240 research outputs found
Wireless remote patient monitoring on general hospital wards.
A novel approach which has potential to improve quality of patient care on general hospital wards is proposed. Patient care is a labour-intensive task that requires high input of human resources. A Remote Patient Monitoring (RPM) system is proposed which can go some way towards improving patient monitoring on general hospital wards. In this system vital signs are gathered from patients and sent to a control unit for centralized monitoring. The RPM system can complement the role of nurses in monitoring patients’ vital signs. They will be able to focus on holistic needs of patients thereby providing better personal care. Wireless network technologies, ZigBee and Wi-Fi, are utilized for transmission of vital signs in the proposed RPM system. They provide flexibility and mobility to patients. A prototype system for RPM is designed and simulated. The results illustrated the capability, suitability and limitation of the chosen technology
Adaptive parameters adjustment in WBAN to mitigate Wi-Fi interferences
Wireless Body Area Network (WBAN), called also Wireless Body Sensor Network (WBSN), is composed of a set of tiny wireless devices (sensors) attached, implanted or ingested into the body. It offers real time and ubiquitous applications thanks to the small form, the lightness, and the wireless interface of sensors. WBAN performance is expected to be considerably degraded in the presence of Wi-Fi networks. Their operating channels overlap in the 2.4 GHz Industrial Scientific and Medical (ISM) band which produces interference when they transmit data, accompanied by data losses and quick battery exhaustion. Therefore, it is crucial to mitigate the interference between WBAN and Wi-Fi networks in order to maintain the efficiency and the reliability of the WBAN system. Proposals in the literature use an added complex hardware in WBAN system, or perform the exchange of additional information, or establish expensive communications, or affect the quality of service of the WBAN. Unlike previous researches, we proposed simple, low cost and dynamic method that adaptively adjusts specific parameters in the Medium Access Control (MAC) layer. We have proved the effectiveness of our approach based on theoretical analysis and simulation using MiXiM framework of OMNet++ simulato
Wireless remote patient monitoring on general hospital wards
A novel approach which has potential to improve quality of patient care on general hospital wards is proposed. Patient care is a labour-intensive task that requires high input of human resources. A Remote Patient Monitoring (RPM) system is proposed which can go some way towards improving patient monitoring on general hospital wards. In this system vital signs are gathered from patients and sent to a control unit for centralized monitoring. The RPM system can complement the role of nurses in monitoring patients’ vital signs. They will be able to focus on holistic needs of patients thereby providing better personal care. Wireless network technologies, ZigBee and Wi-Fi, are utilized for transmission of vital signs in the proposed RPM system. They provide flexibility and mobility to patients. A prototype system for RPM is designed and simulated. The results illustrated the capability, suitability and limitation of the chosen technology.EThOS - Electronic Theses Online ServiceGBUnited Kingdo
Low-Power Wireless for the Internet of Things: Standards and Applications: Internet of Things, IEEE 802.15.4, Bluetooth, Physical layer, Medium Access Control,coexistence, mesh networking, cyber-physical systems, WSN, M2M
International audienceThe proliferation of embedded systems, wireless technologies, and Internet protocols have enabled the Internet of Things (IoT) to bridge the gap between the virtual and physical world through enabling the monitoring and actuation of the physical world controlled by data processing systems. Wireless technologies, despite their offered convenience, flexibility, low cost, and mobility pose unique challenges such as fading, interference, energy, and security, which must be carefully addressed when using resource-constrained IoT devices. To this end, the efforts of the research community have led to the standardization of several wireless technologies for various types of application domains depending on factors such as reliability, latency, scalability, and energy efficiency. In this paper, we first overview these standard wireless technologies, and we specifically study the MAC and physical layer technologies proposed to address the requirements and challenges of wireless communications. Furthermore, we explain the use of these standards in various application domains, such as smart homes, smart healthcare, industrial automation, and smart cities, and discuss their suitability in satisfying the requirements of these applications. In addition to proposing guidelines to weigh the pros and cons of each standard for an application at hand, we also examine what new strategies can be exploited to overcome existing challenges and support emerging IoT applications
Remote vital signs monitoring based on wireless sensor networks
Tese de doutoramento em Líderes para as Indústrias TecnológicasGovernmental and private institutions face a major challenge to provide quality
health care to a population consisting of a growing number of elderly and chronically ill
patients. According to the World Health Organization, in 2006, the total global health
expenditures exceeded US$ 4 trillion and are rising in the majority of countries
including Portugal which, during 2006, expended 9.9% of its gross domestic product in
health care.
