Global ETD Search

1	Remote Surveillance and Measurement Rashid, Muhammad, Mutarraf, Mumtaz January 2008 (has links) <p>Wireless Sensor Network (WSN), a collection of “sensor nodes” promises to change the scientist’s approach of gathering the environmental data in various fields. Sensor nodes can be used for non-stop sensing, event detection, location sensing and local control of actuators, this concept gives surety to many latest application areas like agriculture, military, home or factory automation, logistics and so on. Remote surveillance and measurement missions can be performed by using WSNs. The hot research topic now-a-days is to make such networks remotely controllable and adaptive to the environment and mission.</p><p> </p><p>The work carried out in this thesis is the development of a surveillance application using TinyOS/nesC. The purpose of this application is to perform event-detection mission by using any one of the built-in sensor on Mica2 motes as well as a setup protocol is designed to make the WSN remotely controllable and adaptive to the mission. In this thesis, an experimental work is also performed using TinyDB to build up a surveillance system whose purpose is to detect and count the total number of person present at any time in a given room and to view the results at a remote place. Besides these two system applications, a comparative study between TinyDB and nesC is described which concludes that more hardware control can be achieved through nesC which is a more power efficient platform for long-term applications.</p> Wireless Sensor Network Adaptiveness Surveillance nesC/TinyOS
2	Remote Surveillance and Measurement Rashid, Muhammad, Mutarraf, Mumtaz January 2008 (has links) Wireless Sensor Network (WSN), a collection of “sensor nodes” promises to change the scientist’s approach of gathering the environmental data in various fields. Sensor nodes can be used for non-stop sensing, event detection, location sensing and local control of actuators, this concept gives surety to many latest application areas like agriculture, military, home or factory automation, logistics and so on. Remote surveillance and measurement missions can be performed by using WSNs. The hot research topic now-a-days is to make such networks remotely controllable and adaptive to the environment and mission. The work carried out in this thesis is the development of a surveillance application using TinyOS/nesC. The purpose of this application is to perform event-detection mission by using any one of the built-in sensor on Mica2 motes as well as a setup protocol is designed to make the WSN remotely controllable and adaptive to the mission. In this thesis, an experimental work is also performed using TinyDB to build up a surveillance system whose purpose is to detect and count the total number of person present at any time in a given room and to view the results at a remote place. Besides these two system applications, a comparative study between TinyDB and nesC is described which concludes that more hardware control can be achieved through nesC which is a more power efficient platform for long-term applications. Wireless Sensor Network Adaptiveness Surveillance nesC/TinyOS
3	Implementation of Secure Key Management Techniques in Wireless Sensor Networks Ottallah, Noor 16 May 2008 (has links) Creating a secure wireless sensor network involves authenticating and encrypting messages that are sent throughout the network. The communicating nodes must agree on secret keys in order to be able to encrypt packets. Sensor networks do not have many resources and so, achieving such key agreements is a difficult matter. Many key agreement schemes like Diffie-Hellman and public-key based schemes are not suitable for wireless sensor networks. Pre-distribution of secret keys for all pairs of nodes is not viable due to the large amount of memory used when the network size is large. We propose a novel key management system that works with the random key pre-distribution scheme where deployment knowledge is unknown. We show that our system saves users from spending substantial resources when deploying networks. We also test the new systemâ€™s memory usage, and security issues. The system and its performance evaluation are presented in this thesis. Wireless sensor networks TinyDB node secure key TinyOS NesC
4	Open Secure Office Project : Wireless Sensor Network Andersson, Rikard, Sandberg, Martin, Urszuly, László January 2005 (has links) <p>In recent years, the development of wireless sensor networks has made a great progress. Early projects focused on replacement of existing systems equipped with wires. These systems started out as simple static data collection networks with one smart central node that could decide further actions based on the content of the collected data. Through time, the intelligence has become more decentralized, which means the nodes now can cooperate in a more efficient and dynamic manner. The task given is to evaluate TinyOS and NesC on specific hardware from Crossbow Technology Inc, applied on an application called the Open Secure Office Project. This application is designed to enhance the security without negative effects on comfort in a frequently visited open-plan office. Finally, a real world system demonstration should be performed. We propose a solution where there is no urgent need to cover the entire office area with radio signals to maintain a secure sensor system. This is true as long as all entries and exits to the office area are “guarded” by some base station which has as main task to keep track of people and equipment entering or leaving the office. Small scale tests have been performed which show that it is possible to easily develop and maintain a wireless sensor network security system, that could be coordinated by alternative systems.</p> Wireless sensor network Open secure office TinyOS NesC
