Polynomial Factoring Exercises

\[ 3x(x + 2) \]

Key Idea

We look for the greatest common factor (GCF) shared by all terms of the polynomial. Here, the GCF is \(3x\).

Identifying the GCF

The coefficients \(3\) and \(6\) have GCD \(3\). The variable \(x\) appears in both terms with exponent at least \(1\). Therefore GCF \(= 3x\).

Factoring Out the GCF

\[ 3x^2 + 6x = 3x \cdot x + 3x \cdot 2 = 3x(x + 2) \]

Check

\[ 3x(x+2) = 3x^2 + 6x \]

Answer

\[ \boxed{3x(x+2)} \]

\[ 4x(x^2 - 2x + 3) \]

Identifying the GCF

The coefficients \(4, 8, 12\) have GCD \(4\). The variable \(x\) appears in all terms with exponent at least \(1\). Therefore GCF \(= 4x\).

Factoring Out the GCF

\[ 4x^3 - 8x^2 + 12x = 4x\cdot x^2 - 4x\cdot 2x + 4x\cdot 3 = 4x(x^2 - 2x + 3) \]

Check

\[ 4x(x^2-2x+3) = 4x^3 - 8x^2 + 12x \]

Answer

\[ \boxed{4x(x^2 - 2x + 3)} \]

\[ 3xy(2x - 3y + 1) \]

Identifying the GCF

The coefficients \(6, 9, 3\) have GCD \(3\). The variable \(x\) appears with exponent at least \(1\), and so does \(y\). Therefore GCF \(= 3xy\).

Factoring Out the GCF

\[ 6x^2y - 9xy^2 + 3xy = 3xy\cdot2x - 3xy\cdot3y + 3xy\cdot1 = 3xy(2x - 3y + 1) \]

Check

\[ 3xy(2x-3y+1) = 6x^2y - 9xy^2 + 3xy \]

Answer

\[ \boxed{3xy(2x - 3y + 1)} \]

\[ (x-4)(x+4) \]

Key Idea

We recognize the difference of two squares: \(a^2 - b^2 = (a-b)(a+b)\) with \(a = x\) and \(b = 4\).

Applying the Formula

\[ x^2 - 16 = x^2 - 4^2 = (x-4)(x+4) \]

Check

\[ (x-4)(x+4) = x^2+4x-4x-16 = x^2-16 \]

Answer

\[ \boxed{(x-4)(x+4)} \]

\[ (3x-5)(3x+5) \]

Key Idea

We recognize the difference of two squares with \(a = 3x\) and \(b = 5\).

Applying the Formula

\[ 9x^2 - 25 = (3x)^2 - 5^2 = (3x-5)(3x+5) \]

Check

\[ (3x-5)(3x+5) = 9x^2+15x-15x-25 = 9x^2-25 \]

Answer

\[ \boxed{(3x-5)(3x+5)} \]

\[ (x+3)^2 \]

Key Idea

We recognize a perfect square trinomial: \(a^2+2ab+b^2 = (a+b)^2\) with \(a=x\) and \(b=3\).

Checking the Structure

First term: \(x^2 = x^2\) \(\checkmark\)

Middle term: \(6x = 2\cdot x\cdot3\) \(\checkmark\)

Last term: \(9 = 3^2\) \(\checkmark\)

Answer

\[ \boxed{(x+3)^2} \]

\[ (x+2)(x+3) \]

Key Idea

A monic trinomial of the form \(x^2+bx+c\) factors as \((x+p)(x+q)\) where \(p+q=b\) and \(p\cdot q=c\).

