Heinrich Lenz: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
en>EmausBot
m r2.7.2+) (Robot: Adding pms:Heinrich Friedrich Lenz
 
en>Yakikaki
No edit summary
 
Line 1: Line 1:
Historical past of the of the author is probably Gabrielle Lattimer. For years she's been working [http://Www.dict.cc/?s=compared compared] to a library assistant. For a while she's [http://www.Dict.cc/englisch-deutsch/happened.html happened] to be in Massachusetts. As a woman what your woman really likes is mah jongg but she doesn't have made a dime destinations. She is running and maintaining the best blog here: http://circuspartypanama.com<br><br>
{{no footnotes|date=December 2013}}
'''Global optimization''' is a branch of [[applied mathematics]] and [[numerical analysis]] that deals with the [[optimization (mathematics)|optimization]] of a [[function (mathematics)|function]] or a [[Set (mathematics)|set]] of functions according to some criteria. Typically, a set of bound and more general constraints is also present, and the decision variables are optimized considering also the constraints.


Here is my web blog - [http://circuspartypanama.com clash of clans hack free download]
== General ==
 
A common (standard) model form is the [[maxima and minima|minimization]] of one [[real number|real]]-valued function
<math>f</math> in the parameter-space <math>\vec{x}\in P</math>, or its specified subset <math>\vec{x}\in D</math>: here <math>D</math> denotes the set defined by the constraints.
 
(The maximization of a real-valued function <math>g(x)</math> is equivalent to the minimization of the function <math>f(x):=(-1)\cdot g(x)</math>.)
 
In many nonlinear optimization problems, the objective function <math>f</math> has a large number of ''local'' minima and maxima. Finding an arbitrary local optimum is relatively straightforward by using classical ''local optimization'' methods. Finding the global minimum (or maximum) of a function is far more difficult: symbolic (analytical) methods are frequently not applicable, and the use of numerical solution strategies often leads to very hard challenges.
 
== Applications of global optimization ==
Typical examples of global optimization applications include:
* [[Protein structure prediction]] (minimize the energy/free energy function)
* [[Computational phylogenetics]] (e.g., minimize the number of character transformations in the tree)
* [[Traveling salesman problem]] and electrical circuit design (minimize the path length)
* [[Chemical engineering]] (e.g., analyzing the [[Gibbs free energy]])
* Safety verification, [[safety engineering]] (e.g., of mechanical structures, buildings)
* [[Worst case|Worst-case analysis]]
* Mathematical problems (e.g., the [[Kepler conjecture]])
* Object packing (configuration design) problems
* The starting point of several [[molecular dynamics]] simulations consists of an initial optimization of the energy of the system to be simulated.
* [[Spin glass]]es
* Calibration of [[radio propagation models]] and of many other models in the sciences and engineering
* [[Curve fitting]] like [[non-linear least squares]] analysis and other generalizations, used in fitting model parameters to experimental data in chemistry, physics, medicine, astronomy, engineering.
 
== Approaches ==
=== Deterministic methods ===
The most successful general strategies are:
* Inner approximation
* Outer approximation
* [[Cutting plane]] methods
* [[Branch and bound]] methods
* [[Interval arithmetic|Interval methods]] / Interval algebra (see interalg from [[OpenOpt]] and GlobSol) / [[set inversion|Interval branch and bound methods]].
* Methods based on [[real algebraic geometry]]
 
=== Stochastic methods ===
:''Main page: [[Stochastic optimization]]''
 
Several Monte-Carlo-based algorithms exist:
* [[Simulated annealing]]
* Direct [[Monte Carlo method|Monte-Carlo]] sampling
* [[Stochastic tunneling]]
* [[Parallel tempering]]
 
=== Heuristics and metaheuristics ===
:''Main page: [[Metaheuristic]]''
 
Other approaches include heuristic strategies to search the search space in a more or less intelligent way, including:
* [[Evolutionary algorithm]]s (e.g., [[genetic algorithms]] and [[evolution strategies]])
* [[Swarm intelligence|Swarm-based optimization algorithms]] (e.g., [[particle swarm optimization]], [[Multi-swarm optimization]] and [[ant colony optimization]])
* [[Memetic algorithm]]s, combining global and local search strategies
* [[Reactive search optimization]] (i.e. integration of sub-symbolic machine learning techniques into search heuristics)
* [[Differential evolution]]
* [[Graduated optimization]]
* [[Bayesian optimization]]
 
=== Response surface methodology based approaches ===
* [[IOSO]] Indirect Optimization based on Self-Organization
 
== Global optimization software ==
'''1. Free and opensource:'''
*[[OpenOpt]]
 
'''2. Commercial:'''
* [[LIONsolver]]
* [[TOMLAB]] for Matlab
* [[Optimus platform]]
* The [[NAG Numerical Library]] contains routines for both global and local optimization.
* Demo global optimization software versions are available also for a number of commercial software products.
 
