2017
DOI: 10.3150/15-bej743
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Concentration inequalities in the infinite urn scheme for occupancy counts and the missing mass, with applications

Abstract: An infinite urn scheme is defined by a probability mass function (pj) j≥1 over positive integers. A random allocation consists of a sample of N independent drawings according to this probability distribution where N may be deterministic or Poisson-distributed. This paper is concerned with occupancy counts, that is with the number of symbols with r or at least r occurrences in the sample, and with the missing mass that is the total probability of all symbols that do not occur in the sample. Without any further … Show more

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Cited by 56 publications
(86 citation statements)
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“…This paper extends the results of [7] and [6], where a functional central limit theorem (FCLT) was shown under condition (3) for the vector process 1] in the case θ ∈ (0, 1]. Ordinary (not functional) central limit theorems for the above quantities were established under various conditions in [2], [3], [9], [10], [12], [13], [14]. In particular, under rather general conditions on the sequence (p i ) involving an unbounded growth of the variances, the following results available: a strong law of large numbers and asymptotic normality of R n , an asymptotic normality of the vector (R n,1 , .…”
Section: Introductionsupporting
confidence: 71%
“…This paper extends the results of [7] and [6], where a functional central limit theorem (FCLT) was shown under condition (3) for the vector process 1] in the case θ ∈ (0, 1]. Ordinary (not functional) central limit theorems for the above quantities were established under various conditions in [2], [3], [9], [10], [12], [13], [14]. In particular, under rather general conditions on the sequence (p i ) involving an unbounded growth of the variances, the following results available: a strong law of large numbers and asymptotic normality of R n , an asymptotic normality of the vector (R n,1 , .…”
Section: Introductionsupporting
confidence: 71%
“…Our main result, Theorem 2.1, is an immediate consequence of Proposition 3.7 given in Section 3.2, Theorem 3.2 given next and its corollary. (8) and (9). Then…”
Section: Auxiliary Resultsmentioning
confidence: 99%
“…(b) Condition(8) ensures that Var N (t) = O(t 2γ ) as t → ∞. Pick any δ > 0 such that δ(ω − γ) > 1/2.…”
mentioning
confidence: 99%
“…wherem n ,v − n andv + n are suitable quantities that will be defined in the proof. First we discuss how to determine (18), we remind that D n =M n − M n is a sub-Gamma random variable, as shown in Proposition A.2, hence the following holds (see Ben-Hamou et al (2017)) P(D n > E(D n ) + 2v + n s + s/n) ≤ e −s for any s ≥ 0. Putting e −s = δ, we obtain P(D n ≤ E(D n ) + 2v + n log(1/δ) + log(1/δ)/n) ≥ 1 − δ.…”
Section: A3 Proof Of Theorem 31 and Related Resultsmentioning
confidence: 99%