Learning Generative Models for Active Inference using Tensor Networks

Autor(en)

Samuel T Wauthier, Bram Vanhecke, Tim Verbelen, Bart Dhoedt

Abstrakt

Abstract. Active inference provides a general framework for behavior
and learning in autonomous agents. It states that an agent will attempt
to minimize its variational free energy, defined in terms of beliefs over
observations, internal states and policies. Traditionally, every aspect of a
discrete active inference model must be specified by hand, i.e. by manually
defining the hidden state space structure, as well as the required distributions such as likelihood and transition probabilities. Recently, efforts
have been made to learn state space representations automatically from
observations using deep neural networks. In this paper, we present a novel
approach of learning state spaces using quantum physics-inspired tensor
networks. The ability of tensor networks to represent the probabilistic
nature of quantum states as well as to reduce large state spaces makes
tensor networks a natural candidate for active inference. We show how
tensor networks can be used as a generative model for sequential data.
Furthermore, we show how one can obtain beliefs from such a generative
model and how an active inference agent can use these to compute the
expected free energy. Finally, we demonstrate our method on the classic
T-maze environment.

Organisation(en)

Quantenoptik, Quantennanophysik und Quanteninformation

Externe Organisation(en)

Ghent University

Anzahl der Seiten

14

Publikationsdatum

10-2022

ÖFOS 2012

102019 Machine Learning

Schlagwörter

Link zum Portal

https://ucrisportal.univie.ac.at/de/publications/dd855ec6-082d-4d6b-9eb2-5ea71aeeda6d