1 / 48

Warm-Up Review

Warm-Up Review. Homepage Rule of 72 Single Sum Compounding Annuities. Homepage is Important. Homepage has everything All Slides ……… (important) Lecture outline Quiz and project ..time. location Class/Quiz/Tutorial information Teaching Group (1+4) contact www.ece.uvic.ca/~wli.

kalia-neal
Download Presentation

Warm-Up Review

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Warm-Up Review • Homepage • Rule of 72 • Single Sum Compounding • Annuities

  2. Homepage is Important • Homepage has everything • All Slides ……… (important) • Lecture outline • Quiz and project ..time. location • Class/Quiz/Tutorial information • Teaching Group (1+4) contact • www.ece.uvic.ca/~wli

  3. The Rule of 72 • Estimates how many years an investment will take to double in value • Number of years to double = 72 / annual compound interest rate • Example -- 72 / 8 = 9 therefore, it will take 9 years for an investment to double in value if it earns 8% annually

  4. Example: Double Your Money!!! Quick!How long does it take to double $5,000 at a compound rate of 12% per year? Approx. Years to Double = 72/ i% • 72 / 12% = 6 Years • [Actual Time is 6.12 Years]

  5. Single Sum Problems: Future Value Given: • Amount of deposit today (PV):$50,000 • Interest rate: 11% • Frequency of compounding: Annual • Number of periods (5 years): 5 periods What is the future value of this single sum? FVn = PV(1 + i)n $50,000 x (1.68506) = $84,253

  6. Single Sum Problems: Present Value Given: • Amount of deposit end of 5 years: $84,253 • Interest rate (discount) rate: 11% • Frequency of compounding: Annual • Number of periods (5 years): 5 periods What is the present value of this single sum? • FVn = PV(1 + i)n $84,253 x (0.59345) = $50,000

  7. Annuity Computations An annuity requires that: • the periodic payments or receipts (rents) always be of the same amount, • the interval between such payments or receipts be the same, and • the interest be compounded once each interval.

  8. If one saves $1,000 a year at the end of every year for three years in an account earning 7% interest, compounded annually, how much will one have at the end of the third year? Example of Annuity End of Year 0 1 2 3 4 7% $1,000 $1,000 $1,000 $1,070 $1,145 $3,215 = FVA3 FVA3 = $1,000(1.07)2 + $1,000(1.07)1 + $1,000(1.07)0 = $3,215

  9. Annuities: Future Value Given: • Deposit made at the end of each period: $5,000 • Compounding: Annual • Number of periods: Five • Interest rate: 12% What is future value of these deposits? F = A[(1+i)n - 1] / i $5,000 x (6.35285) = $ 31,764.25

  10. Annuities: Present Value Given: • Rental receipts at the end of each period: $6,000 • Compounding: Annual • Number of periods (years): 5 • Interest rate: 12% What is the present value of these receipts? F = A[(1+i)n - 1] / i $6,000 x (3.60478) = $ 21,628.68

  11. Key of Annuity Calculation Fv = Pv[(1+i)n - 1] / i

  12. Topics Today • Single Payment, Present/Future Value Factor • Sinking Factor, Capital Recovery Factor • Conversion for Arithmetic Gradient Series • Conversion for Geometric Gradient Series

  13. Compound Amount Factor (Single Payment) • This factor finds the equivalent future worth, F, of a present investment, P, held for n periods at i rate of interest. • Example: What is the value in 9 years of $1,200 invested now at 10% interest

  14. Compound Amount Factor (Single Payment) F 1 2 3 4 9 P = $1,200

  15. Present Worth Factor (Single Payment) • This factor finds the equivalent present value, P, of a single future cash flow, F, occurring at n periods in the future when the interest rate is i per period. • Example: What amount would you have to invest now to yield $2,829 in 9 years if the interest rate per year is 10%?

  16. Present Worth Factor (Single Payment) F = $2,829 1 2 3 4 9 P

  17. Compound Amount Factor(Uniform Series) • This factor finds the equivalent future value, F, of the accumulation of a uniform series of equal annual payments, A, occurring over n periods at i rate of interest per period. • Example: What would be the future worth of an annual year-end cash flow of $800 for 6 years at 12% interest per year?

  18. Compound Amount Factor (Uniform Series) F 1 2 3 4 5 6 $800 $800 $800 $800 $800 $800

  19. Sinking Fund Factor • This factor determines how much must be deposited each period in a uniform series, A, for n periods at i interest per period to yield a specified future sum. • Example: If a $1.2 million bond issue is to be retired at the end of 20 years, how much must be deposited annually into a sinking fund at 7% interest per year?

  20. Sinking Fund Factor F = $1,200,000 1 2 3 4 20 A A A A A A

  21. Capital Recovery Factor • This factor finds an annuity, or uniform series of payments, over n periods at i interest per period that is equivalent to a present value, P. • Example: What savings in annual manufacturing costs over an 8 year period would justify the purchase of a $120,000 machine if the firm’s minimum attractive rate of return (MARR) were 25%?

  22. Capital Recovery Factor A A A A A 1 2 3 8 $120,000

  23. Present Worth Factor(Uniform Series) • This factor finds the equivalent present value, P, of a series of end-of-period payments, A, for n periods at i interest per period. • Example: What lump sum payment would be required to provide $50,000 per year for 30 years at an annual interest rate of 9%?