The use of remote vital signs monitoring systems increases the probability of early
detection of risky situations, allows frequent monitoring of in-patients, elderly and
chronically ill patients, and streamlines the work of health professionals. However, at
present, these systems are expensive, complex and employ obtrusive sensors, which
limit their application to intensive care units and cardiac intermediate care units.
This work is part of a project that aims to design, prototype and evaluate a remote
vital signs monitoring system based on the IEEE 802.15.4 and ZigBee protocols, which
allow the development of small low-power sensors. The prototype system comprises
electrocardiogram/heart rate and axillary thermometer sensors, networking devices and
three informatics applications that collect, process, and exhibit medical data.
The wireless sensors, the networking devices and one of the applications were
developed under this work. Additionally, the wireless sensor network was evaluated
through simulations at the MAC level and experimental and field tests. Field tests were
performed at an in-patient floor of Hospital Privado de Guimarães, a Portuguese
hospital. Finally, questionnaires were used to measure the satisfaction of users and
catalog their critics and suggestions for improvement. Simulations considered different topologies, operation modes and a crescent
number of sensors and hops. Experimental and field tests confirmed most of the results
obtained by simulations, but revealed that networks which did not assign transmission
time slots to electrocardiogram sensors were unable to maintain a high delivery ratio.
Contention between devices, aggravated by the inability of routers in receiving
incoming packets during backoff, and collisions between packets generated by hiddennodes
were responsible for most message losses. On the other hand, beacon-enabled star
IEEE 802.15.4 networks that assigned a guaranteed time slot to sensors were able to
maintain a very high delivery ratio. In contrast, these networks are restricted in terms of
the coverage area and the number of sensors. Also, field tests showed that under low
traffic scenarios ZigBee nonbeacon-enabled networks can achieve a high delivery ratio
even in presence of a high percentage of hidden-nodes.Instituições governamentais e privadas enfrentam um grande desafio para prestar
cuidados de saúde de qualidade a uma população constituída por um número crescente
de idosos e doentes crónicos. Segundo a Organização Mundial de Saúde, em 2006, a
despesa mundial em saúde ultrapassou a quantia de 4 bilhões de dólares americanos e
cresce anualmente na maioria dos países, incluindo Portugal, o qual, em 2006, gastou
9,9% do seu produto interno bruto em cuidados de saúde.
O uso de sistemas de monitorização remota de sinais vitais aumenta a probabilidade
de deteção precoce de situações de risco, permite que doentes internados, idosos ou
doentes crónicos sejam frequentemente monitorizados e agiliza o trabalho dos
profissionais de saúde. No entanto, atualmente, estes sistemas são caros e complexos, o
que limita a sua aplicação a alguns setores dos hospitais, tais como as unidades de
cuidados intensivos e as unidades de cuidados intermédios na área da cardiologia.
O projeto no qual insere-se este trabalho visa a conceção, a prototipagem e a
avaliação de um sistema de monitorização remota de sinais vitais com base nos
protocolos IEEE 802.15.4 e ZigBee, os quais oferecem a possibilidade de construção de
sensores com consumos energéticos muito baixos e reduzidas dimensões. O sistema
consiste em sensores de eletrocardiograma/frequência cardíaca e temperatura axilar,
dispositivos de rede e três aplicações que coletam, processam e apresentam o
eletrocardiograma e os sinais vitais.
