How to factor a variable - PSAT Math
Card 0 of 49
Factor 9_x_2 + 12_x_ + 4.
Factor 9_x_2 + 12_x_ + 4.
Nothing common cancels at the beginning. To factor this, we need to find two numbers that multiply to 9 * 4 = 36 and sum to 12. 6 and 6 work.
So 9_x_2 + 12_x_ + 4 = 9_x_2 + 6_x_ + 6_x_ + 4
Let's look at the first two terms and last two terms separately to begin with. 9_x_2 + 6_x_ can be simplified to 3_x_(3_x_ + 2) and 6_x_ + 4 can be simplified into 2(3_x_ + 2). Putting these together gets us
9_x_2 + 12_x_ + 4
= 9_x_2 + 6_x_ + 6_x_ + 4
= 3_x_(3_x_ + 2) + 2(3_x_ + 2)
= (3_x_ + 2)(3_x_ + 2)
This is as far as we can factor.
Nothing common cancels at the beginning. To factor this, we need to find two numbers that multiply to 9 * 4 = 36 and sum to 12. 6 and 6 work.
So 9_x_2 + 12_x_ + 4 = 9_x_2 + 6_x_ + 6_x_ + 4
Let's look at the first two terms and last two terms separately to begin with. 9_x_2 + 6_x_ can be simplified to 3_x_(3_x_ + 2) and 6_x_ + 4 can be simplified into 2(3_x_ + 2). Putting these together gets us
9_x_2 + 12_x_ + 4
= 9_x_2 + 6_x_ + 6_x_ + 4
= 3_x_(3_x_ + 2) + 2(3_x_ + 2)
= (3_x_ + 2)(3_x_ + 2)
This is as far as we can factor.
Compare your answer with the correct one above
Factor the following variable
(x2 + 18x + 72)
Factor the following variable
(x2 + 18x + 72)
You need to find two numbers that multiply to give 72 and add up to give 18
easiest way: write the multiples of 72:
1, 72
2, 36
3, 24
4, 18
6, 12: these add up to 18
(x + 6)(x + 12)
You need to find two numbers that multiply to give 72 and add up to give 18
easiest way: write the multiples of 72:
1, 72
2, 36
3, 24
4, 18
6, 12: these add up to 18
(x + 6)(x + 12)
Compare your answer with the correct one above
When 
is factored, it can be written in the form 
, where 
, 
, 
, 
, 
, and 
are all integer constants, and 
.
What is the value of 
?
When
What is the value of
Let's try to factor x2 – y2 – z2 + 2yz.
Notice that the last three terms are very close to y2 + z2 – 2yz, which, if we rearranged them, would become y2 – 2yz+ z2. We could factor y2 – 2yz+ z2 as (y – z)2, using the general rule that p2 – 2pq + q2 = (p – q)2 .
So we want to rearrange the last three terms. Let's group them together first.
x2 + (–y2 – z2 + 2yz)
If we were to factor out a –1 from the last three terms, we would have the following:
x2 – (y2 + z2 – 2yz)
Now we can replace y2 + z2 – 2yz with (y – z)2.
x2 – (y – z)2
This expression is actually a differences of squares. In general, we can factor p2 – q2 as (p – q)(p + q). In this case, we can substitute x for p and (y – z) for q.
x2 – (y – z)2 = (x – (y – z))(x + (y – z))
Now, let's distribute the negative one in the trinomial x – (y – z)
(x – (y – z))(x + (y – z))
(x – y + z)(x + y – z)
The problem said that factoring x2 – y2 – z2 + 2yz would result in two polynomials in the form (ax + by + cz)(dx + ey + fz), where a, b, c, d, e, and f were all integers, and a > 0.
(x – y + z)(x + y – z) fits this form. This means that a = 1, b = –1, c = 1, d = 1, e = 1, and f = –1. The sum of all of these is 2.
The answer is 2.
Let's try to factor x2 – y2 – z2 + 2yz.
Notice that the last three terms are very close to y2 + z2 – 2yz, which, if we rearranged them, would become y2 – 2yz+ z2. We could factor y2 – 2yz+ z2 as (y – z)2, using the general rule that p2 – 2pq + q2 = (p – q)2 .
