Created
October 1, 2019 16:31
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Scan dihedral angles using Open Babel (here using random angles)
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| #!/usr/bin/env python | |
| from __future__ import print_function | |
| import sys | |
| import os | |
| import math | |
| import random | |
| import pybel | |
| from pybel import ob | |
| # optimize dihedral angle vectors | |
| # using MMFF94 energies and Bayesian optimization | |
| # global variable for the MMFF94 force field | |
| ff = pybel._forcefields["mmff94"] | |
| def energy(): | |
| return ff.Energy(False) # false = don't compute gradients | |
| if __name__ == "__main__": | |
| # Syntax dihedrals.py filename.mol2 | |
| # read molecule | |
| if (sys.argv) != 2: | |
| exit | |
| filename = sys.argv[1] | |
| extension = os.path.splitext(filename)[1] | |
| # read a single molecule from the supplied file | |
| # turn this into a while loop if you want all molecules in a file | |
| mol = next(pybel.readfile(extension[1:], filename)) | |
| if ff.Setup(mol.OBMol) is False: | |
| print("Cannot set up force field, exiting") | |
| exit() | |
| print("Molecule read. Number of atoms: {}".format(len(mol.atoms))) | |
| # set up the pool of rotatable bonds | |
| rl = ob.OBRotorList() | |
| rl.Setup(mol.OBMol) | |
| print("Number of rotatable bonds: {}".format(rl.Size())) | |
| # iterate through them to get the current dihedrals | |
| currentCoords = mol.OBMol.GetCoordinates() | |
| rotIterator = rl.BeginRotors() | |
| rotor = rl.BeginRotor(rotIterator) # first rotatable bond | |
| rotors = [] | |
| angles = [] # in radians | |
| while rotor is not None: | |
| angle = rotor.CalcTorsion(currentCoords) | |
| angles.append(angle) | |
| print("dihedral: {0:3f}".format(math.degrees(angle))) | |
| atoms = rotor.GetDihedralAtoms() | |
| print("GetDihedralAtoms:", rotor.GetDihedralAtoms()) | |
| rotors.append(rotor) | |
| rotor = rl.NextRotor(rotIterator) | |
| print("Current energy", round(energy(), 4)) | |
| # each angle can obviously go from 0 .. 2*pi | |
| # pick a random set of angles | |
| # this would obviously be driven by the Bayesian optimization | |
| for i in range(len(angles)): | |
| angle = random.uniform(0, 2.0 * math.pi) | |
| print("dihedral: {0:.3f}".format(math.degrees(angle))) | |
| angles[i] = angle | |
| rotors[i].SetToAngle(currentCoords, angle) | |
| # update the coordinates and re-compute the energy | |
| mol.OBMol.SetCoordinates(currentCoords) | |
| ff.SetCoordinates(mol.OBMol) | |
| print("New energy: {0:.4f}".format(energy(), 4)) | |
| exit() | |
| # write the current coordinates to a file | |
| newFile = os.path.splitext(filename)[0] + '-opt.sdf' | |
| mol.write("sdf", newFile) |
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