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Adds the Environment, External, Utils folder inside de DPpack. All classes are going to be implemented there
This commit is contained in:
Vitor Hideyoshi
2022-05-31 09:13:08 -03:00
parent f4e892cf34
commit 4ae8385918
23 changed files with 3458 additions and 3611 deletions
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diceplayer/DPpack/Environment/System.py Normal file
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from diceplayer.DPpack.Utils.PTable import *
from diceplayer.DPpack.Utils.Misc import *
from diceplayer.DPpack.Environment.Molecule import ANG2BOHR, BOHR2ANG, Molecule
from diceplayer.DPpack.Environment.Atom import Atom
from typing import IO, Final, Tuple, List, TextIO
from numpy import linalg
import numpy as np
from copy import deepcopy
import sys, math
import sys
import math
BOHR2ANG: Final[float] = 0.52917721092
ANG2BOHR: Final[float] = 1 / BOHR2ANG
class System:
"""
System class declaration. This class is used throughout the DicePlayer program to represent the system containing the molecules.
Atributes:
molecule (List[Molecule]): List of molecules of the system
nmols (List[int]): List of number of molecules in the system
"""
def __init__(self) -> None:
"""
Initializes a empty system object that will be populated afterwards
"""
self.molecule: List[Molecule] = []
self.nmols: List[int] = []
def add_type(self, nmols: int, m: Molecule) -> None:
"""
Adds a new molecule type to the system
Args:
nmols (int): Number of molecules of the new type in the system
m (Molecule): The instance of the new type of molecule
"""
self.molecule.append(m)
self.nmols.append(nmols)
def center_of_mass_distance(self, a: Molecule, b: Molecule) -> float:
"""
Calculates the distance between the center of mass of two molecules
Args:
a (Molecule): First Molecule Instance
b (Molecule): Second Molecule Instance
Returns:
float: module of the distance between the two center of masses
"""
com1 = self.molecule[a].center_of_mass()
com2 = self.molecule[b].center_of_mass()
dx = com1[0] - com2[0]
dy = com1[1] - com2[1]
dz = com1[2] - com2[2]
distance = math.sqrt(dx**2 + dy**2 + dz**2)
return distance
def rmsd_fit(self, p_index: int, r_index: int) -> Tuple[float, Molecule]:
projecting_mol = self.molecule[p_index]
reference_mol = self.molecule[r_index]
if len(projecting_mol.atom) != len(reference_mol.atom):
sys.exit(
"Error in RMSD fit procedure: molecules have different number of atoms"
)
dim = len(projecting_mol.atom)
new_projecting_mol = deepcopy(projecting_mol)
new_reference_mol = deepcopy(reference_mol)
new_projecting_mol.center_of_mass_to_origin()
new_reference_mol.center_of_mass_to_origin()
x = []
y = []
for atom in new_projecting_mol.atom:
x.extend([atom.rx, atom.ry, atom.rz])
for atom in new_reference_mol.atom:
y.extend([atom.rx, atom.ry, atom.rz])
x = np.array(x).reshape(dim, 3)
y = np.array(y).reshape(dim, 3)
r = np.matmul(y.T, x)
rr = np.matmul(r.T, r)
try:
evals, evecs = linalg.eigh(rr)
except:
sys.exit("Error: diagonalization of RR matrix did not converge")
a1 = evecs[:, 2].T
a2 = evecs[:, 1].T
a3 = np.cross(a1, a2)
A = np.array([a1[0], a1[1], a1[2], a2[0], a2[1], a2[2], a3[0], a3[1], a3[2]])
A = A.reshape(3, 3)
b1 = np.matmul(r, a1.T).T # or np.dot(r, a1)
b1 /= linalg.norm(b1)
b2 = np.matmul(r, a2.T).T # or np.dot(r, a2)
b2 /= linalg.norm(b2)
b3 = np.cross(b1, b2)
B = np.array([b1[0], b1[1], b1[2], b2[0], b2[1], b2[2], b3[0], b3[1], b3[2]])
B = B.reshape(3, 3).T
rot_matrix = np.matmul(B, A)
x = np.matmul(rot_matrix, x.T).T
rmsd = 0
for i in range(dim):
rmsd += (
(x[i, 0] - y[i, 0]) ** 2
+ (x[i, 1] - y[i, 1]) ** 2
+ (x[i, 2] - y[i, 2]) ** 2
)
rmsd = math.sqrt(rmsd / dim)
for i in range(dim):
new_projecting_mol.atom[i].rx = x[i, 0]
new_projecting_mol.atom[i].ry = x[i, 1]
new_projecting_mol.atom[i].rz = x[i, 2]
reference_mol.center_of_mass()
projected_mol = new_projecting_mol.translate(reference_mol.com)
return rmsd, projected_mol
def update_molecule(self, position: np.ndarray, fh: TextIO) -> None:
"""Updates the position of the molecule in the Output file
Args:
position (np.ndarray): numpy position vector
fh (TextIO): Output file
"""
position_in_ang = (position * BOHR2ANG).tolist()
self.add_type(self.nmols[0], deepcopy(self.molecule[0]))
for atom in self.molecule[-1].atom:
atom.rx = position_in_ang.pop(0)
atom.ry = position_in_ang.pop(0)
atom.rz = position_in_ang.pop(0)
rmsd, self.molecule[0] = self.rmsd_fit(-1, 0)
self.molecule.pop(-1)
fh.write("\nProjected new conformation of reference molecule with RMSD fit\n")
fh.write("RMSD = {:>8.5f} Angstrom\n".format(rmsd))
def nearest_image(
self,
index_r: int,
index_m: int,
lx: float,
ly: float,
lz: float,
criterium=None,
) -> Tuple[float, Molecule]:
if criterium in None:
criterium = "com"
if criterium != "com" and criterium != "min":
sys.exit("Error in value passed to function nearest_image")
min_dist = 1e20
for i in range(-1, 2):
for j in range(-1, 2):
for k in range(-1, 2):
tr_vector = [i * lx, j * ly, k * lz]
self.add_molecule(self.molecule[index_m].translate(tr_vector))
if criterium == "com":
dist = self.center_of_mass_distance(index_r, -1)
else:
dist = self.minimum_distance(index_r, -1)
if dist < min_dist:
min_dist = dist
nearestmol = deepcopy(self.molecule[-1])
self.molecule.pop(-1)
return min_dist, nearestmol
def print_geom(self, cycle: int, fh: TextIO) -> None:
"""
Print the geometry of the molecule in the Output file
Args:
cycle (int): Number of the cycle
fh (TextIO): Output file
"""
fh.write("Cycle # {}\n".format(cycle))
fh.write("Number of site: {}\n".format(len(self.molecule[0].atom)))
for atom in self.molecule[0].atom:
symbol = atomsymb[atom.na]
fh.write(
"{:<2s} {:>10.6f} {:>10.6f} {:>10.6f}\n".format(
symbol, atom.rx, atom.ry, atom.rz
)
)