2. Warm Up Solve each equation for y. 1. 6 y – 12 x = 24 2. – 2 y – 4 x = 20 3. 2 y – 5 x = 16 4. 3 y + 6 x = 18 y = 2 x + 4 y = – 2 x – 10 y = – 2 x + 6 Course 3 11-1 Graphing Linear Equations y = x + 8 5 2
3. Learn to identify and graph linear equations. Course 3 11-1 Graphing Linear Equations
4. WHAT IS A LINEAR EQUATION? A linear equation is an equation whose solutions fall on a line on the coordinate plane. All solutions of a particular linear equation fall on the line, and all the points on the line are solutions of the equation. Course 3 11-1 Graphing Linear Equations
5. HOW DO I KNOW IF AN EQUATION IS LINEAR? If an equation is linear, a constant change in the x -value corresponds to a constant change in the y-value. 3 3 3 2 2 2 The graph shows an example where each time the x -value increases by 3, the y -value increases by 2. Course 3 11-1 Graphing Linear Equations
6. Make a table, graph the equation, and tell whether it is linear. A. y = 3 x – 1 Graphing Equations – 7 3 (–2) – 1 3 (–1) – 1 3 (0) – 1 3 (1) – 1 3 (2) – 1 – 4 – 1 2 5 (–2, –7) (–1, –4) (0, –1) (1, 2) (2, 5) 2 1 0 – 1 – 2 ( x , y ) y 3 x – 1 x Course 3 11-1 Graphing Linear Equations
7. Each time x increases by 1 unit, y increases by 3 units. y = 3 x – 1 Course 3 11-1 Graphing Linear Equations (2, 5) (1, 2) (0, -1) (-1, -4) (-2, -7) ( x , y )
8. Make a table, graph the equation, and tell whether it is linear. B. y = x 3 Graphing Equations – 8 (–2) 3 (–1) 3 (0) 3 (1) 3 (2) 3 – 1 0 1 8 (–2, –8) (–1, –1) (0, 0) (1, 1) (2, 8) 2 1 0 – 1 – 2 ( x , y ) y x 3 x Course 3 11-1 Graphing Linear Equations
9. The equation y = x 3 is not a linear equation because its graph is not a straight line. Also notice that as x increases by a constant of 1 unit, the change in y is not constant. +7 +1 +1 +7 8 1 0 – 1 – 8 y 2 1 0 – 1 – 2 x Course 3 11-1 Graphing Linear Equations
10. Fill in the table below. Then, graph the equation and tell whether it is linear. A. y = 2 x + 1 Try This – 3 2 (–2) + 1 2 (–1) + 1 2 (0) + 1 2 (1) + 1 2 (2) + 1 – 1 1 3 5 (–3, –3) (–2, –1) (–1, 1) (0, 3) (2, 5) 2 1 0 – 1 – 2 ( x , y ) y 2 x + 1 x Course 3 11-1 Graphing Linear Equations
11. The equation y = 2 x + 1 is a linear equation. Each time x increase by 1 unit, y increases by 2 units. Course 3 11-1 Graphing Linear Equations
14. More Graphing Equations Graph the equation and tell whether it is linear. C. y = – 3 x 4 Course 3 11-1 Graphing Linear Equations
15. Additional Example 1 Continued The equation y = – is a linear equation. 3 x 4 Course 3 11-1 Graphing Linear Equations
16. Graph the equation and tell whether it is linear. D. y = 2 More Graphing Equations For any value of x, y = 2. 2 2 2 2 2 2 2 2 2 2 (–2, 2) (–1, 2) (0, 2) (1, 2) (2, 2) 2 1 0 – 1 – 2 ( x , y ) y 2 x Course 3 11-1 Graphing Linear Equations
17. Additional Example 1D Continued The equation y = 2 is a linear equation because the points form a straight line. As the value of x increases, the value of y has a constant change of 0. Course 3 11-1 Graphing Linear Equations
18. Try This Graph the equation and tell whether it is linear. C. y = x – 8 – 6 0 4 8 (–8, –8) (–6, –6) (0, 0) (4, 4) (8, 8) 8 4 0 – 6 – 8 ( x , y ) y x Course 3 11-1 Graphing Linear Equations
19. Try This : Example 1C Continued The equation y = x is a linear equation because the points form a straight line. Each time the value of x increases by 1, the value of y increases by 1. Course 3 11-1 Graphing Linear Equations
20. Application In an amusement park ride, a car travels according to the equation D = 1250 t where t is time in minutes and D is the distance in feet the car travels. Graph the relationship between time and distance. How far has each person traveled? 3 min Colette 2 min Greg 1 min Ryan Time Rider Course 3 11-1 Graphing Linear Equations
21. Continued The distances are: Ryan, 1250 ft; Greg, 2500 ft; and Collette, 3750 ft. (3, 3750) 3750 1250( 3 ) 3 (2, 2500) 2500 1250( 2 ) 2 (1, 1250) 1250 1250( 1 ) 1 ( t , D) D D =1250 t t Course 3 11-1 Graphing Linear Equations
22. Continued x y This is a linear equation because when t increases by 1 unit, D increases by 1250 units. 1250 2500 1 2 3750 5000 3 4 Time (min) Distance (ft) Course 3 11-1 Graphing Linear Equations
23. Sports Application A lift on a ski slope rises according to the equation a = 130 t + 6250, where a is the altitude in feet and t is the number of minutes that a skier has been on the lift. Five friends are on the lift. What is the altitude of each person if they have been on the ski lift for the times listed in the table? Draw a graph that represents the relationship between the time on the lift and the altitude. Course 3 11-1 Graphing Linear Equations
26. The altitudes are: Anna, 6770 feet; Tracy, 6640 feet; Kwani, 6510 feet; Tony, 6445 feet; George, 6380 feet. This is a linear equation because when t increases by 1 unit, a increases by 130 units. Note that a skier with 0 time on the lift implies that the bottom of the lift is at an altitude of 6250 feet. Additional Example 2 Continued Course 3 11-1 Graphing Linear Equations
29. Warm Up Evaluate each equation for x = –1, 0, and 1. 1. y = 3 x 2. y = x – 7 3. y = 2 x + 5 4. y = 6 x – 2 – 3, 0, 3 – 8, –7, –6 3, 5, 7 – 8, –2, 4 Course 3 11-2 Slope of a Line
30. Learn to find the slope of a line and use slope to understand and draw graphs. Course 3 11-2 Slope of a Line
31. What is slope? vertical change horizontal change change in y change in x = This ratio is often referred to as , or “rise over run,” where rise indicates the number of units moved up or down and run indicates the number of units moved to the left or right. Slope can be positive, negative, zero, or undefined. rise run Course 3 11-2 Slope of a Line
34. GET ON YOUR FEET! Course 3 11-2 Slope of a Line
