An FPGA-Based Weightless Neural Network for Edge Network Intrusion Detection.

Algorithms for mobile networking are increasingly being moved from centralized servers towards the edge in order to decrease latency and improve the user experience. While much of this work is traditionally done using ASICs, 6G emphasizes the adaptability of algorithms for specific user scenarios, which motivates broader adoption of FPGAs. In this paper, we propose the FPGA-based Weightless Intrusion Warden (FWIW), a novel solution for detecting anomalous network traffic on edge devices. While prior work in this domain is based on conventional deep neural networks (DNNs), FWIW incorporates a weightless neural network (WNN), a table lookup-based model which learns sophisticated nonlinear behaviors. This allows FWIW to achieve accuracy far superior to prior FPGA-based work at a very small fraction of the model footprint, enabling deployment on small, low-cost devices. FWIW achieves a prediction accuracy of 98.5% on the UNSW-NB15 dataset with a total model parameter size of just 192 bytes, reducing error by 7.9x and model size by 262x vs. LogicNets, the best prior edge-optimized implementation. Implemented on a Xilinx Virtex UltraScale+ FPGA, FWIW demonstrates a 59x reduction in LUT usage with a 1.6x increase in throughput. The accuracy of FWIW comes within 0.6% of the best-reported result in literature (Edge-Detect), a model several orders of magnitude larger. Our results make it clear that WNNs are worth exploring in the emerging domain of edge networking, and suggest that FPGAs are capable of providing the extreme throughput needed.