1. + CCM1 Unit 5

2. + Warm Up – January 23 Complete the student Information sheet on your desk.

3. + What Do I Remember Spend 15 minutes going though the “What Do I Remember” worksheet

4. + What you should have remembered

5. + Mean- average Median- middle number Describing Data- SOCS Standard Deviation- How much variation exists from the average Range-The difference between the highest and lowest number

6. + Box Plot- Use the 5 number summary Dot Plot- Histogram-

7. + 5 Number Summary- Minimum, Q1, Median, Q3, and Maximum IQR- The difference between Q3 and Q1 Outliers- A number that is numerically distant from the rest of the data

8. + Categorical – data that can be separated by category EX) sorting students by the model of car they have Quantitative – data that can be separated by numerical values EX) sorting students by the number of siblings they have

9. + Algebraic Expressions- Does not have an equal sign, You evaluate Algebraic Expressions Algebraic Equations- has an equal sign Order of Operations- (PEMDAS) Parenthesis Exponents Multiplication/Division Addition/Subtraction Evaluate- means to solve

10. + Solving Equations- Follow reverse order of operations to get the variable by its self on one side of the equation Whole Numbers- Includes zero and all the positives (no fractions or decimals) Integer- Includes all negatives, zero, and all positives (No fractions or decimals) Variable- a symbol that stands for a number Ex) x – 2 = 10 X is the variable

11. + Subtracting Negatives- Keep, change, change Multiplying Negatives- Neg *Neg = Pos Neg*Pos = Neg Pos * Neg = Neg Pos*Pos = Pos Dividing Negatives Neg /Neg = Pos Neg/Pos = Neg Pos /Neg = Neg Pos/Pos = Pos

12. + Distributive Property- Distribute to EVERYTHING inside the parenthesis Constant- just a number, does not have a variable Coefficient- The NUMBER in front of (multiplied by) a variable Like Terms-Terms with the same exact variables Substitution- Putting a number in place of a variable to simplify an expression Equivalent expression- two expressions that have the same most simplified form Solving Equation- Follow reverse order of operations to get the variable by its self on one side of the equation

13. + Less Than < Less than or equal to ≤ Greater Than > Greater Than or Equal To ≥ Open Circle- Use for Closed Circle- Use for ≤ or ≥ Solving Inequalities- Solve like you solve equations; Follow reverse order of operations

14. + Domain Independent Variable X’s Goes on x-axis Goes in L1 when finding line of best fit Range Dependent Variable Y’s Goes on y-axis Goes in L2 when finding line of best fit

15. + Function Notation f(x) = Example: f(x)= 2x + 4 Now-Next Rule: A recursive rule found by relating a number to what comes before it. Written as Ex) NEXT = NOW + 4 NEXT = NOW/2

16. + Direct Variation- Equation: y=kx K = constant of variation Goes through the origin on a graph Finding slope through 2 ordered pairs: (x 1, y 1 ) (x 2, y 2 ) Slope- Intercept Form: y = mx + b M = slope; B = y-intercept Point Slope: y – y 1 = m( x – x 1 ) M = slope; X 1, y 1 are from the ordered pair Standard Form: Ax + By = C No Fractions, C is a constant

17. + Parallel Lines- never intersect, have the SAME SLOPE Perpendicular Lines- Slopes are opposite reciprocal + change to – – change to + Flip the fraction

18. + Pay It Forward http://www.youtube.com/watch?v=DvKAP HvCPS8 http://www.youtube.com/watch?v=DvKAP HvCPS8 To 1:17 http://www.youtube.com/watch?v=vmboo 6cj8ds From 3:10 to 4:39

19. + 1. How many people would receive a Pay It Forward good deed at each of the next several stages of the process? Stage 1:Stage 2: Stage 3:Stage 4: Stage 5:Stage 6: 2. What is your best guess for the number of people who would receive Pay It Forward good deeds at the tenth stage of the process?