35. Finding Slope from a Graph Choose two points on the line: (0, 1) and (3, –4). Guess by looking at the graph: – 5 3 rise run = – 5 3 = – 5 3 Course 3 11-2 Slope of a Line
36. How to find the slope of a line (without a visual)… If you have two points ( x 1 , y 1 ) & ( x 2 , y 2 ) Use the following formula: y 2 – y 1 x 2 – x 1 Course 3 11-2 Slope of a Line
37. Find the slope of the line that passes through (–2, –3) and (4, 6). Finding Slope, Given Two Points Let ( x 1 , y 1 ) be (–2, –3) and ( x 2 , y 2 ) be (4, 6). Substitute 6 for y 2 , –3 for y 1 , 4 for x 2 , and –2 for x 1 . 6 – (–3) 4 – (–2) 9 6 = The slope of the line that passes through (–2, –3) and (4, 6) is . 3 2 = y 2 – y 1 x 2 – x 1 3 2 = Course 3 11-2 Slope of a Line
38. Find the slope of the line that passes through (–4, –6) and (2, 3). Try This : Example 1 Let ( x 1 , y 1 ) be (–4, –6) and ( x 2 , y 2 ) be (2, 3). Substitute 3 for y 2 , –6 for y 1 , 2 for x 2 , and –4 for x 1 . 3 – (–6) 2 – (–4) 9 6 = The slope of the line that passes through (–4, –6) and (2, 3) is . 3 2 = y 2 – y 1 x 2 – x 1 3 2 = Course 3 11-2 Slope of a Line
39. Use the graph of the line to determine its slope. Try This : Example 2 Course 3 11-2 Slope of a Line
40. Try This : Example 2 Continued Choose two points on the line: (1, 1) and (0, –1). Guess by looking at the graph: Use the slope formula. Let (1, 1) be (x 1 , y 1 ) and (0, –1) be (x 2 , y 2 ). = 2 1 2 rise run = 2 1 = 2 = y 2 – y 1 x 2 – x 1 – 2 – 1 = – 1 – 1 0 – 1 Course 3 11-2 Slope of a Line
44. Something you need to remember: Parallel lines have the same slope . The slopes of two perpendicular lines are negative reciprocals of each other. Course 3 11-2 Slope of a Line
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46. Parallel and Perpendicular Lines by Slope line 1: (–6, 4) and (2, –5) line 2: (–1, –4) and (8, 4) slope of line 1: slope of line 2: Line 1 has a slope equal to – and line 2 has a slope equal to , – and are negative reciprocals of each other, so the lines are perpendicular. 9 8 8 9 8 9 9 8 = y 2 – y 1 x 2 – x 1 – 9 8 = – 5 – 4 2 – (–6) 4 – (–4) 8 – (–1) = y 2 – y 1 x 2 – x 1 8 9 = 9 8 = – Course 3 11-2 Slope of a Line
47. Parallel and Perpendicular Lines by Slope line 1: (0, 5) and (6, –2) line 2: (–1, 3) and (5, –4) slope of line 1: slope of line 2: Both lines have a slope equal to – , so the lines are parallel. 7 6 = y 2 – y 1 x 2 – x 1 – 7 6 = – 2 – 5 6 – 0 = y 2 – y 1 x 2 – x 1 7 6 = – – 7 6 = 7 6 = – – 4 – 3 5 – (–1) Course 3 11-2 Slope of a Line
48. Try This line 1: (1, 1) and (2, 2) line 2: (1, –2) and (2, -1) Line 1 has a slope equal to 1 and line 2 has a slope equal to –1. 1 and –1 are negative reciprocals of each other, so the lines are perpendicular. slope of line 1: slope of line 2: = 1 = –1 = y 2 – y 1 x 2 – x 1 1 1 = 2 – 1 2 – 1 = y 2 – y 1 x 2 – x 1 – 1 1 = – 1 – (–2) 2 – (1) Course 3 11-2 Slope of a Line
49. Try This line 1: (–8, 2) and (0, –7) line 2: (–3, –6) and (6, 2) slope of line 1: slope of line 2: Line 1 has a slope equal to – and line 2 has a slope equal to , – and are negative reciprocals of each other, so the lines are perpendicular. 9 8 8 9 8 9 9 8 = y 2 – y 1 x 2 – x 1 – 9 8 = – 7 – 2 0 – (–8) 2 – (–6) 6 – (–3) = y 2 – y 1 x 2 – x 1 8 9 = 9 8 = – Course 3 11-2 Slope of a Line
50. Graphing a Line Using a Point and the Slope 2. Use the slope to count your units. Place another point once you get to the end. 3. Continue until you have enough point and then draw a line. 1. Plot the point given to you. Course 3 11-2 Slope of a Line
51. Graphing a Line Using a Point and the Slope Graph the line passing through (3, 1) with slope 2. Plot the point (3, 1). Then move 2 units up and right 1 unit and plot the point (4, 3). Use a straightedge to connect the two points. The slope is 2, or . So for every 2 units up, you will move right 1 unit, and for every 2 units down, you will move left 1 unit. 2 1 Course 3 11-2 Slope of a Line
53. Try This : Example 4 Graph the line passing through (1, 1) with slope 2. Plot the point (1, 1). Then move 2 units up and right 1 unit and plot the point (2, 3). Use a straightedge to connect the two points. The slope is 2, or . So for every 2 units up, you will move right 1 unit, and for every 2 units down, you will move left 1 unit. 2 1 Course 3 11-2 Slope of a Line
54. Try This : Example 4 Continued 1 2 (1, 1) Course 3 11-2 Slope of a Line
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56. Warm Up Find the slope of the line that passes through each pair of points. 1. (3, 6) and (-1, 4) 2. (1, 2) and (6, 1) 3. (4, 6) and (2, -1) 4. (-3, 0) and (-1, 1) Course 3 11-3 Using Slopes and Intercepts 1 2 - 1 5 7 2 1 2
58. Learn to use slopes and intercepts to graph linear equations. Course 3 11-3 Using Slopes and Intercepts
59. As you watch the video, take notes on your handout. Insert Lesson Title Here Course 3 11-3
60. One way to graph a linear equation easily is by finding the x -intercept and the y -intercept . The x -intercept is the value of x where the line crosses the x -axis ( y = 0). The y -intercept is the value of y where the line crosses the y -axis ( x = 0). Course 3 11-3 Using Intercepts
61. Find the x -intercept and y -intercept of the line 4 x – 3 y = 12. Use the intercepts to graph the equation. Example 1 Find the x -intercept ( y = 0). 4 x – 3 y = 12 4 x – 3 (0) = 12 4 x = 12 x = 3 The x -intercept is 3. 4 x 4 12 4 = Course 3 11-3 Using Intercepts
62. Example 1 Continued Find the y -intercept ( x = 0). 4 x – 3 y = 12 4 (0) – 3 y = 12 – 3 y = 12 y = –4 The y -intercept is –4. -3 y -3 12 -3 = Course 3 11-3 Using Intercepts
63. 4 x – 3 y = 12 Crosses the x -axis at the point (3, 0) Crosses the y -axis at the point (0, –4) Course 3 11-3 Using Intercepts
