Subleading-order theory for condensation transitions in large deviations of sums of independent and identically distributed random variables
Abstract
We study the full distribution PN(A) of sums A = Σi=1N where x1, …, xN are N 1 independent and identically distributed random variables each sampled from a given distribution p(x) with a subexponential x ∞ tail. We consider two particular cases: (I) the one-sided stretched exponential distribution p(x) e-xα where 0 < x < ∞, (II) the two-sided stretched exponential distribution p(x) e-|x|α where -∞ < x < ∞. We assume 0 < α < 1 (in both cases). As follows immediately from known theorems, for both cases (i) typical fluctuations of A = A - A are described by the central-limit theorem, (ii) the tail A ∞ is described by the big-jump principle PN(A) N p(A), and (iii) in between these two regimes there is a nontrivial intermediate regime which displays anomalous scaling PN(A) e-Nβ f( A/Nγ) with anomalous exponents β,γ ∈ (0,1) and large-deviation function f(y) that are all exactly known. In practice, although these theoretical predictions of PN(A) work very well in regimes (i) and (ii), they often perform quite poorly in the intermediate regime (ii), with errors of several orders of magnitude for N as large as 104. We calculate subleading order corrections to the theoretical predictions in the intermediate regime. We find that for 0 < α < αc, these corrections scale as power laws in N, while for αc < α < 1 they scale as stretched exponentials, where the threshold value is αc = 1/2 in case (I) and αc = 2/3 in case (II). This difference between the two cases is a result of the mirror symmetry p(x) = p(-x) which holds only in the latter case.
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