First attempt:

I tried the iterative method and found interesting thing. The approximation may not be true for all `n`

. In fact if I keep track of `(n-1)*I(n-1)`

in each loop I can see

```
I = zeros(20,3);
I(1,1) = 1-1/exp(1);
for ii = 2:20
I(ii,2) = ii-1;
I(ii,3) = (ii-1)*I(ii-1,1);
I(ii,1) = 1-I(ii,3);
end
```

There is some problem around n=18. In fact, I18 = 0.05719 and 18*I18 = 1.029 which is larger than 1. I don't think there is any numerical error or number overflow in this procedure.

Second attempt:

To make sure the maths is correct (I verified twice on paper) I used `trapz`

to numerically evaluate the integral, and n=18 didn't cause any problem.

```
>> x = linspace(0,1,1+1e4);
>> f = @(n) exp(-1)*exp(x).*x.^(n-1);
>> f = @(n) exp(-1)*exp(x).*x.^(n-1)*1e-4;
>> trapz(f(5))
ans =
1.708934160520510e-01
>> trapz(f(17))
ans =
5.571936009790170e-02
>> trapz(f(18))
ans =
5.277113416899408e-02
>>
```

A closer look is as follows. I18 is slightly different (to the 4th significant digit) between the (stable) numerical method and (unstable) iterative method. 18*I18 is therefore possible to exceed 1.

```
I = zeros(20,3);
I(1,1) = 1-1/exp(1);
for ii = 2:20
I(ii,2) = ii-1;
I(ii,3) = (ii-1)*I(ii-1,1);
I(ii,1) = 1-I(ii,3);
end
J = zeros(20,3);
x = linspace(0,1,1+1e4);
f = @(n) exp(-1)*exp(x).*x.^(n-1)*1e-4;
J(1,1) = trapz(f(1));
for jj = 2:20
J(jj,1) = trapz(f(jj));
J(jj,2) = jj-1;
J(jj,3) = (jj-1)*J(jj-1,1);
end
```

I suspect there is an error in each iterative step due to the nature of numerical computations. If the iteration is long, the error propagates and, unfortunately in this case, amplifies rapidly. In order to verify this, I combined the above two methods into a hybrid algo. For most of the time the iterative way is used, and once in a while a numerical integral is evaluated from scratch without relying on previous iterations.

```
K = zeros(40,4);
K(1,1) = 1-1/exp(1);
for kk = 2:40
K(kk,2) = trapz(f(kk));
K(kk,3) = (kk-1)*K(kk-1,1);
K(kk,4) = 1-K(kk,3);
if mod(kk,5) == 0
K(kk,1) = K(kk,2);
else
K(kk,1) = K(kk,4);
end
end
```

If the iteration lasts more than 4 steps, error amplification will be large enough to invert the sign, and starts nonrecoverable oscillation.

The code should be able to explain all the data structures. Anyway, let me put some focus here. The second column is the result of `trapz`

, which is the numerical integral done on the non-iterative integration definition of I(n). The third column is (n-1)*I(n-1) and should be always positive and less than 1. The forth column is 1-(n-1)*I(n-1) and should always be positive. The first column is the choice I have made between the `trapz`

result and iterative result, to be the "true" value of I(n).

As can be seen here, in each iteration there is a small error compared to the independent numerical way. The error grows in the 3rd and 4th iteration and finally breaks the thing in its 5th. This is observed around n=25, under the case that I pick the numerical result in every 5 loops since the beginning.

Conclusion: There is nothing wrong with any definition of this integral. However the numerical error when evaluating the expressions is unfortunately aggregating, hence limiting the way you can perform the computation.

`exp(1)`

is? – Yvon Mar 5 '17 at 15:45