All SAT Math Resources
Example Questions
Example Question #201 : Algebra
Factor 36x2 – 49y2.
(6x + 7y)(6x + 7y)
(6x – 7y)(6x – 7y)
6x2 – 7y2
cannot be factored
(6x + 7y)(6x – 7y)
(6x + 7y)(6x – 7y)
This is a difference of squares. The difference of squares formula is a2 – b2 = (a + b)(a – b). In this problem, a = 6x and b = 7y.
So 36x2 – 49y2 = (6x + 7y)(6x – 7y).
Example Question #7 : How To Factor An Equation
Solve for x:
Find two numbers that add to and multiply to
Factors of
You can use
Then make each factor equal 0.
and
and
Example Question #8 : How To Factor An Equation
Find the roots of
Factoring yields giving roots of and .
Example Question #201 : Equations / Inequalities
Find the root of the equation above.
The numerator can be factored into .
Therefore, it can cancel with the denominator. So imples .
Example Question #203 : Algebra
Solve for .
Find all factors of 24
1, 2, 3,4, 6, 8, 12, 24
Now find two factors that add up to and multiply to ; and are the two factors.
By factoring, you can set the equation to be
If you FOIL it out, it gives you .
Set each part of the equation equal to 0, and solve for .
and
and
Example Question #204 : Algebra
Assume that and are integers and that . The value of must be divisible by all of the following EXCEPT:
The numbers by which x6 – y6 is divisible will be all of its factors. In other words, we need to find all of the factors of x6 – y6 , which essentially means we must factor x6 – y6 as much as we can.
First, we will want to apply the difference of squares rule, which states that, in general, a2 – b2 = (a – b)(a + b). Notice that a and b are the square roots of the values of a2 and b2, because √a2 = a, and √b2 = b (assuming a and b are positive). In other words, we can apply the difference of squares formula to x6 – y6 if we simply find the square roots of x6 and y6.
Remember that taking the square root of a quantity is the same as raising it to the one-half power. Remember also that, in general, (ab)c = abc.
√x6 = (x6)(1/2) = x(6(1/2)) = x3
Similarly, √y6 = y3.
Let's now apply the difference of squares factoring rule.
x6 – y6 = (x3 – y3)(x3 + y3)
Because we can express x6 – y6 as the product of (x3 – y3) and (x3 + y3), both (x3 – y3) and (x3 + y3) are factors of x6 – y6 . Thus, we can eliminate x3 – y3 from the answer choices.
Let's continue to factor (x3 – y3)(x3 + y3). We must now apply the sum of cubes and differences of cubes formulas, which are given below:
In general, a3 + b3 = (a + b)(a2 – ab + b2). Also, a3 – b3 = (a – b)(a2 + ab + b2)
Thus, we have the following:
(x3 – y3)(x3 + y3) = (x – y)(x2 + xy + y2)(x + y)(x2 – xy + y2)
This means that x – y and x + y are both factors of x6 – y6 , so we can eliminate both of those answer choices.
We can rearrange the factorization (x – y)(x2 + xy + y2)(x + y)(x2 – xy + y2) as follows:
(x – y)(x + y)(x2 + xy + y2)(x2 – xy + y2)
Notice that (x – y)(x + y) is merely the factorization of difference of squares. Therefore, (x – y)(x + y) = x2 – y2.
(x – y)(x + y)(x2 + xy +y2)(x2 – xy + y2) = (x2 – y2)(x2 + xy +y2)(x2 – xy + y2)
This means that x2 – y2 is also a factor of x6 – y6.
By process of elimination, x2 + y2 is not necessarily a factor of x6 – y6 .
The answer is x2 + y2 .
Example Question #12 : Factoring Equations
Factor .
Cannot be factored
First pull out any common terms: 4x3 – 16x = 4x(x2 – 4)
x2 – 4 is a difference of squares, so we can also factor that further. The difference of squares formula is a2 – b2 = (a – b)(a + b). Here a = x and b = 2. So x2 – 4 = (x – 2)(x + 2).
Putting everything together, 4x3 – 16x = 4x(x + 2)(x – 2).
Example Question #201 : Algebra
What do you get when you factor:
To factor our quadratic, we are looking for two numbers that multiply to 6 and add to -5.
When we look at the factors of 6: 1 and 6, 2 and 3. We see that 2 and 3 add to 5.
To get the negative, we get -2 and -3. Thus, we have our answer.
Example Question #10 : How To Factor An Equation
Which of the following equations is NOT equivalent to the following equation?
The equation presented in the problem is:
We know that:
Therefore we can see that the answer choice is equivalent to .
is equivalent to . You can see this by first combining like terms on the right side of the equation:
Multiplying everything by , we get back to:
We know from our previous work that this is equivalent to .
is also equivalent since both sides were just multiplied by . Dividing both sides by , we also get back to:
.
We know from our previous work that this is equivalent to .
is also equivalent to since
Only is NOT equivalent to
because
Example Question #207 : Algebra
in factored form is equal to:
is a special type of binomial. Notice that both terms are perfect squares and they are separated by a subtraction symbole; this is known as the difference of squares.
The purpose of this question is to understand the rules of algebra and recognize different forms of expressions. The correct answer is .This is because when evaluated, it equals .
When both terms of the factored form have the same coefficients with different signs, there is no number of x in the simplified version of the expression.