FI:PA217 AI for Games - Course Information
PA217 Artificial Intelligence for Computer Games
Faculty of InformaticsSpring 2025
- Extent and Intensity
- 2/0/0. 2 credit(s) (plus extra credits for completion). Recommended Type of Completion: zk (examination). Other types of completion: k (colloquium).
In-person direct teaching - Teacher(s)
- doc. Mgr. Hana Rudová, Ph.D. (lecturer)
RNDr. Vojtěch Brůža (assistant)
Bc. Vladimír Žbánek (assistant) - Guaranteed by
- doc. Mgr. Hana Rudová, Ph.D.
Department of Machine Learning and Data Processing – Faculty of Informatics
Supplier department: Department of Machine Learning and Data Processing – Faculty of Informatics - Prerequisites
- PV255 Game Development I || SOUHLAS
For completion as an examination, the base knowledge of Unity is required. If PV255 is not successfully passed, the student must demonstrate a representative set of projects solved in Unity. Based on that, course enrollment is confirmed or not. The projects should be sent to the teacher by the beginning of the semester (or in the first week of the semester).
For completion as a colloquium, the prerequisite of PV255 is not required for the course enrollment (agreement is guaranteed). - Course Enrolment Limitations
- The course is also offered to the students of the fields other than those the course is directly associated with.
- fields of study / plans the course is directly associated with
- Image Processing and Analysis (programme FI, N-VIZ)
- Bioinformatics and systems biology (programme FI, N-UIZD)
- Computer Games Development (programme FI, N-VIZ_A)
- Computer Graphics and Visualisation (programme FI, N-VIZ_A)
- Computer Networks and Communications (programme FI, N-PSKB_A)
- Cybersecurity Management (programme FI, N-RSSS_A)
- Formal analysis of computer systems (programme FI, N-TEI)
- Graphic design (programme FI, N-VIZ)
- Graphic Design (programme FI, N-VIZ_A)
- Hardware Systems (programme FI, N-PSKB_A)
- Hardware systems (programme FI, N-PSKB)
- Image Processing and Analysis (programme FI, N-VIZ_A)
- Information security (programme FI, N-PSKB)
- Information Security (programme FI, N-PSKB_A)
- Quantum and Other Nonclassical Computational Models (programme FI, N-TEI)
- Computer graphics and visualisation (programme FI, N-VIZ)
- Computer Networks and Communications (programme FI, N-PSKB)
- Principles of programming languages (programme FI, N-TEI)
- Cybersecurity management (programme FI, N-RSSS)
- Services development management (programme FI, N-RSSS)
- Software Systems Development Management (programme FI, N-RSSS)
- Services Development Management (programme FI, N-RSSS_A)
- Software Systems Development Management (programme FI, N-RSSS_A)
- Software Systems (programme FI, N-PSKB_A)
- Software systems (programme FI, N-PSKB)
- Machine learning and artificial intelligence (programme FI, N-UIZD)
- Computer Games Development (programme FI, N-VIZ)
- Processing and analysis of large-scale data (programme FI, N-UIZD)
- Natural language processing (programme FI, N-UIZD)
- Course objectives
- The course provides information about methods of artificial intelligence used for the development of computer games. Students will learn about data structures and algorithms from artificial intelligence needed for movement, pathfinding, decision making for a single character, strategy, and tactics. Students passing the course using the examination will have practical experience with AI programming.
- Learning outcomes
- The graduate will be able to apply artificial intelligence algorithms and approaches in computer games.
The graduate will learn how to propose and implement the movement of AI characters in games.
The graduate will learn the basics of search algorithms, how to represent worlds in games, and how to process and implement path planning in games.
The graduate will understand principles and approaches for the decision making of a single AI character and will be aware of the principles and ideas behind strategic and tactical behaviors for groups of AI characters.
The graduate will learn what the base algorithms behind board games are.
When passing the course using the examination, the graduate will know how to implement artificial intelligence algorithms in the game engine by coding in Unity. - Syllabus
- Introduction and history.
- Movement: kinematic movement, steering behaviors, combining steering behaviors.
- Search and pathfinding: introduction to search algorithms, A* data structures and heuristics, world representation, hierarchical pathfinding.
- Decision making for a single character: decision trees, state machines, behavior trees, fuzzy logic, Markov systems, goal-oriented behavior, rule-based systems, blackboard architectures, action execution.
- Strategy and tactics: tactical waypoints, tactical analyses, tactical pathfinding, coordinated action.
- Board games: minimaxing, transposition tables, Monte Carlo search.
- Implementation of AI algorithms in Unity.
- Literature
- Millington, I. Artificial intelligence for games. CRC Press, 3rd edition, 2019.
- Unity artificial intelligence programming. Edited by Davide Aversa. Fifth edition. Birmingham, UK: Packt Publishing, 2022, 1 online. ISBN 1803238534. URL info
- Yannakakis, G. N., Togelius, J., Artificial Intelligence and Games. Springer, 2018.
- Buckland, M., Programming Game AI by Example, Jones & Bartlett Learning, 2004.
- Teaching methods
- Standard lecture, no drills. Three homeworks including AI programming in Unity (when passing the course using the examination). Activity in lectures is encouraged by getting bonus points.
- Assessment methods
- When passing the course using an examination, the evaluation is given as a sum of points for homeworks, the final exam, and bonus points for activities at lectures: A more than 90, B 89-80, C 79-70, D 69-60, E 59-55.
It is possible to get up to 70 points for the final written exam; it is obligatory to get at least 40 out of 70 points.
There are three homeworks during the semester. Each student is required to obtain 16 points, at least from the total point of 30 points.
Also, each student can get 1 bonus point for activity in each lecture (1 point: student response to several easy questions and/or student questions to clarify some part of the lecture, student response to one harder question), i.e., it is possible to about 12 bonus points for activity based on the number of lectures.
When passing the course using a colloquium, it is required to get at least 40 out of 70 points from the final written exam (there are no other requirements). - Language of instruction
- English
- Further Comments
- The course is taught annually.
The course is taught: every week. - Teacher's information
- https://is.muni.cz/el/fi/jaro2024/PA217/index.qwarp
- Enrolment Statistics (recent)
- Permalink: https://is.muni.cz/course/fi/spring2025/PA217