Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am trying to re-write this MATLAB program in Python. I haven't succeeded in getting the same Python output, yet. But my attempt is given beneath the MATLAB code. The code does not need any extra files/information to run. So this should run OK on your MATLAB. And, if all goes to plan, Python also...

Summary of what the code does: Performs an integral taking in arguments eV and t, for an array of variables eV. There are also more complicated things considering a substitution for E. But, those familiar with both codes should be able to follow.

Please feel free to ask if you have any questions, and many thanks for any potential help/hints/solutions.



clear all %Remove items from MATLAB workspace and reset MuPAD engine
clc %Clear command window
clf %Clear figure window

global d1 d2 T %Declare global variables

T = 0.02; %Temperature value (K)
d1 = 1; %Energy gap in electrode 1.
d2 = 0.5; %Energy gap in electrode 2.

small = 1e-9; 
eV_values = linspace(0, 2.5, 2e3); %Row vector of 2e3 points linearly spaced between 0 and 0.25. These are the voltage values.

current = zeros(size(eV_values)); %Zeros creates array all of zeros. size gives size of dataset array.

tic %Start clock to measure performance
for x = 1:numel(eV_values) %numel gives number of elements in array ev_values).
    eV = eV_values(x);

    clc %Clear command window
    disp(x) %Display array

    current(x) = quad(@(t)integrand(t, eV), -1 + small, 1 - small); 
toc %End clock

clf %Clear figure window
figure(1) %Create graphics object

hold on %Retain current graph when adding new graphs/Delay evaluation.
box on %Display the boundary of the current axes.
plot(eV_values, real(current), 'b')
plot(eV_values, imag(current), 'r')


function x = integrand(t, eV) %Declare function name and inputs

global d1 d2 T %Declare global variable

E = t./(1 - t.^2); %Variable substitution

x = abs(E)./sqrt(E.^2 - d1^2).*abs(E + eV)./sqrt((E + eV).^2 - d2^2).*...
    (1./(1 + exp(E./T)) - 1./(1 + exp((E + eV)./T)));

x = x.*heaviside(E.^2 - d1^2).*heaviside((E + eV).^2 - d2^2);
x = x.*(1 + t.^2)./(1 - t.^2).^2;

%heaviside step function


from numpy import *
import pylab as pl
import array
from scipy import integrate

T = 0.02    # Global variable - Temperature (K)
d1 = 1      # Global variable - Energy gap in electrode 1.
d2 = 0.5    # Global variable - Energy gap in electrode 2.

small = 1e-9 
eV_values = linspace(0.0, 2.5, num=10)

def heaviside( x ): 
    # Return 0 for x<0, 1 for x>0, 0.5 for x=0. #
    if x == 0:
        return 0.5
    return 0 if x < 0 else 1

def integrand( t, eV ):
    #print(" t: %s, eV: %s" % (t, eV))
    E = t / ( 1 - t*t ) # E substitution.
    x1 = ( abs( E ) / sqrt( E*E - d1*d1 ) ) * ( abs( E + eV ) / ( sqrt( ( E + eV )**2 - d2*d2 ) ) ) * (1/(1 + exp(E/T)) - 1/(1 + exp((E + eV)/T)))
    x2 = x1*(heaviside( E*E - d1*d1 )*heaviside( (E + eV)**2 - d2*d2) )
    x = x2*( ( 1 + t*t ) / ( 1 - t*t )**2 )
    return x

current = []
for eV in eV_values:
    integral, err = integrate.quad( integrand, ( -1 + small ), ( 1 - small ), args=(eV, ) )

#   print( eV, integral )
    print( eV, integral, err)
    current.append( integral )

#print( 'current values')
print( current )


Notable problems:

  • The MATLAB code considers imaginary/real current values in quad. Python code currently doesn't, but ought to for obtaining the same output.
  • The current Python code outputs: Giving nan values for the integral and err. Again, this may be down to the program not considering imaginary and real values in the integral.

In [3]: run IV.py IV.py:22: RuntimeWarning: invalid value encountered in sqrt x1 = (abs(E)/sqrt(E*E - d1*d1)) * (abs(E + eV)/(sqrt((E + eV)**2 - d2*d2))) * (1/(1 + exp(E/T)) - 1/(1 + exp((E + eV)/T))) IV.py:22: RuntimeWarning: overflow encountered in exp x1 = (abs(E)/sqrt(E*E - d1*d1)) * (abs(E + eV)/(sqrt((E + eV)**2 - d2*d2))) * (1/(1 + exp(E/T)) - 1/(1 + exp((E + eV)/T))) (0.0, nan, nan) (0.27777777777777779, nan, nan) (0.55555555555555558, nan, nan) (0.83333333333333337, nan, nan) (1.1111111111111112, nan, nan) (1.3888888888888888, nan, nan) (1.6666666666666667, nan, nan) (1.9444444444444446, nan, nan) (2.2222222222222223, nan, nan) (2.5, nan, nan) [nan, nan, nan, nan, nan, nan, nan, nan, nan, nan]

share|improve this question

closed as too localized by Charles Duffy, bla, Shai, Bob Kaufman, Jeff B Feb 28 '13 at 21:03

This question is unlikely to help any future visitors; it is only relevant to a small geographic area, a specific moment in time, or an extraordinarily narrow situation that is not generally applicable to the worldwide audience of the internet. For help making this question more broadly applicable, visit the help center. If this question can be reworded to fit the rules in the help center, please edit the question.

It's easier for us to answer your question if you try to pare it down to the bits that you're having trouble with and include their output. –  Nick T Feb 28 '13 at 0:44
Cool! Can do, tried doing that (quite ineffectively I see now) by mentioning the notable problems at the end. Will edit this shortly. –  8765674 Feb 28 '13 at 0:50
If you have more MATLAB code to convert to Python, you might consider stackoverflow.com/questions/9845292/converting-matlab-to-python/… although numpy specific issues will probably still have to be resolved manually. –  Ioannis Filippidis Oct 19 '13 at 21:10

1 Answer 1

numpy.sqrt can't deal with minus values. Use numpy.emath.sqrt instead.

And because calculate with floating numbers is not precise, it's better to return the real part of x:

return x.real

In addition, calculations with numpy scalar is slow. It's better to use python standard module math & cmath to do the calculations in integrand().

share|improve this answer
Thanks, learnt a lot from that post. –  8765674 Feb 28 '13 at 12:09

Not the answer you're looking for? Browse other questions tagged or ask your own question.