Solving Rational Expressions - Algebra 2

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Subtract the following expressions: $\frac{x}{2x+1}$-$\frac{1}{2x}$

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In order to subtract the fractions, multiply both denominators together in order to obtain the least common denominator.

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

Simplify the numerators.

$= $$\frac{2x^2$}{(2x+1)(2x)}$-$\frac{2x+1}{(2x+1)(2x)}$$

Combine the numerators.

The answer is:

Solve: $\frac{2}{x+3}$+\frac{8}{x}$

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To simplify this expression, we will need to multiply both denominators together to find the least common denominator.

Convert both fractions to the common denominator.

Combine the fractions.

The answer is:

Determine the value of .

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(x+5)(x+3) is the common denominator for this problem making the numerators 7(x+3) and 8(x+5).

7(x+3)+8(x+5)= 7x+21+8x+40= 15x+61

A=61

Solve for :

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

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First, cross-multiply:

Once we simplify we are left with the following two quadratic equations:

In order to solve a quadratic, we need to have it equal to zero and then we can use the quadratic formula. What we need to do now is combine like terms. We can subtract all of the terms on the left from the like terms on the right:

This gives us:

Now we can use the quadratic formula:

$x= $\frac{-b \pm $\sqrt{b^2$ - 4ac}$}{2a}$

Where the quadratic equation follows the pattern:

Therefore, we can use the terms in our quadratic equation and rewrite the equation as follows:

$x= $\frac{4 \pm $\sqrt{(-4)^2$ - 4(1)(-7)}$}{2(1)}= $\frac{4 \pm \sqrt{44}$}{2}$

Since we can re-write $\sqrt{44}$ as $\sqrt{4*11}$ and $$\sqrt{4}$=2$ , our answer becomes

$x=\frac{4 \pm 2 \sqrt{11}$}{2}$

$x= 2 \pm $\sqrt{11}$$

Simplify:

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First, simplify the expression before attempting to combine like-terms.

Combine like-terms.

Simplify.

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The values can only be added or subtracted if there are like-terms in the expression. Since there are no like-terms in the question, the question is already simplified as is. All the other answers given are incorrect.

Simplify:

$\frac{4x}{x+3}$+\frac{2x}{x+3}$

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$\frac{4x}{x+3}$+\frac{2x}{x+3}$

Because the two rational expressions have the same denominator, we can simply add straight across the top. The denominator stays the same.

Therefore the answer is $\frac{6x}{x+3}$ .

Simplify the rational expression:

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There are multiple operations required in this problem. The exponent must be eliminated before distributing the negative sign. Use the FOIL method which means to mulitply the first terms together, then multiply the outer terms together, then multiply the inner terms togethers, and lastly, mulitply the last terms together.

The negative sign can now be distributed.

Add:

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First factor the denominators which gives us the following:

$\frac{x}{\left( x+1 \right)\left( x-3 \right)}$ + $\frac{1}{\left( x+1 \right)\left( x-3 \right)}$

The two rational fractions have a common denominator hence they are like "like fractions". Hence we get:

$\frac{x+1}{\left( x+1 \right)\left( x-3 \right)}$

Simplifying gives us

$\frac{1}{x-3}$

Subtract:

$$\frac{2x}{x-1}$ - $$\frac{3}{x^{2}$$-1}$

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First let us find a common denominator as follows:

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

Now we can subtract the numerators which gives us :

So the final answer is

Simplify $\frac{x+2}{x-1}$+\frac{x-5}{x+3}$

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This is a more complicated form of $\frac{1}{2}$+\frac{1}{3}$= $\frac{3}{6}$+\frac{2}{6}$=\frac{5}{6}$

Find the least common denominator (LCD) and convert each fraction to the LCD, then add the numerators. Simplify as needed.

$\frac{x+2}{x-1}$+\frac{x-5}{x+3}$=\frac{x+2}{x-1}$\cdot $\frac{x+3}{x+3}$+\frac{x-5}{x+3}$\cdot $\frac{x-1}{x-1}$

which is equivalent to $\frac{(x+2)\cdot (x+3)+(x-5)\cdot (x-1)}{(x+3)\cdot (x-1)}$

Simplify to get

Solve the rational equation:

$\small $\frac{x+2}{2}$-$\frac{3}{2x-4}$=3$

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With rational equations we must first note the domain, which is all real numbers except $\small \tiny x=2$ . (Recall, the denominator cannot equal zero. Thus, to find the domain set each denominator equal to zero and solve for what the variable cannot be.)