5	Range Based Indoor Localization in Wireless Sensor Networks with Telos Pehrson Skidén, Petter January 2013 (has links) Localization of individual nodes in a wireless network is useful in many applications, e.g for tracking patients in hospitals. Using the Received Signal Strength Indicator, RSSI, for this purpose has been explored in numerous studies. It is energy efficient and rarely requires customised hardware of configuration. The possibility to use pre-configured, off-the-shelf products is especially important in large scale sensor network deployments. Using RSSI has, however, many drawbacks, since the radio signal is heavily affected by the surrounding envi- ronment. Most studies in this area discuss the impact of multipath effects. Our study on range based distance estimations, using the Telos hardware, shows that individual profiling requirements and antenna quality are equally challenging. Still, RSSI based indoor localization systems remains an active field of research. A multitude of approaches and algorithms have been proposed to gain accuracy in position estimations. The most common of these techniques are explored in this report. Based on previous work at The Polytechnic University of Catalonia, the Telos hardware has been integrated successfully with existing software to form local wireless sensor networks for indoor localization. We present applications developed on top of TinyOS, an operating system for embedded systems. These applications serve as a platform for related future work at The Polytechnic University of Catalonia and elsewhere. Indoor Localization RSSI WSN Telos TinyOS nesC Trilateration
6	Open Secure Office Project : Wireless Sensor Network Andersson, Rikard, Sandberg, Martin, Urszuly, László January 2005 (has links) In recent years, the development of wireless sensor networks has made a great progress. Early projects focused on replacement of existing systems equipped with wires. These systems started out as simple static data collection networks with one smart central node that could decide further actions based on the content of the collected data. Through time, the intelligence has become more decentralized, which means the nodes now can cooperate in a more efficient and dynamic manner. The task given is to evaluate TinyOS and NesC on specific hardware from Crossbow Technology Inc, applied on an application called the Open Secure Office Project. This application is designed to enhance the security without negative effects on comfort in a frequently visited open-plan office. Finally, a real world system demonstration should be performed. We propose a solution where there is no urgent need to cover the entire office area with radio signals to maintain a secure sensor system. This is true as long as all entries and exits to the office area are “guarded” by some base station which has as main task to keep track of people and equipment entering or leaving the office. Small scale tests have been performed which show that it is possible to easily develop and maintain a wireless sensor network security system, that could be coordinated by alternative systems. Wireless sensor network Open secure office TinyOS NesC
7	Dynamic Bug Detection in TinyOS Operating Environments Wei, Pihui 26 June 2009 (has links) No description available. Computer Science Sensor network Bug detection Dynamic analysis TinyOS NesC
8	Geração automática de código para redes de sensores sem fio baseado em componentes de software Santos, Alyson de Jesus dos 09 September 2011 (has links) Made available in DSpace on 2015-04-22T22:00:54Z (GMT). No. of bitstreams: 1 Dissertacao_Alyson.pdf: 2045006 bytes, checksum: 552fa4e2c7d4a7aa118296a3b4324aa2 (MD5) Previous issue date: 2011-09-09 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / The Wireless Sensor Networks (WSNs) revolutionize the monitoring of environment, enabling the creation of applications and scenarios in various areas of knowledge. As a consequence, we have a very fast growth of the development of new applications and rata increase of system complexity and cost of proposed development. The difficulty in developing new applications is not only due to restrictive features (memory, processor, power), but also by the instructions of low-level programming these networks. This situation is conductive to the creation of new methodologies and tools that support the development of system for that plataform. This work proposes the development of a tool called automatic code generation for wireless sensor network (WSN-GAC), which has as its main objective to enable any product high in developing applications for WSNs using models specified in Model driven architecture (MDA). WSN-GAC receives as input a model of a component-based application created by the designer and then performs automatic code generation of nesC (network embedded system C). Three case studied demonstrate the potential of WSN-GAC to help developers of applications for these networks. / As Redes de Sensores Sem Fio (RSSFs) revolucionam a monitoração de ambientes, possibilitando a criação de aplicações e cenários nas mais diversas áreas do conhecimento. Como consequência, temos o crescimento muito rápido do desenvolvimento de novas aplicações e proporcionalmente aumento de complexidade dos sistemas propostos e do custo de desenvolvimento. A dificuldade no desenvolvimento de novas aplicações não se deve somente às características restritivas (memória, processamento, energia), mas também pelas instruções de programação de baixo nível destas redes. Este