The speed the speed of light is 30,000,000,000 m/s. Write this number in scientific notation.

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Wesley Carpenter
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1 Chapter 1 Section 1.1 Scientific Notation Powers of Ten Standard Scientific Notation N n where 1 N and n is an integers Eamples of numbers in scientific notation Using Scientific Notation The population of Meico Cit is about,, To change the number into scientific notation ou move the decimal place seven places to 7 get:. The speed the speed of light is,,, m/s. Write this number in scientific notation. Answer:.

2 Eample 1 Convert.7 to scientific notation Answer: 7. 8 Eample Convert. to scientific notation Answer:. 1 Eample Convert 8.1 to decimal notation. Answer:,, Eample Convert.11 to decimal notation. Answer: 11, Using operations with scientific notation Multiplication with scientific notation Eample 6 7 Simplif (6.1 )(7.8 ) 6 7 (6.1 )(7.8 ) (6.1)(7.8)

3 Eample 6 7 Simplif ( )(7 ) ( ()(7) )( ) Eample 7 6 Simplif ( )( ) ( ()(). )( 6 6 ) Division with scientific notation Eample 8. Simplif

4 Eample Simplif Eample Simplif 8 ) )(. ( ) )(. (. Eample 11 Simplif 8 ) )(1. ( ) )(1. (

5 Eample 1 1 The National debt is about 7.8, and there about 6,, Americans. What would be the debt per American citizen? Convert the population of America to scientific notation. 6,, $ 7.8 Each American would owe: $.6 $6, 8.6 Estimation Eample 1 You make $1.8 per hour, about how much would make in a ear assuming ou work hours a week? Round $1.8 to $1. Salar per week: $1. $ 6 Salar per ear: $6 $, Eample 1 A high graduate makes about an average of $, per ear while a college graduate makes about an average of $, per ear. High School Graduate : $, $1,, College Graduate : $, $1,6,

6 Section 1. Introduction to Mathematical Modeling Tpes of Modeling 1) Linear Modeling ) Quadratic Modeling ) Eponential Modeling ) Logarithmic Modeling Each tpe of modeling in mathematics is determined b the graph of equation for each model. In the net eamples, there is a sample graph of each tpe of modeling Linear models are described b the following general graph Quadratic models are described b the following general graph

7 Eponential models are described b the following general graph Logarithmic Models are described b the following general graph.

8 Section 1. Linear Models Before ou can stud linear models, ou must understand so basic concepts in Algebra. One of the main algebra concepts used in linear models is the slope-intercept equation of a line. The slope intercept equation is usuall epressed as follows: Standard linear model m b m slope b Intercept In this equation the variable m represents the slope of the equation and the variable b represents the -intercept of the line. When studing linear models, ou must understand the concept of slope. Slope is usuall defined as rise over run or change in over change in. In general slope measures the rate in change. Thus, the idea of slope has man applications in mathematics including velocit, temperature change, pa rates, cost rates, and several other rates of change. Slope Slope m rise run 1 1 change in change in Basic Algebra Skills (Slope and -intercept) In net eamples, we will find the slope of a line given two points on the line. Eample 1 Find the slope between the points (1,) and (,) m

9 Eample Find the slope between the points (,) and (,6) m Slope and -intercept also can be found from the equation in slope-intercept, as shown in this net eample. Notice that the equation is written in slope-intercept form. Eample Find the slope and -intercept b m If the equation is not written in slope intercept form, it can be rearranged to slopeintercept form b solving the equation for. This procedure is shown in the net two eamples. Eample Find the slope and -intercept b m

10 Eample Find the slope and -intercept b m Eample 6 Graph the equation First construct a table using arbitrar values of, and then substitute these values to the equation to get the corresponding values. 1 1 (1) 1 () () 6 ()

11 Net make point using the four points in the above table Applications of Linear Equations Eample 6 (Temperature conversion) F C a) Sketch a graph of F C C F C F () () 18 F () () 6 68 F () (6) 86 F () (8) 7

12 b) Use the model to convert degrees Celsius to degrees Fahrenheit. F F F F C () 16 8 c) Use the model to convert 1 degrees Fahrenheit to Celsius. F C 1 C 1 C 18 C (18) C C C

