LCM = 2 x 2 x 2 x 3 x 3, GCF = 2 x 3, 24 = 2 x 2 x 2 x 3 Other number = 2 x 3 x 3 = 18
You need at least two numbers to find a GCF or an LCM and the LCM of those numbers can never be less than the GCF. 12 and 360 have a GCF of 12 and an LCM of 360. So do 60 and 72.
The pair of numbers 16 and 160 has a GCF of 16 and an LCM of 160.
Factors go into numbers, numbers go into multiples. Multiples are bigger than factors.
The GCF of two numbers multiplied by their LCM will equal the product of the original numbers. If you know the GCF, divide it into the product of the two. The result will be the LCM. If the GCF of two numbers is 1, the LCM is their product.
The product of the GCF and LCM of a pair of numbers is equal to the product of the numbers.
The GCF is the factor, the LCM is the other one.
The product of the original numbers is equal to the product of the GCF and LCM. Divide the product of the LCM and GCF by the one number. The answer will be the other.
The LCM of a set of numbers will never be less than the GCF.
The LCM of a set of numbers will never be less than the GCF.
The other number is: 12
In any number pair where one of the numbers is a multiple of the other, that number is the LCM.
Only if they're the same number. The LCM and GCF of 10 and 10 is 10.
The product of the GCF and LCM of two numbers is equal to the product of the two numbers. The other number is 126.
That is correct. The other number is the LCM.
In number theory, the product of two positive integers will equal the product of their GCF and LCM. Dividing that product by one of them will give you the other.
You need at least two numbers to find a GCF or an LCM and the LCM of those numbers can never be less than the GCF. 12 and 360 have a GCF of 12 and an LCM of 360. So do 60 and 72.
The pair of numbers 16 and 160 has a GCF of 16 and an LCM of 160.