Fermions and Supersymmetry in Neural Network Field Theories
By: Samuel Frank , James Halverson , Anindita Maiti and more
Potential Business Impact:
Builds new computer models for physics.
We introduce fermionic neural network field theories via Grassmann-valued neural networks. Free theories are obtained by a generalization of the Central Limit Theorem to Grassmann variables. This enables the realization of the free Dirac spinor at infinite width and a four fermion interaction at finite width. Yukawa couplings are introduced by breaking the statistical independence of the output weights for the fermionic and bosonic fields. A large class of interacting supersymmetric quantum mechanics and field theory models are introduced by super-affine transformations on the input that realize a superspace formalism.
Similar Papers
Viability of perturbative expansion for quantum field theories on neurons
High Energy Physics - Theory
Helps computers understand tiny particle rules.
Fermionic neural Gibbs states
Quantum Physics
Models how tiny particles behave when hot.
Quantum Mechanics and Neural Networks
High Energy Physics - Theory
Makes quantum physics work like computer programs.