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(c) 2002 Contemporary Engineering Economics 1. Engineers must work within the realm of economics and justification of engineering projectsEngineers must.

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Presentation on theme: "(c) 2002 Contemporary Engineering Economics 1. Engineers must work within the realm of economics and justification of engineering projectsEngineers must."— Presentation transcript:

1 (c) 2002 Contemporary Engineering Economics 1. Engineers must work within the realm of economics and justification of engineering projectsEngineers must work within the realm of economics and justification of engineering projects Engineers play a major role in capital investment decisions based on their analysis, synthesis, and design effort. Engineers play a major role in capital investment decisions based on their analysis, synthesis, and design effort. - formulating, estimatingevaluating the economic outcome - formulating, estimating, and evaluating the economic outcome Finance is a study of value and resource allocation Finance is a study of value and resource allocation - cost of capital - determining the least expensive source of funds Engineering Economy vs Finance ?

2 (c) 2002 Contemporary Engineering Economics 2. Time is Money The Cost of Money : InterestThe Cost of Money : Interest Economic Equivalence Economic Equivalence Geometric Gradient Geometric Gradient Lecture 6

3 (c) 2002 Contemporary Engineering Economics 3. ENINEERING ECONOMIC ANALYSIS (3) TIME VALUE OF MONEY TIME VALUE OF MONEY INTEREST RATE INTEREST RATE MEASURE OF WORTH MEASURE OF WORTH Present worth Future worth Payback period Annual worth Rate of return Benefit/cost ratio Capitalized cost CASH FLOWS Income and cost estimates Financing Tax laws

4 (c) 2002 Contemporary Engineering Economics 4 Money has a time value because it can earn more money over time (earning power). Time value of money is measured in terms of interest rate. Interest is the cost of money—a cost to the borrower and an earning to the lender The change in the amount of money over a given time period is called the time value of money; by far, the most important concept in engineering economy

5 (c) 2002 Contemporary Engineering Economics 5 Repayment Plans End of YearReceiptsPayments Plan 1Plan 2 Year 0$20,000.00 $200.00 Year 15,141.850 Year 25,141.850 Year 35,141.850 Year 45,141.850 Year 55,141.8530,772.48 P = $20,000, A = $5,141.85, F = $30,772.48

6 (c) 2002 Contemporary Engineering Economics 6 Cash Flow Diagram

7 (c) 2002 Contemporary Engineering Economics 7 Methods of Calculating Interest Simple interest: the practice of charging an interest rate only to an initial sum (principal amount). Compound interest: the practice of charging an interest rate to an initial sum and to any previously accumulated interest that has not been withdrawn.

8 (c) 2002 Contemporary Engineering Economics 8 Simple Interest P = Principal amount i = Interest rate N = Number of interest periods Example: –P = $1,000 –i = 8% –N = 3 years End of Year Beginning Balance Interest earned Ending Balance 0$1,000 1 $80$1,080 2 $80$1,160 3 $80$1,240 F = P + I = P(1 + iN)

9 (c) 2002 Contemporary Engineering Economics 9 Compound Interest P = Principal amount i = Interest rate N = Number of interest periods Example: –P = $1,000 –i = 8% –N = 3 years End of Year Beginning Balance Interest earned Ending Balance 0$1,000 1 $80$1,080 2 $86.40$1,166.40 3 $93.31$1,259.71

10 (c) 2002 Contemporary Engineering Economics 10 Comparing Simple to Compound Interest

11 (c) 2002 Contemporary Engineering Economics 11 Economic Equivalence What do we mean by “economic equivalence?” Why do we need to establish an economic equivalence? How do we establish an economic equivalence?

12 (c) 2002 Contemporary Engineering Economics 12 Economic Equivalence Economic equivalence exists between cash flows that have the same economic effect and could therefore be traded for one another. Even though the amounts and timing of the cash flows may differ, the appropriate interest rate makes them equal.

13 (c) 2002 Contemporary Engineering Economics 13 Typical Repayment Plans for a Bank Loan of $20,000 Repayments Plan 1Plan 2Plan 3 Year 1$5,141.850$1,800.00 Year 25,141.8501,800.00 Year 35,141.8501,800.00 Year 45,141.8501,800.00 Year 55,141.85$30,772.4821,800.00 Total of payments $25,709.25$30,772.48$29,000.00 Total interest paid $5,709.25$10,772.48$9,000.00

14 (c) 2002 Contemporary Engineering Economics 14 If you deposit P dollars today for N periods at i, you will have F dollars at the end of period N. F dollars at the end of period N is equal to a single sum P dollars now, if your earning power is measured in terms of interest rate i. N F P 0

15 (c) 2002 Contemporary Engineering Economics 15 Equivalence Between Two Cash Flows Step 1: Determine the base period, say, year 5. Step 2: Identify the interest rate to use. Step 3: Calculate equivalence value. $3,000$2,042 50

