English

On Non-Interactive Source Simulation via Fourier Transform

Information Theory 2022-12-20 v1 Cryptography and Security Systems and Control Systems and Control math.IT Probability

Abstract

The non-interactive source simulation (NISS) scenario is considered. In this scenario, a pair of distributed agents, Alice and Bob, observe a distributed binary memoryless source (Xd,Yd)(X^d,Y^d) generated based on joint distribution PX,YP_{X,Y}. The agents wish to produce a pair of discrete random variables (Ud,Vd)(U_d,V_d) with joint distribution PUd,VdP_{U_d,V_d}, such that PUd,VdP_{U_d,V_d} converges in total variation distance to a target distribution QU,VQ_{U,V} as the input blocklength dd is taken to be asymptotically large. Inner and outer bounds are obtained on the set of distributions QU,VQ_{U,V} which can be produced given an input distribution PX,YP_{X,Y}. To this end, a bijective mapping from the set of distributions QU,VQ_{U,V} to a union of star-convex sets is provided. By leveraging proof techniques from discrete Fourier analysis along with a novel randomized rounding technique, inner and outer bounds are derived for each of these star-convex sets, and by inverting the aforementioned bijective mapping, necessary and sufficient conditions on QU,VQ_{U,V} and PX,YP_{X,Y} are provided under which QU,VQ_{U,V} can be produced from PX,YP_{X,Y}. The bounds are applicable in NISS scenarios where the output alphabets U\mathcal{U} and V\mathcal{V} have arbitrary finite size. In case of binary output alphabets, the outer-bound recovers the previously best-known outer-bound.

Cite

@article{arxiv.2212.09239,
  title  = {On Non-Interactive Source Simulation via Fourier Transform},
  author = {Farhad Shirani and Mohsen Heidari},
  journal= {arXiv preprint arXiv:2212.09239},
  year   = {2022}
}
R2 v1 2026-06-28T07:41:26.829Z