Eliminating critical slowing down in Monte Carlo calculations
Luehrmann, Mia Kerstin
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https://hdl.handle.net/2142/23870
Description
Title
Eliminating critical slowing down in Monte Carlo calculations
Author(s)
Luehrmann, Mia Kerstin
Issue Date
1991
Doctoral Committee Chair(s)
Stack, John D.
Department of Study
Physics
Discipline
Physics
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
monte carlo
slowing down in monte carlo calculations
lattice field theory
Metropolis
heat bath Monte Carlo
Critical Slowing Down (CSD)
Language
en
Abstract
We examine methods to improve the major numerical difficulties in lattice field
theory. Traditional Metropolis and heat bath Monte Carlo methods in lattice calculations
break down whenever one tries to calculate thermodynamic quantities near critical points;
this phenomenon is called Critical Slowing Down, (CSD). Recently, alternate methods
have been proposed to shorten the relaxation time and thereby, reduce CSD. These
methods all modify site-by-site Metropolis and heat bath Monte Carlo to operate on larger
spacial scales. One of these newer techniques is to apply multigrid methods to site-by-site
Monte Carlo algorithms; another is to stochastically determine clusters of sites on the lattice
by simplifying the Hamiltonian until it is determinate.
We have applied both techniques to the Ising model and compared the relaxation time
constants to those determined by site-by-site Monte Carlo methods and found that they are
lower. However, even after we succeeded in vectorizing the algorithms, the computation
time needed to calculate each sweep of the lattice is larger than that needed by the site-bysite
Monte Carlo methods. The important quantity is the computation time needed to move
from one independent configuration to another, which is the time needed to calculate each
sweep of the lattice multiplied by the relaxation time constant. The net result of the
Multigrid Monte Carlo method is that it is less efficient than regular Monte Carlo whenever
the parameters of the algorithm are fixed such that the algorithm satisfies detailed balance.
The net effect of the Stochastic Blocking method is an improvement compared to regular
Monte Carlo when the coupling constant is close to the critical point. We believe the
methods used here can be adapted to lattice gauge theory calculations.
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