Course details
Graph Algorithms (in English)
GALe Acad. year 2024/2025 Winter semester 5 credits
This course discusses graph representations and graphs algorithms for searching (depth-first search, breadth-first search), topological sorting, searching of graph components and strongly connected components, trees and minimal spanning trees, single-source and all-pairs shortest paths, maximal flows and minimal cuts, maximal bipartite matching, Euler graphs, and graph coloring. The principles and complexities of all presented algorithms are discussed.
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Guarantor
Course coordinator
Language of instruction
Completion
Time span
- 39 hrs lectures
- 13 hrs projects
Assessment points
- 60 pts final exam (written part)
- 15 pts mid-term test (written part)
- 25 pts projects
Department
Lecturer
Instructor
Learning objectives
Introduction to graph theory with focus on graph representations, graph algorithms and their complexities.
Fundamental ability to construct an algorithm for a graph problem and to analyze its time and space complexity.
Prerequisite knowledge and skills
Foundations in discrete mathematics and algorithmic thinking.
Study literature
- Electronic copy of lectures.
- T.H. Cormen, C.E. Leiserson, R.L. Rivest, C. Stein, Introduction to Algorithms, 3rd edition. MIT Press, 2009.
- J.A. McHugh, Algorithmic Graph Theory, Prentice-Hall, 1990.
- K. Erciyes: Guide to Graph Algorithms (Sequential, Parallel and Distributed). Springer, 2018.
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A. Mitina: Applied Combinatorics with Graph Theory. NEIU, 2019.
Syllabus of lectures
- Introduction, algorithmic complexity, basic notions and graph representations.
- Graph searching, depth-first search, breadth-first search.
- Topological sort, acyclic graphs.
- Graph components, strongly connected components, examples.
- Trees, minimal spanning trees, algorithms of Jarník and Borůvka.
- Growing a minimal spanning tree, algorithms of Kruskal and Prim.
- Single-source shortest paths, Bellman-Ford algorithm, shortest path in DAGs.
- Dijkstra algorithm. All-pairs shortest paths.
- Shortest paths and matrix multiplication, Floyd-Warshall algorithm.
- Flows and cuts in networks, maximal flow, minimal cut, Ford-Fulkerson algorithm.
- Matching in bipartite graphs, maximal matching.
- Graph coloring.
- Eulerian graphs and tours, Hamiltonian graphs and cycles.
Syllabus - others, projects and individual work of students
- Solving of selected graph problems and presentation of solutions (principle, complexity, implementation, optimization).
Progress assessment
- Mid-term exam - 15 points.
- Projects - 25 points.
- Final exam - 60 points. The minimal number of points which can be obtained from the final exam is 25. Otherwise, no points from the final exam will be assigned to a student.
Schedule
Day | Type | Weeks | Room | Start | End | Capacity | Lect.grp | Groups | Info |
---|---|---|---|---|---|---|---|---|---|
Mon | exam | 2025-01-20 | E105 | 12:00 | 14:50 | GALe: 2. termín | |||
Mon | exam | 2025-02-03 | A112 | 13:00 | 15:50 | GALe: 3. termín | |||
Tue | exam | 2024-11-12 | L314 | 09:00 | 11:00 | GALe: Midterm exam | |||
Tue | lecture | lectures | L314 | 09:00 | 11:50 | 30 | 1EIT 2EIT INTE | xx | Křivka |
Thu | exam | 2025-01-09 | E104 | 10:00 | 12:50 | GALe: 1. termín |
Course inclusion in study plans
- Programme MIT-EN (in English), any year of study, Compulsory-Elective group B