To create a new feature type, derive a new class from the base features.feature. You should then set the numatoms member to the number of atoms your feature acts on, and also override the following functions: eval, deriv, and is_angle. You can also derive your class from any of the built-in MODELLER features (e.g., features.angle) if you desire.
The eval function is called from MODELLER with a model object and the indices of the atoms defining the feature. Your function should return the value of the feature. The deriv function is similar, but is also passed the current feature value; you should return the derivatives of the feature with respect to x, y and z of each defining atom. The is_angle function should return True if your feature is an angle, in which case MODELLER will automatically deal with periodicity for you, and convert any feature values to degrees for the user. (Your eval and deriv functions should, however, return angle values in radians.)
from modeller import *
from modeller.scripts import complete_pdb
env = environ()
env.io.atom_files_directory = ['../atom_files']
log.verbose()
env.libs.topology.read(file='$(LIB)/top_heav.lib')
env.libs.parameters.read(file='$(LIB)/par.lib')
class MyDist(features.feature):
"""An implementation of Modeller's distance feature (type 1) in
pure Python. For improved performance, see cuser_feat.py, which
implements the feature in C."""
numatoms = 2
def eval(self, mdl, atom_indices):
(a1, a2) = self.indices_to_atoms(mdl, atom_indices)
dist = ((a1.x - a2.x) ** 2 + (a1.y - a2.y) ** 2
+ (a1.z - a2.z) ** 2) ** 0.5
return dist
def deriv(self, mdl, atom_indices, feat):
(a1, a2) = self.indices_to_atoms(mdl, atom_indices)
dx1 = (a1.x - a2.x) / feat
dy1 = (a1.y - a2.y) / feat
dz1 = (a1.z - a2.z) / feat
dx2 = -dx1
dy2 = -dy1
dz2 = -dz1
return ((dx1, dx2), (dy1, dy2), (dz1, dz2))
def is_angle(self):
return False
mdl = complete_pdb(env, "1fdn")
sel = selection(mdl)
rsr = mdl.restraints
at = mdl.atoms
rsr.add(forms.gaussian(group=physical.bond,
feature=MyDist(at['CA:1'], at['C:1']),
mean=1.5380, stdev=0.0364))
sel.energy()