English

A Unified Mathematical Framework for Distributed Data Fabrics: Categorical Hypergraph Models

Databases 2026-02-17 v1 Category Theory

Abstract

Current distributed data fabrics lack a rigorous mathematical foundation, often relying on ad-hoc architectures that struggle with consistency, lineage, and scale. We propose a mathematical framework for data fabrics, unifying heterogeneous data management in distributed systems through a hypergraph-based structure F=(D,M,G,T,P,A) \mathcal{F} = (D, M, G, T, P, A) . Datasets, metadata, transformations, policies, and analytics are modeled over a distributed system Σ=(N,C) \Sigma = (N, C) , with multi-way relationships encoded in a hypergraph G=(V,E) G = (V, E) . A categorical approach, with datasets as objects and transformations as morphisms, supports operations like data integration and federated learning. The hypergraph is embedded into a modular tensor category, capturing relational symmetries via braided monoidal structures, with geometric analogies to Hurwitz spaces enriching the algebraic modeling. We prove the NP-hardness of critical tasks, such as schema matching and dynamic partitioning, and propose spectral methods and symmetry-based alignments for scalable solutions. The framework ensures consistency, completeness, and causality under CAP and CAL theorems, leveraging sparse incidence matrices and braiding actions for fault-tolerant operations.

Keywords

Cite

@article{arxiv.2602.14708,
  title  = {A Unified Mathematical Framework for Distributed Data Fabrics: Categorical Hypergraph Models},
  author = {T. Shaska and I. Kotsireas},
  journal= {arXiv preprint arXiv:2602.14708},
  year   = {2026}
}
R2 v1 2026-07-01T10:38:26.584Z