Presentation is loading. Please wait.

Presentation is loading. Please wait.

TM 661 Engineering Economics for Managers Unit 1 Time Value of Money.

Published byJustin Davidson Modified over 8 years ago

Similar presentations

Presentation on theme: "TM 661 Engineering Economics for Managers Unit 1 Time Value of Money."— Presentation transcript:

1 TM 661 Engineering Economics for Managers Unit 1 Time Value of Money

2 Time Value-of-Money Suppose we invest $100. If the bank pays 5% interest, how much will I have after 1 year? 100 F 0 1 t

3 Time Value-of-Money Suppose we invest $100. If the bank pays 5% interest, how much will I have after 1 year? 100 F1F1 0 1 t F 1 = 100 + interest = 100 + 100 (.05) = 105

4 Time Value-of-Money Now suppose I keep that $105 in the bank for another year. Now how much do I have? 100 0 1 2 t F 2 = 105 + interest = 105 + 105 (.05) = 110.25 105 F2F2

5 Time Value-of-Money In General P 0 1 2 t F 1 = P + interest = P + iP = P(1+i) F1F1

6 Time Value-of-Money In General P 0 1 2 t F 1 = P + interest = P + iP = P(1+i) F 2 = F 1 + interest = F 1 + iF 1 = F 1 (1+i) F2F2

7 Time Value-of-Money In General P 0 1 2 t F 1 = P(1+i) F 2 = F 1 + interest = F 1 + iF 1 = F 1 (1+i) = P(1+i)(1+i) = P(1+i) 2 F2F2

8 Time Value-of-Money In General P 0 1 2 3 n F n = P(1+i) n FnFn

9 Example I would like to have $20,000 for my son to go to college in 15 years. How much should I deposit now if I can earn 10% interest? F n = P(1+i) n P 0 1 2 3 n 20,000

10 Example I would like to have $20,000 for my son to go to college in 15 years. How much should I deposit now if I can earn 10% interest? Recall, F n = P(1+i) n P 0 1 2 3 n 20,000

11 Example I would like to have $20,000 for my son to go to college in 15 years. How much should I deposit now if I can earn 10% interest? Recall, F n = P(1+i) n Then, P= F n (1+i) -n P 0 1 2 3 n 20,000

12 Example I would like to have $20,000 for my son to go to college in 15 years. How much should I deposit now if I can earn 10% interest? Then, P= F n (1+i) -n = 20,000(1+.1) -15 = 20,000(0.2394) = $2,394 P 0 1 2 3 n 20,000

13 Future Worth Given Annuity Suppose I wish to compute annual installments to save for college. 0 1234.. n A F

14 Annuities Given FutureWorth F = A(1+i) n-1 + A(1+i) n-2 + A(1+i) n-3 +...+ A(1+i) + A 0 1234.. n A F

15 Annuities Given Future Worth (1+i)F = A(1+i) n + A(1+i) n-1 + A(1+i) n-2 +... + A(1+i) F = A(1+i) n-1 + A(1+i) n-2 + A(1+i) n-3 +...+ A(1+i) + A 0 1234.. n A F

16 Annuities Given Future Worth iF = A(1+i) n + 0 + 0 +... - A (1+i)F = A(1+i) n + A(1+i) n-1 + A(1+i) n-2 +... + A(1+i) F = A(1+i) n-1 + A(1+i) n-2 + A(1+i) n-3 +...+ A(1+i) + A 0 1234.. n A F

17 Annuities Given Future Worth iF = A(1+i) n + 0 + 0 +... - A = A[(1+i) n - 1] (1+i)F = A(1+i) n + A(1+i) n-1 + A(1+i) n-2 +... + A(1+i) F = A(1+i) n-1 + A(1+i) n-2 + A(1+i) n-3 +...+ A(1+i) + A 0 1234.. n A F

18 Annuities Given Future Worth iF = A[(1+i) n - 1] 0 1234.. n A F FA i i A F A in n    ) (,,) 11(

19 Annuities Given Future Worth 0 1234.. n A F AF i i n   ()11

20 Annuities Given Future Worth 0 1234.. n A F AF i i n   ()11 A     20000 1 111 2000000315 50 15, (.) (.),(.) $629.

21 Annuities Given Present Worth PAi k k n k     1 1()     Ai k k n ()1 1, for A 1 = A 2 = A 3 =... = A 0 1234.. n A P

22 Annuities Given Future Worth 0 1234.. n A1A1 F A2A2 A3A3 AnAn A4A4 FAi k k n k     0 1 1()     Ai k k n ()1 0 1, for A 1 = A 2 = A 3 =... = A