No âmbito deste trabalho foram desenvolvidos os sensores sem fios, os dispositivos
de rede e uma das aplicações informáticas. Além disso, foi feita a avaliação do
desempenho da rede de sensores sem fios através da análise de simulações a nível da
camada de acesso ao meio (MAC) e de testes de laboratório e de campo. Os testes de campo da rede de sensores sem fios foram executados em um dos pisos de internamento
do Hospital Privado de Guimarães. Finalmente, foram usados questionários para medir
a satisfação dos utilizadores e recolher críticas e sugestões de melhoria.
As simulações consideraram diferentes topologias e modos de operação, além de
um número crescente de sensores e saltos. Testes experimentais e de campo
confirmaram grande parte dos resultados obtidos por simulação mas, adicionalmente,
revelaram que as redes constituídas por vários sensores de eletrocardiograma e que não
reservaram um intervalo de tempo de transmissão aos sensores não foram capazes de
manter uma elevada taxa de entrega de mensagens. Perdas de mensagens ocorreram
devido a disputas entre sensores pelo acesso ao canal sem fios e devido a ocorrência de
colisões de pacotes transmitidos por nós escondidos. Por outro lado, as redes baseadas
no protocolo IEEE 802.15.4 que atribuíram um intervalo de tempo de transmissão a
cada sensor conseguiram manter uma elevada taxa de entrega. Entretanto, essas redes
são limitadas em termos da área de cobertura e do número de sensores. Adicionalmente,
durante os testes de campo em cenários de tráfego reduzido, as redes ZigBee que não
empregaram beacons atingiram uma elevada taxa de entrega mesmo na presença de uma
grande percentagem de nós escondidos
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Application priority framework for fixed mobile converged communication networks
This thesis was submitted for the degree of Doctor of Philosophy and awarded by Brunel University.The current prospects in wired and wireless access networks, it is becoming increasingly important to address potential convergence in order to offer integrated broadband services. These systems will need to offer higher data transmission capacities and long battery life, which is the catalyst for an everincreasing variety of air interface technologies targeting local area to wide area connectivity. Current integrated industrial networks do not offer application aware context delivery and enhanced services for optimised networks. Application aware services provide value-added functionality to business applications by capturing, integrating, and consolidating intelligence about users and their endpoint devices from various points in the network. This thesis mainly intends to resolve the issues related to ubiquitous application aware service, fair allocation of radio access, reduced energy consumption and improved capacity. A technique that measures and evaluates the data rate demand to reduce application response time and queuing delay for multi radio interfaces is proposed. The technique overcomes the challenges of network integration, requiring no user intervention, saving battery life and selecting the radio access connection for the application requested by the end user. This study is split in two parts. The first contribution identifies some constraints of the services towards the application layer in terms of e.g. data rate and signal strength. The objectives are achieved by application controlled handover (ACH) mechanism in order to maintain acceptable data rate for real-time application services. It also looks into the impact of the radio link on the application and identifies elements and parameters like wireless link quality and handover that will influence the application type. It also identifies some enhanced traditional mechanisms such as distance controlled multihop and mesh topology required in order to support energy efficient multimedia applications. The second contribution unfolds an intelligent application priority assignment mechanism (IAPAM) for medical applications using wireless sensor networks. IAPAM proposes and evaluates a technique based on prioritising multiple virtual queues for the critical nature of medical data to improve instant transmission. Various mobility patterns (directed, controlled and random waypoint) has been investigated and compared by simulating IAPAM enabled mobile BWSN. The following topics have been studied, modelled, simulated and discussed in this thesis: 1. Application Controlled Handover (ACH) for multi radios over fibre 2. Power Controlled Scheme for mesh multi radios over fibre using ACH 3. IAPAM for Biomedical Wireless Sensor Networks (BWSN) and impact of mobility over IAPAM enabled BWSN. Extensive simulation studies are performed to analyze and to evaluate the proposed techniques. Simulation results demonstrate significant improvements in multi radios over fibre performance in terms of application response delay and power consumption by upto 75% and 15 % respectively, reduction in traffic loss by upto 53% and reduction in delay for real time application by more than 25% in some cases
