Discrete optimization

Discrete optimization is a branch of optimization in applied mathematics and computer science.

Scope

As opposed to continuous optimization, some or all of the variables used in a discrete mathematical program are restricted to be discrete variables—that is, to assume only a discrete set of values, such as the integers.^[1]

Branches

Two notable branches of discrete optimization are:^[2]

combinatorial optimization, which refers to problems on graphs, matroids and other discrete structures
integer programming

These branches are closely intertwined however since many combinatorial optimization problems can be modeled as integer programs (e.g. shortest path) and conversely, integer programs can often be given a combinatorial interpretation.

References

^ Lee, Jon (2004), A First Course in Combinatorial Optimization, Cambridge Texts in Applied Mathematics, vol. 36, Cambridge University Press, p. 1, ISBN 9780521010122.
^ Hammer, P. L.; Johnson, E. L.; Korte, B. H. (2000), "Conclusive remarks", Discrete Optimization II, Annals of Discrete Mathematics, vol. 5, Elsevier, pp. 427–453.

[1] Lee, Jon (2004), A First Course in Combinatorial Optimization, Cambridge Texts in Applied Mathematics, vol. 36, Cambridge University Press, p. 1, ISBN 9780521010122.

[2] Hammer, P. L.; Johnson, E. L.; Korte, B. H. (2000), "Conclusive remarks", Discrete Optimization II, Annals of Discrete Mathematics, vol. 5, Elsevier, pp. 427–453.

[1]

[2]

Scope

Branches

See also

References