23 Annuities Given Present Worth Suppose we wish to compute the monthly payment of a car if we borrow $15,000 at 1% per month for 36 months. 0 1234.. n A P

24 Recall: F n = A and P = F n (1 + i) -n Annuities Given Present Worth 0 1234.. n A P ()11  i i n

25 Recall: and P = F n (1 + i) -n Annuities Given Present Worth 0 1234.. n A P FA i i n n   ()11 PA i i iA i ii n n n n       () () () () 11 1 11 1

26 Annuities Given Present Worth Inverting and solving for A gives 0 1234.. n A P P A i ii n n    () () 11 1 AP ii i PAPin n n     () () (/,,) 1 11

27 A= 15,000[.01(1.01) 36 /(1.01 36 - 1)] = $498.22 Car Example We have an initial loan of $15,000 at a rate of i=1% per month for n=36 months. The monthly loan payment is then 0 1234.. 36 A P

28 Car Example; Alternative We have an initial loan of $15,000 at a rate of i=1% per month for n=36 months. The monthly loan payment is then A= 15,000(A/P,i,n) = 15,000(A/P,1,36) = 15,000(.0032) = $498.21 0 1234.. 36 A P

29 Car Example; Tables

30 Example; Home Mortgage Example: Suppose we borrow $75,000 for house at 9% for 30 years. Find monthly payment. Assume that the monthly interest rate is 9/12 = 3/4%.

31 Example; Home Mortgage

32

33 Example: Suppose we borrow $75,000 for house at 9% for 30 years. Find monthly payment. Assume that the monthly interest rate is 9/12 = 3/4%. Using the Formula: A = $75,000 = $603.47 Example; Home Mortgage.(.) (.) 00751 1 1 360  

34 Home Mortgage Using the Table: A= P(A/P, i, n) = 75,000(A/P, 9, 30) = 75,000(.0973) = 7,297.5 / year » $608.12 / month

35 Gradient Series Suppose we have an investment decision which is estimated to return $1,000 in the first year, $1,100 in the second, $1,200 in the third, and so on for the 7 year life of the project. P 123 0 7 1600 1000 1100 1200

36 Gradient Equivalent Flows We can replace the cash flow as the equivalent of an annuity and a constant growth P A 123 0 n AAAA + P G 123 0 n (n-1)G G 2G

37 P W = P A + P G P A = A (P/A, i, n) P G = 0(1+i) -1 + G(1+i) -2 + 2G(1+i) -3 +... Gradient Derivation P A 123 0 n AAAA + P G 123 0 n (n-1)G G 2G

38 Gradient Derivation (1+i)P G = G[ (1+i) -1 + 2(1+i) -2 + 3(1+i) -3 +4(1+i) -4 ] P G = G[ (1+i) -2 + 2(1+i) -3 + 3(1+i) -4 +4(1+i) -5 ]

39 Gradient Derivation (1+i)P G = G[ (1+i) -1 + 2(1+i) -2 + 3(1+i) -3 +4(1+i) -4 ] P G = G[ (1+i) -2 + 2(1+i) -3 + 3(1+i) -4 +4(1+i) -5 ] iP G = G[ (1+i) -1 + (1+i) -2 + (1+i) -3 +(1+i) -4 - 4(1+i) -5 ]

40 Gradient Derivation (1+i)P G = G[ (1+i) -1 + 2(1+i) -2 + 3(1+i) -3 +4(1+i) -4 ] P G = G[ (1+i) -2 + 2(1+i) -3 + 3(1+i) -4 +4(1+i) -5 ] iP G = G[ (1+i) -1 + (1+i) -2 + (1+i) -3 +(1+i) -4 - 4(1+i) -5 ] A Miracle Occurs P G = G[( 1 - (1+ni)(1+i) -n )/ i 2 ]

41 Example Estimated return of $1,000 in the first year, $1,100 in the second, $1,200 in the third, and so on for the 7 year life of the project. P G = A(P/A,10,7) +G(P/G,10,7) = 1000(4.8684) +100(12.7631) = $6,144.71 P 123 0 7 1600 1000 1100 1200

