Neuromorphic Wireless Device-Edge Co-Inference via the Directed Information Bottleneck

• URL: http://arxiv.org/abs/2404.01804v1
• Date: Tue, 2 Apr 2024 10:06:21 GMT
• Title: Neuromorphic Wireless Device-Edge Co-Inference via the Directed Information Bottleneck
• Authors: Yuzhen Ke, Zoran Utkovski, Mehdi Heshmati, Osvaldo Simeone, Johannes Dommel, Slawomir Stanczak,
• Abstract summary: Device-edge co-inference is where a semantic task is partitioned between a device and an edge server. We introduce a new system solution, termed neuromorphic wireless device-edge co-inference. The proposed system is designed using a transmitter-centric information-theoretic criterion that targets a reduction of the communication overhead.
• Score: 40.44060856946713
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: An important use case of next-generation wireless systems is device-edge co-inference, where a semantic task is partitioned between a device and an edge server. The device carries out data collection and partial processing of the data, while the remote server completes the given task based on information received from the device. It is often required that processing and communication be run as efficiently as possible at the device, while more computing resources are available at the edge. To address such scenarios, we introduce a new system solution, termed neuromorphic wireless device-edge co-inference. According to it, the device runs sensing, processing, and communication units using neuromorphic hardware, while the server employs conventional radio and computing technologies. The proposed system is designed using a transmitter-centric information-theoretic criterion that targets a reduction of the communication overhead, while retaining the most relevant information for the end-to-end semantic task of interest. Numerical results on standard data sets validate the proposed architecture, and a preliminary testbed realization is reported.

Related papers

• Collaborative Automatic Modulation Classification via Deep Edge Inference for Hierarchical Cognitive Radio Networks [19.303303020775555]
  In hierarchical cognitive radio networks, edge or cloud servers utilize the data collected by edge devices for modulation classification. In this article, an edge learning (EL) based framework jointly mobilizing the edge device and the edge server for intelligent co-inference is proposed.
  arXiv  Detail & Related papers  (2024-09-12T11:14:25Z)
• Joint Sensing and Task-Oriented Communications with Image and Wireless Data Modalities for Dynamic Spectrum Access [49.83882366499547]
  This paper introduces a deep learning approach to dynamic spectrum access, leveraging the synergy of multi-modal image and spectrum data for the identification of potential transmitters. We consider an edge device equipped with a camera that is taking images of potential objects such as vehicles that may harbor transmitters. We propose a collaborative system wherein the edge device communicates selectively processed information to a trusted receiver acting as a fusion center.
  arXiv  Detail & Related papers  (2023-12-21T15:26:26Z)
• Adaptive Early Exiting for Collaborative Inference over Noisy Wireless Channels [17.890390892890057]
  Collaborative inference systems are one of the emerging solutions for deploying deep neural networks (DNNs) at the wireless network edge. In this work, we study early exiting in the context of collaborative inference, which allows obtaining inference results at the edge device for certain samples. The central part of our system is the transmission-decision (TD) mechanism, which decides whether to keep the early exit prediction or transmit the data to the edge server for further processing.
  arXiv  Detail & Related papers  (2023-11-29T21:31:59Z)
• Sparse Federated Training of Object Detection in the Internet of Vehicles [13.864554148921826]
  Object detection is one of the key technologies in the Internet of Vehicles (IoV) Current object detection methods are mostly based on centralized deep training, that is, the sensitive data obtained by edge devices need to be uploaded to the server. We propose a federated learning-based framework, where well-trained local models are shared in the central server.
  arXiv  Detail & Related papers  (2023-09-07T08:58:41Z)
• Task-Oriented Communications for NextG: End-to-End Deep Learning and AI Security Aspects [78.84264189471936]
  NextG communication systems are beginning to explore shifting this design paradigm to reliably executing a given task such as in task-oriented communications. Wireless signal classification is considered as the task for the NextG Radio Access Network (RAN), where edge devices collect wireless signals for spectrum awareness and communicate with the NextG base station (gNodeB) that needs to identify the signal label. Task-oriented communications is considered by jointly training the transmitter, receiver and classifier functionalities as an encoder-decoder pair for the edge device and the gNodeB.
  arXiv  Detail & Related papers  (2022-12-19T17:54:36Z)
• Task-Oriented Communication for Edge Video Analytics [11.03999024164301]
  This paper proposes a task-oriented communication framework for edge video analytics. Multiple devices collect visual sensory data and transmit the informative features to an edge server for processing. We show that the proposed framework effectively encodes task-relevant information of video data and achieves a better rate-performance tradeoff than existing methods.
  arXiv  Detail & Related papers  (2022-11-25T12:09:12Z)
• Task-Oriented Over-the-Air Computation for Multi-Device Edge AI [57.50247872182593]
  6G networks for supporting edge AI features task-oriented techniques that focus on effective and efficient execution of AI task. Task-oriented over-the-air computation (AirComp) scheme is proposed in this paper for multi-device split-inference system.
  arXiv  Detail & Related papers  (2022-11-02T16:35:14Z)
• Task-Oriented Sensing, Computation, and Communication Integration for Multi-Device Edge AI [108.08079323459822]
  This paper studies a new multi-intelligent edge artificial-latency (AI) system, which jointly exploits the AI model split inference and integrated sensing and communication (ISAC) We measure the inference accuracy by adopting an approximate but tractable metric, namely discriminant gain.
  arXiv  Detail & Related papers  (2022-07-03T06:57:07Z)
• Task-Oriented Communication for Multi-Device Cooperative Edge Inference [14.249444124834719]
  cooperative edge inference can overcome the limited sensing capability of a single device, but it substantially increases the communication overhead and may incur excessive latency. We propose a learning-based communication scheme that optimize local feature extraction and distributed feature encoding in a task-oriented manner.
  arXiv  Detail & Related papers  (2021-09-01T03:56:20Z)
• Towards AIOps in Edge Computing Environments [60.27785717687999]
  This paper describes the system design of an AIOps platform which is applicable in heterogeneous, distributed environments. It is feasible to collect metrics with a high frequency and simultaneously run specific anomaly detection algorithms directly on edge devices.
  arXiv  Detail & Related papers  (2021-02-12T09:33:00Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.