中文

Coded Task Offloading for Fluid Computing: A Privacy-Aware Approach under D2D Networks

分布式、并行与集群计算 2026-07-09 v1

摘要

Fluid Computing aims to support distributed applications execution across heterogeneous cloud, edge, and device resources, motivating task execution mechanisms that adapt to dynamic and privacy-sensitive environments under runtime conditions. In this context, current task offloading schemes rarely address privacy risks and information leakage under adversarial execution settings; furthermore, most coded computing proposals focus on straggler mitigation without considering system-level objectives such as energy awareness. This paper proposes a coded task offloading scheme for D2D networks under stochastic task arrivals and queue-based dynamics. The proposal combines task offloading techniques with linear secret sharing schemes, where tasks are encoded into redundant shares to support threshold-based recovery, straggler mitigation, and privacy preservation while enhancing system performance. Then, we formulate a privacy-aware offloading problem that jointly optimizes delay and energy while penalizing the theoretical privacy leakage of coded tasks under noisy leakage observations. The problem is solved using a branch-and-bound solver alongside a lightweight heuristic scheduler, both of which are evaluated through a discrete-event simulator. Results show that coded offloading improves the delay--energy trade-off with respect to classical full and parallel offloading schemes, while the heuristic achieves near-optimal performance, outperforming baseline and state-of-the-art solvers. The results also show how privacy leakage penalties reshape offloading decisions, exposing an inherent delay--energy--privacy trade-off.

引用

@article{arxiv.2607.08440,
  title  = {Coded Task Offloading for Fluid Computing: A Privacy-Aware Approach under D2D Networks},
  author = {Diego Cajaraville-Aboy and Manuel Fernández-Veiga and Ana Fernández-Vilas and Rebeca P. Díaz-Redondo},
  journal= {arXiv preprint arXiv:2607.08440},
  year   = {2026}
}

备注

19 pages, 6 pages for appendices, 12 figures, 4 tables. Pre-print