Find The Solution Of The System Of Equations.${ \begin{array}{l} -6x - 2y = -40 \ -7x - 2y = -44 \end{array} }$

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Introduction

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In mathematics, a system of linear equations is a set of two or more linear equations that are solved simultaneously to find the values of the variables. These equations are linear because they are in the form of ax + by = c, where a, b, and c are constants, and x and y are variables. In this article, we will focus on solving a system of two linear equations with two variables.

The System of Equations

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The system of equations we will be solving is:

{ \begin{array}{l} -6x - 2y = -40 \\ -7x - 2y = -44 \end{array} \}

Understanding the System

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At first glance, the system of equations may seem daunting, but it is actually quite simple. We have two equations with two variables, x and y. The first equation is -6x - 2y = -40, and the second equation is -7x - 2y = -44. We can see that both equations have the same coefficients for x and y, but the constants are different.

Solving the System

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To solve the system of equations, we can use the method of substitution or elimination. In this case, we will use the elimination method. The idea behind the elimination method is to eliminate one of the variables by adding or subtracting the equations.

Step 1: Multiply the Equations by Necessary Multiples

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To eliminate one of the variables, we need to multiply the equations by necessary multiples such that the coefficients of y's in both equations are the same. We can multiply the first equation by 1 and the second equation by 1.

Step 2: Subtract the Equations

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Now that the coefficients of y's in both equations are the same, we can subtract the second equation from the first equation to eliminate the y variable.

Step 3: Solve for x

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After subtracting the equations, we will be left with an equation in one variable, x. We can solve for x by isolating it on one side of the equation.

Step 4: Substitute x into One of the Original Equations

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Once we have the value of x, we can substitute it into one of the original equations to solve for y.

Solving the System Using the Elimination Method

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Let's apply the steps we discussed above to solve the system of equations.

Step 1: Multiply the Equations by Necessary Multiples

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We will multiply the first equation by 1 and the second equation by 1.

{ \begin{array}{l} -6x - 2y = -40 \\ -7x - 2y = -44 \end{array} \}

Step 2: Subtract the Equations

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We will subtract the second equation from the first equation to eliminate the y variable.

{ \begin{array}{l} -6x - 2y = -40 \\ -7x - 2y = -44 \end{array} \}

$(-6x - 2y) - (-7x - 2y) = -40 - (-44)$

$-6x - 2y + 7x + 2y = -40 + 44$

$x = 4$

Step 3: Substitute x into One of the Original Equations

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We will substitute x = 4 into the first original equation to solve for y.

$-6x - 2y = -40$

$-6(4) - 2y = -40$

$-24 - 2y = -40$

$-2y = -16$

$y = 8$

Conclusion

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In this article, we solved a system of two linear equations with two variables using the elimination method. We multiplied the equations by necessary multiples, subtracted the equations to eliminate the y variable, solved for x, and substituted x into one of the original equations to solve for y. The solution to the system of equations is x = 4 and y = 8.

Final Answer

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The final answer is x = 4 and y = 8.

Tips and Tricks

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• When solving a system of linear equations, it is essential to identify the coefficients and constants in each equation.
• The elimination method is a powerful tool for solving systems of linear equations.
• When using the elimination method, it is crucial to multiply the equations by necessary multiples to eliminate one of the variables.
• After eliminating one of the variables, solve for the other variable by isolating it on one side of the equation.
• Finally, substitute the value of the variable into one of the original equations to solve for the other variable.

Common Mistakes

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• When solving a system of linear equations, it is easy to make mistakes by multiplying the equations by the wrong multiples or subtracting the equations incorrectly.
• To avoid these mistakes, it is essential to carefully read and understand the equations before solving them.
• Additionally, it is crucial to check the solution by substituting the values of the variables into the original equations.

