The brain, the immune system and the formation of clouds, are all examples of complex adaptive systems comprising of many interacting components, often non-linear and dynamic, leading to multiple levels of collective structures and organization.
Inspired by complex adaptive systems in nature, several new methods for information processing have emerged: artificial neural networks resemble neurobiology; genetic algorithms and genetic programming are based on evolutionary processes in nature; the construction of artificial life, the design of autonomous robots and software agents are based on the behaviour of living systems.
Complex adaptive systems master's programme at Chalmers
To understand the dynamics of increasingly complex phenomena where standard simulation methods are inadequate, stochastic algorithms, game theory, adaptive programming, self-similarity, chaos theory and statistical methods are used to describe and increase our understanding of complex systems in nature and society, in the end trying to predict the unpredictable. Examples are gene-regulation networks, the motion of dust particles in turbulent air or the dynamics of financial markets.
Watch a recording of the webinar about Complex adaptive systems on YouTube>> or YouKu>>
One example is fluctuations of share and option prices determining the stability of our economy. Other examples are the dynamics of dust particles in the exhaust of diesel engines, the dynamics of biological or artificial populations, earthquake prediction, and last but not least adaptive learning: the problem of teaching a robot how to respond to unexpected changes in its environment.
Truly interdisciplinary and encompassing several theoretical frameworks, this programme provides you with a broad and thorough introduction to the theory of complex systems and its applications to the world around us. You will gain the knowledge and the tools needed to model and simulate complex systems and learn how to use and build algorithms for analysis, optimization and machine learning.
The master's programme is based on a physics perspective with a focus on general principles, but it also provides courses in information theory, computer science and optimisation algorithms, ecology and genetics as well as adaptive systems and robotics.
Besides traditional lectures on simulation and theory of complex systems, the programme is largely based on numerical calculation and simulation projects. Depending on your course selection, you will also be able to do practical work in our robotics lab.
The subjects of physics, simulation, modeling, robotics and autonomous are fundamental areas in the Complex adaptive systems master's programme. The courses handle topics such as programming, agent based modelling, network theory, turbulence, genetics, game theory, biophysics, morphogenesis, synchronization, chaotic dynamics, fractals and dynamical stochastic process.
Master's programme structure
The master's programme runs for a duration of two years, leading to a Master of Science (MSc) degree. During each year, students can earn 60 credits (ECTS) and complete the programme by accumulating a total of 120 credits. Credits are earned by completing courses where each course is usually 7.5 credits. The programme consists of compulsory courses, compulsory elective courses and elective courses.
Compulsory courses year 1
During the first year the programme starts with six compulsory courses that form a common foundation in Complex adaptive system. Each course is usually 7.5 credits.
- Artificial neural networks
- Simulation of complex systems
- Stochastic optimization algorithms
- Dynamical systems
- Computational biology 1
Compulsory courses year 2
In the second year you must complete a master's thesis in order to graduate. The thesis may be worth 30 credits or 60 credits depending on your choice.
Compulsory elective courses
Through compulsory elective courses, you can make your own profile and specialize in physics/statistical physics, robotics and adaptive systems, machine learning and data science or computational biology/systems biology. During year 1 and 2, you need to select at least 3 compulsory elective courses in order to graduate.
Suggested profile courses
- Quantum mechanics
- Non-equilibrium processes
- Turbulence modelling
- Computational physics
- Computational fluid dynamics
- Information theory for complex systems
Robotics and adaptive systems
- Intelligent agents
- Humanoid robotics
- Autonomous robots
Machine learning and data science
- Statistical learning for big data
- Game theory and rationality
- Deep learning
- Introduction to AI
Computational biology/Systems biology
- Computational biology 2
- Computational methods in bioinformatics
- System biology
Other master's programmes that might interest you
Computer systems and networks, MScEngineering mathematics and computational science, MScSoftware engineering and technology, MSc
Systems, control and mechatronics, MSc
Admissions academic year 2021/22
General entry requirements
An applicant must either have a Bachelor's degree in Science/Engineering/Technology/Architecture or be enrolled in his/her last year of studies leading to such a degree.
Specific entry requirements
Bachelor’s degree with a major in: Engineering physics, Physics, Electrical engineering, Mechanical engineering, Automation and mechatronics engineering, Computer science, Computer engineering, Mathematics, Chemical engineering, Chemistry, Bioengineering or the equivalent
Prerequisites: Mathematics (at least 30 cr. including Linear algebra and Mathematical analysis) and Programming
English language requirements
Chalmers Bachelor’s degree
Are you enrolled in a Bachelor’s degree programme at Chalmers now or do you already have a Bachelor’s degree from Chalmers? If so, different application dates and application instructions apply.
Master of Science (MSc)Credits:
: Second Cycle, Master'sRate of study:
Full-time, 100%Instructional time:
DaytimeLanguage of instruction:
On-campus (Location: campus Johanneberg)Tuition fee:
140 000 SEK/academic year
*EU/EEA Citizens are not required to pay fees
Questions about the application:
Chalmers Admissions, email@example.com
Specific questions about the programme:
Mats Granath, Director of master's programme, firstname.lastname@example.org
The computer modelling and analytical skills acquired in the programme open up a wide range of possibilities on the employment market, in software development and consulting, in research and development, management, and in the financial sector. Some of our previous students have also chosen to continue towards a PhD in a wide spectrum of academic fields.
Research within Complex adaptive systems
The content of the master's programme is closely connected to the research on genetics and turbulence, information theory and adaptive systems and robotics performed at Chalmers and the University of Gothenburg. There is also a lively exchange with international research groups and regular guest lectures on current research that is often directly related to the course material. The programme also has a student project activity with the Fraunhofer-Chalmers Research Centre for Industrial Mathematics
“I have made a Siri-app for football”
Dante Landa Vega, Mexico, Complex adaptive systems
Why did you choose this programme?
– I have a background in mechatronics and was very interested in Artificial neural networks. All the research in the field is now going into machine learning and deep learning is everywhere, in our cellphones, our computers and tablets and soon in our vehicles too. There seems to be a great demand in the industry for people that can develop Artificial intelligence and I wanted to be a part of that.
What have you been working on?
– I have created an intelligent agent like Apple's Siri, but it works only for football teams. I named it Fabio after a Mexican tradition that I have with my friends when we play FIFA. You can ask Fabio questions about your favourite football team and it returns information about when they are playing the next match, their results and images. It works with three different leagues: The Premier League in England, Bundesliga in Germany and La Liga in Spain. The application itself is in the shape of a football and when it finds some information it stars to bump and rotate.
What do you like the most about your programme?
– The combination of theory and practice. Everything is built from scratch from a mathematical model, then passed on to code and then a system. And everything works from my first idea. When I finish a project, it keeps growing and improving without me which is very cool.
What do you want to do in the future?
– I would like to work with machine learning or deep learning for a company here in Sweden rather than having my own business or going for a PhD.