A Scenario Tree-Based Decomposition for Solving Multistage Stochastic Programs [electronic resource] : With Application in Energy Production / by Debora Mahlke.

By:

Mahlke, Debora [author.]

Contributor(s):

SpringerLink (Online service)

Publisher: Wiesbaden : Vieweg+Teubner, 2011Description: XVI, 182 p. 14 illus. online resourceContent type:

text

Media type:

computer

Carrier type:

online resource

ISBN:

9783834898296

Subject(s):

Genre/Form:

Electronic books.

Additional physical formats: Printed edition:: No titleDDC classification:

519.2 23

LOC classification:

QA273.A1-274.9
QA274-274.9

Online resources:

Click here to access online

In: Springer eBooksSummary: Optimization problems involving uncertain data arise in many areas of industrial and economic applications. Stochastic programming provides a useful framework for modeling and solving optimization problems for which a probability distribution of the unknown parameters is available. Motivated by practical optimization problems occurring in energy systems with regenerative energy supply, Debora Mahlke formulates and analyzes multistage stochastic mixed-integer models. For their solution, the author proposes a novel decomposition approach which relies on the concept of splitting the underlying scenario tree into subtrees. Based on the formulated models from energy production, the algorithm is computationally investigated and the numerical results are discussed.

Item type:

eBooks

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Optimization problems involving uncertain data arise in many areas of industrial and economic applications. Stochastic programming provides a useful framework for modeling and solving optimization problems for which a probability distribution of the unknown parameters is available. Motivated by practical optimization problems occurring in energy systems with regenerative energy supply, Debora Mahlke formulates and analyzes multistage stochastic mixed-integer models. For their solution, the author proposes a novel decomposition approach which relies on the concept of splitting the underlying scenario tree into subtrees. Based on the formulated models from energy production, the algorithm is computationally investigated and the numerical results are discussed.

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