The least common denominator or $\small 2$ and $\small 2x-4$ is $\small 2(x-2)$ . Multiply every term by the LCD to cancel out the denominators. The equation reduces to $\small \small (x-2)(x+2)-3=6(x-2)$ . We can FOIL to expand the equation to $\small \small $x^2$ -4-3=6x-12$ . Combine like terms and solve: $\small $x^2$-6x+5=0$ . Factor the quadratic and set each factor equal to zero to obtain the solution, which is $\small x=5$ or $\small x=1$ . These answers are valid because they are in the domain.

Simplify

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a. Find a common denominator by identifying the Least Common Multiple of both denominators. The LCM of 3 and 1 is 3. The LCM of and is . Therefore, the common denominator is .

b. Write an equivialent fraction to using as the denominator. Multiply both the numerator and the denominator by to get . Notice that the second fraction in the original expression already has as a denominator, so it does not need to be converted.

The expression should now look like: .

c. Subtract the numerators, putting the difference over the common denominator.

Combine the following expression into one fraction:

$\small $$\frac{x^2$+y}{25x}$+\frac{z+3}{y}$$

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To combine fractions of different denominators, we must first find a common denominator between the two. We can do this by multiplying the first fraction by $\small $\frac{y}{y}$$ and the second fraction by $\small $\frac{25x}{25x}$$ . We therefore obtain:

$\small $$\frac{x^2$+y}{25x}$\times $\frac{y}{y}$+\frac{z+3}{y}$\times$\frac{25x}{25x}$$

$\small \small $$\frac{x^2y$$+y^2$}{25xy}$+\frac{25xz+75x}{25xy}$$

Since these fractions have the same denominators, we can now combine them, and our final answer is therefore:

$\small $$\frac{x^2y$$+y^2$+25xz+75x}{25xy}$$

What is $\frac{x+1}{3}$ + $\frac{2x-5}{2}$ ?

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We start by adjusting both terms to the same denominator which is 2 x 3 = 6

Then we adjust the numerators by multiplying x+1 by 2 and 2x-5 by 3

$\frac{(x+1)\cdot 2}{3 \cdot 2}$+\frac{(2x-5) \cdot 3}{2 \cdot 3}$

The results are:

$\frac{2x+2}{6}$+\frac{6x-15}{6}$

So the final answer is,

$\frac{8x-13}{6}$

What is $\frac{3x-4}{x+2}$-$\frac{5x+2}{2x+4}$ ?

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Start by putting both equations at the same denominator.

2x+4 = (x+2) x 2 so we only need to adjust the first term:

$\frac{(3x-4)\cdot 2}{(x+2)\cdot 2}$-$\frac{5x+2}{2x+4}$

$=\frac{6x-8}{2x+4}$-$\frac{5x+2}{2x+4}$$

Then we subtract the numerators, remembering to distribute the negative sign to all terms of the second fraction's numerator:

$=\frac{6x -8 -5x-2}{2x+4}$=\frac{x-10}{2x+4}$$

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First, find the common denominator, which is . Then, make sure to offset each numerator. Multiply $\frac{2x-1}{xy}$ by y to get . Multiply by x to get . Then, combine numerators to get . Then, put the numerator over the denominator to get your answer: .

Subtract the expressions: $\frac{8x}{x-3}$-$\frac{2}{x-7}$

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$\frac{8x}{x-3}$-$\frac{2}{x-7}$

Make a common denominator:

$\frac{x-7}{x-7}$$\frac{8x}{x-3}$-$\frac{2}{x-7}$$\frac{x-3}{x-3}$

$\frac{(x-7)8x}{x-3(x-7)}$-$\frac{2(x-3)}{x-7(x-3)}$

Combine and subtract numerators:

$\frac{(x-7)8x-2(x-3)}{(x-7)(x-3)}$

$\frac{4}{x-1}$+\frac{3}{x+1}$

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To start this problem, you must first identify the common denominator, which in this case is teh two denominators multiplied together: . Next, offset the numerators with the newly changed denominators: $\frac{4(x+1)}{(x-1)(x+1)}$+\frac{3(x-1)}{(x-1)(x+1)}$ . Then, add numerators to get: . Put the numerator over your denominator and check to make sure it can't be simplified anymore (it can't). Your answer is: .

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To combine these rational expressions, first find the common denominator. In this case, it is . Then, offset the second equation so that you get the correct denominator: . Then, combine the numerators: . Put your numerator over the denominator for your answer: .