Solutions 271
2.24The ratersatisfies
er=
(
1+^012.^12
) 12
.
The solution isr∼= 0 .1194, about 11.94%.
2.25The frequencymsatisfies
(
1+^0 m.^2
)m
=1+0. 21.
Whencem=2.0.
2.26If monthly compounding at a raterapplies, then
(
1+ 12 r
) 12
=1+reand the
present value of the annuity is
V(0) =1+Cr
12
+( C
1+ 12 r
) 2 +···+
C
(
1+ 12 r
) 12 n
= C
(1 +re)^1 /^12
+ C
(1 +re)^2 /^12
+···+(1 +Cr
e)n
=C^1 −(1 +re)
−n
(1 +re)^1 /^12 − 1
.
2.27If bimonthly compounding at a raterapplies, then
(
1+r 6
) 6
=1+reand the
present value of the perpetuity is
V(0) =1+Cr
6
+( C
1+r 6
) 2 +
C
(
1+r 6
) 3 +···
= C
(1 +re)^1 /^6
+ C
(1 +re)^2 /^6
+ C
(1 +re)^3 /^6
+···
=C^1
(1 +re)^1 /^6 − 1
.
2.28We solve the equation
100 = 95 (1 +r)^12
forrto find the implied effective rate to be about 10.80%. If this rate remains
constant, then the bond price will reach $99 at a timetsuch that
100 = 99 (1 +r)(
(^12) −t)
.
The solution ist∼= 0 .402 years, that is, about 0. 402 × 365 ∼= 146 .73 days. The
bond price will reach $99 on day 147.
2.29The interest rate for annual compounding implied by the bond can be found
by solving the equation
(1 +r)−(1−^0 .5)=0. 9455
forr. The solution is about 11.86%. By solving the equation
(
1+r 2
)−2(1− 0 .5)
=0. 9455 ,
we obtain the semi-annual rate of about 11.53%, and solving
e−r(1−^0 .5)=0. 9455 ,
we find the continuous rate to be about 11.21%.