Papers
Topics
Authors
Recent
Search
2000 character limit reached

New lower bounds on kissing numbers and spherical codes in high dimensions

Published 1 Nov 2021 in math.CO | (2111.01255v3)

Abstract: Let the kissing number $K(d)$ be the maximum number of non-overlapping unit balls in $\mathbb Rd$ that can touch a given unit ball. Determining or estimating the number $K(d)$ has a long history, with the value of $K(3)$ being the subject of a famous discussion between Gregory and Newton in 1694. We prove that, as the dimension $d$ goes to infinity, $$ K(d)\ge (1+o(1)){\frac{\sqrt{3\pi}}{4\sqrt2}}\,\log\frac{3}{2}\cdot d{3/2}\cdot \Big(\frac{2}{\sqrt{3}}\Big){d}, $$ thus improving the previously best known bound of Jenssen, Joos and Perkins by a factor of $\log(3/2)/\log(9/8)+o(1)=3.442...$. Our proof is based on the novel approach from Jenssen, Joos and Perkins that uses the hard core sphere model of an appropriate fugacity. Similar constant-factor improvements in lower bounds are also obtained for general spherical codes, as well as for the expected density of random sphere packings in the Euclidean space $\mathbb Rd$.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (35)
  1. K.M. Anstreicher, The Thirteen Spheres: A New Proof, Discrete and Computational Geometry, 31(4), (2004), 613–625.
  2. A. Baernstein II and B.A. Taylor, Spherical rearrangements, subharmonic functions, and *{}^{*}start_FLOATSUPERSCRIPT * end_FLOATSUPERSCRIPT-functions in n𝑛nitalic_n-space, Duke Mathematical Journal, 43, (1976), 245–268.
  3. K. Ball, A lower bound for the optimal density of lattice packings, International Mathematics Research Notices, 10, (1992), 217–221.
  4. K. Böröczky, The Newton-Gregory problem revisited, Discrete geometry, Marcel Dekker, New York, (2003), 103–110.
  5. P. Boyvalenkov, S. Dodunekov and O.R. Musin, A survey on the kissing numbers, arXiv: 1507.03631, (2015).
  6. C. Chabauty, Résultats sur l’empilement de calottes égales sur une périsphère de Rnet correction à un travail antérieur, Comptes Rendus de l’Académie des Sciences Paris, 236, (1953), 1462–1464.
  7. New upper bounds on sphere packings. I, Annals of Mathematics (2), 157, (2003), 689–714.
  8. The sphere packing problem in dimension 24, Annals of Mathematics (2), 185, (2017), 1017–1033.
  9. Sphere packing bounds via spherical codes, Duke Mathematical Journal, 163, (2014), 1965–2002.
  10. Hlawka’s theorem in the geometry of numbers, Duke Mathematical Journal, 14, (1947), 367–375.
  11. Independent sets, matchings and occupancy fractions, Journal of the London Mathematical Society, 96(1), (2017), 47–66.
  12. On the average size of independent sets in triangle-freegraphs, Proceedings of the American Mathematical Society, 146(1), (2018), 111–124.
  13. P. Delsarte, On the average size of independent sets in triangle-freegraphs, Philips Research Report, 27, (1972), 272–289.
  14. T.C. Hales, A proof of the Kepler conjecture, Annals of Mathematics, 165, (2005), 1065–1185.
  15. M. Jenssen, F. Joos and W. Perkins, On kissing numbers and spherical codes in high dimensions, Advances in Mathematics, 335, (2018), 307–321.
  16. M. Jenssen, F. Joos and W. Perkins, On the hard sphere model and sphere packings in high dimensions, Forum of Mathematics, Sigma, 7, (2019), e1.
  17. Bounds for packings on the sphere and in space, Problemy Peredachi Informatsii, 14, (1978), 3–25.
  18. V.I. Levenšteĭn, On bounds for packing in n𝑛nitalic_n-dimensional Euclidean space, Soviet Mathematics Doklady, 245(6), (1979), 1299–1303.
  19. Analysis, Second Edition, Graduate Studies in Mathematics, American Mathematical Society, Providence, RI, 2001.
  20. H. Maehara, Isoperimetric theorem for spherical polygons and the problem of 13 spheres, Ryukyu Mathematical Journal, 14, (2001), 41–57.
  21. O.R. Musin, The kissing number in four dimensions, Annals of Mathematics, 168, (2008), 1–32.
  22. New bounds on the number of unit spheres that can touch a unit sphere in n dimensions, Journal of Combinatorial Theory, Series A, 26, (1979), 210–214.
  23. Counting independent sets in cubic graphs of given girth, Journal of Combinatorial Theory, Series B, 133, (2018), 211–242.
  24. Kissing numbers, sphere packings, and some unexpected proofs, Notices of the American Mathematical Society, 51(8), (2004), 873–883.
  25. R.A. Rankin, The closest packing of spherical caps in n𝑛nitalic_n dimensions, Proceedings of the Glasgow Mathematical Association, 2(3), (1955), 139–144.
  26. C.A. Rogers, Existence theorems in the geometry of numbers, Annals of Mathematics, 48, (1947), 994–1002.
  27. C.E. Shannon, Probability of error for optimal codes in a Gaussian channel, The Bell System Technical Journal, 38(3), (1959), 611–659.
  28. Real analysis: Measure theory, integration, and Hilbert spaces, Princeton lectures in Analysis, Princeton University Press, 2005.
  29. A. Thue, Om nogle geometrisk taltheoretiske theoremer, Forandlingerneved de Skandinaviske Naturforskeres, 14, (1892), 352–353.
  30. S. Vance, Improved sphere packing lower bounds from Hurwitz lattices, Advances in Mathematics, 227, (2011), 2144–2156.
  31. A. Venkatesh, A note on sphere packings in high dimensions, International Mathematics Research Notices, 7, (2013), 1628–1642.
  32. M.S. Viazovska, The sphere packing problem in dimension 8, Annals of Mathematics (2), 185, (2017), 991–1015.
  33. S. Vlădu\textcommabelowt, Lattices with exponentially large kissing numbers, Moscow Journal of Combinatorics and Number Theory, 8(2), (2019), 163–176.
  34. B.L. van der Waerden and K. Schütte, Das Problem der 13 Kugeln, Mathematische Annalen, 125, (1953), 325–334.
  35. A.D. Wyner, Capabilities of bounded discrepancy decoding, The Bell System Technical Journal, 44(6), (1965), 1061–1122.
Citations (6)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Summarize

Paper to Video (Beta)

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up