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Main Authors: Liu, Xuan, Cai, Siqi, Zhou, Qihua, Guo, Song, Li, Ruibin, Lin, Kaiwei
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.05285
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author Liu, Xuan
Cai, Siqi
Zhou, Qihua
Guo, Song
Li, Ruibin
Lin, Kaiwei
author_facet Liu, Xuan
Cai, Siqi
Zhou, Qihua
Guo, Song
Li, Ruibin
Lin, Kaiwei
contents Perturbation-based mechanisms, such as differential privacy, mitigate gradient leakage attacks by introducing noise into the gradients, thereby preventing attackers from reconstructing clients' private data from the leaked gradients. However, can gradient perturbation protection mechanisms truly defend against all gradient leakage attacks? In this paper, we present the first attempt to break the shield of gradient perturbation protection in Federated Learning for the extraction of private information. We focus on common noise distributions, specifically Gaussian and Laplace, and apply our approach to DNN and CNN models. We introduce Mjolnir, a perturbation-resilient gradient leakage attack that is capable of removing perturbations from gradients without requiring additional access to the original model structure or external data. Specifically, we leverage the inherent diffusion properties of gradient perturbation protection to develop a novel diffusion-based gradient denoising model for Mjolnir. By constructing a surrogate client model that captures the structure of perturbed gradients, we obtain crucial gradient data for training the diffusion model. We further utilize the insight that monitoring disturbance levels during the reverse diffusion process can enhance gradient denoising capabilities, allowing Mjolnir to generate gradients that closely approximate the original, unperturbed versions through adaptive sampling steps. Extensive experiments demonstrate that Mjolnir effectively recovers the protected gradients and exposes the Federated Learning process to the threat of gradient leakage, achieving superior performance in gradient denoising and private data recovery.
format Preprint
id arxiv_https___arxiv_org_abs_2407_05285
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Mjolnir: Breaking the Shield of Perturbation-Protected Gradients via Adaptive Diffusion
Liu, Xuan
Cai, Siqi
Zhou, Qihua
Guo, Song
Li, Ruibin
Lin, Kaiwei
Machine Learning
Artificial Intelligence
Cryptography and Security
Perturbation-based mechanisms, such as differential privacy, mitigate gradient leakage attacks by introducing noise into the gradients, thereby preventing attackers from reconstructing clients' private data from the leaked gradients. However, can gradient perturbation protection mechanisms truly defend against all gradient leakage attacks? In this paper, we present the first attempt to break the shield of gradient perturbation protection in Federated Learning for the extraction of private information. We focus on common noise distributions, specifically Gaussian and Laplace, and apply our approach to DNN and CNN models. We introduce Mjolnir, a perturbation-resilient gradient leakage attack that is capable of removing perturbations from gradients without requiring additional access to the original model structure or external data. Specifically, we leverage the inherent diffusion properties of gradient perturbation protection to develop a novel diffusion-based gradient denoising model for Mjolnir. By constructing a surrogate client model that captures the structure of perturbed gradients, we obtain crucial gradient data for training the diffusion model. We further utilize the insight that monitoring disturbance levels during the reverse diffusion process can enhance gradient denoising capabilities, allowing Mjolnir to generate gradients that closely approximate the original, unperturbed versions through adaptive sampling steps. Extensive experiments demonstrate that Mjolnir effectively recovers the protected gradients and exposes the Federated Learning process to the threat of gradient leakage, achieving superior performance in gradient denoising and private data recovery.
title Mjolnir: Breaking the Shield of Perturbation-Protected Gradients via Adaptive Diffusion
topic Machine Learning
Artificial Intelligence
Cryptography and Security
url https://arxiv.org/abs/2407.05285