Cooperative Local Differential Privacy: Securing Time Series Data in Distributed Environments
- URL: http://arxiv.org/abs/2511.09696v1
- Date: Fri, 14 Nov 2025 01:04:48 GMT
- Title: Cooperative Local Differential Privacy: Securing Time Series Data in Distributed Environments
- Authors: Bikash Chandra Singh, Md Jakir Hossain, Rafael Diaz, Sandip Roy, Ravi Mukkamala, Sachin Shetty,
- Abstract summary: We introduce a Cooperative Local Differential Privacy (CLDP) mechanism that enhances privacy by distributing noise vectors across multiple users.<n>In our approach, noise is collaboratively generated and assigned so that when all users' data is aggregated, the noise cancels out preserving overall statistical properties while protecting individual privacy.
- Score: 5.982082746731629
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The rapid growth of smart devices such as phones, wearables, IoT sensors, and connected vehicles has led to an explosion of continuous time series data that offers valuable insights in healthcare, transportation, and more. However, this surge raises significant privacy concerns, as sensitive patterns can reveal personal details. While traditional differential privacy (DP) relies on trusted servers, local differential privacy (LDP) enables users to perturb their own data. However, traditional LDP methods perturb time series data by adding user-specific noise but exhibit vulnerabilities. For instance, noise applied within fixed time windows can be canceled during aggregation (e.g., averaging), enabling adversaries to infer individual statistics over time, thereby eroding privacy guarantees. To address these issues, we introduce a Cooperative Local Differential Privacy (CLDP) mechanism that enhances privacy by distributing noise vectors across multiple users. In our approach, noise is collaboratively generated and assigned so that when all users' perturbed data is aggregated, the noise cancels out preserving overall statistical properties while protecting individual privacy. This cooperative strategy not only counters vulnerabilities inherent in time-window-based methods but also scales effectively for large, real-time datasets, striking a better balance between data utility and privacy in multiuser environments.
Related papers
- Improving Noise Efficiency in Privacy-preserving Dataset Distillation [59.57846442477106]
We introduce a novel framework that decouples sampling from optimization for better convergence and improves signal quality.<n>On CIFAR-10, our method achieves a textbf10.0% improvement with 50 images per class and textbf8.3% increase with just textbfone-fifth the distilled set size of previous state-of-the-art methods.
arXiv Detail & Related papers (2025-08-03T13:15:52Z) - Dimension Reduction via Random Projection for Privacy in Multi-Agent Systems [1.3812010983144802]
In a Multi-Agent System, individual agents observe various aspects of the environment and transmit this information to a central entity.<n>In a crowd-sourced traffic monitoring system, commuters might share not only their current speed, but also sensitive information such as their location to enable more accurate route prediction.<n>We propose a novel compression-based approach leveraging the notion of robust concepts to sanitize the shared data.
arXiv Detail & Related papers (2024-12-05T10:09:13Z) - 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) - Measuring Privacy Loss in Distributed Spatio-Temporal Data [26.891854386652266]
We propose an alternative privacy loss against location reconstruction attacks by an informed adversary.
Our experiments on real and synthetic data demonstrate that our privacy loss better reflects our intuitions on individual privacy violation in the distributed setting.
arXiv Detail & Related papers (2024-02-18T09:53:14Z) - PrivAgE: A Toolchain for Privacy-Preserving Distributed Aggregation on Edge-Devices [0.5216865930622505]
We present a toolchain called PrivAgE for a distributed, privacy-preserving aggregation of local data.
The distributed aggregation is based on secure summation and simultaneously satisfies the notion of differential privacy.
We demonstrate the flexibility of our toolchain by presenting an extension of the summation of histograms to distributed clustering.
arXiv Detail & Related papers (2023-09-21T20:55:29Z) - Breaking the Communication-Privacy-Accuracy Tradeoff with
$f$-Differential Privacy [51.11280118806893]
We consider a federated data analytics problem in which a server coordinates the collaborative data analysis of multiple users with privacy concerns and limited communication capability.
We study the local differential privacy guarantees of discrete-valued mechanisms with finite output space through the lens of $f$-differential privacy (DP)
More specifically, we advance the existing literature by deriving tight $f$-DP guarantees for a variety of discrete-valued mechanisms.
arXiv Detail & Related papers (2023-02-19T16:58:53Z) - 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) - Robustness Threats of Differential Privacy [70.818129585404]
We experimentally demonstrate that networks, trained with differential privacy, in some settings might be even more vulnerable in comparison to non-private versions.
We study how the main ingredients of differentially private neural networks training, such as gradient clipping and noise addition, affect the robustness of the model.
arXiv Detail & Related papers (2020-12-14T18:59:24Z) - Deep Directed Information-Based Learning for Privacy-Preserving Smart
Meter Data Release [30.409342804445306]
We study the problem in the context of time series data and smart meters (SMs) power consumption measurements.
We introduce the Directed Information (DI) as a more meaningful measure of privacy in the considered setting.
Our empirical studies on real-world data sets from SMs measurements in the worst-case scenario show the existing trade-offs between privacy and utility.
arXiv Detail & Related papers (2020-11-20T13:41:11Z) - Graph-Homomorphic Perturbations for Private Decentralized Learning [64.26238893241322]
Local exchange of estimates allows inference of data based on private data.
perturbations chosen independently at every agent, resulting in a significant performance loss.
We propose an alternative scheme, which constructs perturbations according to a particular nullspace condition, allowing them to be invisible.
arXiv Detail & Related papers (2020-10-23T10:35:35Z) - Privacy-Aware Time-Series Data Sharing with Deep Reinforcement Learning [33.42328078385098]
We study the privacy-utility trade-off (PUT) in time-series data sharing.
Methods that preserve the privacy for the current time may leak significant amount of information at the trace level.
We consider sharing the distorted version of a user's true data sequence with an untrusted third party.
arXiv Detail & Related papers (2020-03-04T18:47:25Z)
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.