Litcius/Paper detail

Gauge invariant input to neural network for path optimization method

Yusuke Namekawa, Kouji Kashiwa, Akira Ohnishi, Hayato Takase

2022Physical review. D/Physical review. D.11 citationsDOIOpen Access PDF

Abstract

We investigate the efficiency of a gauge invariant input to a neural network for the path optimization method. While the path optimization with a completely gauge-fixed link-variable input has successfully tamed the sign problem in a simple gauge theory, the optimization does not work well when the gauge degrees of freedom remain. We propose to employ a gauge invariant input, such as a plaquette, to overcome this problem. The efficiency of the gauge invariant input to the neural network is evaluated for the two-dimensional $U(1)$ gauge theory with a complex coupling. The average phase factor is significantly enhanced by the path optimization with the plaquette input, indicating good control of the sign problem. It opens a possibility that the path optimization is available to complicated gauge theories, including quantum chromodynamics, in a realistic setup.

Topics & Concepts

Invariant (physics)Path (computing)Gauge (firearms)Gauge theorySign (mathematics)Gauge fixingArtificial neural networkQuantum gauge theoryLattice gauge theoryMathematicsHamiltonian lattice gauge theoryPhysicsTopology (electrical circuits)Computer scienceGauge bosonMathematical physicsMathematical analysisArtificial intelligenceCombinatoricsProgramming languageArchaeologyHistoryModel Reduction and Neural NetworksComputational Physics and Python ApplicationsAtomic and Subatomic Physics Research