Revision as of 18:54, 19 November 2023 by Admin (Created page with "'''Solution: C''' The semiannual yield rate is <math display = "block"> 1.1^{1/2}-1 = 0.0488. </math> Assuming the bond is called for 2900 after four years, the purchase price is <math display = "block"> 150a_{\overline{8}|0.0488}+2900(1.0488)^{-8}=150(6.4947)+1980.87=2955.08 </math> With a call after the first coupon, the equation to solve for the semi-annual yield rate (j) and then the annual effective rate (i) is <math display = "block"> \begin{array}{l}{{295...")
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Exercise

ABy Admin
Nov 19'23

Answer

Solution: C

The semiannual yield rate is

[[math]] 1.1^{1/2}-1 = 0.0488. [[/math]]

Assuming the bond is called for 2900 after four years, the purchase price is

[[math]] 150a_{\overline{8}|0.0488}+2900(1.0488)^{-8}=150(6.4947)+1980.87=2955.08 [[/math]]

With a call after the first coupon, the equation to solve for the semi-annual yield rate (j) and then the annual effective rate (i) is

[[math]] \begin{array}{l}{{2955.08=(150+2960)/(1+j)}}\\ {{1+j=1.05242}}\\ {{i=1.05242^{2}-1=0.10759.}}\end{array} [[/math]]

Copyright 2023 . The Society of Actuaries, Schaumburg, Illinois. Reproduced with permission.

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