Computer techniques for lattice gauge theories

The most promising approach to the solution of the theory of strong interactions is large scale numerical simulation using the techniques of lattice gauge theory. At the present time, computing requirements for convincing calculations of the properties of hadrons exceed the capabilities of even the

We describe a compact, optimized algorithm for analyzing the mutual geometric relations between links and elementary squares in a d-dimensional lattice. The algorithm is used to compute plaquettes in Monte Carlo simulations of gauge field dynamics. In such kind of applications our algorithm, due to

The functional integral for a four-dimensional abelian anomalous gauge theory is constructed by taking constraints and anomalies into account. It is found to differ from the nai've Lagrangian form. A gauge invariant reformulation is possible, provided (gauge-) covariant anomalies are used. In both f

Random-lattice fermions have been shown to be free of the doubling problem if there are no interactions or interactions of a non-gauge nature. However, gauge interactions impose stringent constraints as expressed by the Ward-Takahashi identities which could revive the free-field suppressed doubler m