Towards reliable communication in low-power wireless body area networks
Es wird zunehmend die Ansicht vertreten, dass tragbare Computer und Sensoren neue Anwendungen in den Bereichen Gesundheitswesen, personalisierte Fitness oder erweiterte Realität ermöglichen werden. Die am Körper getragenen Geräte sind dabei mithilfe eines Wireless Body Area Network (WBAN) verbunden, d.h. es wird drahtlose Kommunikation statt eines drahtgebundenen Kanals eingesetzt. Der drahtlose Kanal ist jedoch typischerweise ein eher instabiles Kommunikationsmedium und die Einsatzbedingungen von WBANs sind besonders schwierig: Einerseits wird die Kanalqualität stark von den physischen Bewegungen der Person beeinflusst, andererseits werden WBANs häufig in lizenzfreien Funkbändern eingesetzt und sind daher Störungen von anderen drahtlosen Geräten ausgesetzt. Oft benötigen WBAN Anwendungen aber eine zuverlässige Datenübertragung.
Das erste Ziel dieser Arbeit ist es, ein besseres Verständnis dafür zu schaffen, wie sich die spezifischen Einsatzbedingungen von WBANs auf die intra-WBAN Kommunikation auswirken. So wird zum Beispiel analysiert, welchen Einfluss die Platzierung der Geräte auf der Oberfläche des menschlichen Körpers und die Mobilität des Benutzers haben. Es wird nachgewiesen, dass während regelmäßiger Aktivitäten wie Laufen die empfangene Signalstärke stark schwankt, gleichzeitig aber Signalstärke-Spitzen oft einem regulären Muster folgen. Außerdem wird gezeigt, dass in urbanen Umgebungen die Effekte von 2.4 GHz Radio Frequency (RF) Interferenz im Vergleich zu den Auswirkungen von fading (Schwankungen der empfangenen Signalstärke) eher gering sind. Allerdings führt RF Interferenz dazu, dass häufiger Bündelfehler auftreten, d.h. Fehler zeitlich korrelieren. Dies kann insbesondere in Anwendungen, die eine geringe Übertragungslatenz benötigen, problematisch sein.
Der zweite Teil dieser Arbeit beschäftigt sich mit der Analyse von Verfahren, die potentiell die Zuverlässigkeit der Kommunikation in WBANs erhöhen, ohne dass wesentlich mehr Energie verbraucht wird. Zunächst wird der Trade-off zwischen Übertragungslatenz und der Zuverlässigkeit der Kommunikation analysiert. Diese Analyse basiert auf einem neuen Paket-Scheduling Algorithmus, der einen Beschleunigungssensor nutzt, um die WBAN Kommunikation auf die physischen Bewegungen der Person abzustimmen. Die Analyse zeigt, dass unzuverlässige Kommunikationsverbindungen oft zuverlässig werden, wenn Pakete während vorhergesagter Signalstärke-Spitzen gesendet werden. Ferner wird analysiert, inwiefern die Robustheit gegen 2.4 GHz RF Interferenz verbessert werden kann. Dazu werden zwei Verfahren betrachtet: Ein bereits existierendes Verfahren, das periodisch einen Wechsel der Übertragungsfrequenz durchführt (channel hopping) und ein neues Verfahren, das durch RF Interferenz entstandene Bitfehler reparieren kann, indem der Inhalt mehrerer fehlerhafter Pakete kombiniert wird (packet combining). Eine Schlussfolgerung ist, dass Frequenzdiversität zwar das Auftreten von Bündelfehlern reduzieren kann, dass jedoch die statische Auswahl eines Kanals am oberen Ende des 2.4 GHz Bandes häufig schon eine akzeptable Abhilfe gegen RF Interferenz darstellt.There is a growing belief that wearable computers and sensors will enable new applications in areas such as healthcare, personal fitness or augmented reality. The devices are attached to a person and connected through a Wireless Body Area Network (WBAN), which replaces the wires of traditional monitoring systems by wireless communication. This comes, however, at the cost of turning a reliable communication channel into an unreliable one. The wireless channel is typically a rather unstable medium for communication and the conditions under which WBANs have to operate are particularly harsh: not only is the channel strongly influenced by the movements of the person, but WBANs also often operate in unlicensed frequency bands and may therefore be exposed to a significant amount of interference from other wireless devices. Yet, many envisioned WBAN applications require reliable data transmission.
