SAT Math - How to factor a polynomial

If the polynomial

$x^{5} + x^{4} - x^{3} - x^{2}$

is divided by

what is the remainder?

Explanation

By the Remainder Theorem, if a polynomial is divided by a binomial , the remainder is .

Let $P(x)= x^{5} + x^{4} - x^{3} - x^{2}$ . Setting (since ), if is divided by , the remainder is , which can be evaluated by setting in the definition of and evaluating:

$P(x)= x^{5} + x^{4} - x^{3} - x^{2}$

$P(2)= (-2)^{5} + (-2) ^{4} - (-2)^{3} - (-2)^{2}$

Which of the following is a factor of the polynomial $x^{4} -6x ^{3} + 2x ^{2} - 3x - 54$ ?

Explanation

Call $P (x) = x^{4} -6x ^{3} + 2x ^{2} - 3x - 54$

By the Rational Zeroes Theorem, since has only integer coefficients, any rational solution of must be a factor of 54 divided by a factor of 1 - positive or negative. 54 has as its factors 1, 2, 3, 6, 9, 18, 27 , 54; 1 has only itself as a factor. Therefore, the rational solutions of must be chosen from this set:

$\left { 1, 2, 3, 6, 9, 18, 27 , 54, -1,- 2,- 3,- 6, -9, -18, -27 ,- 54 \right }$ .

By the Factor Theorem, a polynomial is divisible by if and only if - that is, if is a zero. By the preceding result, we can immediately eliminate and as factors, since 12 and 16 have been eliminated as possible zeroes.

Of the three remaining choices, we can demonstrate that is the factor by evaluating :

$P (x) = x^{4} -6x ^{3} + 2x ^{2} - 3x - 54$

$P (6) = 6^{4} -6 \cdot 6 ^{3} + 2 \cdot 6 ^{2} - 3 \cdot 6 - 54$

$= 1,296 -6 \cdot 216 + 2 \cdot 36 - 3 \cdot 6 - 54$

, so is a factor.

Of the remaining two choices, and , both can be proved to not be factors by showing that and are both nonzero:

$P (x) = x^{4} -6x ^{3} + 2x ^{2} - 3x - 54$

$P (3) = 3^{4} -6 \cdot 3 ^{3} + 2 \cdot 3 ^{2} - 3 \cdot 3 - 54$

$= 81 -6 \cdot 27+ 2 \cdot 9 - 3 \cdot 3 - 54$

, so is not a factor.

$P (x) = x^{4} -6x ^{3} + 2x ^{2} - 3x - 54$

$P (9) = 9^{4} -6 \cdot 9 ^{3} + 2 \cdot 9 ^{2} - 3 \cdot 9 - 54$

$= 6,561 -6 \cdot 729 + 2 \cdot 81 - 3 \cdot 9 - 54$

, so is not a factor.

If the polynomial

$x^{5} + x^{4} - x^{3} - x^{2}$

is divided by

what is the remainder?

Explanation

By the Remainder Theorem, if a polynomial is divided by a binomial , the remainder is .

Let $P(x)= x^{5} + x^{4} - x^{3} - x^{2}$ . Setting , if is divided by , the remainder is , which can be evaluated by setting in the definition of and evaluating:

$P(x)= x^{5} + x^{4} - x^{3} - x^{2}$

$P(2)= 2^{5} + 2^{4} - 2^{3} - 2^{2}$

If r and t are constants and x2 +rx +6=(x+2)(x+t), what is the value of r?

It cannot be determined from the given information.

Explanation

We first expand the right hand side as x2+2x+tx+2t and factor out the x terms to get x2+(2+t)x+2t. Next we set this equal to the original left hand side to get x2+rx +6=x2+(2+t)x+2t, and then we subtract x2 from each side to get rx +6=(2+t)x+2t. Since the coefficients of the x terms on each side must be equal, and the constant terms on each side must be equal, we find that r=2+t and 6=2t, so t is equal to 3 and r is equal to 5.

