Recall the approximate formulas for change in present value when interest rate changes.

In terms of the “modified” quantities M(i) = ?P?(i)/P(i) , C(i) = P??(i)/P(i) there is a straightforward Taylor approximation

1 2 P(i)?P(i0) 1?M(i0)(i?i0)+2C(i0)(i?i0) .

(a)(10 points) If the cash flow is a single payment of F = \$1000.00 at time t = 10, then P(i)=\$1000(1+i)?10. Leti0 =10%=.1andcalculateP(.1),M(.1),C(.1).

(b)(10 points) Use the quantities you just calculated in (a) to calculate the first and second order approximations to P(.09). Compare with the exact P(.09) = \$1000(1.09)?10.

In terms of the Macaulay duration D there’s a more accurate first order formula P(i) = P(i0)(1 + i0)D

(1+i)D

. In fact this is exact if the cash flow consists of a single payment at future time t = D.

But what if the cash flow consists of two payments (the next simplest case)? For simplicity assume a payment of \$500 / (1.1) at time t = 9 and \$500(1.1) at t = 11. I’m happy to tell you that P(.1) is the same as you calculated in part (a), and the Macaulay duration D = 10.

(c)(20 points) Calculate P(.09) exactly, and the Macaulay first order approximation. How close are they? (You may have to keep a lot of digits of accuracy!)

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