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Agenda Some duration formulas (CT1, Unit 13, Sec. 5.3) An aside on annuity bonds (Lando & Poulsen Sec. 3.3 – attached to hand-out) Convexity (CT1, Unit 13, Sec. 5.4) Immunisation (CT1, Unit 13, Sec. 5.5) MATH 2510: Fin. Math. 2

Duration Measures the sensitivity of present values/prices to changes in the interest rate. It has ”dual” meaning: • A derivative wrt. the interest rate • A value-weighted discounted average of payment times (so: its unit is ”years”) MATH 2510: Fin. Math. 2

Set-up: • Cash-flows at tk • Yield curve flat at i (or continuously compounded/on force form: ) • Present value of cash-flows: MATH 2510: Fin. Math. 2

Macauley Duration The Macauley duration (or: discounted mean term) is defined by Clearly a weighted average of payment dates. But also: Sensitivity to changes in the force of interest. Or put differently: To parallel shifts in the (continuously compounded) yield curve. MATH 2510: Fin. Math. 2

Duration of an Annuitiy The duration of an n-year annuity making payments D is (independent of D and) equal to (Note: On the Oct. 21 slides there was either a D too much or a D too little) where as usual with MATH 2510: Fin. Math. 2

and (IA) is the value of an increasing annuity MATH 2510: Fin. Math. 2

Annuity Bonds The remaining principal (outstanding notional) of an annuity bond with (nominal) coupon rate r and (annual) payment D satisfies Repeated substitution gives MATH 2510: Fin. Math. 2

Suppose (wlog) p0=100. For the loan to be paid off after n periods we must have pn=0, i.e. MATH 2510: Fin. Math. 2

This we can rewrite to solve for the yearly payment In finance people will often refer to this as the annuity formula. The yearly payments (or: instalments) consist of interest payments and repayment of principal. MATH 2510: Fin. Math. 2

Duration of a Bullet Bond Using similar reasoning, the duration of a bullet bond w/ coupon payments D and notional R is (Note: On the Oct. 21 slides D was missing in the denominator.) MATH 2510: Fin. Math. 2

Convexity The convexity of is defined as This is the ”effective” (or: ”volatility” version) – could also do Macauley or Fisher-Weil style. MATH 2510: Fin. Math. 2

Convexity and (effective) duration give a 2nd order accurate (Taylor expansion) approximation to changes in present value for (small) interest rate changes MATH 2510: Fin. Math. 2

A classical ”picture of” duration and convexity MATH 2510: Fin. Math. 2

Convexity is a measure of dispersion around the duration We can write Macauley duration as and Macauley-style convexity as A measure of dispersion around the duration is MATH 2510: Fin. Math. 2

Immunisation Consider a pension fund that has assets and liabilities . We say that the fund is immunised against movements in the interest rate around if and MATH 2510: Fin. Math. 2

By Taylor expanding the difference between assets and liabilities (known as the surplus) we get that the ”inequality condition” is fulfilled if - the assets and the liabilities have the same duration, and - convexity of the assets is higher than the convexity of the liabilities MATH 2510: Fin. Math. 2

These are known as Redington’s conditions. It doesn’t matter whether we use effective or Macaluey duration. Typical exercise approach: The ”equality conditions” give two linear equations in two unknows; the convexity condition follows from a dispersion consideration. MATH 2510: Fin. Math. 2

Immunisation isn’t the be-all-and-end-all of interest rate risk management Note that an immunised portfolio is looks very much like an arbitrage. That tells us that considering only parallel shifts to flat yield curves isn’t the perfect way to model interest rate uncertainty. And models with genuinely random behaviour is the next topic. MATH 2510: Fin. Math. 2

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