Difference between revisions of "MSc: Optimization"
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= Optimization = |
= Optimization = |
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+ | * '''Course name''': Optimization |
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+ | * '''Code discipline''': R-01 |
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+ | * '''Subject area''': |
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+ | == Short Description == |
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− | * <span>'''Course name:'''</span> Optimization |
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+ | This course covers the following concepts: Optimization of a cost function; Algorithms to find solution of linear and nonlinear optimization problems. |
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− | * <span>'''Course number:'''</span> XYZ |
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− | * <span>'''Knowledge area:'''</span> Data Science |
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− | == |
+ | == Prerequisites == |
+ | === Prerequisite subjects === |
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− | * <span>'''Faculty:'''</span> Computer Science and Engineering |
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− | * <span>'''Year of instruction:'''</span> 3rd year of BS |
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− | * <span>'''Semester of instruction:'''</span> 2nd semester |
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− | * <span>'''No. of Credits:'''</span> 5 ECTS |
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− | * <span>'''Total workload on average:'''</span> 180 hours overall |
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− | * <span>'''Class lecture hours:'''</span> 2 per week. |
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− | * <span>'''Class tutorial hours:'''</span> 2 per week. |
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− | * <span>'''Lab hours:'''</span> 2 per week. |
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− | * <span>'''Individual lab hours:'''</span> 0. |
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− | * <span>'''Frequency:'''</span> weekly throughout the semester. |
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− | * <span>'''Grading mode:'''</span> letters: A, B, C, D. |
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− | == Prerequisites == |
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+ | === Prerequisite topics === |
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− | Familiarity with multivariate calculus, elementary real analysis, and linear algebra. |
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+ | |||
+ | |||
+ | == Course Topics == |
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+ | {| class="wikitable" |
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+ | |+ Course Sections and Topics |
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+ | |- |
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+ | ! Section !! Topics within the section |
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+ | |- |
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+ | | Linear programming || |
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+ | # simplex method to solve real linear programs |
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+ | # cutting-plane and branch-and-bound methods to solve integer linear programs. |
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+ | |- |
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+ | | Nonlinear programming || |
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+ | # methods for unconstrained optimization |
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+ | # linear and nonlinear least-squares problems |
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+ | # methods for constrained optimization |
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+ | |} |
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+ | == Intended Learning Outcomes (ILOs) == |
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+ | |||
+ | === What is the main purpose of this course? === |
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+ | The main purpose of this course to make the student aware of basic notions of mathematical programming and of its importance in the area of engineering. |
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+ | === ILOs defined at three levels === |
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− | * Multivariate calculus |
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− | * Linear Algebra |
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− | * Probability and Statistics |
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+ | ==== Level 1: What concepts should a student know/remember/explain? ==== |
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− | == Course outline == |
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+ | By the end of the course, the students should be able to ... |
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+ | * explain the goal of an optimization problem |
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+ | * remind the importance of converge analysis for optimization algorithms |
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+ | * draft solution codes in Python/Matlab. |
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+ | ==== Level 2: What basic practical skills should a student be able to perform? ==== |
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− | This course studies fundamental concepts of optimization, which is the problem of making decisions to maximize or minimize an objective in the presence of constraints. The course takes a unified view of optimization and covers the main areas of application and the main optimization algorithms. It covers linear and nonlinear optimization. |
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+ | By the end of the course, the students should be able to ... |
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+ | * formulate a simple optimization problem |
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+ | * select the appropriate solution algorithm |
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+ | * find the solution. |
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+ | ==== Level 3: What complex comprehensive skills should a student be able to apply in real-life scenarios? ==== |
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− | == Expected learning outcomes == |
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+ | By the end of the course, the students should be able to ... |
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+ | * the simplex method |
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+ | * algorithms to solve nonlinear optimization problems. |
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+ | == Grading == |
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+ | === Course grading range === |
