Privacy-Preserving Semantic Communication over Wiretap Channels with Learnable Differential Privacy
- URL: http://arxiv.org/abs/2510.23274v1
- Date: Mon, 27 Oct 2025 12:34:20 GMT
- Title: Privacy-Preserving Semantic Communication over Wiretap Channels with Learnable Differential Privacy
- Authors: Weixuan Chen, Qianqian Yang, Shuo Shao, Shunpu Tang, Zhiguo Shi, Shui Yu,
- Abstract summary: semantic communication (SemCom) improves transmission efficiency by focusing on task-relevant information.<n>This paper proposes a novel secure SemCom framework for image transmission over wiretap channels, leveraging differential privacy (DP) to provide approximate privacy guarantees.<n>Under comparable security levels, our approach achieves an LPIPS advantage of 0.06-0.29 and an FPPSR advantage of 0.10-0.86 for the legitimate user.
- Score: 27.586640666837997
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: While semantic communication (SemCom) improves transmission efficiency by focusing on task-relevant information, it also raises critical privacy concerns. Many existing secure SemCom approaches rely on restrictive or impractical assumptions, such as favorable channel conditions for the legitimate user or prior knowledge of the eavesdropper's model. To address these limitations, this paper proposes a novel secure SemCom framework for image transmission over wiretap channels, leveraging differential privacy (DP) to provide approximate privacy guarantees. Specifically, our approach first extracts disentangled semantic representations from source images using generative adversarial network (GAN) inversion method, and then selectively perturbs private semantic representations with approximate DP noise. Distinct from conventional DP-based protection methods, we introduce DP noise with learnable pattern, instead of traditional white Gaussian or Laplace noise, achieved through adversarial training of neural networks (NNs). This design mitigates the inherent non-invertibility of DP while effectively protecting private information. Moreover, it enables explicitly controllable security levels by adjusting the privacy budget according to specific security requirements, which is not achieved in most existing secure SemCom approaches. Experimental results demonstrate that, compared with the previous DP-based method and direct transmission, the proposed method significantly degrades the reconstruction quality for the eavesdropper, while introducing only slight degradation in task performance. Under comparable security levels, our approach achieves an LPIPS advantage of 0.06-0.29 and an FPPSR advantage of 0.10-0.86 for the legitimate user compared with the previous DP-based method.
Related papers
- Enhancing Privacy in Semantic Communication over Wiretap Channels leveraging Differential Privacy [51.028047763426265]
Semantic communication (SemCom) improves transmission efficiency by focusing on task-relevant information.<n> transmitting semantic-rich data over insecure channels introduces privacy risks.<n>This paper proposes a novel SemCom framework that integrates differential privacy mechanisms to protect sensitive semantic features.
arXiv Detail & Related papers (2025-04-23T08:42:44Z) - Federated Learning with Differential Privacy: An Utility-Enhanced Approach [12.614480013684759]
Federated learning has emerged as an attractive approach to protect data privacy by eliminating the need for sharing clients' data.<n>Recent studies have shown that federated learning alone does not guarantee privacy, as private data may still be inferred from the uploaded parameters to the central server.<n>We present a modification to these vanilla differentially private algorithms based on a Haar wavelet transformation step and a novel noise injection scheme that significantly lowers the bound of the noise variance.
arXiv Detail & Related papers (2025-03-27T04:48:29Z) - Collaborative Inference over Wireless Channels with Feature Differential Privacy [57.68286389879283]
Collaborative inference among multiple wireless edge devices has the potential to significantly enhance Artificial Intelligence (AI) applications.
transmitting extracted features poses a significant privacy risk, as sensitive personal data can be exposed during the process.
We propose a novel privacy-preserving collaborative inference mechanism, wherein each edge device in the network secures the privacy of extracted features before transmitting them to a central server for inference.
arXiv Detail & Related papers (2024-10-25T18:11:02Z) - Activity Recognition on Avatar-Anonymized Datasets with Masked Differential Privacy [64.32494202656801]
Privacy-preserving computer vision is an important emerging problem in machine learning and artificial intelligence.<n>We present anonymization pipeline that replaces sensitive human subjects in video datasets with synthetic avatars within context.<n>We also proposeMaskDP to protect non-anonymized but privacy sensitive background information.
arXiv Detail & Related papers (2024-10-22T15:22:53Z) - Convergent Differential Privacy Analysis for General Federated Learning: the $f$-DP Perspective [57.35402286842029]
Federated learning (FL) is an efficient collaborative training paradigm with a focus on local privacy.
differential privacy (DP) is a classical approach to capture and ensure the reliability of private protections.
arXiv Detail & Related papers (2024-08-28T08:22:21Z) - TernaryVote: Differentially Private, Communication Efficient, and
Byzantine Resilient Distributed Optimization on Heterogeneous Data [50.797729676285876]
We propose TernaryVote, which combines a ternary compressor and the majority vote mechanism to realize differential privacy, gradient compression, and Byzantine resilience simultaneously.
We theoretically quantify the privacy guarantee through the lens of the emerging f-differential privacy (DP) and the Byzantine resilience of the proposed algorithm.
arXiv Detail & Related papers (2024-02-16T16:41:14Z) - Binary Federated Learning with Client-Level Differential Privacy [7.854806519515342]
Federated learning (FL) is a privacy-preserving collaborative learning framework.
Existing FL systems typically adopt Federated Average (FedAvg) as the training algorithm.
We propose a communication-efficient FL training algorithm with differential privacy guarantee.
arXiv Detail & Related papers (2023-08-07T06:07:04Z) - A Randomized Approach for Tight Privacy Accounting [63.67296945525791]
We propose a new differential privacy paradigm called estimate-verify-release (EVR)
EVR paradigm first estimates the privacy parameter of a mechanism, then verifies whether it meets this guarantee, and finally releases the query output.
Our empirical evaluation shows the newly proposed EVR paradigm improves the utility-privacy tradeoff for privacy-preserving machine learning.
arXiv Detail & Related papers (2023-04-17T00:38:01Z) - Over-the-Air Federated Learning with Privacy Protection via Correlated
Additive Perturbations [57.20885629270732]
We consider privacy aspects of wireless federated learning with Over-the-Air (OtA) transmission of gradient updates from multiple users/agents to an edge server.
Traditional perturbation-based methods provide privacy protection while sacrificing the training accuracy.
In this work, we aim at minimizing privacy leakage to the adversary and the degradation of model accuracy at the edge server.
arXiv Detail & Related papers (2022-10-05T13:13:35Z) - Differentially Private Generative Adversarial Networks with Model
Inversion [6.651002556438805]
To protect sensitive data in training a Generative Adversarial Network (GAN), the standard approach is to use differentially private (DP) gradient descent method.
We propose Differentially Private Model Inversion (DPMI) method where the private data is first mapped to the latent space via a public generator.
Our approach outperforms the standard DP-GAN method based on Inception Score, Fr'echet Inception Distance, and classification accuracy under the same privacy guarantee.
arXiv Detail & Related papers (2022-01-10T02:26:26Z) - Federated Learning with Sparsification-Amplified Privacy and Adaptive
Optimization [27.243322019117144]
Federated learning (FL) enables distributed agents to collaboratively learn a centralized model without sharing their raw data with each other.
We propose a new FL framework with sparsification-amplified privacy.
Our approach integrates random sparsification with gradient perturbation on each agent to amplify privacy guarantee.
arXiv Detail & Related papers (2020-08-01T20:22:57Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.