Let and be integers, such that . If and , then what is ?

Cannot be determined

Explanation

We are told that x3 - y3 = 56. We can factor the left side of the equation using the formula for difference of cubes.

x3 - y3 = (x - y)(x2 + xy + y2) = 56

Since x - y = 2, we can substitute this value in for the factor x - y.

2(x2 + xy + y2) = 56

Divide both sides by 2.

x2 + xy + y2 = 28

Because we are trying to find x2 + y2, if we can get rid of xy, then we would have our answer.

We are told that 3xy = 24. If we divide both sides by 3, we see that xy = 8.

We can then substitute this value into the equation x2 + xy + y2 = 28.

x2 + 8 + y2 = 28

Subtract both sides by eight.

x2 + y2 = 20.

The answer is 20.

ALTERNATE SOLUTION:

We are told that x - y = 2 and 3xy = 24. This is a system of equations.

If we solve the first equation in terms of x, we can then substitute this into the second equation.

x - y = 2

Add y to both sides.

x = y + 2

Now we will substitute this value for x into the second equation.

3(y+2)(y) = 24

Now we can divide both sides by three.

(y+2)(y) = 8

Then we distribute.

y2 + 2y = 8

Subtract 8 from both sides.

y2 + 2y - 8 = 0

We need to factor this by thinking of two numbers that multiply to give -8 but add to give 2. These numbers are 4 and -2.

(y + 4)(y - 2) = 0

This means either y - 4 = 0, or y + 2 = 0

y = -4, or y = 2

Because x = y + 2, if y = -4, then x must be -2. Similarly, if y = 2, then x must be 4.

Let's see which combination of x and y will satisfy the final equation that we haven't used, x3 - y3 = 56.

If x = -2 and y = -4, then

(-2)3 - (-4)3 = -8 - (-64) = 56. So that means that x= -2 and y = -4 is a valid solution.

If x = 4 and y = 2, then

(4)3 - 23 = 64 - 8 = 56. So that means x = 4 and y = 2 is also a valid solution.

The final value we are asked to find is x2 + y2.

If x= -2 and y = -4, then x2 + y2 = (-2)2 + (-4)2 = 4 + 16 = 20.

If x = 4 and y = 2, then x2 + y2 = (4)2 + 22 = 16 + 4 = 20.

Thus, no matter which solution we use for x and y, x2 + y2 = 20.

The answer is 20.

What is a possible value for x in x2 – 12x + 36 = 0 ?

–6

There is not enough information

Explanation

You need to factor to find the possible values for x. You need to fill in the blanks with two numbers with a sum of -12 and a product of 36. In both sets of parenthesis, you know you will be subtracting since a negative times a negative is a positive and a negative plus a negative is a negative

(x –__)(x –__).

You should realize that 6 fits into both blanks.

You must now set each set of parenthesis equal to 0.

x – 6 = 0; x – 6 = 0

Solve both equations: x = 6

2x + 3y = 5a + 2b (1)

3x + 2y = 4a – b (2)

Express x2 – y2 in terms of a and b

〖–9a〗2 + 26ab +〖3b〗2) / 5

–〖9a〗2 + 26ab –〖3b〗2) / 5

(–9a2 – 28ab –3b2) / 5

(–9a2 – 27ab +3b2) / 5

–〖9a〗2 + 27ab +〖3b〗2) / 5

Explanation

Add the two equations together to yield 5x + 5y = 9a + b, then factor out 5 to get 5(x + y) = 9a + b; divide both sides by 5 to get x + y = (9a + b)/5; subtract the two equations to get x - y = -a - 3b. So, x2 – y2 = (x + y)(x – y) = (9a + b)/5 (–a – 3b) = (–\[(9a)\]2 – 28ab – \[(3b)\]2)/5

Solve for $x$ :