def generate_data():
    mol = Molecule.from_file("eth.cml")
    scf = SCF(mol, basis="sto3g")
    scf.iterate()
    shelf = open_shelf()
    shelf["scf"] = scf
    shelf.close()
def generate_data():
    mol = Molecule.from_file("eth.cml")
    scf = SCF(mol, basis="sto3g")
    scf.iterate()
    shelf = open_shelf()
    shelf["scf"]=scf
    shelf.close()
Exemplo n.º 3
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def test_fci():
    """ test FCI calculation"""
    from Molecule import Molecule
    from PyQuante import SCF


    nel = 2
    mult = 1
    m_s = 0
    k=10
    
    # h2 = Molecule('h2',[(1,(0,0,0)),(1,(1.4,0,0))], multiplicity = mult)
    h2 = Molecule('h2',[(1,(0,0,0)),(1,(1.4,0,0))])

    Solver = SCF(h2,method = "HF")
    Solver.iterate()
    print "orbital energies ",Solver.solver.orbe
    print "HF energy = ",Solver.energy
    
    # FCIInst = FCISolver(Solver.h, Solver.ERI, Solver.solver.orbs, nel, mult, m_s, k=k, sigma_eigs=None)
    # eva, eve = FCIInst.iterate()    

    FCIInst = FCIExactSolver(Solver.h, Solver.ERI, h2.get_enuke(), Solver.solver.orbs, nel, mult, m_s)
    eva,eve = FCIInst.diagonalize()

    print "eva = ", eva
    # print "eve = ",eve
    print "correlation energy = ", eva[0] - Solver.energy
    print "correlation energy should be (with 6-31g**) -0.03387 a.u."
Exemplo n.º 4
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def pyquante_hf(mol, x, eps, basis = "sto-3g"):

    
    atoms = [None]*mol.num_atoms
    for i in xrange(mol.num_atoms):
        atoms[i] = (mol.atoms[i].charge,
                    (mol.atoms[i].rad[0],mol.atoms[i].rad[1],mol.atoms[i].rad[2]))
        
    mol_pq = Molecule(mol.name, atoms, units='Bohr')
    solver = SCF(mol_pq,method="HF",ConvCriteria=1e-7,MaxIter=40,basis=basis)
    print 'SCF iteration - done'


    solver.iterate()
    norb=int(solver.solver.nclosed)
    w=solver.basis_set.get()


    cf=solver.solver.orbs[:,0:norb]

    psi = [None]*norb
    for i in xrange(norb):
        psi[i] = gto2tuck(w,cf[:,i],x)
        print psi[i].r
        psi[i] = local(psi[i],1e-14)
        psi[i] = tuck.round(psi[i],eps)
        print psi[i].r

    E = solver.solver.orbe[:norb]

    return psi,E
Exemplo n.º 5
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def test_fci():
    """ test FCI calculation"""
    from Molecule import Molecule
    from PyQuante import SCF

    nel = 2
    mult = 1
    m_s = 0
    k = 10

    # h2 = Molecule('h2',[(1,(0,0,0)),(1,(1.4,0,0))], multiplicity = mult)
    h2 = Molecule('h2', [(1, (0, 0, 0)), (1, (1.4, 0, 0))])

    Solver = SCF(h2, method="HF")
    Solver.iterate()
    print "orbital energies ", Solver.solver.orbe
    print "HF energy = ", Solver.energy

    # FCIInst = FCISolver(Solver.h, Solver.ERI, Solver.solver.orbs, nel, mult, m_s, k=k, sigma_eigs=None)
    # eva, eve = FCIInst.iterate()

    FCIInst = FCIExactSolver(Solver.h, Solver.ERI, h2.get_enuke(),
                             Solver.solver.orbs, nel, mult, m_s)
    eva, eve = FCIInst.diagonalize()

    print "eva = ", eva
    # print "eve = ",eve
    print "correlation energy = ", eva[0] - Solver.energy
    print "correlation energy should be (with 6-31g**) -0.03387 a.u."
Exemplo n.º 6
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    def calculate(self, verbose=False):
        from PyQuante import SCF, Molecule
        if verbose:
            logging.basicConfig(level=logging.DEBUG)
        pyquante_atoms = []
        for a in self._atoms:
            pyquante_atoms.append( (a.number, a.position) )
        m = Molecule('molecule', pyquante_atoms)
        lda = SCF(m, method="DFT")
        lda.iterate()

        result = {
                "total_energy": lda.energy,
                "orbital_energies": lda.solver.orbe,
                }
        return result
Exemplo n.º 7
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def new_grid_tester():
    from PyQuante.TestMolecules import he,h2
    from PyQuante.MolecularGrid import MolecularGrid
    from PyQuante.Ints import getbasis
    from PyQuante import SCF
    mol = h2
    gr = MolecularGrid(mol,do_grad_dens=True)
    gr2 = MG2(mol,do_grad_dens=True)
    print "test_length: ",test_length(gr,gr2)
    print "test_distance: ",test_distance(gr,gr2)

    bfs = getbasis(mol)
    gr.set_bf_amps(bfs)
    gr2.add_basis(bfs)
    print "test_bfgrid: ",test_bfgrid(gr,gr2)

