Abstract

We discuss a possibility that the entire universe on its most fundamental level is a neural network. We identify two different types of dynamical degrees of freedom: “trainable” variables (e.g., bias vector or weight matrix) and “hidden” variables (e.g., state vector of neurons). We first consider stochastic evolution of the trainable variables to argue that near equilibrium their dynamics is well approximated by Madelung equations (with free energy representing the phase) and further away from the equilibrium by Hamilton–Jacobi equations (with free energy representing the Hamilton’s principal function). This shows that the trainable variables can indeed exhibit classical and quantum behaviors with the state vector of neurons representing the hidden variables. We then study stochastic evolution of the hidden variables by considering D non-interacting subsystems with average state vectors, , …, and an overall average state vector . In the limit when the weight matrix is a permutation matrix, the dynamics of can be described in terms of relativistic strings in an emergent dimensional Minkowski space-time. If the subsystems are minimally interacting, with interactions that are described by a metric tensor, and then the emergent space-time becomes curved. We argue that the entropy production in such a system is a local function of the metric tensor which should be determined by the symmetries of the Onsager tensor. It turns out that a very simple and highly symmetric Onsager tensor leads to the entropy production described by the Einstein–Hilbert term. This shows that the learning dynamics of a neural network can indeed exhibit approximate behaviors that were described by both quantum mechanics and general relativity. We also discuss a possibility that the two descriptions are holographic duals of each other.

Highlights

  • Quantum mechanics is a remarkably successful paradigm for modeling physical phenomena on a wide range of scales ranging from 10−19 m to 10+26 m The paradigm is so successful that it is widely believed that, on the most fundamental level, the entire universe is governed by the rules of quantum mechanics and even gravity should somehow emerge from it

  • We discussed a possibility that the entire universe on its most fundamental level is a neural network

  • It turns out that the dynamics of neural networks is so complex that one can only understand it in very specific limits

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Summary

Introduction

Quantum mechanics is a remarkably successful paradigm for modeling physical phenomena on a wide range of scales ranging from 10−19 m (i.e., high-energy experiments) to 10+26 m (i.e., cosmological observations.) The paradigm is so successful that it is widely believed that, on the most fundamental level, the entire universe is governed by the rules of quantum mechanics and even gravity should somehow emerge from it. We shall first demonstrate that near equilibrium the learning evolution of a neural network can be modeled (or approximated) with the Madelung equations (see Section 5), where the phase of the complex wave-function has a precise physical interpretation as the free energy of a statistical ensemble of hidden variables. The classical limit is relevant when the non-equilibrium evolution of the trainable variables is dominated by the entropy destruction, due to learning, but the stochastic entropy production is negligible The dynamics of such a system is well approximated by the Hamilton–Jacobi equations with free energy playing the role of the Hamilton’s principal function (see Section 6).

Neural Networks
Thermodynamics of Learning
Entropic Mechanics
Quantum Mechanics
Hamiltonian Mechanics
Hidden Variables
Relativistic Strings
Emergent Gravity
10. Holography
11. Discussion

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