are dominating sets. Every graph contains at most 3n/3 maximal independent sets,[4] but many graphs have far fewer. The number of maximal independent sets in n-vertex cycle graphs is given by the Perrin numbers, and the number of maximal independent sets in n-vertex path graphs is given by the Padovan sequence.[5] Therefore, both numbers are proportional to powers of 1.324718..., the plastic number.

Finding independent sets
Further information: Clique problem

In computer science, several computational problems related to independent sets have been studied.

In the maximum independent set problem, the input is an undirected graph, and the output is a maximum independent set in the graph. If there are multiple maximum independent sets, only one need be output. This problem is sometimes referred to as "vertex packing".
In the maximum-weight independent set problem, the input is an undirected graph with weights on its vertices and the output is an independent set with maximum total weight. The maximum independent set problem is the special case in which all weights are one.
In the maximal independent set listing problem, the input is an undirected graph, and the output is a list of all its maximal independent sets. The maximum independent set problem may be solved using as a subroutine an algorithm for the maximal independent set listing problem, because the maximum independent set must be included among all the maximal independent sets.
In the independent set decision problem, the input is an undirected graph and a number k, and the output is a Boolean value: true if the graph contains an independent set of size k, and false otherwise.

The first three of these problems are all important in practical applications; the independent set decision problem is not, but is necessary in order to apply the theory of NP-completeness to problems related to independent sets.
Maximum independent sets and maximum cliques

The independent set problem and the clique problem are complementary: a clique in G is an independent set in the complement graph of G and vice versa. Therefore, many computational results may be applied equally well to either problem. For example, the results related to the clique problem have the following corollaries:

The independent set decision problem is NP-complete, and hence it is not believed that there is an efficient algorithm for solving it.

The maximum independent set problem is NP-hard and it is also hard to approximate.

Despite the close relationship between maximum cliques and maximum independent sets in arbitrary graphs, the independent set and clique problems may be very different when restricted to special classes of graphs. For instance, for sparse graphs (graphs in which the number of edges is at most a constant times the number of vertices in any subgraph), the maximum clique has bounded size and may be found exactly in linear time;[6] however, for the same classes of graphs, or even for the more restricted class of bounded degree graphs, finding the maximum independent set is MAXSNP-complete, implying that, for some constant c (depending on the degree) it is NP-hard to find an approximate solution that comes within a factor of c of the optimum.[7]
Finding maximum independent sets
Further information: Clique problem § Finding maximum cliques in arbitrary graphs
Exact algorithms

The maximum independent set problem is NP-hard. However, it can be solved more efficiently than the O(n2 2n) time that would be given by a naive brute force algorithm that examines every vertex subset and checks whether it is an independent set.

As of 2017 it can be solved in time O(1.1996n) using polynomial space.[8] When restricted to graphs with maximum degree 3, it can be solved in time O(1.0836n).[9]

For many classes of graphs, a maximum weight independent set may be found in polynomial time. Famous examples are claw-free graphs,[10] P5-free graphs[11] and perfect graphs.[12] For chordal graphs, a maximum weight independent set can be found in linear time.[13]

Modular decomposition is a good tool for solving the maximum weight independent set problem; the linear time algorithm on cographs is the basic example for that. Another important tool are clique separators as described by Tarjan.[14]

Kőnig's theorem implies that in a bipartite graph the maximum independent set can be found in polynomial time using a bipartite matching algorithm.

Approximation algorithms

In general, the maximum independent set problem cannot be approximated to a constant factor in polynomial time (unless P = NP). In fact, Max Independent Set in general is Poly-APX-complete, meaning it is as hard as any problem that can be approximated to a polynomial factor.[15] However, there are efficient approximation algorithms for restricted classes of graphs.

In planar graphs, the maximum independent set may be approximated to within any approximation ratio c < 1 in polynomial time; similar polynomial-time approximation schemes exist in any family of graphs closed under taking minors.[16]

In bounded degree graphs, effective approximation algorithms are known with approximation ratios that are constant for a fixed value of the maximum degree; for instance, a greedy algorithm that forms a maximal independent set by, at each step, choosing the minimum degree vertex in the graph and removing its neighbors, achieves an approximation ratio of (Δ+2)/3 on graphs with maximum degree Δ.[17] Approximation hardness bounds for such instances were proven in Berman & Karpinski (1999). Indeed, even Max Independent Set on 3-regular 3-edge-colorable graphs is APX-complete.[18]

Independent sets in interval intersection graphs
Main article: Interval scheduling

An interval graph is a graph in which the nodes are 1-dimensional intervals (e.g. time intervals) and there is an edge between two intervals iff they intersect. An independent set in an interval graph is just a set of non-overlapping intervals. The problem of finding maximum independent sets in interval graphs has been studied, for example, in the context of job scheduling: given a set of jobs that has to be executed on a computer, find a maximum set of jobs that can be executed without interfering with each other. This problem can be solved exactly in polynomial time using earliest deadline first scheduling.