panorama é favorável a criação de novas metodologias e ferramentas que dêem suporte ao desenvolvimento de sistemas para tal plataforma. Este trabalho propõe o desenvolvimento de uma ferramenta intitulada Geração Automática de Código para Redes de Sensores Sem Fio (GAC-RSSFs), que tem como objetivo principal possibilitar a alta produtividade no desenvolvimento de aplicações para as RSSFs utilizando modelos especificados na Arquitetura Orientada a Modelos (Model Driven Architecture - MDA). GAC-RSSFs recebe como entrada um modelo baseado em componentes de uma aplicação criada pelo projetista e então realiza a geração automática de código em linguagem nesC (network embedded systems C). Três estudos de caso demonstram o potencial de GAC-RSSFs para ajudar os desenvolvedores de aplicações para essas redes. RSSFs MDA NesC Arquitetura Orientada a Modelos WSNs MDA NesC ENGENHARIAS: ENGENHARIA ELÉTRICA
9	Graphical product-line configuration of nesC-based sensor network applications using feature models Niederhausen, Matthias January 1900 (has links) Master of Science / Department of Computing and Information Sciences / John M. Hatcliff / Developing a wireless sensor network application includes a variety of tasks, such as coding of the implementation, designing the architecture and assessing availability of hardware components, that provide necessary capabilities. Before compiling an application, the developer has to configure the selection of hardware components and set up required parameters. One has to choose from among a variety of configurations regarding communication parameters, such as frequency, channel, subnet identifier, transmission power, etc.. This configuration step also includes setting up parameters for the selection of hardware components, such as a specific hardware platform, which sensor boards and programmer boards to be used or the use of optional services and more. Reasoning about a proper selection of configuration parameters is often very difficult, since there are a lot of dependencies among these parameters which may rule out some other options. The developer has to know about all these constraints in order to pick a valid configuration. Unfortunately, the existing makefile approach that comes with nesC is poorly organized and does not capture important compatibility constraints. The configuration of a particular nesC application is distributed in multiple makefiles. Therefore a developer has to look at multiple files to make sure all necessary parameter are set up correctly for compiling a specific application. Furthermore without analyzing all makefiles it is unclear what the total configurability of a nesC application is and what options and parameters are provided (e.g. is there a parameter for enabling secure communication). In addition to this, the makefile approach tends to be error-prone, since the developer has to type in variable names and values manually, that match the existing implementation. However, the existing configuration system does not capture important compatibility constraints, such as capabilities of selected hardware components. This thesis proposes the use of feature models to configure nesC-based sensor network applications. We provide a tool-supported framework to model valid configurations and a generator that translates this model into a makefile compatible with existing nesC infrastructure. The framework automatically rules out selection of incompatible features using a build-in constraint language. Since all variables are defined in the model, misspellings of variable names are reduced and their domains are clearly defined because most variables come with all its possible options. A developer just needs to choose one or more of them by enabling certain features, where the problem of cardinality is also handled by the model. We show a detailed analysis of nesC's variability domain and how to use feature models to cover the exact behavior of nesC's makefile approach. In a following chapter we simplify our feature model and include the selection of specific hardware components, its capabilities and its dependencies. The feature model and the makefile generator offer a convenient way to configure nesC applications, that is faster, easier to understand and to handle, more transparent and once implemented it gives the possibility to adopt this configuration tool to an existing development environment. Feature model Sensor network nesC Makefile Computer Science (0984) Information Science (0723)
10	Supporting Data-Intensive Wireless Sensor Applications using Smart Data Fragmentation and Buffer Management Masilela, Mbonisi 01 January 2007 (has links) Recent advances in low power device technology have led to the development of smaller powerful sensors geared for use in Wireless Sensor Networks. Some of these sensors are capable of producing large data packets in a single reading. This becomes a challenging problem given the constraints imposed by current MAC and Transport Layer implementations since a single data packet can exceed the MTU of the protocol stack. Little has been done in the way of addressing this issue in Wireless Sensor Networks. This paper proposes a novel solution to this issue. Proposed is a Lightweight Data Transportation Protocol that uses smart data fragmentation and efficient pipelined transmission and buffer management schemes to solve this problem. The methodology outlined in this paper ensures that data is successfully transmitted from source to destination with minimal delay or packet loss. wireless sensor programming data transmission NesC Java protocol structure internet Computer Sciences Physical Sciences and Mathematics

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