The Hintons in your Neural Network: a Quantum Field Theory View of Deep Learning

Roberto Bondesan; Max Welling

2021 ICML ICML 2021

The Hintons in your Neural Network: a Quantum Field Theory View of Deep Learning

Abstract

In this work we develop a quantum field theory formalism for deep learning, where input signals are encoded in Gaussian states, a generalization of Gaussian processes which encode the agent’s uncertainty about the input signal. We show how to represent linear and non-linear layers as unitary quantum gates, and interpret the fundamental excitations of the quantum model as particles, dubbed “Hintons”. On top of opening a new perspective and techniques for studying neural networks, the quantum formulation is well suited for optical quantum computing, and provides quantum deformations of neural networks that can be run efficiently on those devices. Finally, we discuss a semi-classical limit of the quantum deformed models which is amenable to classical simulation.

🌉 Interdisciplinary Bridge — Deep Learning and Machine Learning

🧭 Keyword Pioneer — quantum field theory

🐝 Cross-Pollinator — Artificial Intelligence, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Speech & Audio

📈 Trend Setter — Quantum Computing

🐣 Hot Topic Early Bird — quantum computing

Authors

Roberto Bondesan , Max Welling

Topics

Machine Learning > Optimization & Theory > Theory Deep Learning > Architectures > Neural Networks Deep Learning > Models > Generative Models Interdisciplinary > Science > Quantum Computing Deep Learning > Optimization & Theory > Theory

Keywords

gaussian processes deep learning theory quantum computing deep learning gaussian process optical computing generative model quantum field theory neural network quantum gate

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