==See also==
* [[Multidisciplinary design optimization]]
* [[Multiobjective optimization]]
* [[Optimization (mathematics)]]
 
== References ==
{{refbegin}}
Deterministic global optimization:
* R. Horst, H. Tuy, Global Optimization: Deterministic Approaches, Springer, 1996.
* R. Horst, P.M. Pardalos and N.V. Thoai, Introduction to Global Optimization, Second Edition.  Kluwer Academic Publishers, 2000.
*[http://www.mat.univie.ac.at/~neum/ms/glopt03.pdf A.Neumaier, Complete Search in Continuous Global Optimization and Constraint Satisfaction, pp. 271-369 in: Acta Numerica 2004 (A. Iserles, ed.), Cambridge University Press 2004.]
* M. Mongeau, H. Karsenty, V. Rouzé and J.-B. Hiriart-Urruty, Comparison of public-domain software for black box global optimization. Optimization Methods & Software 13(3), pp.&nbsp;203–226, 2000.
* J.D. Pintér, Global Optimization in Action - Continuous and Lipschitz Optimization: Algorithms, Implementations and Applications. Kluwer Academic Publishers, Dordrecht, 1996. Now distributed by Springer Science and Business Media, New York. This book also discusses stochastic global optimization methods.
* L. Jaulin, M. Kieffer, O. Didrit, E. Walter (2001). Applied Interval Analysis. Berlin: Springer.
* E.R. Hansen (1992), Global Optimization using Interval Analysis, Marcel Dekker, New York.
* R.G. Strongin, Ya.D. Sergeyev  (2000) Global optimization with non-convex constraints: Sequential and parallel algorithms, Kluwer Academic Publishers, Dordrecht.
* Ya.D. Sergeyev, R.G. Strongin, D. Lera (2013) Introduction to global optimization exploiting space-filling curves, Springer, NY.
 
For simulated annealing:
* S. Kirkpatrick, C.D. Gelatt, and M.P. Vecchi. ''Science'', 220:671&ndash;680, 1983.
For reactive search optimization:
* [[Roberto Battiti]], M. Brunato and F. Mascia, Reactive Search and Intelligent Optimization, Operations Research/Computer Science Interfaces Series, Vol. 45, Springer, November 2008. ISBN 978-0-387-09623-0
For stochastic methods:
* [[Anatoly Zhigljavsky|A. Zhigljavsky]].  Theory of Global Random Search.  Mathematics and its applications. Kluwer Academic Publishers. 1991.
* K. Hamacher. Adaptation in Stochastic Tunneling Global Optimization of Complex Potential Energy Landscapes, ''Europhys.Lett.'' 74(6):944, 2006.
* K. Hamacher and W. Wenzel. The Scaling Behaviour of Stochastic Minimization Algorithms in a Perfect Funnel Landscape. ''Phys. Rev. E'', 59(1):938-941, 1999.
* W. Wenzel and K. Hamacher. A Stochastic tunneling approach for global minimization. ''Phys. Rev. Lett.'', 82(15):3003-3007, 1999.
For parallel tempering:
* U. H. E. Hansmann. ''Chem.Phys.Lett.'', 281:140, 1997.
For continuation methods:
* Zhijun Wu.  The effective energy transformation scheme as a special continuation approach to global optimization with application to molecular conformation.  Technical Report, Argonne National Lab., IL (United States), November 1996.
For general considerations on the dimensionality of the domain of definition of the objective function:
* K. Hamacher. On Stochastic Global Optimization of one-dimensional functions. ''Physica A'' 354:547-557, 2005.
{{refend}}
 
== External links ==
*[http://www.mat.univie.ac.at/~neum/glopt.html A. Neumaier’s page on Global Optimization]
*[http://www.lix.polytechnique.fr/~liberti/teaching/dix/inf572-09/nonconvex_optimization.pdf Introduction to global optimization by L. Liberti]
*[http://biomath.ugent.be/~brecht/downloads.html Global optimization algorithms for MATLAB]
*[http://www.midaco-solver.com/ MIDACO-Solver] Global optimization software based on evolutionary computing (Matlab,Python, C/C++ and Fortran)
*[http://www.it-weise.de/projects/book.pdf Free e-book by Thomas Weise]
 
[[Category:Mathematical optimization]]

Latest revision as of 19:41, 30 June 2013

Template:No footnotes Global optimization is a branch of applied mathematics and numerical analysis that deals with the optimization of a function or a set of functions according to some criteria. Typically, a set of bound and more general constraints is also present, and the decision variables are optimized considering also the constraints.

