For some series, such as the one shown, you can use the alternating series test to compute the sum to within a desired error. Libraries such as Decimal, GyPy, mpmath, or bigfloat, etc, can be used if your calculation will bump into the precision of built-in floats.
Note on integer approaches:
Although the ratio-of-integers approachs seems more accurate, they are completely impractical for real calculations. The reason for this is: 1) adding fractions requires creating equal denominators, and this basically requires multiplying the denominators, so by then end, the size of the numbers is something like
n! (i.e., the factorial); and, 2) for the example series, a precision of
m digits requires
m terms. Therefore, even for only six digit accuracy, one requires numbers roughly equal to 1000000! = 8×105,565,708. For bigger numbers, it's roughly 1010n, which quickly becomes completely impractical. Meanwhile, a decimal solution calculated to 6 or 7 or even 40 digits is trivial.
For example, running nightcrackers solution, the times and numbers of digits in the denominator or numerator I get are:
n t n_digits_in_denominator
10 0.0003 14
100 0.0167 170
1000 5.5027 1727
10000 ???? ???? (gave up after waiting one hour)
And this becomes impractical for only ~4 digits of accuracy.
So if you want to exactly calculate a finite and small number of terms and express the final result as a ratio, then the integer solutions would be a good choice, but if you want to express the final result as a decimal, you'd be better off just sticking with decimals.