1,640 research outputs found
An energy-efficient and scalable slot-based privacy homomorphic encryption scheme for WSN-integrated networks
YesWith the advent of Wireless Sensor Networks (WSN) and its immense popularity in a wide range of applications, security has been a major concern for these resource-constraint systems. Alongside security, WSNs are currently being integrated with existing technologies such as the Internet, satellite, Wi-Max, Wi-Fi, etc. in order to transmit data over long distances and hand-over network load to more powerful devices. With the focus currently being on the integration of WSNs with existing technologies, security becomes a major concern. The main security requirement for WSN-integrated networks is providing end-to-end security along with the implementation of in-processing techniques of data aggregation. This can be achieved with the implementation of Homomorphic encryption schemes which prove to be computationally inexpensive since they have considerable overheads. This paper addresses the ID-issue of the commonly used Castelluccia Mykletun Tsudik (CMT) [12] homomorphic scheme by proposing an ID slotting mechanism which carries information pertaining to the security keys responsible for the encryption of individual sensor data. The proposed scheme proves to be 93.5% lighter in terms of induced overheads and 11.86% more energy efficient along with providing efficient WSN scalability compared to the existing scheme. The paper provides analytical results comparing the proposed scheme with the existing scheme thus justifying that the modification to the existing scheme can prove highly efficient for resource-constrained WSNs
REISCH: incorporating lightweight and reliable algorithms into healthcare applications of WSNs
Healthcare institutions require advanced technology to collect patients' data accurately and continuously. The tradition technologies still suffer from two problems: performance and security efficiency. The existing research has serious drawbacks when using public-key mechanisms such as digital signature algorithms. In this paper, we propose Reliable and Efficient Integrity Scheme for Data Collection in HWSN (REISCH) to alleviate these problems by using secure and lightweight signature algorithms. The results of the performance analysis indicate that our scheme provides high efficiency in data integration between sensors and server (saves more than 24% of alive sensors compared to traditional algorithms). Additionally, we use Automated Validation of Internet Security Protocols and Applications (AVISPA) to validate the security procedures in our scheme. Security analysis results confirm that REISCH is safe against some well-known attacks
EMMON - EMbedded MONitoring
Despite the steady increase in experimental deployments, most of research work on WSNs has focused only on
communication protocols and algorithms, with a clear lack of effective, feasible and usable system architectures,
integrated in a modular platform able to address both functional and non–functional requirements. In this paper, we
outline EMMON [1], a full WSN-based system architecture for large–scale, dense and real–time embedded monitoring
[3] applications. EMMON provides a hierarchical communication architecture together with integrated middleware and
command and control software. Then, EM-Set, the EMMON engineering toolset will be presented. EM-Set includes a
network deployment planning, worst–case analysis and dimensioning, protocol simulation and automatic remote
programming and hardware testing tools. This toolset was crucial for the development of EMMON which was designed
to use standard commercially available technologies, while maintaining as much flexibility as possible to meet specific
applications requirements. Finally, the EMMON architecture has been validated through extensive simulation and
experimental evaluation, including a 300+ nodes testbed
Arm Mbed – AWS IoT System Integration [Open access]
This project explores the different Internet of Things (IoT) architectures and the available platforms
to define a general IoT Architecture to connect Arm microcontrollers to Amazon Web Services. In
order to accommodate the wide range of IoT applications, the architecture was defined with different
routes that an Arm microcontroller can take to reach AWS. Once this Architecture was defined, a
performance analysis on the different routes was performed in terms of communication speed and
bandwidth. Finally, a Smart Home use case scenario is implemented to show the basic functionalities
of an IoT system such as sending data to the device and data storage in the Cloud. Furthermore, a
Cloud ML algorithm is triggered in real time by the Smart Home to receive a prediction of the current
Comfort Level in the room
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GOVERNMENT AID PORTAL
In today’s world, contacting government officials seems a big task when it comes to reporting small concerns. There are many authorities and officials which makes it very difficult for ordinary people to figure out who they should contact to resolve their daily issues. To address this problem, I have developed an application which can act as intermediary between citizens and government authorities. This portal will enable locals to submit complaints regarding personal or general issues through a complaint form, which will then be routed to the appropriate government department. Once a complaint is filed, government teams are immediately alerted and can use the program to gain more insight into the issue. Furthermore, the app will notify the complainant about the status of their request, providing updates on whether the problem has been resolved. The app also includes a feature that allows users to provide detailed information about a problem by selecting a specific problem category, location, and uploading relevant photos. This will give government officials a better understanding of the issue and allow them to take immediate action. To build this portal, I leverage Amazon web service such as Amazon Lambda, Amazon S3, Amazon DynamoDB, Elastic Beanstalk, AWS Lambda, AWS Cognito, API Gateways, and Secret Manager. Furthermore, this application will contain all the mentioned features along with user-friendly interface to provide more convenient experience. The application will be available for use as a software and hence, the delivery model will be Software as a Service (SaaS). The users will use the services directly, and they will not require access to the infrastructure components or the platform on which the application will be built
Design and implementation of application-specific medium access control protocol for scalable smart home embedded systems
Thesis (M.S.) University of Alaska Fairbanks, 2016By incorporating electrical devices, appliances and house features in a system that is controlled and monitored either remotely or on-site, smart home technologies have recently gained an increasing popularity. There are several smart home systems already available, ranging from simple on-site home monitoring to self-learning and Wi-Fi enabled systems. However, current systems do not fully make use of recent technological advancement and synergy among a variable number of sensors for improved data collection. For a synergistic system to be provident it needs to be modular and scalable to match exact user needs (type of applications and adequate number of sensors for each application). With an increased number of sensors intelligently placed to optimize the data collection, a wireless network is indispensable for a flexible and inexpensive installation. Such a network requires an efficient medium access control protocol to sustain a reliable system, provide flexibility in design and to achieve lower power consumption. This thesis brings to light practical ways to improve current smart home systems. As the main contribution of this work, we introduce a novel application-specific medium access control protocol able to support suggested improvements. In addition, a smart home prototype system is implemented to evaluate the protocol performance and prove concepts of recommended advances. This thesis covers the design of the proposed novel medium access protocol and the software/hardware implementation of the prototype system focusing on the monitoring and data analysis side, while providing inputs for the control side of the system. The smart home system prototype is Wi-Fi and Web connected, designed and implemented to emphasize system usability and energy efficiency
An IoT-oriented fast prototyping platform for BLE-based star topology networks
The Internet of Things (IoT) is characterized by many technologies, standards, tools and devices for a wide range of application fields and often, for the end-users (makers and developers), is hard to orientate in an equally wide range of offers from various manufacturers. In recent years, the Bluetooth Low Energy (BLE) communication protocol is achieving a large portion of the market, thanks to its low-power and low-cost orientation and its pervasiveness in mobile devices, like smartphones. For these reasons, BLE is increasingly used in IoT-oriented Wireless Personal Area Networks (WPAN), where a small set of devices arranged in star topology network and connected to a smartphone and a Wi-Fi gateway, can cover a large number of monitoring and controlling use case scenarios. This work presents the ST’s STM32 Open Development Environment (ODE), a complete suite of hardware and software tools representing a reference point for end-users willing to create BLE-based star topology networks for a wide range of applications. Through a simple use case in a smart home context, it is shown how all provided tools can be used to fast prototype applications addressing all user requirements
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