## Powers of Ginibre Eigenvalues. (arXiv:1711.03151v1 [math.PR])

We study the images of the complex Ginibre eigenvalues under the power maps $\pi_M: z \mapsto z^M$, for any integer $M$. We establish the following equality in distribution, $${\rm{Gin}}(N)^M \stackrel{d}{=} \bigcup_{k=1}^M {\rm{Gin}} (N,M,k),$$ where the so-called Power-Ginibre distributions ${\rm{Gin}}(N,M,k)$ form $M$ independent determinantal point processes. This result can be extended to any radially symmetric normal matrix ensemble, and generalizes Rains' superposition theorem for the CUE to a wider class of point processes. In the same spirit, we prove a generalization of Kostlan's and Rains' independence theorems for two-dimensional beta ensembles with radial symmetry and even parameter $\beta$, replacing independence by conditional independence. Our proof technique also allows us to recover a result by Edelman and La Croix for the GUE, and gives new insight into some of the questions they raised.查看全文

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 你的名字 留空匿名提交 你的Email或网站 用户可以联系你 标题 简单描述 内容 We study the images of the complex Ginibre eigenvalues under the power maps $\pi_M: z \mapsto z^M$, for any integer $M$. We establish the following equality in distribution, $${\rm{Gin}}(N)^M \stackrel{d}{=} \bigcup_{k=1}^M {\rm{Gin}} (N,M,k),$$ where the so-called Power-Ginibre distributions ${\rm{Gin}}(N,M,k)$ form $M$ independent determinantal point processes. This result can be extended to any radially symmetric normal matrix ensemble, and generalizes Rains' superposition theorem for the CUE to a wider class of point processes. In the same spirit, we prove a generalization of Kostlan's and Rains' independence theorems for two-dimensional beta ensembles with radial symmetry and even parameter $\beta$, replacing independence by conditional independence. Our proof technique also allows us to recover a result by Edelman and La Croix for the GUE, and gives new insight into some of the questions they raised.