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Chapter 2

Chapter 2. Graphing Linear Relations and Functions. By Kathryn Valle. 2-1 Relations and Functions. A set of ordered pairs forms a relation . Example: {(2, 4) (0, 3) (4, -2) (-1, -8)}

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Chapter 2

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  1. Chapter 2 Graphing Linear Relations and Functions By Kathryn Valle

  2. 2-1 Relations and Functions • A set of ordered pairs forms a relation. • Example: {(2, 4) (0, 3) (4, -2) (-1, -8)} • The domain is the set of all the first coordinates (x-coordinate) and the range is the set of all the second coordinates (y-coordinate). • Example: domain: {2, 0, 4, -1} and range: {4, 3, -2, -8} • Mapping shows how each member of the domain and range are paired. • Example: 1 9 4 3 -3 2 1 0 7 -5 -2 -6 7

  3. 2-1 Relations and Functions (cont.) • A function is a relation where an element from the domain is paired with only one element from the range. • Example (from mapping example): The first is a function, but the second is not because the 1 is paired with both the 3 and the 0. • If you can draw a vertical line everywhere through the graph of a relation and that line only intersects the graph at one point, then you have a function.

  4. 2-1 Relations and Functions (cont.) • A discrete function consists of individual points that are not connected. • When the domain of a function can be graphed with a smooth line or curve, then the function is called continuous.

  5. 2-1 Practice • Find the domain and range of the following: • {(3, 6) (-1, 5) (0, -2)} • {(4, 1) (1, 0) (3, 1) (1, -2)} • Are the following functions? If yes, are they discrete or continuous? • {(2, 2) (3, 6) (-2, 0) (0, 5)} c. y = 8x2 + 4 • {(9, 3) (8, -1) (9, 0) (9, 1) (0, -4)} Answers: 1)a) domain: {3, -1, 0} range: {6, 5, -2} b) domain: {4, 1, 3} range: {1, 0, -2} 2)a) function; discrete b) not a function c) function; continuous

  6. 2-2 Linear Equations • A linear equation is an equation whose graph is a straight line. The standard form of a linear equation is: Ax + By = C, where A, B, and C are all integers and A and B cannot both be 0. • Linear functions have the form f(x) = mx + b, where m and b are real numbers. • A constant function has a graph that is a straight, horizontal line. The equation has the form f(x) = b

  7. 2-2 Linear Equations (cont.) • The point on the graph where the line crosses the y-axis is called the y-intercept. • Example: find the y-intercept of 4x – 3y = 6 4(0) – 3y = 6  substitute 0 for x y = -2, so the graph crosses the y-axis at the point (0, -2) • The point on the graph where the line crosses the x-axis is called the x-intercept. • Example: find the x-intercept of 3x + 5y = 9 3x + 5(0) = 9  substitute 0 for y x = 3, so the graph crosses the x-axis at the point (3, 0)

  8. 2-2 Practice • Determine if the following are linear equations. If so, write the equation in standard form and determine A, B, and C. • 4x + 3y = 10 c. 5 – 3y = 8x • x2 + y = 2 d. 1/x + 4y = -5 • Find the x- and y-intercepts of the following: • 4x – 3y = -12 • ½ y + 2 = ½ x Answers: 1)a) yes; A = 4, B = 3, C = 10 b) no c) yes; A = 8, B = 3, C = 5 d) no 2)a) x-intercept: -3 y-intercept: 4 b) x-intercept: 4 y-intercept: -4

  9. 2-3 Slope • The slope of a line is the change in y over the change in x. • If a line passes through the points (x1, y1) and (x2, y2), then the slope is given by m = y2 – y1 , where x1 ≠ x2. x2 – x1 • In an equation with the from y = mx + b, m is the slope and b is the y-intercept. • Two lines with the same slope are parallel. • If the product of the slopes of two lines is -1, then the lines are perpendicular.

  10. 2-3 Practice • Find the slope of the following: • (-2, 4) (3, -6) d. (-1, 8) (14, 8) • (3.5, -2) (0, -16) e. 12x + 3y – 6 = 0 • y = 3x + b f. y = -7 • Determine whether the following lines are perpendicular or parallel by finding the slope. • (4, -2) (6, 0), (7, 3) (6, 2) • y = 2x – 3, (6, 6) (4, 7) Answers: 1)a) -2 b) 4 c) 3 d) 0 e) -4 f) 0 2)a) 1; parallel b) -1; perpendicular

  11. 2-4 Writing Linear Equations • The form y = mx + b is called slope-intercept form, where m is the slope and b is the y-intercept. • The point-slope form of the equation of a line is y – y1 = m(x – x1). Here (x1, y1) are the coordinates of any point found on that line.

