An Optimal In-Situ Multipole Algorithm for the Isotropic Three-Point Correlation Functions

Abstract

We present an optimised multipole algorithm for computing the three-point correlation function (3PCF), tailored for application to large-scale cosmological datasets. The algorithm builds on a in\, situ interpretation of correlation functions, wherein spatial displacements are implemented via translation window functions. In Fourier space, these translations correspond to plane waves, whose decomposition into spherical harmonics naturally leads to a multipole expansion framework for the 3PCF. To accelerate computation, we incorporate density field reconstruction within the framework of multiresolution analysis, enabling efficient summation using either grid-based or particle-based schemes. In addition to the shared computational cost of reconstructing the multipole-decomposed density fields - scaling as O(L2trun Ng Ng) (where Ng is the number of grids and Ltrun is the truncation order of the multipole expansion) - the final summation step achieves a complexity of O(D6sup Ng) for the grid-based approach and O(D3sup Np) for the particle-based scheme (where Dsup is the support of the basis function and Np is the number of particles). The proposed in\, situ multipole algorithm is fully GPU-accelerated and implemented in the open-source Hermes toolkit for cosmic statistics. This development enables fast, scalable higher-order clustering analyses for large-volume datasets from current and upcoming cosmological surveys such as Euclid, DESI, LSST, and CSST.