25 research outputs found
FRUGAL & SCALABLE FRAMEWORK FOR ROBUST & INTELLIGENT REMOTE MONITORING IN AN AGING DEMOGRAPHY
Ph.DDOCTOR OF PHILOSOPH
Intelligent home automation security system based on novel logical sensing and behaviour prediction
The thesis, Intelligent Home Automation Security System Based on Novel Logical Sensing and Behavior Prediction, was designed to enhance authentication, authorization and security in smart home devices and services. The work proposes a three prong defensive strategy each of which are analyzed and evaluated separately to drastically improve security. The Device Fingerprinting techniques proposed, not only improves the existing approaches but also identifies the physical device accessing the home cybernetic and mechatronic systems using device specific and browser specific parameters. The Logical Sensing process analyses home inhabitant actions from a logical stand point and develops sophisticated and novel sensing techniques to identify intrusion attempts to a home’s physical and cyber space. Novel Behavior prediction methodology utilizes Bayesian networks to learn normal user behavior which is later compared to distinguish and identify suspicious user behaviors in the home in a timely manner. The logical sensing, behavior prediction and device fingerprinting techniques proposed were successfully tested, evaluated and verified in an actual home cyber physical system. The algorithms and techniques proposed in the thesis can be easily modified and adapted into many practical applications in Industrial Internet of Things, Industry 4.0 and cyber-physical systems.Thesis (PhD)--University of Pretoria, 2017.Electrical, Electronic and Computer EngineeringPhDUnrestricte
Providing lightweight telepresence in mobile communication to enhance collaborative living
Thesis (Ph. D.)--Massachusetts Institute of Technology, School of Architecture and Planning, Program in Media Arts and Sciences, 2004.Includes bibliographical references (p. 117-124).Two decades of computer-supported cooperative work (CSCW) research has addressed how people work in groups and the role technology plays in the workplace. This body of work has resulted in a myriad of deployed technologies with underlying theories and evaluations. It is our hypothesis that similar technologies, and lessons learned from this domain, can also be employed outside the workplace to help people get on with life. The group in this environment is a special set of people with whom we have day-to-day relationships, people who are willing to share intimate personal information. Therefore we call this computer-supported collaborative living. This thesis describes a personal communicator in the form of a watch, intended to provide a link between family members or intimate friends, providing social awareness and helping them infer what is happening in another space and the remote person's availability for communication. The watch enables the wearers to be always connected via awareness cues, text and voice instant message, or synchronous voice connectivity. Sensors worn with the watch track location (via GPS), acceleration, and speech activity; these are classified and conveyed to the other party, where they appear in iconic form on the watch face, providing a lightweight form of telepresence. When a remote person with whom this information is shared examines it, their face appears on the watch of the person being checked on. A number of design criteria defined for collaborative living systems are illustrated through this device.by Natalia Marmasse.Ph.D
Telemedicine
Telemedicine is a rapidly evolving field as new technologies are implemented for example for the development of wireless sensors, quality data transmission. Using the Internet applications such as counseling, clinical consultation support and home care monitoring and management are more and more realized, which improves access to high level medical care in underserved areas. The 23 chapters of this book present manifold examples of telemedicine treating both theoretical and practical foundations and application scenarios
Non-invasive wearable sensing systems for continuous health monitoring and long-term behavior modeling
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, February 2006.Includes bibliographical references (p. 212-228).Deploying new healthcare technologies for proactive health and elder care will become a major priority over the next decade, as medical care systems worldwide become strained by the aging populations. This thesis presents LiveNet, a distributed mobile system based on low-cost commodity hardware that can be deployed for a variety of healthcare applications. LiveNet embodies a flexible infrastructure platform intended for long-term ambulatory health monitoring with real-time data streaming and context classification capabilities. Using LiveNet, we are able to continuously monitor a wide range of physiological signals together with the user's activity and context, to develop a personalized, data-rich health profile of a user over time. Most clinical sensing technologies that exist have focused on accuracy and reliability, at the expense of cost-effectiveness, burden on the patient, and portability. Future proactive health technologies, on the other hand, must be affordable, unobtrusive, and non-invasive if the general population is going to adopt them.