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Input #60

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275bad8
Flags can be set from input
ilfreddy Oct 20, 2023
c3119fd
Update to gitignore
ilfreddy Oct 27, 2023
3bc4818
1. Some output improvements
ilfreddy Oct 27, 2023
393ee7e
precSmall = precLarge/100
ilfreddy Oct 27, 2023
d57cd7b
add threshold
ilfreddy Oct 27, 2023
5e0bb38
The iteration is now interrupted either when the change in orbital no…
ilfreddy Jan 24, 2024
1c062b3
Added precision modulation to the 2e case as well
ilfreddy Jan 24, 2024
49ebf67
moved two function definitions out of a third function
ilfreddy Jan 24, 2024
5520c64
Adds precision modulation for the D2 method for 2 electrons
ilfreddy Jan 24, 2024
2b44fa6
Improves energy priting D2 two electrons
ilfreddy Jan 25, 2024
7a88212
Bugfix
ilfreddy Jan 25, 2024
abe2b9e
prints energy components in D and D2
ilfreddy Jan 25, 2024
6b3f66c
alternative exp val
ilfreddy Mar 19, 2024
569d6ad
pythonized input
ilfreddy May 6, 2024
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2 changes: 2 additions & 0 deletions .gitignore
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Expand Up @@ -136,3 +136,5 @@ dmypy.json
*.out
*.prof
*.txt
*.err
*.tree
98 changes: 63 additions & 35 deletions one_electron.py
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Expand Up @@ -17,94 +17,122 @@ def analytic_1s(light_speed, n, k, Z):
tmp3 = 1 + tmp2**2
return light_speed**2 / np.sqrt(tmp3)

def gs_D_1e(spinorb1, potential, mra, prec, derivative):
print('Hartree-Fock 1e')
def gs_D_1e(spinorb1, potential, mra, prec, thr, derivative):
print('One-electron calculations')

error_norm = 1
#compute_last_energy = False

light_speed = spinorb1.light_speed

while error_norm > prec:
old_energy = 0
delta_e = 1
while (error_norm > thr and delta_e > thr/1000):
hd_psi = orb.apply_dirac_hamiltonian(spinorb1, prec, der = derivative)
v_psi = orb.apply_potential(-1.0, potential, spinorb1, prec)
add_psi = hd_psi + v_psi
energy = spinorb1.dot(add_psi).real
print('Energy',energy - light_speed**2)
mu = orb.calc_dirac_mu(energy, light_speed)
tmp = orb.apply_helmholtz(v_psi, mu, prec)
tmp.crop(prec/10)
# tmp = orb.apply_dirac_hamiltonian(v_psi, prec, energy, der = derivative)
tmp.cropLargeSmall(prec)
new_orbital = orb.apply_dirac_hamiltonian(tmp, prec, energy, der = derivative)
new_orbital.crop(prec/10)
# new_orbital = orb.apply_helmholtz(tmp, mu, prec)
# new_orbital.cropLargeSmall(prec)
new_orbital.cropLargeSmall(prec)
new_orbital.normalize()
delta_psi = new_orbital - spinorb1
#orbital_error = delta_psi.dot(delta_psi).real
deltasq = delta_psi.squaredNorm()
error_norm = np.sqrt(deltasq)
print('Error', error_norm)
delta_e = np.abs(energy - old_energy)
print('Delta E', delta_e)
print('Energy',energy - light_speed**2)
old_energy = energy
spinorb1 = new_orbital

hd_psi = orb.apply_dirac_hamiltonian(spinorb1, prec, der = derivative)
v_psi = orb.apply_potential(-1.0, potential, spinorb1, prec)
add_psi = hd_psi + v_psi
energy = spinorb1.dot(add_psi).real
print('Final Energy',energy - light_speed**2)
energy_1s = analytic_1s(light_speed, 1, -1, 1)
print("Exact energy: ", energy_1s - light_speed**2)
print('Final Energy:',energy - light_speed**2)
print('Delta Energy:',energy - old_energy)
print('Error Energy:',energy - energy_1s)
return spinorb1


def gs_D2_1e(spinorb1, potential, mra, prec, derivative):
def gs_D2_1e(spinorb1, potential, mra, prec, thr, derivative):
print('Hartree-Fock 1e D2')
error_norm = 1
delta_e = 1
light_speed = spinorb1.light_speed
c2 = light_speed * light_speed