64. Find the x -intercept and y -intercept of the line 8 x – 6 y = 48. Use the intercepts to graph the equation. Try This Find the x -intercept ( y = 0). 8 x – 6 y = 48 8 x – 6 (0) = 48 8 x = 48 x = 6 The x -intercept is 6 so the point is (6, 0). 8 x 8 48 8 = Course 3 11-3 Using Intercepts
65. Try This Find the y -intercept ( x = 0). 8 x – 6 y = 48 8(0) – 6 y = 48 – 6 y = 48 y = –8 The y -intercept is –6 so the point is (0, -8). -6 y -6 48 -6 = Course 3 11-3 Using Intercepts
66. Try This : Example 1 Continued The graph of 8 x – 6 y = 48 is the line that crosses the x -axis at the point (6, 0) and the y -axis at the point (0, –8). Course 3 11-3 Using Slopes and Intercepts
67. In an equation written in slope-intercept form , y = mx + b , m is the slope and b is the y -intercept. y = m x + b Slope y -intercept Course 3 11-3 Using Slopes and Intercepts
68. Using the Slope-Intercept Form 1. Isolate the y so that you equation is in y = m x +b form. 2. Slope will always be “m” (the number in front of x ). 3. The y-intercept will always be “b” (the number by itself). Write this point as (0,b) For an equation such as y = x – 6, write it as y = x + (–6) to read the y -intercept, –6. The point would be (0,-6) Helpful Hint Course 3 11-3 Using Slopes and Intercepts
69. Example 2 Write each equation in slope-intercept form, and then find the slope and y -intercept. A. 2 x + y = 3 2 x + y = 3 – 2 x –2 x Subtract 2x from both sides. y = 3 – 2 x y = –2 x + 3 The equation is in slope-intercept form. m = –2 b = 3 The slope of the line is –2, and the y -intercept is 3. Course 3 11-3 Using Slopes and Intercepts
70. More Examples B. 5 y = 3 x 5 y = 3 x Divide both sides by 5 to solve for y. The equation is in slope-intercept form. b = 0 The slope of the line is , and the y -intercept is 0. = x 3 5 5 y 5 y = x + 0 3 5 m = 3 5 3 5 Course 3 11-3 Using Slopes and Intercepts
71. More Examples C. 4 x + 3 y = 9 4 x + 3 y = 9 Subtract 4x from both sides. b = 3 – 4 x –4 x 3 y = –4 x + 9 Divide both sides by 3. The equation is in slope-intercept form. y =- x + 3 4 3 m =- 4 3 The slope of the line 4 x+ 3 y = 9 is – , and the y -intercept is 3. 4 3 = + – 4 x 3 3 y 3 9 3 Course 3 11-3 Using Slopes and Intercepts
72. Try This Write each equation in slope-intercept form, and then find the slope and y-intercept. A. 4 x + y = 4 – 4 x –4 x Subtract 4x from both sides. y = 4 – 4 x Rewrite to match slope-intercept form. y = –4 x + 4 The equation is in slope-intercept form. m = –4 b = 4 The slope of the line 4 x + y = 4 is –4, and the y -intercept is 4. Course 3 11-3 Using Slopes and Intercepts
73. Try This B. 7y = 2x 7 y = 2 x Divide both sides by 7 to solve for y. The equation is in slope-intercept form. b = 0 = x 2 7 7 y 7 y = x + 0 2 7 m = 2 7 The slope of the line 7 y = 2 x is , and the y -intercept is 0. 2 7 Course 3 11-3 Using Slopes and Intercepts
74. Try This C. 5 x + 4 y = 8 5 x + 4 y = 8 Subtract 5x from both sides. Rewrite to match slope-intercept form. b = 2 – 5 x –5 x 4 y = 8 – 5 x 5 x + 4 y = 8 Divide both sides by 4. The equation is in slope-intercept form. y =- x + 2 5 4 The slope of the line 5 x + 4 y = 8 is – , and the y -intercept is 2. 5 4 = + – 5 x 4 4 y 4 8 4 m =- 5 4 Course 3 11-3 Using Slopes and Intercepts
75. Additional Example 3: Entertainment Application A video club charges $8 to join, and $1.25 for each DVD that is rented. The linear equation y = 1.25 x + 8 represents the amount of money y spent after renting x DVDs. Graph the equation by first identifying the slope and y -intercept. y = 1.25 x + 8 The equation is in slope-intercept form. b = 8 m =1.25 Course 3 11-3 Using Slopes and Intercepts
76. Additional Example 3 Continued The slope of the line is 1.25, and the y -intercept is 8. The line crosses the y -axis at the point (0, 8) and moves up 1.25 units for every 1 unit it moves to the right. Course 3 11-3 Using Slopes and Intercepts
77. Try This : Example 3 A salesperson receives a weekly salary of $500 plus a commission of 5% for each sale. Total weekly pay is given by the equation S = 0.05 c + 500. Graph the equation using the slope and y -intercept. y = 0.05 x + 500 The equation is in slope-intercept form. b = 500 m =0.05 Course 3 11-3 Using Slopes and Intercepts
78. Try This : Example 3 Continued The slope of the line is 0.05, and the y -intercept is 500. The line crosses the y -axis at the point (0, 500) and moves up 0.05 units for every 1 unit it moves to the right. x y 500 1000 1500 2000 10,000 5000 15,000 Course 3 11-3 Using Slopes and Intercepts
79. Additional Example 4: Writing Slope-Intercept Form Write the equation of the line that passes through (3, –4) and (–1, 4) in slope-intercept form. Find the slope. The slope is –2. Choose either point and substitute it along with the slope into the slope-intercept form. y = mx + b 4 = –2 (–1) + b 4 = 2 + b Substitute –1 for x, 4 for y, and –2 for m. Simplify. = –2 4 – (–4) – 1 – 3 = y 2 – y 1 x 2 – x 1 8 – 4 = Course 3 11-3 Using Slopes and Intercepts
80. Additional Example 4 Continued Solve for b . Subtract 2 from both sides. Write the equation of the line, using –2 for m and 2 for b . 4 = 2 + b – 2 –2 2 = b y = –2 x + 2 Course 3 11-3 Using Slopes and Intercepts
81. Try This : Example 4 Write the equation of the line that passes through (1, 2) and (2, 6) in slope-intercept form. Find the slope. The slope is 4. Choose either point and substitute it along with the slope into the slope-intercept form. y = mx + b 2 = 4 (1) + b 2 = 4 + b Substitute 1 for x, 2 for y, and 4 for m. Simplify. = 4 6 – 2 2 – 1 = y 2 – y 1 x 2 – x 1 4 1 = Course 3 11-3 Using Slopes and Intercepts
82. Try This : Example 4 Continued Solve for b . Subtract 4 from both sides. Write the equation of the line, using 4 for m and –2 for b . 2 = 4 + b – 4 –4 – 2 = b y = 4 x – 2 Course 3 11-3 Using Slopes and Intercepts
