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Prototype system for detecting and processing of IEEE 802.11a signals /Goh, Che Seng. January 2004 (has links) (PDF)
Thesis (M.S. in Systems Engineering)--Naval Postgraduate School, March 2004. / Thesis advisor(s): Tri T. Ha. Includes bibliographical references (p. 68). Also available online.
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Performance analysis of the IEEE 802.11A WLAN standard optimum and sub-optimum receiver in frequency-selective, slowly fading Nakagami channels with AWGN and pulsed noise jamming /Kalogrias, Christos. January 2004 (has links) (PDF)
Thesis (M.S. in Electrical Engineering and M.S. in Systems Engineering)--Naval Postgraduate School, March 2004. / Thesis advisor(s): Clark Robertson. Includes bibliographical references (p. 143). Also available online.
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Computer wireless networks : a design plan for building wireless networks using IEEE 802.11 standard /Almantheri, Hamed. January 2003 (has links) (PDF)
Thesis (M.S. in Computer Science)--Naval Postgraduate School, March 2003. / Thesis advisor(s): Bert Lundy, Richard Riehle. Includes bibliographical references (p. 77-79, 81). Also available online.
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Evaluation of secure 802.1X port-based network access authentication over 802.11 wireless local area networks /Ozturk, Huseyin Selcuk. January 2003 (has links) (PDF)
Thesis (M.S. in Computer Science)--Naval Postgraduate School, March 2003. / Thesis advisor(s): Geoffrey Xie, John Gibson. Includes bibliographical references (p. 171-172). Also available online.
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Wireless LAN extension /Tay, Chye Bin. January 2003 (has links) (PDF)
Thesis (M.S. in Information Technology Management)--Naval Postgraduate School, March 2003. / Thesis advisor(s): Norman F. Schneidewind, Douglas E. Brinkley. Includes bibliographical references (p. 67). Also available online.
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Improving spectrum utilization in wireless networksBhartia, Apurv 09 February 2015 (has links)
With the proliferation of wireless-enabled devices, the information being transmitted on the wireless spectrum has increased manifolds. This explosive growth of wireless traffic has created spectrum crisis. Further, combined with the inherently lossy wireless medium, it is imperative to develop techniques that can significantly improve wireless spectrum efficiency. This dissertation develops three complementary techniques to enhance spectrum efficiency: (i) sending more information per transmission, (ii) sending more transmissions per spectrum, and (iii) selecting the right spectrum for transmission. More specifically, in (i), we observe that network coding allows us to send more information per transmission by combining (coding) multiple packets together in a single transmission and letting multiple receivers extract different information from the same transmission. However, wireless networks are inherently prone to loss and how to harness network coding gain under such conditions poses a significant challenge. To this end, we develop a novel routing protocol, called O3, which jointly optimizes network coding, opportunistic routing, and rate limiting. Multi-antenna devices (MIMO) dramatically increase wireless network capacity by sending multiple transmissions simultaneously. However, most existing work focuses on MIMO in single hop wireless networks, and how to effectively extend MIMO benefits to multihop wireless networks remain an open problem. In (ii), we propose a new routing protocol, called DM+, which is the first practical distributed MIMO routing protocol. It optimizes spatial multiplexing, routing, and rate limiting in the presence of interference. Using simulation and testbed experiments, we show it out-performs state-of-the-art shortest part routing and opportunistic routing protocols. Finally, in (iii), we examine spectrum selection at two different granularities: (a) selecting an appropriate channel to transmit a frame, and (b) selecting a subcarrier (within a channel) to transmit a symbol of the frame. In (a), we propose LBRH, a novel channel hopping algorithm that allows different nodes converge to a fair and efficient channel hopping sequence in a completely distributed fashion. In (b), we develop Smart-Fi, a series of techniques to harness the frequency diversity of the channel while transmitting the current frame. We demonstrate the effectiveness of both approaches using simulation and testbed experiments. / text
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Distributed DHCP for WMNs using IPv6Molerón Bermudez, Daniel, Sánchez-Camacho Capilla, Sergio January 2007 (has links)
In a Wireless Mesh Network (WMN) exists mobile nodes which have an unpredictable behaviour, i.e. they can join, leave and free move around the network. For this reason, a static network configuration is not proper for them. A distributed Dynamic Host Configuration Protocol (DHCP) is needed due to the unavailability of a centralized server in a network placed over a vast extension. This report shows a Distributed DHCP for WMNs using IPv6 (Internet Protocol version 6). It is fault tolerant, robust and durable. The algorithm was created using counters Bloom filters as data structure. After, a complete simulation of the system was done. The simulations showed that using 24 servers with 16Mbits of memory each one is possible to manage around 9000000 clients without adding an excessive network load. Therefore, the DDHCPv6 could be in a near future the host configuration protocol in WMN.
