Integral test for convergence

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In mathematics, the integral test for convergence is a method used to test infinite series of monotonic terms for convergence. It was developed by Colin Maclaurin and Augustin-Louis Cauchy and is sometimes known as the Maclaurin–Cauchy test.

The integral test applied to the harmonic series. Since the area under the curve y = 1/x for x[1, ∞) is infinite, the total area of the rectangles must be infinite as well.

Statement of the test

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Consider an integer N and a function f defined on the unbounded interval [N, ∞), on which it is monotone decreasing. Then the infinite series

 

converges to a real number if and only if the improper integral

 

is finite. In particular, if the integral diverges, then the series diverges as well.

Remark

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If the improper integral is finite, then the proof also gives the lower and upper bounds

  (1)

for the infinite series.

Note that if the function   is increasing, then the function   is decreasing and the above theorem applies.

Many textbooks require the function   to be positive,[1][2][3] but this condition is not really necessary, since when   is negative and decreasing both   and   diverge.[4][better source needed]

Proof

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The proof uses the comparison test, comparing the term   with the integral of   over the intervals   and   respectively.

The monotonic function   is continuous almost everywhere. To show this, let

 

For every  , there exists by the density of  , a   so that  .

Note that this set contains an open non-empty interval precisely if   is discontinuous at  . We can uniquely identify   as the rational number that has the least index in an enumeration   and satisfies the above property. Since   is monotone, this defines an injective mapping   and thus   is countable. It follows that   is continuous almost everywhere. This is sufficient for Riemann integrability.[5]

Since f is a monotone decreasing function, we know that

 

and

 

Hence, for every integer nN,

  (2)

and, for every integer nN + 1,

  (3)

By summation over all n from N to some larger integer M, we get from (2)

 

and from (3)

 

Combining these two estimates yields

 

Letting M tend to infinity, the bounds in (1) and the result follow.

Applications

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The harmonic series

 

diverges because, using the natural logarithm, its antiderivative, and the fundamental theorem of calculus, we get

 

On the other hand, the series

 

(cf. Riemann zeta function) converges for every ε > 0, because by the power rule

 

From (1) we get the upper estimate

 

which can be compared with some of the particular values of Riemann zeta function.

Borderline between divergence and convergence

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The above examples involving the harmonic series raise the question of whether there are monotone sequences such that f(n) decreases to 0 faster than 1/n but slower than 1/n1+ε in the sense that

 

for every ε > 0, and whether the corresponding series of the f(n) still diverges. Once such a sequence is found, a similar question can be asked with f(n) taking the role of 1/n, and so on. In this way it is possible to investigate the borderline between divergence and convergence of infinite series.

Using the integral test for convergence, one can show (see below) that, for every natural number k, the series

  (4)

still diverges (cf. proof that the sum of the reciprocals of the primes diverges for k = 1) but

  (5)

converges for every ε > 0. Here lnk denotes the k-fold composition of the natural logarithm defined recursively by

 

Furthermore, Nk denotes the smallest natural number such that the k-fold composition is well-defined and lnk(Nk) ≥ 1, i.e.

 

using tetration or Knuth's up-arrow notation.

To see the divergence of the series (4) using the integral test, note that by repeated application of the chain rule

 

hence

 

To see the convergence of the series (5), note that by the power rule, the chain rule and the above result

 

hence

 

and (1) gives bounds for the infinite series in (5).

See also

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References

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  • Knopp, Konrad, "Infinite Sequences and Series", Dover Publications, Inc., New York, 1956. (§ 3.3) ISBN 0-486-60153-6
  • Whittaker, E. T., and Watson, G. N., A Course in Modern Analysis, fourth edition, Cambridge University Press, 1963. (§ 4.43) ISBN 0-521-58807-3
  • Ferreira, Jaime Campos, Ed Calouste Gulbenkian, 1987, ISBN 972-31-0179-3
  1. ^ Stewart, James; Clegg, Daniel; Watson, Saleem (2021). Calculus: Metric Version (9 ed.). Cengage. ISBN 9780357113462.
  2. ^ Wade, William (2004). An Introduction to Analysis (3 ed.). Pearson Education. ISBN 9780131246836.
  3. ^ Thomas, George; Hass, Joel; Heil, Christopher; Weir, Maurice; Zuleta, José Luis (2018). Thomas' Calculus: Early Transcendentals (14 ed.). Pearson Education. ISBN 9781292253114.
  4. ^ savemycalculus. "Why does it have to be positive and decreasing to apply the integral test?". Mathematics Stack Exchange. Retrieved 2020-03-11.
  5. ^ Brown, A. B. (September 1936). "A Proof of the Lebesgue Condition for Riemann Integrability". The American Mathematical Monthly. 43 (7): 396–398. doi:10.2307/2301737. ISSN 0002-9890. JSTOR 2301737.