84. Warm Up Problem of the Day Lesson Presentation 11-4 Point-Slope Form Course 3
85. Warm Up Write the equation of the line that passes through each pair of points in slope-intercept form. 1. (0, –3) and (2, –3) 2. (5, –3) and (5, 1) 3. (–6, 0) and (0, –2) 4. (4, 6) and (–2, 0) y = –3 x = 5 y = x + 2 Course 3 11-4 Point-Slope Form y = – x – 2 1 3
86. Problem of the Day Without using equations for horizontal or vertical lines, write the equations of four lines that form a square. Possible answer: y = x + 2, y = x – 2, y = – x + 2, y = – x – 2 Course 3 11-4 Point-Slope Form
87. Learn to find the equation of a line given one point and the slope. Course 3 11-4 Point-Slope Form
89. Point on the line ( x 1 , y 1 ) Point-slope form y – y 1 = m ( x – x 1 ) slope The point-slope of an equation of a line with slope m passing through ( x 1 , y 1 ) is y – y 1 = m ( x – x 1 ). Course 3 11-4 Point-Slope Form
90. Use the point-slope form of each equation to identify a point the line passes through and the slope of the line. A. y – 7 = 3( x – 4) Additional Example 1: Using Point-Slope Form to Identify Information About a Line y – y 1 = m ( x – x 1 ) y – 7 = 3 ( x – 4 ) m = 3 ( x 1 , y 1 ) = (4, 7) The line defined by y – 7 = 3( x – 4) has slope 3, and passes through the point (4, 7). The equation is in point-slope form. Read the value of m from the equation. Read the point from the equation. Course 3 11-4 Point-Slope Form
91. B. y – 1 = ( x + 6) Additional Example 1B: Using Point-Slope Form to Identify Information About a Line y – y 1 = m ( x – x 1 ) ( x 1 , y 1 ) = (–6, 1) Rewrite using subtraction instead of addition. 1 3 1 3 y – 1 = ( x + 6) y – 1 = [ x – ( –6 )] 1 3 m = 1 3 The line defined by y – 1 = ( x + 6) has slope , and passes through the point (–6, 1). 1 3 1 3 Course 3 11-4 Point-Slope Form
92. Use the point-slope form of each equation to identify a point the line passes through and the slope of the line. A. y – 5 = 2 ( x – 2) Try This : Example 1 y – y 1 = m ( x – x 1 ) y – 5 = 2 ( x – 2 ) m = 2 ( x 1 , y 1 ) = (2, 5) The line defined by y – 5 = 2( x – 2) has slope 2, and passes through the point (2, 5). The equation is in point-slope form. Read the value of m from the equation. Read the point from the equation. Course 3 11-4 Point-Slope Form
93. B. y – 2 = (x + 3) Try This : Example 1B ( x 1 , y 1 ) = (–3, 2) Rewrite using subtraction instead of addition. y – y 1 = m ( x – x 1 ) 2 3 2 3 y – 2 = ( x + 3 ) y – 2 = [ x – (–3)] 2 3 m = 2 3 The line defined by y – 2 = ( x + 3) has slope , and passes through the point (–3, 2). 2 3 2 3 Course 3 11-4 Point-Slope Form
94. Write the point-slope form of the equation with the given slope that passes through the indicated point. A. the line with slope 4 passing through (5, -2) Additional Example 2: Writing the Point-Slope Form of an Equation y – y 1 = m (x – x 1 ) The equation of the line with slope 4 that passes through (5, –2) in point-slope form is y + 2 = 4( x – 5). Substitute 5 for x 1 , –2 for y 1 , and 4 for m. [ y – ( –2 )] = 4 ( x – 5 ) y + 2 = 4( x – 5) Course 3 11-4 Point-Slope Form
95. B. the line with slope –5 passing through (–3, 7) Additional Example 2: Writing the Point-Slope Form of an Equation y – y 1 = m ( x – x 1 ) The equation of the line with slope –5 that passes through (–3, 7) in point-slope form is y – 7 = –5( x + 3). Substitute –3 for x 1 , 7 for y 1 , and –5 for m. y – 7 = -5[ x – ( –3 )] y – 7 = –5( x + 3) Course 3 11-4 Point-Slope Form
96. Write the point-slope form of the equation with the given slope that passes through the indicated point. A. the line with slope 2 passing through (2, –2) Try This : Example 2A y – y 1 = m (x – x 1 ) The equation of the line with slope 2 that passes through (2, –2) in point-slope form is y + 2 = 2( x – 2). Substitute 2 for x 1 , –2 for y 1 , and 2 for m. [ y – ( –2 )] = 2 ( x – 2 ) y + 2 = 2( x – 2) Course 3 11-4 Point-Slope Form
97. B. the line with slope -4 passing through (-2, 5) Try This : Example 2B y – y 1 = m ( x – x 1 ) The equation of the line with slope –4 that passes through (–2, 5) in point-slope form is y – 5 = –4( x + 2). Substitute –2 for x 1 , 5 for y 1 , and –4 for m. y – 5 = –4[ x – ( –2 )] y – 5 = –4( x + 2) Course 3 11-4 Point-Slope Form
98. A roller coaster starts by ascending 20 feet for every 30 feet it moves forward. The coaster starts at a point 18 feet above the ground. Write the equation of the line that the roller coaster travels along in point-slope form, and use it to determine the height of the coaster after traveling 150 feet forward. Assume that the roller coaster travels in a straight line for the first 150 feet. Additional Example 3: Entertainment Application As x increases by 30, y increases by 20, so the slope of the line is or . The line passes through the point (0, 18). 20 30 2 3 Course 3 11-4 Point-Slope Form
99. Additional Example 3 Continued y – y 1 = m ( x – x 1 ) y – 18 = 100 y = 118 The value of y is 118, so the roller coaster will be at a height of 118 feet after traveling 150 feet forward. Substitute 0 for x 1 , 18 for y 1 , and for m. 2 3 The equation of the line the roller coaster travels along, in point-slope form, is y – 18 = x . Substitute 150 for x to find the value of y . 2 3 y – 18 = ( 150 ) 2 3 y – 18 = ( x – 0 ) 2 3 Course 3 11-4 Point-Slope Form
100. Try This: Example 3 A roller coaster starts by ascending 15 feet for every 45 feet it moves forward. The coaster starts at a point 15 feet above the ground. Write the equation of the line that the roller coaster travels along in point-slope form, and use it to determine the height of the coaster after traveling 300 feet forward. Assume that the roller coaster travels in a straight line for the first 300 feet. As x increases by 45, y increases by 15, so the slope of the line is or . The line passes through the point (0, 15). 15 45 1 3 Course 3 11-4 Point-Slope Form