while error_norm > prec:
old_energy = 0
while (error_norm > thr and delta_e > thr/1000):
v_psi = orb.apply_potential(-1.0, potential, spinorb1, prec)
vv_psi = orb.apply_potential(-0.5/c2, potential, v_psi, prec)
vv_psi = orb.apply_potential(-0.5/c2, potential, v_psi, prec*c2)
beta_v_psi = v_psi.beta2()
apV_psi = v_psi.alpha_p(prec, derivative)
ap_psi = spinorb1.alpha_p(prec, derivative)
Vap_psi = orb.apply_potential(-1.0, potential, ap_psi, prec)
apV_psi = v_psi.alpha_p(prec*light_speed, derivative)
ap_psi = spinorb1.alpha_p(prec*light_speed, derivative)
Vap_psi = orb.apply_potential(-1.0, potential, ap_psi, prec*light_speed)
anticom = apV_psi + Vap_psi
anticom.cropLargeSmall(prec)
#beta_v_psi.cropLargeSmall(prec)
vv_psi.cropLargeSmall(prec)
# anticom.cropLargeSmall(prec)
# beta_v_psi.cropLargeSmall(prec)
# vv_psi.cropLargeSmall(prec)
RHS = beta_v_psi + vv_psi + anticom * (0.5/light_speed)
#RHS.cropLargeSmall(prec)
RHS.cropLargeSmall(prec)
cke = spinorb1.classicT()
cpe = (spinorb1.dot(RHS)).real
print("Classic-like energies:", "cke =", cke,"cpe =", cpe,"cke + cpe =", cke + cpe)
classic_energy = cke + cpe
energy = c2*(np.sqrt(1+2*classic_energy/c2)-1)
mu = orb.calc_non_rel_mu(cke+cpe)
print("mu =", mu)
new_orbital = orb.apply_helmholtz(RHS, mu, prec)
new_orbital.cropLargeSmall(prec)
new_orbital.normalize()
delta_psi = new_orbital - spinorb1
deltasq = delta_psi.squaredNorm()
error_norm = np.sqrt(deltasq)
print("Error =", error_norm)
delta_e = np.abs(energy - old_energy)
print('Delta E', delta_e)
print('Energy',energy, old_energy)
old_energy = energy
spinorb1 = new_orbital

hd_psi = orb.apply_dirac_hamiltonian(spinorb1, prec, der = derivative)
v_psi = orb.apply_potential(-1.0, potential, spinorb1, prec)
add_psi = hd_psi + v_psi
energy = spinorb1.dot(add_psi).real
energy_dirac = spinorb1.dot(add_psi).real

cke = spinorb1.classicT()
# v_psi = orb.apply_potential(-1.0, potential, spinorb1, prec)
vv_psi = orb.apply_potential(-0.5/c2, potential, v_psi, prec*c2)
beta_v_psi = v_psi.beta2()
beta_pot = (beta_v_psi.dot(spinorb1)).real
pot_sq = (v_psi.dot(v_psi)).real
ap_psi = spinorb1.alpha_p(prec, derivative)
anticom = (ap_psi.dot(v_psi)).real
energy_kutzelnigg = cke + beta_pot + pot_sq/(2*c2) + anticom/light_speed

print('Kutzelnigg =',cke, beta_pot, pot_sq/(2*c2), anticom/light_speed, energy_kutzelnigg)
print('Quadratic approx =',energy_kutzelnigg - energy_kutzelnigg**2/(2*c2))
print('Correct from Kutzelnigg =', c2*(np.sqrt(1+2*energy_kutzelnigg/c2)-1))
print('Final Energy =',energy - light_speed**2)

apV_psi = v_psi.alpha_p(prec*light_speed, derivative)
ap_psi = spinorb1.alpha_p(prec*light_speed, derivative)
Vap_psi = orb.apply_potential(-1.0, potential, ap_psi, prec*light_speed)
anticom = apV_psi + Vap_psi
# anticom.cropLargeSmall(prec)
# beta_v_psi.cropLargeSmall(prec)
# vv_psi.cropLargeSmall(prec)
RHS = beta_v_psi + vv_psi + anticom * (0.5/light_speed)
RHS.cropLargeSmall(prec)
cke = spinorb1.classicT()
cpe = (spinorb1.dot(RHS)).real
classic_energy = cke + cpe
energy = c2*(np.sqrt(1+2*classic_energy/c2)-1)
energy_1s = analytic_1s(light_speed, 1, -1, 1)

