English

Random points on $\mathbb{S}^3$ with small logarithmic energy

Probability 2026-02-13 v1

Abstract

We analyse several constructions of random point sets on the sphere S3R4\mathbb{S}^{3}\subset\mathbb{R}^4 evaluating and comparing them through their discrete logarithmic energy: \begin{equation*} E_0(\omega_N) = \sum_{\substack{i, j=1\\ i \neq j}}^{N} \log\frac{1}{\|x_i - x_j\|}, \; \text{ where}\; \omega_N=\{x_1,\ldots,x_N\} \subset \mathbb{S}^3. \end{equation*} Using the Hopf fibration, we lift a range of well-distributed families of points from the 22-dimensional sphere - including uniformly random points, antipodally symmetric sets, determinantal point processes, and the Diamond ensemble - to S3\mathbb{S}^{3}, in order to assess their energy performance. In particular, we carry out this asymptotic analysis for the Spherical ensemble (a well known determinantal point process on S2\mathbb{S}^2), obtaining as a result a family of points on the 33-dimensional sphere whose logarithmic energy is asymptotically the lowest achieved to date. This, in turn, provides a new upper bound for the minimal logarithmic energy on S3\mathbb{S}^3. Although an analytic treatment of the lifted Diamond ensemble remains elusive, extensive simulations presented here show that its empirical energies lie below all other deterministic and non-deterministic constructions considered. Together, these results sharpen the quantitative link between potential-theoretic optima on S2\mathbb{S}^{2} and S3\mathbb{S}^{3} and provide both theoretical and numerical benchmarks for future work.

Keywords

Cite

@article{arxiv.2602.11856,
  title  = {Random points on $\mathbb{S}^3$ with small logarithmic energy},
  author = {Ujué Etayo and Pablo G. Arce},
  journal= {arXiv preprint arXiv:2602.11856},
  year   = {2026}
}

Comments

31 pages, 2 figures

R2 v1 2026-07-01T10:33:31.202Z