The goals of this thesis are twofold: first, we aim at establishing a better understanding of how the specific WBAN operating conditions, such as node placement on the human body surface and user mobility, impact intra-WBAN communication. We show that during periodic activities like walking the received signal strength on an on-body communication link fluctuates strongly, but signal strength peaks often follow a regular pattern. Furthermore, we find that in comparison to the effects of fading 2.4 GHz Radio Frequency (RF) interference causes relatively little packet loss - however, urban 2.4 GHz RF noise is bursty (correlated in time), which may be problematic for applications with low latency bounds.
The second goal of this thesis is to analyze how communication reliability in WBANs can be improved without sacrificing a significant amount of additional energy. To this end, we first explore the trade-off between communication latency and communication reliability. This analysis is based on a novel packet scheduling algorithm, which makes use of an accelerometer to couple WBAN communication with the movement patterns of the user. The analysis shows that unreliable links can often be made reliable if packets are transmitted at predicted signal strength peaks. In addition, we analyze to what extent two mechanisms can improve robustness against 2.4 GHz RF interference when adopted in a WBAN context: we analyze the benefits of channel hopping, and we examine how the packet retransmission process can be made more efficient by using a novel packet combining algorithm that allows to repair packets corrupted by RF interference. One of the conclusions is that while frequency agility may decrease "burstiness" of errors the static selection of a channel at the upper end of the 2.4 GHz band often already represents a good remedy against RF interference
Comunicações sem-fios de tempo-real para ambientes abertos
Doutoramento em Engenharia InformáticaWireless communication technologies have become widely adopted, appearing
in heterogeneous applications ranging from tracking victims, responders and
equipments in disaster scenarios to machine health monitoring in networked
manufacturing systems. Very often, applications demand a strictly bounded
timing response, which, in distributed systems, is generally highly dependent
on the performance of the underlying communication technology. These
systems are said to have real-time timeliness requirements since data
communication must be conducted within predefined temporal bounds, whose
unfulfillment may compromise the correct behavior of the system and cause
economic losses or endanger human lives.
The potential adoption of wireless technologies for an increasingly broad range
of application scenarios has made the operational requirements more complex
and heterogeneous than before for wired technologies. On par with this trend,
there is an increasing demand for the provision of cost-effective distributed
systems with improved deployment, maintenance and adaptation features.
These systems tend to require operational flexibility, which can only be ensured
if the underlying communication technology provides both time and event
triggered data transmission services while supporting on-line, on-the-fly
parameter modification.
Generally, wireless enabled applications have deployment requirements that
can only be addressed through the use of batteries and/or energy harvesting
mechanisms for power supply. These applications usually have stringent
autonomy requirements and demand a small form factor, which hinders the use
of large batteries. As the communication support may represent a significant
part of the energy requirements of a station, the use of power-hungry
technologies is not adequate. Hence, in such applications, low-range
technologies have been widely adopted. In fact, although low range
technologies provide smaller data rates, they spend just a fraction of the energy
of their higher-power counterparts.
