Linear / Rational / Variable Equations - Algebra 1

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Question

Solve the rational equation:

$\small \frac{1}{m+3}+\frac{1}{m-3}=\frac{6}{m^2-9}$

Answer

With rational equations we must first note the domain, which is all real numbers except $\small \small m=-3$ and $\small \small m=3$ . That is, these are the values of $\small m$ that will cause the equation to be undefined. Since the least common denominator of $\small m+3$ , $\small m-3$ , and $\small m^2-9$ is $\small (m+3)(m-3)$ , we can mulitply each term by the LCD to cancel out the denominators and reduce the equation to $\small (m-3)+(m+3)=6$ . Combining like terms, we end up with $\small 2m=6$ . Dividing both sides of the equation by the constant, we obtain an answer of $\small m=3$ . However, this solution is NOT in the domain. Thus, there is NO SOLUTION because $\small m=3$ is an extraneous answer.

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Question

Solve for :

Answer

Combine like terms on each side of the equation:

Next, subtract from both sides.

Then subtract from both sides.

This is nonsensical; therefore, there is no solution to the equation.

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Question

Find the solution set:

Answer

Use the substitution method to solve for the solution set.

Solve equation 2 for y:

Substitute into equation 1:

If equation 1 was solved for a variable and then substituted into the second equation a similar result would be found. This is because these two equations have No solution. Change both equations into slope-intercept form and graph to visualize. These lines are parallel; they cannot intersect.

*Any method of finding the solution to this system of equations will result in a no solution answer.

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Question

How many solutions does the equation below have?

Answer

When finding how many solutions an equation has you need to look at the constants and coefficients.

The coefficients are the numbers alongside the variables.

The constants are the numbers alone with no variables.

If the coefficients are the same on both sides then the sides will not equal, therefore no solutions will occur.

Use distributive property on the right side first.

No solutions

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Question

Solve: $\frac{x^2-1}{x-1} = 2$

Answer

First factorize the numerator.

Rewrite the equation.

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

The terms can be eliminated.

Subtract one on both sides.

However, let's substitute this answer back to the original equation to check whether if we will get as an answer.

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

Simplify the left side.

$\frac{0}{0}=2$

The left side does not satisfy the equation because the fraction cannot be divided by zero.

Therefore, is not valid.

The answer is: $\textup{No solution.}$

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Question

Solve the equation: $\left | 2x+3\right |=-1$

Answer

Notice that the end value is a negative. Any negative or positive value that is inside an absolute value sign must result to a positive value.

If we split the equation to its positive and negative solutions, we have:

Solve the first equation.

The answer to is:

Solve the second equation.

The answer to is:

If we substitute these two solutions back to the original equation, the results are positive answers and can never be equal to negative one.

The answer is no solution.

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Question

Simplify:

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

Answer

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

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 $\frac{6x}{x+3}$ .

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Question

Solve for :

$\frac{3}{x-1} + \frac{4}{x- 3 } = 5$

Answer

Multiply both sides by :

$\frac{3}{x-1} + \frac{4}{x- 3 } = 5$

$\frac{3}{x-1} \cdot (x-1) (x-3)+ \frac{4}{x- 3 } \cdot (x-1) (x-3) = 5\cdot (x-1) (x-3)$

$3 \cdot (x-3)+4\cdot (x-1) = 5\cdot (x-1) (x-3)$

$3x-9 + 4x-4 = 5 (x ^{2 } -4x+3)$

$7x-13= 5 x ^{2 } -20x+15$

$7x -13 -7x + 13= 5 x ^{2 } -20x -7x +15+ 13$

$5 x ^{2 } -27x + 28 = 0$

Factor this using the -method. We split the middle term using two integers whose sum is and whose product is $5 \cdot28 = 140$ . These integers are :

$5 x ^{2 } -20x -7x + 28 = 0$

$\left (5 x ^{2 } -20x \right ) - \left (7x - 2 8\right ) = 0$

$5x \left (x-4 \right ) - 7 \left (x-4 \right ) = 0$

$\left (5x - 7 \right )\left (x-4 \right ) = 0$

Set each factor equal to 0 and solve separately:

$5x \div 5 = 7 \div 5$

$x = \frac{7}{5} = 1 \frac{2}{5}$

or

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Question

Solve the rational equation:

$\frac{1}{y}+\frac{1}{2}=8$

Answer

With rational equations we must first note the domain, which is all real numbers except $\small \small y=0$ . (If $\small y=0$ , then the term $\small \frac{1}{y}$ will be undefined.) Next, the least common denominator is $\small 2y$ , so we multiply every term by the LCD in order to cancel out the denominators. The resulting equation is $\small 2 +y=16y$ . Subtract $\small y$ on both sides of the equation to collect all variables on one side: $\small 2=15y$ . Lastly, divide by the constant to isolate the variable, and the answer is $\small y=\frac{2}{15}$ . Be sure to double check that the solution is in the domain of our equation, which it is.