101. Try This : Example 3 Continued y – y 1 = m ( x – x 1 ) y – 15 = 100 y = 115 The value of y is 115, so the roller coaster will be at a height of 115 feet after traveling 300 feet forward. Substitute 0 for x 1 , 15 for y 1 , and for m. 1 3 The equation of the line the roller coaster travels along, in point-slope form, is y – 15 = x . Substitute 300 for x to find the value of y . 1 3 y – 15 = ( 300 ) 1 3 y – 15 = ( x – 0 ) 1 3 Course 3 11-4 Point-Slope Form
102. Warm Up Problem of the Day Lesson Presentation 11-5 Direct Variation Course 3
103. Warm Up Use the point-slope form of each equation to identify a point the line passes through and the slope of the line. 1. y – 3 = – ( x – 9) 2. y + 2 = ( x – 5) 3. y – 9 = –2( x + 4) 4. y – 5 = – ( x + 7) (–4, 9), –2 Course 3 11-5 Direct Variation 1 7 2 3 1 4 (9, 3), – 1 7 (5, –2), 2 3 (–7, 5), – 1 4
104. Problem of the Day Where do the lines defined by the equations y = –5 x + 20 and y = 5 x – 20 intersect? (4, 0) Course 3 11-5 Direct Variation
105. Learn to recognize direct variation by graphing tables of data and checking for constant ratios. Course 3 11-5 Direct Variation
106. Vocabulary direct variation constant of proportionality Insert Lesson Title Here Course 3 11-5 Direct Variation
108. Course 3 11-5 Direct Variation The graph of a direct-variation equation is always linear and always contains the point (0, 0). The variables x and y either increase together or decrease together. Helpful Hint
109. Determine whether the data set shows direct variation. A. Additional Example 1A: Determining Whether a Data Set Varies Directly Course 3 11-5 Direct Variation
110. Make a graph that shows the relationship between Adam’s age and his length. Additional Example 1A Continued Course 3 11-5 Direct Variation
111. You can also compare ratios to see if a direct variation occurs. 81 264 81 ≠ 264 The ratios are not proportional. The relationship of the data is not a direct variation. Additional Example 1A Continued 22 3 27 12 = ? Course 3 11-5 Direct Variation
112. Determine whether the data set shows direct variation. B. Additional Example 1B: Determining Whether a Data Set Varies Directly Course 3 11-5 Direct Variation
113. Make a graph that shows the relationship between the number of minutes and the distance the train travels. Additional Example 1B Continued Plot the points. The points lie in a straight line. (0, 0) is included. Course 3 11-5 Direct Variation
114. You can also compare ratios to see if a direct variation occurs. The ratios are proportional. The relationship is a direct variation. = = = Compare ratios. Additional Example 1B Continued 25 10 50 20 75 30 100 40 Course 3 11-5 Direct Variation
115. Determine whether the data set shows direct variation. A. Try This : Example 1A 0 3 5 Number of Baskets 40 30 20 Distance (ft) Kyle's Basketball Shots Course 3 11-5 Direct Variation
116. Make a graph that shows the relationship between number of baskets and distance. Try This : Example 1A Continued Number of Baskets Distance (ft) 2 3 4 20 30 40 1 5 Course 3 11-5 Direct Variation
117. You can also compare ratios to see if a direct variation occurs. Try This : Example 1A 60 150 150 60. The ratios are not proportional. The relationship of the data is not a direct variation. 5 20 3 30 = ? Course 3 11-5 Direct Variation
118. Determine whether the data set shows direct variation. B. Try This : Example 1B Cup (c) Ounces (oz) 4 3 2 1 32 24 16 8 Ounces in a Cup Course 3 11-5 Direct Variation
119. Make a graph that shows the relationship between ounces and cups. Try This : Example 1B Continued Plot the points. The points lie in a straight line. (0, 0) is included. Number of Cups Number of Ounces 2 3 4 8 16 24 1 32 Course 3 11-5 Direct Variation
120. You can also compare ratios to see if a direct variation occurs. Try This : Example 1B Continued The ratios are proportional. The relationship is a direct variation. Compare ratios. Course 3 11-5 Direct Variation = 1 8 = = 2 16 3 24 4 32
121. Find each equation of direct variation, given that y varies directly with x. A. y is 54 when x is 6 Additional Example 2A: Finding Equations of Direct Variation y = kx 54 = k 6 9 = k y = 9 x y varies directly with x. Substitute for x and y. Solve for k. Substitute 9 for k in the original equation. Course 3 11-5 Direct Variation
122. B. x is 12 when y is 15 Additional Example 2B: Finding Equations of Direct Variation y = kx 15 = k 12 y varies directly with x. Substitute for x and y. Solve for k. = k 5 4 Substitute for k in the original equation. 5 4 y = k 5 4 Course 3 11-5 Direct Variation
123. C. y is 8 when x is 5 Additional Example 2C: Finding Equations of Direct Variation y = kx 8 = k 5 y varies directly with x. Substitute for x and y. Solve for k. = k 8 5 Substitute for k in the original equation. 8 5 y = k 8 5 Course 3 11-5 Direct Variation
124. Find each equation of direct variation, given that y varies directly with x. A. y is 24 when x is 4 Try This : Example 2A y = kx 24 = k 4 6 = k y = 6 x y varies directly with x. Substitute for x and y. Solve for k. Substitute 6 for k in the original equation. Course 3 11-5 Direct Variation
125. B. x is 28 when y is 14 Try This : Example 2B y = kx 14 = k 28 y varies directly with x. Substitute for x and y. Solve for k. = k 1 2 Substitute for k in the original equation. 1 2 y = k 1 2 Course 3 11-5 Direct Variation
126. C. y is 7 when x is 3 Try This : Example 2C y = kx 7 = k 3 y varies directly with x. Substitute for x and y. Solve for k. = k 7 3 Substitute for k in the original equation. 7 3 y = k 7 3 Course 3 11-5 Direct Variation
