12-1: Solving Systems of Equations

1. 12-1: Solving Systems of Equations Essential Question: Why are we in Algebra 2?

2. 12-1: Solving Systems of Equations • Solutions of a System of Equations • A set of values that satisfy all the equations in the system. • Example 1: Determine whether (0, 7, 12) and (1, 2, 3) are solutions to the system of equations: • 2x – 5y + 3z = 1 • x + 2y – z = 2 • 3x + y + 2z = 11 • Trying (0, 7, 12) • 2(0) – 5(7) + 3(12) = 1 • (0) + 2(7) – (12) = 2 • 3(0) + (7) + 2(12) = 31 doesn’t work • (0, 7, 12) is not a solution

3. 12-1: Solving Systems of Equations • Solution of a System of Equations • A set of values that satisfy all the equations in the system. • Example 1: Determine whether (0, 7, 12) and (1, 2, 3) are solutions to the system of equations: • 2x – 5y + 3z = 1 • x + 2y – z = 2 • 3x + y + 2z = 11 • Trying (1, 2, 3) • 2(1) – 5(2) + 3(3) = 1 • (1) + 2(2) – (3) = 2 • 3(1) + (2) + 2(3) = 11 • (1, 2, 3) is a solution

4. 12-1: Solving Systems of Equations • Solving Systems with Graphs • You can solve systems of two variables by finding the point of intersection. • Steps: • Solve each equation for y • Graph each equation • Use the intersection tool on your graphing calculator to find the point of intersection • Example 2: Find a solution to the system • 2x – y = 1 • 3x + 2y = 4 • Graph on board • Solution is (0.86, 0.71) → • y = 2x – 1 • y = -3/2 x + 2

5. 12-1: Solving Systems of Equations • Type of System and Number of Solutions • Because graphs in a linear system with two variables are lines, there are exactly three possibilities • Inconsistent System: The lines are parallel and have no point of intersection • Independent System: The lines intersect at a single point • Dependent System: The lines coincide (they’re the same line)

6. 12-1: Solving Systems of Equations • Solving Systems Algebraically • Substitution Method • Solve one equation for x (or y) • Substitute the expression for x (or y) into the other equation • Solve for the remaining variable • Substitute the value found in Step 3 into one of the original equations, and solve for the other variable. • Verify the solution in each equation. • Example 3 • Solve the system of equations below by substitution • 3x – y = 12 • 2x + 3y = 2

7. 12-1: Solving Systems of Equations • 3x – y = 12 • 2x + 3y = 2 • Solve the first equation for y • y = 3x – 12 • Substitute 3x – 12 for y in the second equation • 2x + 3(3x – 12) = 2 • Solve for x • 2x + 9x – 36 = 2 • 11x = 38 • x = 38/11 • Substitute 38/11 into the equation from step 1 • y = 3(38/11) – 12 • y = -18/11 • The solution is (38/11, -18/11)

8. 12-1: Solving Systems of Equations • Solving Systems Algebraically • Elimination Method • Multiply one or both of the equations by a nonzero constant so that the coefficients of x (or y) are opposite of each other • Eliminate x (or y) by adding the equations, and solve for the remaining variable • Substitute the value found in Step 2 into one of the original equations, and solve for the other variable • Verify the solution in each equation • Example 4 • Solve the system of equations below by substitution • x – 3y = 4 • 2x + y = 1

9. 12-1: Solving Systems of Equations • x – 3y = 4 • 2x + y = 1 • (Eliminating x) Multiply the top equation by -2 • -2x + 6y = -8 • 2x + y = 1 • Add the equations together • 7y = -7 • Solve for y • y = -1 • Substitute -1 for y into either equation to solve for x • x – 3(-1) = 4 • x + 3 = 4 • x = 1 • The solution is (1, -1)

10. 12-1: Solving Systems of Equations • Recognizing a System with Infinitely Many or No Solutions • Solve the system • 2x – 4y = 6 • -3x + 6y = -9 • Multiply the top equation by 3 and the bottom equation by 2 • 6x – 12y = 18 • -6x + 12y = -18 • Add the two equations • 0 = 0 • This is a true statement, which means the equations are the same line, which means there are an infinite number of solutions • If your ending statement would come out false, that would mean there is no solution

11. 12-1: Solving Systems of Equations • Assignment • Page 788 – 789 • Problems 1 – 25 (odds)

12. 12-1: Solving Systems of Equations • Ex 7: Solving Larger Systems by Elimination • Solve the system by elimination • [1] 2x + y – z = -1 • [2] -x – 3y + z = 5 • [3] x + 4y – 2z = -10 • Eliminate z by adding [1] and [2] • [1] 2x + y – z = -1 • [2] -x – 3y + z = 5 • [4] x – 2y = 4 • Eliminate z by using any two other equations, like [2] & [3] • [2] -x – 3y + z = 5 → multiply by 2 → -2x – 6y + 2z = 10 • [3] x + 4y – 2z = -10x + 4y – 2z = -10 • [5] -x – 2y = 0 (Continued)

13. 12-1: Solving Systems of Equations • Bringing everything over so far… • [1] 2x + y – z = -1 [4] x – 2y = 4 • [2] -x – 3y + z = 5 [5] -x – 2y = 0 • [3] x + 4y – 2z = -10 • Eliminate x by adding [4] and [5] • [4] x – 2y = 4 • [5] -x – 2y = 0 • -4y = 4 • y = -1 • Substitute y = -1 in [4] to solve for x • x – 2(-1) = 4 • x + 2 = 4 • x = 2 • Substitute y = -1 and x = 2 in [2] to solve for z • –(2) – 3(-1) + z = 5 • -2 + 3 + z = 5 • 1 + z = 5 • z = 4 • Solution is (2, -1, 4)

14. 12-1: Solving Systems of Equations • Ex 8: Applications of Systems • A ball game is attended by 575 people, and total ticket sales are $2575. If tickets cost $5 for adults and $3 for children, how many adults and how many children attended the game? • Let x = number of adultsLet y = number of children • Two equations • x + y = 575 • 5x + 3y = 2575

15. 12-1: Solving Systems of Equations • x + y = 575 • 5x + 3y = 2575 • (Eliminating y) Multiply the top equation by -3 • -3x – 3y = -1725 • 5x + 3y = 2575 • Add the equations together • 2x = 850 • Solve for x • x = 425 • Substitute 425 for x into either equation to solve for y • (425) + y = 575 • y = 150 • There were 425 adults (x) and 150 children (y) in attendance

16. 12-1: Solving Systems of Equations • Ex 9: Mixture Application • A café sells two kinds of coffee in bulk. The Costa Rican sells for $4.50 per pound, and the Kenyan sells for $7.00 per pound. The owner wishes to mix a blend that would sell for $5.00 per pound. How much of each type of coffee should be used in the blend? • Let x = Costa Rican blendLet y = Kenyan blend • Two equations • x + y = 1 (making one pound) • 4.50x + 7.00y = 5

17. 12-1: Solving Systems of Equations • x + y = 1 • 4.5x + 7y = 5 • (Eliminating y) Multiply the top equation by -7 • -7x – 7y = -7 • 4.5x + 7y = 5 • Add the equations together • -2.5x = -2 • Solve for x • x = 0.8 • Substitute .8 for x into either equation to solve for y • (.8) + y = 1 • y = .2 • The owner should use 80% Costa Rican and 20% Kenyan in the new blend

18. 12-1: Solving Systems of Equations • Assignment • Page 789 – 790 • Problems 33 & 34, 41 – 49 (odds)