TY - JOUR
T1 - A Survey and Experimental Study on Privacy-Preserving Trajectory Data Publishing
AU - Jin, Fengmei
AU - Hua, Wen
AU - Francia, Matteo
AU - Chao, Pingfu
AU - Orlowska, Maria E.
AU - Zhou, Xiaofang
N1 - Funding Information:
This work was supported by Australian Research Council under Grants DP200103650 and LP180100018
Publisher Copyright:
© 1989-2012 IEEE.
PY - 2023/6/1
Y1 - 2023/6/1
N2 - Trajectory data has become ubiquitous nowadays, which can benefit various real-world applications such as traffic management and location-based services. However, trajectories may disclose highly sensitive information of an individual including mobility patterns, personal profiles and gazetteers, social relationships, etc, making it indispensable to consider privacy protection when releasing trajectory data. Ensuring privacy on trajectories demands more than hiding single locations, since trajectories are intrinsically sparse and high-dimensional, and require to protect multi-scale correlations. To this end, extensive research has been conducted to design effective techniques for privacy-preserving trajectory data publishing. Furthermore, protecting privacy requires carefully balance two metrics: privacy and utility. In other words, it needs to protect as much privacy as possible and meanwhile guarantee the usefulness of the released trajectories for data analysis. In this survey, we provide a comprehensive study and a systematic summarization of existing protection models, privacy and utility metrics for trajectories developed in the literature. We also conduct extensive experiments on two real-life public trajectory datasets to evaluate the performance of several representative privacy protection models, demonstrate the trade-off between privacy and utility, and guide the choice of the right privacy model for trajectory publishing given certain privacy and utility desiderata.
AB - Trajectory data has become ubiquitous nowadays, which can benefit various real-world applications such as traffic management and location-based services. However, trajectories may disclose highly sensitive information of an individual including mobility patterns, personal profiles and gazetteers, social relationships, etc, making it indispensable to consider privacy protection when releasing trajectory data. Ensuring privacy on trajectories demands more than hiding single locations, since trajectories are intrinsically sparse and high-dimensional, and require to protect multi-scale correlations. To this end, extensive research has been conducted to design effective techniques for privacy-preserving trajectory data publishing. Furthermore, protecting privacy requires carefully balance two metrics: privacy and utility. In other words, it needs to protect as much privacy as possible and meanwhile guarantee the usefulness of the released trajectories for data analysis. In this survey, we provide a comprehensive study and a systematic summarization of existing protection models, privacy and utility metrics for trajectories developed in the literature. We also conduct extensive experiments on two real-life public trajectory datasets to evaluate the performance of several representative privacy protection models, demonstrate the trade-off between privacy and utility, and guide the choice of the right privacy model for trajectory publishing given certain privacy and utility desiderata.
KW - attack models
KW - privacy metrics
KW - privacy protection models
KW - Trajectory data publishing
KW - utility metrics
UR - http://www.scopus.com/inward/record.url?scp=85132525373&partnerID=8YFLogxK
U2 - 10.1109/TKDE.2022.3174204
DO - 10.1109/TKDE.2022.3174204
M3 - Journal article
AN - SCOPUS:85132525373
SN - 1041-4347
VL - 35
SP - 5577
EP - 5596
JO - IEEE Transactions on Knowledge and Data Engineering
JF - IEEE Transactions on Knowledge and Data Engineering
IS - 6
ER -