Unit 8: Exponential & Logarithmic Functions

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Date Period Unit 8: Eponential & Logarithmic Functions DAY TOPIC ASSIGNMENT 1 8.1 Eponential Growth Pg 47 48 #1 15 odd; 6, 54, 55 8.1 Eponential Decay Pg 47 48 #16 all; 5 1 odd; 5, 7 4 all; 45 5 all 4 5 8. Properties of Eponential Functions; Continuous Compound Interest ( e ) 8. Logarithmic Functions; Converting between log and ep. 8. Logarithmic Functions; Inverses; Graphs; Domain and Range Pg 44 46 #1 odd; 4 6; 6, 40 Pg 441 44 #6 5 all; 5 61 all Pg 44 # 6 8 odd; 89 Graph # 75 8 odd 6 8.4 Properties of Logarithms Pg 449 #1 85 every other odd 7 Quiz (Days 1 5) 8 8.5 Eponential and Logarithmic Equations Pg 456 458 #1 1 odd, 50 54, 58, 60, 79 81, 89-91 9 8.5 Solving Logarithmic Equations Pg 456 458 # 47 odd; 55 57; 8 84 all; 86 94 even 10 Applications of Logarithms Pg 459 #97 99all 11 8.6 Natural Logs Pg 464-466 #1 7 odd; 1 8 all; 56 6 even 1 Applications of Natural Logs Worksheet 1 Review 14 Test

Date Period U8D1: Eponential Growth Objective: To model eponential growth. Thinking Skill: Eamine information from more than one point of view. A. Warm Up: Complete the table of values below. Plot the coordinates and connect the points with a smooth curve to graph the function y. y 1 0 1 Check your graph using your graphing calculator. B. An eponential function is a function with the general form, where is a real number, a 0, b 0, and b 1. Eponential Growth Eponential Decay Equation a b y y ab 0 ab 0 a b 1 a 0 b 1 When, b is the growth factor. When, b is the decay factor.

An eponential function can model growth. If you know the rate of increase r, you can find the growth factor by using the equation: b = To create a model for growth, use the formula: Initial value y Final value ab Number of time periods Growth Factor C. In 000, the U.S. population was 81 million people and the annual rate of increase in was about 1.4%. 1. Find the growth factor for the U.S. population.. Suppose the rate of increase continues to be 1.4%. Write a function to model the population growth.. Use your model from above to predict the U.S. populations in 05 to the nearest million.

D. Graph each function and give its initial value and growth factor. Also, give the domain and range using interval notation. Check on your calculator. 1. y 1.5. y 5 Initial value: Growth factor: Domain: Range: Initial value: Growth factor: Domain: Range: E. Write an eponential function y ab for a graph that includes the given points. 1. 4,8, 6,

.,18, 5,60.75 F. Closure: On you Own About 84 million homes used the internet in 000. The usage grew by about 4% each year until 005. Write a function to model internet usage in the United States. Use your model to predict the number of homes that used internet in 005.

Date Period Objective: To model eponential decay. Thinking Skill: Eamine information from more than one point of view. Eponential Growth Eponential Decay U8D: Eponential Decay Equation a b y y ab 0 ab 0 a b 1 a 0 b 1 A. Without graphing, determine if each equation represents eponential growth or decay. 1. y 00 4 growth / decay. y.05.87 growth / decay. 4 1 y 5 growth / decay 1 y growth / decay 4. B. Horizontal Asymptote: A line that the graph approaches. 1 1. What is the horizontal asymptote for y? 1. For y 1. For y? 5? C. Graph each function and then identify the horizontal asymptote. 1 y 1 y 1 y 5

1. y 0.5 1. f 1 5 5 H.A. H.A. Similar to the growth factor, you can identify the decay factor if you know the rate of decrease r, by using the equation b = Depreciation is the decline in an item s value resulting from age or wear. When an item loses the same percent of its value each year, you can use an eponential function to model the depreciation. D. Suppose you want to buy a used car that costs $11,800. The epected depreciation of the car is 0% per year. Estimate the depreciated value of the car after 6 years. E. Write an eponential function to model each situation. Be careful, some are growth and some are decay.

