Sum of two cubes

In mathematics, the sum of two cubes is a cubed number added to another cubed number.

Factorization

Every sum of cubes may be factored according to the identity $a^{3}+b^{3}=(a+b)(a^{2}-ab+b^{2})$ in elementary algebra.

Binomial numbers generalize this factorization to higher odd powers.

Proof

Starting with the expression, $a^{2}-ab+b^{2}$ and multiplying by $a + b$ $(a+b)(a^{2}-ab+b^{2})=a(a^{2}-ab+b^{2})+b(a^{2}-ab+b^{2}).$ distributing a and b over $a^{2}-ab+b^{2}$ , $a^{3}-a^{2}b+ab^{2}+a^{2}b-ab^{2}+b^{3}$ and canceling the like terms, $a^{3}+b^{3}.$

Similarly for the difference of cubes, ${\begin{aligned}(a-b)(a^{2}+ab+b^{2})&=a(a^{2}+ab+b^{2})-b(a^{2}+ab+b^{2})\\&=a^{3}+a^{2}b+ab^{2}\;-a^{2}b-ab^{2}-b^{3}\\&=a^{3}-b^{3}.\end{aligned}}$

"SOAP" mnemonic

The mnemonic "SOAP", short for "Same, Opposite, Always Positive", helps recall of the signs:

	original sign		Same		Opposite		Always Positive

$a 3$	$+$	$b 3 = (a$	$+$	$b)(a 2$	$-$	$ab$	$+$	$b 2)$
$a 3$	$-$	$b 3 = (a$	$-$	$b)(a 2$	$+$	$ab$	$+$	$b 2)$

Fermat's last theorem

Fermat's last theorem in the case of exponent 3 states that the sum of two non-zero integer cubes does not result in a non-zero integer cube. The first recorded proof of the exponent 3 case was given by Euler.

Taxicab and Cabtaxi numbers

A Taxicab number is the smallest positive number that can be expressed as a sum of two positive integer cubes in n distinct ways. The smallest taxicab number after Ta(1) = 1, is Ta(2) = 1729 (the Ramanujan number), expressed as

1^{3}+12^{3}

or

9^{3}+10^{3}

Ta(3), the smallest taxicab number expressed in 3 different ways, is 87,539,319, expressed as

436^{3}+167^{3}

,

423^{3}+228^{3}

or

414^{3}+255^{3}

A Cabtaxi number is the smallest positive number that can be expressed as a sum of two integer cubes in n ways, allowing the cubes to be negative or zero as well as positive. The smallest cabtaxi number after Cabtaxi(1) = 0, is Cabtaxi(2) = 91, expressed as: