Centered triangular number

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A centered (or centred) triangular number is a centered figurate number that represents an equilateral triangle with a dot in the center and all its other dots surrounding the center in successive equilateral triangular layers.

This is also the number of points of a hexagonal lattice with nearest-neighbor coupling whose distance from a given point is less than or equal to ${\displaystyle n}$.

The following image shows the building of the centered triangular numbers by using the associated figures: at each step, the previous triangle (shown in red) is surrounded by a triangular layer of new dots (in blue).

• The gnomon of the n-th centered triangular number, corresponding to the (n + 1)-th triangular layer, is:

${\displaystyle C_{3,n+1}-C_{3,n}=3(n+1).}$

• The n-th centered triangular number, corresponding to n layers plus the center, is given by the formula:

${\displaystyle C_{3,n}=1+3{\frac {n(n+1)}{2}}={\frac {3n^{2}+3n+2}{2}}.}$

• Each centered triangular number has a remainder of 1 when divided by 3, and the quotient (if positive) is the previous regular triangular number.

• Each centered triangular number from 10 onwards is the sum of three consecutive regular triangular numbers.

• For n > 2, the sum of the first n centered triangular numbers is the magic constant for an n by n normal magic square.

The centered triangular numbers can be expressed in terms of the centered square numbers:

${\displaystyle C_{3,n}={\frac {3C_{4,n}+1}{4}},}$

where

${\displaystyle C_{4,n}=n^{2}+(n+1)^{2}.}$

The first centered triangular numbers (C_3,n < 3000) are:

1, 4, 10, 19, 31, 46, 64, 85, 109, 136, 166, 199, 235, 274, 316, 361, 409, 460, 514, 571, 631, 694, 760, 829, 901, 976, 1054, 1135, 1219, 1306, 1396, 1489, 1585, 1684, 1786, 1891, 1999, 2110, 2224, 2341, 2461, 2584, 2710, 2839, 2971, … (sequence A005448 in the OEIS).

The first simultaneously triangular and centered triangular numbers (C_3,n = T_N < 10⁹) are:

1, 10, 136, 1 891, 26 335, 366 796, 5 108 806, 71 156 485, 991 081 981, … (sequence A128862 in the OEIS).

If the centered triangular numbers are treated as the coefficients of the McLaurin series of a function, that function converges for all ${\displaystyle |x|<1}$, in which case it can be expressed as the meromorphic generating function

${\displaystyle 1+4x+10x^{2}+19x^{3}+31x^{4}+~...={\frac {1-x^{3}}{(1-x)^{4}}}={\frac {x^{2}+x+1}{(1-x)^{3}}}~.}$

• Lancelot Hogben: Mathematics for the Million (1936), republished by W. W. Norton & Company (September 1993), ISBN 978-0-393-31071-9
• Weisstein, Eric W. "Centered Triangular Number". MathWorld.