IDP: A Privacy Provisioning Framework for TIP Attributes in Trusted Third Party-based Location-based Services Systems

In recent trends, growth of location based services have been increased due to the large usage of cell phones, personal digital assistant and other devices like location based navigation, emergency services, location based social networking, location based advertisement, etc. Users are provided with important information based on location to the service provider that results the compromise with their personal information like user’s identity, location privacy etc. To achieve location privacy of the user, cryptographic technique is one of the best technique which gives assurance. Location based services are classified as Trusted Third Party (TTP) & without Trusted Third Party that uses cryptographic approaches. TTP free is one of the prominent approach in which it uses peer-to-peer model. In this approach, important users mutually connect with each other to form a network to work without the use of any person/server. There are many existing approaches in literature for privacy preserving location based services, but their solutions are at high cost or not supporting scalability. In this paper, our aim is to propose an approach along with algorithms that will help the location based services (LBS) users to provide location privacy with minimum cost and improve scalability.

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A Hybrid Location Privacy Solution for Mobile LBS

Mobile Information Systems ◽

10.1155/2017/2189646 ◽

2017 ◽

Vol 2017 ◽

pp. 1-11 ◽

Cited By ~ 4

Author(s):

Ruchika Gupta ◽

Udai Pratap Rao

Keyword(s):

Location Privacy ◽

Homomorphic Encryption ◽

Location Based Services ◽

Third Party ◽

Location Services ◽

Trusted Third Party ◽

Location Data ◽

Complete Knowledge ◽

Current Location ◽

Hybrid Solution

The prevalent usage of location based services, where getting any service is solely based on the user’s current location, has raised an extreme concern over location privacy of the user. Generalized approaches dealing with location privacy, referred to as cloaking and obfuscation, are mainly based on a trusted third party, in which all the data remain available at a central server and thus complete knowledge of the query exists at the central node. This is the major limitation of such approaches; on the other hand, in trusted third-party-free framework clients collaborate with each other and freely communicate with the service provider without any third-party involvement. Measuring and evaluating trust among peers is a crucial aspect in trusted third-party-free framework. This paper exploits the merits and mitigating the shortcomings of both of these approaches. We propose a hybrid solution, HYB, to achieve location privacy for the mobile users who use location services frequently. The proposed HYB scheme is based on the collaborative preprocessing of location data and utilizes the benefits of homomorphic encryption technique. Location privacy is achieved at two levels, namely, at the proximity level and at distant level. The proposed HYB solution preserves the user’s location privacy effectively under specific, pull-based, sporadic query scenario.

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Information and documentation. Trusted third party repository for digital records

10.3403/30241711 ◽

2013 ◽

Cited By ~ 1

Keyword(s):

Third Party ◽

Trusted Third Party

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ILSSPP: Intelligent location sharing system with privacy preserving features for smart cities

Journal of Intelligent & Fuzzy Systems ◽

10.3233/jifs-219102 ◽

2021 ◽

pp. 1-12

Author(s):

Gokay Saldamli ◽

Richard Chow ◽

Hongxia Jin

Keyword(s):

Service Providers ◽

Smart Cities ◽

User Interaction ◽

Privacy Preserving ◽

Location Based Services ◽

Third Party ◽

Location Information ◽

Fine Grained ◽

Location Sharing ◽

Social Network Structure

Social networking services are increasingly accessed through mobile devices. This trend has prompted services such as Facebook and Google+to incorporate location as a de facto feature of user interaction. At the same time, services based on location such as Foursquare and Shopkick are also growing as smartphone market penetration increases. In fact, this growth is happening despite concerns (growing at a similar pace) about security and third-party use of private location information (e.g., for advertising). Nevertheless, service providers have been unwilling to build truly private systems in which they do not have access to location information. In this paper, we describe an architecture and a trial implementation of a privacy-preserving location sharing system called ILSSPP. The system protects location information from the service provider and yet enables fine grained location-sharing. One main feature of the system is to protect an individual’s social network structure. The pattern of location sharing preferences towards contacts can reveal this structure without any knowledge of the locations themselves. ILSSPP protects locations sharing preferences through protocol unification and masking. ILSSPP has been implemented as a standalone solution, but the technology can also be integrated into location-based services to enhance privacy.

