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Category : Electronic books
Languages : en
Pages : 116
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The use of frequency division duplex (FDD) communication in a multihop wireless network partitions the nodes in two operating modes (or genders), depending on the frequency bands used for the transmission and reception. Since the FDD nodes of the same gender, located in a 1-hop neighborhood, cannot communicate with each other, it can limit the availability of communication links between the neighboring nodes and leads to network partitioning. Therefore, the operating mode of these nodes should be selected such that every node can establish links with its 1-hop neighbors. The multihop network of static FDD nodes is modeled as a graph, and a novel, distributed bipartite graph coloring scheme, for mode selection of FDD nodes is designed. Unlike the existing graph coloring schemes, which use the entire network topology and yet do not ensure network connectivity, this scheme requires only the local information of the 1-hop neighborhood of each node in a distributed manner. The proposed mode selection algorithm ensures that every FDD node can establish the communication links with approximately half of its 1-hop neighbors for omni as well as directional communication, without introducing any disconnected node. This mode selection algorithm has lower computational complexity and provides robust network connectivity, which would help in fault tolerance and establishing stable routes in the network. Next, a novel, distributed, low-complexity mode reassignment (MR) scheme is designed for maintaining connectivity among the mobile FDD nodes in a decentralized, multihop wireless network. Since it is not practical to know the complete topology of such a network in real-time, the proposed scheme is fully distributed, relies only on the local node information, and is applied only on those nodes whose connectivity drops below a threshold. Besides maintaining a desired value of connectivity degree for each node at all time steps, the proposed MR scheme minimizes the impact of mode change on the existing links and ongoing data transmissions. A Kalman filter based node mobility prediction and link failure prediction scheme is designed to select the best candidate nodes for mode change. Several novel measurements are introduced to evaluate the performance of our MR scheme. The optimality and error control bounds of the proposed MR scheme show that it consistently increases the nodes’ connectivity degree (achieves optimal connectivity for most nodes) while requiring a low number of nodes undergoing the mode change at each MR round. This MR scheme has low computational complexity and would help in establishing stable routes in a mobile network. Next, a mobile wireless ad-hoc network equipped with full-duplex nodes is considered. The full-duplex capability can be provided either by transmitting and receiving data simultaneously in a given frequency band by canceling the self-interference or can be provided by utilizing two separate frequency channels for transmission and reception at the same time in the FDD node. In either case, the full-duplex capability allows the formation of bidirectional routes, where every forward and reverse route between a source and destination pair completely overlaps. These completely overlapped bidirectional routes can support efficient transmission of bidirectional flows between a pair of source and destination nodes. In this dissertation, a novel routing protocol, called as bidirectional AOMDV (BAOMDV) is proposed, that discovers multiple, link-disjoint, bidirectional routes in the network, to make efficient use of full-duplex nodes. This routing protocol overcomes the limitations of existing AOMDV based protocols in finding the bidirectional routes. Additionally, the effect of route break in the presence of multiple active routes among source and destination pairs is considered and a novel bidirectional local route repair scheme called BAOMDV-LR is proposed in this dissertation. This scheme is capable of locally repairing routes formed based on the proposed BAOMDV protocols while preserving the link-disjoint and bidirectional nature of the routes, and can avoid the expensive route discovery procedure in the mobile ad-hoc networks. The scheme helps to maintain multiple active bidirectional routes for longer duration and reduce the need for frequent route discovery. The proposed BAOMDV-LR scheme is able to increase the overall network performance especially at higher data rates, and node speeds.