(cont.) In this thesis, we focus on the potential of using features derived from minimally invasive physiological and contextual sensors such as motion, speech, heart rate, skin conductance, and temperature/heat flux that can be used in combination with mobile technology to create powerful context-aware systems that are transparent to the user. In many cases, these non-invasive sensing technologies can completely replace more invasive diagnostic sensing for applications in long-term monitoring, behavior and physiology trending, and real-time proactive feedback and alert systems. Non-invasive sensing technologies are particularly important in ambulatory and continuous monitoring applications, where more cumbersome sensing equipment that is typically found in medical and clinical research settings is not usable. The research in this thesis demonstrates that it is possible to use simple non-invasive physiological and contextual sensing using the LiveNet system to accurately classify a variety of physiological conditions. We demonstrate that non-invasive sensing can be correlated to a variety of important physiological and behavioral phenomenon, and thus can serve as substitutes to more invasive and unwieldy forms of medical monitoring devices while still providing a high level of diagnostic power.(cont.) From this foundation, the LiveNet system is deployed in a number of studies to quantify physiological and contextual state. First, a number of classifiers for important health and general contextual cues such as activity state and stress level are developed from basic non-invasive physiological sensing. We then demonstrate that the LiveNet system can be used to develop systems that can classify clinically significant physiological and pathological conditions and that are robust in the presence of noise, motion artifacts, and other adverse conditions found in real-world situations. This is highlighted in a cold exposure and core body temperature study in collaboration with the U.S. Army Research Institute of Environmental Medicine. In this study, we show that it is possible to develop real-time implementations of these classifiers for proactive health monitors that can provide instantaneous feedback relevant in soldier monitoring applications. This thesis also demonstrates that the LiveNet platform can be used for long-term continuous monitoring applications to study physiological trends that vary slowly with time.(cont.) In a clinical study with the Psychiatry Department at the Massachusetts General Hospital, the LiveNet platform is used to continuously monitor clinically depressed patients during their stays on an in-patient ward for treatment. We show that we can accurately correlate physiology and behavior to depression state, as well as to track changes in depression state over time through the course of treatment. This study demonstrates how long-term physiology and behavioral changes can be captured to objectively measure medical treatment and medication efficacy. In another long-term monitoring study, the LiveNet platform is used to collect data on people's everyday behavior as they go through daily life. By collecting long-term behavioral data, we demonstrate the possibility of modeling and predicting high-level behavior using simple physiologic and contextual information derived solely from ambulatory mobile sensing technology.by Michael Sung.Ph.D
Tecnologias IoT para pastoreio e controlo de postura animal
The unwanted and adverse weeds that are constantly growing in vineyards,
force wine producers to repeatedly remove them through the use of mechanical
and chemical methods. These methods include machinery such
as plows and brushcutters, and chemicals as herbicides to remove and
prevent the growth of weeds both in the inter-row and under-vine areas.
Nonetheless, such methods are considered very aggressive for vines, and, in
the second case, harmful for the public health, since chemicals may remain
in the environment and hence contaminate water lines. Moreover, such
processes have to be repeated over the year, making it extremely expensive
and toilsome. Using animals, usually ovines, is an ancient practice used
around the world. Animals, grazing in vineyards, feed from the unwanted
weeds and fertilize the soil, in an inexpensive, ecological and sustainable
way. However, sheep may be dangerous to vines since they tend to feed
on grapes and on the lower branches of the vines, which causes enormous
production losses. To overcome that issue, sheep were traditionally used to
weed vineyards only before the beginning of the growth cycle of grapevines,
thus still requiring the use of mechanical and/or chemical methods during the
remainder of the production cycle.
