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mc_nvt_lj.py
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executable file
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#!/usr/bin/env python3
# mc_nvt_lj.py
#------------------------------------------------------------------------------------------------#
# This software was written in 2016/17 #
# by Michael P. Allen <m.p.allen@warwick.ac.uk>/<m.p.allen@bristol.ac.uk> #
# and Dominic J. Tildesley <d.tildesley7@gmail.com> ("the authors"), #
# to accompany the book "Computer Simulation of Liquids", second edition, 2017 ("the text"), #
# published by Oxford University Press ("the publishers"). #
# #
# LICENCE #
# Creative Commons CC0 Public Domain Dedication. #
# To the extent possible under law, the authors have dedicated all copyright and related #
# and neighboring rights to this software to the PUBLIC domain worldwide. #
# This software is distributed without any warranty. #
# You should have received a copy of the CC0 Public Domain Dedication along with this software. #
# If not, see <http://creativecommons.org/publicdomain/zero/1.0/>. #
# #
# DISCLAIMER #
# The authors and publishers make no warranties about the software, and disclaim liability #
# for all uses of the software, to the fullest extent permitted by applicable law. #
# The authors and publishers do not recommend use of this software for any purpose. #
# It is made freely available, solely to clarify points made in the text. When using or citing #
# the software, you should not imply endorsement by the authors or publishers. #
#------------------------------------------------------------------------------------------------#
"""Monte Carlo, NVT ensemble."""
def calc_variables ( ):
"""Calculates all variables of interest.
They are collected and returned as a list, for use in the main program.
"""
# In this example we simulate using the cut (but not shifted) potential
# The values of < p_c >, < e_c > and density should be consistent (for this potential)
# For comparison, long-range corrections are also applied to give
# estimates of < e_f > and < p_f > for the full (uncut) potential
# The value of the cut-and-shifted potential is not used, in this example
import numpy as np
import math
from averages_module import msd, VariableType
from lrc_module import potential_lrc, pressure_lrc, pressure_delta
from mc_lj_module import force_sq
# Preliminary calculations (n,r,total are taken from the calling program)
vol = box**3 # Volume
rho = n / vol # Density
fsq = force_sq ( box, r_cut, r ) # Total squared force
# Variables of interest, of class VariableType, containing three attributes:
# .val: the instantaneous value
# .nam: used for headings
# .method: indicating averaging method
# If not set below, .method adopts its default value of avg
# The .nam and some other attributes need only be defined once, at the start of the program,
# but for clarity and readability we assign all the values together below
# Move acceptance ratio
m_r = VariableType ( nam = 'Move ratio', val = m_ratio, instant = False )
# Internal energy per atom for simulated, cut, potential
# Ideal gas contribution plus cut (but not shifted) PE divided by N
e_c = VariableType ( nam = 'E/N cut', val = 1.5*temperature + total.pot/n )
# Internal energy per atom for full potential with LRC
# LRC plus ideal gas contribution plus cut (but not shifted) PE divided by N
e_f = VariableType ( nam = 'E/N full', val = potential_lrc(rho,r_cut) + 1.5*temperature + total.pot/n )
# Pressure for simulated, cut, potential
# Delta correction plus ideal gas contribution plus total virial divided by V
p_c = VariableType ( nam = 'P cut', val = pressure_delta(rho,r_cut) + rho*temperature + total.vir/vol )
# Pressure for full potential with LRC
# LRC plus ideal gas contribution plus total virial divided by V
p_f = VariableType ( nam = 'P full', val = pressure_lrc(rho,r_cut) + rho*temperature + total.vir/vol )
# Configurational temperature
# Total squared force divided by total Laplacian
t_c = VariableType ( nam = 'T config', val = fsq/total.lap )
# Heat capacity (full)
# MSD potential energy divided by temperature and sqrt(N) to make result intensive; LRC does not contribute
# We add ideal gas contribution, 1.5, afterwards
c_f = VariableType ( nam = 'Cv/N full', val = total.pot/(temperature*math.sqrt(n)),
method = msd, add = 1.5, instant = False )
# Collect together into a list for averaging
return [ m_r, e_c, p_c, e_f, p_f, t_c, c_f ]
# Takes in a configuration of atoms (positions)
# Cubic periodic boundary conditions
# Conducts Monte Carlo at the given temperature
# Uses no special neighbour lists
# Reads several variables and options from standard input using JSON format
# Leave input empty "{}" to accept supplied defaults
# Positions r are divided by box length after reading in
# However, input configuration, output configuration, most calculations, and all results
# are given in simulation units defined by the model
# For example, for Lennard-Jones, sigma = 1, epsilon = 1
# Despite the program name, there is nothing here specific to Lennard-Jones
# The model is defined in mc_lj_module
import json
import sys
import numpy as np
import math
from platform import python_version
from config_io_module import read_cnf_atoms, write_cnf_atoms
from averages_module import run_begin, run_end, blk_begin, blk_end, blk_add
from maths_module import random_translate_vector, metropolis
from mc_lj_module import introduction, conclusion, potential, potential_1, PotentialType
cnf_prefix = 'cnf.'