1. A tree ft. tall grows 8% each year. How tall will the tree be at the end of 14 years? Round the answer to the nearest hundredth.. A motorcycle purchased for $9,000 today will be worth 6% less each year. For what can you epect to sell the motorcycle at then end of 5 years?. The price of a new home is $16,000. The value of the home appreciates % each year. How much will the home be worth in 10 years? F. Closure: The value of a truck bought new for $,000 decreases 16.5% each year. Write an eponential function, and graph the function using your calculator and the window settings below. Use the TRACE function to predict when the value will fall to $000.

Date Period U8D: Properties of Eponential Functions h Objective: To identify the role of constants in y ab k and to use e as a base. Thinking Skill: Eplicitly assess information and draw conclusions. A. Warm Up: Use your calculator to graph each of the functions below. Net, analyze the equation and make some generalizations about how they affect the graph. y y 1 y 1 y B. Translations: If you are able to graph y ab (i.e. y ), then h To graph: y ab k, move h units and move k units. For eample, 1 1. Graph y, and then graph.. 4. 1 y 1 y 1 y 1

C. Just like, e is an irrational number approimately equal to.7188 Eponential functions with a base of e are useful for describing continuous growth or decay. Your graphing calculator has a key for e Graph y e and then evaluate the following (to 4 decimal places). 1. e. 4 e. e NOTE: e is a, not a. D. Compound Interest Continuous eponential growth model: A Pe rt r n times per year: A P 1 n nt Key: A P r t n

1. Suppose you invest $1050 at an annual interest rate of 5.5% compounded continuously. How much will you have in the account after 5 years?. How much money would you need to invest at an annual interest rate of 4.% compounded continuously in order to have $1479 in the account after three years?. Suppose you invest $000 at an annual interest rate of 4.5%. How much will you have after 5 years? Annually: Quarterly: Monthly: Daily: Continuously: Which method gives you the most? By how much?

Date Period Objective: To write and evaluate logarithmic epressions. Thinking Skill: Eplicitly assess information and draw conclusions. A. Logarithm Definition: U8D4: Introduction to Logarithms A logarithm is the that a specified base must be raised to in order to get a certain value. If b a, then log b a b 0 and b 1 A logarithmic function is the of an eponential function. What does that mean?! (more on this later) B. Write the eponential equation in logarithmic form. 1. 5 15. 1 6 6. 0 9 1 4. 10 5. 4 16 100 1 Special Properties of Logarithms log b b 1 log 1 0 b

C. Write the logarithmic equation in eponential form. 1 1. log5 5. log 8. log5 1 5 4. log 1 5. log81 0 D. Evaluate each logarithm. A common logarithm is a logarithm whose base is, denoted just log. 1. log100. log81. log9 7 log 16 5. log 9 4. 8 1 6. log64 Change of Base Formula log b log a log n n a b

Date Period Objective: To graph logarithmic functions. Thinking Skill: Eamine information from more than one point of view. A. Vocabulary 1. A logarithm is the that a specified base must be raised to in order to get a certain value.. A common logarithm is a logarithm whose base is, denoted log or just log. 10. Because logarithms are the of eponents, the inverse of an eponential function, such as y, is a logarithmic function, y log. Asymptote: U8D5: Graphing Logarithmic Functions y 10 y log Domain: Range: Notice, y 10 and y log are inverses because they are reflected over the line. B. Graph y log Step 1: Write in eponential form. Step : Make a table of values. Step : Pick values for y, and solve for. (this is backwards of what you re used to) Step 4: Graph the points & connect y Domain: Range:

C. Now that we know how to graph logs, we can use to graph other logs! 1. y log ( ) 4 and state the domain, range, and asymptote. y log y Translate! y log ( ) 4 y Asymptote: Domain: Range:. Graph y log Asymptote: Domain: Range:

. Graph y log 1 6 Asymptote: Domain: Range:

Date Period U8D6: Properties of Logarithms Objective: To use the properties of logarithms. Thinking Skill: Demonstrate understanding of concepts. A. Warm Up: Complete the table below using your calculator. Round each value to the nearest thousandth. 1 4 5 6 7 8 9 10 15 0 log Directions: Complete each pair of statements below by using the information in the table you completed. 1. log log5 = log 5 log 15. log log. log9 log 9 log = 4. log10 log log 10 log 0 Product Property: log MN log M log N b b b Properties of Logarithms: M Quotient Property: log log M log N b b b N Power Property: log M log M Note: M, N, and b must be positive and b 0 b b B. State the property or properties used to rewrite each epression. 1. log 8 log 4 log. logb logb logb y y

