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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 1 Bruce Mayer, PE Chabot College Mathematics Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu Chabot Mathematics §9.1b The Base e
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 2 Bruce Mayer, PE Chabot College Mathematics Review § Any QUESTIONS About §9.1 → Exponential Functions, base a Any QUESTIONS About HomeWork §9.1 → HW-43 9.1 MTH 55
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 3 Bruce Mayer, PE Chabot College Mathematics Compound Interest Terms INTEREST ≡ A fee charged for borrowing a lender’s money is called the interest, denoted by I PRINCIPAL ≡ The original amount of money borrowed is called the principal, or initial amount, denoted by P Then Total AMOUNT, A, that accululates in an interest bearing account if the sum of the Interest & Principal → A = P + I
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 4 Bruce Mayer, PE Chabot College Mathematics Compound Interest Terms TIME: Suppose P dollars is borrowed. The borrower agrees to pay back the initial P dollars, plus the interest amount, within a specified period. This period is called the time (or time-period) of the loan and is denoted by t. SIMPLE INTEREST ≡ The amount of interest computed only on the principal is called simple interest.
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 5 Bruce Mayer, PE Chabot College Mathematics Compound Interest Terms INTEREST RATE: The interest rate is the percent charged for the use of the principal for the given period. The interest rate is expressed as a decimal and denoted by r. Unless stated otherwise, it is assumed the time-base for the rate is one year; that is, r is an annual interest rate.
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 6 Bruce Mayer, PE Chabot College Mathematics Simple Interest Formula The simple interest amount, I, on a principal P at a rate r (expressed as a decimal) per year for t years is
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 7 Bruce Mayer, PE Chabot College Mathematics Example Calc Simple Interest Rosarita deposited $8000 in a bank for 5 years at a simple interest rate of 6% a)How much interest will she receive? b)How much money will she receive at the end of five years? SOLUTION a) Use the simple interest formula with: P = 8000, r = 0.06, and t = 5
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 8 Bruce Mayer, PE Chabot College Mathematics Example Calc Simple Interest SOLUTION a) Use Formula SOLUTION b) The total amount, A, due her in five years is the sum of the original principal and the interest earned
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 9 Bruce Mayer, PE Chabot College Mathematics Compound Interest Formula A = $-Amount after t years P = Principal (original $-amount) r = annual interest rate (expressed as a decimal) n = number of times interest is compounded each year t = number of years
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 10 Bruce Mayer, PE Chabot College Mathematics Compare Compounding Periods One hundred dollars is deposited in a bank that pays 5% annual interest. Find the future-value amount, A, after one year if the interest is compounded: a)Annually. b)SemiAnnually. c)Quarterly. d)Monthly. e)Daily.
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 11 Bruce Mayer, PE Chabot College Mathematics Compare Compounding Periods SOLUTION In each of the computations that follow, P = 100 and r = 0.05 and t = 1. Only n, the number of times interest is compounded each year, is changing. Since t = 1, nt = n∙1 = n. a)Annual Amount:
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 12 Bruce Mayer, PE Chabot College Mathematics Compare Compounding Periods b)Semi Annual Amount: c)Quarterly Amount:
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 13 Bruce Mayer, PE Chabot College Mathematics Compare Compounding Periods d)Monthly Amount: e)Daily Amount:
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 14 Bruce Mayer, PE Chabot College Mathematics The Value of the Natural Base e The number e, an irrational number, is sometimes called the Euler constant. Mathematically speaking, e is the fixed number that the expression approaches as h gets larger and larger The value of e to 15 places: e = 2.718281828459045
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 15 Bruce Mayer, PE Chabot College Mathematics Continuous Compound Interest The formula for Interest Compounded Continuously; e.g., a trillion times a sec. A = $-Amount after t years P = Principal (original $-amount) r = annual interest rate (expressed as a decimal) t = number of years
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 16 Bruce Mayer, PE Chabot College Mathematics Example Continuous Interest Find the amount when a principal of $8300 is invested at a 7.5% annual rate of interest compounded continuously for eight years and three months. SOLUTION: Convert 8-yrs & 3-months to 8.25 years. P = $8300 and r = 0.075 then use Formula
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 17 Bruce Mayer, PE Chabot College Mathematics Compare Continuous Compounding Italy's Banca Monte dei Paschi di Siena (MPS), the world's oldest bank founded in 1472 and is today one the top five banks in Italy If in 1795 Thomas Jefferson Placed a Deposit of $450k the MPS bank at an interest rate of 6%, then find the value $-Amount for the this Account Today, 213 years Later
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 18 Bruce Mayer, PE Chabot College Mathematics Compare Continuous Compounding SIMPLE Interest YEARLY Compounding
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 19 Bruce Mayer, PE Chabot College Mathematics
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 20 Bruce Mayer, PE Chabot College Mathematics The NATURAL Exponential Fcn The exponential function with base e is so prevalent in the sciences that it is often referred to as THE exponential function or the NATURAL exponential function.