Author:
Publisher:
ISBN:
Category : Electronic books
Languages : en
Pages : 116
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Book Description
The use of frequency division duplex (FDD) communication in a multihop wireless network partitions the nodes in two operating modes (or genders), depending on the frequency bands used for the transmission and reception. Since the FDD nodes of the same gender, located in a 1-hop neighborhood, cannot communicate with each other, it can limit the availability of communication links between the neighboring nodes and leads to network partitioning. Therefore, the operating mode of these nodes should be selected such that every node can establish links with its 1-hop neighbors. The multihop network of static FDD nodes is modeled as a graph, and a novel, distributed bipartite graph coloring scheme, for mode selection of FDD nodes is designed. Unlike the existing graph coloring schemes, which use the entire network topology and yet do not ensure network connectivity, this scheme requires only the local information of the 1-hop neighborhood of each node in a distributed manner. The proposed mode selection algorithm ensures that every FDD node can establish the communication links with approximately half of its 1-hop neighbors for omni as well as directional communication, without introducing any disconnected node. This mode selection algorithm has lower computational complexity and provides robust network connectivity, which would help in fault tolerance and establishing stable routes in the network. Next, a novel, distributed, low-complexity mode reassignment (MR) scheme is designed for maintaining connectivity among the mobile FDD nodes in a decentralized, multihop wireless network. Since it is not practical to know the complete topology of such a network in real-time, the proposed scheme is fully distributed, relies only on the local node information, and is applied only on those nodes whose connectivity drops below a threshold. Besides maintaining a desired value of connectivity degree for each node at all time steps, the proposed MR scheme minimizes the impact of mode change on the existing links and ongoing data transmissions. A Kalman filter based node mobility prediction and link failure prediction scheme is designed to select the best candidate nodes for mode change. Several novel measurements are introduced to evaluate the performance of our MR scheme. The optimality and error control bounds of the proposed MR scheme show that it consistently increases the nodes’ connectivity degree (achieves optimal connectivity for most nodes) while requiring a low number of nodes undergoing the mode change at each MR round. This MR scheme has low computational complexity and would help in establishing stable routes in a mobile network. Next, a mobile wireless ad-hoc network equipped with full-duplex nodes is considered. The full-duplex capability can be provided either by transmitting and receiving data simultaneously in a given frequency band by canceling the self-interference or can be provided by utilizing two separate frequency channels for transmission and reception at the same time in the FDD node. In either case, the full-duplex capability allows the formation of bidirectional routes, where every forward and reverse route between a source and destination pair completely overlaps. These completely overlapped bidirectional routes can support efficient transmission of bidirectional flows between a pair of source and destination nodes. In this dissertation, a novel routing protocol, called as bidirectional AOMDV (BAOMDV) is proposed, that discovers multiple, link-disjoint, bidirectional routes in the network, to make efficient use of full-duplex nodes. This routing protocol overcomes the limitations of existing AOMDV based protocols in finding the bidirectional routes. Additionally, the effect of route break in the presence of multiple active routes among source and destination pairs is considered and a novel bidirectional local route repair scheme called BAOMDV-LR is proposed in this dissertation. This scheme is capable of locally repairing routes formed based on the proposed BAOMDV protocols while preserving the link-disjoint and bidirectional nature of the routes, and can avoid the expensive route discovery procedure in the mobile ad-hoc networks. The scheme helps to maintain multiple active bidirectional routes for longer duration and reduce the need for frequent route discovery. The proposed BAOMDV-LR scheme is able to increase the overall network performance especially at higher data rates, and node speeds.
Author: Anita Yadav
Publisher: GRIN Verlag
ISBN: 3346132161
Category : Computers
Languages : en
Pages : 142
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Doctoral Thesis / Dissertation from the year 2016 in the subject Computer Science - Miscellaneous, grade: 16, , language: English, abstract: In this thesis, we have modified AODV routing protocol by incorporating link prediction algorithm using a proposed link prediction model. This algorithm predicts the link availability time and even before the link breaks; either it repairs the route locally or sends information to the source nodes to enable them to initiate a new route search well in time. This algorithm improves the quality of service of the network. Simulation results show that AODV routing algorithm with link availability model performs better than the existing AODV. Advances in wireless technology and hand-held computing devices have brought revolution in the area of mobile communication. The increasing mobility of humans across the globe generated demand for infrastructure-less and quickly deployable mobile networks. Such networks are referred to as Mobile Adhoc Networks (MANET). Usually, nodes in a MANET also act as a router while being is free to roam while communicating each others. Adhoc networks are suited for use in situations where infrastructure is unavailable or to deploy one is not cost-effective. Frequent changes in network topology due to mobility and limited battery power of the mobile devices are the key challenges in the adhoc networks. The depletion of power source may cause early unavailability of nodes and thus links in the network. The mobility of nodes will also causes frequent routes breaks and adversely affects the required performance for the applications. Availability of a route in future mainly depends on the availability of links between the nodes forming the route. Therefore, it is important to predict the future availability of a link that is currently available. We have proposed an analytical model for link prediction using Newton divided difference method. This link availability algorithm is incorporated in AODV routing algorithm (AODVLP) to evaluate the performance of AODV routing protocol using the metrics viz. delivery rate, average end-to-end delay, average RTS collisions per node and route failure. In the existing AODV protocol, packets are routed until a link in the existing path fails. This results in degradation of quality of service of network in terms of end-to-end delay and delivery ratio.
Author:
Publisher:
ISBN:
Category : Electronic books
Languages : en
Pages : 64
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The main challenges of designing mobile ad hoc network (MANET) is in the design of a robust routing algorithm that can find efficient routes capable of adapting to the frequent changes in network topology, and the design of a MAC protocol that can efficiently share the available physical channel with minimum collisions. In this thesis, we consider a wireless ad-hoc network consisting of multi-beam frequency division duplex (FDD) nodes. The multi-beams FDD nodes are able to communicate on their different beams simultaneously and form full-duplex links using frequency division duplex. This allows for formation of the full-duplex, bidirectional routes between the source and destination nodes. First, we discuss the full-duplex MAC layer protocol to support the bidirectional wireless links between two multi-beam FFD nodes. Secondly, we discuss the use of multiple disjoint bidirectional routes in the network that make the most efficient use of multi-beam FDD nodes. We study the routing protocols such as ad hoc on-demand multipath distance vector (AOMDV) and its extensions, in order to find multiple loop-free disjoint routes between source and destination node pairs. Also these routes are needed to be bidirectional to handle the full-duplex data flow between a source and destination node. We study the performance and limitations of AOMDV and Optimized AOMDV (OAOMDV) in finding the multiple routes using the bidirectional routes that can handle full-duplex data flows between source and destination. Having looked at the limitations of these protocols, we present a better routing protocol, called the Bidirectional Routing AOMDV (BR-AOMDV) that can overcome these limitations in finding the bidirectional routes.
