List of shapes with known packing constant

The packing constant of a geometric body is the largest average density achieved by packing arrangements of congruent copies of the body. For most bodies the value of the packing constant is unknown.^[1] The following is a list of bodies in Euclidean spaces whose packing constant is known.^[1] Fejes Tóth proved that in the plane, a point symmetric body has a packing constant that is equal to its translative packing constant and its lattice packing constant.^[2] Therefore, any such body for which the lattice packing constant was previously known, such as any ellipse, consequently has a known packing constant. In addition to these bodies, the packing constants of hyperspheres in 8 and 24 dimensions are almost exactly known.^[3]

Image	Description	Dimension	Packing constant	Comments
	Monohedral prototiles	all	1	Shapes such that congruent copies can form a tiling of space
	Circle, Ellipse	2	π/√12 ≈ 0.906900	Proof attributed to Thue[4]
	Regular pentagon	2	${\displaystyle {\frac {5-{\sqrt {5}}}{3}}\approx 0.92131}$	Thomas Hales and Wöden Kusner[5]
	Smoothed octagon	2	${\displaystyle \eta _{so}={\frac {8-4{\sqrt {2}}-\ln {2}}{2{\sqrt {2}}-1}}\approx 0.902414}$	Reinhardt[6]
	All 2-fold symmetric convex polygons	2		Linear-time (in number of vertices) algorithm given by Mount and Ruth Silverman[7]
	Sphere	3	π/√18 ≈ 0.7404805	See Kepler conjecture
	Bi-infinite cylinder	3	π/√12 ≈ 0.906900	Bezdek and Kuperberg[8]
	Half-infinite cylinder	3	π/√12 ≈ 0.906900	Wöden Kusner[9]
	All shapes contained in a rhombic dodecahedron whose inscribed sphere is contained in the shape	3	Fraction of the volume of the rhombic dodecahedron filled by the shape	Corollary of Kepler conjecture. Examples pictured: rhombicuboctahedron and rhombic enneacontahedron.
	Hypersphere	8	${\displaystyle {\frac {({\frac {\pi }{2}})^{4}}{4!}}\approx 0.2536695}$	See Hypersphere packing[10][11]
	Hypersphere	24	${\displaystyle {\frac {({\frac {\pi }{2}})^{12}}{12!}}\approx 0.000000471087}$	See Hypersphere packing

References

1. Bezdek, András; Kuperberg, Włodzimierz (2010). "Dense packing of space with various convex solids". arXiv:1008.2398v1 [math.MG].
2. Fejes Tóth, László (1950). "Some packing and covering theorems". Acta Sci. Math. Szeged. 12.
3. Cohn, Henry; Kumar, Abhinav (2009). "Optimality and uniqueness of the Leech lattice among lattices". Annals of Mathematics. 170 (3): 1003–1050. arXiv:math/0403263. doi:10.4007/annals.2009.170.1003. S2CID 10696627.
4. Chang, Hai-Chau; Wang, Lih-Chung (2010). "A Simple Proof of Thue's Theorem on Circle Packing". arXiv:1009.4322v1 [math.MG].
5. Hales, Thomas; Kusner, Wöden (2016). "Packings of regular pentagons in the plane". arXiv:1602.07220 [math.MG].
6. Reinhardt, Karl (1934). "Über die dichteste gitterförmige Lagerung kongruente Bereiche in der Ebene und eine besondere Art konvexer Kurven". Abh. Math. Sem. Univ. Hamburg. 10: 216–230. doi:10.1007/bf02940676. S2CID 120336230.
7. Mount, David M.; Silverman, Ruth (1990). "Packing and covering the plane with translates of a convex polygon". Journal of Algorithms. 11 (4): 564–580. doi:10.1016/0196-6774(90)90010-C.
8. Bezdek, András; Kuperberg, Włodzimierz (1990). "Maximum density space packing with congruent circular cylinders of infinite length". Mathematika. 37: 74–80. doi:10.1112/s0025579300012808.
9. Kusner, Wöden (2014). "Upper bounds on packing density for circular cylinders with high aspect ratio". Discrete & Computational Geometry. 51 (4): 964–978. arXiv:1309.6996. doi:10.1007/s00454-014-9593-6. S2CID 38234737.
10. Klarreich, Erica (March 30, 2016), "Sphere Packing Solved in Higher Dimensions", Quanta Magazine
11. Viazovska, Maryna (2016). "The sphere packing problem in dimension 8". Annals of Mathematics. 185 (3): 991–1015. arXiv:1603.04246. doi:10.4007/annals.2017.185.3.7. S2CID 119286185.