  12. 2-4 Writing Linear Equations • Example: Find the slope-intercept form of the equation passing through the point (-3, 5) with a slope of 2. y = mx + b 5 = (2)(-3) + b 5 = -6 + b b = 11 y = 2x + 11

  13. 2-4 Writing Linear Equations • Example: Find the point-slope form of the equation of a line that passes through the points (1, -5) and (0, 4). m = y2 – y1y – y1 = m(x – x1) x2 – x1 y – (-5) = (-1)(x – 1) m = 4 + 5 y + 5 = -x + 1 0 – 1 y = -x – 4 m = 9 -1 m = -1

  14. 2-4 Practice • Find the slope-intercept form of the following: • a line passing through the point (0, 5) with a slope of -7 • a line passing through the points (-2, 4) and (3, 14) • Find the point-slope form of the following: • a line passing through the point (-2, 6) with a slope of 3 • a line passing through the points (0, -9) and (-2, 1) Answers: 1)a) y = -7x + 5 b) y = 2x + 8 2)a) y = 3x + 12 b) y = -5x -9

  15. 2-5 Modeling Real-World Data Using Scatter Plots • Plotting points that do not form a straight line forms a scatter plot. • The line that best represents the points is the best-fit line. • A prediction equation uses points on the scatter plot to approximate through calculation the equation of the best-fit line.

  16. 2-5 Practice • Plot the following data. Approximate the best-fit line by creating a prediction equation. Answers: 1) y = 4x + 11

  17. 2-6 Special Functions • Whenever a linear function has the form y = mx + b and b = 0 and m ≠ 0, it is called a direction variation. • A constant function is a linear function in the form y = mx + b where m = 0. • An identity function is a linear function in the form y = mx + b where m = 1 and b = 0.

  18. 2-6 Special Functions • Step functions are functions depicted in graphs with open circles which mean that the particular point is not included. • Example:

  19. 2-6 Special Functions • A type of step function is the greatest integer function which is symbolized as [x] and means “the greatest integer not greater than x.” • Examples: [8.2] = 8 [3.9] = 3 [5.0] = 5 [7.6] = 7 • An absolute value function is the graph of the function that represents an absolute value. • Examples: |-4| = 4 |-9| = 9

  20. 2-6 Practice • Identify each of the following as constant, identity, direct variation, absolute value, or greatest integer function • h(x) = [x – 6] e. f(x) = 3|-x + 1| • f(x) = -½ x f. g(x) = x • g(x) = |2x| g. h(x) = [2 + 5x] • h(x) = 7 h. f(x) = 9x • Graph the equation y = |x – 6|

  21. 2-6 Answers • Answers: 1)a) greatest integer function b) direct variation c) absolute value d) constant e) absolute value f) identity g) greatest integer function h) direct variation 2)

  22. 2-7 Linear Inequalities • Example: Graph 2y – 8x ≥ 4 • Graph the “equals” part of the equation. 2y – 8x = 4 2y = 8x + 4 y = 4x + 2 x-intercept 0 = 4x + 2 -2 = 4x -1/2 = x y-intercept y = 4(0) +2 y = 2

  23. 2-7 Linear Inequalities • Use “test points” to determine which side of the line should be shaded. (2y – 8x ≥ 4) (-2, 2) 2(2) – 8(-2) ≥ 4 4 – (-16) ≥ 4 20 ≥ 4  true (0, 0) 2(0) – 8(0) ≥ 4 0 – 0 ≥ 4 0 ≥ 4  false • So we shade the side of the line that includes the “true” point, (-2, 2)

  24. 2-7 Linear Inequalities • Example: Graph 12 < -3y – 9x • Graph the line. 12 ≠ -3y – 9x 3y ≠ -9x – 12 y ≠ -3x – 4 x-intercept 0 = -3x – 4 4 = -3x -4/3 = x y-intercept y = 3(0) – 4 y = -4

  25. 2-7 Linear Inequalities • Use “test points” to determine which side of the line should be shaded. (12 < -3y – 9x) (-3, -3) 12 < -3(-3) – 9(-3) 12 < 9 + 27 12 < 36  true (0, 0) 12 < -3(0) – 9(0) 12 < 0 – 0 12 < 0  false • So we shade the side of the line that includes the “true” point, (-3, -3)

  26. 2-7 Problems • Graph each inequality. • 2x > y – 4 e. 2y ≥ 6|x| • 5 ≥ y f. 42x > 7y • 4 < -2y g. |x| < y + 2 • y ≤ |x| + 3 h. x – 4 ≤ 8y

  27. 2-7 Answers 1)a) b) c) d)

  28. 2-7 Answers 1)e) f) g) h)

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