Centered octahedral number

Template:Short description Template:Use American English Template:Use mdy dates Template:Infobox integer sequence In mathematics, a centered octahedral number or Haüy octahedral number is a figurate number that counts the points of a three-dimensional integer lattice that lie inside an octahedron centered at the origin.^[1] The same numbers are special cases of the Delannoy numbers, which count certain two-dimensional lattice paths.^[2] The Haüy octahedral numbers are named after René Just Haüy.

The name "Haüy octahedral number" comes from the work of René Just Haüy, a French mineralogist active in the late 18th and early 19th centuries. His "Haüy construction" approximates an octahedron as a polycube, formed by accreting concentric layers of cubes onto a central cube. The centered octahedral numbers count the cubes used by this construction.^[3] Haüy proposed this construction, and several related constructions of other polyhedra, as a model for the structure of crystalline minerals.^[4][5]

The number of three-dimensional lattice points within n steps of the origin is given by the formula

${\displaystyle \frac{(2n+1)(2n^2+2n+3)}{3}}$

The first few of these numbers (for n = 0, 1, 2, ...) are

1, 7, 25, 63, 129, 231, 377, 575, 833, 1159, ...^[6]

The generating function of the centered octahedral numbers is^[6][7]

${\displaystyle \frac{(1+x{)}^3}{(1-x{)}^4}.}$

The centered octahedral numbers obey the recurrence relation^[1]

${\displaystyle C(n)=C(n-1)+4n^2+2.}$

They may also be computed as the sums of pairs of consecutive octahedral numbers.

The octahedron in the three-dimensional integer lattice, whose number of lattice points is counted by the centered octahedral number, is a metric ball for three-dimensional taxicab geometry, a geometry in which distance is measured by the sum of the coordinatewise distances rather than by Euclidean distance. For this reason, Template:Harvtxt call the centered octahedral numbers "the volume of the crystal ball".^[7]

The same numbers can be viewed as figurate numbers in a different way, as the centered figurate numbers generated by a pentagonal pyramid. That is, if one forms a sequence of concentric shells in three dimensions, where the first shell consists of a single point, the second shell consists of the six vertices of a pentagonal pyramid, and each successive shell forms a larger pentagonal pyramid with a triangular number of points on each triangular face and a pentagonal number of points on the pentagonal face, then the total number of points in this configuration is a centered octahedral number.^[1]

The centered octahedral numbers are also the Delannoy numbers of the form D(3,n). As for Delannoy numbers more generally, these numbers count the paths from the southwest corner of a 3 × n grid to the northeast corner, using steps that go one unit east, north, or northeast.^[2]

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