Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Xu, Yuhua, Jiang, Mingtao, Hu, Chenfei, Wang, Yinglong, Zhang, Chuan, Li, Meng, Lu, Ming, Zhu, Liehuang
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2603.29688
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866917374727290880
author Xu, Yuhua
Jiang, Mingtao
Hu, Chenfei
Wang, Yinglong
Zhang, Chuan
Li, Meng
Lu, Ming
Zhu, Liehuang
author_facet Xu, Yuhua
Jiang, Mingtao
Hu, Chenfei
Wang, Yinglong
Zhang, Chuan
Li, Meng
Lu, Ming
Zhu, Liehuang
contents In low-altitude wireless networks (LAWN), federated learning (FL) enables collaborative intelligence among unmanned aerial vehicles (UAVs) and integrated sensing and communication (ISAC) devices while keeping raw sensing data local. Due to the "right to be forgotten" requirements and the high mobility of ISAC devices that frequently enter or leave the coverage region of UAV-assisted servers, the influence of departing devices must be removed from trained models. This necessity motivates the adoption of federated unlearning (FUL) to eliminate historical device contributions from the global model in LAWN. However, existing FUL approaches implicitly assume that the UAV-assisted server executes unlearning operations honestly. Without client-verifiable guarantees, an untrusted server may retain residual device information, leading to potential privacy leakage and undermining trust. To address this issue, we propose VerFU, a privacy-preserving and client-verifiable federated unlearning framework designed for LAWN. It empowers ISAC devices to validate the server-side unlearning operations without relying on original data samples. By integrating linear homomorphic hash (LHH) with commitment schemes, VerFU constructs tamper-proof records of historical updates. ISAC devices ensure the integrity of unlearning results by verifying decommitment parameters and utilizing the linear composability of LHH to check whether the global model accurately removes their historical contributions. Furthermore, VerFU is capable of efficiently processing parallel unlearning requests and verification from multiple ISAC devices. Experimental results demonstrate that our framework efficiently preserves model utility post-unlearning while maintaining low communication and verification overhead.
format Preprint
id arxiv_https___arxiv_org_abs_2603_29688
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Client-Verifiable and Efficient Federated Unlearning in Low-Altitude Wireless Networks
Xu, Yuhua
Jiang, Mingtao
Hu, Chenfei
Wang, Yinglong
Zhang, Chuan
Li, Meng
Lu, Ming
Zhu, Liehuang
Cryptography and Security
In low-altitude wireless networks (LAWN), federated learning (FL) enables collaborative intelligence among unmanned aerial vehicles (UAVs) and integrated sensing and communication (ISAC) devices while keeping raw sensing data local. Due to the "right to be forgotten" requirements and the high mobility of ISAC devices that frequently enter or leave the coverage region of UAV-assisted servers, the influence of departing devices must be removed from trained models. This necessity motivates the adoption of federated unlearning (FUL) to eliminate historical device contributions from the global model in LAWN. However, existing FUL approaches implicitly assume that the UAV-assisted server executes unlearning operations honestly. Without client-verifiable guarantees, an untrusted server may retain residual device information, leading to potential privacy leakage and undermining trust. To address this issue, we propose VerFU, a privacy-preserving and client-verifiable federated unlearning framework designed for LAWN. It empowers ISAC devices to validate the server-side unlearning operations without relying on original data samples. By integrating linear homomorphic hash (LHH) with commitment schemes, VerFU constructs tamper-proof records of historical updates. ISAC devices ensure the integrity of unlearning results by verifying decommitment parameters and utilizing the linear composability of LHH to check whether the global model accurately removes their historical contributions. Furthermore, VerFU is capable of efficiently processing parallel unlearning requests and verification from multiple ISAC devices. Experimental results demonstrate that our framework efficiently preserves model utility post-unlearning while maintaining low communication and verification overhead.
title Client-Verifiable and Efficient Federated Unlearning in Low-Altitude Wireless Networks
topic Cryptography and Security
url https://arxiv.org/abs/2603.29688