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Regular version of the site
Bachelor 2024/2025

Optimization Methods

Type: Compulsory course (Data Science and Business Analytics)
Area of studies: Applied Mathematics and Information Science
When: 3 year, 1, 2 module
Mode of studies: distance learning
Online hours: 10
Open to: students of one campus
Instructors: Andrei Ignatov
Language: English
ECTS credits: 4

Course Syllabus

Abstract

Optimization holds an important place in both practical and theoretical worlds, as understanding the timing and magnitude of actions to be carried out helps achieve a goal in the best possible way. This course emphasizes data-driven modeling, theory and numerical algorithms for optimization with real variables. The course gives a comprehensive foundation for theory, methods and algorithms of mathematical optimization. The prerequisites are linear algebra and calculus.
Learning Objectives

Learning Objectives

  • Students will study main concepts of optimization theory and develop a methodology for theoretical investigation of optimization problems.
  • Students will obtain an understanding of creation, effectiveness and application optimization methods and algorithms on practice.
  • The course will give students the possibility of solving standard and nonstandard mathematical problems connected to finding optimal solutions.
Expected Learning Outcomes

Expected Learning Outcomes

  • Students should be able to acces the rate of convergence of the first and second order optimization methods.
  • Students should be able to classify optimization problems according to their mathematical properties.
  • Students should be able to describe the numerical complexity of the optimization algorithms studied during the course.
  • Students should be able to implement different optimization codes in a computer environment.
  • Students should be able to perform a theoretical investigation of a given optimization problem in order to access its complexity.
  • Students should be able to solve simple optimization problems without computer.
  • Students should be able to write down first and second-order optimality condition.
  • Students should be able to write down first and second-order optimality conditions.
Course Contents

Course Contents

  • One-dimensional optimization: unimodal functions, convex and quasiconvex functions, zero and first-order methods, local and global minima.
  • Existence of solutions: continuous and lower semicontinuous functions, coercive functions, Weierstrass theorem, unique and nonunique solutions.
  • Quadratic unconstrained optimization: algebraic solution, complete optimization analysis, steepest descent and conjugate gradient methods.
  • Theory of optimality conditions: Fermat principle, the Hessian matrix, positive and negative semidefinite matrices, the Lagrange function and Lagrange multipliers, the Karush-Kuhn-Tucker conditions, regularity, complementarity constraints, stationary points.
  • First-order optimization methods: the steepest descent method, conjugate directions, gradient-based methods.
  • Second order optimization methods: Newton's method and modifications, trust-region methods.
  • Convex optimization: optimality conditions, duality, subgradients and subdifferential, cutting planes and bundle methods, the complexity of convex optimization.
  • Computational optimization methods: first-order, second-order, Quasi-Newton methods
  • Linear Programming, Knapsack problem
  • Combinatorial optimization, Transport problems
  • Multi-criteria optimization
Assessment Elements

Assessment Elements

  • non-blocking Home Assignments
  • non-blocking Controlled Assessements
  • non-blocking Final Exam
Interim Assessment

Interim Assessment

  • 2024/2025 2nd module
    Final grade = 0.6 * Cumulative + 0.4 * Final exam. The cumulative is rounded off mathematically, includes Home Assinments and Controlled Assessements which have equal weights.
Bibliography

Bibliography

Recommended Core Bibliography

  • Arkadi Nemirovski. (2001). Lectures on modern convex optimization. Retrieved from http://search.ebscohost.com/login.aspx?direct=true&site=eds-live&db=edsbas&AN=edsbas.5E080C05
  • Mokhtar S. Bazaraa, Hanif D. Sherali, & C. M. Shetty. (2006). Nonlinear Programming : Theory and Algorithms: Vol. 3rd ed. Wiley-Interscience.

Recommended Additional Bibliography

  • Yurii Nesterov. (2018). Lectures on Convex Optimization (Vol. 2nd ed. 2018). Springer.

Authors

  • KHAMISOV OLEG VALEREVICH
  • USOV ALEKSANDR LEONIDOVICH
  • IGNATOV ANDREI DMITRIEVICH