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Does anyone know how to write a program in Python that will calculate the addition of the harmonic series. i.e. 1 + 1/2 +1/3 +1/4...

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the first term in the harmonic series is 1 –  hop Jan 1 '09 at 1:19

8 Answers 8

@Kiv's answer is correct but it is slow for large n if you don't need an infinite precision. It is better to use an asymptotic formula in this case:

asymptotic expansion for harmonic number

#!/usr/bin/env python
from math import log

def H(n):
    """Returns an approximate value of n-th harmonic number.

    # Euler-Mascheroni constant
    gamma = 0.57721566490153286060651209008240243104215933593992
    return gamma + log(n) + 0.5/n - 1./(12*n**2) + 1./(120*n**4)

@Kiv's answer for Python 2.6:

from fractions import Fraction

harmonic_number = lambda n: sum(Fraction(1, d) for d in xrange(1, n+1))


>>> N = 100
>>> h_exact = harmonic_number(N)
>>> h = H(N)
>>> rel_err = (abs(h - h_exact) / h_exact)
>>> print n, "%r" % h, "%.2g" % rel_err
100 5.1873775176396242 6.8e-16

At N = 100 relative error is less then 1e-15.

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@recursive's solution is correct for a floating point approximation. If you prefer, you can get the exact answer in Python 3.0 using the fractions module:

>>> from fractions import Fraction
>>> def calc_harmonic(n):
...   return sum(Fraction(1, d) for d in range(1, n + 1))
>>> calc_harmonic(20) # sum of the first 20 terms
Fraction(55835135, 15519504)

Note that the number of digits grows quickly so this will require a lot of memory for large n. You could also use a generator to look at the series of partial sums if you wanted to get really fancy.

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You have off-by-one error. range(1, n) produces (n-1) items not n items as required. Sum of the first 20 terms is 55835135/ 15519504. See stackoverflow.com/questions/404346/… –  J.F. Sebastian Jan 1 '09 at 10:56
Use xrange to prevent it from eating tons of memory –  zenazn Jan 1 '09 at 15:34
This is Python 3.0 - xrange has been renamed range and the old memory-hungry range is gone. –  Kiv Jan 1 '09 at 16:08
@Kiv: range in Python 3.0 is not just renamed xrange e.g., range accepts large integers but xrange doesn't. –  J.F. Sebastian Jan 1 '09 at 16:46
You're right. Is this due to a change in the xrange code, or a consequence of unifying the int/long types? Both versions require an int argument, but the definition of an int changed. –  Kiv Jan 1 '09 at 17:21

The harmonic series diverges, i.e. its sum is infinity..

edit: Unless you want partial sums, but you weren't really clear about that.

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I was assuming he was looking for a finite sub-series, since looping over the whole series would also take infinitely long. –  recursive Jan 1 '09 at 1:03
Well, but that's a moot point - the series diverges anyway, so adding up an infinite number of terms is an exercise in futility. –  dancavallaro Jan 1 '09 at 1:06

This ought to do the trick.

def calc_harmonic(n):
    return sum(1.0/d for d in range(2,n+1))
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If you are using Python 3 you can do 1/d instead of 1.0/d –  mdec Jan 1 '09 at 1:01
If you use xrange, this doesn't use an exorbitant amount of memory for large n –  zenazn Jan 1 '09 at 1:15
Also note the loss of precision in using floating point numbers -- @Kiv's answer yields the exact value for all n. –  cdleary Jan 1 '09 at 2:39
@cdleary: What are you going to do with the exact answer? The numerator and denominator grow exponentially, so using floating points is a good idea. [And it's much much faster to print an approximation; just print "ln n + 0.5772156649" -- see en.wikipedia.org/wiki/Euler-Mascheroni_constant ] –  ShreevatsaR Jan 1 '09 at 14:16

Just a footnote on the other answers that used floating point; starting with the largest divisor and iterating downward (toward the reciprocals with largest value) will put off accumulated round-off error as much as possible.

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How about this:

partialsum = 0
for i in xrange(1,1000000):
    partialsum += 1.0 / i
print partialsum

where 1000000 is the upper bound.

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When you assign to sum, you're overwriting a builtin function. I try to avoid doing that, because it can lead to weird bugs if you try to call that function later. –  recursive Jan 1 '09 at 1:03
Oops. I'll fix it. –  zenazn Jan 1 '09 at 1:05
Also, another minor thing: your first term is 1/1. In the question it's 1/2. –  recursive Jan 1 '09 at 1:06
If I remember correctly, the first term of the harmonic series is 1/1. –  dancavallaro Jan 1 '09 at 1:08
That's how I learned it too, but the question says otherwise. Oh well. –  recursive Jan 1 '09 at 1:09

A fast, accurate, smooth, complex-valued version of the H function can be calculated using the digamma function as explained here. The Euler-Mascheroni (gamma) constant and the digamma function are available in the numpy and scipy libraries, respectively.

from numpy import euler_gamma
from scipy.special import digamma

def digamma_H(s):
    """ If s is complex the result becomes complex. """
    return digamma(s + 1) + euler_gamma

from fractions import Fraction

def Kiv_H(n):
    return sum(Fraction(1, d) for d in xrange(1, n + 1))

def J_F_Sebastian_H(n):
    return euler_gamma + log(n) + 0.5/n - 1./(12*n**2) + 1./(120*n**4)

Here's a comparison of the three methods for speed and precision (with Kiv_H for reference):

Kiv_H(x) J_F_Sebastian_H(x) digamma_H(x) x seconds bits seconds bits seconds bits 1 5.06e-05 exact 2.47e-06 8.8 1.16e-05 exact 10 4.45e-04 exact 3.25e-06 29.5 1.17e-05 52.6 100 7.64e-03 exact 3.65e-06 50.4 1.17e-05 exact 1000 7.62e-01 exact 5.92e-06 52.9 1.19e-05 exact

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It's a divergent series, so it's impossible to sum it for all terms.

I don't know Python, but I know how to write it in Java.

public class Harmonic
    private static final int DEFAULT_NUM_TERMS = 10;

    public static void main(String[] args)
        int numTerms = ((args.length > 0) ? Integer.parseInt(args[0]) : DEFAULT_NUM_TERMS);

        System.out.println("sum of " + numTerms + " terms=" + sum(numTerms));

     public static double sum(int numTerms)
         double sum = 0.0;

         if (numTerms > 0)
             for (int k = 1; k <= numTerms; ++k)
                 sum += 1.0/k;

         return sum;
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+1, why all the downvotes, children? –  Ali Afshar Jan 1 '09 at 12:48
It does sort of fail at being a "python program to calculate harmonic series" –  J.T. Hurley Jan 1 '09 at 14:34
but certainly if somebody was sincere at wanting to do the calculation they could piece it together from this. [note to self: learn python] –  duffymo Jan 1 '09 at 15:14
I think it's always nice to have an alternative perspective on things. –  Ali Afshar Jan 1 '09 at 16:02
Think of it as pseudo-code instead of Java. –  duffymo Jan 1 '09 at 16:16

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