So we want to rearrange the last three terms. Let's group them together first.
x2 + (–y2 – z2 + 2yz)
If we were to factor out a –1 from the last three terms, we would have the following:
x2 – (y2 + z2 – 2yz)
Now we can replace y2 + z2 – 2yz with (y – z)2.
x2 – (y – z)2
This expression is actually a differences of squares. In general, we can factor p2 – q2 as (p – q)(p + q). In this case, we can substitute x for p and (y – z) for q.
x2 – (y – z)2 = (x – (y – z))(x + (y – z))
Now, let's distribute the negative one in the trinomial x – (y – z)
(x – (y – z))(x + (y – z))
(x – y + z)(x + y – z)
The problem said that factoring x2 – y2 – z2 + 2yz would result in two polynomials in the form (ax + by + cz)(dx + ey + fz), where a, b, c, d, e, and f were all integers, and a > 0.
(x – y + z)(x + y – z) fits this form. This means that a = 1, b = –1, c = 1, d = 1, e = 1, and f = –1. The sum of all of these is 2.
The answer is 2.
Compare your answer with the correct one above
Factor and simplify:
$$\frac{64y^{2}$$ - 16}{8y + 4}
Factor and simplify:
$$\frac{64y^{2}$$ - 16}{8y + 4}
$64y^{2}$ - 16 is a difference of squares.
The difference of squares formula is $a^{2}$ - $b^{2}$ = (a - b)(a + b).
Therefore, $$\frac{64y^{2}$$ - 16}{8y + 4} = $\frac{(8y + 4)(8y - 4)}{8y + 4}$ = 8y - 4.
$64y^{2}$ - 16 is a difference of squares.
The difference of squares formula is $a^{2}$ - $b^{2}$ = (a - b)(a + b).
Therefore, $$\frac{64y^{2}$$ - 16}{8y + 4} = $\frac{(8y + 4)(8y - 4)}{8y + 4}$ = 8y - 4.
Compare your answer with the correct one above
If $$\frac{x^{2}$$-9}{x+3}=5 , and xneq -3 , what is the value of x?
If $$\frac{x^{2}$$-9}{x+3}=5 , and xneq -3 , what is the value of x?
The numerator on the left can be factored so the expression becomes $\frac{left ( x+3 right )times left ( x-3 right )}{left ( x+3 right )}$=5, which can be simplified to left ( x-3 right )=5
Then you can solve for x by adding 3 to both sides of the equation, so x=8
The numerator on the left can be factored so the expression becomes $\frac{left ( x+3 right )times left ( x-3 right )}{left ( x+3 right )}$=5, which can be simplified to left ( x-3 right )=5
Then you can solve for x by adding 3 to both sides of the equation, so x=8
Compare your answer with the correct one above
Factor:
$-12x^2$+27
Factor:
$-12x^2$+27
We can first factor out -3:
$-3(4x^{2}$-9)
This factors further because there is a difference of squares:
-3(2x+3)(2x-3)
We can first factor out -3:
$-3(4x^{2}$-9)
This factors further because there is a difference of squares:
-3(2x+3)(2x-3)
Compare your answer with the correct one above
Solve for x:
$x^2$+3x+2=0
Solve for x:
$x^2$+3x+2=0
First, factor.
$x^2$+3x+2=(x+2)(x+1)=0
Set each factor equal to 0
x+2=0; x=-2
x+1=0; x=-1
Therefore,
x=-2 or-1
First, factor.
$x^2$+3x+2=(x+2)(x+1)=0
Set each factor equal to 0
x+2=0; x=-2
x+1=0; x=-1
Therefore,
x=-2 or-1
Compare your answer with the correct one above
Factor the following variable
(x2 + 18x + 72)
Factor the following variable
(x2 + 18x + 72)
You need to find two numbers that multiply to give 72 and add up to give 18
easiest way: write the multiples of 72:
1, 72
2, 36
3, 24
4, 18
6, 12: these add up to 18
(x + 6)(x + 12)
You need to find two numbers that multiply to give 72 and add up to give 18
easiest way: write the multiples of 72:
1, 72
2, 36
3, 24
4, 18
6, 12: these add up to 18
(x + 6)(x + 12)
Compare your answer with the correct one above
When is factored, it can be written in the form , where , , , , , and are all integer constants, and .
What is the value of ?
When
What is the value of
Let's try to factor x2 – y2 – z2 + 2yz.
Notice that the last three terms are very close to y2 + z2 – 2yz, which, if we rearranged them, would become y2 – 2yz+ z2. We could factor y2 – 2yz+ z2 as (y – z)2, using the general rule that p2 – 2pq + q2 = (p – q)2 .
