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Analytic combinatorics

Analytic combinatorics uses techniques from complex analysis to solve problems in enumerative combinatorics, specifically to find asymptotic estimates for the coefficients of generating functions.[1][2][3]

History

One of the earliest uses of analytic techniques for an enumeration problem came from Srinivasa Ramanujan and G. H. Hardy's work on integer partitions,[4][5] starting in 1918, first using a Tauberian theorem and later the circle method.[6]

Walter Hayman's 1956 paper "A Generalisation of Stirling's Formula" is considered one of the earliest examples of the saddle-point method.[7][8][9]

In 1990, Philippe Flajolet and Andrew Odlyzko developed the theory of singularity analysis.[10]

In 2009, Philippe Flajolet and Robert Sedgewick wrote the book Analytic Combinatorics, which presents analytic combinatorics with their viewpoint and notation.

Some of the earliest work on multivariate generating functions started in the 1970s using probabilistic methods.[11][12]

Development of further multivariate techniques started in the early 2000s.[13]

Techniques

Meromorphic functions

If is a meromorphic function and is its pole closest to the origin with order , then[14]

as

Tauberian theorem

If

as

where and is a slowly varying function, then[15]

as

See also the Hardy–Littlewood Tauberian theorem.

Circle Method

For generating functions with logarithms or roots, which have branch singularities.[16]

Darboux's method

If we have a function where and has a radius of convergence greater than and a Taylor expansion near 1 of , then[17]

See Szegő (1975) for a similar theorem dealing with multiple singularities.

Singularity analysis

If has a singularity at and

as

where then[18]

as

Saddle-point method

For generating functions including entire functions which have no singularities.[19][20]

Intuitively, the biggest contribution to the contour integral is around the saddle point and estimating near the saddle-point gives us an estimate for the whole contour.

If is an admissible function,[21] then[22][23]

as

where .

See also the method of steepest descent.

Notes

  1. ^ Melczer 2021, pp. vii and ix.
  2. ^ Pemantle and Wilson 2013, pp. xi.
  3. ^ Flajolet and Sedgewick 2009, pp. ix.
  4. ^ Melczer 2021, pp. vii.
  5. ^ Pemantle and Wilson 2013, pp. 62-63.
  6. ^ Pemantle and Wilson 2013, pp. 62.
  7. ^ Pemantle and Wilson 2013, pp. 63.
  8. ^ Wilf 2006, pp. 197.
  9. ^ Flajolet and Sedgewick 2009, pp. 607.
  10. ^ Flajolet and Sedgewick 2009, pp. 438.
  11. ^ Melczer 2021, pp. 13.
  12. ^ Flajolet and Sedgewick 2009, pp. 650 and 717.
  13. ^ Melczer 2021, pp. 13-14.
  14. ^ Sedgewick 4, pp. 59
  15. ^ Flajolet and Sedgewick 2009, pp. 435. Hardy 1949, pp. 166. I use the form in which it is stated by Flajolet and Sedgewick.
  16. ^ Pemantle and Wilson 2013, pp. 55-56.
  17. ^ Wilf 2006, pp. 194.
  18. ^ Flajolet and Sedgewick 2009, pp. 393.
  19. ^ Wilf 2006, pp. 196.
  20. ^ Flajolet and Sedgewick 2009, pp. 542.
  21. ^ See Flajolet and Sedgewick 2009, pp. 565 or Wilf 2006, pp. 199.
  22. ^ Flajolet and Sedgewick 2009, pp. 553.
  23. ^ Sedgewick 8, pp. 25.

References

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Further reading

See also