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Enhancing Privacy in PUF-Cash through Multiple Trusted Third Parties and Reinforcement Learning

ACM Journal on Emerging Technologies in Computing Systems ◽

10.1145/3441139 ◽

2022 ◽

Vol 18 (1) ◽

pp. 1-26

Author(s):

Georgios Fragkos ◽

Cyrus Minwalla ◽

Eirini Eleni Tsiropoulou ◽

Jim Plusquellic

Keyword(s):

User Anonymity ◽

Third Party ◽

Security And Privacy ◽

Machine Learning Techniques ◽

User Privacy ◽

Trusted Third Party ◽

Physical Unclonable Functions ◽

Learning Techniques ◽

Direct Contrast ◽

Debit Cards

Electronic cash ( e-Cash ) is a digital alternative to physical currency such as coins and bank notes. Suitably constructed, e-Cash has the ability to offer an anonymous offline experience much akin to cash, and in direct contrast to traditional forms of payment such as credit and debit cards. Implementing security and privacy within e-Cash, i.e., preserving user anonymity while preventing counterfeiting, fraud, and double spending, is a non-trivial challenge. In this article, we propose major improvements to an e-Cash protocol, termed PUF-Cash, based on physical unclonable functions ( PUFs ). PUF-Cash was created as an offline-first, secure e-Cash scheme that preserved user anonymity in payments. In addition, PUF-Cash supports remote payments; an improvement over traditional currency. In this work, a novel multi-trusted-third-party exchange scheme is introduced, which is responsible for “blinding” Alice’s e-Cash tokens; a feature at the heart of preserving her anonymity. The exchange operations are governed by machine learning techniques which are uniquely applied to optimize user privacy, while remaining resistant to identity-revealing attacks by adversaries and trusted authorities. Federation of the single trusted third party into multiple entities distributes the workload, thereby improving performance and resiliency within the e-Cash system architecture. Experimental results indicate that improvements to PUF-Cash enhance user privacy and scalability.

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Multiparty authentication services and key agreement protocols with semi-trusted third party

Journal of Computer Science and Technology ◽

10.1007/bf02960765 ◽

2002 ◽

Vol 17 (6) ◽

pp. 749-756 ◽

Cited By ~ 4

Author(s):

Dong Zheng ◽

Kefei Chen ◽

Jinyuan You

Keyword(s):

Key Agreement ◽

Third Party ◽

Trusted Third Party ◽

Agreement Protocols

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IoT Notary : Attestable Sensor Data Capture in IoT Environments

ACM Transactions on Internet of Things ◽

10.1145/3478290 ◽

2022 ◽

Vol 3 (1) ◽

pp. 1-30

Author(s):

Nisha Panwar ◽

Shantanu Sharma ◽

Guoxi Wang ◽

Sharad Mehrotra ◽

Nalini Venkatasubramanian ◽

...

Keyword(s):

Real Time ◽

Location Based Services ◽

Third Party ◽

Sensor Data ◽

Published Data ◽

Resource Limited ◽

User Data ◽

Data Capturing ◽

Iot Devices ◽

The University

Contemporary IoT environments, such as smart buildings, require end-users to trust data-capturing rules published by the systems. There are several reasons why such a trust is misplaced—IoT systems may violate the rules deliberately or IoT devices may transfer user data to a malicious third-party due to cyberattacks, leading to the loss of individuals’ privacy or service integrity. To address such concerns, we propose IoT Notary , a framework to ensure trust in IoT systems and applications. IoT Notary provides secure log sealing on live sensor data to produce a verifiable “proof-of-integrity,” based on which a verifier can attest that captured sensor data adhere to the published data-capturing rules. IoT Notary is an integral part of TIPPERS, a smart space system that has been deployed at the University of California, Irvine to provide various real-time location-based services on the campus. We present extensive experiments over real-time WiFi connectivity data to evaluate IoT Notary , and the results show that IoT Notary imposes nominal overheads. The secure logs only take 21% more storage, while users can verify their one day’s data in less than 2 s even using a resource-limited device.

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A Quantum Dual-Signature Protocol Based on SNOP States without Trusted Participant

Entropy ◽

10.3390/e23101294 ◽

2021 ◽

Vol 23 (10) ◽

pp. 1294

Author(s):

Kejia Zhang ◽

Xu Zhao ◽

Long Zhang ◽

Guojing Tian ◽

Tingting Song

Keyword(s):

Quantum Signature ◽

Third Party ◽

Trusted Third Party ◽

Protocol Security ◽

Verification Process ◽

Orthogonal Product ◽

First Time

Quantum dual-signature means that two signed quantum messages are combined and expected to be sent to two different recipients. A quantum signature requires the cooperation of two verifiers to complete the whole verification process. As an important quantum signature aspect, the trusted third party is introduced to the current protocols, which affects the practicability of the quantum signature protocols. In this paper, we propose a quantum dual-signature protocol without arbitrator and entanglement for the first time. In the proposed protocol, two independent verifiers are introduced, here they may be dishonest but not collaborate. Furthermore, strongly nonlocal orthogonal product states are used to preserve the protocol security, i.e., no one can deny or forge a valid signature, even though some of them conspired. Compared with existing quantum signature protocols, this protocol does not require a trusted third party and entanglement resources.

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