I have the following integral equation:

I'm trying to solve the integral equation to see whether f(u) is predicted as cos(2u). Since we know that the solution to the integral equation is cos(2u), we can approximate the integral from 0 to infinity to the limits 0 to say, 5 if we make the value of the integral from 5 to infinity negligible, and this can be done by choosing t to be small. I have chosen 100 evaluation points for the integral between 0 to 5, and this implies that i am solving for 100 values of f(u). Since i need to solve for 100 values of f(u), I need to generate 100 equations, and thus need 100 values of time t. I choose 100 values for time t between 1 and 1.3 since this will ensure that the integral is negligible for values of 5 and beyond. The following is the scipy code for doing this:

```
from scipy import*
from matplotlib.pyplot import*
Nt_samples=100 #100 evaluation points for the time t
t=linspace(1.0,1.3,100)
number_eval_points=100 #100 evaluation points for u
eval_points=linspace(0.005,5,number_eval_points)
delta=eval_points[1]-eval_points[0]
R=zeros(100,1)
R=0.5*sqrt(2*3.14)*t*exp(-2*t*t)
A=zeros((Nt_samples,number_eval_points))
for i in range(100):
for j in range(100):
A[i,j]=delta*exp(-(eval_points[j]*eval_points[j])/(2*(t[i]*t[i])))
Z=cos(2*eval_points)
Fu=dot(linalg.inv(A),R)
plot(eval_points,Fu,eval_points,Z)
```

**Somehow, my results for f(u) are a far cry from cos(2u).** In fact, they look like a lot of random noise and follow no pattern at all! Also, the magnitude of f(u) is very large. I have tried playing around with the number of evaluation points and the value of t, but I have no luck.

**Is there anything wrong with the code/setting of parameters/logic?**

Thanks a million!

`3.14 != pi`

? I always cringe when I see people use this. I actually spent a week debugging why a program I wrote didn't give the same output as an older version of the code, and it was because the old version used 3.14. You should replace that with`math.pi`

. – SethMMorton Oct 25 '13 at 19:55