Antithetic variates

In statistics, the antithetic variates method is a variance reduction technique used in Monte Carlo methods. Considering that the error in the simulated signal (using Monte Carlo methods) has a one-over square root convergence, a very large number of sample paths is required to obtain an accurate result. The antithetic variates method reduces the variance of the simulation results.^[1]^[2]

Underlying principle

The antithetic variates technique consists, for every sample path obtained, in taking its antithetic path — that is given a path $\{\varepsilon _{1},\dots ,\varepsilon _{M}\}$ to also take $\{-\varepsilon _{1},\dots ,-\varepsilon _{M}\}$ . The advantage of this technique is twofold: it reduces the number of normal samples to be taken to generate N paths, and it reduces the variance of the sample paths, improving the precision.

Suppose that we would like to estimate

\theta =\mathrm {E} (h(X))=\mathrm {E} (Y)\,

For that we have generated two samples

Y_{1}{\text{ and }}Y_{2}\,

An unbiased estimate of ${\theta }$ is given by

{\hat {\theta }}={\frac {Y_{1}+Y_{2}}{2}}.

And

{\text{Var}}({\hat {\theta }})={\frac {{\text{Var}}(Y_{1})+{\text{Var}}(Y_{2})+2{\text{Cov}}(Y_{1},Y_{2})}{4}}

so variance is reduced if ${\text{Cov}}(Y_{1},Y_{2})$ is negative.

Example 1

If the law of the variable X follows a uniform distribution along [0, 1], the first sample will be $u_{1},\ldots ,u_{n}$ , where, for any given i, $u_{i}$ is obtained from U(0, 1). The second sample is built from $u'_{1},\ldots ,u'_{n}$ , where, for any given i: $u'_{i}=1-u_{i}$ . If the set $u_{i}$ is uniform along [0, 1], so are $u'_{i}$ . Furthermore, covariance is negative, allowing for initial variance reduction.

Example 2: integral calculation

We would like to estimate

I=\int _{0}^{1}{\frac {1}{1+x}}\,\mathrm {d} x.

The exact result is $I=\ln 2\approx 0.69314718$ . This integral can be seen as the expected value of $f(U)$ , where

f(x)={\frac {1}{1+x}}

and U follows a uniform distribution [0, 1].

The following table compares the classical Monte Carlo estimate (sample size: 2n, where n = 1500) to the antithetic variates estimate (sample size: n, completed with the transformed sample 1 − u_i):

	Estimate	standard error
Classical Estimate	0.69365	0.00255
Antithetic Variates	0.69399	0.00063

The use of the antithetic variates method to estimate the result shows an important variance reduction.

References

^ Botev, Z.; Ridder, A. (2017). "Variance Reduction". Wiley StatsRef: Statistics Reference Online: 1–6. doi:10.1002/9781118445112.stat07975. ISBN 9781118445112.
^ Kroese, D. P.; Taimre, T.; Botev, Z. I. (2011). Handbook of Monte Carlo methods. John Wiley & Sons.(Chapter 9.3)

[varred17-1] Botev, Z.; Ridder, A. (2017). "Variance Reduction". Wiley StatsRef: Statistics Reference Online: 1–6. doi:10.1002/9781118445112.stat07975. ISBN 9781118445112.

[2] Kroese, D. P.; Taimre, T.; Botev, Z. I. (2011). Handbook of Monte Carlo methods. John Wiley & Sons.(Chapter 9.3)

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Antithetic variates

Contents

Underlying principle

Example 1

Example 2: integral calculation

See also

References