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Question

Solve the rational equation:

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

Answer

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.

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Question

Simplify the following:

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

Answer

Before you can add the two numerators from the fractions, the fractions must have a common denominator. The common denominator will be the Lowest Common Denominator (LCD). When you are dealing with variables, you get this by multiplying the two denominators together:

$\frac{2x}{x+3} + \frac{4}{x} = \frac{?}{x(x+3)}$

To follow through with this LCD, you must multiply each fraction by the other fraction's denominator so that they end up with common denominators. The first fraction needs to be multiplied by $\frac{x}{x}$ and the second fraction needs to be multiplied by $\frac{x+3}{x+3}$ . Note that both of these are equivalent to ONE, so the value of the fraction does not change:

$\frac{(2x)(x)}{(x+3)(x)} + \frac{(4)(x+3)}{(x)(x+3)} = \frac{2x^2}{x(x+3)} + \frac{4x+12}{x(x+3)}$

Now that the two fractions have common denominators, you can add the two numerators:

$\frac{2x^2+4x+12}{x(x+3)}$

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Question

Simplify the following:

$\frac{4x}{7} - \frac{2x}{2x+4}$

Answer

Before you can subtract the two numerators from the fractions, the fractions must have a common denominator. The common denominator will be the Lowest Common Denominator (LCD). When you are dealing with variables, you get this by multiplying the two denominators together:

$\frac{4x}{7} - \frac{2x}{2x+4} = \frac{?}{7(2x+4)}$

To follow through with this LCD, you must multiply each fraction by the other fraction's denominator so that they end up with common denominators. The first fraction needs to be multiplied by $\frac{2x+4}{2x+4}$ and the second fraction needs to be multiplied by $\frac{7}{7}$ . Note that both of these are equivalent to ONE, so the value of the fraction does not change:

$\frac{4x(2x+4)}{7(2x+4)} - \frac{2x(7)}{2x+4(7)} = \frac{8x^2+16x}{7(2x+4)} - \frac{14x}{7(2x+4)}$

Now that the two fractions have common denominators, you can subtract the two numerators. You can also distribute the denominator so you can simplify later:

$\frac{8x^2+2x}{14x+28}$

Finally you can divide out each term in the numerator and denominator by 2 to fully simplify the answer:

$\frac{4x^2+x}{7x+14}$

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Question

Solve for :

$\frac{3x}{x+3} + \frac{10}{x+3} = 5$

Answer

Since the two fractions already have a common denominator, you can add the fractions by adding up the two numerators and keeping the common denominator:

$\frac{3x+10}{x+3} = 5$

Next you will algebraically solve for by isolating it on one side of the equation. The first step is to multiply each side by :

$(x+3)\frac{3x+10}{x+3} = 5(x+3)$

Cancel out the on the left and distribute out on the right. Then solve for by subtracting to the left and subtracting 10 to the right. Finally divide each side by negative 2:

$x=-\frac{5}{2}$

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Question

Solve this rational equation: $\frac{8}{x(x+5)}-\frac{4}{x+5}=\frac{12}{x}$

Answer

There are two ways to solve this problem using LCD (Least Common Denominator). The first method requires that you convert all denominators to the LCD by multiplying appropriately, and then follow the operations the equation requests. The second method allows you to cancel out terms using the LCD by mutiplying each term by the LCD. This is the method used for this problem and sometimes the simpler method since it tends to eliminate some of the fractions.

$\frac{8}{x(x+5)}-\frac{4}{x+5}=\frac{12}{x}$

Find the LCD:

The LCD will be based of the denominator of the first fraction (with 8 in the numerator). The middle term, based on this, is missing an x while the third term is missing . Our LCD will be since it has all the parts of each denominator. Multiply each term by this LCD.

$\frac{8}{x(x+5)}[\frac{x(x+5)}{1}]-\frac{4}{x+5}[\frac{x(x+5)}{1}]=\frac{12}{x}[\frac{x(x+5)}{1}]$

Cancel terms that are present in our denominators and the LCD (same terms) we are multiplying by (red numbers will be canceled out):

$\frac{8}{\color{Red} {x(x+5)}}[\frac{\color{Red} {x(x+5)}}{1}]-\frac{4}{\color{Red} {x+5}}[\frac{x{\color{Red} (x+5)}}{1}]=\frac{12}{\color{Red} {x}}[\frac{{\color{Red} x}(x+5)}{1}]$

Rewrite equation:

Distribute the right side of the equation:

Move x's to one side:

completely isolate x:

$x=-\frac{13}{4}$

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Question

Simplify the following expression:

$\frac{4}{x^2-4}+\frac{7x}{2x^3+8x^2+8x}$

Answer

In order to simplify this problem, we are going to need to factor the ploynimials and then get the two terms to have the same denominator.

