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IMP Reference Guide  2.6.2
The Integrative Modeling Platform
doc/examples/pmi/em.py
1 ## \example pmi/em.py
2 """This script shows how to create DENSITY representations.
3 and set up the Gaussian EM restraint.
4 
5 These representations are useful when you are doing EM fitting with rigid bodies.
6 
7 Preliminary step: you should convert your EM map to a GMM file
8 with the command line utility create_gmm.py (located in isd/pyext/src/create_gmm.py):
9 python create_gmm.py emd_1883.mrc 50 emd_1883.gmm50.txt -m emd_1883.gmm50.mrc
10 """
11 
12 import IMP
13 import RMF
14 import IMP.atom
15 import IMP.algebra
16 import IMP.rmf
17 import IMP.pmi
18 import IMP.pmi.topology
19 import IMP.pmi.dof
20 import IMP.pmi.macros
22 import tempfile
23 import os
24 ###################### SYSTEM SETUP #####################
25 # Preliminaries
26 mdl = IMP.Model()
28 
29 # Setup just one molecule
31 st = s.create_state()
32 mol = st.create_molecule("Rpn4",sequence=seqs["1WCM:D"],chain_id="D")
33 atomic_res = mol.add_structure(IMP.pmi.get_example_path('data/1WCM_fitted.pdb'),
34  chain_id="D",
35  offset=0)
36 
37 # Below we create a GMM approximation for this moleucle
38 # This "DENSITY" representation is used in the GaussianEMRestraint (and others in the future)
39 # For structure regions we "fit" GMM components to all atom centers
40 mol.add_representation(atomic_res,
41  resolutions=[1,10],
42  density_residues_per_component=10, #how much to coarsen this representation
43  density_prefix="Rpn4_gmm", # will write a .txt and .mrc file forcomponent
44  density_force_compute=False, # set True if you want to overwrite
45  density_voxel_size=3.0) # set to 0 if you don't care about writing the map
46  # if rasterizing takes too long, increase this value
47 
48 # for the unstructured regions, we simply decorate each bead AS a gaussian, so no fitting is necessary
49 mol.add_representation(mol.get_non_atomic_residues(),
50  resolutions=[10],
51  setup_particles_as_densities=True) # just set this flag, nothing is written
52 
53 hier = s.build()
54 
55 # You can always check the representations with:
57 
58 ###################### RESTRAINTS #####################
59 output_objects = []
60 
61 # To add the GaussianEMRestraint, first select all densities
62 densities = IMP.atom.Selection(hier,representation_type=IMP.atom.DENSITIES).get_selected_particles()
64  densities,
65  target_fn=IMP.pmi.get_example_path('data/emd_1883.gmm50.txt'), # created by user, see top of file
66  slope=0.01, # a small number, helps drag bits into map
67  scale_target_to_mass=False, # if the model is the same size as map, usually set to True
68  target_mass_scale=100000, # manually set the mass of the target map (remove if you set above to True)
69  weight=100.0) # the data weight
70 emr.add_to_model()
71 output_objects.append(emr)
72 mdl.update()
73 print(emr.evaluate())
Fit Gaussian-decorated particles to an EM map (also represented with a set of Gaussians) ...
void show_with_representations(Hierarchy h, std::ostream &out=std::cout)
Traverse through the tree and show atom info, including representations.
Set of python classes to create a multi-state, multi-resolution IMP hierarchy.
std::string get_example_path(std::string file_name)
Return the full path to one of this module's example files.
Protocols for sampling structures and analyzing them.
Definition: macros.py:1
This class initializes the root node of the global IMP.atom.Hierarchy.
Class for storing model, its restraints, constraints, and particles.
Definition: Model.h:72
Restraints for handling electron microscopy maps.
General purpose algebraic and geometric methods that are expected to be used by a wide variety of IMP...
Create movers and setup constraints for PMI objects.
Python classes to represent, score, sample and analyze models.
A dictionary-like wrapper for reading and storing sequence data.
Functionality for loading, creating, manipulating and scoring atomic structures.
Select hierarchy particles identified by the biological name.
Definition: Selection.h:66
Support for the RMF file format for storing hierarchical molecular data and markup.