Difference between revisions of "ALPS 2 Tutorials:MC-01 Equilibration"
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Based on the timeseries, the user will then judge for himself/herself whether the simulation has reached equilibration. | Based on the timeseries, the user will then judge for himself/herself whether the simulation has reached equilibration. | ||
| − | ==== | + | ==== A convenient tool: steady_state_check ==== |
| − | + | ALPS Python provides a convenient tool to check whether a measurement observable(s) has (have) reached steady state equilibrium. | |
| + | |||
| + | For example: | ||
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| + | pyalps.steady_state_check(files[0], 'Density') | ||
=== Using Vistrails === | === Using Vistrails === | ||
Revision as of 16:50, 28 August 2013
Contents
Equilibration
Rule of thumb: All Monte Carlo simulations have to be equilibrated before taking measurements.
Example: Quantum Monte Carlo (directed worm algorithm) simulations
As an example, we consider a Quantum Monte Carlo simulation implemented in the directed worm algorithm for boson Hubbard model in square lattice geometry of size 202.
Using command line
The parameter file parm1a:
LATTICE="square lattice"
MODEL="boson Hubbard"
L=20
Nmax=20
t=1.
U=16.
mu=32.
THERMALIZATION=10000
SWEEPS=100000
SKIP=400
{T=1.0}
We first convert the input parameters to XML and then run the application dwa:
parameter2xml parm1a dwa parm1a.in.xml
Detailed information regarding the Density measurements, for example, can be extracted from:
h5dump -g /simulation/results/Density parm1a.task1.out.h5
or its (binned) timeseries from:
h5dump -g /simulation/results/Density/timeseries parm1a.task1.out.h5
We can extract the timeseries data into a CSV file:
h5dump -d /simulation/results/Density/timeseries/data -w 1 -y -o parm1a.task1.out.density.timeseries.csv parm1a.task1.out.h5
and plot it using your favourite graphical plotter, say xmgrace:
xmgrace parm1a.task1.out.density.timeseries.csv
or, say gnuplot:
gnuplot <<@@ set datafile separator ',' plot "parm1a.task1.out.density.timeseries.csv" @@
Based on the timeseries, the user will then judge for himself/herself whether the simulation has reached equilibration.
Using Python
The following describes what is going on within the script file tutorial1a.py.
The headers:
import pyalps
Set up a python list of parameters (python) dictionaries:
parms = [{
'LATTICE' : "square lattice",
'MODEL' : "boson Hubbard",
'L' : 20,
'Nmax' : 20,
't' : 1.,
'U' : 16.,
'mu' : 32.,
'T' : 1.,
'THERMALIZATION' : 10000,
'SWEEPS' : 100000,
'SKIP' : 400
}]
Write into XML input file:
input_file = pyalps.writeInputFiles('parm1a',parms)
and run the application dwa:
pyalps.runApplication('dwa', input_file, Tmin=10, writexml=True)
We first get the list of all hdf5 result files via:
files = pyalps.getResultFiles(prefix='parm1a', format='hdf5')
and then extract, say the timeseries of the Density measurements:
ar = pyalps.hdf5.h5ar(files[0]) density_timeseries = ar['/simulation/results']['Density']['timeseries']['data']
We can then visualize graphically:
import matplotlib.pyplot as plt plt.plot(density_timeseries) plt.show()
Based on the timeseries, the user will then judge for himself/herself whether the simulation has reached equilibration.
A convenient tool: steady_state_check
ALPS Python provides a convenient tool to check whether a measurement observable(s) has (have) reached steady state equilibrium.
For example:
pyalps.steady_state_check(files[0], 'Density')