The timeliness requirements of data communications, in general, can be met by
ensuring the availability of the medium for any station initiating a transmission.
In controlled (close) environments this can be guaranteed, as there is a strict
regulation of which stations are installed in the area and for which purpose.
Nevertheless, in open environments, this is hard to control because no a priori
abstract
knowledge is available of which stations and technologies may contend for the
medium at any given instant. Hence, the support of wireless real-time
communications in unmanaged scenarios is a highly challenging task.
Wireless low-power technologies have been the focus of a large research
effort, for example, in the Wireless Sensor Network domain. Although bringing
extended autonomy to battery powered stations, such technologies are known
to be negatively influenced by similar technologies contending for the medium
and, especially, by technologies using higher power transmissions over the
same frequency bands. A frequency band that is becoming increasingly
crowded with competing technologies is the 2.4 GHz Industrial, Scientific and
Medical band, encompassing, for example, Bluetooth and ZigBee, two lowpower
communication standards which are the base of several real-time
protocols. Although these technologies employ mechanisms to improve their
coexistence, they are still vulnerable to transmissions from uncoordinated
stations with similar technologies or to higher power technologies such as Wi-
Fi, which hinders the support of wireless dependable real-time communications
in open environments.
The Wireless Flexible Time-Triggered Protocol (WFTT) is a master/multi-slave
protocol that builds on the flexibility and timeliness provided by the FTT
paradigm and on the deterministic medium capture and maintenance provided
by the bandjacking technique. This dissertation presents the WFTT protocol
and argues that it allows supporting wireless real-time communication services
with high dependability requirements in open environments where multiple
contention-based technologies may dispute the medium access. Besides, it
claims that it is feasible to provide flexible and timely wireless communications
at the same time in open environments. The WFTT protocol was inspired on
the FTT paradigm, from which higher layer services such as, for example,
admission control has been ported. After realizing that bandjacking was an
effective technique to ensure the medium access and maintenance in open
environments crowded with contention-based communication technologies, it
was recognized that the mechanism could be used to devise a wireless
medium access protocol that could bring the features offered by the FTT
paradigm to the wireless domain. The performance of the WFTT protocol is
reported in this dissertation with a description of the implemented devices, the
test-bed and a discussion of the obtained results.As tecnologias de comunicação sem fios tornaram-se amplamente adoptadas,
surgindo em aplicações heterógeneas que vão desde a localização de vítimas,
pessoal médico e equipamentos em cenários de desastre à monitorização da
condição física de máquinas em ambientes industrials. Muito frequentemente,
as aplicações exigem uma resposta limitada no tempo que, geralmente, em
sistemas distribuídos, é substancialmente dependente do desempenho da
tecnologia de comunicação utilizada. Estes sistemas tendem a possuir
requisitos de tempo-real uma vez que a comunicação de dados tem de ser
conduzida dentro de limites temporais pré-definidos que, quando não
cumpridos, podem comprometer o correcto funcionamento do sistema e
resultar em perdas económicas ou colocar em risco vidas humanas.
A potencial adopção de tecnologias sem-fios para um crescente número de
cenários traduz-se num aumento da complexidade e heterogeneidade dos
requisitos operacionais relativamente às tecnologias cabladas. A acompanhar
esta tendência verifica-se uma crescente procura de sistemas distribuídos,
caracterizados quer por uma boa relação custo-eficácia, quer pela simplicidade
de instalação, manutenção e adaptação. Ao mesmo tempo, estes sistemas
tendem a requerer flexibilidade operacional, que apenas pode ser assegurada
se a tecnlogia de comunicação empregue supportar transmissões de dados
dispoletadas quer por eventos (event-triggered), quer por tempo (timetriggered)
e se, ao mesmo tempo, em funcionamento, permitir a alteração dos
parâmetros de comunicação correspondentes.