42 Determine PW of a depreciation scheme which saves $1000 in the first year and declines by $100 per year for the next 10 years if i = 10% Depreciation Example PWPW 123 0 10 1000 900 800 100

43 Example; (cont.) PW= 1000(P/A, 10, 10) - 100(P/G, 10, 10) = 1000(6.1446) - 100(22.8913) = $3,855.47 0 PAPA 123 10 1000 + PGPG 123 0 10 900 100 200

44 Gradient Alternative A = G(A/G, 10, 10) = 100(3.7255) = $372.55 P W = (1000 - 372.55)(P/A, 10, 10) = 627.45(6.1446) = $3,855.43 0 PAPA 123 10 1000 + PGPG 123 0 10 900 100 200

45 Geometric Series Suppose we start a new computer consultant business. We assume that we will start our business with a modest income but that the business will grow at a rate of 10% per year. If we assume an initial return of 1000 and a growth rate of 10% over 4 years, the cash flow diagram might appear as follows. 123 0 4 1000 1100 1210 1331

46 Geometric Series P= A 1 (1 + i) -1 + A 2 (1 + i) -2 +......+A n (1 + i) -n = A(1 + i) -1 + A(1 + j)(1 + i) -2 + A(1 + j) 2 (1 + i) -3 +..... + A(1 + j) n - 1 (1 + i) -n = A ()()11 1 1     ji tt t n P 123 0 n A A(1+j) A(1+j) 2 A(1+j) n-1

47 Geometric Series Special Case: For the special case where i = j, we have P = A = A ()()11 1 1     ii tt t n ()1 1 1     i t n

48 Geometric Series Special Case: For the special case where i = j, we have P = A = A P = ()()11 1 1     ii tt t n ()1 1 1     i t n nA i()1 

49 Geometric Series Case i j: For the case when the interest rate i and the growth rate j are not equal, we have P = A = A(P/A,i,j,n) ()()11 1 1     ji tt t n Miracle 2 Occurs  PA ji ij nn     111()()

50 Geometric Series Case i j: For the case when the interest rate i and the growth rate j are not equal, we have P = A ()()11 1 1     ji tt t n Miracle 2 Occurs  PA ji ij nn     111()()       A j j i t n t (1) 1 1 1

51 Example; Geometric Computer business has initial return of 1000 and a growth rate of 10% over 4 years, the cash flow diagram might appear as follows. If i = 10%, 123 0 4 1000 1100 1210 1331

52 Example; Geometric Computer business has initial return of 1000 and a growth rate of 10% over 4 years, the cash flow diagram might appear as follows. If i = 10%, P = 1000(P/A,i,j,n) = 1000(P/A,10,10,4) = 1000(3.6363) = $3,636 123 0 4 1000 1100 1210 1331

53 Example Example: Individual deposits of $1000 in end of year 1 and increases by 10% each year for 30 years. If the account earns 10% per year, how much will he have at end of 30 years?

54 Example (Cont). Solution: F = A(F/A, i, j, n) = 1000((F/A, 10, 10, 30) = 1000(475.8934) = $475,893 Alternative Solution: F = 1000(30)(1 +.10) 29 = $475,892

55 Summary F n = P(1 + i) n = P(F/P,i,n) P = F n (1 + i) -n = F(P/F,i,n) F n 12340n 100..

56 Summary = A(F/A,i,n) = F n (A/F,i,n) 01234.. n A F n FA i i n n   ()11 AF i i n n   ()11

57 Summary = A(P/A,i,n) = P(A/P,i,n) 0 1234.. n A P PA i ii n n    () () 11 1 AP ii i n n    () () 1 11

58 Summary P G = G = G(P/G,i,n) A= G = G (A/G, i, n) 123 0 n (n-1)G G 2G 1 i 11 n ii n   [() 111 2   ()()nii i n

59 Summary Case i j P = A = A(P/A,i,j,n) F = A = A(F/A,i,j,n) P 123 0 n A A(1+j) A(1+j) 2 A(1+j) n-1 ()()11   ij ij nn 111    ()()ji ij nn 

