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http://dx.doi.org/10.3837/tiis.2014.11.007

Cross-layer Video Streaming Mechanism over Cognitive Radio Ad hoc Information Centric Networks  

Han, Longzhe (school of Information Engineering, Nanchang Institute of Technology)
Nguyen, Dinh Han (Hung Yen University of Technology and Education)
Kang, Seung-Seok (Department of Computer Science, Seoul Women's University)
In, Hoh Peter (College of Information and Communications, Korea University)
Publication Information
KSII Transactions on Internet and Information Systems (TIIS) / v.8, no.11, 2014 , pp. 3775-3788 More about this Journal
Abstract
With the increasing number of the wireless and mobile networks, the way that people use the Internet has changed substantively. Wireless multimedia services, such as wireless video streaming, mobile video game, and mobile voice over IP, will become the main applications of the future wireless Internet. To accommodate the growing volume of wireless data traffic and multimedia services, cognitive radio (CR) and Information-Centric Network (ICN) have been proposed to maximize the utilization of wireless spectrum and improve the network performance. Although CR and ICN have high potential significance for the future wireless Internet, few studies have been conducted on collaborative operations of CR and ICN. Due to the lack of infrastructure support in multi-hop ad hoc CR networks, the problem is more challenging for video streaming services. In this paper, we propose a Cross-layer Video Streaming Mechanism (CLISM) for Cognitive Radio Ad Hoc Information Centric Networks (CRAH-ICNs). The CLISM included two distributed schemes which are designed for the forwarding nodes and receiving nodes in CRAH-ICNs. With the cross-layer approach, the CLISM is able to self-adapt the variation of the link conditions without the central network controller. Experimental results demonstrate that the proposed CLISM efficiently adjust video transmission policy under various network conditions.
Keywords
Cognitive Radio; information-centric network; cross-layer; video streaming;
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