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− | After this course, students will be able to: |
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+ | {| class="wikitable" |
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+ | |+ |
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+ | |- |
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+ | ! Grade !! Range !! Description of performance |
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+ | |- |
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+ | | A. Excellent || 86-100 || - |
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+ | |- |
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+ | | B. Good || 71-85 || - |
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+ | |- |
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+ | | C. Satisfactory || 56-70 || - |
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+ | |- |
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+ | | D. Poor || 0-55 || - |
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+ | |} |
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+ | === Course activities and grading breakdown === |
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− | * be able to formulate problems in their fields of research as optimization problems |
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+ | {| class="wikitable" |
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− | * be able to transform an optimization problem into its standard form |
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+ | |+ |
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− | * understand how to assess and check the feasiblity and optimality of a particular solution to a general constrained optimization problem |
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+ | |- |
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− | * be able to use the optimality conditions to search for a local or global solution from a starting point. |
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+ | ! Activity Type !! Percentage of the overall course grade |
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− | * understand the computational details behind the numerical methods discussed in class, when they apply, and what their convergence rates are. |
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+ | |- |
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− | * be able to implement the numerical methods discussed in class and verify their theoretical properties in practice. |
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+ | | Labs/seminar classes (weekly evaluations) || 0 |
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− | * be able to apply the learned techniques and analysis tools to problems arising in their own research. |
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+ | |- |
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+ | | Interim performance assessment (class participation) || 100/0 |
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+ | |- |
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+ | | Exams || 0/100 |
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+ | |} |
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+ | === Recommendations for students on how to succeed in the course === |
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− | == Expected acquired core competences == |
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− | * Numerical analysis |
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− | * Numerical optimization |
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+ | == Resources, literature and reference materials == |
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− | == Detailed topics covered in the course == |
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+ | === Open access resources === |
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− | * Linear Optimization |
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+ | * Textbook: C.H. Papadimitriou, K. Steiglitz, Combinatorial Optimization, Dover, New York, 1982. |
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− | * Simplex Method |
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+ | * Textbook: D. Bertsekas, Nonlinear Programming, Athena Scientific, 1999. |
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− | * Branch and Bound and Cutting planes |
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− | * Nonlinear Optimization |
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+ | === Closed access resources === |
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− | == Textbook == |
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− | * C.H. Papadimitriou, K. Steiglitz, Combinatorial Optimization, Dover, New York, 1982. |
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− | * D. Bertsekas, Nonlinear Programming, Athena Scientific, 1999. |
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+ | === Software and tools used within the course === |
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− | == Reference material == |
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+ | |||
+ | = Teaching Methodology: Methods, techniques, & activities = |
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+ | == Activities and Teaching Methods == |
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− | Slides of the lectures |
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+ | {| class="wikitable" |
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+ | |+ Activities within each section |
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+ | |- |
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+ | ! Learning Activities !! Section 1 !! Section 2 |
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+ | |- |
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+ | | Midterm evaluation || 1 || 1 |
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+ | |- |
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+ | | Testing (written or computer based) || 1 || 1 |
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+ | |} |
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+ | == Formative Assessment and Course Activities == |
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− | == |
+ | === Ongoing performance assessment === |
+ | ==== Section 1 ==== |
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− | Matlab or Python. |
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+ | {| class="wikitable" |
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+ | |+ |
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+ | |- |
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+ | ! Activity Type !! Content !! Is Graded? |
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+ | |- |
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+ | | Question || How a convex set and a convex function are defined? || 1 |
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+ | |- |
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+ | | Question || What is the difference between polyhedron and polytope? || 1 |
