In finance, an option on realized variance (or variance option) is a type of variance derivatives which is the derivative securities on which the payoff depends on the annualized realized variance of the return of a specified underlying asset, such as stock index, bond, exchange rate, etc. Another liquidated security of the same type is variance swap, which is, in other words, the futures contract on realized variance.
With a similar notion to the vanilla options, variance options give the owner a right but without obligation to buy or sell the realized variance in exchange with some agreed price (variance strike) sometime in the future (expiry date), except that risk exposure is solely subjected to the price's variance itself. This property gains interest among traders since they can use it as an instrument to speculate the future movement of the asset volatility to, for example, delta-hedge a portfolio, without taking a directional risk of possessing the underlying asset.
In practice, the annualized realized variance is defined by the sum of the square of discrete-sampling log-return of the specified underlying asset. In other words, if there are
n+1
| S | |
| t0 |
| ,S | |
| t2 |
| ,...,S | |
| tn |
ti
0\leqti-1<ti\leqT
i\in\{1,...,n\}
RVd
| RV | ||||
|
| n | |
| \sum | |
| i=1 |
| ||||||||||||
| ln |
)
where
A
A=252
A=52
A=12
T
n/{A}.
If one puts
| C | |
| K | |
| var |
L
then payoffs at expiry for the call and put options written on
RVd
| C | |
| (RV | |
| var |
)+ x L
and
| C | |
| (K | |
| var |
| + x | |
| -RV | |
| d) |
L
respectively.
Note that the annualized realized variance can also be defined through continuous sampling, which resulted in the quadratic variation of the underlying price. That is, if we suppose that
\sigma(t)
RVc:=
| 1 | |
| T |
| T | |
| \int | |
| 0 |
\sigma2(s)ds
defines the continuous-sampling annualized realized variance which is also proved to be the limit in the probability of the discrete form[1] i.e.
\limn\toinftyRVd=\limn\toinfty
| A | |
| n |
| n | |
| \sum | |
| i=1 |
| |||||||||||||
| ln | )= |
| 1 | |
| T |
| T | |
| \int | |
| 0 |
| 2(s)ds=RV | |
| \sigma | |
| c |
However, this approach is only adopted to approximate the discrete one since the contracts involving realized variance are practically quoted in terms of the discrete sampling.
Suppose that under a risk-neutral measure
Q
S=(St)0\leq
| dSt | |
| St |
=r(t)dt+\sigma(t)dWt, S0>0
where:
r(t)\inR
\sigma(t)>0
W=(Wt)0\leq
(\Omega,l{F},F,Q)
F=(l{F}t)0\leq
W
ฺBy this setting, in the case of variance call, its fair price at time
t0
| var | |
| C | |
| t0 |
| \operatorname{var}:=e | |
| C | |
| t0 |
| ||||||||||
\operatorname{E}Q[(RV( ⋅ )
| C | |
| -K | |
| \operatorname{var |
where
RV( ⋅ )=RVd
RV( ⋅ )=RVc
| var | |
| C | |
| t0 |
RV( ⋅ )