Resource management in wireless networks

This thesis considers resource management issues in wireless sensor networks (WSNs), wireless local area networks (WLANs), and cognitive radio (CR) networks. Since energy is a critical resource in WSNs, we consider energy minimization techniques based on explicit node cooperation and distributed sou...

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Main Author: Pillutla, Laxminarayana S.
Format: Others
Language:English
Published: University of British Columbia 2008
Subjects:
TCP
Online Access:http://hdl.handle.net/2429/2829
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spelling ndltd-UBC-oai-circle.library.ubc.ca-2429-28292018-01-05T17:23:09Z Resource management in wireless networks Pillutla, Laxminarayana S. Spatial correlation Sensor networks WLAN Cognitive radio TCP Dynamic spectrum access Pricing Game theory Nash equilibrium Mutual information This thesis considers resource management issues in wireless sensor networks (WSNs), wireless local area networks (WLANs), and cognitive radio (CR) networks. Since energy is a critical resource in WSNs, we consider energy minimization techniques based on explicit node cooperation and distributed source coding (DSC). The explicit node cooperation based on space time block codes (STBC) improves energy efficiency of WSNs, by reducing the energy consumption per bit of each sensor node. The DSC on the other hand exploits the spatial correlation in WSNs, and thus reduces the data generated in a WSN. For the purpose of our analysis, we model the spatial correlation according to a linear Gauss-Markov model. Through our numerical results, we observe that the node cooperation combined with DSC can improve energy efficiency for many cases of interest. A unique aspect of our work is we obtain important structural results using the concepts from monotone comparative statics. These structural results provide insights into the general design of WSNs. Through our numerical results, we also demonstrate that, the cooperation based transmission can achieve better mutual information (MI)-energy tradeoff than the non-cooperation based transmission scheme. From the perspective of WLANs, we propose a price based approach to regulate the channel occupancy of low rate users, which is known to be the primary cause for low overall throughput in WLANs. Owing to the decentralized nature of WLANs we use non-cooperative game theory as a tool for analysis. Specifically, we use supermodular game theory. Through our analysis, we show that an increase in price leads to an increase in rate of WLAN users. We also prove that the best response dynamics indeed converge to the Nash equilibrium of the underlying non-cooperative game. Through our numerical results, we demonstrate that by proper tuning of the price, the proposed price based approach can lead to an improvement in overall throughput of a WLAN. Finally from the perspective of CR networks, we consider the impact of number of channels captured by a secondary user on its transmission control protocol (TCP) throughput. From our simulation results it was found that, there exists a definite optimal number of channels a secondary user needs to capture, to maximize its TCP throughput. Applied Science, Faculty of Electrical and Computer Engineering, Department of Graduate 2008-12-03T15:38:55Z 2008-12-03T15:38:55Z 2008 2009-05 Text Thesis/Dissertation http://hdl.handle.net/2429/2829 eng Attribution-NonCommercial-NoDerivatives 4.0 International http://creativecommons.org/licenses/by-nc-nd/4.0/ 1312441 bytes application/pdf University of British Columbia
collection NDLTD
language English
format Others
sources NDLTD
topic Spatial correlation
Sensor networks
WLAN
Cognitive radio
TCP
Dynamic spectrum access
Pricing
Game theory
Nash equilibrium
Mutual information
spellingShingle Spatial correlation
Sensor networks
WLAN
Cognitive radio
TCP
Dynamic spectrum access
Pricing
Game theory
Nash equilibrium
Mutual information
Pillutla, Laxminarayana S.
Resource management in wireless networks
description This thesis considers resource management issues in wireless sensor networks (WSNs), wireless local area networks (WLANs), and cognitive radio (CR) networks. Since energy is a critical resource in WSNs, we consider energy minimization techniques based on explicit node cooperation and distributed source coding (DSC). The explicit node cooperation based on space time block codes (STBC) improves energy efficiency of WSNs, by reducing the energy consumption per bit of each sensor node. The DSC on the other hand exploits the spatial correlation in WSNs, and thus reduces the data generated in a WSN. For the purpose of our analysis, we model the spatial correlation according to a linear Gauss-Markov model. Through our numerical results, we observe that the node cooperation combined with DSC can improve energy efficiency for many cases of interest. A unique aspect of our work is we obtain important structural results using the concepts from monotone comparative statics. These structural results provide insights into the general design of WSNs. Through our numerical results, we also demonstrate that, the cooperation based transmission can achieve better mutual information (MI)-energy tradeoff than the non-cooperation based transmission scheme. From the perspective of WLANs, we propose a price based approach to regulate the channel occupancy of low rate users, which is known to be the primary cause for low overall throughput in WLANs. Owing to the decentralized nature of WLANs we use non-cooperative game theory as a tool for analysis. Specifically, we use supermodular game theory. Through our analysis, we show that an increase in price leads to an increase in rate of WLAN users. We also prove that the best response dynamics indeed converge to the Nash equilibrium of the underlying non-cooperative game. Through our numerical results, we demonstrate that by proper tuning of the price, the proposed price based approach can lead to an improvement in overall throughput of a WLAN. Finally from the perspective of CR networks, we consider the impact of number of channels captured by a secondary user on its transmission control protocol (TCP) throughput. From our simulation results it was found that, there exists a definite optimal number of channels a secondary user needs to capture, to maximize its TCP throughput. === Applied Science, Faculty of === Electrical and Computer Engineering, Department of === Graduate
author Pillutla, Laxminarayana S.
author_facet Pillutla, Laxminarayana S.
author_sort Pillutla, Laxminarayana S.
title Resource management in wireless networks
title_short Resource management in wireless networks
title_full Resource management in wireless networks
title_fullStr Resource management in wireless networks
title_full_unstemmed Resource management in wireless networks
title_sort resource management in wireless networks
publisher University of British Columbia
publishDate 2008
url http://hdl.handle.net/2429/2829
work_keys_str_mv AT pillutlalaxminarayanas resourcemanagementinwirelessnetworks
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