9:27 AM
It's entirely plausible for the code to give the same (or similar) output. You are trying to evaluate an infinite integral. You're gradually increasing the upper limit. You believe that the infinite integral should give you a positive scalar, so, as you increase the upper limit, I'd expect a similar number to be produced, possibly increasing slightly with each increase of the upper integration limit
9:44 AM
10:37 AM
from qutip import * from matplotlib import * import numpy as np import scipy from scipy.constants import * import matplotlib.pyplot as plt hamiltonian = np.array([[215, -104.1, 5.1, -4.3 ,4.7,-15.1 ,-7.8 ], [-104.1, 220.0, 32.6 ,7.1, 5.4, 8.3, 0.8], [ 5.1, 32.6, 0.0, -46.8, 1.0 , -8.1, 5.1], [-4.3, 7.1, -46.8, 125.0, -70.7, -14.7, -61.5], [ 4.7, 5.4, 1.0, -70.7, 450.0, 89.7, -2.5], [-15.1, 8.3, -8.1, -14.7, 89.7, 330.0, 32.7], [-7.8, 0.8, 5.1, -61.5, -2.5, 32.7, 280.0]])
The code above should get you going. It evolves your system from t=0 to t=25 and then plots (using matplotlib) <3|rho(t)|3> for you to get a feel of it.
Note - I plot 1000 intermediate times. You might want to do fewer, or evolve the time further - play around!
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Aug13
Aug '1514
Aug15
Room for J Richard Snape and TanMath
This room is to discuss stackoverflow.com/questions/31900993/…...