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harmonic number
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(Definition)
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The <</SPAN>#57#>harmonic number of order $n$ of $\theta$ is defined as
$$ H_{\theta}(n) = \sum_{i=1}^n \frac{1}{i^{\theta}} $$
Note that $n$ may be equal to $\infty$ provided $\theta > 1$
If $\theta \le 1$ while $n=\infty$ the harmonic series does not converge and hence the harmonic number does not exist.
If $\theta = 1$ we may just write $H_{\theta}(n)$ as $H_n$ (this is a common notation).
Properties
- If $\Re(\theta) > 1$ and $n=\infty$ then the sum is the Riemann zeta function.
- If $\theta=1$ then we get what is known simply as``the harmonic number'', and it has many important properties. For example, it has asymptotic expansion $H_n=\ln n+\gamma+\frac{1}{2m}+\dotsc$ where $\gamma$ is Euler's constant.
- It is possible 1 to define harmonic numbers for non-integral $n$ This is done by means of the series $H_n(z)=\sum_{n\geq 1}(n^{-z}-(n+x)^{-z})$
Footnotes
- 1
- See ``The Art of computer programming'' vol. 2 by D. Knuth
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"harmonic number" is owned by mathcam. [ full author list (2) | owner history (1) ]
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Cross-references: series, Euler's constant, properties, Riemann zeta function, sum, converge, harmonic series
There are 3 references to this entry.
This is version 7 of harmonic number, born on 2002-09-05, modified 2006-08-10.
Object id is 3421, canonical name is HarmonicNumber.
Accessed 9819 times total.
Classification:
| AMS MSC: | 40A05 (Sequences, series, summability :: Convergence and divergence of infinite limiting processes :: Convergence and divergence of series and sequences) | | | 26A06 (Real functions :: Functions of one variable :: One-variable calculus) |
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Pending Errata and Addenda
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