The answers by Ramchandra Apte and Lazarus both contain what seems to be the essence of the correct answer, but both are also (at least to me) a bit hard to follow. Let me try to explain the trick they seem to be getting at, as I understand it, a bit more clearly:

The basic idea is that, to find out whether *a* or *a*+1 is closer to ^{k}√*n*, we need to test whether ^{k}√*n* < *a*+½.

To get rid of the ½, we can simply multiply both sides of this inequality by 2, giving 2·^{k}√*n* < 2*a*+1, and by raising both sides to the *k*-th power (and assuming they're both positive) we get the equivalent inequality 2^{k}·*n* < (2*a*+1)^{k}. So, at least as long as 2^{k}·*n* = *n* ≪ *k* does not overflow, we can simply compare it with (2*a*+1)^{k} to obtain the answer.

In fact, we could simply compute *b* = ⌊ ^{k}√(2^{k}·*n*) ⌋ to begin with. If *b* is even, then the closest integer to ^{k}√*n* is *b* / 2; if *b* is odd, it is (*b* + 1) / 2. Indeed, we can combine the two cases and say that the closest integer to ^{k}√*n* is ⌊ (*b*+1) / 2 ⌋, or, in pseudo-C:

```
int round_root( int k, int n ) {
int b = floor_root( k, n << k );
return (b + 1) / 2;
}
```

Ps. An alternative approach could be to compute an approximation (*a*+½)^{k} directly using the binomial theorem as
(*a*+½)^{k}
= ∑_{i=0..k} (*k* choose *i*) *a*^{k−i} / 2^{i}
≈ *a*^{k}
+ *k*·*a*^{k−1} / 2 + ... and compare it directly with *n*. However, at least naïvely, summing all the terms of the binomial expansion would still require keeping track of *k* extra bits of precision (or at least *k*−1; I believe the last term can be safely neglected), so it may not gain much over the method suggested above.