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Main Authors: Sarpong, Dickson Akuoko, Kamrath, Adam, Bhusal, Rohit, Guo, Hongzhi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.09789
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author Sarpong, Dickson Akuoko
Kamrath, Adam
Bhusal, Rohit
Guo, Hongzhi
author_facet Sarpong, Dickson Akuoko
Kamrath, Adam
Bhusal, Rohit
Guo, Hongzhi
contents Near Field Communication (NFC) is widely used in security applications such as door access systems and ID cards. However, clone attacks can replicate digital information, enabling unauthorized access. RF fingerprinting offers a robust defense by extracting unique physical-layer features from NFC cards that cannot be cloned. While RF fingerprinting has been extensively applied to Internet of Things (IoT) device authentication, NFC tags present distinct characteristics that require specialized approaches. This paper focuses on RF fingerprinting for the ISO15693 NFC tag, which is a widely used international standard, by leveraging multi-channel, multi-rate data sampling to enhance accuracy. Deep learning and Random Forest models are employed to identify NFC tags, while uncertainty quantification, particularly Conformal Prediction, accelerates the identification process with high confidence and precision. A software-defined radio (SDR) testbed is developed to transmit customized commands and collect multi-channel multi-rate NFC signals. The multi-channel multi-rate NFC signals are progressively collected to ensure fast and accurate identification. Experimental results demonstrate that the proposed system achieves high accuracy by adaptively utilizing the optimal combination of NFC signals. The developed solution is model-agnostic which can be utilized for any machine learning-based NFC tag identification.
format Preprint
id arxiv_https___arxiv_org_abs_2503_09789
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Model-Agnostic Uncertainty Quantification for Fast NFC Tag Identification using RF Fingerprinting
Sarpong, Dickson Akuoko
Kamrath, Adam
Bhusal, Rohit
Guo, Hongzhi
Signal Processing
Near Field Communication (NFC) is widely used in security applications such as door access systems and ID cards. However, clone attacks can replicate digital information, enabling unauthorized access. RF fingerprinting offers a robust defense by extracting unique physical-layer features from NFC cards that cannot be cloned. While RF fingerprinting has been extensively applied to Internet of Things (IoT) device authentication, NFC tags present distinct characteristics that require specialized approaches. This paper focuses on RF fingerprinting for the ISO15693 NFC tag, which is a widely used international standard, by leveraging multi-channel, multi-rate data sampling to enhance accuracy. Deep learning and Random Forest models are employed to identify NFC tags, while uncertainty quantification, particularly Conformal Prediction, accelerates the identification process with high confidence and precision. A software-defined radio (SDR) testbed is developed to transmit customized commands and collect multi-channel multi-rate NFC signals. The multi-channel multi-rate NFC signals are progressively collected to ensure fast and accurate identification. Experimental results demonstrate that the proposed system achieves high accuracy by adaptively utilizing the optimal combination of NFC signals. The developed solution is model-agnostic which can be utilized for any machine learning-based NFC tag identification.
title Model-Agnostic Uncertainty Quantification for Fast NFC Tag Identification using RF Fingerprinting
topic Signal Processing
url https://arxiv.org/abs/2503.09789