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 Lesson 1: 2.1 Symmetry (3-1)  Lesson 2: 2.2 Graph Families (3-2, 3-3) Lesson 2:  Lesson 3: 2.3 Inverses (3-4) Lesson 3:  Lesson 4: 2.4 Continuity.

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Presentation on theme: " Lesson 1: 2.1 Symmetry (3-1)  Lesson 2: 2.2 Graph Families (3-2, 3-3) Lesson 2:  Lesson 3: 2.3 Inverses (3-4) Lesson 3:  Lesson 4: 2.4 Continuity."— Presentation transcript:

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2  Lesson 1: 2.1 Symmetry (3-1)  Lesson 2: 2.2 Graph Families (3-2, 3-3) Lesson 2:  Lesson 3: 2.3 Inverses (3-4) Lesson 3:  Lesson 4: 2.4 Continuity (3-5) Lesson 4:  Lesson 5: 2.5 Extrema (3-6) Lesson 5:  Lesson 6: 2.6 Rational Functions (3-7) Lesson 6:

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4 In this unit we will learn… STANDARD 2.1: use algebraic tests to determine symmetry in graphs, including even-odd tests (3-1) STANDARD 2.2: graph parent functions and perform transformations to them (3-2, 3-3) STANDARD 2.3: determine and graph inverses of functions (3-4) STANDARD 2.4: determine the continuity and end behavior of functions (3-5) STANDARD 2.5: use appropriate mathematical terminology to describe the behavior of graphs (3-6) STANDARD 2.6: graph rational functions (3-7)

5  In this lesson we will…  Discuss what symmetry is and the different types that exist.  Learn to determine symmetry in graphs.  Classify functions as even or odd.

6  Point Symmetry: Symmetry about one point  Figure will spin about the point and land on itself in less than 360º.

7 M P’ P

8  This is the main point we look at for symmetry.  Let’s build some symmetry!

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14  x-axis  y-axis  y = x  y = -x

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20  HW 2.1: P 134 #15 – 35 odd

21  Get a piece of graph paper and a calculator.  Graph the following on separate axii:

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23 In this section we will…  Identify the graphs of some simple functions.  Recognize and perform transformations of simple graphs.  Sketch graphs of related functions.

24  Any function based on a simple function will have the basic “look” of that family.  Multiplying, dividing, adding or subtracting from the function may move it, shrink it or stretch it but won’t change its basic shape.

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26 Reflections

27 Vertical Translations

28 Horizontal Translations

29 Vertical Dilations

30 Horizontal Dilations

31 Send One person from your group to get a white board with a graph on it, a pen and an eraser.

32 In this section we will…  Use function families to graph inequalities.

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34  HW1 2.2: P 143 #13-29 odd, 33  HW2 2.2: P 150 #21-31 odd

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37 In this section we will…  Determine inverses of relations and functions.  Graph functions and their inverses.

38  An inverse of function will take the answers (range) from the function and give back the original domain.

39  Easy!!! Just switch the domain and range!  Are they both functions?

40  If f(x) and f –1 (x) are inverse functions, then  In other words… ◦ Two relations are inverse relations iff one relation contains the element (b,a) whenever the other relation contains (a,b). ◦ Does this remind you of something?

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42  Are reflections of each other over the line y = x.

43 Is the inverse a function?

44  If the original function passes the HORIZONTAL line test then the inverse will be a function.  Let’s check our parent graphs.

45 Is the inverse a function?

46 Is this a function?

47  If two functions are actually inverses then both the composites of the functions will equal x.  You must prove BOTH true.

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49  Replace f(x) with y (it is just easier to look at this way).  Switch the x and y in the equation.  Resolve the equation for y.  The result is the inverse.  Now check!

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51  The fixed costs for manufacturing a particular stereo system are $96,000, and the variable costs are $80 per unit. ◦ A. Write an equation that expresses the total cost C(x) as a function of x given that x units are manufactured.

52  B. Determine the equation for the inverse process and describe the real-world situation it models.

53  C. Determine the number of units that can be made for $144,000.

54  HW 2.3: P 156 #15 – 39 odd and 45

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57 In this section we will…  Determine the continuity or discontinuity of a function.  Identify the end behavior of functions.  Determine whether a function is increasing or decreasing on an interval.

58  A continuous function’s graph can be drawn without ever lifting up your pencil.  It has no holes or gaps.

59 AAnything which disrupts the flow of the graph. WWhat parent graphs do we have which demonstrate discontinuous functions?

60  Function is undefined at a value but, otherwise, the graph matches up.  Graph has a “hole”.

61  Graph stops at one y- value, then “jumps” to a different y-value for the same x-value.  Common in piece- wise functions.

62  A major disruption in the graph.  As graph approaches the domain restriction, the graph will shoot towards either positive or negative infinity.

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69  A function is continuous on an interval iff it is continuous at each number in the interval.

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72  Increasing means uphill left to right.  Decreasing means downhill left to right.  Constant means a flat or horizontal line left to right.

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74  P 166 #26, 28, 30  Determine the intervals where the functions are increasing or decreasing.  Write the intervals in interval notation and in in terms of x.

75 26. 28. 30.

76  What will the function be doing at the outermost reaches of its domain and range?

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80  HW 2.4: P 166 #13 – 31 odd, 39  You will need a graphing calculator.

81 Check these out! Find discontinuities, intervals inc/dec and end behavior

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83 In this section we will…  Find the extrema of functions.  Learn the difference between Absolute Extrema and Relative Extrema.  Find the point of inflection of a functions (if it exists).

84  An Absolute Minimum of Maximum is the lowest or highest value the range of the function can have.  The slope of the line drawn tangent to the min or max will have a slope of zero.  That point is called a critical point for the graph.

85 Find the Extrema and Describe End Behavior:

86  These points are not the absolute highs or lows for the function but they are the high or low over a certain interval.  The slope of the line tangent to a relative min or max is still zero so the point is a critical point.  Minimums are said to be concave up and maximums are concave down.

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88  A point of inflection occurs when a graph changes from one concavity to another.  The slope of the tangent line to this point is undefined ( a vertical line). This point is also considered a critical point.  You will learn to calculate the point of inflection in calculus.

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90 HW 2.5: P 177 #13 – 29 every other odd and 34  You will need a graphing calculator.

91 Describe the end behavior of the graph.

92 In this section we will…  Graph Rational Functions  Determine vertical, horizontal and slant asymptotes

93  Have a variable in the denominator.  The denominator restriction will have a profound effect on the function’s graph.

94  Caused by values which make the denominator 0.  Also known as removable and non-removable discontinuities.

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98 3 cases possible: 1.Degree of numerator < Degree of denominator H.A. at y = 0. 2.Degree of numerator = Degree of denominator H.A. is the ratio of the coefficients. 3.Degree of numerator > Degree of denominator Do long division to find the Slant Asymptote.

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100  HW 2.6: P 186 #15 – 39 odd, 43


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