60 Break Time

61 Geometric Derivation 01234.. n A F n     Ai k k n ()1 0 1 F

62 Geometric Derivation 01234.. n A F n     Ai k k n ()1 0 1 F Recall the geometric series x x x k k n n       0 1 1 1 Letting x = (1+i) k

63 Geometric Derivation 01234.. n A F n     Ai k k n ()1 0 1 F Recall the geometric series x x x k k n n       0 1 1 1 Letting x = (1+i) k  Fx k  k  0 n  1

64 Geometric Derivation 01234.. n A F n    1 1 x x n  Fx k  k  0 n  1

65 Geometric Derivation 01234.. n A F n    1 1 x x n  Fx k  k  0 n  1     11 11 1() () i i n   1()i i n A

66 1  Geometric Derivation 01234.. n A F n    1 1 x x n  Fx k  k  0 n  1     11 11 1() () i i n   1()i i n A FA i i A F A in n   () (,,) 1

Download ppt "TM 661 Engineering Economics for Managers Unit 1 Time Value of Money."

Similar presentations

Chapter 4 More Interest Formulas

Chapter 4 More Interest Formulas
Example 1: In the following cash flow diagram, A8=A9=A10=A11=5000, and

Example 1: In the following cash flow diagram, A8=A9=A10=A11=5000, and
Engineering Economics I

Engineering Economics I
1 Warm-Up Review Homepage Rule of 72 Single Sum Compounding Annuities.

1 Warm-Up Review Homepage Rule of 72 Single Sum Compounding Annuities.
Net Present Value.

Net Present Value.
The Time Value of Money Chapter 8 October 3, 2012.

The Time Value of Money Chapter 8 October 3, 2012.
Engineering Economics

Engineering Economics
Engineering Economics Outline Overview

Engineering Economics Outline Overview
Example 1 Ms. Smith loans Mr. Brown $10,000 with interest compounded at a rate of 8% per year. How much will Mr. Brown owe Ms. Smith if he repays the loan.

Example 1 Ms. Smith loans Mr. Brown $10,000 with interest compounded at a rate of 8% per year. How much will Mr. Brown owe Ms. Smith if he repays the loan.
Chapter 2 Solutions 1 TM 661Chapter 2 Solutions 1 # 9) Suppose you wanted to become a millionaire at retirement. If an annual compound interest rate of.

Chapter 2 Solutions 1 TM 661Chapter 2 Solutions 1 # 9) Suppose you wanted to become a millionaire at retirement. If an annual compound interest rate of.
(c) 2002 Contemporary Engineering Economics 1 Chapter 4 Time Is Money Interest: The Cost of Money Economic Equivalence Development of Interest Formulas.

(c) 2002 Contemporary Engineering Economics 1 Chapter 4 Time Is Money Interest: The Cost of Money Economic Equivalence Development of Interest Formulas.
Borrowing, Lending, and Investing

Borrowing, Lending, and Investing
© 2012 by McGraw-Hill, New York, N.Y All Rights Reserved 3-1 Lecture slides to accompany Engineering Economy 7 th edition Leland Blank Anthony Tarquin.

© 2012 by McGraw-Hill, New York, N.Y All Rights Reserved 3-1 Lecture slides to accompany Engineering Economy 7 th edition Leland Blank Anthony Tarquin.
State University of New York WARNING All rights reserved. No part of the course materials used in the instruction of this course may be reproduced in any.

State University of New York WARNING All rights reserved. No part of the course materials used in the instruction of this course may be reproduced in any.
Module 3 ANNUITY Engr. Gerard Ang School of EECE.

Module 3 ANNUITY Engr. Gerard Ang School of EECE.
(c) 2002 Contemporary Engineering Economics

(c) 2002 Contemporary Engineering Economics
(c) 2002 Contemporary Engineering Economics

(c) 2002 Contemporary Engineering Economics
Interest Formulas – Equal Payment Series

Interest Formulas – Equal Payment Series
Flash Back from before break The Five Types of Cash Flows (a) Single cash flow (b) Equal (uniform) payment series (c) Linear gradient series (d) Geometric.

Flash Back from before break The Five Types of Cash Flows (a) Single cash flow (b) Equal (uniform) payment series (c) Linear gradient series (d) Geometric.
Chapter 2 Factors: How Time and Interest Affect Money

Chapter 2 Factors: How Time and Interest Affect Money

Similar presentations

Ads by Google