1. Slide 2- 1 Copyright © 2012 Pearson Education, Inc. Copyright © 2006 Pearson Education, Inc. Publishing as Pearson Addison-Wesley

2. Copyright © 2012 Pearson Education, Inc. 2.1Linear Functions and Models 2.2Equations of Lines 2.3Linear Equations 2.4Linear Inequalities 2.5 Absolute value Equations and Inequalities Linear Functions and Equations 2

3. Copyright © 2012 Pearson Education, Inc. Linear Inequalities ♦Understand basic terminology related to inequalities ♦Solve linear inequalities symbolically ♦Solve linear inequalities graphically and numerically ♦Solve compound inequalities 2.4

4. Slide 2- 4 Copyright © 2012 Pearson Education, Inc. Terminology Related to Inequalities Inequalities result whenever the equals sign in an equation is replaced with any one of the symbols ≤, ≥,. Examples of inequalities include: x – 5 > 2x + 3 x 2 ≤ 1 – 2x xy – x < x 2 5 > 1

5. Slide 2- 5 Copyright © 2012 Pearson Education, Inc. Linear Inequality in One Variable A linear inequality in one variable is an inequality that can be written in the form ax + b > 0 where a ≠ 0. (The symbol may be replaced by ≤, ≥, ) Examples of linear inequalities in one variable: 5x + 4 ≤ 2 + 3x simplifies to 2x + 2 ≤ 0  1(x – 3) + 4(2x + 1) > 5 simplifies to 7x + 2 > 0 Examples of inequalities in one variable which are not linear: x 2 < 1

6. Slide 2- 6 Copyright © 2012 Pearson Education, Inc. Interval Notation The solution to a linear inequality in one variable is typically an interval on the real number line. See examples of interval notation below.

7. Slide 2- 7 Copyright © 2012 Pearson Education, Inc. What Happens When Both Sides of An Inequality Are Multiplied By A Negative Number? Note that 3 symbol must be used. 3 < 5 but  3 >  5 So when both sides of an inequality are multiplied (or divided) by a negative number the direction of the inequality must be reversed.

8. Slide 2- 8 Copyright © 2012 Pearson Education, Inc. Solving Linear Inequalities Symbolically The procedure for solving a linear inequality symbolically is the same as the procedure for solving a linear equation, except when both sides of an inequality are multiplied (or divided) by a negative number the direction of the inequality is reversed. Example of Solving a Linear Equation SymbolicallyLinear Inequality Symbolically Solve  2x + 1 = x  2Solve  2x + 1 < x  2  2x  x =  2  1  2x  x <  2  1  3x =  3  3x <  3 x > 1 x = 1 x > 1 Note that we divided both sides by  3 so the direction was reversed. In interval notation the solution set is (1,∞).

9. Slide 2- 9 Copyright © 2012 Pearson Education, Inc. Example Solve graphically. Solution [  2, 15, 1] by [  2, 15, 1] Note that the graphs intersect at the point (8.20, 7.59). The graph of y 1 is above the graph of y 2 to the right of the point of intersection or when x > 8.20. Thus in interval notation the solution set is (8.20, ∞). STEP1STEP1 STEP2STEP2 STEP3STEP3

10. Slide 2- 10 Copyright © 2012 Pearson Education, Inc. Comments on Previous Problem Solve Note that the inequality above becomes y 1 > y 2 since in Step 1 we let y 1 equal the left-hand side of the inequality and y 2 equal the right hand side. To write the solution set of the inequality we are looking for the values of x for which the graph of y 1 is above the graph of y 2. These are values of x to the right of 8.20, that is values larger than 8.20. Thus the solution is x > 8.20 which is (8.20, ∞) in interval notation. STEP1STEP1 STEP3STEP3

11. Slide 2- 11 Copyright © 2012 Pearson Education, Inc. Example Solve Solution [  10, 10, 1] by [  10, 10, 1] Note that the graphs intersect at the point (  1.36, 2.72). The graph of y 1 is above the graph of y 2 to the left of the point of intersection or when x <  1.36. When x ≤  1.36 the graph of y 1 is on or above the graph of y 2. Thus in interval notation the solution set is (  ∞,  1.36]. STEP1STEP1 STEP2STEP2 STEP3STEP3

12. Slide 2- 12 Copyright © 2012 Pearson Education, Inc. Comments on Previous Problem Solve Note that the inequality above becomes y 1 ≥ y 2 since in Step 1 we let y 1 equal the left-hand side of the inequality and y 2 equal the right hand side. To write the solution set of the inequality we are looking for the values of x for which the graph of y 1 is on or above the graph of y 2. These values of x are values less than or equal to  1.36 which is (  ∞,  1.36] in interval notation. STEP1STEP1 STEP3STEP3

13. Slide 2- 13 Copyright © 2012 Pearson Education, Inc. Example Solve numerically. Solution Note that the inequality above becomes y 1 ≥ y 2 since in Step 1 we let y 1 equal the left- hand side and y 2 equal the right hand side. To write the solution set of the inequality we are looking for the values of x in the table for which y 1 is the same or larger than y 2. Note that when x =  1.3, y 1 is less than y 2 ; but when x =  1.4, y 1 is larger than y 2. By the Intermediate Value Property, there is a value of x between  1.4 and  1.3 such that y 1 = y 2. In order to find an approximation of this value, make a new table in which x is incremented by 0.01 (x is incremented by 0.1 in the table to the left.) STEP1STEP1 STEP2STEP2

14. Slide 2- 14 Copyright © 2012 Pearson Education, Inc. To write the solution set of the inequality we are looking for the values of x in the table for which y 1 is the same as or larger than y 2. Note that when x is approximately  1.36, y 1 equals y 2 and when x is smaller than  1.36 y 1 is larger than y 2 so the solutions can be written x ≤  1.36 or (  ∞,  1.36] in interval notation. Example continued

15. Slide 2- 15 Copyright © 2012 Pearson Education, Inc. Example Suppose the Fahrenheit temperature x miles above the ground level is given by T(x) = 88 – 32x. Determine the altitudes where the air temp is from 30 0 to 40 0. Solution We must solve the inequality 30 < 88 – 32 x < 40. The goal is to isolate the variable x in the middle of the three-part inequality Direction reversed – Divided each side of an inequality by a negative. Between 1.5 and 1.8215 miles above ground level, the air temperature is between 30 and 40 degrees Fahrenheit.