I'll summarize my comments here so it's easier to understand for new visitors.
As others have pointed out, Sequence A is merely a sequence of squares; and as OP clarified through his comments, Sequence B will be ever-changing.
A restatement of OP's problem might be
Is there a faster way to determine the first square in an increasing sequence, than computing each term of the sequence?
Indeed, there is. The obvious idea is to devise a way to "skip" the computation of some terms, based on insight regarding the rates of growth of squares, versus the sequence. But it will be hard to programmatically derive insight about an arbitrary sequence.
A more robust solution might be to reformulate the problem as finding the smallest zero of:
B(x) - x^2 = 0
And for that, there may exist root-finding algorithms that may help. If you don't need to find the smallest zero, then even easier: implement any root-finding algorithm, watch the algorithm converge to a zero, add
x^2 to compensate for the reformulation, and there you have it.
(The comment box was too limited to reply to yours.)
When I said "bisection", I actually meant "binary search". This requires an upper bound, so doesn't really apply to your problem.
Let me offer a naive algorithm though, as a start, although you've probably already thought exactly this.
B(1). Say it's
1692 (not a square).
B(2). Say it's
1707 (not a square).
B(2)-B(1), call it the "delta", e.g.
15. Consider this a naive estimation of the rate of growth of
B. It's almost definitely wrong, of course, but all we're aiming for here is some way to skip terms. That's what's to be optimized, later.
- What's the next square greater than
1707? A formula,
- How many terms should we skip to try to reach that square? Another formula,
3.8, which we might round to
B(2+4) = B(6).
- If smaller than
1764, then you need to keep going. But you've saved, in this case, having to compute 3 terms. Exactly how you choose to keep going, is just another choice. You can compute
B(7) and go to step 3 (computing
B(7)-B(6) as a new delta). You can go directly to step 3 (computing
(B(6)-B(2))/4 as a new delta). (You can't really know what's best without characterizing the possible functions for
- If larger than
1764, then you need to go back. Again, there's many ways. Binary search is actually a simple, reasonable way. Compute
B(4) since it's directly in between
B(6). If less than
B(5). If greater than
B(3). If either don't match, then carry on starting with
B(7). With binary search, at most you'll do
So that sounds like a good deal, right? You'll either skip a number of computations, or you'll do
log(N) at most. (Or, you'll find even better optimizations to this.) But, obviously, it's not that simple, because you're doing extra computations to find these deltas, projections, binary search, etc. Since squares grow very slowly (there's only so many integers between squares), I feel such an algorithm will only beat the "linear search" (computing every term) if you're dealing with large integers, or extremely complex sequences of
B (but given that
B has to always increase, how complex can a sequence really be?) The key would be to find a characterization that fits all your sequences, and capitalize on that by finding an optimization specific to it.
I still don't know what your application is, but at this point you might as well just try it and benchmark it (versus linear search) over realistic datasets. This would immediately tell you whether there's any practical gain, and whether more time should be invested in optimization. And it'll be faster than trying to do all the theoretical math, characterizing sequences and whatnot.