Independent sets in geometric intersection graphs
Main article: Maximum disjoint set

A geometric intersection graph is a graph in which the nodes are geometric shapes and there is an edge between two shapes iff they intersect. An independent set in a geometric intersection graph is just a set of disjoint (non-overlapping) shapes. The problem of finding maximum independent sets in geometric intersection graphs has been studied, for example, in the context of Automatic label placement: given a set of locations in a map, find a maximum set of disjoint rectangular labels near these locations.

Finding a maximum independent set in intersection graphs is still NP-complete, but it is easier to approximate than the general maximum independent set problem. A recent survey can be found in the introduction of Chan & Har-Peled (2012).
Finding maximal independent sets
Main article: Maximal independent set

The problem of finding a maximal independent set can be solved in polynomial time by a trivial greedy algorithm.[19] All maximal independent sets can be found in time O(3n/3) = O(1.4423n).
Software for searching maximum independent set

Name License API language Brief info
igraph GPL C, Python, R, Ruby exact solution. "The current implementation was ported to igraph from the Very Nauty Graph Library by Keith Briggs and uses the algorithm from the paper S. Tsukiyama, M. Ide, H. Ariyoshi and I. Shirawaka. A new algorithm for generating all the maximal independent sets. SIAM J Computing, 6:505–517, 1977".
LightGraphs MIT Julia exact solution. See the documentation for more details.
NetworkX BSD Python approximate solution, see the routine maximum_independent_set
mis Open Rust (binaries) approximate solution by random sampling of maximal independent set space, see web page for more details

Applications

The maximum independent set and its dual, the minimum vertex cover problem, is involved in proving the computational complexity of many theoretical problems.[20] They also serve as useful models for real world optimization problems, for example minimum independent set is a useful model for discovering stable genetic components for designing engineered genetic systems.[21]
See also

An independent set of edges is a set of edges of which no two have a vertex in common. It is usually called a matching.
A vertex coloring is a partition of the vertex set into independent sets.

Notes

Korshunov (1974)
Godsil & Royle (2001), p. 3.
PROOF: A set V of vertices is an independent set IFF every edge in the graph is adjacent to at most one member of V IFF every edge in the graph is adjacent to at least one member not in V IFF the complement of V is a vertex cover.
Moon & Moser (1965).
Füredi (1987).
Chiba & Nishizeki (1985).
Berman & Fujito (1995).
Xiao & Nagamochi (2017)
Xiao & Nagamochi (2013)
Minty (1980),Sbihi (1980),Nakamura & Tamura (2001),Faenza, Oriolo & Stauffer (2014),Nobili & Sassano (2015)
Lokshtanov, Vatshelle & Villanger (2014)
Grötschel, Lovász & Schrijver (1988)
Frank (1976)
Tarjan (1985)
Bazgan, Cristina; Escoffier, Bruno; Paschos, Vangelis Th. (2005). "Completeness in standard and differential approximation classes: Poly-(D)APX- and (D)PTAS-completeness". Theoretical Computer Science. 339 (2–3): 272–292. doi:10.1016/j.tcs.2005.03.007.
Baker (1994); Grohe (2003).
Halldórsson & Radhakrishnan (1997).
Chlebík, Miroslav; Chlebíková, Janka (2003). "Approximation Hardness for Small Occurrence Instances of NP-Hard Problems". Proceedings of the 5th International Conference on Algorithms and Complexity. Lecture Notes in Computer Science. 2653: 152–164. doi:10.1007/3-540-44849-7_21. ISBN 978-3-540-40176-6.
Luby (1986).
Skiena, Steven S. (2012). The algorithm design manual. Springer. ISBN 978-1-84800-069-8. OCLC 820425142.

Hossain, Ayaan; Lopez, Eriberto; Halper, Sean M.; Cetnar, Daniel P.; Reis, Alexander C.; Strickland, Devin; Klavins, Eric; Salis, Howard M. (2020-07-13). "Automated design of thousands of nonrepetitive parts for engineering stable genetic systems". Nature Biotechnology: 1–10. doi:10.1038/s41587-020-0584-2. ISSN 1546-1696. PMID 32661437. S2CID 220506228.

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