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+ | |- |
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+ | | Question || Why does always a linear program include constraints? || 1 |
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+ | |- |
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+ | | Question || Consider the problem:<br><math>{\displaystyle {\text{minimize }}c_{1}x_{1}+c_{2}x_{2}+c_{3}x_{3}+c_{4}x_{4}}</math> <br><math>{\displaystyle {\text{subject to }}x_{1}+x_{2}+x_{3}+x_{4}=2}</math> <br><math>{\displaystyle 2x_{1}+3x_{3}+4x_{4}=2}</math> <br><math>{\displaystyle x_{1},x_{2},x_{3},x_{4}\geqslant 0}</math> <br>Solve it using simplex method. || 0 |
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+ | |- |
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+ | | Question || Consider the problem:<br><math>{\displaystyle {\text{minimize }}x_{1}+x_{2}}</math> <br><math>{\displaystyle {\text{subject to }}-5x_{1}+4x_{2}\leq 0}</math> <br><math>{\displaystyle 6x_{1}+2x_{2}\ \leq 17}</math> <br><math>{\displaystyle x_{1},\ x_{2}\geq 0}</math> <br>Solve it using cutting-plane and branch-and-bound methods. || 0 |
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+ | |} |
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+ | ==== Section 2 ==== |
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+ | {| class="wikitable" |
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+ | |+ |
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+ | |- |
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+ | ! Activity Type !! Content !! Is Graded? |
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+ | |- |
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+ | | Question || Which are the necessary and sufficient conditions of optimality of a generic minimization/maximization problem? || 1 |
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+ | |- |
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+ | | Question || What is the goal of a descent algorithm? || 1 |
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+ | |- |
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+ | | Question || What does it mean to fit some experimental data points || 1 |
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+ | |- |
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+ | | Question || Consider the problem:<br><math>{\displaystyle {\text{minimize }}{\frac {1}{2}}\left(x_{1}^{1}+x_{2}^{2}\right)}</math> <br>Solve it using the suitable method. || 0 |
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+ | |- |
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+ | | Question || Consider the problem:<br><math>{\displaystyle {\text{minimize }}-\left(x_{1}-2\right)^{2}}</math> <br><math>{\displaystyle {\text{subject to }}\ x_{1}+x_{2}^{2}=1}</math> <br><math>{\displaystyle -1\leq x_{2}\leq 1}</math> <br>Solve it using the suitable method. || 0 |
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+ | |} |
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+ | === Final assessment === |
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+ | '''Section 1''' |
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+ | # Why does the simplex method require to be initialized with a correct basic feasible solution? |
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+ | # How one can test absence of solutions to a linear program? |
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+ | # How one can test unbounded solutions to a linear program? |
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+ | # How can the computational complexity of an optimization algorithm can be defined? |
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+ | '''Section 2''' |
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+ | # How is it possible to compute the Lagrange multiplier of a constrained optimization problem? |
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+ | # Which are the convergence conditions of the steepest descent method? |
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+ | # Which are the convergence conditions of the Newton’s method? |
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+ | # How can one “penalize” a constraint? |
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+ | === The retake exam === |
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− | == Evaluation == |
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+ | '''Section 1''' |
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+ | # Consider the problem: |
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+ | <math>{\displaystyle {\text{minimize }}x_{1}+x_{2}}</math> |
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+ | <math>{\displaystyle {\text{subject to }}x_{1}+{2x}_{2}+2x_{3}\leq 20}</math> |
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+ | <math>{\displaystyle 2x_{1}+x_{2}+2x_{3}\leq 20}</math> |
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+ | <math>{\displaystyle 2x_{1}+2x_{2}+x_{3}\leq 20}</math> |
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+ | <math>{\displaystyle x_{1},\ x_{2},\ x_{3}\geq 0}</math> |
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+ | Solve it using simplex method. |
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+ | # Consider the problem: |
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+ | <math>{\displaystyle {\text{maximize }}15x_{1}+{12x}_{2}+4x_{3}+2x_{4}}</math> |
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+ | <math>{\displaystyle {\text{subject to }}8x_{1}+5x_{2}+3x_{3}+2x_{4}\leq 10}</math> |
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+ | <math>{\displaystyle x_{i}\in \{0,1\}}</math> |
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+ | Solve it using cutting-plane and branch-and-bound methods. |
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+ | '''Section 2''' |
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− | * Quizzes (0%) |
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+ | # Consider the problem: |
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− | * Labs (0%) |
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+ | <math>{\displaystyle {\text{minimize }}100\left(x_{2}-x_{1}^{2}\right)^{2}+\left(1-x_{1}\right)^{2}}</math> |
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− | * Assignments (100% or 0%), i.e., as alternative to the final exam. |
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+ | <math>{\displaystyle {\text{subject to }}x_{1},\ x_{2}\geq 0}</math> |
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− | * Final Exam (0% or 100%), i.e., as alternative to the assignments. |
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+ | Solve it using the suitable method. |
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− | * Class and lab participation (0%) |
Latest revision as of 14:09, 10 November 2022
Optimization
- Course name: Optimization
- Code discipline: R-01
- Subject area:
Short Description
This course covers the following concepts: Optimization of a cost function; Algorithms to find solution of linear and nonlinear optimization problems.