    # This is a little weird, but now use the hf density matrix to
    #  test whether the densities are the same
    hf = SCF(mol)
    hf.iterate()
    gr.setdens(hf.dmat)
    gr2.set_density(hf.dmat)
    print "test_density: ",test_density(gr,gr2)
    print "test_gamma: ",test_gamma(gr,gr2)
Exemplo n.º 8
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def new_grid_tester():
    from PyQuante.TestMolecules import he,h2
    from PyQuante.MolecularGrid import MolecularGrid
    from PyQuante.Ints import getbasis
    from PyQuante import SCF
    mol = h2
    gr = MolecularGrid(mol,do_grad_dens=True)
    gr2 = MG2(mol,do_grad_dens=True)
    print "test_length: ",test_length(gr,gr2)
    print "test_distance: ",test_distance(gr,gr2)

    bfs = getbasis(mol)
    gr.set_bf_amps(bfs)
    gr2.add_basis(bfs)
    print "test_bfgrid: ",test_bfgrid(gr,gr2)

    # This is a little weird, but now use the hf density matrix to
    #  test whether the densities are the same
    hf = SCF(mol)
    hf.iterate()
    gr.setdens(hf.dmat)
    gr2.set_density(hf.dmat)
    print "test_density: ",test_density(gr,gr2)
    print "test_gamma: ",test_gamma(gr,gr2)
Exemplo n.º 9
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def Edot(method='ROHF'):
    O = Molecule('O', atomlist=[('O', (0, 0, 0))], multiplicity=3)
    job = SCF(O, method=method, basis='6-31G**')
    job.iterate()
    return job.energy
Exemplo n.º 10
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from PyQuante.Molecule import Molecule
from PyQuante import SCF

#Intializing the molecules
H2 = Molecule('H2', [(1, (0, 0, 0)), (1, (1.4, 0, 0))])
OHmin = Molecule('OHmin', [(8, (0., 0., -0.08687037)),
                           (1, (0., 0., 0.86464814))],
                 units='Angstrom',
                 charge=-1)

#HF method example
#Different basis can be used, sto-3g
#H2solver = SCF(H2, method="HF")
H2solver = SCF(H2, method="HF")
H2solver.iterate()
print "HF energy = ", H2solver.energy

#DFT method example
lda = SCF(H2, method="DFT")
lda.iterate()
blyp = SCF(H2, method="DFT", functional="BLYP")
blyp.iterate()
print "DFT results: LDA = ", lda.energy, " BLYP = ", blyp.energy

#Open shell Hartree Fock
# method='UHF' or method='ROHF'
Exemplo n.º 11
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from PyQuante import Molecule, SCF

# Define the atom
he = Molecule('he',atomlist=[(2,(0,0,0))],charge=0,multiplicity=1)

# Run HF
solver = SCF(he,method="HF",basis="dzvp")
solver.iterate()

# Show result
print solver
print "HF Energy = ",solver.energy

print "---With fractional charge---"
he = Molecule('he',atomlist=[(2.04,(0,0,0))],charge=0,multiplicity=1)

# Run HF
solver = SCF(he,method="HF",basis="dzvp")
solver.iterate()

# Show result
print solver
print "HF Energy = ",solver.energy
Exemplo n.º 12
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from numpy import *


def const_init(vec, label):
    log = "const double %s[%d]  = {" % (label, vec.size)
    for i, v in enumerate(vec[:-1]):
        log += "%15.8f," % v
        if not i % 5: log += "\n"
    log += "%15.8f};\n" % vec[-1]
    print log


h2o = Molecule('H2O', [(8, (-3.08471, 1.12313, 0.00396)),
                       (1, (-2.11791, 0.90877, 0.01763)),
                       (1, (-3.12325, 2.07922, -0.24921))],
               units='Angstrom')

solver = SCF(h2o, basis='sto3g', method="HF", etol=1e-15)
solver.iterate()
print "Energy: %14.12f" % solver.energy

D = (solver.dmat * 2.0).ravel()
S = solver.S.ravel()
F = solver.F.ravel()
H = solver.h.ravel()

const_init(D, "ref_D")
const_init(S, "ref_S")
const_init(F, "ref_F")
const_init(H, "ref_H")
Exemplo n.º 13
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from PyQuante.Molecule import Molecule
from PyQuante import SCF

#Intializing the molecules
H2 = Molecule('H2', [ (1, (0,0,0)), (1,(1.4,0,0)) ] )
OHmin = Molecule( 'OHmin', [ (8, (0., 0., -0.08687037)) , (1, (0., 0., 0.86464814)) ], units='Angstrom', charge=-1  )


