SOLUTION: If x+y+z =3 2x-y+z=2 find x, y & z value 3x+2y- 4x=1 by matrix method

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Question 865486: If x+y+z =3 2x-y+z=2 find x, y & z value 3x+2y- 4x=1 by matrix method
Answer by richwmiller(17219) About Me  (Show Source):
You can put this solution on YOUR website!
x+y+z =3 2x-y+z=3
3x+2y-4x=1
Solved by pluggable solver: Using Cramer's Rule to Solve Systems with 3 variables



system%281%2Ax%2B1%2Ay%2B1%2Az=3%2C2%2Ax%2B-1%2Ay%2B1%2Az=3%2C3%2Ax%2B2%2Ay%2B-4%2Az=1%29



First let A=%28matrix%283%2C3%2C1%2C1%2C1%2C2%2C-1%2C1%2C3%2C2%2C-4%29%29. This is the matrix formed by the coefficients of the given system of equations.


Take note that the right hand values of the system are 3, 3, and 1 and they are highlighted here:




These values are important as they will be used to replace the columns of the matrix A.




Now let's calculate the the determinant of the matrix A to get abs%28A%29=20. To save space, I'm not showing the calculations for the determinant. However, if you need help with calculating the determinant of the matrix A, check out this solver.



Notation note: abs%28A%29 denotes the determinant of the matrix A.



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Now replace the first column of A (that corresponds to the variable 'x') with the values that form the right hand side of the system of equations. We will denote this new matrix A%5Bx%5D (since we're replacing the 'x' column so to speak).






Now compute the determinant of A%5Bx%5D to get abs%28A%5Bx%5D%29=26. Again, as a space saver, I didn't include the calculations of the determinant. Check out this solver to see how to find this determinant.



To find the first solution, simply divide the determinant of A%5Bx%5D by the determinant of A to get: x=%28abs%28A%5Bx%5D%29%29%2F%28abs%28A%29%29=%2826%29%2F%2820%29=13%2F10



So the first solution is x=13%2F10




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We'll follow the same basic idea to find the other two solutions. Let's reset by letting A=%28matrix%283%2C3%2C1%2C1%2C1%2C2%2C-1%2C1%2C3%2C2%2C-4%29%29 again (this is the coefficient matrix).




Now replace the second column of A (that corresponds to the variable 'y') with the values that form the right hand side of the system of equations. We will denote this new matrix A%5By%5D (since we're replacing the 'y' column in a way).






Now compute the determinant of A%5By%5D to get abs%28A%5By%5D%29=13.



To find the second solution, divide the determinant of A%5By%5D by the determinant of A to get: y=%28abs%28A%5By%5D%29%29%2F%28abs%28A%29%29=%2813%29%2F%2820%29=13%2F20



So the second solution is y=13%2F20




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Let's reset again by letting A=%28matrix%283%2C3%2C1%2C1%2C1%2C2%2C-1%2C1%2C3%2C2%2C-4%29%29 which is the coefficient matrix.



Replace the third column of A (that corresponds to the variable 'z') with the values that form the right hand side of the system of equations. We will denote this new matrix A%5Bz%5D






Now compute the determinant of A%5Bz%5D to get abs%28A%5Bz%5D%29=21.



To find the third solution, divide the determinant of A%5Bz%5D by the determinant of A to get: z=%28abs%28A%5Bz%5D%29%29%2F%28abs%28A%29%29=%2821%29%2F%2820%29=21%2F20



So the third solution is z=21%2F20




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Final Answer:




So the three solutions are x=13%2F10, y=13%2F20, and z=21%2F20 giving the ordered triple (13/10, 13/20, 21/20)




Note: there is a lot of work that is hidden in finding the determinants. Take a look at this 3x3 Determinant Solver to see how to get each determinant.