3-3: Cramer’s Rule.

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Presentation transcript:

3-3: Cramer’s Rule

Cramer’s Rule - 2 x 2 Cramer’s Rule relies on determinants. Consider the system below with variables x and y:

Cramer’s Rule - 2 x 2 The formulae for the values of x and y are shown below. The numbers inside the determinants are the coefficients and constants from the equations.

Cramer’s Rule Example: Solve the system: 3x - 2y = 10 4x + y = 6 The solution is (2, -2)

Cramer’s Rule - 3 x 3 Consider the 3-equation system below with variables x, y and z:

Cramer’s Rule - 3 x 3 The formulae for the values of x, y and z are shown below. Notice that all three have the same denominator.

Cramer’s Rule Not all systems have a definite solution. If the determinant of the coefficient matrix is zero, a solution cannot be found using Cramer’s Rule due to division by zero. When the solution cannot be determined, one of two conditions exists: The planes graphed by each equation are parallel and there are no solutions. The three planes share one line (like three pages of a book share the same spine) or represent the same plane, in which case there are infinite solutions.

Cramer’s Rule Example: Solve the system 3x - 2y + z = 9 x + 2y - 2z = -5 x + y - 4z = -2

Cramer’s Rule Example, continued: 3x - 2y + z = 9 x + 2y - 2z = -5 x + y - 4z = -2 The solution is (1, -3, 0)