So we want to rearrange the last three terms. Let's group them together first.
x2 + (–y2 – z2 + 2yz)
If we were to factor out a –1 from the last three terms, we would have the following:
x2 – (y2 + z2 – 2yz)
Now we can replace y2 + z2 – 2yz with (y – z)2.
x2 – (y – z)2
This expression is actually a differences of squares. In general, we can factor p2 – q2 as (p – q)(p + q). In this case, we can substitute x for p and (y – z) for q.
x2 – (y – z)2 = (x – (y – z))(x + (y – z))
Now, let's distribute the negative one in the trinomial x – (y – z)
(x – (y – z))(x + (y – z))
(x – y + z)(x + y – z)
The problem said that factoring x2 – y2 – z2 + 2yz would result in two polynomials in the form (ax + by + cz)(dx + ey + fz), where a, b, c, d, e, and f were all integers, and a > 0.
(x – y + z)(x + y – z) fits this form. This means that a = 1, b = –1, c = 1, d = 1, e = 1, and f = –1. The sum of all of these is 2.
The answer is 2.
Let's try to factor x2 – y2 – z2 + 2yz.
Notice that the last three terms are very close to y2 + z2 – 2yz, which, if we rearranged them, would become y2 – 2yz+ z2. We could factor y2 – 2yz+ z2 as (y – z)2, using the general rule that p2 – 2pq + q2 = (p – q)2 .
So we want to rearrange the last three terms. Let's group them together first.
x2 + (–y2 – z2 + 2yz)
If we were to factor out a –1 from the last three terms, we would have the following:
x2 – (y2 + z2 – 2yz)
Now we can replace y2 + z2 – 2yz with (y – z)2.
x2 – (y – z)2
This expression is actually a differences of squares. In general, we can factor p2 – q2 as (p – q)(p + q). In this case, we can substitute x for p and (y – z) for q.
x2 – (y – z)2 = (x – (y – z))(x + (y – z))
Now, let's distribute the negative one in the trinomial x – (y – z)
(x – (y – z))(x + (y – z))
(x – y + z)(x + y – z)
The problem said that factoring x2 – y2 – z2 + 2yz would result in two polynomials in the form (ax + by + cz)(dx + ey + fz), where a, b, c, d, e, and f were all integers, and a > 0.
(x – y + z)(x + y – z) fits this form. This means that a = 1, b = –1, c = 1, d = 1, e = 1, and f = –1. The sum of all of these is 2.
The answer is 2.
Compare your answer with the correct one above
Factor 9_x_2 + 12_x_ + 4.
Factor 9_x_2 + 12_x_ + 4.
Nothing common cancels at the beginning. To factor this, we need to find two numbers that multiply to 9 * 4 = 36 and sum to 12. 6 and 6 work.
So 9_x_2 + 12_x_ + 4 = 9_x_2 + 6_x_ + 6_x_ + 4
Let's look at the first two terms and last two terms separately to begin with. 9_x_2 + 6_x_ can be simplified to 3_x_(3_x_ + 2) and 6_x_ + 4 can be simplified into 2(3_x_ + 2). Putting these together gets us
9_x_2 + 12_x_ + 4
= 9_x_2 + 6_x_ + 6_x_ + 4
= 3_x_(3_x_ + 2) + 2(3_x_ + 2)
= (3_x_ + 2)(3_x_ + 2)
This is as far as we can factor.
Nothing common cancels at the beginning. To factor this, we need to find two numbers that multiply to 9 * 4 = 36 and sum to 12. 6 and 6 work.
So 9_x_2 + 12_x_ + 4 = 9_x_2 + 6_x_ + 6_x_ + 4
Let's look at the first two terms and last two terms separately to begin with. 9_x_2 + 6_x_ can be simplified to 3_x_(3_x_ + 2) and 6_x_ + 4 can be simplified into 2(3_x_ + 2). Putting these together gets us
9_x_2 + 12_x_ + 4
= 9_x_2 + 6_x_ + 6_x_ + 4
= 3_x_(3_x_ + 2) + 2(3_x_ + 2)
= (3_x_ + 2)(3_x_ + 2)
This is as far as we can factor.
Compare your answer with the correct one above
Factor and simplify:
$$\frac{64y^{2}$$ - 16}{8y + 4}
Factor and simplify:
$$\frac{64y^{2}$$ - 16}{8y + 4}
$64y^{2}$ - 16 is a difference of squares.
The difference of squares formula is $a^{2}$ - $b^{2}$ = (a - b)(a + b).
Therefore, $$\frac{64y^{2}$$ - 16}{8y + 4} = $\frac{(8y + 4)(8y - 4)}{8y + 4}$ = 8y - 4.
$64y^{2}$ - 16 is a difference of squares.
The difference of squares formula is $a^{2}$ - $b^{2}$ = (a - b)(a + b).