127. Mrs. Perez has $4000 in a CD and $4000 in a money market account. The amount of interest she has earned since the beginning of the year is organized in the following table. Determine whether there is a direct variation between either of the data sets and time. If so, find the equation of direct variation. Additional Example 3: Money Application Course 3 11-5 Direct Variation
128. Additional Example 3 Continued A. interest from CD and time The second and third pairs of data result in a common ratio. In fact, all of the nonzero interest from CD to time ratios are equivalent to 17. The variables are related by a constant ratio of 17 to 1, and (0, 0) is included. The equation of direct variation is y = 17 x , where x is the time, y is the interest from the CD, and 17 is the constant of proportionality. interest from CD time = 17 1 interest from CD time = = 17 34 2 = = = 17 interest from CD time = = 17 1 34 2 51 3 68 4 Course 3 11-5 Direct Variation
129. Additional Example 3 Continued B. interest from money market and time 19 ≠ 18.5 If any of the ratios are not equal, then there is no direct variation. It is not necessary to compute additional ratios or to determine whether (0, 0) is included. interest from money market time = = 19 19 1 interest from money market time = =18.5 37 2 Course 3 11-5 Direct Variation
130. Mr. Ortega has $2000 in a CD and $2000 in a money market account. The amount of interest he has earned since the beginning of the year is organized in the following table. Determine whether there is a direct variation between either of the data sets and time. If so, find the equation of direct variation. Try This : Example 3 Course 3 11-5 Direct Variation
131. Try This : Example 3 Continued 50 50 4 45 40 3 40 30 2 15 12 1 0 0 0 Money Market ($) from CD ($) Time (mo) Interest from Interest Course 3 11-5 Direct Variation
132. Try This : Example 3 Continued The second and third pairs of data do not result in a common ratio. If any of the ratios are not equal, then there is no direct variation. It is not necessary to compute additional ratios or to determine whether (0, 0) is included. A. interest from CD and time interest from CD time = 12 1 interest from CD time = = 15 30 2 Course 3 11-5 Direct Variation
133. Try This: Example 3 Continued B. interest from money market and time 15 ≠ 20 If any of the ratios are not equal, then there is no direct variation. It is not necessary to compute additional ratios or to determine whether (0, 0) is included. interest from money market time = = 15 15 1 interest from money market time = =20 40 2 Course 3 11-5 Direct Variation
134. Warm Up Problem of the Day Lesson Presentation 11-6 Graphing Inequalities in Two Variables Course 3
135. Warm Up Find each equation of direct variation, given that y varies directly with x . 1. y is 18 when x is 3. 2. x is 60 when y is 12. 3. y is 126 when x is 18. 4. x is 4 when y is 20. y = 6 x y = 7 x y = 5 x Course 3 11-6 Graphing Inequalities in Two Variables y = x 1 5
136. Problem of the Day The circumference of a pizza varies directly with its diameter. If you graph that direct variation, what will the slope be? Course 3 11-6 Graphing Inequalities in Two Variables
137. Learn to graph inequalities on the coordinate plane. Course 3 11-6 Graphing Inequalities in Two Variables
138. Vocabulary boundary line linear inequality Insert Lesson Title Here Course 3 11-6 Graphing Inequalities in Two Variables
139. A graph of a linear equation separates the coordinate plane into three parts: the points on one side of the line, the points on the boundary line , and the points on the other side of the line. Course 3 11-6 Graphing Inequalities in Two Variables
140. Course 3 11-6 Graphing Inequalities in Two Variables
141. When the equality symbol is replaced in a linear equation by an inequality symbol, the statement is a linear inequality . Any ordered pair that makes the linear inequality true is a solution. Course 3 11-6 Graphing Inequalities in Two Variables
142. Graph each inequality. A. y < x – 1 Additional Example 1A: Graphing Inequalities First graph the boundary line y = x – 1. Since no points that are on the line are solutions of y < x – 1, make the line dashed . Then determine on which side of the line the solutions lie. (0, 0) y < x – 1 Test a point not on the line. Substitute 0 for x and 0 for y. 0 < 0 – 1 ? 0 < –1 ? Course 3 11-6 Graphing Inequalities in Two Variables
143. Additional Example 1A Continued Since 0 < –1 is not true, (0, 0) is not a solution of y < x – 1. Shade the side of the line that does not include (0, 0). Course 3 11-6 Graphing Inequalities in Two Variables
144. B. y 2 x + 1 Additional Example 1B: Graphing Inequalities First graph the boundary line y = 2 x + 1. Since points that are on the line are solutions of y 2 x + 1, make the line solid . Then shade the part of the coordinate plane in which the rest of the solutions of y 2 x + 1 lie. (0, 4) Choose any point not on the line. Substitute 0 for x and 4 for y. y ≥ 2 x + 1 4 ≥ 0 + 1 ? Course 3 11-6 Graphing Inequalities in Two Variables
145. Additional Example 1B Continued Since 4 1 is true, (0, 4) is a solution of y 2 x + 1. Shade the side of the line that includes (0, 4). Course 3 11-6 Graphing Inequalities in Two Variables
146. C. 2 y + 5 x < 6 Additional Example 1C: Graphing Inequalities First write the equation in slope-intercept form. 2 y < –5 x + 6 2 y + 5 x < 6 Subtract 5x from both sides. Divide both sides by 2. y < – x + 3 5 2 Then graph the line y = – x + 3. Since points that are on the line are not solutions of y < – x + 3, make the line dashed. Then determine on which side of the line the solutions lie. 5 2 5 2 Course 3 11-6 Graphing Inequalities in Two Variables
147. Additional Example 1C Continued (0, 0) Choose any point not on the line. Since 0 < 3 is true, (0, 0) is a solution of y < – x + 3. Shade the side of the line that includes (0, 0). 5 2 y < – x + 3 5 2 0 < 0 + 3 ? 0 < 3 ? Course 3 11-6 Graphing Inequalities in Two Variables