To mitigate the problems above, a new technological solution was investigated
under the scope of the SheepIT project and developed in the
scope of this thesis. The system monitors sheep during grazing periods on
vineyards and implements a posture control mechanism to instruct them to
feed only from the undesired weeds. This mechanism is based on an IoT
architecture, being designed to be compact and energy efficient, allowing it to
be carried by sheep while attaining an autonomy of weeks.
In this context, the thesis herein sustained states that it is possible to
design an IoT-based system capable of monitoring and conditioning sheep’s
posture, enabling a safe weeding process in vineyards. Moreover, we support
such thesis in three main pillars that match the main contributions of this
work and that are duly explored and validated, namely: the IoT architecture
design and required communications, a posture control mechanism and
the support for a low-cost and low-power localization mechanism. The
system architecture is validated mainly in simulation context while the posture
control mechanism is validated both in simulations and field experiments.
Furthermore, we demonstrate the feasibility of the system and the contribution
of this work towards the first commercial version of the system.O constante crescimento de ervas infestantes obriga os produtores a manter
um processo contínuo de remoção das mesmas com recurso a mecanismos
mecânicos e/ou químicos. Entre os mais populares, destacam-se o uso de
arados e roçadores no primeiro grupo, e o uso de herbicidas no segundo
grupo. No entanto, estes mecanismos são considerados agressivos para as
videiras, assim como no segundo caso perigosos para a saúde pública, visto
que os químicos podem permanecer no ambiente, contaminando frutos e
linhas de água. Adicionalmente, estes processos são caros e exigem mão de
obra que escasseia nos dias de hoje, agravado pela necessidade destes processos
necessitarem de serem repetidos mais do que uma vez ao longo do
ano. O uso de animais, particularmente ovelhas, para controlar o crescimento
de infestantes é uma prática ancestral usada em todo o mundo. As ovelhas,
enquanto pastam, controlam o crescimento das ervas infestantes, ao mesmo
tempo que fertilizam o solo de forma gratuita, ecológica e sustentável. Não
obstante, este método foi sendo abandonado visto que os animais também
se alimentam da rama, rebentos e frutos da videira, provocando naturais
estragos e prejuízos produtivos.
Para mitigar este problema, uma nova solução baseada em tecnologias
de Internet das Coisas é proposta no âmbito do projeto SheepIT, cuja espinha
dorsal foi construída no âmbito desta tese. O sistema monitoriza as ovelhas
enquanto estas pastoreiam nas vinhas, e implementam um mecanismo de
controlo de postura que condiciona o seu comportamento de forma a que se
alimentem apenas das ervas infestantes. O sistema foi incorporado numa
infraestrutura de Internet das Coisas com comunicações sem fios de baixo
consumo para recolha de dados e que permite semanas de autonomia,
mantendo os dispositivos com um tamanho adequado aos animais.
Neste contexto, a tese suportada neste trabalho defende que é possível
projetar uma sistema baseado em tecnologias de Internet das Coisas,
capaz de monitorizar e condicionar a postura de ovelhas, permitindo que
estas pastem em vinhas sem comprometer as videiras e as uvas. A tese
é suportada em três pilares fundamentais que se refletem nos principais
contributos do trabalho, particularmente: a arquitetura do sistema e respetivo
sistema de comunicações; o mecanismo de controlo de postura; e o suporte
para implementação de um sistema de localização de baixo custo e baixo
consumo energético. A arquitetura é validada em contexto de simulação,
e o mecanismo de controlo de postura em contexto de simulação e de
experiências em campo. É também demonstrado o funcionamento do
sistema e o contributo deste trabalho para a conceção da primeira versão
comercial do sistema.Programa Doutoral em Informátic
Context Awareness for Navigation Applications
This thesis examines the topic of context awareness for navigation applications and asks the question, “What are the benefits and constraints of introducing context awareness in navigation?” Context awareness can be defined as a computer’s ability to understand the situation or context in which it is operating. In particular, we are interested in how context awareness can be used to understand the navigation needs of people using mobile computers, such as smartphones, but context awareness can also benefit other types of navigation users, such as maritime navigators. There are countless other potential applications of context awareness, but this thesis focuses on applications related to navigation. For example, if a smartphone-based navigation system can understand when a user is walking, driving a car, or riding a train, then it can adapt its navigation algorithms to improve positioning performance.
