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218 Mathematics for Finance


onebasis point, so here the rate drops by 100 basis points.) ThenB(6,12)∼=
0 .9692, which is more than in scenario 1. As a result, we are going to earn
more, achieving a logarithmic return of 4.13%.


  1. The rate increases toy(6) = 8.26%.In this case the logarithmic return on
    our investment will be 3.13%, which is lower than in scenario 1, the bond
    price beingB(6,12)∼= 0. 9596.


We can see a pattern here: One is better off if the rate drops and worse off if
the rate increases. A general formula for the return on this kind of investment
is easy to find.


Suppose that the initial yieldy(0) changes randomly to becomey(n)=y(0)
at timen. Hence


B(0,N)=e−y(0)τN,B(n, N)=e−y(n)τ(N−n),

and the return on an investment closed at timenwill be


k(0,n)=lnBB((0n,N,N))=lney(0)τN−y(n)τ(N−n)=y(0)τN−y(n)τ(N−n).

We can see that the return decreases as the ratey(n)increases.The impact
of a rate change on the return depends on the timing. For example, ifτ= 121 ,
N=12andn=6,then a rate increase of 120 basis points will reduce the
return by 0.6% as compared to the case when the rate remains unchanged.


Exercise 10.2


Letτ = 121. Invest $100 in six-month zero-coupon bonds trading at
B(0,6) = 0.9400 dollars. After six months reinvest the proceeds in bonds
of the same kind, now trading atB(6,12) = 0.9368 dollars. Find the
implied interest rates and compute the number of bonds held at each
time. Compute the logarithmic return on the investment over one year.

Exercise 10.3


Suppose thatB(0,12) = 0.8700 dollars. What is the interest rate after
6 months if an investment for 6 months in zero-coupon bonds gives a
logarithmic return of 14%?

Exercise 10.4


In this exercise we take a finer time scale withτ = 3601 .(Ayearis
assumed to have 360 days here.) Suppose thatB(0,360) = 0.9200 dollars,
the rate remains unchanged for the first six months, goes up by 200 basis
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