148. Graph each inequality. A. y < x – 4 Try This : Example 1A First graph the boundary line y = x – 4. Since no points that are on the line are solutions of y < x – 4, make the line dashed . Then determine on which side of the line the solutions lie. (0, 0) y < x – 4 Test a point not on the line. Substitute 0 for x and 0 for y. 0 < 0 – 4 ? 0 < –4 ? Course 3 11-6 Graphing Inequalities in Two Variables
149. Try This : Example 1A Continued Since 0 < –4 is not true, (0, 0) is not a solution of y < x – 4. Shade the side of the line that does not include (0, 0). Course 3 11-6 Graphing Inequalities in Two Variables
150. B. y > 4 x + 4 Try This : Example 1B First graph the boundary line y = 4 x + 4. Since points that are on the line are solutions of y 4 x + 4, make the line solid . Then shade the part of the coordinate plane in which the rest of the solutions of y 4 x + 4 lie. (2, 3) Choose any point not on the line. Substitute 2 for x and 3 for y. y ≥ 4 x + 4 3 ≥ 8 + 4 ? Course 3 11-6 Graphing Inequalities in Two Variables
151. Try This : Example 1B Continued Since 3 12 is not true, (2, 3) is not a solution of y 4 x + 4. Shade the side of the line that does not include (2, 3). Course 3 11-6 Graphing Inequalities in Two Variables
152. C. 3 y + 4 x 9 Try This : Example 1C First write the equation in slope-intercept form. 3 y –4 x + 9 3 y + 4 x 9 Subtract 4x from both sides. Divide both sides by 3. y – x + 3 4 3 4 3 Then graph the line y = – x + 3. Since points that are on the line are solutions of y – x + 3, make the line solid. Then determine on which side of the line the solutions lie. 4 3 Course 3 11-6 Graphing Inequalities in Two Variables
153. Try This : Example 1C Continued (0, 0) Choose any point not on the line. Since 0 3 is not true, (0, 0) is not a solution of y – x + 3. Shade the side of the line that does not include (0, 0). 4 3 y – x + 3 4 3 0 0 + 3 ? 0 3 ? Course 3 11-6 Graphing Inequalities in Two Variables
154. A successful screenwriter can write no more than seven and a half pages of dialogue each day. Graph the relationship between the number of pages the writer can write and the number of days. At this rate, would the writer be able to write a 200-page screenplay in 30 days? Additional Example 2: Career Application First find the equation of the line that corresponds to the inequality. In 0 days the writer writes 0 pages. point (0, 0) point (1, 7.5) In 1 day the writer writes no more than 7 pages. 1 2 Course 3 11-6 Graphing Inequalities in Two Variables
155. Additional Example 2 Continued With two known points, find the slope. y 7.5 x + 0 The y-intercept is 0. No more than means . Graph the boundary line y = 7.5 x . Since points on the line are solutions of y 7.5 x make the line solid. Shade the part of the coordinate plane in which the rest of the solutions of y 7.5 x lie. Course 3 11-6 Graphing Inequalities in Two Variables m = 7.5 – 0 1 – 0 7.5 1 = = 7.5
156. (2, 2) Choose any point not on the line. y 7.5 x Substitute 2 for x and 2 for y. Since 2 15 is true, (2, 2) is a solution of y 7.5 x . Shade the side of the line that includes point (2, 2). Additional Example 2 Continued 2 7.5 2 ? 2 15 ? Course 3 11-6 Graphing Inequalities in Two Variables
157. The point (30, 200) is included in the shaded area, so the writer should be able to complete the 200 page screenplay in 30 days. Additional Example 2 Continued Course 3 11-6 Graphing Inequalities in Two Variables
158. A certain author can write no more than 20 pages every 5 days. Graph the relationship between the number of pages the writer can write and the number of days. At this rate, would the writer be able to write 140 pages in 20 days? Try This : Example 2 First find the equation of the line that corresponds to the inequality. In 0 days the writer writes 0 pages. point (0, 0) point (5, 20) In 5 days the writer writes no more than 20 pages. Course 3 11-6 Graphing Inequalities in Two Variables
159. Try This : Example 2 Continued With two known points, find the slope. y 4 x + 0 The y-intercept is 0. No more than means . Graph the boundary line y = 4 x . Since points on the line are solutions of y 4 x make the line solid. Shade the part of the coordinate plane in which the rest of the solutions of y 4 x lie. 20 - 0 5 - 0 m = = 20 5 = 4 Course 3 11-6 Graphing Inequalities in Two Variables
160. (5, 60) Choose any point not on the line . y 4 x Substitute 5 for x and 60 for y. Since 60 20 is not true, (5, 60) is not a solution of y 4 x . Shade the side of the line that does not include (5, 60). Try This : Example 2 Continued 60 4 5 ? 60 20 ? Course 3 11-6 Graphing Inequalities in Two Variables
161. The point (20, 140) is not included in the shaded area, so the writer will not be able to write 140 pages in 20 days. Try This : Example 2 Continued x y 200 180 160 140 120 100 80 60 40 20 Pages 5 10 15 20 25 30 35 40 45 50 Days Course 3 11-6 Graphing Inequalities in Two Variables
162. Warm Up Problem of the Day Lesson Presentation 11-7 Lines of Best Fit Course 3
163. Warm Up Answer the questions about the inequality 5 x + 10 y > 30. 1. Would you use a solid or dashed boundary line? 2. Would you shade above or below the boundary line? 3. What are the intercepts of the graph? dashed above (0, 3) and (6, 0) Course 3 11-7 Lines of Best Fit
164. Problem of the Day Write an inequality whose positive solutions form a triangular region with an area of 8 square units. ( Hint : Sketch such a region on a coordinate plane.) Possible answer: y < – x + 4 Course 3 11-7 Lines of Best Fit
165. Learn to recognize relationships in data and find the equation of a line of best fit. Course 3 11-7 Lines of Best Fit
166.
