Solve Systems of Linear Equations - Pre-Calculus
Card 0 of 13
Solve the following system of linear equations:
Solve the following system of linear equations:
In order to solve a system of linear equations, we must start by solving one of the equations for a single variable:
We can now substitute this value for y into the other equation and solve for x:
Our last step is to plug this value of x into either equation to find y:
In order to solve a system of linear equations, we must start by solving one of the equations for a single variable:
We can now substitute this value for y into the other equation and solve for x:
Our last step is to plug this value of x into either equation to find y:
Compare your answer with the correct one above
Solve the system of linear equations for 
:
Solve the system of linear equations for
We first move 
to the left side of the equation:
Subtract the bottom equation from the top one:
Left Side:
Right Side:
So
So dividing by a -1 we get our result.
We first move
Subtract the bottom equation from the top one:
Left Side:
Right Side:
So
So dividing by a -1 we get our result.
Compare your answer with the correct one above
Solve the following system of linear equations:
Solve the following system of linear equations:
For any system of linear equations, we can start by solving one equation for one of the variables, and then plug its value into the other equation. In this system, however, we can see that both equations are equal to y, so we can set them equal to each other:
Now we can plug this value for x back into either equation to solve for y:
So the solutions to the system, where the lines intersect, is at the following point:
For any system of linear equations, we can start by solving one equation for one of the variables, and then plug its value into the other equation. In this system, however, we can see that both equations are equal to y, so we can set them equal to each other:
Now we can plug this value for x back into either equation to solve for y:
So the solutions to the system, where the lines intersect, is at the following point:
Compare your answer with the correct one above
Solve the following system of linear equations:
Solve the following system of linear equations:
In order to solve a system of linear equations, we can either solve one equation for one of the variables, and then substitute its value into the other equation, or we can solve both equations for the same variable so that we can set them equal to each other. Let's solve both equations for y so that we can set them equal to each other:
Now we just plug our value for x back into either equation to find y:
So the solution to the system is the point:
In order to solve a system of linear equations, we can either solve one equation for one of the variables, and then substitute its value into the other equation, or we can solve both equations for the same variable so that we can set them equal to each other. Let's solve both equations for y so that we can set them equal to each other:
Now we just plug our value for x back into either equation to find y:
So the solution to the system is the point:
Compare your answer with the correct one above
Use back substitution to solve the system of linear equations.
Use back substitution to solve the system of linear equations.
Start from equation 3 because it has the least number of variables. We see directly that 
.
Back substitute into the equation with the next fewest variables, equation 2. Then,
. Solving for 
, we get
or 
.
Then back substitute our 
and 
into equation 1 to get
.
Solving for x,
.
So our solution to the system is
Start from equation 3 because it has the least number of variables. We see directly that
Back substitute into the equation with the next fewest variables, equation 2. Then,
Then back substitute our
Solving for x,
So our solution to the system is
Compare your answer with the correct one above
Solve the following system:
Solve the following system:
We can solve the system using elimination. We can eliminate our 
by multiplying the top equation by 
:
and then adding it to the bottom equation:
____________________
We can now plug in our y-value into the top equation and solve for our x-value:
Our solution is then 
We can solve the system using elimination. We can eliminate our
and then adding it to the bottom equation:
____________________
We can now plug in our y-value into the top equation and solve for our x-value:
Our solution is then
Compare your answer with the correct one above
Solve the following system:
Solve the following system:
We can solve the system using substitution since the bottom equation is already solved for 
:
Now we can plug in our value into the bottom equation to find our x-value:
So our solution is 
We can solve the system using substitution since the bottom equation is already solved for
Now we can plug in our value into the bottom equation to find our x-value:
So our solution is
Compare your answer with the correct one above
Solve the following system:
Solve the following system:
We can solve the system using elimination. We can eliminate the x terms by multiplying the bottom equation by 
:
and now add it to the top equation:
__________________
We plug in our y-value into the bottom equation to get our x-value:
Our solution is then 
We can solve the system using elimination. We can eliminate the x terms by multiplying the bottom equation by
and now add it to the top equation:
__________________
We plug in our y-value into the bottom equation to get our x-value:
Our solution is then
Compare your answer with the correct one above
Solve the following system:
Solve the following system:
We can solve this system using either substitution or elimination. We'll eliminate them here.
Note: If you wanted to do substitution, we can do it by substituting the top equation into the bottom for 
.
We'll rearrange the bottom equation to have both y-values aligned and then add the equations:
_____________________
Now that we have our x-value, we can find our y-value:
Our answer is then 
We can solve this system using either substitution or elimination. We'll eliminate them here.
Note: If you wanted to do substitution, we can do it by substituting the top equation into the bottom for
We'll rearrange the bottom equation to have both y-values aligned and then add the equations:
_____________________
Now that we have our x-value, we can find our y-value:
Our answer is then
Compare your answer with the correct one above
Solve the following system of equations:
Solve the following system of equations:
There are many ways to solve this system of equations. The following is just one way to reach the answer.
Add the two together, to elimnate the y variable. Solve for x and then plug it back in to the first equation to solve for y.
There are many ways to solve this system of equations. The following is just one way to reach the answer.
Add the two together, to elimnate the y variable. Solve for x and then plug it back in to the first equation to solve for y.
Compare your answer with the correct one above
Find the point of intersection by using Gaussian elimination:
Find the point of intersection by using Gaussian elimination:
To solve this, let's first try to eliminate x. We can do this by adding the two equations:
-------------------------------
Which implies
We can now solve for x by plugging 2 in for y in either equation.
Thus we have the answer
To solve this, let's first try to eliminate x. We can do this by adding the two equations:
-------------------------------
Which implies
We can now solve for x by plugging 2 in for y in either equation.
Thus we have the answer
Compare your answer with the correct one above
Solve the following system of equations:
Solve the following system of equations:
Let's solve this equation by eliminating the variable x by adding a multiple of the second equation to the first.
---------------------------
Now let's combine those y values and solve for y.
Now all we have to do is plug that in for y in either original equation to solve for x.
Thus this yields the intersection point
Let's solve this equation by eliminating the variable x by adding a multiple of the second equation to the first.
---------------------------
Now let's combine those y values and solve for y.
Now all we have to do is plug that in for y in either original equation to solve for x.
Thus this yields the intersection point
Compare your answer with the correct one above
Solve the following system of equations for the intersection point in space:
Solve the following system of equations for the intersection point in space:
Because one of the variables, z, has already been isolated, let's use the substitution method to solve this system of equations. We know z = 1, so let's plug that into the middle equation to solve for y:
Now that we have found y, let's solve for x by plugging both y and z into the top equation:
Thus we have found that the point of intersection would be
Because one of the variables, z, has already been isolated, let's use the substitution method to solve this system of equations. We know z = 1, so let's plug that into the middle equation to solve for y:
Now that we have found y, let's solve for x by plugging both y and z into the top equation:
Thus we have found that the point of intersection would be
Compare your answer with the correct one above