Abstract
We derive machine learning algorithms from discretized Euclidean field theories, making inference and learning possible within dynamics described by quantum field theory. Specifically, we demonstrate that the $\phi^{4}$ scalar field theory satisfies the Hammersley-Clifford theorem, therefore recasting it as a machine learning algorithm within the mathematically rigorous framework of Markov random fields. We illustrate the concepts by minimizing an asymmetric distance between the probability distribution of the $\phi^{4}$ theory and that of target distributions, by quantifying the overlap of statistical ensembles between probability distributions and through reweighting to complex-valued actions with longer-range interactions. Neural network architectures are additionally derived from the $\phi^{4}$ theory which can be viewed as generalizations of conventional neural networks and applications are presented. We conclude by discussing how the proposal opens up a new research avenue, that of developing a mathematical and computational framework of machine learning within quantum field theory.
Highlights
Relativistic quantum fields [1] are formulated on Minkowski space where intricate mathematical problems related to the hyperbolic geometry emerge
We explore the implications of including a local symmetry-breaking term in the φ4 Markov random field, and rearrange the lattice topology to derive a φ4 neural network which can be viewed as a generalization of conventional neural network architectures
We recall that the local homogeneous action Af3g has coupling constant g4 1⁄4 0 and the target distribution of action Af4g includes a term with coupling constant g04 1⁄4 −1.0
Summary
Relativistic quantum fields [1] are formulated on Minkowski space where intricate mathematical problems related to the hyperbolic geometry emerge. Of high importance is the reverse direction: that of arriving at a quantum field in Minkowski space by constructing it from one in Euclidean space.
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