C. Write each logarithmic epression as a single logarithm. 1. log 0 log 4. log log y. log log 4 log16 4. Can you epress log 9 log6 9 as a single logarithm? Why/why not? D. Epand each logarithm. 1. log 5 y. 4 log r. log 7b 4. y log 5. 4 log7 a b 6. log 8 a 8 5 7. log m 8. 4 n p log b 5 y 9. log 5 Review for Quiz:

Look back at all your notes and homework! Know your formulas! Day 1 Day 5: You will be able to use a calculator. 1. A student wants to save $8000 for college in five years. How much should be put into an account that earns 5.% annual interest compounded continuously? Round your answer to the nearest hundredth.. Write an eponential function for a graph that includes (, 4) and (, 1). Solve for. 1. log 4. log 8 4 5. 7 log 4 Graph the following. Then, state the domain, range, and asymptote.

1 6. y 7. y log ( ) 8. Suppose you purchase a home that costs $5,000. If the epected rate of appreciation of the home is % per year. Estimate the value of the home after 0 years.

Date Period U8D8: Eponential Equations Objective: To solve eponential equations. Thinking Skill: Eplicitly assess information and draw conclusions. A. Warm Up: Write the epression as a single logarithm. Then, simplify if possible. 1. log 4 log. log 5 log 5 log. log 4log y 4. 1 1 log log 4 log9 1 1 6. log1 log100 4 4 5. log log B. An eponential equation is an equation containing one or more epressions that have a variable as an eponent. Strategies to solve eponential equations: Epress each side with the same base. Use the One-to-One property: If a y a, then y. Take the logarithm of both sides. Solve. 1. 7 8. 7 50 C. Solve these eponential equations.

1. 7. 15. 5 00 D. You can choose a prize of either a $5,000 car or one penny on the first day, triple that ( cents) on the second day, and so on for a month. On what day would you would you receive more than the value of the car? Closure: What are two ways to solve an eponential equation?

Date Period U8D9: Logarithmic Equations Goal: To solve logarithmic equations. Thinking Skill: Eamine information from more than one point of view. A. Warm Up: Solve. Round to the nearest ten-thousandth. 1. 8 6. 7 1. 5 40 Strategies for solving Logarithmic Equations 1) Write as a single log using properties of logs (when necessary). y ) Convert to eponential form: If log b a y, then b a. ) Use the One-to-One property: If log M log N, then M N. 4) Check for etraneous solutions. (The argument should never be negative.) b b B. Solve the logarithmic equation. log 1. log 0 log 6 4. 1. 4 log 8 4. log log 1 5. log log log 9

C. Solve on your own. 1. log 1 1. 6 log 100 log 1 1. 4 4 4 log5 8 4. log log 1 1 5. log log log 5 1 1 8 8 8

Date Period U8D10: Application of Eponents / Logarithms Objective: To learn how logarithms are used in real-life scenarios. Thinking Skill: Eplicitly assess information and draw conclusions. A. Warm up: Solve for. If there is no solution, write no solution. 1. 5 log 8 9. log 4 6 4. log 4 1 log 8 4. log 8 log log 8 5 5 6 6 6 B. Suppose that the number of bacteria per square millimeter in a culture in your biology lab is increasing eponentially with time. On Tuesday there are 000 bacteria per square millimeter. On Thursday, the number has increased to 4500. 1. Write an eponential equation to represent the growth.. Predict the number of bacteria per square millimeter that will be in the culture on Tuesday net week.. Predict the time when the number of bacteria per square millimeter reaches 10,000.

Assignment 1. The pressure of the air in the Earth s atmosphere decreases eponentially with altitude above the surface of the Earth. The pressure at the Earth s surface (sea level) is about 14.7 pounds per square inch (PSI) and the pressure at 000 feet is approimately 1.5 PSI. a. Write the equation epressing pressure in terms of altitude. b. Predict the pressure at Meico City (7500 feet) and Mount Everest (9,000). c. Human blood at body temperature will boil if the pressure is below 0.9 PSI. At what altitude would your blood start to boil if you were in an unpressurized airplane?

. The intensity of sunlight reaching points below the surface of the ocean varies eponentially with the depth of the point below the surface of the water. Suppose that when the intensity at the surface is 1000 units, the intensity at a depth of meters is 60 units. a. Write the particular equation epressing intensity in terms of depth. b. Predict the intensity at depths of 4, 6, 8, and 10 meters. c. Plants cannot grow beneath the surface if the intensity of sunlight is below 0.001 units. What is the maimum depth at which plants will grow?