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 21 Bruce Mayer, PE Chabot College Mathematics Compare 2 x, e x, 3 x Several Exponentials Graphically
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 22 Bruce Mayer, PE Chabot College Mathematics Example Xlate e x, Graphs Use translation to sketch the graph of SOLUTION Move e x graph: 1 Unit RIGHT 2 Units UP
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 23 Bruce Mayer, PE Chabot College Mathematics Example Graph Exponential Graph f(x) = 2 − e −3x SOLUTION Make T-Table, Connect-Dots 22 1.951 1 −18.09 −401.43 y = f(x) 0 −1−1 −2−2 x
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 24 Bruce Mayer, PE Chabot College Mathematics Exponential Growth or Decay Math Model for “Natural” Growth/Decay: A(t) = amount at time t A 0 = A(0), the initial amount k = relative rate of Growth (k > 0) Decay (k < 0) t = time
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 25 Bruce Mayer, PE Chabot College Mathematics Exponential Growth An exponential GROWTH model is a function of the form where A 0 is the population at time 0, A(t) is the population at time t, and k is the exponential growth rate The doubling time is the amount of time needed for the population to double in size A0A0 A(t)A(t) t 2A02A0 Doubling time
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 26 Bruce Mayer, PE Chabot College Mathematics Exponential Decay An exponential DECAY model is a function of the form where A 0 is the population at time 0, A(t) is the population at time t, and k is the exponential decay rate The half-life is the amount of time needed for half of the quantity to decay A0A0 A(t) t ½A 0 Half-life
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 27 Bruce Mayer, PE Chabot College Mathematics Example Exponential Growth In the year 2000, the human population of the world was approximately 6 billion and the annual rate of growth was about 2.1 percent. Using the model on the previous slide, estimate the population of the world in the years a)2030 b)1990
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 28 Bruce Mayer, PE Chabot College Mathematics Example Exponential Growth SOLUTION a) Use year 2000 as t = 0 Thus for 2030 t = 30 The model predicts there will be 11.26 billion people in the world in the year 2030
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 29 Bruce Mayer, PE Chabot College Mathematics Example Exponential Growth SOLUTION b) Use year 2000 as t = 0 Thus for 1990 t = −10 The model postdicted that the world had 4.86 billion people in 1990 (actual was 5.28 billion).
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 30 Bruce Mayer, PE Chabot College Mathematics WhiteBoard Work Problems From §9.1 Exercise Set 40, 58, 63 Calculating e
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 31 Bruce Mayer, PE Chabot College Mathematics All Done for Today World Population
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BMayer@ChabotCollege.edu MTH55_Lec-54_sec_8-5a_PolyNom_InEqual.ppt 32 Bruce Mayer, PE Chabot College Mathematics Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu Chabot Mathematics Appendix –
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