13 Eample 7 (Business Applications) The revenue of a compan that makes backpacks is given b the formula where represents the number of backpacks sold. R 1. a) Graph the linear model R 1. X R 1. R 1.() 1 R 1.() R 1.() 6 R 1.() 86 b) Use the model to calculate the revenue for selling backpacks R 1. 1.() $7. c) What is the slope m $1. d) What is the meaning of the slope? Cost per unit sold Revenue made per backpack solid

14 Eample 8 (Sales) A salesperson is paid $ plus $6 per sale each week. The model S 6 is used to calculate the salesperson s weekl salar where is the number of sales per week. a) Graph S 6 S 6 S 6() S 6() 6 S 6(6) S 6(8) 8 8 b) Use the model to calculate the salespersons weekl salar if he/she makes 8 sales. S 6(8) 8 $8. c) What is the slope of the equation m 6 $ sale d) What is the meaning of the slope Dollars per each sale

15 Eample Given the following data sketch a graph Time Temperature 1 min C min 7 C min 11 C min 1 C Sketch a graph of the given data and then compute the slope of the resulting line. 1 8 (,7) 6 (1,) Use the points (1,) and (,7) in the above graph to compute the slope 7 m 1 1

16 Eample An approimate linear model that gives the remaining distance, in miles, a plane must travel from Los Angeles to Paris given b d 6 t where d is the remaining distance and t is the hours after the flight begins. Find the remaining distance to Paris after hours and hours. d d d d d d 6 () 6 16 miles 6 () 6 7 miles How long should it take for the plane to flight from Los Angeles to Paris? 6 t t 6 t t t 6 t 6 t. hours

17 Problem Set 1. 1) Find the slope between the points (1,1) and (,) ) Find the slope between the points (,) and (,) Given the equation, find the slope and -intercept. ) ) 6 ) 6 Graph the following equations 6) 7) 8) 1 1 ) 6 Linear Models ) The revenue of a compan that makes backpacks is given b the formula R. where represents the number of backpacks sold. a) Graph the linear model R. b) Use the model to calculate the revenue for selling backpacks? c) What is the slope of the model? d) What is the meaning of the slope? 11) A salesperson is paid $ plus $ per sale each week. The model S is used to calculate the salesperson s weekl salar where is the number of sales per week. a) Graph S b) Use the model to calculate the salespersons weekl salar if he/she makes 8 sales. c) What is the slope of the equation? d) What is the meaning of the slope?

18 1) A salesperson is paid $ plus $ per sale each week. The model S is used to calculate the salesperson s weekl salar where is the number of sales per week. a) Graph S b) Use the model to calculate the salespersons weekl salar if he/she makes 8 sales. c) What is the slope of the equation? d) What is the meaning of the slope? 1) An approimate linear model that gives the remaining distance, in miles, a plane must travel from San Francisco to London given b d( t) t where d(t) is the remaining distance and t is the hours after the flight begins. Find the remaining distance to London after hours and hours.

19 Section 1. Quadratic Models Graph of Quadratic Models The graph of a quadratic model alwas results in a parabola. The general form of a quadratic function is given in the following definition. A quadratic function is a function where the graph is a parabola and the equation is of the form: a b c where a b The -coordinate of verte is given b the equation: a The verte is the turning point on the graph of a parabola. If the parabola opens upward, then the verte is the lowest point of the graph. If the parabola opens downward, then the verte is the highest point on the graph. The direction of the parabola opens can be determined b the sign of the term or the a term in the above equation. If a, then the parabola open downward. Similarl if a, then the parabola opens upward. (See graphs below in figure 1-1) Figure 1-1 A parabola where a and the verte is the lowest point on the graph

20 A parabola where a and the verte is the highest point on the graph Here are some eamples of finding the verte and -intercepts of an eponential equation. The graph of the quadratic equation is also provided in these eamples Eample 1 Find the verte and -intercepts of the quadratic equation, and then make a sketch of the parabola. a 1, c (1) -intercepts: (,) and (,)

21 Graph for Eample 1 Eample Find the verte and -intercepts of the quadratic equation, and then make a sketch of the parabola. (1) Verte -intercepts (,) (,) ) ( and or

22 Graph of the function Eample Find the verte and -intercepts of the quadratic equation, and then make a sketch of the parabola. 6 Verte ( 6) 6 1 () 6 (1, )

23 -intercepts 6 ( ) or (,) and (,) Graph of 6 More about Quadratic Equations In some instances, the quadratic equation will not factor properl. In this case, ou must use what is called the quadratic formula. In the net few eamples, the quadratic formula will be used to find the solutions of a quadratic equation. The Quadratic Formula The solution to the equation a b c is given b b b ac a