Therefore, $$\frac{64y^{2}$$ - 16}{8y + 4} = $\frac{(8y + 4)(8y - 4)}{8y + 4}$ = 8y - 4.
Compare your answer with the correct one above
If $$\frac{x^{2}$$-9}{x+3}=5 , and xneq -3 , what is the value of x?
If $$\frac{x^{2}$$-9}{x+3}=5 , and xneq -3 , what is the value of x?
The numerator on the left can be factored so the expression becomes $\frac{left ( x+3 right )times left ( x-3 right )}{left ( x+3 right )}$=5, which can be simplified to left ( x-3 right )=5
Then you can solve for x by adding 3 to both sides of the equation, so x=8
The numerator on the left can be factored so the expression becomes $\frac{left ( x+3 right )times left ( x-3 right )}{left ( x+3 right )}$=5, which can be simplified to left ( x-3 right )=5
Then you can solve for x by adding 3 to both sides of the equation, so x=8
Compare your answer with the correct one above
Factor:
$-12x^2$+27
Factor:
$-12x^2$+27
We can first factor out -3:
$-3(4x^{2}$-9)
This factors further because there is a difference of squares:
-3(2x+3)(2x-3)
We can first factor out -3:
$-3(4x^{2}$-9)
This factors further because there is a difference of squares:
-3(2x+3)(2x-3)
Compare your answer with the correct one above
Solve for x:
$x^2$+3x+2=0
Solve for x:
$x^2$+3x+2=0
First, factor.
$x^2$+3x+2=(x+2)(x+1)=0
Set each factor equal to 0
x+2=0; x=-2
x+1=0; x=-1
Therefore,
x=-2 or-1
First, factor.
$x^2$+3x+2=(x+2)(x+1)=0
Set each factor equal to 0
x+2=0; x=-2
x+1=0; x=-1
Therefore,
x=-2 or-1
Compare your answer with the correct one above
Factor 9_x_2 + 12_x_ + 4.
Factor 9_x_2 + 12_x_ + 4.
Nothing common cancels at the beginning. To factor this, we need to find two numbers that multiply to 9 * 4 = 36 and sum to 12. 6 and 6 work.
So 9_x_2 + 12_x_ + 4 = 9_x_2 + 6_x_ + 6_x_ + 4
Let's look at the first two terms and last two terms separately to begin with. 9_x_2 + 6_x_ can be simplified to 3_x_(3_x_ + 2) and 6_x_ + 4 can be simplified into 2(3_x_ + 2). Putting these together gets us
9_x_2 + 12_x_ + 4
= 9_x_2 + 6_x_ + 6_x_ + 4
= 3_x_(3_x_ + 2) + 2(3_x_ + 2)
= (3_x_ + 2)(3_x_ + 2)
This is as far as we can factor.
Nothing common cancels at the beginning. To factor this, we need to find two numbers that multiply to 9 * 4 = 36 and sum to 12. 6 and 6 work.
So 9_x_2 + 12_x_ + 4 = 9_x_2 + 6_x_ + 6_x_ + 4
Let's look at the first two terms and last two terms separately to begin with. 9_x_2 + 6_x_ can be simplified to 3_x_(3_x_ + 2) and 6_x_ + 4 can be simplified into 2(3_x_ + 2). Putting these together gets us
9_x_2 + 12_x_ + 4
= 9_x_2 + 6_x_ + 6_x_ + 4
= 3_x_(3_x_ + 2) + 2(3_x_ + 2)
= (3_x_ + 2)(3_x_ + 2)
This is as far as we can factor.
Compare your answer with the correct one above
Factor the following variable
(x2 + 18x + 72)
Factor the following variable
(x2 + 18x + 72)
You need to find two numbers that multiply to give 72 and add up to give 18
easiest way: write the multiples of 72:
1, 72
2, 36
3, 24
4, 18
6, 12: these add up to 18
(x + 6)(x + 12)
You need to find two numbers that multiply to give 72 and add up to give 18
easiest way: write the multiples of 72:
1, 72
2, 36
3, 24
4, 18
6, 12: these add up to 18
(x + 6)(x + 12)
Compare your answer with the correct one above
When is factored, it can be written in the form , where , , , , , and are all integer constants, and .
What is the value of ?
When
What is the value of
Let's try to factor x2 – y2 – z2 + 2yz.
Notice that the last three terms are very close to y2 + z2 – 2yz, which, if we rearranged them, would become y2 – 2yz+ z2. We could factor y2 – 2yz+ z2 as (y – z)2, using the general rule that p2 – 2pq + q2 = (p – q)2 .
