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Overview of the Telemetry Network System (TMNS) RF Data Link LayerKaba, James, Connolly, Barbara 10 1900 (has links)
ITC/USA 2012 Conference Proceedings / The Forty-Eighth Annual International Telemetering Conference and Technical Exhibition / October 22-25, 2012 / Town and Country Resort & Convention Center, San Diego, California / As the integrated Network Enhanced Telemetry (iNET) program prepares for developmental flights tests, refinements are being made to the Radio Access Network Standard that ensures interoperability of networked radio components. One key aspect of this interoperability is the definition of Telemetry Network System (TmNS) RF Data Link Layer functionality for conducting efficient communications between radios in a TDMA (Time Division Multiple Access) channel sharing scheme. This paper examines the overall structure of the TmNS RF Data Link Layer and provides an overview of its operation. Specific topics include Medium Access Control (MAC) scheduling and framing in the context of a burst-oriented TDMA structure, link layer encryption, the priority-enabled Automatic Repeat reQuest (ARQ) protocol, high-level network packet and link control message encapsulation, payload segmentation and reassembly, and radio Link Layer Control Messaging.
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Dynamic wireless access methods with applications to eHealth servicesPhunchongharn, Phond January 2009 (has links)
For opportunistic spectrum access and spectrum sharing in cognitive radio networks, one key problem is how to develop wireless access schemes for secondary users so that harmful interference to primary users can be avoided and quality-of-service
(QoS) of secondary users can be guaranteed. In this research, dynamic wireless access protocols for secondary users are designed and optimized for both infrastructure-based and ad-hoc wireless networks.
Under the infrastructure-based model, the secondary users are connected through a controller (i.e., an access point). In particular, the problem of wireless access for eHealth applications is considered. In a single service cell, an innovative wireless access scheme, called electromagnetic interference (EMI)-aware prioritized wireless access, is proposed to address the issues of EMI to the medical devices and QoS differentiation for different eHealth applications. Afterwards, the resource management problem for multiple service cells, specifically, in multiple spatial reuse time-division multiple access (STDMA) networks is addressed. The problem is formulated as a dual objective optimization problem that maximizes the spectrum utilization of secondary users and minimizes their power consumption subject to the EMI constraints for active and passive medical devices and minimum throughput guarantee for secondary users. Joint scheduling and power control algorithms based on greedy approaches are proposed to solve the problem with much less computational complexity.
In an ad-hoc wireless network, the robust transmission scheduling and power control problem for collision-free spectrum sharing between secondary and primary users in STDMA wireless networks is investigated. Traditionally, the problem only considers the average link gains; therefore, QoS violation can occur due to improper power allocation with respect to instantaneous channel gain realization. To overcome this problem, a robust power control problem is formulated. A column generation based algorithm is proposed to solve the problem by considering only the potential subset of variables when solving the problem. To increase the scalability, a novel distributed two-stage algorithm based on the distributed column generation method is then proposed to obtain the near-optimal solution of the robust transmission schedules for vertical spectrum sharing in an ad-hoc wireless network.
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MULTIPLE CHANNEL COHERENT AMPLITUDE MODULATED (AM) TIME DIVISION MULTIPLEXING (TDM) SOFTWARE DEFINED RADIO (SDR) RECEIVERAlluri, Veerendra Bhargav 01 January 2008 (has links)
It is often required in communication and navigation systems to be able to receive signals from multiple stations simultaneously. A common practice to do this is to use multiple hardware resources; a different set of resources for each station. In this thesis, a Coherent Amplitude Modulated (AM) receiver system was developed based on Software Defined Radio (SDR) technology enabling reception of multiple signals using hardware resources needed only for one station. The receiver system architecture employs Time Division Multiplexing (TDM) to share the single hardware resource among multiple streams of data. The architecture is designed so that it can be minimally modified to support any number of stations. The Verilog Hardware Description Language (HDL) was used to capture the receiver system architecture and design. The design and architecture are initially validated using HDL post-synthesis and post-implementation simulation. In addition, the receiver system architecture and design were implemented to a Xilinx Field Programmable Gate Array (FPGA) technology prototyping board for experimental testing and final validation.
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Energy efficient distributed receiver based cooperative medium access control protocol for wireless sensor networks.Gama, Sithembiso G. January 2013 (has links)
Wireless sensor networks are battery operated computing and sensing devices that collaborate to
achieve a common goal for a specific application. They are formed by a cluster of sensor nodes
where each sensor node is composed of a single chip with embedded memory (microprocessor), a
transceiver for transmission and reception (resulting in the most energy consumption), a sensor device
for event detection and a power source to keep the node alive. Due to the environmental nature
of their application, it is not feasible to change or charge the power source once a sensor node is deployed.
The main design objective in WSNs (Wireless Sensor Networks) is to define effective and
efficient strategies to conserve energy for the nodes in the network. With regard to the transceiver,
the highest consumer of energy in a sensor node, the factors contributing to energy consumption in
wireless sensor networks include idle listening, where nodes keep listening on the channel with no
data to receive; ovehearing, where nodes hears or intercept data that is meant for a different node;
and collision, which occurs at the sink node when it receives data from different nodes at the same
time. These factors all arise during transmission or reception of data in the Transceiver module in
wireless sensor networks.
