Cake number

If n! denotes the factorial, and we denote the binomial coefficients by

${\displaystyle {n \choose k}={\frac {n!}{k!(n-k)!}},}$ 

and we assume that n planes are available to partition the cube, then the n-th cake number is:^[1]

${\displaystyle C_{n}={n \choose 3}+{n \choose 2}+{n \choose 1}+{n \choose 0}={\tfrac {1}{6}}\!\left(n^{3}+5n+6\right)={\tfrac {1}{6}}(n+1)\left(n(n-1)+6\right).}$ 

The cake numbers are the 3-dimensional analogue of the 2-dimensional lazy caterer's sequence. The difference between successive cake numbers also gives the lazy caterer's sequence.^[1]

The fourth column of Bernoulli's triangle (k = 3) gives the cake numbers for n cuts, where n ≥ 3.

The sequence can be alternatively derived from the sum of up to the first 4 terms of each row of Pascal's triangle:^[2]

k n	0	1	2	3		Sum
0	1	—	—	—		1
1	1	1	—	—		2
2	1	2	1	—		4
3	1	3	3	1		8
4	1	4	6	4		15
5	1	5	10	10		26
6	1	6	15	20		42
7	1	7	21	35		64
8	1	8	28	56		93
9	1	9	36	84		130

In n spatial (not spacetime) dimensions, Maxwell's equations represent ${\displaystyle C_{n}}$  different independent real-valued equations.

• Dividing a circle into areas (Moser's circle problem)
• Lazy caterer's sequence
• Pizza theorem

• Eric Weisstein. "Space Division by Planes". MathWorld. Retrieved January 14, 2021.
• Eric Weisstein. "Cake Number". MathWorld. Retrieved January 14, 2021.