Author: Ahed Alshanyour
Publisher:
ISBN:
Category :
Languages : en
Pages : 138
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Book Description
Mobile Ad Hoc Networks (MANETs) are gaining increasing popularity in recent years because of their ease of deployment. They are distributed, dynamic, and self-configurable without infrastructure support. Routing in ad hoc networks is a challenging task because of the MANET dynamic nature. Hence, researchers were focused in designing best-effort distributed and dynamic routing protocols to ensure optimum network operations in an unpredictable wireless environment. Nowadays, there is an increased demand on multimedia applications (stringent delay and reliability requirements), which makes a shift from best-effort services to Quality of Services. Actually, the challenge in wireless ad hoc networks is that neighbor nodes share the same channel and they take part in forwarding packets. Therefore, the total effective channel capacity is not only limited by the raw channel capacity but is also limited by the interactions and interferences among neighboring nodes. Thus, such factors should be taken in consideration in order to offer QoS routing. While, some of the distributed QoS route selection algorithms assume the availability of such information, others propose mechanisms to estimate them. The goals of this thesis are: (i) to analyze the performance of IEEE 802.11 MAC mechanism in non-saturation conditions, (ii) to use the analysis in the context of multi-hop ad hoc networks, (iii) to derive theoretical limits for nodes performance in multi-hop ad hoc networks, (iv) to use the multi-hop analysis in QoS route selection. We start the thesis by proposing a discrete-time 3D Markov chain model to analyze the saturation performance of the RTS/CTS access mode. This model integrates the backoff countdown process, retransmission retry limits, and transmission errors into one model. The impact of system parameters (e.g., number of nodes, packet size, retry limits, and BERs) are analyzed. Next, we extend the 3D model to analyze the performance under non-saturation conditions and finite buffer capacity using two different approaches. First, we extend the 3D model into a 4D model to integrate the transmission buffer behavior. Second, we replace the 4D model by an M/G/1/K queueing system model with independent samples from the saturation analysis. The latter model gives similar results as the former but with a reduction in the analysis complexity. Next and by means of the non-saturation analysis, we proposed an approximate mathematical model for multi-hop ad hoc networks. Furthermore, we proposed an iterative mechanism to estimate the throughput in the presence of multiple flows. Finally, we used the multi-hop analysis to propose a QoS route selection algorithm. In this algorithm, we concentrate on the throughput as a QoS parameter. However, the proposed algorithm is valid to be used with other QoS parameters, such as packet delay, packet loss probability, and fairness. Analytical and simulation results show the deficiency of the current route selection algorithm in AODV and at the same time verifies the need for QoS route selection algorithms.
Author: Hui Xu
Publisher:
ISBN:
Category :
Languages : en
Pages : 270
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Author: G Ram Mohana Reddy
Publisher: CRC Press
ISBN: 1315351633
Category : Computers
Languages : en
Pages : 139
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Book Description
In recent years, a lot of work has been done in an effort to incorporate Swarm Intelligence (SI) techniques in building an adaptive routing protocol for Mobile Ad Hoc Networks (MANETs). Since centralized approach for routing in MANETs generally lacks in scalability and fault-tolerance, SI techniques provide a natural solution through a distributed approach for the adaptive routing for MANETs. In SI techniques, the captivating features of insects or mammals are correlated with the real world problems to find solutions. Recently, several applications of bio-inspired and nature-inspired algorithms in telecommunications and computer networks have achieved remarkable success. The main aims/objectives of this book, "Mobile Ad Hoc Networks: Bio-Inspired Quality of Service Aware Routing Protocols", are twofold; firstly it clearly distinguishes between principles of traditional routing protocols and SI based routing protocols, while explaining in detail the analogy between MANETs and SI principles. Secondly, it presents the readers with important Quality of Service (QoS) parameters and explains how SI based routing protocols achieves QoS demands of the applications. This book also gives quantitative and qualitative analysis of some of the SI based routing protocols for MANETs.
Author: Hong Yi Xiong
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Author: Dr.D.Usha
Publisher: SK Research Group of Companies
ISBN: 9391077943
Category : Technology & Engineering
Languages : en
Pages : 106
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Book Description
Dr.D.Usha, Assistant Professor, Department of Computer Science, Mother Teresa Womens University, Kodaikanal, Tamil Nadu, India
Author: Yali Wang
Publisher:
ISBN:
Category :
Languages : en
Pages : 84
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Author: Stephen Ng Mueller
Publisher:
ISBN:
Category :
Languages : en
Pages : 146
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