```
f(x) = (exp(x)-1)/x;
g(x) = (exp(x)-1)/log(exp(x))
```

Analytically, `f(x) = g(x)`

for all `x`

.

When x approaches 0, both `f(x)`

and `g(x)`

approach 1.

```
% Compute y against x
for k = 1:15
x(k) = 10^(-k);
f(k) =(exp(x(k))-1)/x(k);
De(k) = log(exp(x(k)));
g(k)= (exp(x(k))-1)/De(k);
end
% Plot y
plot(1:15,f,'r',1:15,g,'b');
```

However, `g(x)`

works better than `f(x)`

. `f(x)`

actually diverges when `x`

approaches 0. Why is `g(x)`

better than `f(x)`

?