The augmented matrix represents a system of linear equations in the variables x and y. [1...

The augmented matrix below represents a system of linear equations associated with a real world prob-...

The augmented matrix below represents a system of linear equations associated with a real world prob- lem. The augmented matrix has already been completely row reduced. 1 0 6 12  0 1 −2 0  0000 (a) Use the reduced matrix to write down the parametric solution for the system as a point (x, y, z).    (b) Assuming that x, y, and z represent the number of whole items, determine how many “actual” solutions this system has, and...

Please give examples of matrices which (1) is an augmented matrix of a linear system which...

Please give examples of matrices which (1) is an augmented matrix of a linear system which 3 equations and 3 variables. (2) is an augmented matrix of a linear system which 3 equations and 3 variables and all variables should be presented. (3) is an augmented matrix of a linear system which 3 equations and 3 variables and one of the variables is not presented. (4) is an augmented matrix of a linear system which is inconsistent. (5) is an...

There exists infinite many solutions of a system of equations, if: 1) number of variables is...

There exists infinite many solutions of a system of equations, if: 1) number of variables is less than number of non zero rows in augmented matrix 2) None 3) number of non zero rows in augmented matrix is less than number of variables 4) number of non zero rows and number of variables are equal Which one is correct?

Use Gauss-Jordan method (augmented matrix method) to solve the following systems of linear equations. Indicate whether...

Use Gauss-Jordan method (augmented matrix method) to solve the following systems of linear equations. Indicate whether the system has a unique solution, infinitely many solutions, or no solution. Clearly write the row operations you use. (a) x − 2y + z = 8 2x − 3y + 2z = 23 − 5y + 5z = 25 (b) x + y + z = 6 2x − y − z = 3 x + 2y + 2z = 0

Consider a system of linear equations with augmented matrix A and coefficient matrix C. In each...

Consider a system of linear equations with augmented matrix A and coefficient matrix C. In each case either prove the statement or give an example showing that it is false. • If there is more than one solution, A has a row of zeros. • If A has a row of zeros, there is more than one solution. • If there is no solution, the row-echelon form of C has a row of zeros. • If the row-echelon form of...

Use Gauss-Jordan method (augmented matrix method) to solve the following systems of linear equations. Indicate whether...

Use Gauss-Jordan method (augmented matrix method) to solve the following systems of linear equations. Indicate whether the system has a unique solution, infinitely many solutions, or no solution. Clearly write the row operations you use. (a) (5 points) x + y + z = 6 2x − y − z = 3 x + 2y + 2z = 0 (b) (5 points) x − 2y + z = 4 3x − 5y + 3z = 13 3y − 3z =...

Let A be a n × n matrix, and let the system of linear equations A~x...

Let A be a n × n matrix, and let the system of linear equations A~x = ~b have infinitely many solutions. Can we use Cramer’s rule to find x1? If yes, explain how to find it. If no, explain why not.

4. [10] Consider the system of linear equations x + y + z = 4 x...

4. [10] Consider the system of linear equations x + y + z = 4 x + y + 2z = 6 x + y + (b2 − 3)z = b + 2 where b is an unspecified real number. Determine, with justification, the values of b (if any) for which the system has (i) no solutions; (ii) a unique solution; (ii) infinitely many solutions.

1) Solve the system of equations. Give your answer as an ordered pair (x,y) {y=−7 {5x-6y=72...

1) Solve the system of equations. Give your answer as an ordered pair (x,y) {y=−7 {5x-6y=72 a) One solution: b) No solution c) Infinite number of solutions 2) Solve the system of equations. Give your answer as an ordered pair (x,y) {x=2 {3x-6y=-30 a) One solution: b) No solution c) Infinite number of solutions

4. Solve the system of linear equations by using the Gauss-Jordan (Matrix) Elimination Method. No credit...

4. Solve the system of linear equations by using the Gauss-Jordan (Matrix) Elimination Method. No credit in use any other method. Use exactly the notation we used in class and in the text. Indicate whether the system has a unique solution, no solution, or infinitely many solutions. In the latter case, present the solutions in parametric form. 3x + 6y + 3z = -6 -2x -3y -z = 1 x +2y + z = -2