#HF method example
#Different basis can be used, sto-3g
#H2solver = SCF(H2, method="HF")
H2solver = SCF(H2, method="HF")
H2solver.iterate()
print "HF energy = ", H2solver.energy

#DFT method example
lda = SCF(H2,method="DFT")
lda.iterate()
blyp = SCF(H2,method="DFT",functional="BLYP")
blyp.iterate()
print "DFT results: LDA = ", lda.energy, " BLYP = ", blyp.energy

#Open shell Hartree Fock
# method='UHF' or method='ROHF'
Exemplo n.º 14
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def Edot(method='ROHF'):
    O = Molecule('O',atomlist=[('O',(0,0,0))],multiplicity=3)
    job = SCF(O,method=method,basis='6-31G**')
    job.iterate()
    return job.energy
Exemplo n.º 15
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 def testH(self):
     solv = SCF(h, method='DFT')
     solv.iterate()
     self.assertAlmostEqual(solv.energy, -7.431364, 4)
Exemplo n.º 16
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import logging

from numpy import array

from PyQuante import SCF, Molecule

atoms = [(14, array([0, 0, 0])), (14, array([ 2.3419588,  0.       ,  0.       ])), (14, array([ 3.21218834,  2.05887837,  0.        ])), (14, array([ 1.23984519,  3.29297073, -0.42228815])), (14, array([-0.05485092,  1.72185148, -1.63972761])), (14, array([ 1.15882181,  0.99278059, -3.55206339])), (14, array([ 3.39816913,  0.26950033, -3.1977073 ])), (14, array([ 4.55928267,  1.90791736, -1.93502226])), (14, array([ 3.39316637, -1.42643782, -1.53138653])), (1, array([-0.6106289 ,  0.43621736,  1.28608097])), (1, array([-0.5834327 , -1.31182802, -0.39633738])), (1, array([-1.43155677,  2.12871605, -2.08077878])), (1, array([ 1.53825752,  4.55183661, -1.16374012])), (1, array([ 0.53075288,  3.66105357,  0.83588437])), (1, array([ 5.94172312,  1.43875952, -1.62950356])), (1, array([ 4.67251821,  3.2307785 , -2.61584443])), (1, array([ 3.97839267, -0.14357093, -4.51963896])), (1, array([ 2.59722827, -2.64784197, -1.83682433])), (1, array([ 4.77261873, -1.8301562 , -1.14139106])), (1, array([ 0.40165221, -0.13112135, -4.18238283])), (1, array([ 1.17882996,  2.10638397, -4.5476595 ]))]

logging.basicConfig(level=logging.DEBUG)
m = Molecule('molecule', atoms)
lda = SCF(m, method="DFT")
lda.iterate()
Exemplo n.º 17
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from PyQuante import Molecule, SCF

# Define the atom
he = Molecule('he', atomlist=[(2, (0, 0, 0))], charge=0, multiplicity=1)

# Run HF
solver = SCF(he, method="HF", basis="dzvp")
solver.iterate()

# Show result
print solver
print "HF Energy = ", solver.energy

print "---With fractional charge---"
he = Molecule('he', atomlist=[(2.04, (0, 0, 0))], charge=0, multiplicity=1)

# Run HF
solver = SCF(he, method="HF", basis="dzvp")
solver.iterate()

# Show result
print solver
print "HF Energy = ", solver.energy
Exemplo n.º 18
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def energy(R=1.217, method='UHF'):
    O2 = Molecule('O2',atomlist=[('O',(0,0,0)),('O',(R,0,0))],\
                  units='Angstrom',multiplicity=3)
    O2abinitio = SCF(O2, method=method, basis='6-31G**')
    O2abinitio.iterate()
    return O2abinitio.energy
Exemplo n.º 19
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"""
Calculates the H2 molecule using UHF.

And plots the charge density along the x-axis.
"""

from PyQuante import SCF, Molecule
from PyQuante.NumWrap import arange
from pylab import plot, savefig

# Do the lda calculation:
h2 = Molecule('h2', [(1, (-0.7, 0, 0)), (1, (0.7, 0, 0))])
hf = SCF(h2, method="UHF", basis="6-31G**")
hf.iterate()

# print some info:
print "UHF Results: energy =", hf.energy
print "orbital energies:", hf.solvera.orbe

# Get the items we'll need to compute the density with
orbs = hf.solvera.orbs
bfs = hf.basis_set.get()
nclosed,nopen = h2.get_closedopen()
nbf = len(bfs)

x,y,z = 0, 0, 0
xs = arange(-1.0, 1.1, 0.1)
ds = []
for x in xs:
    amp_xyz = 0
    for i in range(nclosed):
Exemplo n.º 20
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def energy(R=1.217,method='UHF'):
    O2 = Molecule('O2',atomlist=[('O',(0,0,0)),('O',(R,0,0))],\
                  units='Angstrom',multiplicity=3)
    O2abinitio = SCF(O2,method=method,basis='6-31G**')
    O2abinitio.iterate()
    return O2abinitio.energy