Finding \(p\) and \(q\)

We need two numbers whose product is \(6\) and whose sum is \(5\):

\[ p\cdot q = 6 \qquad p + q = 5 \implies p = 2,\; q = 3 \]

Factored Form

\[ x^2+5x+6 = (x+2)(x+3) \]

Check

\[ (x+2)(x+3) = x^2+3x+2x+6 = x^2+5x+6 \]

Answer

\[ \boxed{(x+2)(x+3)} \]

\[ (x-3)(x-4) \]

Finding \(p\) and \(q\)

We need two numbers whose product is \(12\) and whose sum is \(-7\):

\[ p\cdot q = 12 \qquad p+q = -7 \implies p=-3,\; q=-4 \]

Factored Form

\[ x^2-7x+12 = (x-3)(x-4) \]

Check

\[ (x-3)(x-4) = x^2-4x-3x+12 = x^2-7x+12 \]

Answer

\[ \boxed{(x-3)(x-4)} \]

\[ (x+3)(x-2) \]

Finding \(p\) and \(q\)

We need two numbers whose product is \(-6\) and whose sum is \(1\):

\[ p\cdot q = -6 \qquad p+q=1 \implies p=3,\; q=-2 \]

Factored Form

\[ x^2+x-6 = (x+3)(x-2) \]

Check

\[ (x+3)(x-2) = x^2-2x+3x-6 = x^2+x-6 \]

Answer

\[ \boxed{(x+3)(x-2)} \]

\[ (2x+1)(x+3) \]

Key Idea

For a trinomial \(ax^2+bx+c\) with \(a\neq1\), we use the ac-method: find two numbers whose product is \(ac = 6\) and whose sum is \(b = 7\).

The \(ac\) Product and Factor Search

\[ a\cdot c = 2\cdot3 = 6 \qquad p+q=7 \implies p=1,\; q=6 \]

Splitting the Middle Term

\[ 2x^2+7x+3 = 2x^2+x+6x+3 \]

Factoring by Grouping

\[ = x(2x+1)+3(2x+1) = (2x+1)(x+3) \]

Check

\[ (2x+1)(x+3) = 2x^2+6x+x+3 = 2x^2+7x+3 \]

Answer

\[ \boxed{(2x+1)(x+3)} \]

\[ (3x-1)(x-3) \]

The \(ac\) Product and Factor Search

\[ a\cdot c = 3\cdot3 = 9 \qquad p+q=-10 \implies p=-1,\; q=-9 \]

Splitting the Middle Term

\[ 3x^2-10x+3 = 3x^2-x-9x+3 \]

Factoring by Grouping

\[ = x(3x-1)-3(3x-1) = (3x-1)(x-3) \]

Check

\[ (3x-1)(x-3) = 3x^2-9x-x+3 = 3x^2-10x+3 \]

Answer

\[ \boxed{(3x-1)(x-3)} \]

\[ (3x+2)(2x-1) \]

The \(ac\) Product and Factor Search

\[ a\cdot c = 6\cdot(-2) = -12 \qquad p+q=1 \implies p=4,\; q=-3 \]

Splitting the Middle Term

\[ 6x^2+x-2 = 6x^2+4x-3x-2 \]

Factoring by Grouping

\[ = 2x(3x+2)-(3x+2) = (3x+2)(2x-1) \]

Check

\[ (3x+2)(2x-1) = 6x^2-3x+4x-2 = 6x^2+x-2 \]

Answer

\[ \boxed{(3x+2)(2x-1)} \]

\[ x(x-1)(x+1) \]

Step 1: Factor Out \(x\)

\[ x^3 - x = x(x^2 - 1) \]

Step 2: Difference of Two Squares

\[ x^2 - 1 = (x-1)(x+1) \]

Complete Factorization

\[ x^3-x = x(x-1)(x+1) \]

Check

\[ x(x-1)(x+1) = x(x^2-1) = x^3-x \]

Answer

\[ \boxed{x(x-1)(x+1)} \]

\[ (x+2)(x^2 - 2x + 4) \]

Key Idea

We recognize the sum of two cubes: \(a^3+b^3=(a+b)(a^2-ab+b^2)\) with \(a=x\) and \(b=2\).

Applying the Formula

\[ x^3+8 = x^3+2^3 = (x+2)(x^2-2x+4) \]

Check

\[ (x+2)(x^2-2x+4) = x^3-2x^2+4x+2x^2-4x+8 = x^3+8 \]

Answer

\[ \boxed{(x+2)(x^2-2x+4)} \]

\[ (x-3)(x^2+3x+9) \]

Key Idea

We recognize the difference of two cubes: \(a^3-b^3=(a-b)(a^2+ab+b^2)\) with \(a=x\) and \(b=3\).

