Centered hexagonal number

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A centered hexagonal number, or hex number,^[1] is a centered figurate number that represents a hexagon with a dot in the center and all other dots surrounding the center dot in a hexagonal lattice. Centered hexagonal numbers have practical applications in materials logistics management.

Description

A centered hexagonal number is a centered figurate number that represents a hexagon with a dot in the center and all other dots surrounding the center dot in a hexagonal lattice.

1		7		19		37
+1		+6		+12		+18

The $n$ th centered hexagonal number is given by the formula

n^{3}-(n-1)^{3}=3n(n-1)+1.\,

Expressing the formula as

1+6\left({\frac {n(n-1)}{2}}\right)

shows that the centered hexagonal number for $n$ is 1 more than 6 times the $(n - 1)$ th triangular number.

The first few centered hexagonal numbers are (sequence A003215 in the OEIS):

1, 7, 19, 37, 61, 91, 127, 169, 217, 271, 331, 397, 469, 547, 631, 721, 817, 919.

Properties

In base 10 one can notice that the hexagonal numbers' rightmost (least significant) digits follow the pattern 1–7–9–7–1.

The sum of the first $n$ centered hexagonal numbers is $n 3$ . That is, centered hexagonal pyramidal numbers and cubes are the same numbers, but they represent different shapes. Viewed from the opposite perspective, centered hexagonal numbers are differences of two consecutive cubes, so that the centered hexagonal numbers are the gnomon of the cubes. (This can be seen geometrically from the diagram.) In particular, prime centered hexagonal numbers are cuban primes.

The difference between $(2 n) 2$ and the $n$ th centered hexagonal number is a number of the form $3 n 2 + 3 n - 1$ , while the difference between $(2 n - 1) 2$ and the $n$ th centered hexagonal number is a pronic number.

Applications

Centered hexagonal numbers have practical applications in materials logistics management, for example, in packing round items into larger round containers, such as Vienna sausages into round cans, or combining individual wire strands into a cable.

Finding the root

The root $n$ of a centered hexagonal number $x$ can be calculated using the following formula:

n={\frac {3+{\sqrt {12x-3}}}{6}}

References

^ Hindin, H. J. (1983). "Stars, hexes, triangular numbers and Pythagorean triples". J. Rec. Math. 16: 191–193.

centered	Centered triangular numbers Centered square numbers Centered pentagonal numbers Centered hexagonal numbers Centered heptagonal numbers Centered octagonal numbers Centered nonagonal numbers Centered decagonal numbers Star numbers
non-centered	Triangular numbers Square numbers Pentagonal numbers Hexagonal numbers Heptagonal numbers Octagonal numbers Nonagonal numbers Decagonal numbers Dodecagonal numbers

3-dimensional

centered	Centered tetrahedral numbers Centered cube numbers Centered octahedral numbers Centered dodecahedral numbers Centered icosahedral numbers
non-centered	Cube numbers Octahedral numbers Dodecahedral numbers Icosahedral numbers Stella octangula numbers
pyramidal	Tetrahedral numbers Square pyramidal numbers

4-dimensional

non-centered	Pentatope numbers Squared triangular numbers Tesseractic numbers

Higher dimensional

non-centered	5-hypercube numbers 6-hypercube numbers 7-hypercube numbers 8-hypercube numbers

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3-dimensional

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4-dimensional

non-centered	Pentatope Squared triangular Tesseractic

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Description

Properties

Applications

Finding the root

References

See also