Exploiting cross layer opportunities for secrecy and efficiency in wireless networks.
详细信息
- 作者:Nandha Premnath ; Sriram.
- 学历:Ph.D.
- 年:2013
- 导师:Kasera, Sneha,eadvisorBalasubramonian, Rajeevecommittee memberRicci, Robertecommittee memberPatwari, Nealecommittee memberFarhang-Boroujeny, Behrouzecommittee member
- 毕业院校:The University of Utah
- Department:School of Computing
- ISBN:9781267987488
- CBH:3556567
- Country:USA
- 语种:English
- FileSize:2527550
- Pages:161
文摘
Cross layer system design represents a paradigm shift that breaks the traditional layer-boundaries in a network stack to enhance a wireless network in a number of different ways. Existing work has used the cross layer approach to optimize a wireless network in terms of packet scheduling, error correction, multimedia quality, power consumption, selection of modulation/coding and user experience, etc. We explore the use of new cross layer opportunities to achieve secrecy and efficiency of data transmission in wireless networks. In the first part of this dissertation, we build secret key establishment methods for private communication between wireless devices using the spatio-temporal variations of symmetric-wireless channel measurements. We evaluate our methods on a variety of wireless devices, including laptops, telosB sensor nodes, and Android smartphones, with diverse wireless capabilities. We perform extensive measurements in real-world environments and show that our methods generate high entropy secret bits at a significantly faster rate in comparison to existing approaches. While the first part of this dissertation focuses on achieving secrecy in wireless networks, the second part of this dissertation examines the use of special pulse shaping filters of the filterbank multicarrier FBMC) physical layer in reliably transmitting data packets at a very high rate. We first analyze the mutual interference power across subcarriers used by different transmitters. Next, to understand the impact of FBMC beyond the physical layer, we devise a distributed and adaptive medium access control protocol that coordinates data packet traffic among the different nodes in the network in a best effort manner. Using extensive simulations, we show that FBMC consistently achieves an order-of-magnitude performance improvement over orthogonal frequency division multiplexing OFDM) in several aspects, including packet transmission delays, channel access delays, and effective data transmission rate available to each node in static indoor settings as well as in vehicular networks.