EGR 403 Capital Allocation Theory Dr. Phillip R. Rosenkrantz

1. Chapter 4More Interest FormulasClick here for Streaming Audio To Accompany Presentation (optional) EGR 403 Capital Allocation Theory Dr. Phillip R. Rosenkrantz Industrial & Manufacturing Engineering Department Cal Poly Pomona

2. EGR 403 - The Big Picture • Framework:Accounting& Breakeven Analysis • “Time-value of money” concepts - Ch. 3, 4 • Analysis methods • Ch. 5 - Present Worth • Ch. 6 - Annual Worth • Ch. 7, 8 - Rate of Return (incremental analysis) • Ch. 9 - Benefit Cost Ratio & other techniques • Refining the analysis • Ch. 10, 11 - Depreciation & Taxes • Ch. 12 - Replacement Analysis EGR 403 - Cal Poly Pomona - SA6

3. Components of Engineering Economic Analysis • Calculation of P and F are fundamental. • Some problems are more complex and require an understanding of added components: • Uniform series. • Arithmetic or geometric gradients. • Nominal and effective interest rates (covered in presentation #5 on Chapter 3). • Continuous compounding. EGR 403 - Cal Poly Pomona - SA6

4. Uniform Payment SeriesCapital Recovery Factor • The series of uniform payments that will recover an initial investment. A = P(A/P, i, n) EGR 403 - Cal Poly Pomona - SA6

5. Uniform Payment SeriesCompound Amount Factor F • The future value of an investment based on periodic, constant payments and a constant interest rate. F = A(F/A, i, n) EGR 403 - Cal Poly Pomona - SA6

6. Year Cash in Cash out 0 0 1 $500 2 $500 3 $500 4 $500 5 $500 -$2763 Example 4-1 At 5%/year F = $500(F/A, 5%, 5) = $500(5.526) = $2763 EGR 403 - Cal Poly Pomona - SA6

7. Uniform Payment SeriesSinking Fund Factor • The constant periodic amount, at a constant interest rate that must be deposited to accumulate a future value. A = F(A/F, i, n) EGR 403 - Cal Poly Pomona - SA6

8. Uniform Payment SeriesPresent Worth Factor The present value of a series of uniform future payments. P = A(P/A, i, n) EGR 403 - Cal Poly Pomona - SA6

9. Year Cash flow 1 $100 2 $100 3 $100 4 $0 5 F Example 4-6 F’ = $100(F/A, 15%, 3) = $347.25 F’’ = $347.25(F/P, 15%, 2) = $459.24 EGR 403 - Cal Poly Pomona - SA6

10. Year Cash flow 0 P 1 0 2 $ 20 3 $ 30 4 $ 20 Example 4-7Finding the Present Value (P) for each cash flow is sometimes the easiest way to find the equivalent P. P = $20(P/F, 15%, 2) + $30(P/F, 15%, 3) + $20(P/F, 15%, 4) = $46.28 EGR 403 - Cal Poly Pomona - SA6

11. Arithmetic Gradient • A uniform increasing amount. • The first cash flow is always equal to zero. • G = the difference between each cash amount. G = $10 EGR 403 - Cal Poly Pomona - SA6

12. Arithmetic Gradient combined with a Uniform Series • Decompose the cash flows into a uniform series and a pure gradient. Then add or subtract the Present Value of the gradient to the Present Value of the Uniform series • Example 4-8: Use P/G factor to find present value of the pure gradient portion of the cash flow EGR 403 - Cal Poly Pomona - SA6

13. Arithmetic Gradient Uniform Series Factor A pure gradient (uniformly increasing amount) can also be converted into the equivalent present value of uniform series: AG = G(A/G, i, n) See Example 4-9: Notice that the uniform series portion of the cash flow was subtracted to separate the pure gradient. EGR 403 - Cal Poly Pomona - SA6

14. Geometric Series Present Worth Factor Sometimes cash flows increase at a constant rate rather than a constant amount. Inflation, for example, could be reflected in a cash flow diagram that way. The equivalent present value of a geometrically increasing amount. g = the rate of increase (e.g., .05) P = A(P/A, g, i, n) where (P/A, g, i, n) must be computed from equation 4-30 or 4-31 • Example 4-12 uses g = .10 and i = .08 EGR 403 - Cal Poly Pomona - SA6