I did this in Mathematica to compute Sqrt[5]:

```
a[0] = 2
a[n_] := a[n] = a[n-1] - (a[n-1]^2-5)/2/a[n-1]
```

How close is a[25] to Sqrt[5]?

```
N[Sqrt[5]-a[25]] // FortranForm
4.440892098500626e-16
```

And how close is a[25]^2 to 5?

```
N[a[25]^2-5] // FortranForm
8.305767102358763e-42074769
```

This seems odd to me. My estimate: if x is within 10^-n of Sqrt[5], then x^2 is within 10^(-2*n) of 5, give or take. No? In fact:

```
a[25]^2 = (Sqrt[5]-4.440892098500626e-16)^2 ~ 5 - 2*5*4.440892098500626e-16
```

(expanding (a-b)^2), so the accuracy should be only about 14 digits (or n digits in general).

Of course, Newton's method yielding only 15 accurate digits in 25 iterations also seems odd.

Am I losing precision too early in the calculations above? Note that:

```
N[Log[Sqrt[5]-a[25]]] // FortranForm
-35.35050620855721
```

agrees w/ the 15 digit precision above, even though I do N[] *after*
taking the Log (so it should be accurate).