Volatility swap explained

In finance, a volatility swap is a forward contract on the future realised volatility of a given underlying asset. Volatility swaps allow investors to trade the volatility of an asset directly, much as they would trade a price index. Its payoff at expiration is equal to

(\sigma_realised-K_vol)N_vol

where:

\sigma_realised

is the annualised realised volatility,

K_vol

is the volatility strike, and

N_vol

is a preagreed notional amount.

that is, the holder of a volatility swap receives

N_vol

for every point by which the underlying's annualised realised volatility

\sigma_realised

exceeded the delivery price of

K_vol

, and conversely, pays

N_vol

for every point the realised volatility falls short of the strike.^[1]

The underlying is usually a financial instrument with an active or liquid options market, such as foreign exchange, stock indices, or single stocks. Unlike an investment in options, whose volatility exposure is contaminated by its price dependence, these swaps provide pure exposure to volatility alone. This is truly the case only for forward starting volatility swaps. However, once the swap has its asset fixings its mark-to-market value also depends on the current asset price. One can use these instruments to speculate on future volatility levels, to trade the spread between realized and implied volatility, or to hedge the volatility exposure of other positions or businesses.

Volatility swaps are more commonly quoted and traded than the very similar but simpler variance swaps, which can be replicated with a linear combination of options and a dynamic position in futures. The difference between the two is convexity: The payoff of a variance swap is linear with variance but convex with volatility.^[1] That means, inevitably, a static replication (a buy-and-hold strategy) of a volatility swap is impossible. However, using the variance swap (

	2
\Sigma
	T

) as a hedging instrument and targeting volatility (

\Sigma_T

), volatility can be written as a function of variance:

\Sigma_T=

	2
a\Sigma
	T

and

chosen to minimise the expect expected squared deviation of the two sides:

minE[(\Sigma_T-

	2
a\Sigma
	T

-b)²]

then, if the probability of negative realised volatilities is negligible, future volatilities could be assumed to be normal with mean

\bar\Sigma

and standard deviation

\sigma_\Sigma

\Sigma_T\simN(\bar\Sigma,\sigma_\Sigma)

then the hedging coefficients are:

\bar\Sigma+

	2
\sigma
	\Sigma

\bar\Sigma

	2
\sigma
	\Sigma

\bar\Sigma²

Definition of the realized volatility

Definition of the annualized realized volatility depends on traders viewpoint on the underlying price observation, which could be either discretely or continuously in time. For the former one, with the analogous construction to that of the variance swap, if there are

n+1

sampling points of the observed underlying prices, says,

S
	t₀

,S
	t₁

,...,

S
	t_n

where

0\leqt_i-1<t_i\leqT

for

i=1

. Define

R_i=

ln(S
	t_i

/S
	t_i-1

the natural log returns.Then the discrete-sampling annualized realized volatility is defined by

\sigma_realised:=\sqrt{

	A
	n

	n
\sum
	i=1

	2
R
	i

which basically is the square root of annualized realized variance. Here,

denotes an annualized factor which commonly selected to be the number of the observed price in a year i.e.

A=252

if the price is monitored daily or

A=52

if it is done weekly.

is the expiry date of the volatility swap defined by

n/A

The continuous version of the annualized realized volatility is defined by means of the square root of quadratic variation of the underlying price log-return:

\tilde{\sigma}_realized:=\sqrt{

	1
	T

	T
\int
	0

\sigma^2(s)ds},

where

\sigma(s)

is the instantaneous volatility of the underlying asset. Once the number of price's observation increase to infinity, one can find that

\sigma_realised

converges in probability to

\tilde{\sigma}_realized

^[2] i.e.

\lim_n\toinfty\sqrt{

	A
	n

	n
\sum
	i=1

	2
R
	i

}=\sqrt{

	1
	T

	T
\int
	0

\sigma^2(s)ds},

representing the interconnection and consistency between the two approaches.

Pricing and valuation

In general, for a specified underlying asset, the main aim of pricing swaps is to find a fair strike price since there is no cost to enter the contract. One of the most popular approaches to such fairness is exploiting the Martingale pricing method, which is the method to find the expected present value of given derivative security with respect to some risk-neutral probability measure (or Martingale measure). And how such a measure is chosen depends on the model used to describe the price evolution.

Mathematically speaking, if we suppose that the price process

S=(S_t)_0\leq

follows the Black-Scholes model under the martingale measure

, then it solves the following SDE:

	dS_t
	S_t

=r(t)dt+\sigma(t)dW_t, S_0>0

where:

represents the swap contract expiry date,

r(t)\inR

is (time-dependent) risk-free interest rate,

\sigma(t)>0

is (time-dependent) price volatility, and

W=(W_t)_0\leq

is a Brownian motion under the filtered probability space

(\Omega,l{F},F,Q)

where

F=(l{F}_t)_0\leq

is the natural filtration of

Since we know that

(\sigma_realised-K_vol) x N_vol

is the volatility swap payoff at expiry in the discretely sampled case (which is switched to

\tilde{\sigma}_realized

for the continuous case), then its expected value at time

t₀

, denoted by

V
	t₀

V
	t₀

	T
\int		r(s)ds
	t₀

E^Q[\sigma_realised-K_vol

\|l{F}
	t₀

] x N_vol,

which gives

K_vol=E^Q[\sigma_realised

\|l{F}
	t₀

]

due to the zero price of the swap, defining the value of a fair volatility strike. The solution can be discovered in various ways. For instance, we obtain the closed-form pricing formula once the probability distribution function of

\sigma}_{realized</math>}_realized

is known, or compute it numerically by means of the Monte Carlo method. Alternatively, Upon certain restrictions, one can utilize the value of the European options to approximate the solution.^[3]

Pricing volatility swap with continuous-sampling

Regarding the argument of Carr and Lee (2009),^[3] in the case of the continuous- sampling realized volatility if we assumes that the contract begins at time

t₀₌₀

r(t)

is deterministic and

\sigma(t)

is arbitrary (deterministic or a stochastic process) but independent of the price's movement i.e. there is no correlation between

\sigma(t)

and

S_t

, and denotes by

C_t(K,T)

the Black-Scholes formula for European call option written on

S_t

with the strike price

at time

t, 0\leqt\leqT

with expiry date

, then by the auxilarity of the call option chosen to be at-the-money i.e.

K=S₀

, the volatility strike

K_vol

can be approximated by the function

K_vol=E^Q[\tilde{\sigma}_realised

\|l{F}
	t₀

] ≈ \sqrt{

	2\pi
	T

}\frac-2r(T)

which is resulted from applying Taylor's series on the normal distribution parts of the Black-Scholes formula.

External links

Prepackaged Volatility Plays

Notes and References

Web site: Derman . Emanuel . Dmeterfi . Kresimir . Kamal . Michael . Zou . Joseph . More Than You Ever Wanted To Know About Volatility Swaps . Quantitative Strategis Research Notes . Goldman Sachs . 16 December 2019.
Barndorff-Nielsen . Ole E. . Shephard . Neil . Ole Barndorff-Nielsen. Neil Shephard . May 2002 . Econometric analysis of realised volatility and its use in estimating stochastic volatility models. 253–280 . 10.1111/1467-9868.00336. Journal of the Royal Statistical Society, Series B . 64 . 2 . 122716443 . free .
Carr . Peter . Lee . Roger . Volatility Derivatives . Annual Review of Financial Economics . 2009-12-05 . 1 . 1 . 319-339. 10.1146/annurev.financial.050808.114304.

Volatility swap explained

Definition of the realized volatility

Pricing and valuation

Pricing volatility swap with continuous-sampling

See also

External links

Notes and References