• A factor is a number that divides another number completely, with no remainder.

What is a Factor?

• A factor is a number that divides another number completely, with no remainder.

What is a Factor?

• We say 2 is a factor of 8 because \(\frac{8}{2}=4\) with a remainder of 0.

• A factor is a number that divides another number completely, with no remainder.

What is a Factor?

• We say 2 is a factor of 8 because \(\frac{8}{2}=4\) with a remainder of 0.

• 2 is also a factor of 12 because \(\frac{12}{2}=6\) with no remainder.

• A factor is a number that divides another number completely, with no remainder.

What is a Factor?

• We say 2 is a factor of 8 because \(\frac{8}{2}=4\) with a remainder of 0.

• 2 is also a factor of 12 because \(\frac{12}{2}=6\) with no remainder.

• However, 2 is not a factor of 7 because when we divided 7 by 2, we get a quotient of 3 and a remainder of 1.

Two Sides of the Same Coin

• Multiplication

\((5) \cdot (7) = 35\)

• Factorization

\(35=(5) \cdot (7)\)

Two Sides of the Same Coin

• Multiplication

• We can say that 35 is a multiple of 5.

\((5) \cdot (7) = 35\)

• Factorization

• We can say that 5 is a factor of 35 because \(\frac{35}{5}=7\).

\(35=(5) \cdot (7)\)

Two Sides of the Same Coin

• Multiplication

• We can say that 35 is a multiple of 5.

• Also, we can say that 35 is a multiple of 7.

\((5) \cdot (7) = 35\)

• Factorization

• We can say that 5 is a factor of 35 because \(\frac{35}{5}=7\).

• Also, we can say that 7 is a factor of 35 because \(\frac{35}{7}=5\).

\(35=(5) \cdot (7)\)

Two Sides of a Similar Coin

\((x+1) \cdot (x+2) = x^2+3x+2\)

Two Sides of a Similar Coin

Multiplication

• We say that \((x^2+3x+2)\) is a multiple of \((x+1)\) and \((x+2)\).

\((x+1) \cdot (x+2) = x^2+3x+2\)

Two Sides of a Similar Coin

Multiplication

• We say that \((x^2+3x+2)\) is a multiple of \((x+1)\) and \((x+2)\).

• We say that \((x+1)\) and \((x+2)\) are factors of
  \((x^2+3x+2)\).

\((x+1) \cdot (x+2) = x^2+3x+2\)

Factorization