We argue that the primary set of tools available for generating context awareness is
machine learning. Machine learning is, in fact, a collection of many different algorithms and techniques for developing “computer systems that automatically improve their performance through experience” [1]. This thesis examines systematically the ability of existing algorithms from machine learning to endow computing systems with context awareness. Specifically, we apply machine learning techniques to tackle three different tasks related to context awareness and having applications in the field of navigation:
(1) to recognize the activity of a smartphone user in an indoor office environment,
(2) to recognize the mode of motion that a smartphone user is undergoing outdoors, and
(3) to determine the optimal path of a ship traveling through ice-covered waters. The
diversity of these tasks was chosen intentionally to demonstrate the breadth of problems encompassed by the topic of context awareness.
During the course of studying context awareness, we adopted two conceptual “frameworks,” which we find useful for the purpose of solidifying the abstract concepts of context and context awareness. The first such framework is based strongly on the writings of a rhetorician from Hellenistic Greece, Hermagoras of Temnos, who defined seven elements of “circumstance”. We adopt these seven elements to describe contextual information. The second framework, which we dub the “context pyramid” describes the processing of raw sensor data into contextual information in terms of six different levels. At the top of the pyramid is “rich context”, where the information is expressed in prose, and the goal for the computer is to mimic the way that a human would describe a situation.
We are still a long way off from computers being able to match a human’s ability to
understand and describe context, but this thesis improves the state-of-the-art in context awareness for navigation applications. For some particular tasks, machine learning has succeeded in outperforming humans, and in the future there are likely to be tasks in navigation where computers outperform humans. One example might be the route optimization task described above. This is an example of a task where many different types of information must be fused in non-obvious ways, and it may be that computer algorithms can find better routes through ice-covered waters than even well-trained human navigators. This thesis provides only preliminary evidence of this possibility, and future work is needed to further develop the techniques outlined here. The same can be said of the other two navigation-related tasks examined in this thesis
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Behaviour recognition and monitoring of the elderly using wearable wireless sensors. Dynamic behaviour modelling and nonlinear classification methods and implementation.
In partnership with iMonSys - an emerging company in the passive care field - a new system, 'Verity', is being developed to fulfil the role of a passive behaviour monitoring and alert detection device, providing an unobtrusive level of care and assessing an individual's changing behaviour and health status whilst still allowing for independence of its elderly user. In this research, a Hidden Markov Model incorporating Fuzzy Logic-based sensor fusion is created for the behaviour detection within Verity, with a method of Fuzzy-Rule induction designed for the system's adaptation to a user during operation. A dimension reduction and classification scheme utilising Curvilinear Distance Analysis is further developed to deal with the recognition task presented by increasingly nonlinear and high dimension sensor readings, and anomaly detection methods situated within the Hidden Markov Model provide possible solutions to identification of health concerns arising from independent living. Real-time implementation is proposed through development of an Instance Based Learning approach in combination with a Bloom Filter, speeding up the classification operation and reducing the storage requirements for the considerable amount of observation data obtained during operation. Finally, evaluation of all algorithms is completed using a simulation of the Verity system with which the behaviour monitoring task is to be achieved
Determining the potential of wearable technologies within the disease landscape of sub-Saharan Africa
Thesis (MEng)--Stellenbosch University, 2019.ENGLISH ABSTRACT: Please refer to full text for abstract.AFRIKAANSE OPSOMMING: Raadpleeg asseblief vol teks vir opsomming