I am trying to evaluate the following integral:

I can find the area for the following polynomial as follows:

```
pn =
-0.0250 0.0667 0.2500 -0.6000 0
```

First using the integration by Simpson's rule

```
fn=@(x) exp(polyval(pn,x));
area=quad(fn,-10,10);
fprintf('area evaluated by Simpsons rule : %f \n',area)
```

and the result is `area evaluated by Simpsons rule : 11.483072`

Then with the following code that evaluates the summation in the above formula with gamma function

```
a=pn(1);b=pn(2);c=pn(3);d=pn(4);f=pn(5);
area=0;
result=0;
for n=0:40;
for m=0:40;
for p=0:40;
if(rem(n+p,2)==0)
result=result+ (b^n * c^m * d^p) / ( factorial(n)*factorial(m)*factorial(p) ) *...
gamma( (3*n+2*m+p+1)/4 ) / (-a)^( (3*n+2*m+p+1)/4 );
end
end
end
end
result=result*1/2*exp(f)
```

and this returns 11.4831. More or less the same result with the `quad`

function. Now my question is whether or not it is possible for me to get rid of this nested loop as I will construct the cumulative distribution function so that I can get samples from this distribution using the inverse CDF transform. (for constructing the cdf I will use `gammainc`

i.e. the incomplete gamma function instead of `gamma`

)

I will need to sample from such densities that may have different polynomial coefficients and speed is of concern to me. I can already sample from such densities using Monte Carlo methods but I would like to see whether or not it is possible for me to use exact sampling from the density in order to speed up. Thank you very much in advance.