Resource Management in Multi-hop Cellular Networks

In recent years, mobile communications have become affordable and popular. High cellular capacity in terms of number of users and data-rates is in need. As the available frequency spectrums for mobile communications are limited, the utilization of the radio resources to achieve high capacity without...

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Main Author: Tam, Yik Hung
Other Authors: Queen's University (Kingston, Ont.). Theses (Queen's University (Kingston, Ont.))
Format: Others
Language:en
en
Published: 2009
Subjects:
TDD
Online Access:http://hdl.handle.net/1974/1694
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-OKQ.1974-16942013-12-20T03:39:00ZResource Management in Multi-hop Cellular NetworksTam, Yik Hungmulti-hopTDDCDMAcellular networksoptimalchannel assignmentcell sizecoverageW-CDMAIn recent years, mobile communications have become affordable and popular. High cellular capacity in terms of number of users and data-rates is in need. As the available frequency spectrums for mobile communications are limited, the utilization of the radio resources to achieve high capacity without imposing high equipment cost is of utmost importance. Recently, multi-hop cellular networks (MCNs) were introduced. These networks have the potential of enhancing the cell capacity and extending the cell coverage at low extra cost. However, in a cellular network, the cell or system capacity is inversely related to the cell size. In MCNs, the cell size, the network density and topology affect the coverage of source nodes and the total demands that can be served and, thus, the system throughput. Although the cell size is an important factor, it has not been exploited for maximizing throughput. Another major issue in MCNs is the increase in packet delay because multi-hopping is involved. High packet delay affects quality of service provisioning in these networks. In this thesis, we propose the Optimal Cell Size (OCS) and the Optimal Channel Assignment (OCA) schemes to address the cell size and packet delay issues for a time division duplex (TDD) wideband code division multiple access (W-CDMA) MCN. OCS finds the optimal cell sizes to provide an optimal balance of cell capacity and coverage to maximize the system throughput, whereas OCA assigns channels optimally in order to minimize packet relaying delay. Like many optimized schemes, OCS and OCA are computationally expensive and may not be suitable for large real-time problems. Hence, we also propose heuristics for solving the problems. For the cell size problem, we propose two heuristics: Smallest Cell Size First (SCSF) and Highest Throughput Cell Size First (HTCSF). For the channel assignment problem, we propose the Minimum Slot Waiting First (MSWF) heuristic. Simulation results show that OCS achieves high throughput compared to that of conventional (single-hop) cellular networks and OCA achieves low packet delay in MCNs. Results also show that the heuristics, SCSF, HTCSF and MSWF, provide good results compared to the optimal ones provided by OCS and OCA, respectively.Thesis (Ph.D, Computing) -- Queen's University, 2009-02-02 22:53:41.825Queen's University (Kingston, Ont.). Theses (Queen's University (Kingston, Ont.))2009-01-30 16:58:28.7622009-02-02 22:53:41.8252009-02-03T16:59:37Z2009-02-03T16:59:37Z2009-02-03T16:59:37ZThesis690394 bytesapplication/pdfhttp://hdl.handle.net/1974/1694enenCanadian thesesThis publication is made available by the authority of the copyright owner solely for the purpose of private study and research and may not be copied or reproduced except as permitted by the copyright laws without written authority from the copyright owner.
collection NDLTD
language en
en
format Others
sources NDLTD
topic multi-hop
TDD
CDMA
cellular networks
optimal
channel assignment
cell size
coverage
W-CDMA
spellingShingle multi-hop
TDD
CDMA
cellular networks
optimal
channel assignment
cell size
coverage
W-CDMA
Tam, Yik Hung
Resource Management in Multi-hop Cellular Networks
description In recent years, mobile communications have become affordable and popular. High cellular capacity in terms of number of users and data-rates is in need. As the available frequency spectrums for mobile communications are limited, the utilization of the radio resources to achieve high capacity without imposing high equipment cost is of utmost importance. Recently, multi-hop cellular networks (MCNs) were introduced. These networks have the potential of enhancing the cell capacity and extending the cell coverage at low extra cost. However, in a cellular network, the cell or system capacity is inversely related to the cell size. In MCNs, the cell size, the network density and topology affect the coverage of source nodes and the total demands that can be served and, thus, the system throughput. Although the cell size is an important factor, it has not been exploited for maximizing throughput. Another major issue in MCNs is the increase in packet delay because multi-hopping is involved. High packet delay affects quality of service provisioning in these networks. In this thesis, we propose the Optimal Cell Size (OCS) and the Optimal Channel Assignment (OCA) schemes to address the cell size and packet delay issues for a time division duplex (TDD) wideband code division multiple access (W-CDMA) MCN. OCS finds the optimal cell sizes to provide an optimal balance of cell capacity and coverage to maximize the system throughput, whereas OCA assigns channels optimally in order to minimize packet relaying delay. Like many optimized schemes, OCS and OCA are computationally expensive and may not be suitable for large real-time problems. Hence, we also propose heuristics for solving the problems. For the cell size problem, we propose two heuristics: Smallest Cell Size First (SCSF) and Highest Throughput Cell Size First (HTCSF). For the channel assignment problem, we propose the Minimum Slot Waiting First (MSWF) heuristic. Simulation results show that OCS achieves high throughput compared to that of conventional (single-hop) cellular networks and OCA achieves low packet delay in MCNs. Results also show that the heuristics, SCSF, HTCSF and MSWF, provide good results compared to the optimal ones provided by OCS and OCA, respectively. === Thesis (Ph.D, Computing) -- Queen's University, 2009-02-02 22:53:41.825
author2 Queen's University (Kingston, Ont.). Theses (Queen's University (Kingston, Ont.))
author_facet Queen's University (Kingston, Ont.). Theses (Queen's University (Kingston, Ont.))
Tam, Yik Hung
author Tam, Yik Hung
author_sort Tam, Yik Hung
title Resource Management in Multi-hop Cellular Networks
title_short Resource Management in Multi-hop Cellular Networks
title_full Resource Management in Multi-hop Cellular Networks
title_fullStr Resource Management in Multi-hop Cellular Networks
title_full_unstemmed Resource Management in Multi-hop Cellular Networks
title_sort resource management in multi-hop cellular networks
publishDate 2009
url http://hdl.handle.net/1974/1694
work_keys_str_mv AT tamyikhung resourcemanagementinmultihopcellularnetworks
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