Model I-V.

Method: Perform an integral, as a function of E, which outputs Current for each Voltage value used. This is repeated for an array of v_values. The equation can be found below.

Although the limits in this equation range from `-inf`

to `inf`

, the limits must be restricted so that (E+eV)^2-\Delta^2>0 and E^2-\Delta^2>0, to avoid poles. (\Delta_1 = \Delta_2). Therefore there are currently two integrals, with limits from `-inf`

to `-gap-e*v`

and `gap`

to `inf`

.

However, I keep returning a `math range error`

although I believe I have excluded the troublesome E values by using the limits stated above. Pastie of errors: http://pastie.org/private/o3ugxtxai8zbktyxtxuvg

Apologies for the vagueness of this question. But, can anybody see obvious mistakes or code misuse?

My attempt:

```
from scipy import integrate
from numpy import *
import scipy as sp
import pylab as pl
import numpy as np
import math
e = 1.60217646*10**(-19)
r = 3000
gap = 400*10**(-6)*e
g = (gap)**2
t = 0.02
k = 1.3806503*10**(-23)
kt = k*t
v_values = np.arange(0,0.001,0.0001)
I=[]
for v in v_values:
val, err = integrate.quad(lambda E:(1/(e*r))*(abs(E)/np.sqrt(abs(E**2-g)))*(abs(E+e*v)/(np.sqrt(abs((E+e*v)**2-g))))*((1/(1+math.exp((E+e*v)/kt)))-(1/(1+math.exp(E/k*t)))),-inf,(-gap-e*v)*0.9)
I.append(val)
I = array(I)
I2=[]
for v in v_values:
val2, err = integrate.quad(lambda E:(1/(e*r))*(abs(E)/np.sqrt(abs(E**2-g)))*(abs(E+e*v)/(np.sqrt(abs((E+e*v)**2-g))))*((1/(1+math.exp((E+e*v)/kt)))-(1/(1+math.exp(E/k*t)))),gap*0.9,inf)
I2.append(val2)
I2 = array(I2)
I[np.isnan(I)] = 0
I[np.isnan(I2)] = 0
pl.plot(v_values,I,'-b',v_values,I2,'-b')
pl.show()
```

numerical computationdoes not involve really small floats such as`k`

and`e`

, etc. It's all fine when doing pure math, but numerical algorithms often do not work well when the floats are so small. – HappyLeapSecond Feb 18 '13 at 18:31`exp`

in the second Boltzmann term or you have simply forgotten to replace`k*t`

there with`kt`

. Besides, you are integrating in`[0.9*gap-ev, 0.9*gap]`

. Perhaps you'd like to split it into two integrals: one in`(-inf,-0.9*gap-ev]`

and one in`[0.9*gap, inf)`

. – Hristo Iliev Feb 18 '13 at 19:16`abs`

's in the denominators of the first two terms of the integrand. Having them there hides the wrong integration range. – Hristo Iliev Feb 18 '13 at 19:21`def`

not`lambda`

unless the function is extremely simple; (3) Split complicated formulas into multiple steps (e.g. define f(E) as a separate function). :-D – Steve B Feb 20 '13 at 13:22