print('Exact Energy =',energy_1s - light_speed**2)
print('Difference 1 =',energy_1s - energy)
print('Difference 2 =',energy_1s - energy_kutzelnigg - light_speed**2)
# print('Kutzelnigg =',cke, cpe, energy_kutzelnigg)
# print('Quadratic approx =',energy_kutzelnigg - energy_kutzelnigg**2/(2*c2))
print('Exact Energy = ', energy_1s - light_speed**2)
print('Dirac Energy = ', energy_dirac - light_speed**2)
print('Kutze Energy = ', energy)
print('Error Kutze = ', energy - energy_1s + light_speed**2)
print('Error Dirac = ', energy_dirac - energy_1s)
print('Delta Energy = ', energy - old_energy)
print('Dirac - Kutzelnigg = ', energy_dirac - energy - light_speed**2)
return spinorb1
83 changes: 10 additions & 73 deletions orbital4c/nuclear_potential.py
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Original file line number Diff line number Diff line change
Expand Up @@ -5,30 +5,13 @@
from vampyr import vampyr3d as vp
from vampyr import vampyr1d as vp1

import argparse
import numpy as np
import numpy.linalg as LA
import sys, getopt

def read_file_with_named_lists(atomlist):
charge_list = {"H" : 1, "He": 2, "Ne": 10, "Ar": 18, "Kr": 36, "Xe": 54, "Rn": 86, "Th": 90, "U":92, "Pu": 94}
atom_list = {}
index = 0
with open(atomlist, 'r') as file:
for line in file:
terms = line.strip().split()
charge = charge_list[terms[0]]
atom_list[index] = [terms[0], charge, float(terms[1]), float(terms[2]), float(terms[3])]
index += 1
number = len(atom_list)
return atom_list, number


def calculate_center_of_mass(atoms_list):
total_mass = 0.0
center_of_mass = [0.0, 0.0, 0.0]

for atom in atoms_list.values():
for atom in atoms_list:
# Assuming each atom has mass 1.0 (modify if necessary)
mass = 1.0
total_mass += mass
Expand All @@ -43,57 +26,9 @@ def calculate_center_of_mass(atoms_list):

return center_of_mass

#def pot(coordinates, typenuc, mra, prec, der):
# atomic_potentials = []
# V_tree = vp.FunctionTree(mra)
# V_tree.setZero()
# for atom, origin in coordinates.items():
# atom = get_original_list_name(atom)
# print("Atom:", atom)
# fileObj = open("Z.txt", "r")
# charge = ""
# for line in fileObj:
# if not line.startswith("#"):
# line = line.strip().split()
# if len(line) == 2:
# if line[0] == atom:
# charge = float(line[1])
# print("Charge:", charge)
# fileObj.close()
# print("Origin:", origin)
# print() # Print an empty line for separation
#
# if typenuc == 'point_charge':
# Peps = vp.ScalingProjector(mra,prec/10)
# f = lambda x: point_charge(x, origin, charge)
# V = Peps(f)
# elif typenuc == 'coulomb_HFYGB':
# Peps = vp.ScalingProjector(mra,prec/10)
# f = lambda x: coulomb_HFYGB(x, origin, charge, prec)
# V = Peps(f)
# elif typenuc == 'homogeneus_charge_sphere':
# Peps = vp.ScalingProjector(mra,prec/10)
# f = lambda x: homogeneus_charge_sphere(x, origin, charge, atom)
# V = Peps(f)
# elif typenuc == 'gaussian':
# Peps = vp.ScalingProjector(mra,prec/10)
# f = lambda x: gaussian(x, origin, charge, atom)
# V = Peps(f)
# print("Potential for atom ", atom)
# print(V)
# atomic_potentials.append(V)
## vp.advanced.add(prec, V_tree, atomic_potentials)
# V_tree = atomic_potentials[0] + atomic_potentials[1]
# print('Define V Potential', typenuc, 'DONE')
# return V_tree
#




def nuclear_potential(position, atoms_list, typenuc, mra, prec, der):
potential = 0
for atom in atoms_list.values():
for atom in atoms_list:
charge = atom[1]
atomname = atom[0]
atom_coordinates = [atom[2], atom[3], atom[4]]
Expand All @@ -116,17 +51,19 @@ def point_charge(position, center , charge):
distance = np.sqrt(d2)
return charge / distance

def smoothing_HFYGB(charge, prec):
factor = 0.00435 * prec / charge**5
return factor**(1./3.)

