Second-order limits for component counts C_{j_n}(n) in Chinese restaurant process partitions are a stationary Ornstein-Uhlenbeck process in the subcritical regime and a stationary M/M/∞ queue in the critical regime, obtained by first proving the results for the Karlin infinite urn model.
On central limit theorems for Ewens-Pitman model
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abstract
We establish a quenched functional central limit theorem for the total number of components of random partitions induced by Chinese restaurant process with parameters $(\alpha,\theta), \alpha\in(0,1), \theta>-\alpha$. With $P_j$ denoting the asymptotic frequency of $j$-th table, it is well-known that the component count has the same law as the occupancy count of an infinite urn scheme with sampling frequencies being $(P_j)_{j\in\mathbb N}$. Our analysis follows this approach and is based on earlier results of Karlin (1967) and Durieu and Wang (2016). In words, our result reveals that the fluctuations of component count consist of two parts, one due to the sampling effect given the asymptotic frequencies $(P_j)_{j\in\mathbb N}$, the other due to the fluctuations of the random asymptotic frequencies, and in the limit the fluctuations of two parts are conditionally independent given the $\alpha$-diversity. Our result strengthens a recent central limit theorem obtained by Bercu and Favaro (2024) via a different method.
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Second-order fluctuations for a phase transition in random partitions
Second-order limits for component counts C_{j_n}(n) in Chinese restaurant process partitions are a stationary Ornstein-Uhlenbeck process in the subcritical regime and a stationary M/M/∞ queue in the critical regime, obtained by first proving the results for the Karlin infinite urn model.