1. Equations as Relations

2. The equation p = 0.69d is an example of an equation in two variables. A solution of an equation in two variables is an ordered pair that results in a true statement when substituted into the equation.

3. Example 4-1a Find the solution set for given the replacement set {(–5, 0), (–3, –2), (2, 13), (4, 19)}. Make a table or do the calculations mentally. Substitute each ordered pair into the equation. 0–5 true false 194 132 –2–3 True or False? yx Solve Using a Replacement Set The ordered pairs ( –3, –2 ), ( 2, 13 ) and ( 4, 19 ) result in true statements. Answer: The solution set is {(–3, –2), (2, 13), (4, 19)}.

4. Example 4-1b Answer: {(1, 5), (–1, –1)} Solve Using a Replacement Set Find the solution set for given the replacement set {(3, 1), (6, 8), (1, 5), (–1, 1)}.

5. Equations as Relations Since the solutions of an equation in two variable are ordered pairs, the equation describes a relation. So, in an equation involving x and y, the set of x values is the domain and the corresponding set of y values is the range.

6. Example 4-2a Solve if the domain is {–2, 0, 3, 5, 8}. Make a table or do the calculations mentally. The values of c come from the domain. Substitute each value of c into the equation to determine the values of d in the range. c8 – c8 – cd (c, d)(c, d) –28 – (–2)10 (–2, 10) 08 – 08 – 08 (0, 8) 38 – 38 – 35 (3, 5) 58 – 58 – 53 (5, 3) 88 – 88 – 80 (8, 0) Answer: The solution set is {(–2, 10), (0, 8), (3, 5), (5, 3), (8, 0)}. Solve Using a Given Domain

7. Example 4-2b Answer: {(–1, –6), (0, –4), (2, 0), (5, 6)} Solve if the domain is {–1, 0, 2, 5}. Solve Using a Given Domain

8. Equations as Relations You can graph the ordered pairs in the solution set for an equation in two variables. The domain contains values represented by the independent variable. The range contains values represented by the dependent variable.

9. Example 4-3a Solve if the domain is {0, 1, 2, 3}. Graph the solution set. First solve the equation for y in terms of x. This makes creating a table of values easier. Original equation Subtract 9x from each side. Simplify. Divide each side by 3. Simplify. Solve and Graph the Solution Set

10. Example 4-3a Substitute each value of x from the domain to determine the corresponding values of y in the range. x5 – 3x5 – 3xy (x, y)(x, y) 05 – 3(0)5 (0, 5) 15 – 3(1)2 (1, 2) 25 – 3(2)–1 (2, –1) 35 – 3(3)–4 (3, –4) Answer: The solution set is {(0, 5), (1, 2), (2, –1), (3, –4)}. Graph the ordered pairs. Solve and Graph the Solution Set

11. Example 4-3b Solve if the domain is {0, 1, 2, 3}. Graph the solution set. Answer: {(0, 4), (1, 1), (2, –2), (3, –5)} Solve and Graph the Solution Set

12. Equations as Relations When you solve an equation for a given variable, that variable becomes the dependent variable. That is, its value depends upon the domain values chosen for the other variable.

13. Example 4-4a Travel In 2002, 12 countries in Europe made the switch to a single currency, the euro. Suppose the exchange rate between U.S. dollars and euros is one dollar = 1.11 euros. The equationcan be used to convert U.S. dollars to euros. If a traveler is going to spend the following amounts per day while in Europe, find the equivalent U.S. dollars for the amounts given in euros (EUR) Graph the ordered pairs. Hotel90 EUR Food50 EUR Transportation30 EUR Gifts20 EUR Solve for a Dependent Variable

14. PlanThe values of E, {90, 50, 30, 20}, are the domain. Use the equation to find the values for range. Example 4-4a ExploreIn the equation, D represents U.S. dollars and E represents the euro. However, we are given values in euros and want to find values in dollars. Solve the equation for D since the values for D depend on the given values of E. Original equation Divide each side by 1.11. Simplify and round to the nearest hundredth. Solve for a Dependent Variable

15. Example 4-4a SolveMake a table of values or do the calculations mentally. Substitute each value of E from the domain to determine the corresponding values of D. Round to the nearest dollar. E0.90ED (E, D)(E, D) 900.90(90)$81 (90, 81) 500.90(50)$45 (50, 45) 300.90(30)$27 (30, 27) 200.90(20)$18 (20, 18) Solve for a Dependent Variable

16. Example 4-4a Graph the ordered pairs. Answer: Notice that the values for the independent variable E are graphed along the horizontal axis, and the values for the dependent variable D are graphed along the vertical axis. Solve for a Dependent Variable

17. Example 4-4a The equivalent amounts in U.S. dollars for the given amounts in euros is shown in the table. ExamineLook at the values in the range. The cost in dollars is lower than the cost in euros. Do the results make sense? ExpenseEurosDollars Hotel 9081 Food 5045 Transportation 3027 Gifts 2018 Solve for a Dependent Variable

18. Example 4-4b Travel The exchange rate between U.S. dollars and Swiss francs is one dollar = 1.68 Swiss francs. The equationcan be used to convert U.S. dollars to Swiss francs F. If a traveler is going to spend the following amounts per day while he is in Switzerland, find the equivalent U.S. dollars for the amounts given. Graph the ordered pairs. Hotel 80 francs $48 Food 45 francs $27 Transportation 35 francs $21 Gifts 15 francs $9 Answer: Solve for a Dependent Variable

19. Example 4-4b Solve for a Dependent Variable