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Confirmed Speakers

  • Andreas Daffertshofer, Amsterdam Movement Sciences & Institute for Brain and Behavior Amsterdam, Vrije Universiteit Amsterdam, Netherlands

  • Alexey Ustinov, Physikalisches Institut, Karlsruhe Institute of Technology, Germany

  • Christian Bick, Department of Mathematics, University of Exeter, United Kingdom

  • Canceled: Marc Timme, TU Dresden, Germany

  • Mogens H. Jensen, Niels Bohr Institute, University of Copenhagen, Denmark

  • Jean-Guy Caputo, Laboratoire de Mathématiques de l'INSA Rouen France

  • Elisenda Feliu, Department of Mathematics, Copenhagen University, Denmark

  • Frank Hellmann, Potsdam Institute for Climate Impact Research, Potsdam, Germany

  • Peter Ditlevsen, Niels Bohr Institute, Copenhagen University, Denmark

  • Kim Sneppen, Niels Bohr Institute, Copenhagen University, Denmark

  • Canceled: Johnny Ottesen, Group for Mathematical Health and Disease Modeling, Dept. of Science, Roskilde University, Denmark

  • Namiko Mitarai, Niels Bohr Institute, Copenhagen University, Denmark

  • Niels Grønbech-Jensen, Department of Mechanical and Aerospace Engineering & Department of Mathematics, UC Davis, USA

  • Hyunsuk Hong, Chonbuk National University, South Korea

  • Krasimira Tsaneva-Atanasova, Department of Mathematics, University of Exeter, United Kingdom

  • Sandeep Krishna, National Centre for Biological Sciences, Tata Institute for Fundamental Research, Bangalore, India

  • Camille Poignard, Dept. of Mathematics, University of Exeter, United Kingdom

  • Marius Yamakou, Max Planck Institute for Mathematics in Sciences, Leipzig, Germany

  • Konstantin Klemm, IFISC, University of the Balearic Islands, Spain

  • Jason Hindes, Nonlinear Dynamical Systems Section, U.S. Naval Research Laboratory, Washington, USA

  • Piotr Slowiński, University of Exeter, United Kingdom

  • Henrik Lindén, Department of Neuroscience, University of Copenhagen, Denmark

  • Hans True, Dept. of Applied Mathematics and Computer Science, Technical University of Denmark, Denmark

  • Chuang Xu, Department of Mathematical Sciences, University of Copenhagen, Denmark

About the Workshop

Networks pervade all areas in nature and technology, from statistical physics over engineering to biology, and from small to large scales. Complex networks are omnipresent and play a vital role in in our every-day lives, coordinating complex interactions on the level of cells, organisms and of society. Interacting units in such networks are for instance wind turbine generators, neurons, pacemaker cells in the heart, all of which obey dynamic behaviors such as oscillations. When connected in a network, these units may exhibit a collective dynamics which may serve functions such as information processing in the brain or robust delivery of power in the electric grid.

Previous research yielded many valuable insights into the significance of network structures in our every-day biological and technological life; but today, researchers are about to face and tackle new challenges: to function properly, systems in biology and technology must often operate in a non-steady, out-of-equilibrium state; in fact, they are constantly subject to varying levels of (stochastic) fluctuations and heterogeneities which may lead to non-uniform dynamic behaviors within the network. However, uniform (or non-uniform) behavior on a large-scale may be either undesired or preferable, depending on the context. For instance, if all neurons in our brain entrain to the same rhythmic activity, the resulting epileptic seizure compromises normal brain function; conversely, generators and consumers in the power grid need to stay (uniformly) synchronized to maintain optimal power transmission and to avoid costly power outages (black-out).

Thus, pressing questions manifest themselves, including: how do fluctuations or transients spread through the network and affect its dynamics, potentially destabilizing the system? On the other hand, how can the network be controlled to maintain and serve its function? Can we quantify fundamental properties such as the dimensionality of the network and reduce apparently large complex systems to smaller systems that are simpler to analyze and understand? Such questions are not merely of theoretical interest; but they bear tremendous significance to understanding the proper operation of novel smart networks we design (traffic and power networks), the function of the brain, or the complex biomic network in our human body. Clearly, we need to get a better understanding of such systems if we are to tackle next-generation challenges regarding engineering infrastructures or disease.

Our interdisciplinary workshop gathers researchers from fields lying at the boundary of biology, technology, physics and mathematics. The workshop aims at discussing the state-of the-art and emerging problems concerning dynamic interactions in complex dynamic networks, such as power grid dynamics, transport networks, brain/neural dynamics, systems biology from cell to body level, and the mathematical/physical theory of oscillation and network dynamics.


2010 Erik (technique by Sven)