1. Chapter 7 7-2 Systems of linear Equations

2. Objectives O Use the method of elimination to solve systems of linear equations O Graphically interpret the number of solutions of a system

3. Elimination method O In section 7.1 you studied two methods for solving a system of equations: substitution and graphing.

4. Elimination method O The addition method of solving systems of equations is also called the method of elimination. This method is similar to the method you probably learned for solving simple equations. solving simple equations O If you had the equation "x + 6 = 11", you would write "–6" under either side of the equation, and then you'd "add down" to get "x = 5" as the solution. O x + 6 = 11 –6 –6 x = 5 O You'll do something similar with the elimination method

5. The steps for the method of elimination O 1. obtain coefficients for x(or y) that differ only in sign by multiplying all terms for one or both equations O 2. Add the equations to eliminate one variable; solve the resulting equation. O 3. Back-substitute the value obtained in step 2 into either of the original equations O 45. check your solution

6. Example #1

7. Example#2

8. Check it out!!! O Solve the following system. O 2x + y = 9 3x – y = 16 Then the solution is (x, y) = (5, –1)

9. Check it out!!!! O Solve the following system. O x – 2y = –9 x + 3y = 16 Then the solution is (x, y) = (1, 5).

10. GRAPHICAL INTERPRETATION O When you are solving systems, you are, graphically, finding intersections of lines. For two-variable systems, there are then three possible types of solutions: Case 1Case 2Case 3

11. GRAPHS O The first graph above, "Case 1", shows two distinct non-parallel lines that cross at exactly one point. This is called an "independent" system of equations, and the solution is always some x,y-point. Independent system: one solution point

12. GRAPHS O The second graph above, "Case 2", shows two distinct lines that are parallel. Since parallel lines never cross, then there can be no intersection; that is, for a system of equations that graphs as parallel lines, there can be no solution. This is called an "inconsistent" system of equations, and it has no solution. O Inconsistent system: no solution and no intersection point

13. GRAPHS O The third graph above, "Case 3", appears to show only one line. Actually, it's the same line drawn twice. These "two" lines, really being the same line, "intersect" at every point along their length. This is called a "dependent" system, and the "solution" is the whole line.

14. GRAPHS O This shows that a system of equations may have one solution (a specific x,y-point), no solution at all, or an infinite solution (being all the solutions to the equation). You will never have a system with two or three solutions; it will always be one, none, or infinitely-many. O A system of linear equations is consistent when it has at least one solution. It is inconsistent when it has no solution

15. Example Solve the following system by graphing. 2x – 3y = –2 4x + y = 24

16. Example O Solve the following system by graphing. O y = 36 – 9x 3x + y / 3 = 12

17. Example O Solve the following system by graphing. O 7x + 2y = 16 –21x – 6y = 24