General

A common (standard) model form is the minimization of one real-valued function f in the parameter-space xP, or its specified subset xD: here D denotes the set defined by the constraints.

(The maximization of a real-valued function g(x) is equivalent to the minimization of the function f(x):=(1)g(x).)

In many nonlinear optimization problems, the objective function f has a large number of local minima and maxima. Finding an arbitrary local optimum is relatively straightforward by using classical local optimization methods. Finding the global minimum (or maximum) of a function is far more difficult: symbolic (analytical) methods are frequently not applicable, and the use of numerical solution strategies often leads to very hard challenges.

Applications of global optimization

Typical examples of global optimization applications include:

Approaches

Deterministic methods

The most successful general strategies are:

Stochastic methods

Main page: Stochastic optimization

Several Monte-Carlo-based algorithms exist:

Heuristics and metaheuristics

Main page: Metaheuristic

Other approaches include heuristic strategies to search the search space in a more or less intelligent way, including:

Response surface methodology based approaches

  • IOSO Indirect Optimization based on Self-Organization

Global optimization software

1. Free and opensource:

2. Commercial:

See also

References

Template:Refbegin Deterministic global optimization:

  • R. Horst, H. Tuy, Global Optimization: Deterministic Approaches, Springer, 1996.
  • R. Horst, P.M. Pardalos and N.V. Thoai, Introduction to Global Optimization, Second Edition. Kluwer Academic Publishers, 2000.
  • A.Neumaier, Complete Search in Continuous Global Optimization and Constraint Satisfaction, pp. 271-369 in: Acta Numerica 2004 (A. Iserles, ed.), Cambridge University Press 2004.
  • M. Mongeau, H. Karsenty, V. Rouzé and J.-B. Hiriart-Urruty, Comparison of public-domain software for black box global optimization. Optimization Methods & Software 13(3), pp. 203–226, 2000.
  • J.D. Pintér, Global Optimization in Action - Continuous and Lipschitz Optimization: Algorithms, Implementations and Applications. Kluwer Academic Publishers, Dordrecht, 1996. Now distributed by Springer Science and Business Media, New York. This book also discusses stochastic global optimization methods.
  • L. Jaulin, M. Kieffer, O. Didrit, E. Walter (2001). Applied Interval Analysis. Berlin: Springer.
  • E.R. Hansen (1992), Global Optimization using Interval Analysis, Marcel Dekker, New York.
  • R.G. Strongin, Ya.D. Sergeyev (2000) Global optimization with non-convex constraints: Sequential and parallel algorithms, Kluwer Academic Publishers, Dordrecht.
  • Ya.D. Sergeyev, R.G. Strongin, D. Lera (2013) Introduction to global optimization exploiting space-filling curves, Springer, NY.

For simulated annealing:

  • S. Kirkpatrick, C.D. Gelatt, and M.P. Vecchi. Science, 220:671–680, 1983.

For reactive search optimization:

  • Roberto Battiti, M. Brunato and F. Mascia, Reactive Search and Intelligent Optimization, Operations Research/Computer Science Interfaces Series, Vol. 45, Springer, November 2008. ISBN 978-0-387-09623-0

For stochastic methods:

  • A. Zhigljavsky. Theory of Global Random Search. Mathematics and its applications. Kluwer Academic Publishers. 1991.
  • K. Hamacher. Adaptation in Stochastic Tunneling Global Optimization of Complex Potential Energy Landscapes, Europhys.Lett. 74(6):944, 2006.
  • K. Hamacher and W. Wenzel. The Scaling Behaviour of Stochastic Minimization Algorithms in a Perfect Funnel Landscape. Phys. Rev. E, 59(1):938-941, 1999.
  • W. Wenzel and K. Hamacher. A Stochastic tunneling approach for global minimization. Phys. Rev. Lett., 82(15):3003-3007, 1999.

For parallel tempering:

  • U. H. E. Hansmann. Chem.Phys.Lett., 281:140, 1997.

For continuation methods:

  • Zhijun Wu. The effective energy transformation scheme as a special continuation approach to global optimization with application to molecular conformation. Technical Report, Argonne National Lab., IL (United States), November 1996.

For general considerations on the dimensionality of the domain of definition of the objective function:

  • K. Hamacher. On Stochastic Global Optimization of one-dimensional functions. Physica A 354:547-557, 2005.

Template:Refend

External links