Optimization : Nonlinear programming [ LINMA2460 ]
5.0 crédits ECTS
30.0 h + 22.5 h
2q
Teacher(s) |
Nesterov Yurii ;
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Language |
English
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Place of the course |
Louvain-la-Neuve
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Online resources |
The full syllabus (in English) can be downloaded from the web page of the course.
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Prerequisites |
LFSAB1102 (Mathématiques 2)
Basic knowledge of Nonlinear Analysis and Linear Algebra.
The target audience is the students interested in scientific computing, machine learning and optimization in engineering.
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Main themes |
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General nonlinear optimization.
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Smooth and non-smooth convex optimization.
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Interior-point methods.
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Aims |
Learning outcomes:
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AA1.1, AA1.2, AA1.3
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AA2.1
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AA5.2, AA5.3
After this course, the student will be able to :
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Estimate the actual complexity of Nonlinear Optimization problems.
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Apply lower complexity bounds, which establish the limits of performance of optimization method.
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Explain the main principles for constructing the optimal methods for solving different types of minimization problems.
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Use the main problem classes (general nonlinear problems, smooth convex problems, nonsmooth convex problems, structural optimization ' polynomial-time interior-point methods).
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Understand the rate of convergence of the main optimization methods.
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Two testing computer projects give a possibility to compare the theoretical conclusions and predictions with real performance of minimization methods
Additional benefits :
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Training in scientific English
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Experience in solving difficult nonlinear optimization problems
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Evaluation methods |
In the written exam (in English or French) there are four questions, one for each chapter of the course (up to 5 points for each question). The marks for the exam and the exercises are combined in the final mark.
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Teaching methods |
The course is given in 12-15 lectures. The computer projects are implemented by the students themselves with supporting consultations.
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Content |
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General problem of nonlinear optimization. Black-box concept. Iterative methods and analytical complexity. Gradient method and Newton method. Local complexity analysis.
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Convex optimization: convex sets and functions; minimization of differentiable and non-differentiable convex functions; lower complexity bounds; optimal methods.
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Interior-point methods: notion of self-concordant functions and barriers; path-following methods; structural optimization.
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Bibliography |
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Yu.Nesterov. "Introductory lectures on convex optimization. Basic course", Kluwer 2004
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P. Polyak, « Introduction in optimization », J. Willey & Sons, 1989
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Yu. Nesterov, A. Nemirovsky, « Interior-point polynomial algorithms in nonlinear optimization », SIAM, Philadelphia, 1994.
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Cycle et année d'étude |
> Master [120] in Mathematical Engineering
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Faculty or entity in charge |
> MAP
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