87997 - Physics of Complex Systems

Academic Year 2024/2025

  • Teaching Mode: Traditional lectures
  • Campus: Bologna
  • Corso: Second cycle degree programme (LM) in Physics (cod. 9245)

Learning outcomes

At the end of the course the student will have the basic knowledge of Complex Systems Physics with application to biological and social systems. He/she will acquire theoretical tools to analyze, predict and control the evolution of models, including: - statistical physics and dynamical system theory of complex systems; - dynamics of systems on network structures; - stochastic thermodynamics; - stochastic dynamical systems.

Course contents

Complex Systems Physics

Main objective: to join the methodologies of Statistical Mechanics, that studies the equilibrium states of many dimensional systems, with the results of Dynamical Systems Theory, that usually considers low dimensional systems. This objective is related to one of the main goal of Complex Systems Physics, that is to develop the non-equilibrium Statistical Physics.

Contents of the course

Introduction to the Dynamical Systems theory: integrable and chaotic systems, stability analysis, linear and nonlinear resonance, the definition of Lyapunov exponents and the concept of attractors, emergent properties.

Introduction to perturbation theory, averaging theorems and element of adiabatic invariant theory.

The probabilistic approach to describe chaotic dynamics, Gibbs Entropy and Kolmogorov-Sinai entropy rate for a dynamical system, conditional entropy. Relation between entropy and the concept of predictability for dynamical systems.

Definition of Stochastic processes and Markov processes. Master equation as continuity equation. Entropy rate of a stochastic process, maximum entropy principles to characterize the equilibrium states, non-equilibrium stationary states.

Wiener process, Ito integral and stochastic differential equations. Stochastic dynamical systems and stochastically perturbed dynamical systems, Fokker Planck equation for diffusion processes, transition rate theory (Kramers' theory), theory of stochastic resonance.

Examples of complex systems models: compartmental models, Lotka Volterra models, traffic models, opinion model, cellular automata, nonlinear neural networks, master equations for biological systems, diffusion on graphs (transport networks), reaction diffusion models.

Readings/Bibliography

Materials and notes provided during the lessons

Gregoire Nicolis, Catherine Nicolis Foundations of Complex Systems Nonlinear Dynamics, Statistical Physics, Information and Prediction World Scientific, 3 set 2007

Yaneer Bar-yam Dynamics Of Complex Systems Perseus Books Cambridge, MA, USA ©1997

Nino Boccara "Modeling Complex Systems" Graduate Text in Contemporary Physics, Springer, 2004
Per Bak "How Nature Works: The Science of Self-Organised Criticality" New York, NY: Copernicus Press, 1996

N. G. Van Kampen, Stochastic Processes in Physics and Chemistry. Elsevier, 2007.

V. I. Arnold, A. Avez, Ergodic Problems of Classical Mechanics, Addison-Wesley

T. M. Cover, J. A. Thomas, Elements of Information Theory, Wiley

Teaching methods

Frontal lessons and use of computational models

Assessment methods

Presentation of a project/essay on a topic related to the topics discussed during the course, with possible questions on the course program

Teaching tools

use of computer for model simulations

Office hours

See the website of Armando Bazzani