Applying the Formula

\[ x^3-27 = x^3-3^3 = (x-3)(x^2+3x+9) \]

Check

\[ (x-3)(x^2+3x+9) = x^3+3x^2+9x-3x^2-9x-27 = x^3-27 \]

Answer

\[ \boxed{(x-3)(x^2+3x+9)} \]

\[ (x-1)^2(x+1) \]

Key Idea

We apply factoring by grouping, pairing the terms two by two.

Grouping the Terms

\[ (x^3-x^2)+(-x+1) = x^2(x-1)-(x-1) \]

Factoring Out \((x-1)\)

\[ (x-1)(x^2-1) \]

Further Factoring: Difference of Two Squares

\[ (x-1)(x-1)(x+1) = (x-1)^2(x+1) \]

Check

\[ (x-1)^2(x+1) = (x^2-2x+1)(x+1) = x^3+x^2-2x^2-2x+x+1 = x^3-x^2-x+1 \]

Answer

\[ \boxed{(x-1)^2(x+1)} \]

\[ (2x+1)(x-1)(x+1) \]

Factoring by Grouping

\[ (2x^3+x^2)+(-2x-1) = x^2(2x+1)-(2x+1) \]

Factoring Out \((2x+1)\)

\[ (2x+1)(x^2-1) \]

Difference of Two Squares

\[ (2x+1)(x-1)(x+1) \]

Check

\[ (2x+1)(x^2-1) = 2x^3-2x+x^2-1 = 2x^3+x^2-2x-1 \]

Answer

\[ \boxed{(2x+1)(x-1)(x+1)} \]

\[ (x-1)(x+1)(x^2+1) \]

Step 1: Difference of Two Squares

\[ x^4-1 = (x^2)^2-1^2 = (x^2-1)(x^2+1) \]

Step 2: Another Difference of Two Squares

\[ x^2-1 = (x-1)(x+1) \]

The factor \(x^2+1\) is irreducible over \(\mathbb{R}\) (discriminant \(-4 < 0\)).

Complete Factorization

\[ x^4-1 = (x-1)(x+1)(x^2+1) \]

Check

\[ (x^2-1)(x^2+1) = x^4+x^2-x^2-1 = x^4-1 \]

Answer

\[ \boxed{(x-1)(x+1)(x^2+1)} \]

\[ (x-1)(x+1)(x-2)(x+2) \]

Key Idea

This is a biquadratic trinomial. We substitute \(t = x^2\) to reduce it to a standard quadratic in \(t\).

Substitution \(t = x^2\)

\[ t^2-5t+4 = 0 \implies (t-1)(t-4) = 0 \implies t=1 \text{ or } t=4 \]

Back-Substitution

\[ t=1 \implies x^2-1=(x-1)(x+1) \]

\[ t=4 \implies x^2-4=(x-2)(x+2) \]

Complete Factorization

\[ x^4-5x^2+4 = (x^2-1)(x^2-4) = (x-1)(x+1)(x-2)(x+2) \]

Check

\[ (x^2-1)(x^2-4) = x^4-4x^2-x^2+4 = x^4-5x^2+4 \]

Answer

\[ \boxed{(x-1)(x+1)(x-2)(x+2)} \]

\[ (x+3)(x-2)(x+2) \]

Factoring by Grouping

\[ (x^3+3x^2)+(-4x-12) = x^2(x+3)-4(x+3) \]

Factoring Out \((x+3)\)

\[ (x+3)(x^2-4) \]

Difference of Two Squares

\[ x^2-4 = (x-2)(x+2) \]

Complete Factorization

\[ x^3+3x^2-4x-12 = (x+3)(x-2)(x+2) \]

Check

\[ (x+3)(x^2-4) = x^3-4x+3x^2-12 = x^3+3x^2-4x-12 \]

Answer

\[ \boxed{(x+3)(x-2)(x+2)} \]