Variance swap

Structure and features

The features of a variance swap include:

The payoff of a variance swap is given as follows:

where:

The annualised realised variance is calculated based on a prespecified set of sampling points over the period. It does not always coincide with the classic statistical definition of variance as the contract terms may not subtract the mean. For example, suppose that there are n+1 sample points S 0 , S 1 , . . . , S n . Define, for i=1 to n, R i = ln ⁡ ( S i / S i-1 ) , the natural log returns. Then

where A is an annualisation factor normally chosen to be approximately the number of sampling points in a year (commonly 252). It can be seen that subtracting the mean return will decrease the realised variance. If this is done, it is common to use n − 1 as the divisor rather than n , corresponding to an unbiased estimate of the sample variance.

It is market practice to determine the number of contract units as follows:

where N vol is the corresponding vega notional for a volatility swap. This makes the payoff of a variance swap comparable to that of a volatility swap, another less popular instrument used to trade volatility.

Pricing and valuation

The variance swap may be hedged and hence priced using a portfolio of European call and put options with weights inversely proportional to the square of strike.

Any volatility smile model which prices vanilla options can therefore be used to price the variance swap. For example, using the Heston model, a closed-form solution can be derived for the fair variance swap rate. Care must be taken with the behaviour of the smile model in the wings as this can have a disproportionate effect on the price.

We can derive the payoff of a variance swap using Ito's Lemma. We first assume that the underlying stock is described as follows:

d S t S t   = μ d t + σ d Z t

Applying Ito's formula, we get:

d ( log ⁡ S t ) = ( μ − σ 2 2   ) d t + σ d Z t

d S t S t   − d ( log ⁡ S t ) = σ 2 2   d t

Taking integrals, the total variance is:

Variance = 1 T   ∫ 0 T σ 2 d t   = 2 T   ( ∫ 0 T d S t S t     − ln ⁡ ( S T S 0   ) )

We can see that the total variance consists of a rebalanced hedge of 1 S t   and short a log contract.
Using a static replication argument , i.e., any twice continuously differentiable contract can be replicated using a bond, a future and infinitely many puts and calls, we can show that a short log contract position is equal to being short a futures contract and a collection of puts and calls:

− ln ⁡ ( S T S ∗   ) = − S T − S ∗ S ∗   + ∫ K ≤ S ∗ ( K − S T ) + d K K 2   + ∫ K ≥ S ∗ ( S T − K ) + d K K 2  

Taking expectations and setting the value of the variance swap equal to zero, we can rearrange the formula to solve for the fair variance swap strike:

K v a r = 2 T   ( r T − ( S 0 S ∗   e r T − 1 ) − log ⁡ ( S ∗ S 0   ) + e r T ∫ 0 S ∗ 1 K 2   P ( K ) d K + e r T ∫ S ∗ ∞ 1 K 2   C ( K ) d K )

Where:
S 0 is the initial price of the underlying security,
S ∗ > 0 is an arbitrary cutoff,
K is the strike of the each option in the collection of options used.

Often the cutoff S ∗ is chosen to be the current forward price S ∗ = F 0 = S 0 e r T , in which case the fair variance swap strike can be written in the simpler form:

K v a r = 2 e r T T   ( ∫ 0 F 0 1 K 2   P ( K ) d K + ∫ F 0 ∞ 1 K 2   C ( K ) d K )

Uses

Many traders find variance swaps interesting or useful for their purity. An alternative way of speculating on volatility is with an option, but if one only has interest in volatility risk, this strategy will require constant delta hedging, so that direction risk of the underlying security is approximately removed. What is more, a replicating portfolio of a variance swap would require an entire strip of options, which would be very costly to execute. Finally, one might often find the need to be regularly rolling this entire strip of options so that it remains centered on the current price of the underlying security.

The advantage of variance swaps is that they provide pure exposure to the volatility of the underlying price, as opposed to call and put options which may carry directional risk (delta). The profit and loss from a variance swap depends directly on the difference between realized and implied volatility.

Another aspect that some speculators may find interesting is that the quoted strike is determined by the implied volatility smile in the options market, whereas the ultimate payout will be based upon actual realized variance. Historically, implied variance has been above realized variance, a phenomenon known as the Variance risk premium, creating an opportunity for volatility arbitrage, in this case known as the rolling short variance trade. For the same reason, these swaps can be used to hedge Options on Realized Variance.

Related instruments

Closely related strategies include straddle, volatility swap, correlation swap, gamma swap, conditional variance swap, corridor variance swap, forward-start variance swap, option on realized variance and correlation trading.