The number of cells in a generalized Chinese checkers board (or "centered" hexagram). Unlike the
polygonal numbers, there is ambiguity in the
case of the star numbers as to whether 
or 
should be set equal to 1, since the equation defining star numbers never gives 0.
For consistency with other figurate numbers, which are all defined such that 
, that definition is used here as
well, and 
is defined by
 |
(1)
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The first few for 
,
2, ... are 1, 13, 37, 73, 121, ... (OEIS A003154),
and the generating function for the star numbers
is
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(2)
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The star numbers satisfy the linear recurrence equation
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(3)
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Every star number has digital root 1 or 4, and the final digit must be one of 1, 3, or 7, and the final two digits must be one of 01, 13, 21, 33, 37, 41, 53, 61, 73, 81, or 93.
The first few triangular star numbers are 1, 253, 49141, 9533161, ... (OEIS A006060), and can be computed using
 |  | ![(3[(7+4sqrt(3))^(2n-1)+(7-4sqrt(3))^(2n-1)]-10)/(32)](/images/equations/StarNumber/Inline8.svg) |
(4)
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 |  |  |
(5)
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The indices of the corresponding triangular numbers are 1, 22, 313, 4366, 60817, ... (OEIS A068774), and of the star numbers are 1, 7, 91, 1261, 17557, ... (OEIS A068775).
The first few square star numbers are 1, 121, 11881, 1164241, 114083761, ... (OEIS A006061). The indices of the corresponding square numbers are 1, 11, 109, 1079, 10681, 105731, 1046629, ... (OEIS A054320), and of the star numbers are 1, 5, 45, 441, 4361, 43165, 427285, ... (OEIS A068778). Square star numbers are obtained by solving the Diophantine equation
 |
(6)
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and can be computed using
![SS_n=([(5+2sqrt(6))^n(sqrt(6)-2)-(5-2sqrt(6))^n(sqrt(6)+2)]^2)/4.](/images/equations/StarNumber/NumberedEquation5.svg) |
(7)
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