20. + 3. Which of the graphs below do you think is most likely to represent the pattern by which the number of people receiving Pay It Forward good deeds increases as the process continues over time? Graph Number: ___________

21. + 4. Take your values for each stage (from #1) and graph the data. Hint: Your x-axis needs to be the stage number and your y-axis needs to be the number of people receiving Pay It Forward.

22. + Mathematical terminology EXPONENTIAL This graphs represents EXPONENTIAL growth. EXPONENTIAL FUNCTIONS. These data sets display properties of EXPONENTIAL FUNCTIONS.

23. +

24. + Warm Up – January 24 th

25. + Exponent Rules Review Exponents are a “short-hand” way of multiplying the same quantity over and over. Example: X 4 = (x)(x)(x)(x)

26. + Try Some: Expand the following 4 3 Y 4 X 2 y 5 w 6 z 1

27. + Using Exponents to simplify Write using exponents X*x*x*x 2*2*2*2*x*x*x*y*y 3*3*3*4*4*4*4*x

28. + Zero as an exponent Anything with an exponent of zero equals 1. Ex x 0 = 1 6 0 = Y 0 =

29. + Negative Exponents When you have a NEGATIVE exponent you turn it POSITIVE and FLIP it. EX x -3

30. + Try Some

31. + Multiplication When multiplying like bases you ADD exponents Ex: x 4 x 2

32. + Try some! X 3 x 4 Y 3 x 4 y 7 z 3 y 2 x 5 z 5 y 6 x 10

33. + Exponents of Exponents When you have an exponent of an exponent you MULTIPLY EX: (x 4 ) 3

34. + Try Some! (x) 5 (x 2 y 4 ) 5 (2x 3 ) 6

35. + Division When you divide like bases you SUBTRACT exponents

36. + Try Some

37. + Growing Sequences Arithmetic Sequence: goes from one term to the next by always adding (or subtracting) the same value Common Difference : The number added (or subtracted) at each stage of an arithmetic sequence Initial Term : Starting term For example, find the common difference and the next term of the following sequence: 3, 11, 19, 27, 35,...

38. + Growing Sequences Geometric Sequence: goes from one term to the next by always multiplying (or dividing) by the same value Common Ratio: The number multiplied (or divided) at each stage of a geometric sequence Determine the common ratio r of the Brown Tree Snake Sequence. 1, 5, 25, 125, 625,...

39. +

40. + Warm Up – January 25 th

41. + The geometric sequence from the Brown Tree Snake problem (1, 5, 25, 125, 625...) can be written in the form of a table, as shown below: The Brown Tree Snake was first introduced to Guam in year 0. At the end of year 1, five snakes were found; at the end of year 2, twenty-five snakes were discovered, and so on…

42. + Since we now have a table of the information, a graph can be drawn, where the year is the independent variable (x) and the number of snakes is the dependent variable (y). See below:

43. + The curved graph of this problem situation is known as an exponential growth function. An exponential growth function occurs when the common ratio r is greater than one.

44. + In your group’s complete the worksheet handed out. Group Work

45. +

46. + Tuesday, January 29 th Warm Up # 4

47. + Homework Check – 5.4

48. + What is the difference between an arithmetic and geometric sequence? What is the difference between a common ratio & a common difference? Which type of sequence does each go with?

49. + The Ladybug Invasion As a biology project, Tamara is studying the growth of a ladybug population. She starts her experiment with 5 ladybugs. The next month she counts 15 ladybugs. 1) The ladybug population is growing arithmetically. How many beetles can Tamara expect to find after 2, 3, and 4 months? Write the sequence. 2) What is the common difference? 3) Now put the sequence into a table in the space below.

50. + 4) How long will it take the ladybug population to reach 200 if it is growing linearly?

51. + 5) Suppose the ladybug population is growing exponentially. How many beetles can Tamara expect to find after 2, 3, and 4 months? Write the sequence. 6) What is the common ratio? 7) Now put the sequence into a table in the space below.

52. + 8) How long will it take the ladybug population to reach 200 if it is growing exponentially? 9) Why does it take the ladybug population longer to reach 200 when it grows linearly?

