Reputation Aware Obfuscation for Mobile Opportunistic Networks

Radenkovic, Milena; Benslimane, Abderrahim; McAuley, Derek

doi:10.1109/tpds.2013.265

Cited by 12 publications

(11 citation statements)

References 30 publications

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“…Today, resource constraints of wearables in terms of their energy (battery lifetime limitations), bandwidth (link capacity and data transmission latency), and computation (sensing and processing costs) constitute the major user adoption barriers. Further, wearables are person-centric in the sense that they collect and communicate information only about their specific wearer, which may raise privacy concerns that need to be addressed with e.g., adaptive obfuscation mechanisms [5]. Finally, small numbers of involved participants may compromise the efficiency of a crowd sensing service and thus scalable solutions are needed for incentivizing user involvement into data sharing.…”

Section: B Urban Crowd Sensing Over Wearablesmentioning

confidence: 99%

Wirelessly Powered Urban Crowd Sensing over Wearables: Trading Energy for Data

Galinina

Mikhaylov

Huang

et al. 2018

IEEE Wireless Commun.

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In this article, we put forward the mobile crowd sensing paradigm based on ubiquitous wearable devices carried by human users. The key challenge for mass user involvement into prospective urban crowd sending applications, such as monitoring of large-scale phenomena (e.g., traffic congestion and air pollution levels), is the appropriate sources of motivation. We thus advocate for the use of wireless power transfer provided in exchange for sensed data to incentivize the owners of wearables to participate in collaborative data collection. Based on this construction, we develop the novel concept of wirelessly powered crowd sensing and offer the corresponding network architecture considerations together with a systematic review of wireless charging techniques to implement it. Further, we contribute a detailed system-level feasibility study that reports on the achievable performance levels for the envisioned setup. Finally, the underlying energy-data trading mechanisms are discussed, and the work is concluded with outlining open research opportunities.

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Section: B Urban Crowd Sensing Over Wearablesmentioning

confidence: 99%

Wirelessly Powered Urban Crowd Sensing over Wearables: Trading Energy for Data

Galinina

Mikhaylov

Huang

et al. 2018

IEEE Wireless Commun.

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“…Mechanism Our distributed reputation aware mechanism built within information-centric layer of CafRepCache integrates four main features: centrality, credit-based feedback, reputation discounting and secondary response (as in line with [1,2,18]) to weigh the value of exchanged content popularities among ego network nodes in order to improve the collaborative caching decisions in highly mobile and disconnection-prone scenarios. Fig.…”

Section: B Reputation-based Content Popularity Weightingmentioning

confidence: 99%

“…Assuming that take social metrics as the first reputation into account for every node, the aggregated content popularity of the content observed from all the neighbours of is now rewritten as: Then, we base on our previous work [1,3,18] to propose credit-based feedback algorithm in order to evaluate the accuracy and usefulness the content popularity value reported from a node in ego networks to a caching point.…”

Section: 3mentioning

confidence: 99%

“…In addition to using historical observations, we also use adaptive expiration timer, reputation discounting and secondary response [1,2,18] specifically tailored for our highly challenged environment in order to increase the accuracy and reliability of the reputation resolution. Each node holds N neighbour reputation records where N can be determined by the node's resource capacity.…”

Section: 3mentioning

confidence: 99%

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Understanding Information Centric Layer of Adaptive Collaborative Caching Framework in Mobile Disconnection-Prone Networks

Huynh

Radenkovic

John

2018

2018 14th International Wireless Communications &Amp; Mobile Computing Conference (IWCMC)

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Abstract-Smart networks and services leverage in-network caching to improve transmission efficiency and support large amount of content sharing, decrease high operating costs and handle disconnections. In this paper, we investigate the complex challenges related to content popularity weighting process in collaborative caching algorithm in heterogeneous mobile disconnection prone environments. We describe a reputationbased popularity weighting mechanism built in informationcentric layer of our adaptive collaborative caching framework CafRepCache which considers a realistic case where caching points gathering content popularity observed by nodes differentiates between them according to node's reputation and network's connectivity. We extensively evaluate CafRepCache with competitive protocols across three heterogeneous real-world mobility, connectivity traces and use YouTube dataset for different workload and content popularity patterns. We show that our collaborative caching mechanism CafRepCache balances the trade-off that achieves higher cache hit ratio, efficiency and success ratios while keeping lower delays, packet loss and caching footprint compared to competing protocols across three traces in the face of dynamic mobility of publishers and subscribers.

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“…To mitigate the impact of resource-related attacks by biased, selfish, and malicious nodes we propose a novel, distributed, decentralised, adaptive, collaborative, scalable framework for Trust-Aware Communications in Disaster -TACID. Our framework builds upon lessons learned from AdaptAnon [19] and OCOT-AA [20] and uses localised, predictive, real-time analytics derived from collaborative multidimensional multi-natured complex temporal graphs. TACID is a peer to peer, reputation and trust-aware approach for reliable and secure dissemination of sensitive resource-related communications amongst heterogeneous user groups in highly challenging, large-scale, distributed, delay and disconnection prone environments with hostile nodes present.…”

Section: Introductionmentioning

confidence: 99%

Towards Better Understanding the Challenges of Reliable and Trust-Aware Critical Communications in the Aftermath of Disaster

Radenkovic

Walker

Bai

2018

2018 14th International Wireless Communications &Amp; Mobile Computing Conference (IWCMC)

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This paper seeks to better understand the highly multi-dimensional, multi-faceted challenges of meeting trust and reliability requirements in critical, disaster aftermath communication networks comprising heterogeneous groups of nodes. Through emulation of a UK based flooding event in the South of England we show the impact of selfish and malicious nodes on disaster communications when disparate, distributed, and disconnected nodes are carrying sensitive messages relating to resource availability and need. To further support the need for trust-aware schemes in such environments we compare benchmark DTN protocols against our reliable, trust-aware framework, TACID, which penalises and excludes malicious nodes. We show that in disaster aftermath networks trust-aware schemes can significantly reduce the impact of malicious intermediary nodes and increase overall reliability whilst simultaneously maintaining message confidentiality. I.

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Reputation Aware Obfuscation for Mobile Opportunistic Networks

Cited by 12 publications

References 30 publications

Wirelessly Powered Urban Crowd Sensing over Wearables: Trading Energy for Data

Wirelessly Powered Urban Crowd Sensing over Wearables: Trading Energy for Data

Understanding Information Centric Layer of Adaptive Collaborative Caching Framework in Mobile Disconnection-Prone Networks

Towards Better Understanding the Challenges of Reliable and Trust-Aware Critical Communications in the Aftermath of Disaster

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