Simplifying Expressions - Algebra 2

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Question

Simplify x(4 – x) – x(3 – x).

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Answer

You must multiply out the first set of parenthesis (distribute) and you get 4x – x2. Then multiply out the second set and you get –3x + x2. Combine like terms and you get x.

x(4 – x) – x(3 – x)

4x – x2 – x(3 – x)

4x – x2 – (3x – x2)

4x – x2 – 3x + x2 = x

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Question

Expand:

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Answer

To expand, multiply 8x by both terms in the expression (3x + 7).

8x multiplied by 3x is 24x².

8x multiplied by 7 is 56x.

Therefore, 8x(3x + 7) = 24x² + 56x.

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Question

Divide by .

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Answer

First, set up the division as the following:

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && & & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \end{array}$

Look at the leading term in the divisor and in the dividend. Divide by gives ; therefore, put on the top:

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && 3x & & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \end{array}$

Then take that and multiply it by the divisor, , to get . Place that under the division sign:

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && 3x & & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \ & && $3x^3$ & -3x \end{array}$

Subtract the dividend by that same and place the result at the bottom. The new result is , which is the new dividend.

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && 3x & & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \ & && $3x^3$ & -3x \ \cline{4-7} & && & $5x^2$ & 2x & 8 \end{array}$

Now, is the new leading term of the dividend. Dividing by gives 5. Therefore, put 5 on top:

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && 3x & 5 & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \ & && $3x^3$ & -3x \ \cline{4-7} & && & $5x^2$ & 2x & 8 \end{array}$

Multiply that 5 by the divisor and place the result, , at the bottom:

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && 3x & 5 & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \ & && $3x^3$ & -3x \ \cline{4-7} & && & $5x^2$ & 2x & 8 \ & && & $5x^2$ & -5 \end{array}$

Perform the usual subtraction:

$\begin{array}{2r @{\hskip\arraycolsep}c@{\hskip\arraycolsep} 4r} & && 3x & 5 & & \ \cline{3-7} $x^2$ & -1 &\big)& $3x^3$ & $5x^2$ & -x & 8 \ & && $3x^3$ & -3x \ \cline{4-7} & && & $5x^2$ & 2x & 8 \ & && & $5x^2$ & -5 \ \cline{5-7} & && & & 2x & 13 \ \end{array}$

Therefore the answer is with a remainder of , or .

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Question

Simplify the expression.

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Answer

When multiplying exponential components, you must add the powers of each term together.

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Question

Simplify the expression.

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Answer

When simplifying polynomials, only combine the variables with like terms.

can be added to , giving .

can be subtracted from to give .

Combine both of the terms into one expression to find the answer:

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Question

Simplify:

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Answer

First, distribute –5 through the parentheses by multiplying both terms by –5.

Then, combine the like-termed variables (–5x and –3x).

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Question

Find the product:

$\small 7n(8n-2)$

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Answer

First, mulitply the mononomial by the first term of the polynomial:

$\small 7n\times8n\ = $56n^2$$

Second, multiply the monomial by the second term of the polynomial:

$\small 7n\times (-2)\ = -14n$

Add the terms together:

$\small $56n^2$\ +\ (-14n)\ = $56n^2$-14n$

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Question

Evaluate the following to its simplest form:

$$\frac{1}{2}$(4x+2)(x-2)+\frac{1}{3}$(2x-3)$

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Answer

$$\frac{1}{2}$(4x+2)(x-2)+\frac{1}{3}$(2x-3)$

First we will foil the first function before distributing.

We will then distribute out the $\frac{1}{2}$

We will then distribute out the $\frac{1}{3}$

Now the only like terms we have are $-3x+\frac{2}{3}$x$ and , so our final answer is:

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Question

Simplify:

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Answer

. However, cannot be simplified any further because the terms have different exponents.

(Like terms are terms that have the same variables with the same exponents. Only like terms can be combined together.)

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Question

Find the product:

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Answer

times gives us , while times 4 gives us . So it equals .

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Question

Simplify:

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Answer

and cancel out, leaving in the numerator. 5 and 25 cancel out, leaving 5 in the denominator

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Question

Simplify the expression:

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Answer

distributes to , multiplying to become , and distributes to , multiplying to make .

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Question

Distribute:

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Answer

Be sure to distribute the along with its coefficient.

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Question

Simplify the following:

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Answer

First, FOIL the two binomials:

Then distribute the through the terms in parentheses:

Combine like terms:

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Question

Simplify the following:

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Answer

First we will factor the numerator:

Then factor the denominator:

We can re-write the original fraction with these factors and then cancel an (x-5) term from both parts:

$\frac{(x-5)(x-5)}{(x-5)(x+5)}$=\frac{x-5}{x+5}$

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Question

Simplify the following:

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Answer

First, let us factor the numerator:

$$\frac{2x(2+3x)}{2x}$=2+3x$

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Question

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Answer

When multiplying polynomials, add the powers of each like-termed variable together.

For x: 5 + 2 = 7

For y: 17 + 2 = 19

Therefore the answer is .

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Question

Simplify the expression:

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Answer

When dividing polynomials, subtract the exponent of the variable in the numberator by the exponent of the same variable in the denominator.

If the power is negative, move the variable to the denominator instead.

First move the negative power in the numerator to the denominator:

Then subtract the powers of the like variables:

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Question

Expand:

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Answer

First, FOIL:

Simplify:

Distribute the $\frac{1}{3}$ through the parentheses:

Rewrite to make the expression look like one of the answer choices:

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Question

Multiply, expressing the product in simplest form:

$\small $$\frac{15x^{5}$$$}{14y^{3}$} \cdot $$\frac{21y^{2}$$ $}{25x^{3}$}$

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Answer

Cross-cancel the coefficients by dividing both 15 and 25 by 5, and both 14 and 21 by 7:

$\small \small \small \small $$\frac{15x^{5}$$$}{14y^{3}$} \cdot $$\frac{21y^{2}$$ $}{25x^{3}$} = \small \small \small \small $$\frac{3x^{5}$$$}{2y^{3}$} \cdot $$\frac{3y^{2}$$ $}{5x^{3}$} = $$\frac{3x^{5}$$ \cdot $3y^{2}$$}{5x^{3}$ \cdot $2y^{3}$} = $\frac{3 \cdot 3 \cdot $x^{5}$$ $y^{2}$}{5\cdot 2\cdot $x^{3}$ $y^{3}$} = $\frac{9 $x^{5}$$ $y^{2}$}{10 $x^{3}$ $y^{3}$}$

Now use the quotient rule on the variables by subtracting exponents:

$\small $\frac{9 $x^{5}$$ $y^{2}$}{10 $x^{3}$ $y^{3}$} = $\frac{9 $x^{5-3}$$}{10 $y^{3-2}$} = $\frac{9 $x^{2}$$}{10 $y^{1}$} = $\frac{9 $x^{2}$$}{10 y}$

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