Bond convexity

 

In finance, convexity is a measure of the sensitivity of the duration of a bond to changes in interest rates.

Calculation of convexity

Duration is a linear measure or 1st derivative of how the price of a bond changes in response to interest rate changes. As interest rates change, the price is not likely to change linearly, but instead it would change over some curved function of interest rates. The more curved the price function of the bond is, the more inaccurate duration is as a measure of the interest rate sensitivity.

Convexity is a measure of the curvature or 2nd derivative of how the price of a bond varies with interest rate, i.e. how the duration of a bond changes as the interest rate changes. Specifically, one assumes that the interest rate is constant across the life of the bond and that changes in interest rates occur evenly. Using these assumptions, duration can be formulated as the first derivative of the price function of the bond with respect to the interest rate in question. Then the convexity would be the second derivative of the price function with respect to the interest rate.

In actual markets the assumption of constant interest rates and even changes is not correct, and more complex models are needed to actually price bonds. However, these simplifying assumptions allow one to quickly and easily calculate factors which describe the sensitivity of the bond prices to interest rate changes.

Why bond convexities differ

The price sensitivity to parallel IR shifts is highest with a zero-coupon bond, and lowest with an amortizing bond (where the payments are front-loaded). Although the amortizing bond and the zero-coupon bond have different sensitivities at the same maturity, if their final maturities differ so that they have identical bond durations they will have identical sensitivities. That is, their prices will be affected equally by small, first-order, (and parallel) yield curve shifts. They will, however start to change by different amounts with each further incremental parallel rate shift due to their differing payment dates and amounts.

Algebraic definition

If the flat floating interest rate is r and the bond price is B, then the convexity C is defined as

Another way of expressing C is in terms of the duration D:

Therefore

leaving

How bond duration changes with a changing interest rate

Return to the standard definition of duration:

where P(i) is the present value of coupon i, and t(i) is the future payment date.

As the interest rate increases the present value of longer-dated payments declines in relation to earlier coupons (by the discount factor between the early and late payments). However, bond price also declines when interest rate increase but changes in the present value of all coupons (the numerator) is larger than changes in the bond price (the denominator). Therefore, increases in r must decrease the duration (or, in the case of zero-coupon bonds, leave it constant).

Given the convexity definition above, conventional bond convexities must always be positive.

The positivity of convexity can also be proven analytically for basic interest rate securities. For example, under the assumption of a flat yield curve one can write the value of a coupon-bearing bond as Failed to parse (unknown function\scriptstyle): \scriptstyle B (r)\ =\ \sum_{i=1}^{n} c_i e^{-r t_i} , where c_i stands for the coupon paid at time t_i. Then it is easy to see that

Note that this conversely implies the negativity of the derivative of duration by differentiating Failed to parse (unknown function\scriptstyle): \scriptstyle dB / dr\ =\ - D B .

Application of convexity

1. Convexity is a risk management figure, used similarly to the way 'gamma' is used in derivatives risks management; it is a number used to manage the market risk a bond portfolio is exposed to. If the combined convexity of a trading book is high, so is the risk. However, if the combined convexity and duration are low, the book is hedged, and little money will be lost even if fairly substantial interest movements occur. (Parallel in the yield curve.)
2. The second-order approximation of bond price movements due to rate changes uses the convexity:

See also

• Black-Scholes equation
• bond duration
• bond valuation
• Immunization (finance)
• List of convexity topics
• List of finance topics

External links

• The Investment Fund For Foundations explains the dangers of buying high-negative-convexity bonds
• Investopedia convexity explanation
• Duration and convexity Investment Analysts Society of South Africa
• Bond Yield Duration and Convexity Calculator Financial Technology Laboratories
• Real time Bond Price, Duration, and Convexity Calculator: [1]

Bond market
Fixed income · Bond · Debenture
Types of bonds by issuer	Government bond · Sovereign bond · Agency bond · Municipal bond · Corporate bond · Emerging market debt
Types of bonds by payout	Fixed rate bond · Floating rate note · Zero coupon bond · Inflation-indexed bond · Commercial paper · Accrual bond · Auction rate security · High-yield debt · Convertible bond · Mortgage-backed security · Asset-backed security
Derivatives	Bond option · Credit derivative · Credit default swap · Collateralized debt obligation · Collateralized mortgage obligation
Pricing	Bond valuation · Par value · Coupon · Clean price · Dirty price · Accrued interest · Day count convention
Yield analysis	Nominal yield · Current yield · Yield to maturity  · Yield curve · Bond duration  · Bond convexity
Credit and spread analysis	Credit analysis · Credit risk · Credit spread · Yield spread · Option adjusted spread
Interest rate models	Short rate models · Rendleman-Bartter · Vasicek · Ho-Lee · Hull-White · Cox-Ingersoll-Ross · Chen · Heath-Jarrow-Morton · Black-Derman-Toy · Brace-Gatarek-Musiela

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