167. Plot the data and find a line of best fit. Additional Example 1: Finding a Line of Best Fit Plot the data points and find the mean of the x - and y -coordinates. Course 3 11-7 Lines of Best Fit x m = = 6 4 + 7 + 3 + 8 + 8 + 6 6 y m = = 4 4 + 5 + 2 + 6 + 7 + 4 6 2 3 4 7 6 2 5 4 y 6 8 8 3 7 4 x 2 3 ( x m , y m )= 6 , 4
168. Course 3 11-7 Lines of Best Fit The line of best fit is the line that comes closest to all the points on a scatter plot. Try to draw the line so that about the same number of points are above the line as below the line. Remember!
169. Additional Example 1 Continued Course 3 11-7 Lines of Best Fit Draw a line through 6 , 4 that best represents the data. Estimate and plot the coordinates of another point on that line, such as (8, 6). Find the equation of the line. 2 3
170. Find the slope. y – y 1 = m ( x – x 1 ) Use point-slope form. Substitute. Additional Example 1 Continued Course 3 11-7 Lines of Best Fit y – 4 = ( x – 6 ) 2 3 2 3 y – 4 = x – 4 2 3 2 3 2 3 y = x + 2 3 The equation of a line of best fit is . 2 3 y = x + 2 3 2 3 1 3 m = = = 6 – 4 8 – 6 1 2 2 3
171. Plot the data and find a line of best fit. Try This : Example 1 Plot the data points and find the mean of the x - and y -coordinates. ( x m , y m ) = (2 , 1 ) Course 3 11-7 Lines of Best Fit x m = = 2 – 1 + 0 + 2 + 6 + –3 + 8 6 y m = = 1 – 1 + 0 + 3 + 7 + –7 + 4 6 4 – 7 7 3 0 – 1 y 8 – 3 6 2 0 – 1 x
172. Try This : Example 1 Continued Draw a line through ( 2 , 1 ) that best represents the data. Estimate and plot the coordinates of another point on that line, such as (10, 10). Find the equation of the line. Course 3 11-7 Lines of Best Fit
173. Find the slope. y – y 1 = m ( x – x 1 ) Use point-slope form. Substitute. Try This : Example 1 Continued Course 3 11-7 Lines of Best Fit y – 1 = ( x – 2 ) 9 8 y – 1 = x – 9 8 9 4 The equation of a line of best fit is . y = x – 9 8 5 4 m = = 10 – 1 10 – 2 9 8 y = x – 9 8 5 4
174. Find a line of best fit for the Main Street Elementary annual softball toss. Use the equation of the line to predict the winning distance in 2006. Additional Example 2: Sports Application Let 1990 represent year 0. The first point is then (0, 98), and the last point is (12, 107). ( x m , y m ) = ( 5 , 103 ) Course 3 11-7 Lines of Best Fit x m = = 5 0 + 2 + 4 + 7 + 12 5 107 106 103 101 98 Distance (ft) 2002 1997 1994 1992 1990 Year y m = = 103 98 + 101 + 103 + 106 + 107 5
175. Additional Example 2 Continued Draw a line through ( 5 , 103 ) that best represents the data. Estimate and plot the coordinates of another point on that line, such as (10, 107). Find the equation of the line. Course 3 11-7 Lines of Best Fit
176. Find the slope. y – y 1 = m ( x – x 1 ) Use point-slope form. y – 103 = 0.8 ( x – 5 ) Substitute. y – 103 = 0.8 x – 4 y = 0.8 x + 99 The equation of a line of best fit is y = 0.8 x + 99. Since 1990 represents year 0, 2006 represents year 16. Additional Example 2 Continued Course 3 11-7 Lines of Best Fit m = = 0.8 107 - 103 10 - 5
177. Substitute. y = 12.8 + 99 y = 0.8 (16) + 99 The equation predicts a winning distance of about 112 feet for the year 2006. y = 111.8 Additional Example 2 Continued Course 3 11-7 Lines of Best Fit
178. Predict the winning weight lift in 2010. Try This : Example 2 Let 1990 represent year 0. The first point is then (0, 100), and the last point is (10, 170). ( x m , y m ) = ( 6 , 132 ) Course 3 11-7 Lines of Best Fit x m = = 6 0 + 5 + 7 + 8 + 10 5 y m = = 132 100 + 120 + 130 + 140 + 170 5 170 140 130 120 100 Lift (lb) 2000 1998 1997 1995 1990 Year
179. Try This : Example 2 Continued Draw a line through ( 5 , 132 ) the best represents the data. Estimate and plot the coordinates of another point on that line, such as (7, 140). Find the equation of the line. Course 3 11-7 Lines of Best Fit Years since 1990 weight (lb) 0 100 120 140 160 180 2 4 6 8 10 200
180. Find the slope. y – y 1 = m ( x – x 1 ) Use point-slope form. y – 132 = 4 ( x – 5 ) Substitute. y – 132 = 4 x – 20 y = 4 x + 112 The equation of a line of best fit is y = 4 x + 112. Since 1990 represents year 0, 2010 represents year 20. Try This : Example 2 Continued Course 3 11-7 Lines of Best Fit m = = 4 140 – 132 7 – 5
181. Substitute. y = 192 y = 4 (20) + 112 The equation predicts a winning lift of about 192 lb for the year 2010. Try This : Example 2 Continued Course 3 11-7 Lines of Best Fit