Arithmetic sensitivity of cumulant growth in lacunary sums: transcendental versus algebraic ratio limits

Abstract

We study the asymptotic behavior of cumulants of lacunary trigonometric sums Sn(ω) := Σk=1n (2 π ak ω), ω∈[0,1], and show that cumulant growth is highly sensitive to the arithmetic structure of the sequence (ak)k ≥ 1 of positive integers. In particular, if k ∞ ak+1/ak = η > 1 for some transcendental number η, we prove that for every m∈ N the m-th cumulant of Sn is asymptotically equivalent to the m-th cumulant of the ``independent model'' Sn := Σk=1n (2 π ak Uk), where U1, U2, … are independent random variables having uniform distribution on [0,1]. In particular, the order of growth of the cumulants as n ∞ is linear in this case. We also show that the transcendence condition for k ∞ ak+1/ak is in general necessary: when the ratio limit η is algebraic, the cumulants of Sn may have a different asymptotic order from those of Sn. For instance, for ak = 2k+1 (with η = 2), the sixth cumulant of Sn grows quadratically in n. In contrast, for ak = 2k (again η = 2) or when (ak)k ≥ 1 is the Fibonacci sequence (with η = (1+ 5)/2), the m-th cumulant of Sn grows linearly as n∞, but with a growth rate that differs from the one of the independent model Sn. Overall, our results show that the asymptotic behavior of the cumulants of lacunary trigonometric sums depends on arithmetic effects in a very delicate way. This is particularly remarkable since many other probabilistic limit theorems, such as the Central Limit Theorem, hold for lacunary trigonometric sums in a universal way without any such sensitivity towards arithmetic effects.

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