inp_tag = 'inp'
out_tag = 'out'
sav_tag = 'sav'
print('mc_nvt_lj')
print('Python: '+python_version())
print('NumPy: '+np.__version__)
print()
print('Monte Carlo, constant-NVT ensemble')
print('Simulation uses cut (but not shifted) potential')
# Read parameters in JSON format
try:
nml = json.load(sys.stdin)
except json.JSONDecodeError:
print('Exiting on Invalid JSON format')
sys.exit()
# Set default values, check keys and typecheck values
defaults = {"nblock":10, "nstep":1000, "temperature":1.0, "r_cut":2.5, "dr_max":0.15}
for key, val in nml.items():
if key in defaults:
assert type(val) == type(defaults[key]), key+" has the wrong type"
else:
print('Warning', key, 'not in ',list(defaults.keys()))
# Set parameters to input values or defaults
nblock = nml["nblock"] if "nblock" in nml else defaults["nblock"]
nstep = nml["nstep"] if "nstep" in nml else defaults["nstep"]
temperature = nml["temperature"] if "temperature" in nml else defaults["temperature"]
r_cut = nml["r_cut"] if "r_cut" in nml else defaults["r_cut"]
dr_max = nml["dr_max"] if "dr_max" in nml else defaults["dr_max"]
introduction()
np.random.seed()
# Write out parameters
print( "{:40}{:15d} ".format('Number of blocks', nblock) )
print( "{:40}{:15d} ".format('Number of steps per block', nstep) )
print( "{:40}{:15.6f}".format('Specified temperature', temperature) )
print( "{:40}{:15.6f}".format('Potential cutoff distance', r_cut) )
print( "{:40}{:15.6f}".format('Maximum displacement', dr_max) )
# Read in initial configuration
n, box, r = read_cnf_atoms ( cnf_prefix+inp_tag)
print( "{:40}{:15d} ".format('Number of particles', n) )
print( "{:40}{:15.6f}".format('Box length', box) )
print( "{:40}{:15.6f}".format('Density', n/box**3) )
r = r / box # Convert positions to box units
r = r - np.rint ( r ) # Periodic boundaries
# Initial energy and overlap check
total = potential ( box, r_cut, r )
assert not total.ovr, 'Overlap in initial configuration'
# Initialize arrays for averaging and write column headings
m_ratio = 0.0
run_begin ( calc_variables() )
for blk in range(1,nblock+1): # Loop over blocks
blk_begin()
for stp in range(nstep): # Loop over steps
moves = 0
for i in range(n): # Loop over atoms
rj = np.delete(r,i,0) # Array of all the other atoms
partial_old = potential_1 ( r[i,:], box, r_cut, rj ) # Old atom potential, virial etc
assert not partial_old.ovr, 'Overlap in current configuration'
ri = random_translate_vector ( dr_max/box, r[i,:] ) # Trial move to new position (in box=1 units)
ri = ri - np.rint ( ri ) # Periodic boundary correction
partial_new = potential_1 ( ri, box, r_cut, rj ) # New atom potential, virial etc
if not partial_new.ovr: # Test for non-overlapping configuration
delta = partial_new.pot - partial_old.pot # Use cut (but not shifted) potential
delta = delta / temperature
if metropolis ( delta ): # Accept Metropolis test
total = total + partial_new - partial_old # Update total values
r[i,:] = ri # Update position
moves = moves + 1 # Increment move counter
m_ratio = moves / n
blk_add ( calc_variables() )
blk_end(blk) # Output block averages
sav_tag = str(blk).zfill(3) if blk<1000 else 'sav' # Number configuration by block
write_cnf_atoms ( cnf_prefix+sav_tag, n, box, r*box ) # Save configuration
run_end ( calc_variables() )
total = potential ( box, r_cut, r ) # Double check book-keeping
assert not total.ovr, 'Overlap in final configuration'
write_cnf_atoms ( cnf_prefix+out_tag, n, box, r*box ) # Save configuration
conclusion()