Prerequisites
Prerequisite subjects
Prerequisite topics
Course Topics
Section | Topics within the section |
---|---|
Linear programming |
|
Nonlinear programming |
|
Intended Learning Outcomes (ILOs)
What is the main purpose of this course?
The main purpose of this course to make the student aware of basic notions of mathematical programming and of its importance in the area of engineering.
ILOs defined at three levels
Level 1: What concepts should a student know/remember/explain?
By the end of the course, the students should be able to ...
- explain the goal of an optimization problem
- remind the importance of converge analysis for optimization algorithms
- draft solution codes in Python/Matlab.
Level 2: What basic practical skills should a student be able to perform?
By the end of the course, the students should be able to ...
- formulate a simple optimization problem
- select the appropriate solution algorithm
- find the solution.
Level 3: What complex comprehensive skills should a student be able to apply in real-life scenarios?
By the end of the course, the students should be able to ...
- the simplex method
- algorithms to solve nonlinear optimization problems.
Grading
Course grading range
Grade | Range | Description of performance |
---|---|---|
A. Excellent | 86-100 | - |
B. Good | 71-85 | - |
C. Satisfactory | 56-70 | - |
D. Poor | 0-55 | - |
Course activities and grading breakdown
Activity Type | Percentage of the overall course grade |
---|---|
Labs/seminar classes (weekly evaluations) | 0 |
Interim performance assessment (class participation) | 100/0 |
Exams | 0/100 |
Recommendations for students on how to succeed in the course
Resources, literature and reference materials
Open access resources
- Textbook: C.H. Papadimitriou, K. Steiglitz, Combinatorial Optimization, Dover, New York, 1982.
- Textbook: D. Bertsekas, Nonlinear Programming, Athena Scientific, 1999.
Closed access resources
Software and tools used within the course
Teaching Methodology: Methods, techniques, & activities
Activities and Teaching Methods
Learning Activities | Section 1 | Section 2 |
---|---|---|
Midterm evaluation | 1 | 1 |
Testing (written or computer based) | 1 | 1 |
Formative Assessment and Course Activities
Ongoing performance assessment
Section 1
Activity Type | Content | Is Graded? |
---|---|---|
Question | How a convex set and a convex function are defined? | 1 |
Question | What is the difference between polyhedron and polytope? | 1 |
Question | Why does always a linear program include constraints? | 1 |
Question | Consider the problem: Solve it using simplex method. |
0 |
Question | Consider the problem: Solve it using cutting-plane and branch-and-bound methods. |
0 |
Section 2
Activity Type | Content | Is Graded? |
---|---|---|
Question | Which are the necessary and sufficient conditions of optimality of a generic minimization/maximization problem? | 1 |
Question | What is the goal of a descent algorithm? | 1 |
Question | What does it mean to fit some experimental data points | 1 |
Question | Consider the problem: Solve it using the suitable method. |
0 |
Question | Consider the problem: Solve it using the suitable method. |
0 |
Final assessment
Section 1
- Why does the simplex method require to be initialized with a correct basic feasible solution?
- How one can test absence of solutions to a linear program?
- How one can test unbounded solutions to a linear program?
- How can the computational complexity of an optimization algorithm can be defined?
Section 2
- How is it possible to compute the Lagrange multiplier of a constrained optimization problem?
- Which are the convergence conditions of the steepest descent method?
- Which are the convergence conditions of the Newton’s method?
- How can one “penalize” a constraint?
The retake exam
Section 1
- Consider the problem:
Solve it using simplex method.
- Consider the problem:
Solve it using cutting-plane and branch-and-bound methods.
Section 2
- Consider the problem:
Solve it using the suitable method.