ENGM 661 Engineering Economics for Managers

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

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

Time Value-of-Money • Suppose we invest $100. If the bank pays 5% interest, how much will I have after 1 year? F1 F1 = 100 + interest = 100 + 100 (.05) = 105 0 1 t 100

Time Value-of-Money • Now suppose I keep that $105 in the bank for another year. Now how much do I have? F2 F2 = 105 + interest = 105 + 105 (.05) = 110.25 0 1 2 t 100 105

Time Value-of-Money • In General F1 F1 = P + interest = P + iP = P(1+i) 0 1 2 t P

Time Value-of-Money • In General F2 F1 = P + interest = P + iP = P(1+i) F2 = F1 + interest = F1 + iF1 = F1(1+i) 0 1 2 t P

Time Value-of-Money • In General F2 F1 = P(1+i) F2 = F1 + interest = F1 + iF1 = F1(1+i) = P(1+i)(1+i) = P(1+i)2 0 1 2 t P

Time Value-of-Money Fn • In General Fn = P(1+i)n 0 1 2 3 n P

20,000 0 1 2 3 n P 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? Fn = P(1+i)n

20,000 0 1 2 3 n P 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, Fn = P(1+i)n

20,000 0 1 2 3 n P 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, Fn = P(1+i)n Then, P = Fn(1+i)-n

20,000 0 1 2 3 n P 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 = Fn(1+i)-n = 20,000(1+.1)-15 = 20,000(0.2394) = $2,394

F 1 2 3 4 n 0 . . . . A Future Worth Given Annuity • Suppose I wish to compute annual installments to save for college.

F 1 2 3 4 n 0 . . . . A Annuities Given FutureWorth F = A(1+i)n-1 + A(1+i)n-2 + A(1+i)n-3+...+ A(1+i)+ A

F 1 2 3 4 n 0 . . . . A F = A(1+i)n-1 + A(1+i)n-2 + A(1+i)n-3+...+ A(1+i)+ A (1+i)F = A(1+i)n + A(1+i)n-1 + A(1+i)n-2 + . . . + A(1+i) Annuities Given Future Worth

F 1 2 3 4 n 0 . . . . A F = A(1+i)n-1 + A(1+i)n-2 + A(1+i)n-3+...+ A(1+i)+ A 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) Annuities Given Future Worth

F 1 2 3 4 n 0 . . . . A F = A(1+i)n-1 + A(1+i)n-2 + A(1+i)n-3+...+ A(1+i)+ A 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) Annuities Given Future Worth

F 1 2 3 4 n 0 . . . . A Annuities Given Future Worth iF = A[(1+i)n - 1] + - n ( 1 i ) 1 F = = F A A ( , i , n ) i A

F i 1 2 3 4 n = A F 0 . . . . + - n ( 1 i ) 1 A Annuities Given Future Worth

F i 1 2 3 4 n = A F 0 . . . . + - n ( 1 i ) 1 A (. 1 ) = A 20 , 000 + - 15 ( 1 . 1 ) 1 = 20 , 000 ( 0 . 0315 ) = $629 . 50 Annuities Given Future Worth

P 1 2 3 4 n 0 . . . . n  k A  P  A ( 1  i ) k k  1 n  k   A ( 1  i ) k  1 Annuities Given Present Worth , for A1 = A2 = A3 = ... = A

n  1 k  F  A ( 1  i ) k k  0 n  1 k   A ( 1  i ) , for A1 = A2 = A3 = . . . = A k  0 Annuities Given Future Worth F 1 2 3 4 n 0 . . . . A1 A2 A3 A4 An

P 1 2 3 4 n 0 . . . . A 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.