Frequentemente, as aplicações com comunicações sem fios caracterizam-se
por exigências de instalação que apenas podem ser endereçadas usando
alimentação através de baterias e/ou mecanismos de recolha de energia do
ambiente envolvente. Estas aplicações têm tipicamente requisitos exigentes de
autonomia e de tamanho, impedindo o recurso a baterias de grande dimensão.
Dado que o suporte de comunicações pode representar uma parte significativa
dos requisitos de energia da estação, o uso de tecnologias de comunicação de
elevado consumo não é adequado. Desta forma, nestas aplicações, as
tecnologias de comunicação de curto-alcance tornaram-se amplamente
adoptadas uma vez que, apesar de se caracterizarem por taxas de
transmissão inferiores, consomem apenas uma fracção da energia das
tecnologias de maior alcance.
resumo
Em geral, os requisitos de pontualidade da comunicação de dados podem ser
cumpridos através da garantia da disponibilidade do meio no instante em que
qualquer estação inicie uma transmissão. Em ambientes controlados esta
disponibilidade pode ser garantida, na medida em que existe um controlo de
quais as estações que foram instaladas na área e qual a sua função.
Contrariamente, em ambientes abertos, tal controlo é difícil de garantir uma
vez que não existe conhecimento a priori de que estações ou tecnologias
podem competir pelo meio, tornando o suporte de comunicações de temporeal
um desafio difícil de implementar em cenários com estações de
comunicação não controladas.
As comunicações de baixo consumo têm sido o foco de um esforço de
investigação bastante amplo, por exemplo, no domínio das redes de sensores
sem fios. Embora possam permitir uma maior autonomia a estações baseadas
em baterias, estas tecnologias são reconhecidas como sendo negativamente
influenciadas por tecnologias semelhantes competindo pelo mesmo meio e,
em particular, por tecnologias que utilizem níveis de potência de transmissão
mais elevados em bandas de frequências comuns. De forma cada vez mais
acentuada, a banda industrial, científica e médica (ISM) dos 2.4 GHz tem-se
tornado mais saturada com tecnologias que competem entre si pelo acesso ao
meio tais como, por exemplo, Bluetooth e ZigBee, dois padrões de
comunicação que são a base de vários protocolos de tempo-real. Apesar
destas tecnologias aplicarem mecanismos para melhorar a sua coexistência,
são vulneráveis a transmissões de estações não controladas que usem as
mesmas tecnologias ou que usem tecnologias com níveis de potência de
transmissão mais elevados, impedindo, desta forma, o suporte de
comunicações de tempo-real fiáveis em ambientes abertos.
O protocolo de comunicação sem fios flexível disparado por tempo (WFTT) é
baseado numa arquitectura mestre/múltiplo escravo alavancado na
flexibilidade e pontualidade promovidas pelo paradigma FTT e na captura e
manutenção determinística do meio suportadas pela técnica de bandjacking
(captura de banda). Esta tese apresenta o protocolo WFTT e argumenta que
este permite suportar serviços de comunicação de tempo-real com requisitos
elevados de fiabilidade em ambientes abertos onde várias tecnologias de
comunicação baseadas em contenção disputam o acesso ao meio. Adicionalmente, esta tese reivindica que é possível suportar comunicações
sem-fios simultaneamente flexíveis e pontuais em ambientes abertos. O
protocolo WFTT foi inspirado no paradigma FTT, do qual importa os serviços
de alto nível como, por exemplo, o controlo de admissão. Após a observação
da eficácia da técnica de bandjacking em assegurar o acesso ao meio e a
correspondente manutenção, foi reconhecida a possibilidade de utilização
deste mecanismo para o desenvolvimento de um protocolo de acesso ao meio,
capaz de oferecer as funcionalidades do paradigma FTT em meios de
comunicação sem-fios. O desempenho do protocolo WFTT é reportado nesta
tese com uma descrição dos dispositivos implementados, da bancada de
ensaios desenvolvida e dos resultados obtidos
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