Abstract-Communication messages in vehicular ad hoc networks (VANET) can be used to locate and track vehicles. While tracking can be beneficial for vehicle navigation, it can also lead to threats on location privacy of vehicle user. In this paper, we address the problem of mitigating unauthorized tracking of vehicles based on their broadcast communications, to enhance the user location privacy in VANET. Compared to other mobile networks, VANET exhibits unique characteristics in terms of vehicular mobility constraints, application requirements such as a safety message broadcast period, and vehicular network connectivity. Based on the observed characteristics, we propose a scheme called AMOEBA, that provides location privacy by utilizing the group navigation of vehicles. By simulating vehicular mobility in freeways and streets, the performance of the proposed scheme is evaluated under VANET application constraints and two passive adversary models. We make use of vehicular groups for anonymous access to location based service applications in VANET, for user privacy protection. The robustness of the user privacy provided is considered under various attacks.
Abstract. The lack of a formal model in wireless location privacy protection research makes it difficult to evaluate new location privacy protection proposals, and difficult to utilize existing research results in anonymous communication into this new problem. In this paper, we analyze a wireless location privacy protection system (W LP 2 S), and generalize it to a MIX based formal model, which includes a MIX, a set of MIX's user, and a intruder of MIX. In addition, we also use information theory approach to define anonymity and measures of this model, and describe the characteristics of observation process in W LP 2 S in detail. Two benefits arise from our model. Firstly, it provides a means of evaluating the privacy level of proposed location privacy protection protocols. We use the measures of proposed formal model to study the performance of our novel silent period technique. Simulation results reveal the role of many parameters-such as users' mobility pattern and intruders' tracking accuracy-on users' privacy level. The results shed more light on improving our defense protocol. Secondly, our approach provides a link between existing defense and attack protocols in MIX research and the new location privacy protection problem. By utilizing the formal model, we conducted preliminary studies in identifying potential attacks, and improve the performance of existing defense protocol. This study results an extension of existing defense protocols. Those simulation and analytical results demonstrates the promising potential of our model.
Abstract. In a wireless communication network, it is possible to locate a user and track its trajectory based on its transmission, during communication with access points. This type of tracking leads to the breach of a user's location privacy. Prior solutions to this problem enhances user's location privacy at the expense of communication Quality of Service(QoS) degradation. In this paper, we propose silent cascade to enhance a user' location privacy by trading users' delay in silent cascade for anonymity. As a result, it avoids the problem of QoS degradation in prior solutions. Furthermore, we abstract silent cascade as a mix-network based formal model, and use this model to evaluate the performance of silent cascade. Study results prove the effectiveness of silent cascade under different types of QoS requirements. Besides, we also derive the optimal configuration of silent cascade to achieves target anonymity within minimum duration of time. and the theoretical upper bound of a silent cascade's anonymity.
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