P n ( 1  i )  1 1 2 3 4 n i 0 . . . . A Annuities Given Present Worth • Recall: • Fn = A • and • P = Fn(1 + i) -n

P 1 2 3 4 n 0 . . . . A + n i ( 1 i ) = = A P P ( A / P , i , n ) + - n ( 1 i ) 1 + - n ( 1 i ) 1 = P A + n i ( 1 i ) Annuities Given Present Worth • Inverting and solving for A gives

P 1 2 3 4 36 0 . . . . A 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 A = 15,000[.01(1.01)36/(1.0136 - 1)] = $498.22

P 1 2 3 4 36 0 . . . . A 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

Car Example; Tables

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%.

1600 1200 1100 1000 0 1 2 3 7 P 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.

(n-1)G 2G G A A A A + 0 0 1 2 3 1 2 3 n n P P A G Gradient Equivalent Flows • We can replace the cash flow as the equivalent of an annuity and a constant growth

(n-1)G 2G G A A A A + 0 0 1 2 3 1 2 3 n n P P A G Gradient Derivation • PW = PA + PG • PA = A (P/A, i, n) • PG = 0(1+i)-1 + G(1+i)-2 + 2G(1+i)-3 +...

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

Gradient Derivation • (1+i)PG = G[ (1+i)-1 + 2(1+i)-2 + 3(1+i)-3 +4(1+i)-4 ] • PG = G[ (1+i)-2+ 2(1+i)-3 + 3(1+i)-4 +4(1+i)-5 ] • iPG = G[ (1+i)-1 + (1+i)-2 + (1+i)-3 +(1+i)-4 - 4(1+i)-5 ]

1600 1200 1100 1000 0 1 2 3 7 P 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. • PG = A(P/A,10,7) +G(P/G,10,7) • = 1000(4.8684) +100(12.7631) • = $6,144.71

1000 900 800 100 0 1 2 3 10 PW Depreciation Example • 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%

PG 1000 1000 1000 1000 1 2 3 10 + 0 1 2 3 0 10 100 200 PA 900 Example; (cont.) • PW = 1000(P/A, 10, 10) - 100(P/G, 10, 10) • = 1000(6.1446) - 100(22.8913) • = $3,855.47

PG 1000 1000 1000 1000 1 2 3 10 + 0 1 2 3 0 10 100 200 PA 900 Gradient Alternative • A = G(A/G, 10, 10) • = 100(3.7255) • = $372.55 • PW = (1000 - 372.55)(P/A, 10, 10) • = 627.45(6.1446) • = $3,855.43

1331 1210 1100 1000 0 1 2 3 4 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.

A(1+j)n-1 A(1+j)2 A(1+j) A 0 1 2 3 n P n  t  1  t ( 1  j ) ( 1  i ) t  1 Geometric Series • P = A1(1 + i)-1 + A2(1 + i)-2 +......+An(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

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

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

1331 1210 1100 1000 0 1 2 3 4 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%,

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?

F n Summary • Fn = P(1 + i)n = P(F/P,i,n) • P = Fn(1 + i)-n = F(P/F,i,n) 0 1 2 3 4 . . . . n 100

F n 0 1 2 3 4 n . . . . A + - n ( 1 i ) 1 = F A n i i = A F n + - n ( 1 i ) 1 Summary • = A(F/A,i,n) • = Fn(A/F,i,n)

+ - n ( 1 i ) 1 = P A + n i ( 1 i ) + n i ( 1 i ) = A P + - n ( 1 i ) 1 Summary P • = A(P/A,i,n) • = P(A/P,i,n) 1 2 3 4 n 0 . . . . A

 n 1  ( 1  ni )( 1  i ) 2 i 1 n  n i i [( 1  i )  1 Summary (n-1)G 2G G • PG = G = G(P/G,i,n) • A = G = G (A/G, i, n) 0 1 2 3 n

A(1+j)n-1 A(1+j)2 A(1+j) A 0 1 2 3 n P n  n 1  ( 1  j ) ( 1  i ) i  j n n ( 1  i )  ( 1  j ) i  j Summary • Case i j • P = A = A(P/A,i,j,n) • F = A = A(F/A,i,j,n) ¹

Break Time

ENGM 661 Engineering Economics for Managers