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wypy : an extensible, online interference detection tool for wireless networksLotun, Reza M. E. 05 1900 (has links)
WiFi networks have become ubiquitous. However, due to the nature of the
radio-wave medium, the performance of 802.11 is unpredictable and highly
dependent on the environment. This problem is fundamental to 802.11's
decentralized, signal-based airspace arbitration mechanism. When devices have
incomplete and inconsistent channel conditions for an overlapping
interference domain, their signals alone cannot ensure a fair competition for
airspace. As a result, competing flows may suffer from unfair bandwidth
distribution if the shared airspace is congested.
A useful tool to visualize and diagnose problematic wireless networks is the
set of devices interfering with each other at a given time. We say two
devices a and b interfere when one of two possible situations occur. First,
a is able to sense b's radio signals, though not necessarily decode them,
resulting in a unable to send data. Second, a and b aren't in radio range,
but their destination devices are, resulting in packet collisions. We call
such a set of mutually interfering devices the interference neighbourhood.
We present wypy, an online system which merges trace-files and produces a map
of interfering devices contained within the trace. wypy is able to identify
pairs of devices exhibiting either hidden or exposed terminal interference
using a pipeline that consists of trace merging and reconstruction, filtering
of simultaneously sending devices, throughput and delay signal calculations,
and a test for interference correlation. We evaluate wypy using an in-lab
testbed set up in known interference scenarios.
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wypy : an extensible, online interference detection tool for wireless networksLotun, Reza M. E. 05 1900 (has links)
WiFi networks have become ubiquitous. However, due to the nature of the
radio-wave medium, the performance of 802.11 is unpredictable and highly
dependent on the environment. This problem is fundamental to 802.11's
decentralized, signal-based airspace arbitration mechanism. When devices have
incomplete and inconsistent channel conditions for an overlapping
interference domain, their signals alone cannot ensure a fair competition for
airspace. As a result, competing flows may suffer from unfair bandwidth
distribution if the shared airspace is congested.
A useful tool to visualize and diagnose problematic wireless networks is the
set of devices interfering with each other at a given time. We say two
devices a and b interfere when one of two possible situations occur. First,
a is able to sense b's radio signals, though not necessarily decode them,
resulting in a unable to send data. Second, a and b aren't in radio range,
but their destination devices are, resulting in packet collisions. We call
such a set of mutually interfering devices the interference neighbourhood.
We present wypy, an online system which merges trace-files and produces a map
of interfering devices contained within the trace. wypy is able to identify
pairs of devices exhibiting either hidden or exposed terminal interference
using a pipeline that consists of trace merging and reconstruction, filtering
of simultaneously sending devices, throughput and delay signal calculations,
and a test for interference correlation. We evaluate wypy using an in-lab
testbed set up in known interference scenarios.
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An improved media access control protocol for wireless LANs a thesis submitted to Auckland University of Technology in partial fulfilment of the requirements of the degree of Master of Information Technology, 2004.Lian, Jason Hailin. January 2004 (has links) (PDF)
Thesis (M Info Tech) -- Auckland University of Technology, 2004. / Also held in print (100 leaves, 30 cm.) in Wellesley Theses Collection (T 004.68 LIA)
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