Scaling Up Machine Learning For Quantum Field Theory with Equivariant Continuous Flows

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Oct 06, 2021
Pim de Haan, Corrado Rainone, Miranda Cheng, Roberto Bondesan
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We propose a continuous normalizing flow for sampling from the high-dimensional probability distributions of Quantum Field Theories in Physics. In contrast to the deep architectures used so far for this task, our proposal is based on a shallow design and incorporates the symmetries of the problem. We test our model on the $\phi^4$ theory, showing that it systematically outperforms a realNVP baseline in sampling efficiency, with the difference between the two increasing for larger lattices. On the largest lattice we consider, of size $32\times 32$, we improve a key metric, the effective sample size, from 1% to 66% w.r.t. the realNVP baseline.

* 9 pages, 4 figures  
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