What Is The Solution To This System Of Equations?$\[ \begin{align*} \frac{2}{3} X + Y &= 6 \\ -\frac{2}{3} X - Y &= 2 \end{align*} \\]A. (1, -1) B. (0, 8) C. Infinitely Many Solutions D. No Solution

Introduction

Solving a system of equations is a fundamental concept in mathematics, and it is essential to understand the different types of solutions that can arise from such systems. In this article, we will explore the solution to a given system of equations and discuss the possible outcomes.

The System of Equations

The given system of equations is:

{ \begin{align*} \frac{2}{3} x + y &= 6 \\ -\frac{2}{3} x - y &= 2 \end{align*} \}

Step 1: Multiply the Equations by 3

To simplify the equations, we can multiply both equations by 3 to eliminate the fractions.

{ \begin{align*} 2x + 3y &= 18 \\ -2x - 3y &= 6 \end{align*} \}

Step 2: Add the Equations

Now, we can add the two equations to eliminate the variable x.

{ \begin{align*} (2x + 3y) + (-2x - 3y) &= 18 + 6 \\ 0 &= 24 \end{align*} \}

This result is a contradiction, as 0 cannot equal 24. Therefore, we can conclude that the system of equations has no solution.

Conclusion

In this article, we have explored the solution to a given system of equations. By multiplying the equations by 3 and adding them, we have shown that the system has no solution. This is a classic example of a system of equations with no solution, and it highlights the importance of understanding the different types of solutions that can arise from such systems.

No Solution

The system of equations has no solution, as the result of adding the equations is a contradiction.

Why is the System of Equations No Solution?

The system of equations is no solution because the result of adding the equations is a contradiction. This means that the two equations are inconsistent, and there is no value of x and y that can satisfy both equations simultaneously.

What are the Possible Outcomes of a System of Equations?

There are three possible outcomes of a system of equations:

• One solution: The system has a unique solution, and there is only one value of x and y that can satisfy both equations simultaneously.
• Infinitely many solutions: The system has infinitely many solutions, and there are an infinite number of values of x and y that can satisfy both equations simultaneously.
• No solution: The system has no solution, and there is no value of x and y that can satisfy both equations simultaneously.

How to Determine the Outcome of a System of Equations

To determine the outcome of a system of equations, we can use the following steps:

1. Solve the first equation for one variable: Solve the first equation for one variable, such as x or y.
2. Substitute the expression into the second equation: Substitute the expression into the second equation to eliminate one variable.
3. Solve the resulting equation: Solve the resulting equation to determine the outcome of the system.

Example of a System of Equations with One Solution

Consider the following system of equations:

{ \begin{align*} x + y &= 4 \\ 2x - 2y &= -2 \end{align*} \}

To solve this system, we can use the following steps:

1. Solve the first equation for x: Solve the first equation for x to get x = 4 - y.
2. Substitute the expression into the second equation: Substitute the expression into the second equation to get 2(4 - y) - 2y = -2.
3. Solve the resulting equation: Solve the resulting equation to get 8 - 4y - 2y = -2, which simplifies to 8 - 6y = -2.

Solving for y, we get y = 5/3. Substituting this value into the first equation, we get x = 4 - 5/3 = 7/3.

Therefore, the solution to the system is (7/3, 5/3).

Example of a System of Equations with Infinitely Many Solutions

Consider the following system of equations:

{ \begin{align*} x + y &= 4 \\ x - y &= 2 \end{align*} \}

To solve this system, we can use the following steps:

1. Add the two equations: Add the two equations to get 2x = 6.
2. Solve for x: Solve for x to get x = 3.
3. Substitute the value of x into one of the equations: Substitute the value of x into one of the equations to get 3 + y = 4.

Solving for y, we get y = 1.

Therefore, the solution to the system is (3, 1).

However, we can also add the two equations to get 2x = 6, and then solve for x to get x = 3. Substituting this value into the first equation, we get 3 + y = 4, which gives y = 1.

But we can also add the two equations to get 2x = 6, and then solve for x to get x = 3. Substituting this value into the second equation, we get 3 - y = 2, which gives y = 1.

Therefore, the system has infinitely many solutions, and any value of x and y that satisfies both equations simultaneously is a solution to the system.

Example of a System of Equations with No Solution

Consider the following system of equations:

{ \begin{align*} x + y &= 4 \\ x + y &= 2 \end{align*} \}

To solve this system, we can use the following steps:

1. Subtract the two equations: Subtract the two equations to get 0 = -2.

This result is a contradiction, as 0 cannot equal -2. Therefore, the system has no solution.

Q: What is a system of equations?

A: A system of equations is a set of two or more equations that are related to each other through a common variable or variables.

Q: How do I solve a system of equations?

A: To solve a system of equations, you can use various methods such as substitution, elimination, or graphing. The method you choose depends on the type of system and the number of equations.

Q: What is the difference between a linear and a nonlinear system of equations?

A: A linear system of equations is a system where each equation is a linear equation, meaning it can be written in the form ax + by = c, where a, b, and c are constants. A nonlinear system of equations, on the other hand, is a system where at least one equation is not linear.

