# GRAPH THEORY

**Academic Year 2023/2024**- Teacher:

**ELENA MARIA GUARDO**

## Expected Learning Outcomes

The couse has the following objectives:

**Knowledge and understanding:**

- Mathematic Instruments in graph theory such as theorems and algoritms will be provide in the course. They permit to develop mathematical abilities in reasoning and calculation. These abilities could permit to resolve known problems by mathematical model.

**Applying and knowledge and understanding:**

- At the end of course student will be able to get knowledge for a tightened use of new mathematical techniques and an understanding of treated arguments in such way to link them each other.

**Making judgements:**

- Course is based on logical-deductive method which wants to give to students authonomus judgement useful to understanding incorrect method of demonstration also, by logical reasoning, student will be able to face not difficult problems in graph theory with teacher's help.

**Communication skills:**

- In the final exam, student must show for learned different mathematical techniques an adapt maturity on oral communication using also multimedia tools.

**Learning skills**

- Autonomously student will be able to face application and theoretical arguments which could be studied in new classes or in different working fields; for example flow theory and connectivity have huge application on telecommunications field (Local Area Network and Metropolitan Area Network: LAN e MAN), on electrical and communication fields (Industrial design).

## Course Structure

Graph Theory 9 CFU

### teaching organization

### total study 225 hours

152 hours of individual study

49 hours of frontal lectures

24 hours of exercises

The lessons will be held through classroom. In these lessons the program will be divided into the following sections: basic notions, planar graphs, cycles and cocycles, different graph connections, graph fluxes, matchings and coverings, colorability.

In each of these sections first it will be discussed the main theoretical topics and then showed how these topics can be linked to possible applications. Then algorithms can be presented, and they allow in many cases to identify particular graphs or solutions proposed by the theoretical results

*Should teaching be carried out in mixed mode or remotely, it may be necessary to introduce changes with respect to previous statements, in line with the programme planned and outlined in the syllabus.*

*Learning assessment may also be carried out on line, should the conditions require it.*

Information for students with disabilities and / or SLD

To guarantee equal opportunities and in compliance with the laws in force, interested students can ask for a personal interview in order to plan any compensatory and / or dispensatory measures, based on the didactic objectives and specific needs. It is also possible to contact the referent teacher CInAP (Center for Active and Participated Integration - Services for Disabilities and / or SLD) of our Department, prof.ssa Daniele.

## Required Prerequisites

## Attendance of Lessons

## Detailed Course Content

Basic definition on Graph Theory. Cycles and cocycles. Cyclomatic and cocyclomatic numbers. Planar graph and their property. Euler's formula. Tree and cotree. Spanning tree. Strongly and minimally connected graphs and their property. Maximum and perfect matchings. Covering and minimum covering of a graph. Matching in bipartite graph, Köenig's theorem. Hamiltonian and Eulerian graphs. Edge and vertex colourings, chromatic number and index number. Vizing's theorem. Properties of digraphs. Basic notion on Matroids

*Should teaching be carried out in mixed mode or remotely, it may be necessary to introduce changes with respect to previous statements, in line with the programme planned and outlined in the syllabus.*

*Learning assessment may also be carried out on line, should the conditions require it.*

## Textbook Information

- C. Berge, "Graph and Hypergraph", Elsevier.
- Notes of the course - E. Guardo
- M. Gionfriddo, Notes on Graph Theory 2018 (available on Studium with the permission of Prof. Hemeritus M. Gionfriddo)
- R. J. Wilson, Introduction to Graph Theory

## Course Planning

Subjects | Text References | |
---|---|---|

1 | Grafi | 1), 2), 3) |

2 | Trees and their properties | 2), 3), 4) |

3 | Eulerian and Hamiltonian Graphs | 2), 3), 4) |

4 | Grafi planari | 2) , 3) |

5 | Factorizations, Matchings | 2), 3) |

6 | Vertex colorings | 1), 2), 3) |

7 | Edge coloring | 1) , 2) , 3) |

8 | Chromatic Polynomial | 1), 2) ,3) |

9 | internal and external stability | 2), 3) |

10 | Digraphs | 1) |

11 | Network, Flows | 1) |

12 | Strngly connected graphs | 1), 2) |

13 | Matroids | 2), 4) |

14 | Basic notion on G designs and hypergraphs |

## Learning Assessment

### Learning Assessment Procedures

Final grades will be assigned taking into account the following crieria:

__Rejected__: Basic knowledges have not been acquired. The student is not able to solve simple exercises.

__18-23__: Basic knowledges have been acquired. The student solves simple exercises and has sufficient communications skills and making judgements.

__24-27__: All the knowledges have been acquired. The student solves all the proposed exercises making few errors and has good communications skills and making judgements.

__28-30 cum laude__: All the knowledges have been completely acquired. The student applies knowledge and has excellent communications skills, learning skills and making judgements.

Learning assessment may also be carried out online, should the conditions require it.

### Examples of frequently asked questions and / or exercises

Trees, Minimum Spanning trees

Eulerian and hamoltonian graphs

Planar graph and their property. Euler's formula.

Maximum and perfect matchings.

Matching in bipartite graph, Hall's Theorem Köenig's theorem.

Edge and vertex colourings, chromatic number and index number.

Properties of digraphs. Basic notion on Matroids