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Supercell

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Revision as of 09:45, 15 April 2010 by Speleo3 (talk | contribs) (link to mailing list)
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Overview

Can display multiple copies of the unit cell.

See thread on pymol-users mailing list.

Example

run supercell.py
fetch 2x19, async=0
supercell 2,1,1, 2x19, green
supercell 1,1,2, 2x19, orange, name=super2

The Code

'''
(c) 2010 Thomas Holder

PyMOL python script (load with `run supercell.py`)
Usage: See "help supercell"
'''

from pymol import cmd, cgo
from math import cos, sin, radians, sqrt
import numpy

def cellbasis(angles, edges):
	'''
	For the unit cell with given angles and edge lengths calculate the basis
	transformation (vectors) as a 4x4 numpy.array
	'''
	rad = [radians(i) for i in angles]
	basis = numpy.identity(4)
	basis[0][1] = cos(rad[2])
	basis[1][1] = sin(rad[2])
	basis[0][2] = cos(rad[1])
	basis[1][2] = (cos(rad[0]) - basis[0][1]*basis[0][2])/basis[1][1]
	basis[2][2] = sqrt(1 - basis[0][2]**2 - basis[1][2]**2)
	edges.append(1.0)
	return basis * edges # numpy.array multiplication!

def supercell(a=1, b=1, c=1, object=None, color='blue', name='supercell'):
	'''
DESCRIPTION

    Draw a supercell, as requested by Nicolas Bock on the pymol-users
    mailing list (Subject: [PyMOL] feature request: supercell construction
    Date: 04/12/2010 10:12:17 PM (Mon, 12 Apr 2010 14:12:17 -0600))

USAGE

    supercell a, b, c [, object [, color [, name]]]

ARGUMENTS

    a, b, c = integer: repeat cell in x,y,z direction a,b,c times
    {default: 1,1,1}

    object = string: name of object to take cell definition from

    color = string: color of cell {default: blue}

    name = string: name of the cgo object to create {default: supercell}

SEE ALSO

    show cell

	'''
	if object is None:
		object = cmd.get_object_list()[0]

	sym = cmd.get_symmetry(object)
	cell_edges = sym[0:3]
	cell_angles = sym[3:6]

	basis = cellbasis(cell_angles, cell_edges)
	assert isinstance(basis, numpy.ndarray)

	ts = list()
	for i in range(int(a)):
		for j in range(int(b)):
			for k in range(int(c)):
				ts.append([i,j,k])

	obj = [
		cgo.BEGIN,
		cgo.LINES,
		cgo.COLOR,
	]
	obj.extend(cmd.get_color_tuple(color))
	
	for t in ts:
		shift = basis[0:3,0:3] * t
		shift = shift[:,0] + shift[:,1] + shift[:,2]
	
		for i in range(3):
			vi = basis[0:3,i]
			vj = [
				numpy.array([0.,0.,0.]),
				basis[0:3,(i+1)%3],
				basis[0:3,(i+2)%3],
				basis[0:3,(i+1)%3] + basis[0:3,(i+2)%3]
			]
			for j in range(4):
				obj.append(cgo.VERTEX)
				obj.extend((shift + vj[j]).tolist())
				obj.append(cgo.VERTEX)
				obj.extend((shift + vj[j] + vi).tolist())

	cmd.delete(name)
	cmd.load_cgo(obj, name)

cmd.extend('supercell', supercell)