Large deviations of Gaussian random functions
A random function – of either one variable (a random process), or two or more variables (a random field) – is called Gaussian if every finite-dimensional distribution is a multivariate normal distribution. Gaussian random fields on the sphere are useful (for example) when analysing
- the anomalies in the cosmic microwave background radiation (see,[1] pp. 8–9);
- brain images obtained by positron emission tomography (see,[1] pp. 9–10).
Sometimes, a value of a Gaussian random function deviates from its expected value by several standard deviations. This is a large deviation. Though rare in a small domain (of space or/and time), large deviations may be quite usual in a large domain.
Basic statement
Let be the maximal value of a Gaussian random function on the (two-dimensional) sphere. Assume that the expected value of is (at every point of the sphere), and the standard deviation of is (at every point of the sphere). Then, for large , is close to , where is distributed (the standard normal distribution), and is a constant; it does not depend on , but depends on the correlation function of (see below). The relative error of the approximation decays exponentially for large .
The constant is easy to determine in the important special case described in terms of the directional derivative of at a given point (of the sphere) in a given direction (tangential to the sphere). The derivative is random, with zero expectation and some standard deviation. The latter may depend on the point and the direction. However, if it does not depend, then it is equal to (for the sphere of radius ).
The coefficient before is in fact the Euler characteristic of the sphere (for the torus it vanishes).
It is assumed that is twice continuously differentiable (almost surely), and reaches its maximum at a single point (almost surely).
The clue: mean Euler characteristic
The clue to the theory sketched above is, Euler characteristic of the set of all points (of the sphere) such that . Its expected value (in other words, mean value) can be calculated explicitly:
(which is far from being trivial, and involves Poincaré–Hopf theorem, Gauss–Bonnet theorem, Rice's formula etc.).
The set is the empty set whenever ; in this case . In the other case, when , the set is non-empty; its Euler characteristic may take various values, depending on the topology of the set (the number of connected components, and possible holes in these components). However, if is large and then the set is usually a small, slightly deformed disk or ellipse (which is easy to guess, but quite difficult to prove). Thus, its Euler characteristic is usually equal to (given that ). This is why is close to .
See also
Further reading
The basic statement given above is a simple special case of a much more general (and difficult) theory stated by Adler.[1][2][3] For a detailed presentation of this special case see Tsirelson's lectures.[4]
- 1 2 3 Robert J. Adler, "On excursion sets, tube formulas and maxima of random fields", The Annals of Applied Probability 2000, Vol. 10, No. 1, 1–74. (Special invited paper.)
- ↑ Robert J. Adler, Jonathan E. Taylor, "Random fields and geometry", Springer 2007. ISBN 978-0-387-48112-8
- ↑ Robert J. Adler, "Some new random field tools for spatial analysis", arXiv:0805.1031.
- ↑ Lectures of B. Tsirelson (especially, Sect. 5).