2. Warm Up Graph each of the following points in the coordinate plane. 1. A (2, β1) 2. B (β4, 2) 3. Find the intercepts of the line . x : β9; y : 3
5. A Global Positioning System (GPS) gives locations using the three coordinates of latitude, longitude, and elevation. You can represent any location in three-dimensional space using a three-dimensional coordinate system , sometimes called coordinate space .
6. Each point in coordinate space can be represented by an ordered triple of the form ( x, y, z ). The system is similar to the coordinate plane but has an additional coordinate based on the z -axis . Notice that the axes form three planes that intersect at the origin.
7. Graph the point in three-dimensional space. Example 1A: Graphing Points in Three Dimensions A (3, β2, 1) From the origin, move 3 units forward along the x -axis, 2 units left, and 1 unit up. ο· A (3, β2, 1 ) y x z
8. Graph the point in three-dimensional space. Example 1B: Graphing Points in Three Dimensions B (2, β1, β3) From the origin, move 2 units forward along the x -axis, 1 unit left, and 3 units down. B (2, β1, β3) ο· y x z
9. Graph the point in three-dimensional space. Example 1C: Graphing Points in Three Dimensions C (β1, 0, 2) From the origin, move 1 unit back along the x -axis, 2 units up. Notice that this point lies in the xz -plane because the y -coordinate is 0. C ( β1,0, 2) ο· y x z
10. Graph the point in three-dimensional space. D (1, 3, β1) From the origin, move 1 unit forward along the x -axis, 3 units right, and 1 unit down. ο· D (1, 3, β1 ) Check It Out! Example 1a y x z
11. Graph the point in three-dimensional space. E (1, β3, 1) From the origin, move 1 unit forward along the x -axis, 3 units left, and 1 unit up. E (1, β3, 1) ο· Check It Out! Example 1b y x z
12. Graph the point in three-dimensional space. F (0, 0, 3) From the origin, move 3 units up. F (0 , 0, 3) ο· Check It Out! Example 1c y x z
13. Recall that the graph of a linear equation in two dimensions is a straight line. In three-dimensional space, the graph of a linear equation is a plane. Because a plane is defined by three points, you can graph linear equations in three dimensions by finding the three intercepts.
14. To find an intercept in coordinate space, set the other two coordinates equal to 0. Helpful Hint
15. Graph the linear equation 2 x β 3 y + z = β6 in three-dimensional space. Example 2: Graphing Linear Equations in Three Dimensions Step 1 Find the intercepts: x -intercept: 2 x β 3(0) + (0) = β6 x = β3 y -intercept: 2(0) β 3 y + (0) = β6 z -intercept: 2(0) β 3(0) + z = β6 y = 2 z = β6
16. Step 2 Plot the points (β3, 0, 0), (0, 2, 0), and (0, 0, β6). Sketch a plane through the three points. Example 2 Continued ο· ( β3, 0, 0 ) (0, 2 , 0 ) (0, 0, β6 ) ο· ο· y x z
17. Graph the linear equation x β 4 y + 2 z = 4 in three-dimensional space. Step 1 Find the intercepts: x -intercept: x β 4(0) + 2(0) = 4 x = 4 y -intercept: (0) β 4 y + 2(0) = 4 z -intercept: (0) β 4(0) + 2 z = 4 y = β1 z = 2 Check It Out! Example 2
18. Step 2 Plot the points (4, 0, 0), (0, β1, 0), and (0, 0, 2). Sketch a plane through the three points. β (4 , 0, 0 ) (0, β1, 0 ) (0, 0, 2) ο· ο· Check It Out! Example 2 Continued y x z
19. Track relay teams score 5 points for finishing first, 3 for second, and 1 for third. Linβs team scored a total of 30 points. Example 3A: Sports Application Write a linear equation in three variables to represent this situation. Let f = number of races finished first, s = number of races finished second, and t = number of races finished third. Points for first 5 f + + + + Points for second 3 s Points for third 1 t + = = 30 30
20. Example 3B: Sports Application If Lin β s team finishes second in six events and third in two events, in how many events did it finish first? 5 f + 3 s + t = 30 5 f + 3(6) + (2) = 30 f = 2 Use the equation from A. Substitute 6 for s and 2 for t. Solve for f. Linn β s team placed first in two events.
21. Check It Out! Example 3a Steve purchased $61.50 worth of supplies for a hiking trip. The supplies included flashlights for $3.50 each, compasses for $1.50 each, and water bottles for $0.75 each. Write a linear equation in three variables to represent this situation. flashlights 3.50 x + + + compasses 1.50 y water bottles 0.75 z + = = 61.50 61.50 Let x = number of flashlights, y = number of compasses, and z = number of water bottles.
22. Check It Out! Example 3b Steve purchased 6 flashlights and 24 water bottles. How many compasses did he purchase? 3.5 x + 1.5 y + 0.75 z = 61.50 3.5(6) + 1.5 y + 0.75(24) = 61.50 y = 15 Use the equation from a. Substitute 6 for x and 24 for z. Solve for y. Steve purchased 15 compasses. 21 + 1.5 y + 18 = 61.50 1.5 y = 22.5
23. Lesson Quiz: Part I Graph each point in three dimensional space. 1. A (β2, 3, 1) 2. B (0, β2, 3) A ( β2, 3, 1) ο· B ( 0 , β2, 3 ) ο· y x z
24. Lesson Quiz: Part II 3. Graph the linear equation 6 x + 3 y β 2 z = β12 in three-dimensional space.
25. Lesson Quiz: Part III 4. Lily has $6.00 for school supplies. Pencils cost $0.20 each, pens cost $0.30 each, and erasers cost $0.25 each. a. Write a linear equation in three variables to represent this situation. b. If Lily buys 6 pencils and 6 erasers, how many pens can she buy? 0.2 x + 0.3 y +0.25 z = 6 11