English

Scalable Multi-task Edge Sensing via Task-oriented Joint Information Gathering and Broadcast

Signal Processing 2025-04-17 v1

Abstract

The recent advance of edge computing technology enables significant sensing performance improvement of Internet of Things (IoT) networks. In particular, an edge server (ES) is responsible for gathering sensing data from distributed sensing devices, and immediately executing different sensing tasks to accommodate the heterogeneous service demands of mobile users. However, as the number of users surges and the sensing tasks become increasingly compute-intensive, the huge amount of computation workloads and data transmissions may overwhelm the edge system of limited resources. Accordingly, we propose in this paper a scalable edge sensing framework for multi-task execution, in the sense that the computation workload and communication overhead of the ES do not increase with the number of downstream users or tasks. By exploiting the task-relevant correlations, the proposed scheme implements a unified encoder at the ES, which produces a common low-dimensional message from the sensing data and broadcasts it to all users to execute their individual tasks. To achieve high sensing accuracy, we extend the well-known information bottleneck theory to a multi-task scenario to jointly optimize the information gathering and broadcast processes. We also develop an efficient two-step training procedure to optimize the parameters of the neural network-based codecs deployed in the edge sensing system. Experiment results show that the proposed scheme significantly outperforms the considered representative benchmark methods in multi-task inference accuracy. Besides, the proposed scheme is scalable to the network size, which maintains almost constant computation delay with less than 1% degradation of inference performance when the user number increases by four times.

Keywords

Cite

@article{arxiv.2504.11843,
  title  = {Scalable Multi-task Edge Sensing via Task-oriented Joint Information Gathering and Broadcast},
  author = {Huawei Hou and Suzhi Bi and Xian Li and Shuoyao Wang and Liping Qian and Zhi Quan},
  journal= {arXiv preprint arXiv:2504.11843},
  year   = {2025}
}

Comments

15 pages, 10 figures. The paper is submitted for potential journal publication

R2 v1 2026-06-28T23:00:09.436Z