A MAC (Medium Access Control) protocol is one of the techniques that enables successful operation
while minimizing the energy consumption in the network. Its task is to avoid collision,
reduce overhearing and to reduce idle listening by properly managing the state of each node in the
network. The aim, when designing a MAC protocol for WSNs is to achieve a balance amongst
minimum energy consumption, minimum latency, maximum fault-tolerance and providing QoS
(Quality of Service).
To carefully achieve this balance, this dissertation has proposed, designed, simulated and analyzed
a new cooperative MAC scheme with an overhearing avoidance technique with the aim of
minimizing energy consumption by attempting to minimize the overhearing in the WSN. The new
MAC protocol for WSNs supports the cooperative diversity and overhearing communications in
order to reduce the effects of energy consumption thus increase the network lifetime, providing improved
communication reliability and further mitigating the effects of multipath fading in WSNs.
The MAC scheme in this work focuses on cooperation with overhearing avoidance and reducing
transmissions in case of link failures in order to minimize energy consumption. The cooperative
MAC scheme presented herein uses the standard IEEE 802.15.4 scheme as its base physical
model. It introduces cooperation, overhearing avoidance, receiver based relay node selection and a Markov-based channel state estimation. The performance analysis of the developed Energy Efficient
Distributed Receiver based MAC (E2DRCMAC) protocol for WSNs shows an improvement
from the standard IEEE 802.15.4 MAC layer with regard to the energy consumption, throughput,
reliability of message delivery, bit error rates, system capacity, packet delay, packet error rates, and
packet delivery ratios. / M.Sc.Eng. University of KwaZulu-Natal, Durban 2013.
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Dynamic wireless access methods with applications to eHealth servicesPhunchongharn, Phond January 2009 (has links)
For opportunistic spectrum access and spectrum sharing in cognitive radio networks, one key problem is how to develop wireless access schemes for secondary users so that harmful interference to primary users can be avoided and quality-of-service
(QoS) of secondary users can be guaranteed. In this research, dynamic wireless access protocols for secondary users are designed and optimized for both infrastructure-based and ad-hoc wireless networks.
Under the infrastructure-based model, the secondary users are connected through a controller (i.e., an access point). In particular, the problem of wireless access for eHealth applications is considered. In a single service cell, an innovative wireless access scheme, called electromagnetic interference (EMI)-aware prioritized wireless access, is proposed to address the issues of EMI to the medical devices and QoS differentiation for different eHealth applications. Afterwards, the resource management problem for multiple service cells, specifically, in multiple spatial reuse time-division multiple access (STDMA) networks is addressed. The problem is formulated as a dual objective optimization problem that maximizes the spectrum utilization of secondary users and minimizes their power consumption subject to the EMI constraints for active and passive medical devices and minimum throughput guarantee for secondary users. Joint scheduling and power control algorithms based on greedy approaches are proposed to solve the problem with much less computational complexity.
In an ad-hoc wireless network, the robust transmission scheduling and power control problem for collision-free spectrum sharing between secondary and primary users in STDMA wireless networks is investigated. Traditionally, the problem only considers the average link gains; therefore, QoS violation can occur due to improper power allocation with respect to instantaneous channel gain realization. To overcome this problem, a robust power control problem is formulated. A column generation based algorithm is proposed to solve the problem by considering only the potential subset of variables when solving the problem. To increase the scalability, a novel distributed two-stage algorithm based on the distributed column generation method is then proposed to obtain the near-optimal solution of the robust transmission schedules for vertical spectrum sharing in an ad-hoc wireless network.
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Optimal allocation of power to AMCS for maximum throughput in WCDMA /Lu, Hong, January 1900 (has links)
Thesis (M.App.Sc.) - Carleton University, 2002. / Includes bibliographical references (p. 124-127). Also available in electronic format on the Internet.
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Network time synchronization and code-based scheduling for wireless Ad Hoc network /Rentel, Carlos H. January 1900 (has links)
Thesis (Ph.D.) - Carleton University, 2006. / Includes bibliographical references (p. 156-164). Also available in electronic format on the Internet.
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Flexible-schedule-based TDMA protocols for supporting fault-tolerance, on-demand TDMA slot transfer, and peer-to-peer communication in wireless sensor networks /Louis Lee, Winnie. January 2008 (has links)
Thesis (Ph.D.)--University of Western Australia, 2008.
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"Integration of smart antennas with software radio" /Wang, Wei, January 1900 (has links)
Thesis (M. Eng.)--Carleton University, 2000. / Includes bibliographical references. Also available in electronic format on the Internet.
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Network-layer reservation TDM for ad-hoc 802.11 networksDuff, Kevin Craig January 2008 (has links)
Ad-Hoc mesh networks offer great promise. Low-cost ad-hoc mesh networks can be built using popular IEEE 802.11 equipment, but such networks are unable to guarantee each node a fair share of bandwidth. Furthermore, hidden node problems cause collisions which can cripple the throughput of a network. This research proposes a novel mechanism which is able to overcome hidden node problems and provide fair bandwidth sharing among nodes on ad-hoc 802.11 networks, and can be implemented on existing network devices. The scheme uses TDM (time division multiplexing) with slot reservation. A distributed beacon packet latency measurement mechanism is used to achieve node synchronisation. The distributed nature of the mechanism makes it applicable to ad-hoc 802.11 networks, which can either grow or fragment dynamically.
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