Real-World Applications

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Solving systems of linear equations has numerous real-world applications in various fields, including:

• Physics: Solving systems of linear equations is essential in physics to describe the motion of objects and solve problems involving forces and energies.
• Engineering: Engineers use systems of linear equations to design and optimize systems, such as electrical circuits and mechanical systems.
• Economics: Economists use systems of linear equations to model economic systems and make predictions about economic trends.
• Computer Science: Computer scientists use systems of linear equations to solve problems involving computer networks and data analysis.

Conclusion

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In conclusion, solving systems of linear equations is a fundamental concept in mathematics that has numerous real-world applications. By understanding the elimination method and applying it correctly, we can solve systems of linear equations and make predictions about complex systems.

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Introduction

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In our previous article, we discussed how to solve a system of linear equations using the elimination method. However, we understand that sometimes, it can be challenging to grasp the concept, and that's where our Q&A guide comes in. In this article, we will answer some of the most frequently asked questions about solving systems of linear equations.

Q: What is a system of linear equations?

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A system of linear equations is a set of two or more linear equations that are solved simultaneously to find the values of the variables. These equations are linear because they are in the form of ax + by = c, where a, b, and c are constants, and x and y are variables.

Q: What are the different methods for solving systems of linear equations?

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There are several methods for solving systems of linear equations, including:

• Elimination Method: This method involves adding or subtracting the equations to eliminate one of the variables.
• Substitution Method: This method involves substituting the value of one variable into the other equation to solve for the other variable.
• Graphical Method: This method involves graphing the equations on a coordinate plane and finding the point of intersection.

Q: What is the elimination method, and how does it work?

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The elimination method is a powerful tool for solving systems of linear equations. It involves adding or subtracting the equations to eliminate one of the variables. The idea behind the elimination method is to multiply the equations by necessary multiples such that the coefficients of one of the variables are the same. Then, we can add or subtract the equations to eliminate that variable.

Q: How do I know which variable to eliminate first?

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When using the elimination method, it's essential to identify which variable to eliminate first. To do this, we need to look at the coefficients of the variables in both equations. If the coefficients of one variable are the same, we can eliminate that variable. If the coefficients are different, we need to multiply the equations by necessary multiples to make the coefficients the same.

Q: What are some common mistakes to avoid when solving systems of linear equations?

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When solving systems of linear equations, it's easy to make mistakes. Here are some common mistakes to avoid:

• Multiplying the equations by the wrong multiples: Make sure to multiply the equations by necessary multiples to eliminate one of the variables.
• Subtracting the equations incorrectly: Double-check your work when subtracting the equations to eliminate one of the variables.
• Not checking the solution: Always check the solution by substituting the values of the variables into the original equations.

Q: How do I know if the solution is correct?

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To check if the solution is correct, we need to substitute the values of the variables into the original equations. If the solution satisfies both equations, then it's correct. If the solution doesn't satisfy both equations, then it's incorrect.

Q: What are some real-world applications of solving systems of linear equations?

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Solving systems of linear equations has numerous real-world applications in various fields, including:

• Physics: Solving systems of linear equations is essential in physics to describe the motion of objects and solve problems involving forces and energies.
• Engineering: Engineers use systems of linear equations to design and optimize systems, such as electrical circuits and mechanical systems.
• Economics: Economists use systems of linear equations to model economic systems and make predictions about economic trends.
• Computer Science: Computer scientists use systems of linear equations to solve problems involving computer networks and data analysis.

Conclusion

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In conclusion, solving systems of linear equations is a fundamental concept in mathematics that has numerous real-world applications. By understanding the elimination method and applying it correctly, we can solve systems of linear equations and make predictions about complex systems. We hope this Q&A guide has helped you understand the concept better and has provided you with the tools you need to solve systems of linear equations.

Final Tips

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• Practice, practice, practice: The more you practice solving systems of linear equations, the more comfortable you'll become with the concept.
• Use online resources: There are many online resources available that can help you learn and practice solving systems of linear equations.
• Seek help when needed: Don't be afraid to ask for help if you're struggling with a problem.