Rapid LoRA Aggregation for Wireless Channel Adaptation in Open-Set Radio Frequency Fingerprinting
Mingxi Zhang, Renjie Xie, Jincheng Wang, Guyue Li, Wei Xu
TLDR
This paper proposes a LoRA-based framework for rapid, self-adaptive radio frequency fingerprinting, improving open-set authentication in dynamic wireless channels.
Key contributions
- Introduces a lightweight, self-adaptive RFF extraction framework using LoRA.
- Pretrains LoRA modules per environment for rapid adaptation to new channel conditions.
- Dynamically combines weighted LoRAs during inference to optimize feature extraction.
- Reduces Equal Error Rate (EER) by 15% and training time by 83% compared to baselines.
Why it matters
Radio frequency fingerprints (RFFs) are vital for secure wireless authentication but face challenges in dynamic, open-set environments. This paper provides a scalable and efficient LoRA-based solution, significantly improving RFF performance and training speed for robust security in vehicular networks.
Original Abstract
Radio frequency fingerprints (RFFs) enable secure wireless authentication but struggle in open-set scenarios with unknown devices and varying channels. Existing methods face challenges in generalization and incur high computational costs. We propose a lightweight, self-adaptive RFF extraction framework using Low-Rank Adaptation (LoRA). By pretraining LoRA modules per environment, our method enables fast adaptation to unseen channel conditions without full retraining. During inference, a weighted combination of LoRAs dynamically enhances feature extraction. Experimental results demonstrate a 15% reduction in equal error rate (EER) compared to non-finetuned baselines and an 83% decrease in training time relative to full fine-tuning, using the same training dataset. This approach provides a scalable and efficient solution for open-set RFF authentication in dynamic wireless vehicular networks.
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