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Precalculus – MAT 129 Instructor: Rachel Graham Location: BETTS Rm. 107 Time: 8 – 11:20 a.m. MWF
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Chapter Three Exponential and Logarithmic Functions
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Ch. 3 Overview Exponential Fxns and Their Graphs Logarithmic Fxns and Their Graphs Properties of Logarithms Solving Exponential and Logarithmic Equations Exponential and Logarithmic Models Nonlinear Models
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3.1 – Exponential Fxns and Their Graphs Exponential Functions Graphs of Exponential Functions The Natural Base e Applications
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3.1 – Exponential Functions The exponential function f with base a is denoted by: f(x)=a x
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3.1 – Graphs of Exponential Fxns Figure 3.1 on pg. 185 shows the form of the graph of: y=a x Figure 3.2 on pg. 185 shows the form of the graph of: y=a -x
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Example 1.3.1 Pg. 187 Example 4 After looking at the solution read the paragraph at the bottom of the page.
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3.1 – The Natural Base e e≈2.71828 –Useful for a base in many situations. f(x)=e x is called the natural exponential function.
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Example 2.3.1 Pg. 189 Example 6 Be sure you know how to evaluate this function on your calculator.
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3.1 – Applications The most widely used application of the exponential function is for showing investment earnings with continuously compounded interest.
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Formulas for Compounding Interest After t years, the balance A in an account with principal P and annual interest rate r (in decimal form) is given by the following formulas: 1.For n compoundings per year: A=P(1+r/n) nt 2.For continuous compounding: A=Pe rt
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Example 3.3.1 Pg. 191 Examples 8 and 9. You will be responsible for knowing the compound interest formula.
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Activities (191) 1. Determine the balance A at the end of 20 years if $1500 is invested at 6.5% interest and the interest is compounded (a) quarterly and (b) continuously. 2. Determine the amount of money that should be invested at 9% interest, compounded monthly, to produce a final balance of $30,000 in 15 years.
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3.2 – Logarithmic Fxns and Their Graphs Logarithmic Functions Graphs of Logarithmic Functions The Natural Logarithmic Function Applications
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3.2 – Logarithmic Functions The inverse of the exponential function is the logarithmic function. For x>0, a>0, and a≠1, y=log a x if and only if x=a y. f(x)=log a x is called the logarithmic function with base a.
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Properties of Logarithms 1.log a 1=0 because a 0 =1. 2.log a a=1 because a 1 =a. 3.log a a x =x because a logx =x. 4.If log a x=log a y, then x=y
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Example 1.3.2 Pg. 203 #33. Solve the equation for x. log 7 x=log 7 9
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Solution Example 1.3.2 Pg. 203 #33. x=9
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3.2 – Graphs of Logarithmic Fxns See beige box on pg. 199
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3.2 – The Natural Logarithmic Fxn For x>0, y=ln x if and only if x=e y. f(x) = log e x = ln x is called the natural logarithmic function.
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Properties of Natural Logarithms 1.ln 1=0 because e 0 =1. 2.ln e=1 because e 1 =e. 3.ln e x =x because e ln x =x. 4.If ln x=ln y, then x=y
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Example 2.3.2 Pg. 201 Example 9. Note both the algebraic and graphical solutions.
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3.2 – Application See example 10 on pg. 202 for the best application of logarithmic functions.
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3.3 – Properties of Logarithms Change of Base Properties of Logarithms Rewriting Logarithmic Expressions
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3.3 – Change of Base To evaluate logarithms at different bases you can use the change of base formula: log a x = (log b x/ log b a)
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Example 1.3.3 Pg. 207 Examples 1 & 2. Note both log and ln functions will yield the same result.
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3.3 – Properties of Logarithms See blue box on pg. 208.
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Example 2.3.3 Pg. 208 Example 3 These should be pretty self explanatory.
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3.3 – Rewriting Log Fxns This is where you use the multiplication, division, and power rules to expand and condense logarithmic expressions.
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Example 3.3.3 Pg. 209 Examples 5&6. Note that a square root is equal to the power of ½.
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3.4 – Solving Exponential and Logarithmic Equations Introduction Solving Exponential Equations Solving Logarithmic Equations Applications
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3.5 –Exponential and Logarithmic Models Introduction Exponential Growth and Decay Gaussian Models Logistic Growth Models Logarithmic Models
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The Models
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Example 1.3.5 Example 2 on pg. 227 In a research experiment, a population of fruit flies is increasing according to the law of exponential growth. After 2 days there are 100 fruit flies, and after 4 days there are 300 fruit flies. How many flies will there be after 5 days?
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Example 2.3.5 Example 5 on pg. 230 On a college campus of 5000 students, one student returns from vacation with a contagious flu virus. The spread of the virus is modeled on pg. 230 where y is the total number infected after t days. The college will cancel classes when 40% or more are infected. a)How many students are infected after 5 days? b)After how many days will the college cancel classes?
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Example 3.3.5 On the Richter scale, the magnitude R of an earthquake of intensity I is given by R = log 10 I/I 0 where I 0 = 1 is the minimum intensity used for comparison. Intensity is a measure of wave energy of an earthquake.
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Activities In Class QUIZ: pp. 234 #30, 41a, 42a.
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