def uHFYGB(r):
u = erf(r)/r + (1/(3*np.sqrt(np.pi)))*(np.exp(-(r**2)) + 16*np.exp(-4*r**2))
return u

def coulomb_HFYGB(position, center, charge, precision):
d2 = ((position[0] - center[0])**2 +
(position[1] - center[1])**2 +
(position[2] - center[2])**2)
distance = np.sqrt(d2)
def smoothing_HFYGB(charge, prec):
factor = 0.00435 * prec / charge**5
return factor**(1./3.)
def uHFYGB(r):
u = erf(r)/r + (1/(3*np.sqrt(np.pi)))*(np.exp(-(r**2)) + 16*np.exp(-4*r**2))
return u
factor = smoothing_HFYGB(charge, precision)
value = uHFYGB(distance/factor)
return charge * value / factor
Expand Down
24 changes: 12 additions & 12 deletions orbital4c/operators.py
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Expand Up @@ -94,11 +94,11 @@ def setup(self):
vp.advanced.add(self.prec, rho, rholist)
self.potential = (4.0*np.pi) * self.poisson(rho).crop(self.prec)

def __call__(self, phi):
def __call__(self, phi, prec_mod = 1.0):
complex_pot = cf.complex_fcn()
complex_pot.real = self.potential
complex_pot.imag.setZero()
out = orb.apply_complex_potential(1.0, complex_pot, phi, self.prec)
out = orb.apply_complex_potential(1.0, complex_pot, phi, self.prec * prec_mod)
out.cropLargeSmall(self.prec)
return out

Expand All @@ -108,20 +108,20 @@ def __init__(self, mra, prec, Psi):
self.poisson = vp.PoissonOperator(mra=self.mra, prec=self.prec)
self.potential = None

def __call__(self, phi):
def __call__(self, phi, prec_mod = 1):
Kij_array = []
coeff_array = []
for i in range(0, len(self.Psi)):
V_ij = cf.complex_fcn()
overlap_density = self.Psi[i].overlap_density(phi, self.prec)
V_ij.real = self.poisson(overlap_density.real).crop(self.prec)
V_ij.imag = self.poisson(overlap_density.imag).crop(self.prec)
tmp = orb.apply_complex_potential(1.0, V_ij, self.Psi[i], self.prec)
overlap_density = self.Psi[i].overlap_density(phi, self.prec * prec_mod)
V_ij.real = self.poisson(overlap_density.real).crop(self.prec * prec_mod)
V_ij.imag = self.poisson(overlap_density.imag).crop(self.prec * prec_mod)
tmp = orb.apply_complex_potential(1.0, V_ij, self.Psi[i], self.prec * prec_mod)
Kij_array.append(tmp)
coeff_array.append(1.0)
output = orb.add_vector(Kij_array, coeff_array, self.prec)
output = orb.add_vector(Kij_array, coeff_array, self.prec * prec_mod)
output *= 4.0 * np.pi
output.cropLargeSmall(self.prec)
output.cropLargeSmall(self.prec * prec_mod)
return output

class PotentialOperator(Operator):
Expand All @@ -130,11 +130,11 @@ def __init__(self, mra, prec, potential, real = True):
self.potential = potential
self.real = real

def __call__(self, phi):
def __call__(self, phi, prec_mod = 1):
if(self.real):
result = orb.apply_potential(1.0, self.potential, phi, self.prec)
result = orb.apply_potential(1.0, self.potential, phi, self.prec * prec_mod)
else:
result = orb.apply_complex_potential(1.0, self.potential, phi, self.prec)
result = orb.apply_complex_potential(1.0, self.potential, phi, self.prec * prec_mod)
result.cropLargeSmall(self.prec)
return result

Expand Down
2 changes: 1 addition & 1 deletion orbital4c/orbital.py
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Expand Up @@ -101,7 +101,7 @@ def cropLargeSmall(self, prec):
largeNorm = np.sqrt(self.squaredLargeNorm())
smallNorm = np.sqrt(self.squaredSmallNorm())
precLarge = prec * largeNorm
precSmall = prec * smallNorm
precSmall = prec * largeNorm / 100
# print('precisions', precLarge, precSmall)
self['La'].crop(precLarge, True)
self['Lb'].crop(precLarge, True)
Expand Down
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