Polynomials - Math

Card 1 of 136

0

Didn't Know

0

Didn't Know

Knew It

0

1 of 2019 left

Question

Find the zeros.

$f(x)=x^{3}-1$

Tap to reveal answer

Answer

This is a difference of perfect cubes so it factors to . Only the first expression will yield an answer when set equal to 0, which is 1. The second expression will never cross the -axis. Therefore, your answer is only 1.

← Didn't Know|Knew It →

Question

Find the zeros.

Tap to reveal answer

Answer

Factor the equation to . Set and get one of your 's to be . Then factor the second expression to . Set them equal to zero and you get $\pm \sqrt{2}$ .

← Didn't Know|Knew It →

Question

Factor $x^{3}-64$

Tap to reveal answer

Answer

Use the difference of perfect cubes equation:

In $x^{3}-64$ ,

and $b=\sqrt[3]{64}=4$

← Didn't Know|Knew It →

Question

Factor the following expression:

Tap to reveal answer

Answer

You can see that each term in the equation has an "x", therefore by factoring "x" from each term you can get that the equation equals .

← Didn't Know|Knew It →

Question

Factor this expression:

Tap to reveal answer

Answer

First consider all the factors of 12:

1 and 12

2 and 6

3 and 4

Then consider which of these pairs adds up to 7. This pair is 3 and 4.

Therefore the answer is .

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by extracting from the polynomial:

Now, factor the remainder of the polynomial as a difference of cubes:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by rearranging like terms:

Now, factor out like terms:

Rearrange the polynomial:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by rearranging like terms:

Now, factor out like terms:

Rearrange the polynomial:

Factor:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by separating into like terms. You do this by multiplying and , then finding factors which sum to

Now, extract like terms:

Simplify:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

To begin, distribute the squares:

Now, combine like terms:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by extracting from the polynomial:

Now, distribute the cubic polynomial:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by extracting like terms:

Now, rearrange the right side of the polynomial by reversing the signs:

Combine like terms:

Factor the square and cubic polynomial:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by rearranging the terms to group together the quadratic:

Now, convert the quadratic into a square:

Finally, distribute the :

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by extracting from the polynomial:

Now, rearrange to combine like terms:

Extract the like terms and factor the cubic:

Simplify by combining like terms:

← Didn't Know|Knew It →

Question

Factor the following polynomial:

Tap to reveal answer

Answer

Begin by extracting from the polynomial:

Now, rearrange to combine like terms:

Extract the like terms and factor the cubic:

Simplify by combining like terms:

← Didn't Know|Knew It →

Question

Simplify.

$x^{-6}x^3x^9$

Tap to reveal answer

Answer

Put the negative exponent on the bottom so that you have $\frac{x^{12}}{x^{6}}$ which simplifies further to $x^{6}$ .

← Didn't Know|Knew It →

Question

Simplify the following expression:

$3x^9y^4 \cdot (2y)^3$ .

Tap to reveal answer

Answer

First, multiply out the second expression so that you get .

Then, multiply your like terms, taking care to remember that when multiplying terms that have the same base, you add the exponents. Thus, you get $24x^9y^{12}$ .

← Didn't Know|Knew It →

Question

Simplify:

$\frac{13x^2y^5z^9}{169xy^5z^4}$

Tap to reveal answer

Answer

Focus on each pair of like terms. The completely cancel out, there is one left on top, and five left on the bottom.

$\frac{13}{169}$ reduces to $\frac{1}{13}$ .

Put that all together to get $\frac{xz^5}{13}$ .

← Didn't Know|Knew It →

Question

Expand this expression:

Tap to reveal answer

Answer

Use the FOIL method (First, Outer, Inner, Last):

Put all of these terms together:

Combine like terms:

← Didn't Know|Knew It →

Question

Simplify the following polynomial:

$ab^{-2}(a^2b+a^{-1}b^3-a^3b^{-1})$

Tap to reveal answer

Answer

To simplify the polynomial, begin by multiplying the first binomial by every term within the parentheses:

$ab^{-2}(a^2b+a^{-1}b^3-a^3b^{-1})$

$aa^2b^{-2}b+aa^{-1}b^{-2}b^3-aa^3b^{-2}b^{-1}$

Now, combine like terms:

$a^3b^{-1}+b^1-a^4b^{-3}$

Convert the polynomial into fraction form:

$\frac{a^3}{b}+b-\frac{a^4}{b^3}$

← Didn't Know|Knew It →

0

Knew It