So we want to rearrange the last three terms. Let's group them together first.
x2 + (–y2 – z2 + 2yz)
If we were to factor out a –1 from the last three terms, we would have the following:
x2 – (y2 + z2 – 2yz)
Now we can replace y2 + z2 – 2yz with (y – z)2.
x2 – (y – z)2
This expression is actually a differences of squares. In general, we can factor p2 – q2 as (p – q)(p + q). In this case, we can substitute x for p and (y – z) for q.
x2 – (y – z)2 = (x – (y – z))(x + (y – z))
Now, let's distribute the negative one in the trinomial x – (y – z)
(x – (y – z))(x + (y – z))
(x – y + z)(x + y – z)
The problem said that factoring x2 – y2 – z2 + 2yz would result in two polynomials in the form (ax + by + cz)(dx + ey + fz), where a, b, c, d, e, and f were all integers, and a > 0.
(x – y + z)(x + y – z) fits this form. This means that a = 1, b = –1, c = 1, d = 1, e = 1, and f = –1. The sum of all of these is 2.
The answer is 2.
Let's try to factor x2 – y2 – z2 + 2yz.
Notice that the last three terms are very close to y2 + z2 – 2yz, which, if we rearranged them, would become y2 – 2yz+ z2. We could factor y2 – 2yz+ z2 as (y – z)2, using the general rule that p2 – 2pq + q2 = (p – q)2 .
So we want to rearrange the last three terms. Let's group them together first.
x2 + (–y2 – z2 + 2yz)
If we were to factor out a –1 from the last three terms, we would have the following:
x2 – (y2 + z2 – 2yz)
Now we can replace y2 + z2 – 2yz with (y – z)2.
x2 – (y – z)2
This expression is actually a differences of squares. In general, we can factor p2 – q2 as (p – q)(p + q). In this case, we can substitute x for p and (y – z) for q.
x2 – (y – z)2 = (x – (y – z))(x + (y – z))
Now, let's distribute the negative one in the trinomial x – (y – z)
(x – (y – z))(x + (y – z))
(x – y + z)(x + y – z)
The problem said that factoring x2 – y2 – z2 + 2yz would result in two polynomials in the form (ax + by + cz)(dx + ey + fz), where a, b, c, d, e, and f were all integers, and a > 0.
(x – y + z)(x + y – z) fits this form. This means that a = 1, b = –1, c = 1, d = 1, e = 1, and f = –1. The sum of all of these is 2.
The answer is 2.
Compare your answer with the correct one above
Factor and simplify:
$$\frac{64y^{2}$$ - 16}{8y + 4}
Factor and simplify:
$$\frac{64y^{2}$$ - 16}{8y + 4}
$64y^{2}$ - 16 is a difference of squares.
The difference of squares formula is $a^{2}$ - $b^{2}$ = (a - b)(a + b).
Therefore, $$\frac{64y^{2}$$ - 16}{8y + 4} = $\frac{(8y + 4)(8y - 4)}{8y + 4}$ = 8y - 4.
$64y^{2}$ - 16 is a difference of squares.
The difference of squares formula is $a^{2}$ - $b^{2}$ = (a - b)(a + b).
Therefore, $$\frac{64y^{2}$$ - 16}{8y + 4} = $\frac{(8y + 4)(8y - 4)}{8y + 4}$ = 8y - 4.
Compare your answer with the correct one above
If $$\frac{x^{2}$$-9}{x+3}=5 , and xneq -3 , what is the value of x?
If $$\frac{x^{2}$$-9}{x+3}=5 , and xneq -3 , what is the value of x?
The numerator on the left can be factored so the expression becomes $\frac{left ( x+3 right )times left ( x-3 right )}{left ( x+3 right )}$=5, which can be simplified to left ( x-3 right )=5
Then you can solve for x by adding 3 to both sides of the equation, so x=8
The numerator on the left can be factored so the expression becomes $\frac{left ( x+3 right )times left ( x-3 right )}{left ( x+3 right )}$=5, which can be simplified to left ( x-3 right )=5
Then you can solve for x by adding 3 to both sides of the equation, so x=8
Compare your answer with the correct one above
Factor:
$-12x^2$+27
Factor:
$-12x^2$+27
We can first factor out -3:
$-3(4x^{2}$-9)
This factors further because there is a difference of squares:
-3(2x+3)(2x-3)
We can first factor out -3:
$-3(4x^{2}$-9)
This factors further because there is a difference of squares:
-3(2x+3)(2x-3)
Compare your answer with the correct one above