16 (c) 2002 Contemporary Engineering Economics 16 Example 4.5 Equivalence Various dollar amounts that will be economically equivalent to $3,000 in 5 years, given an interest rate of 8%

17 (c) 2002 Contemporary Engineering Economics 17 Equivalent Cash Flows are Equivalent at Any Common Point In Time

18 (c) 2002 Contemporary Engineering Economics 18 Example 4.5 Equivalence Calculations with Multiple Payments

19 (c) 2002 Contemporary Engineering Economics 19 Types of Cash Flows (a)Single cash flow (b)Equal (uniform) payment series (c)Linear gradient series (d)Geometric gradient series (e)Irregular payment series

20 (c) 2002 Contemporary Engineering Economics 20 Single Cash Flow Formula Single payment compound amount factor (growth factor) Given: Find: P F N 0

21 (c) 2002 Contemporary Engineering Economics 21 Single Cash Flow Formula Single payment present worth factor (discount factor) Given: Find: P F N 0

22 (c) 2002 Contemporary Engineering Economics 22 Uneven Payment Series

23 (c) 2002 Contemporary Engineering Economics 23 Example 4.12 Calculating the Actual Worth of a Long-Term Contract

24 (c) 2002 Contemporary Engineering Economics 24 Equal Payment Series A 0 1 2 3 4 5 N-1 N F P

25 (c) 2002 Contemporary Engineering Economics 25 Equal Payment Series Compound Amount Factor Example 4.13: Given: A = $3,000, N = 10 years, and i = 7% Find: F Solution: F = $3,000(F/A,7%,10) = $41,449.20 0 1 2 3 N F A

26 (c) 2002 Contemporary Engineering Economics 26 Sinking Fund Factor Example 4.15: Given: F = $5,000, N = 5 years, and i = 7% Find: A Solution: A = $5,000(A/F,7%,5) = $869.50 0 1 2 3 N F A

27 (c) 2002 Contemporary Engineering Economics 27 Capital Recovery Factor Example 4.16: Given: P = $250,000, N = 6 years, and i = 8% Find: A Solution: A = $250,000(A/P,8%,6) = $54,075 1 2 3 N P A 0

28 (c) 2002 Contemporary Engineering Economics 28 Equal Payment Series Present Worth Factor Example 4.18: Given: A = $32,639, N = 9 years, and i = 8% Find: P Solution: P = $32,639(P/A,8%,9) = $203,893 1 2 3 N P A 0

29 (c) 2002 Contemporary Engineering Economics 29 Linear Gradient Series P

30 (c) 2002 Contemporary Engineering Economics 30 Gradient Series as a Composite Series

31 (c) 2002 Contemporary Engineering Economics 31 Example 4.20 $1,000 $1,250 $1,500 $1,750 $2,000 1 2 3 4 5 0 P =? How much do you have to deposit now in a savings account that earns a 12% annual interest, if you want to withdraw the annual series as shown in the figure?

32 (c) 2002 Contemporary Engineering Economics 32 Method 1: $1,000 $1,250 $1,500 $1,750 $2,000 1 2 3 4 5 0 P =? $1,000(P/F, 12%, 1) = $892.86 $1,250(P/F, 12%, 2) = $996.49 $1,500(P/F, 12%, 3) = $1,067.67 $1,750(P/F, 12%, 4) = $1,112.16 $2,000(P/F, 12%, 5) = $1,134.85 $5,204.03

33 (c) 2002 Contemporary Engineering Economics 33 Method 2:

34 (c) 2002 Contemporary Engineering Economics 34 Geometric Gradient Series

35 (c) 2002 Contemporary Engineering Economics 35 Example 4.24 Geometric Gradient: Find P, Given A 1,g,i,N Given: g = 7% i = 12% N = 5 years A 1 = $54,440 Find: P

36 (c) 2002 Contemporary Engineering Economics 36 Unconventional Equivalence Calculations Situation 1: If you make 4 annual deposits of $100 in your savings account which earns a 10% annual interest, what equal annual amount can be withdrawn over 4 subsequent years?

37 (c) 2002 Contemporary Engineering Economics 37 Unconventional Equivalence Calculations Situation 2: What value of A would make the two cash flow transactions equivalent if i = 10%?

38 (c) 2002 Contemporary Engineering Economics 38

39 (c) 2002 Contemporary Engineering Economics 39

40 (c) 2002 Contemporary Engineering Economics 40 Summary Money has a time value because it can earn more money over time. Economic equivalence exists between individual cash flows and/or patterns of cash flows that have the same value. Even though the amounts and timing of the cash flows may differ, the appropriate interest rate makes them equal. The purpose of developing various interest formulas was to facilitate the economic equivalence computation.


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