Starting out with factoring:

$\frac{4}{x^2-4}+\frac{7x}{2x^3+8x^2+8x}$

$\frac{4}{(x+2)(x-2)}+\frac{7x}{2x(x^2+4x+4)}$

the x's on the right term cancel:

$\frac{4}{(x+2)(x-2)}+\frac{7}{2(x^2+4x+4)}$

factoring one more time:

$\frac{4}{(x+2)(x-2)}+\frac{7}{2(x+2)^2}$

Now we need to make the denominators on both terms the same. Let's start by multiplying the left term by (x+2)/(x+2):

$\frac{(x+2)}{(x+2)}\cdot\frac{4}{(x+2)(x-2)}+\frac{7}{2(x+2)^2}$

$\frac{4(x+2)}{(x+2)^2(x-2)}+\frac{7}{2(x+2)^2}$

**Note: We can do this because (x+2)/(x+2)=1 and multiplying something by 1 does not change its value

Now let's multiply the right term by (x-2)/(x-2):

$\frac{4(x+2)}{(x+2)^2(x-2)}+\frac{7}{2(x+2)^2}\cdot \frac{(x-2)}{(x-2)}$

$\frac{4(x+2)}{(x+2)^2(x-2)}+\frac{7(x-2)}{2(x+2)^2(x-2)}$

Now the only difference in the denominators is the 2 on the right term. Let's multipl the left term by 2/2 in order to solve this:

$\frac{2}{2}\cdot\frac{4(x+2)}{(x+2)^2(x-2)}+\frac{7(x-2)}{2(x+2)^2(x-2)}$

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

Our denominators are finally the same! Let's combine the fractions:

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

Now let's distribute and combine like terms (we are almost done):

$\frac{8x+16+7x-14}{2(x+2)^2(x-2)}$

$\frac{15x+2}{2(x+2)^2(x-2)}$

This expression can't be simplified any further. We have our answer!

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Question

Solve the equation: $\frac{x}{3}-\frac{4}{15}=3$

Answer

$\frac{x}{3}-\frac{4}{15}=3$

Find a common denominator:

$\frac{5}{5}*\frac{x}{3}-\frac{4}{15}=3\rightarrow \frac{5x}{15}-\frac{4}{15}=3$

Subtract the fractions and multiply to cancel the denominator:

$\frac{5x-4}{15}=3\rightarrow 5x-4=45$

Move over the constant and isolate x:

$5x=49\rightarrow x=\frac{49}{5}$

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Question

Find the solution: $x=\frac{3}{x}+\frac{1}{2}$

Answer

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

Multiply both sides by 2x:

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

Move all terms to one side:

Solve the quadratic:

$2x+3=0\rightarrow \mathbf{x=-\frac{3}{2}}$

$x-2=0\rightarrow \mathbf{x=2}$

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Question

What is ?

Answer

The key to solving this question is noticing that we can factor out a 2:

2_x_ + 6_y_ = 44 is the same as 2(x + 3_y_) = 44.

Therefore, x + 3_y_ = 22.

In this case, x + 3_y_ + 33 is the same as 22 + 33, or 55.

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Question

Simplify the result of the following steps, to be completed in order:

1. Add to

2. Multiply the sum by

3. Add to the product

4. Subtract from the sum

Answer

Step 1: 7_x_ + 3_y_

Step 2: 4 * (7_x_ + 3_y_) = 28_x_ + 12_y_

Step 3: 28_x_ + 12_y_ + x = 29_x_ + 12_y_

Step 4: 29_x_ + 12_y_ – (x – y) = 29_x_ + 12_y_ – x + y = 28_x_ + 13_y_

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Question

Solve for .

Answer

Subtract x from both sides of the second equation.

Divide both sides by to get $y=\frac{18-x}{5}$ .

Plug in y to the other equation.

$5x+15= 10*\frac{18-x}{5}$

Divide 10 by 5 to eliminate the fraction, yielding .

Distribute the 2 to get .

Add to each side, and subtract 15 from each side to get .

Divide both sides by 7 to get $\frac{x}{7}=\frac{21}{7}$ , which simplifies to .

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