53. + 10) Graph both tables on the designated graphs provided below. Be sure to label your axes Linear Growth Exponential Growth

54. + Homework Worksheet 5.5

55. + Wednesday January 30

56. + Warm Up - # 5 Homework 5.5

57. + One Grain of Rice

58. + Exponential Functions An exponential function is a function with the general form y = ab x a ≠ 0 and b > 0, and b ≠ 1

59. + A and B A is your starting value B is growth factor X is time Y is the amount after time

60. + Starting Value and Growth Factor Identify each starting value and the growth factor. 1. Y= 3(1/4) x 2. Y=.5(3) x 3. Y = (.85) x

61. + Modeling Exponential Functions Suppose 20 rabbits are taken to an island. The rabbit population then triples every year. The function f(x) = 20 3 x where x is the number of years, models this situation. What does “a” represent in this problems? “b”? How many rabbits would there be after 2 years?

62. + Modeling Exponential Functions Suppose a Zombie virus has infected 20 people at our school. The number of zombies doubles every day. Write an equation that models this. How many zombies are there after 5 days? If there are 1800 students at Knightdale, how long will it take for the Zombie virus to infect the whole school?

63. + 3. A Bacteria culture doubles in size every hour. The culture starts at 150 cells. How many will there be after 24 hours? After 72 hours?

64. + 4. A population of 2500 triples in size every year. What will the population be in 30 years?

65. +

66. + Warm up Homework

67. + Remember Exponential Functions An exponential function is a function with the general form y = ab x a ≠ 0 and b > 0, and b ≠ 1 A is your starting value B is growth factor X is time Y is the amount after time

68. + Intervals of Time In an exponential equation when your growth factor happens over a special interval of time, we must divide our x by that interval. n is your interval of time

69. + Modeling Exponential Functions Suppose a Zombie virus has infected 20 people at our school. The number of zombies doubles every 30 minutes. Write an equation that models this. How many zombies are there after 5 hours?

70. + 4. A population of 2500 triples in size every 10 years. What will the population be in 30 years?

71. + Friday February 1 st Compound Interest

72. + Warm Up Homework

73. + Review

74. + Quiz

75. + Compound Interest

76. + Decimals as Percent's To Write a Decimal as a Percent: Move decimal place 2 places right. Ex:.3434.25 1.7362.2798

77. + Percent's as Decimals To Write a Percent as a Decimal: Move decimal place 2 places left. Ex: 45%63.3% 100.5%5.64%

78. + Compound Interest Compound Interest is another type exponential function: Here P = starting amount R = rate (AS A DECIMAL!!!!) n = period T = time

79. + Compound Interest Find the balance of a checking account that has $3,000 compounded annually at 14% for 4 years.

80. + Compound Interest Find the balance of a checking account that has $500 compounded semiannually at 8% for 5 years.

81. + Transformations

82. + Warm Up Homework Compound Interest Practice Go over Review Sheet

83. + Transformations Remember: Translations are moments of a function! Complete Worksheet

84. + Transformation Sum Up y = 2 x-h + k + h left - h right - k down + k up

85. + Part of an Exponential Graph Horizontal Asymptote: A horizontal line that the graph “flat lines” at Y-Intercept: Where the graph crosses the y-axis.

86. + Identify Horizontal Asymptotes and y-intercept

87. +

88. + Write an Equation if the Base = 2

89. +

90. +

91. + Exponential Decay

92. + Warm UP Homework Finish Translations

93. + Drug Filtering Assume that your kidneys can filter out 25% of a drug in your blood every 4 hours. You take one 1000-milligram dose of the drug. Fill in the table showing the amount of the drug in your blood as a function of time. The first three data points are already completed. Round each value to the nearest milligram

94. + Time since taking the drug (hrs) Amount of drug in your blood (mg) 01000 4750 8562 12 16 20 24 28 32 36 40 44 48 52 56 60 64 68

95. +

96. + 3. How many milligrams of the drug are in your blood after 2 days? 4. Will you ever completely remove the drug from your system? Explain your reasoning. 5. A blood test is able to detect the presence of the drug if there is at least 0.1 mg in your blood. How many days will it take before the test will come back negative? Explain your answer.

