In this workshop we will explore how to use physical intuition and ideas to design new classes of machine learning (ML) algorithms. Physics-inspired sampling algorithms could be used to train ML structures or sample the hyper-parameter space (e.g. deep Neural Networks). Additionally, physics-based models such as Ising/Potts models or energy-based models have influenced ML inference frameworks such as Markov Random Fields and Restricted Boltzmann Machines, and we want to continue the discussion to facilitate this innovation transfer. Finally, physical insight could be used to enhance learning in the situation of scarce data by enforcing smoothness, differentiability or other physical properties relevant to a given problem. We will also explore the use of Koopmans’ theorem to design learning algorithms for dynamical systems. Finally, we will discuss and try to promote theories from physics and mathematics that can help us understand and systematize the deep learning framework.
This workshop will include a poster session; a request for posters will be sent to registered participants in advance of the workshop.
(Facebook, Canadian Institute for Advanced Research)
Matthias Rupp (Citrine Informatics & Fritz-Haber-Institut der Max-Planck-Gesellschaft)
Lenka Zdeborová (Commissariat à l'Énergie Atomique (CEA))
Riccardo Zecchina (Bocconi University)