archived_user
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- Jun 18, 2026
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See practice question below - in the solution why does PV0 change in the denominator (it appears they have just dropped a 9)?
Thanks in advance!
Consider the following information for a traditional (option-free) fixed-rate bond where PV0 is the bond’s original price, PV+ is the new price of the bond when the yield to maturity is increased, PV− is the new price of the bond when the yield to maturity is decreased, ∆Curve is the change in the benchmark yield curve, and ∆Yield is the change in the yield to maturity:
PV0
PV+
PV−ΔCurve
ΔYield
99.41172
99.32213
99.50132
3 bps
1 bp
Q. The bond’s approximate convexity is closest to:
C is correct. The bond’s approximate convexity (ApproxCon) is 10.05918, calculated as:
ApproxCon
=
(PV−) + (PV + )−[2 × (PV0)] / (∆Yield)2 × (PV0)
=
99.50132 + 99.322123−(2 × 99.41172) / (0.0001)2 × 9.41172
=
10.05918
Thanks in advance!
Consider the following information for a traditional (option-free) fixed-rate bond where PV0 is the bond’s original price, PV+ is the new price of the bond when the yield to maturity is increased, PV− is the new price of the bond when the yield to maturity is decreased, ∆Curve is the change in the benchmark yield curve, and ∆Yield is the change in the yield to maturity:
PV0
PV+
PV−ΔCurve
ΔYield
99.41172
99.32213
99.50132
3 bps
1 bp
Q. The bond’s approximate convexity is closest to:
- 0.00101.
- 1.11769.
- 10.05918.
C is correct. The bond’s approximate convexity (ApproxCon) is 10.05918, calculated as:
ApproxCon
=
(PV−) + (PV + )−[2 × (PV0)] / (∆Yield)2 × (PV0)
=
99.50132 + 99.322123−(2 × 99.41172) / (0.0001)2 × 9.41172
=
10.05918