I tried to use the standard iterative algorithm to compute nth roots.

For instance (111^123)^(1/123).

The standard algorithm computes high powers ~~of the base (in this case 111^123)~~ which takes a lot of time. The algorithm is given here http://en.wikipedia.org/wiki/Nth_root_algorithm

However, I noticed that the same thing using double takes less than a millisecond. So obviously they use some smart ideas. Any hints on this?

`a^(1/x)`

for large`a, x`

with`x`

integer, I computed a random`b`

such that`b^x < a`

but`b^(x+1)>a`

. Let`c=a/b^x`

. I computed`a^(1/x) = (a*b^x/(b^x))^(1/x) = c^(1/x)*b`

. I was hoping that by keeping the base`c`

small, I could gain some time. Unfortunately, I either get divide by zero error in computation of`c^(1/x)`

if I keep the scale of the division small, or long computation time if I keep this scale big. So this does not buy anything. – Jus12 Jan 28 '10 at 14:00`b^x<a < b^(x+sqrt(x))`

. The time of several minutes is still not short enough. – Jus12 Jan 29 '10 at 21:47