Q: How do I determine the number of solutions to a system of equations?

A: To determine the number of solutions to a system of equations, you can use the following methods:

• Substitution method: Substitute the expression for one variable into the other equation to eliminate one variable.
• Elimination method: Add or subtract the equations to eliminate one variable.
• Graphing method: Graph the equations on a coordinate plane to see if they intersect at a single point, intersect at multiple points, or are parallel.

Q: What is the difference between a consistent and an inconsistent system of equations?

A: A consistent system of equations is a system where the equations have a solution, meaning there is at least one value of x and y that satisfies both equations simultaneously. An inconsistent system of equations, on the other hand, is a system where the equations have no solution, meaning there is no value of x and y that satisfies both equations simultaneously.

Q: How do I solve a system of equations with no solution?

A: To solve a system of equations with no solution, you can use the following steps:

1. Add the equations: Add the equations to eliminate one variable.
2. Solve for the other variable: Solve for the other variable using the resulting equation.
3. Check for consistency: Check if the resulting equation is consistent with the original equations.

Q: What is the difference between a dependent and an independent system of equations?

A: A dependent system of equations is a system where the equations have infinitely many solutions, meaning there are an infinite number of values of x and y that satisfy both equations simultaneously. An independent system of equations, on the other hand, is a system where the equations have a unique solution, meaning there is only one value of x and y that satisfies both equations simultaneously.

Q: How do I solve a system of equations with infinitely many solutions?

A: To solve a system of equations with infinitely many solutions, you can use the following steps:

1. Add the equations: Add the equations to eliminate one variable.
2. Solve for the other variable: Solve for the other variable using the resulting equation.
3. Express the solution in terms of a parameter: Express the solution in terms of a parameter, such as x = a + b, where a and b are constants.

Q: What is the difference between a homogeneous and a nonhomogeneous system of equations?

A: A homogeneous system of equations is a system where all the equations are equal to zero, meaning ax + by = 0. A nonhomogeneous system of equations, on the other hand, is a system where at least one equation is not equal to zero.

Q: How do I solve a homogeneous system of equations?

A: To solve a homogeneous system of equations, you can use the following steps:

1. Find the solution to the corresponding nonhomogeneous system: Find the solution to the corresponding nonhomogeneous system by setting the constant term to zero.
2. Express the solution in terms of a parameter: Express the solution in terms of a parameter, such as x = a + b, where a and b are constants.

Q: What is the difference between a system of linear equations and a system of nonlinear equations?

A: A system of linear equations is a system where each equation is a linear equation, meaning it can be written in the form ax + by = c, where a, b, and c are constants. A system of nonlinear equations, on the other hand, is a system where at least one equation is not linear.

Q: How do I solve a system of nonlinear equations?

A: To solve a system of nonlinear equations, you can use various methods such as substitution, elimination, or numerical methods. The method you choose depends on the type of system and the number of equations.

Q: What is the difference between a system of equations with one solution and a system of equations with infinitely many solutions?

A: A system of equations with one solution is a system where there is only one value of x and y that satisfies both equations simultaneously. A system of equations with infinitely many solutions, on the other hand, is a system where there are an infinite number of values of x and y that satisfy both equations simultaneously.

Q: How do I determine the number of solutions to a system of equations?

A: To determine the number of solutions to a system of equations, you can use the following methods:

• Substitution method: Substitute the expression for one variable into the other equation to eliminate one variable.
• Elimination method: Add or subtract the equations to eliminate one variable.
• Graphing method: Graph the equations on a coordinate plane to see if they intersect at a single point, intersect at multiple points, or are parallel.

Q: What is the difference between a consistent and an inconsistent system of equations?

A: A consistent system of equations is a system where the equations have a solution, meaning there is at least one value of x and y that satisfies both equations simultaneously. An inconsistent system of equations, on the other hand, is a system where the equations have no solution, meaning there is no value of x and y that satisfies both equations simultaneously.

Q: How do I solve a system of equations with no solution?

A: To solve a system of equations with no solution, you can use the following steps:

1. Add the equations: Add the equations to eliminate one variable.
2. Solve for the other variable: Solve for the other variable using the resulting equation.
3. Check for consistency: Check if the resulting equation is consistent with the original equations.

Q: What is the difference between a dependent and an independent system of equations?

A: A dependent system of equations is a system where the equations have infinitely many solutions, meaning there are an infinite number of values of x and y that satisfy both equations simultaneously. An independent system of equations, on the other hand, is a system where the equations have a unique solution, meaning there is only one value of x and y that satisfies both equations simultaneously.

Q: How do I solve a system of equations with infinitely many solutions?

A: To solve a system of equations with infinitely many solutions, you can use the following steps:

1. Add the equations: Add the equations to eliminate one variable.
2. Solve for the other variable: Solve for the other variable using the resulting equation.
3. Express the solution in terms of a parameter: Express the solution in terms of a parameter, such as x = a + b, where a and b are constants.