24 Eample Solve 7 a 1 b c 7 b b ac a (1)( 7) (1) 8 Eample Solve (1)( ) (7) 7 6 (7) Eample 6 At a local frog jumping contest. Rivet s jump can be approimated b the equation 1 and Croak s jump can be approimate b 1, where = the 6 length of jump in feet and = the height of the jump in feet. a) Which frog can jump higher Rivet s verte: 6 Height: 1 (6) (6) ft Croak s verte: Height: 1 () () ft 1 1 Croak can jump higher at 8 feet b) Which frog can jump farther Rivet s can jump farther at (6 ft) = 1 feet

25 Graph of the frogs jumps 8-1 g = f = Using the parabola to find the maimum or minimum value of a quadratic function The parabola can be used to find either the maimum value or the minimum value of a quadratic function. (See figure 1-1) This can simpl be done b find the verte of the parabola. Remember as stated earlier the verte will turn out to be either the highest point on the curve or the lowest point on the curve. In the net eamples, the verte of the parabola will be use to find the maimum value. Eample 7 The path of a ball thrown b a bo is given b the equation. 1. where is the horizontal distance the ball travels and is the height of the ball. Find the maimum height of the ball in ards. Find the verte of the ball 1. (.) (18.7) ards

26 Eample 8 The path of a cannon ball is given b the equation.1 6. where is the horizontal distance the ball travels and is the height of the cannon ball. Find the maimum height of the cannon ball in feet. Find the verte of the cannon ball (.1). 6() 18 feet

27 Problem Set 1. Find the verte and -intercepts of the given parabola, and then make a sketch of the parabola. 1) ) ) 1 ) ) 16 6) 6 Quadratic Models 7) The path of a ball thrown b a baseball plaer is given b the equation where is the horizontal distance the ball travels and is the height of the ball. Find the maimum height of the ball in ards. 8) The path of a ball thrown b a bo is given b the equation where is the horizontal distance the ball travels and is the height of the ball. Find the maimum height of the ball in ards. ) The path of a cannon ball is given b the equation. 6. where is the horizontal distance the ball travels and is the height of the cannon ball. Find the maimum height of the cannon ball in feet. ) The path of a cannon ball is given b the equation.1 8. where is the horizontal distance the ball travels and is the height of the cannon ball. Find the maimum height of the cannon ball in feet.

28 Section 1.6 Eponential models The eponential function e.718 The Euler number Eample 1: Simplif the following eponential functions 1) e ) e ) e e 1.. The graph of the eponential function Eample Graph e e - e. 1-1 e 1. 7 e o 1 1 e 1. 7 e 7.

29 Eample Graph e. Y -.( ) e. e ( 1) e. e 8..() e e 1.(1) e. e 1..() e. e 1. Eponential Models Eponential models are used to predict human populations, animal populations, mone growth, pollution growth, and other aspects of societ that fit eponential models. The variable of an eponential model is found in the eponent of the equation.

30 Eponential Growth kt P P e P New Value P Original Value k rate t time Eample The population of the United States is million, what would be the population of the U. S. be in ears if its population would growth at a stead rate of.7 % for ears? P k.7%.7 t P P P P P P e kt,,e,,e.7().1,,(1.1) 7

31 Eample The population of Blacksburg, Virginia is 1,, what would be the population in ears if Blacksburg would grow at a rate of 1.1 % per ear? P 1, t k.11 P P e kt P 1,e.11() 1,e.111,767 Eample 6 In 1 the United States had greenhouse emissions of about 1 million tons, where as China had greenhouse emissions of about 8 million tons. If in the net ears China greenhouse emission grew b percent and the U. S. greenhouse emission grew b 1. percent, what would the emissions in tons for both countries in? U. S. Emissions in P P (1 r) P 1 million r 1.%.1 t t.1()) 1 P 1e 1e 18million tons China' s Emissions in P P (1 r) P 8 million r.%. t t.() 1 P 8e 8e 11 million tons

32 Eample 7 Using the eponential growth formula, find the amount of mone that ou would have in a bank account if ou deposited $, in the account for 1 ears at 1.1 % interest rate? P P t P (1 r) k 1.1%.11 t 1 P e.11(1) e.16 $8.18 Eponential deca Eponential deca models are use to measure radioactive deca, decreasing populations, Half-life, and other elements that fit an eponential model. Again, the one variable in an eponential deca models in found in the eponent. Eponential Deca Formula P P e kt P New Value P Original Value k rate t time

