2,331 research outputs found
Path optimization method for the sign problem
We propose a path optimization method (POM) to evade the sign problem in the
Monte-Carlo calculations for complex actions. Among many approaches to the sign
problem, the Lefschetz-thimble path-integral method and the complex Langevin
method are promising and extensively discussed. In these methods, real field
variables are complexified and the integration manifold is determined by the
flow equations or stochastically sampled. When we have singular points of the
action or multiple critical points near the original integral surface, however,
we have a risk to encounter the residual and global sign problems or the
singular drift term problem. One of the ways to avoid the singular points is to
optimize the integration path which is designed not to hit the singular points
of the Boltzmann weight. By specifying the one-dimensional integration-path as
and by optimizing to enhance the average
phase factor, we demonstrate that we can avoid the sign problem in a
one-variable toy model for which the complex Langevin method is found to fail.
In this proceedings, we propose POM and discuss how we can avoid the sign
problem in a toy model. We also discuss the possibility to utilize the neural
network to optimize the path.Comment: Talk given at the 35th International Symposium on Lattice Field
Theory, 18-24 June 2017, Granada, Spain. 8 pages, 4 figures (references are
updated in v2
Lefschetz thimbles in fermionic effective models with repulsive vector-field
We discuss two problems in complexified auxiliary fields in fermionic
effective models, the auxiliary sign problem associated with the repulsive
vector-field and the choice of the cut for the scalar field appearing from the
logarithmic function. In the fermionic effective models with attractive scalar
and repulsive vector-type interaction, the auxiliary scalar and vector fields
appear in the path integral after the bosonization of fermion ilinears. When we
make the path integral well-defined by the Wick rotation of the vector field,
the oscillating Boltzmann weight appears in the partition function. This
"auxiliary" sign problem can be solved by using the Lefschetz-thimble
path-integral method, where the integration path is constructed in the complex
plane. Another serious obstacle in the numerical construction of Lefschetz
thimbles is caused by singular points and cuts induced by multivalued functions
of the complexified scalar field in the momentum integration. We propose a new
prescription which fixes gradient flow trajectories on the same Riemann sheet
in the flow evolution by performing the momentum integration in the complex
domain.Comment: 6 pages, 5 figure
Toward solving the sign problem with path optimization method
We propose a new approach to circumvent the sign problem in which the
integration path is optimized to control the sign problem. We give a trial
function specifying the integration path in the complex plane and tune it to
optimize the cost function which represents the seriousness of the sign
problem. We call it the path optimization method. In this method, we do not
need to solve the gradient flow required in the Lefschetz-thimble method and
then the construction of the integration-path contour arrives at the
optimization problem where several efficient methods can be applied. In a
simple model with a serious sign problem, the path optimization method is
demonstrated to work well; the residual sign problem is resolved and precise
results can be obtained even in the region where the global sign problem is
serious.Comment: 4 pages, 6 figure
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