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This script calculates the true center-of-mass (COM) or the center-of-geometry (COG) for a given selection and returns the x, y, z values in the form of a [[Pseudoatom]] (rather than a CGO sphere). The benefit of using a [[Pseudoatom]] is that it can be selected and used in calculations. In addition, this script also iteratively goes through all states of a selection if more than one state exists and appends the corresponding COM/COG values as states into the [[Pseudoatom]]. The script itself is quite simple yet robust enough to be applied in different settings. As well, the calculation of the COM/COG is handled independently from the formation of the [[Pseudoatom]] and can be called as an independent function where applicable. | This script calculates the true center-of-mass (COM) or the center-of-geometry (COG) for a given selection and returns the x, y, z values in the form of a [[Pseudoatom]] (rather than a CGO sphere). The benefit of using a [[Pseudoatom]] is that it can be selected and used in calculations. In addition, this script also iteratively goes through all states of a selection if more than one state exists and appends the corresponding COM/COG values as states into the [[Pseudoatom]]. The script itself is quite simple yet robust enough to be applied in different settings. As well, the calculation of the COM/COG is handled independently from the formation of the [[Pseudoatom]] and can be called as an independent function where applicable. | ||
Note: In order to use the [[Pseudoatom]] in your measurements (i.e. distance), you need to invoke the distance calculation directly via the command line using the [[Distance]] function and not via the Wizard! | |||
===Usage=== | ===Usage=== | ||
Revision as of 08:39, 27 May 2010
Description
This script calculates the true center-of-mass (COM) or the center-of-geometry (COG) for a given selection and returns the x, y, z values in the form of a Pseudoatom (rather than a CGO sphere). The benefit of using a Pseudoatom is that it can be selected and used in calculations. In addition, this script also iteratively goes through all states of a selection if more than one state exists and appends the corresponding COM/COG values as states into the Pseudoatom. The script itself is quite simple yet robust enough to be applied in different settings. As well, the calculation of the COM/COG is handled independently from the formation of the Pseudoatom and can be called as an independent function where applicable.
Note: In order to use the Pseudoatom in your measurements (i.e. distance), you need to invoke the distance calculation directly via the command line using the Distance function and not via the Wizard!
Usage
com selection [,state=None [,mass=None [,name=None]]]
Examples
fetch 1c3y, finish=1, multiplex=0
com 1c3y, state=1
#Create a pseudoatom representing the 1c3y COG and store it as "1c3y_COM"
#The "1c3y_COM" object will contain 1 state only
com 1c3y, state=1, name=COG
#Create a pseudoatom representing the 1c3y COG and store it as "COG"
#The "COG" object will contain 1 state only
com 1c3y, state=1, name=COM, mass=1
#Create a pseudoatom representing the 1c3y COM and store it as "COM"
#The "COM" object will contain 1 state only
com 1c3y, name=COM, mass=1
#Create a single pseudoatom containing the COM for each state found in 1c3y and store it as "COM"
#The "COM" object will contain MULTIPLE states!
PyMOL API
from pymol import cmd
def com (selection,state=None,mass=None,name=None):
"""
Author: Sean Law
Michigan State University
slaw (at) msu . edu
"""
if (name == None):
name=selection+"_COM"
cmd.delete(name)
if (state != None):
x, y, z=get_com(selection,mass=mass)
print "%f %f %f" % (x, y, z)
cmd.pseudoatom(name,pos=[x, y, z])
cmd.show("spheres",name)
else:
for i in range(cmd.count_states()):
x, y, z=get_com(selection,mass=mass,state=i+1)
print "State %d:%f %f %f" % (i+1, x, y, z)
cmd.pseudoatom(name,pos=[x, y, z],state=i+1)
cmd.show("spheres",name)
return
cmd.extend("com",com)
def get_com (selection,state=1,mass=None):
"""
Author: Sean Law
Michigan State University
slaw (at) msu . edu
"""
atmass={'H':1.00800000000000, 'C':12.0110000000000, \
'N':14.0070000000000, 'O':15.9994000000000, \
'P':30.9740000000000, 'S':32.0600000000000, \
'F':18.9980000000000
}
totmass=0.0
if (mass!=None):
print "Calculating mass-weighted COM"
state=int(state)
model = cmd.get_model(selection,state)
x,y,z=0,0,0
for a in model.atom:
if (mass != None):
if (a.name[0] in atmass):
x+= a.coord[0]*atmass[a.name[0]]
y+= a.coord[1]*atmass[a.name[0]]
z+= a.coord[2]*atmass[a.name[0]]
totmass+=atmass[a.name[0]]
else:
print "Please add atomic mass for "+a.name+" to atmass"
return
else:
x+= a.coord[0]
y+= a.coord[1]
z+= a.coord[2]
if (mass!=None):
return x/totmass, y/totmass, z/totmass
else:
return x/len(model.atom), y/len(model.atom), z/len(model.atom)
cmd.extend("get_com", get_com)
Previous Implementation
Here is a script that calculates the center of geometry from a selection. It gets hold of the coordinates with cmd.get_model. Make sure the atoms in the selection are of equal weight.
For a sample application, see: "Convergent Evolution Examples"
## Author: Andreas Henschel 2006
from pymol import cmd
from pymol.cgo import *
def centerOfMass(selection):
## assumes equal weights (best called with "and name ca" suffix)
model = cmd.get_model(selection)
x,y,z=0,0,0
for a in model.atom:
x+= a.coord[0]
y+= a.coord[1]
z+= a.coord[2]
return (x/len(model.atom), y/len(model.atom), z/len(model.atom))
cmd.load("/group/bioinf/Data/PDBLinks/1c7c.pdb")
cmd.select("domain", "/1c7c//A/143-283/ and name ca") ## selecting a domain
domainCenter=centerOfMass("domain")
print "Center of mass: (%.1f,%.1f,%.1f)"% domainCenter
cmd.as("cartoon", "all")
cmd.show("spheres", "domain")
## Creating a sphere CGO
com = [COLOR, 1.0, 1.0, 1.0, SPHERE]+list(domainCenter) + [3.0] ## white sphere with 3A radius
cmd.load_cgo(com, "CoM")
cmd.zoom("1c7c", 1.0)
cmd.center("domain")
#ah@bioinfws19:~/Projects/PyMOL$ pymol -qc centerOfMass4.py
#Center of mass: (-1.0,24.5,48.2)
#ah@bioinfws19:~/Projects/PyMOL$