. During the first stages of an epidemic, the number of sick people increases eponentially with time. Suppose that at time t = 0 days there are 40 people sick. By the time t = days, 00 people are sick. a. Find the particular equation epressing number of sick people in terms of time. b. How many people will be sick by the time t = 6 days? c. Predict the number of sick people by the end of the first week. d. At what time t does the number of sick people reach 7,000?

Date Period U8D11: Natural Logs Objective: To evaluate natural logarithmic epressions and to solve equations using natural logarithms. Thinking Skill: Eplicitly assess information and draw conclusions. A. Remember e? We use e (approimately.7188) to graph eponential equations of the form y e. Just as y b has an inverse, y e has an inverse called a natural log. Natural logarithms are written as ln, rather than log e. The properties of common logs apply to natural logs as well. B. Simplify: write each epression as a single logarithm. 1. ln ln 8. ln ln y C. Solve each equation 1. ln 6. ln( 5) 4. ln( 9) 4. ln 1 D. Use natural logarithms to solve each equation.

1. 7e.5 0. 1 e 0. 5 e 7. 9.1 4. An initial investment of $100 is now valued at $149.18. The interest rate is 8%, compounded continuously. How long has the money been invested? Do not round any intermediate computations, and round your answer to the nearest hundredth. 5. Suppose that $1900 is initially invested in an account at a fied interest rate, compounded continuously. Suppose also that, after two years, the amount of money in the account is $1984. Find the interest rate per year. Write your answer as a percentage. Do not round any intermediate computations, and round your percentage to the nearest hundredth. E. Closure: Solve for. 1. ln e. ln 1

Date Period Objective: To continue using natural logs. Thinking Skill: Eamine information from more than one point of view. Graph each logarithm. U8D1: Applications of Natural Logs 1. y log6. y log( ) Epand each logarithm.. log s r 5 4. log ( ) 6 log 4 y 5. 6 Solve each equation 6. 7 1 7. log5 8. log 9

9. If $1000 is invested at 16% interest compounded annually, how long will it take (to the nearest year) for the money to quadruple? 10. If $1000 is invested at 1% interest compounded quarterly, how long will it take (to the nearest quarter) for the money to reach $500? 11. If $1000 is invested at 15% interest compounded continuously, how long will it take (to the nearest year) for the money to triple? 1. The learning curve describes the rate at which a person learns certain tasks. If a person sets a goal of typing N words per minute (wpm), the length of time t N days to achieve this goal is given by: t 6.5ln 1 80 a.) How long would it take to learn to type 0 wpm? b.) If we accept this formula, is it possible to learn to type 80 wpm? c.) Solve for N. Solve the following equations.

1. log5 5 14. log 8 15. ln 16. ln 9. ln 17. log log15 18. log 7 19. log 10 0 0. ln ln1 1. log 84. e 10. 1 e 4. 1 5 e 15 1 1 1 6. log7 log7 4 log 7( ) 5. log8 5 log8 9 log8 7. 1 ln ln 9 ln ( ) 8. 1 ln10 ln 5 ln

Date Period Objective: To review in preparation for the test. Thinking Skill: Demonstrate understanding of concepts. 1. Consider the function: y log 1 a. Sketch the graph by using a table. U8D1: Test Review b. Identify the asymptote (write its equation!!) c. Find the inverse of the function. d. On the same ais, sketch the inverse. Be sure to label which is which!. Evaluate each logarithm. If you need to use a calculator, do it! 1 a. log b. log4 6 c. log510 log816 7. Write as a single logarithm. log log y log z

4. Use the properties of logarithms to epand each logarithm. a. log y z b. ln 5 c. log y 4 z 5. Solve for in each equation. Be sure to check your solution! log 5 0 b. log c. a. 1 5 0 d. 1 4 e 15 e. log4 1 log4 f. 1 4 g. e ln( ) h. log 1

6. You decide to plant asparagus in your kitchen garden. You harvest 10 stalks on Jan. 1, 1986. By 1988, you produce 50 stalks. Assume the number of stalks you harvest varies eponentially with the number of years since you started harvesting the plants. a) Find the particular equation of this function. b) You will need 100 stalks to enter the gardening contest at the local fair. In what year will you harvest 100 stalks? c) What was your production in the year 000?