"""Example illustrating the use of TDVP in tenpy.
As of now, we have TDVP only for finite systems. The call structure is quite similar to TEBD. A
difference is that we can run one-site TDVP or two-site TDVP. In the former, the bond dimension can
not grow; the latter allows to grow the bond dimension and hence requires a truncation.
"""
# Copyright 2019-2021 TeNPy Developers, GNU GPLv3
import numpy as np
import tenpy.linalg.np_conserved as npc
import tenpy.models.spins
import tenpy.networks.mps as mps
import tenpy.networks.site as site
from tenpy.algorithms import tdvp
from tenpy.networks.mps import MPS
import copy
def run_out_of_equilibrium():
L = 10
chi = 5
delta_t = 0.1
model_params = {
'L': L,
'S': 0.5,
'conserve': 'Sz',
'Jz': 1.0,
'Jy': 1.0,
'Jx': 1.0,
'hx': 0.0,
'hy': 0.0,
'hz': 0.0,
'muJ': 0.0,
'bc_MPS': 'finite',
}
heisenberg = tenpy.models.spins.SpinChain(model_params)
product_state = ["up"] * (L // 2) + ["down"] * (L - L // 2)
# starting from a domain-wall product state which is not an eigenstate of the Heisenberg model
psi = MPS.from_product_state(heisenberg.lat.mps_sites(),
product_state,
bc=heisenberg.lat.bc_MPS,
form='B')
tdvp_params = {
'start_time': 0,
'dt': delta_t,
'trunc_params': {
'chi_max': chi,
'svd_min': 1.e-10,
'trunc_cut': None
}
}
tdvp_engine = tdvp.TDVPEngine(psi, heisenberg, tdvp_params)
times = []
S_mid = []
for i in range(30):
tdvp_engine.run_two_sites(N_steps=1)
times.append(tdvp_engine.evolved_time)
S_mid.append(psi.entanglement_entropy(bonds=[L // 2])[0])
for i in range(30):
tdvp_engine.run_one_site(N_steps=1)
#psi_2=copy.deepcopy(psi)
#psi_2.canonical_form()
times.append(tdvp_engine.evolved_time)
S_mid.append(psi.entanglement_entropy(bonds=[L // 2])[0])
import matplotlib.pyplot as plt
plt.figure()
plt.plot(times, S_mid)
plt.xlabel('t')
plt.ylabel('S')
plt.axvline(x=3.1, color='red')
plt.text(0.0, 0.0000015, "Two sites update")
plt.text(3.1, 0.0000015, "One site update")
plt.show()
if __name__ == "__main__":
import logging
logging.basicConfig(level=logging.INFO)
run_out_of_equilibrium()