Your problem/question is too vague / too general. I cannot offer more, therefore, than a few general remarks:

For starters, a general method to sum "any" infinite series does not exist. For each series individually you will have to determine how to sum THAT PARTICULAR ONE and this requires, first of all, a study of its convergence-characteristics: a series may converge, diverge, or conditionally converge. Simply adding terms until a term gets smaller than some limit, or until the difference between successive terms becomes smaller than some limit is not a guarantee that you're close to the limiting sum. In fact, it doesn't even guarantee that the sum is finite at all (consider the series 1 + 1/2 + 1/3 + 1/4 ... for example).

Now, let's view your example: -sum( x^n/n; n=1..inf ).
This particular series doesn't have a finite sum for any x>=1 and neither for x<-1: it doesn't converge unless -1<=x<1, the terms get larger and larger... (however, read on!).

For `abs(x)<1`

a 'straightforward' approach of adding successive terms will 'in the end' give you the correct answer, but it will take a long while before you get close to the limiting sum, unless x is very small, and assessing HOW close you are with any finite sub-sum is far from trivial. Moreover, there are better (=faster-converging) methods to sum such types of series.

In this specific case, you may note that it is log(1-x), expressed in a Maclaurin series expansion, so there's not need to set up a tedious summation at all, because the result of the infinite summation is already known.

Now, consider at the one hand that we can easily see that the terms will get bigger and bigger for higher 'n' whenever abs(x) is greater than 1, so that any simple summing-procedure is bound to fail.
At the other hand we have this Maclaurin expansion for {log(1-x); -1<=x<1} and we may ponder how it all fits in with the knowledge that surely log(1-x) also exists and is finite for x=-4: could we maybe 'define' the limit of the summation also for x<-1 by this logarithm?! Enter the wonderful world of analytic continuation. I won't go into this, it would take far too much space here.

All in all, summing an infinite series is an art, not something to throw into a standard-summing-machine. Consequently, without specifying which series you wish to sum, you cannot a priori say what method one should apply.

Finally, I do not know what you mean by a "mixed method", so I cannot comment on that, or on its comparison against a recursive method. A recursive method might come in whenever you can write your series in a form that is very similar to the original, but just 'slightly simpler'. An example, not from an infinite series, but from a finite series: the Fibonacci number F(n) can be defined as the finite sum F(N-1)+F(n-2). That is recursion and you 'only' have to know some base-value(s) - i.c: F(0)=F(1)=1 - and there you have your recurrence set-up. Rewriting a series in a recursive form may help to find an analytic solution, or to split off a part that has an analytic solution leaving a 'more convenient' series that lends itself to a fast-converging numerical approach.

Maybe "mixed method" is intended to indicate a mixture of an analytical summation - as with your series: log(1-x) - and some (smart or brute-force) numerical approximation (where, as others pointed out, 'recursive' might be meant to be 'iterative').

To conclude: (a) clarify what you mean by "mixed" and "recursive" methods; (b) be specific about what type of series you need to sum, lest there's no sensible answer possible.

`a_i = 1/i`

. Any more details on the "row"? Is it geometric series? – amit Oct 22 '12 at 9:29`1/2^i`

doesn't sum to infinity – amit Oct 22 '12 at 9:31