97. + Initial (starting) value = a Growth or Decay Factor = b x is the variable, so we change that value based on what we are looking for! Remember that the growth or decay factor is related to how the quantities are changing. Growth: Doubling = 2, Tripling = 3. Decay: Losing half = Losing a third = Recall: y = ab x

98. + Exponential Decay When b is between 0 and 1! Growth : b is greater than 1

99. + If the rate of increase or decrease is a percent: we use a base of 1 + r for growth or 1 – r for decay

100. + Ex 1. Suppose the depreciation of a car is 15% each year? A) Write a function to model the cost of a $25,000 car x years from now. B) How much is the car worth in 5 years?

101. + Ex 2: Your parents increase your allowance by 20% each year. Suppose your current allowance is $40. A) Write a function to model the cost of your allowance x years from now. B) How much is your allowance the worth in 3 years?

102. + Complete the 2 practice problems

103. + Other Drug Filtering Problems 1. Assume that your kidneys can filter out 10% of a drug in your blood every 6 hours. You take one 200-milligram dose of the drug. Fill in the table showing the amount of the drug in your blood as a function of time. The first two data points are already completed. Round each value to the nearest milligram.

104. + TIME SINCE TAKING THE DRUG (HR) AMOUNT OF DRUG IN YOUR BLOOD (MG) 0200 6180 12 18 24 30 36 42 48 54 60 66

105. +

106. + A) How many milligrams of the drug are in your blood after 2 days? B) A blood test is able to detect the presence of the drug if there is at least 0.1 mg in your blood. How many days will it take before the test will come back negative? Explain your answer.

107. + 2. Calculate the amount of drug remaining in the blood in the original lesson, but instead of taking just one dose of the drug, now take a new dose of 1000 mg every four hours. Assume the kidneys can still filter out 25% of the drug in your blood every four hours. Have students make a complete a table and graph of this situation.

108. + TIME SINCE TAKING THE DRUG (HR) AMOUNT OF DRUG IN YOUR BLOOD (MG) 01000 41750 82312 12 16 20 24 28 32 36 40 44 48

109. +

110. + A) How do the results differ from the situation explored during the main lesson? Refer to the data table and graph to justify your response. B) How many milligrams of the drug are in your blood after 2 days?

111. + HW 5.10

112. + Growth VS Decay and Percent Growth and Decay

113. + Exponential Functions Remember! An exponential function is a function with the general form y = ab x/n a ≠ 0 and b > 0, and b ≠ 1

114. + A and B A Starting Value B is direction GrowthDecay b > 10 < b < 1

115. + Y-Intercept and Growth vs. Decay Identify each y-intercept and whether it is a growth or decay. 1. Y= 3(1/4) x 2. Y=.5(3) x 3. Y = (.85) x 4. Y = 300(1.3) x 5. Y = 4500(.4) x 6. Y = 76(3/4) x

116. + Increase and Decrease by percent Exponential Models can also be used to show an increase or decrease by a percentage.

117. + Increase and Decrease by percent The rate of increase or decrease is a percent, we use a change factor/base of 1 + r or 1 – r. GrowthDecay. b > 10 < b < 1 Change factorChange Factor (1 + r) (1 - r)

118. + Percent to Change Factor When something grows or decays by a percent, we have to add or subtract it from one to find b. 1. Increase of 25%2. increase of 130% 2. Decrease of 30% 4. Decrease of 80%

119. + Growth Factor to Percent Find the percent increase or decease from the following exponential equations. 1. Y = 3(.5) x 2. Y = 2(2.3) x 3. Y = 0.5(1.25) x

120. + Percent Increase and Decrease A dish has 212 bacteria in it. The population of bacteria will grow by 80% every day. How many bacteria will be present in 4 days?

121. + Percent Increase and Decrease The house down the street has termites in the porch. The exterminator estimated that there are about 800,000 termites eating at the porch. He said that the treatment he put on the wood would kill 40% of the termites every day. How many termites will be eating at the porch in 3 days?