  24. Present Worth Factor(Uniform Series) $50,000 $50,000 $50,000 $50,000 $50,000 1 2 3 30 P

  25. Series and Arithmetic Series • A series is the sum of the terms of a sequence. • The sum of an arithmetic progression (an arithmetic series, difference between one and the previous term is a constant) • Can we find a formula so we don’t have to add up every arithmetic series we come across?

  26. Sum of terms of a finite AP

  27. Arithmetic Gradient Series • A series of N receipts or disbursements that increase by a constant amount from period to period. • Cash flows: 0G, 1G, 2G, ..., (N–1)G at the end of periods 1, 2, ..., N • Cash flows for arithmetic gradient with base annuity: A', A’+G, A'+2G, ..., A'+(N–1)G at the end of periods 1, 2, ..., N where A’ is the amount of the base annuity

  28. Arithmetic Gradient to Uniform Series • Finds A, given G, i and N • The future amount can be “converted” to an equivalent annuity. The factor is: • The annuity equivalent (not future value!) to an arithmetic gradient series is A = G(A/G, i, N)

  29. Arithmetic Gradient to Uniform Series • The annuity equivalent to an arithmetic gradient series is A = G(A/G, i, N) • If there is a base cash flow A', the base annuity A' must be included to give the overall annuity: Atotal = A' + G(A/G, i, N) • Note that A' is the amount in the first year and G is the uniform increment starting in year 2.

  30. Arithmetic Gradient Series with Base Annuity

  31. Example 3-8 • A lottery prize pays $1000 at the end of the first year, $2000 the second, $3000 the third, etc., for 20 years. If there is only one prize in the lottery, 10 000 tickets are sold, and you can invest your money elsewhere at 15% interest, how much is each ticket worth, on average?

  32. Example 3-8: Answer • Method 1: First find annuity value of prize and then find present value of annuity. A' = 1000, G = 1000, i = 0.15, N = 20 A = A' + G(A/G, i, N) = 1000 + 1000(A/G, 15%, 20) = 1000 + 1000(5.3651) = 6365.10 • Now find present value of annuity: P = A (P/A, i, N) where A = 6365.10, i = 15%, N = 20 P = 6365.10(P/A, 15, 20) = 6365.10(6.2593) = 39 841.07 • Since 10 000 tickets are to be sold, on average each ticket is worth (39 841.07)/10,000 = $3.98.

  33. Arithmetic Gradient Conversion Factor(to Uniform Series) • The arithmetic gradient conversion factor (to uniform series) is used when it is necessary to convert a gradient series into a uniform series of equal payments. • Example: What would be the equal annual series, A, that would have the same net present value at 20% interest per year to a five year gradient series that started at $1000 and increased $150 every year thereafter?

  34. Arithmetic Gradient Conversion Factor(to Uniform Series) 1 2 3 4 5 1 2 3 4 5 $1000 $1150 A A A A A $1300 $1450 $1600

  35. Arithmetic Gradient Conversion Factor(to Present Value) • This factor converts a series of cash amounts increasing by a gradient value, G, each period to an equivalent present value at i interest per period. • Example: A machine will require $1000 in maintenance the first year of its 5 year operating life, and the cost will increase by $150 each year. What is the present worth of this series of maintenance costs if the firm’s minimum attractive rate of return is 20%?

  36. Arithmetic Gradient Conversion Factor(to Present Value) $1600 $1450 $1300 $1150 $1000 1 2 3 4 5 P

  37. Geometric Gradient Series • A series of cash flows that increase or decrease by a constant proportion each period • Cash flows: A, A(1+g), A(1+g)2, …, A(1+g)N–1 at the end of periods 1, 2, 3, ..., N • g is the growth rate, positive or negative percentage change • Can model inflation and deflation using geometric series

  38. Geometric Series • The sum of the consecutive terms of a geometric sequence or progression is called a geometric series. • For example: Is a finite geometric series with quotient k. • What is the sum of the n terms of a finite geometric series

  39. Sum of terms of a finite GP • Where a is the first term of the geometric progression, k is the geometric ratio, and n is the number of terms in the progression.

  40. Geometric Gradient to Present Worth • The present worth of a geometric series is: • Where A is the base amount and g is the growth rate. • Before we may get the factor, we need what is called a growth adjusted interest rate:

  41. Geometric Gradient to Present Worth Factor: (P/A, g, i, N) Four cases: (1) i > g > 0: i° is positive  use tables or formula (2) g < 0: i° is positive  use tables or formula (3) g > i > 0: i° is negative  Must use formula (4) g = i > 0: i° = 0 

  42. Compound Interest FactorsDiscrete Cash Flow, Discrete Compounding

  43. Compound Interest FactorsDiscrete Cash Flow, Discrete Compounding

  44. Compound Interest FactorsDiscrete Cash Flow, Continuous Compounding

  45. Compound Interest FactorsDiscrete Cash Flow, Continuous Compounding

  46. Compound Interest FactorsContinuous Uniform Cash Flow, Continuous Compounding

  47. Calculator Talk • No programmable • No economic Function • Simple the best • Trust your ability • Trust your teaching group

  48. Summary • Single Sum Compounding • Annuities • Conversion for Arithmetic Gradient Series • Conversion for Geometric Gradient Series • Key: Compound Interests Calculation

More Related