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.

MATLAB CODE:

**Main.m**

```
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);
end
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')
title('S-S')
xlabel('eV/\Delta')
ylabel('I(eV)')
```

**Integrand.m**

```
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
```

PYTHON CODE:

```
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 )
#pl.plot(eV_values,current,'b')
#pl.plot(eV_values,imag(current),'r')
#pl.title('S-S')
#pl.xlabel(r'eV/$\Delta$')
#pl.ylabel('I(eV)')
#pl.show()
```

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]
```