33 Eample 8 A certain population of black bears in the eastern United States has been decreasing b.1 percent per ear. If this trend keeps up, what will be the population of bears in ears if there are currentl bears. P t k.1%.1 kt.1().6 P P e e e (.8) 8 bears Eample A certain isotope decreases at a rate of % per ear. It there is currentl grams of the isotope, how man grams of the isotope will there be in ears? P P t t P (1 r) k %. kt.() 1 P P e e e (.678) 1 grams

34 Problem Set 1. Eponential Functions Evaluate using a calculator 1) e 1 ) e ) e Graph the following functions ) ) e 1 6) 7) e e Growth Models (Show Work) 8) The current population of German is 8,,. What would be the population of German in ears if its population would growth at a stead rate of. % for ears? ) The current population of Salem, Virginia is,. What would be the population of Salem in ears if Salem would grow at a rate of 1. % per ear? ) Using the eponential growth formula, find the amount of mone that ou would have in a bank account if ou deposited $, in the account for ears at 1.6 % interest rate?.t 11) A certain rabbit population is modeled b the equation P e where t is the time in months. Use the model to predict the population after months. Deca Models 11) A certain population of Panda Bears in China has been decreasing b 1. percent per ear. If this trend keeps up, what will be the population of Panda Bears in ears if there are currentl bears?

35 1) A certain isotope decreases at a rate of % per ear. It there is currentl grams of the isotope, how man grams of the isotope will there be in ears? Section 1.6 Basic Logarithms Definition of a Logarithm log b a b a Eample 1 i) Write as a logarithmic epression. log ii) Write 6 as a logarithmic epression. 6 log 6 Eample i) Write log 16 as eponential epression. log ii) Write log, as an eponential epression. log,, Log base ten Another wa of writing log is log. The wa we find the answer to log is to ask the question of raised to what power gives ou? Since we know that, the answer is.

36 Eample i) Find log, Since,, log, ii) Find log Since, log Eample Use a scientific calculator to evaluate the following logarithms i) log 67 Answer: log 67 =.7 ii) log 8 Answer: log 8 =. iii) log 678 Answer: log 678 =.66 Graph of basic logarithms Eample Graph log 6 Y log( 6()) log(1) 1. 7 log( 6()) log(6) 1. 8

37 log( 6()) log(). 1 log( 6()) log( ). Plot the given values from the table gives the following graph Eample 6 Graph log( 1) X log( 1) log(). log( 1) log(11). log( 1) log( 1) 6. 6 log( 1) log( 1) 8. 1 Plot the given values from the table gives the following graph

38 Eample 7 (Using logarithmic models to model height) A logarithmic model to approimate the percentage P of an adult height a male has reached at an age A form 1 and 18 is P 16log( A 1) 8 1) Sketch a graph of this function. P A 1 P 16log(1 1) P 16log(1 1) 8 16log( ) P 16log(1 1) 8 16log() P 16log(18 1) 8 16log(6) Plot the given values from the table gives the following graph

39 ) What does the graph tell ou about the height of male after age of 18? Usuall males stop growing after age 18 ) Use the model to compute the average height of a 16 ear old male. P 16log(16 1) 8 16.log( ) % Eample 8 Use the following model for $ invested in saving account given b n 6. 1.log( A), to find the amount of time (n) for the amount of mone A to grow to $,. n log n 6. 1.() n n 6.8

40 Problem Set 1.6 I) Write as a logarithmic epression. 1) e a ) 6 6 II) Write as an eponential epression. 1) log 81 ) ln III) Graph each logarithmic equation. 1) ln ) ln ln 6 )

Chapter 4. Introduction to Mathematical Modeling. Types of Modeling. 1) Linear Modeling 2) Quadratic Modeling 3) Exponential Modeling

Chapter 4. Introduction to Mathematical Modeling. Types of Modeling. 1) Linear Modeling 2) Quadratic Modeling 3) Exponential Modeling Chapter 4 Introduction to Mathematical Modeling Tpes of Modeling 1) Linear Modeling ) Quadratic Modeling ) Eponential Modeling Each tpe of modeling in mathematics is determined b the graph of equation