Multi-Hop Wireless Sensor Network for Continuous Oxygen Tank’s Level Detection

Wireless sensor network technology is considered as one of the modern technologies that are used in a lot of areas to measure physical, chemical or environmental variables because of their low of cost and high efficiency in data transmission. This project aims to design a wireless sensor network that will be used to measure pressure or level of Oxygen gas inside the Oxygen tanks that are found in different places in hospitals in order to overcome the problem of the manual checking of tanks level, which may cause a lot of problems because of the lack of accuracy measurement and the absence of a continuous monitoring from the control room. The designing of this project will be based on the concept of multi-hop wireless sensor network using XBee modules. XCTU software will be used to update and configure XBee modules and PROCESSING software will be used to develop a program that reads data from XBee and show it in interactive way on the screen

Detection and Localization of Wireless Jammer using XBee module

Now days, wireless technologies has becomes more popular and affordable. In every field e.g. government sector, education, business, military, medical etc. use of wireless network have been increased which enables broad class of new applications. These applications make work easier and faster but one threat which is harmful i.e. jamming attack. The wireless jammer continually emits a radio signal along the same frequency that the wireless nodes use. Jamming technology generally does not discriminate between desirable and undesirable communication. A jammer can block all radio communication on any device that operates on radio frequencies within its range which create nuisance in our critical communication services. Most reliable solution to avoid nuisance is detection and localization of wireless jammer which helps to take further security actions. This project aims to detect wireless jammer and find the location of wireless jammer by experimental setup. DOI: 10.17762/ijritcc2321-8169.15017

Automatic monitoring and control of museums’ environment based on Wireless Sensor Networks

In museums, it is critical to properly conserve the existing artwork. For this purpose, it is fundamental to continuously monitor its environment, either in storage or exhibition rooms. Contrarily to traditional measuring equipments and procedures used in museums, the deployment of a Wireless Sensor Network (WSN) can help to implement these measurements continuously, in a real-time basis, and in a much easier and cheaper way. This is the main objective of the WISE-MUSE project, which proposes the use of WSNs for museums’ environmental and structural monitoring, and automatic environmental control. In this paper, the implementation and the main results of the WISE-MUSE project, which was carried out in a contemporary art museum, are described. Among other important contributions that will also be described in this paper, the development of a new wireless sensor node and a Web-based visualization tool, which bring some considerable advantages when compared with other commercially available solutions, are emphasized.info:eu-repo/semantics/publishedVersio

An integrating platform for environmental monitoring in museums based on wireless sensor networks

Monitoring the museum’s environment for preventive conservation of art purposes is one major concern to all museums. In order to properly conserve the artwork it is critical to continuously measure some parameters, such as temperature, relative humidity, light and, also, pollutants, either in storage or exhibition rooms. The deployment of a Wireless Sensor Network in a museum can help implementing these measurements in real-time, continuously, and in a much easier and cheap way. In this paper, we present the first testbed deployed in an Contemporary Art Museum, located in Madeira Island, Portugal, and the preliminary results of these experiments. On the other hand, we propose a new wireless sensor node that offers some advantages when compared with several commercially available solutions. Furthermore, we present a system that automatically controls the dehumidifying devices, maintaining the humidity at more constant levels.info:eu-repo/semantics/publishedVersio

Design and Implementation of Wireless Modules for Farm Monitoring

Since the last quarter of the 20th century, technological advancement in the industry has grown exponentially, likewise the agricultural sector. The extent is as far as the use of drones and automated robots on farms. Today wireless automation has become very popular in homes and industries alike since they are considered more efficient, safe and financially viable. Microcontroller applications in the area of wireless automation is very advanced considering the cheap cost compared to PLCs and the general cheap cost of electronic components has driven more funds into researching and further industrializing microcontroller technology. The aim of this Master's Thesis "Design and Implementation of Wireless Modules for Farm Monitoring" was to plan, design, construct and implement wireless modules to be used to automate, control and monitor a farm. The modules consists of two nodes, each equipped with RF modules to enable communication between the nodes wirelessly. One of the nodes is also connected to a computer (the raspberry pi), enabling access to the modules remotely via internet. This Master's Thesis describes the software and hardware tasks necessary for the total operation of the modules such as the control of IOs, communication between the wireless nodes and the control of the nodes via internet. Range measurement results and throughput measurements were also discussed.fi=Opinnäytetyö kokotekstinä PDF-muodossa.|en=Thesis fulltext in PDF format.|sv=Lärdomsprov tillgängligt som fulltext i PDF-format

Smart Environment Monitoring System Using Wired and Wireless Network: A Comparative Study

This chapter focuses on the implementation of a smart environment monitoring system using wired and wireless sensor networks (WSN). The goal was to develop a LabVIEW based system to monitor environmental parameters that provide inaccessible, real-time monitoring. The development of portable and efficient environment monitoring system based on LabVIEW GUI that monitors various environmental parameters such as temperature, relative humidity, Air quality and light intensity was developed. This chapter targets on both wired and wireless approach for environment monitoring. The limitations of wired network were explained by flourishing the portable system. For proceedings with the impediment and insufficiency of wired network, Arduino augmentation ascendancy, are mingled with XBee wireless sensor network. The data from the environment was sent to the sink node wirelessly through mote. Monitoring of the data was done in a personal computer (PC) through a graphical user interface made by LabVIEW. The pertinent sensor for each was connected to analog input of Arduino UNO and their values are displayed on front panel of LabVIEW. LabVIEW run time engine makes the system cost effective and facile. To reveal the effectiveness of the system, some measurement results are also predicted in this chapter

Intelligent and portable seat belt reminder for vehicle

This project describes the design an intelligent and portable Seat Belt Reminder (SBR) for vehicle, which integrated with Peripheral Interface Controller (PIC) and use a Bluetooth technology in order to send data to user. The Bluetooth technology is one of the wireless technology that capable to transmit and receive data over the short range. In order to make sure intelligent seat belt reminder work as expected, all sensor should be measured and tested before implemented. The combination of microcontroller, Bluetooth technology, Android platform and sensors in seat belt reminder system will reduced the occupant’s risk from being injure during crash when accident happen. A fully functioning embedded SBR prototype device has successfully developed which can alert the occupants of any vehicle if seat belts are not worn. By applying new concept of wireless technology and smart mobile device in the implemented system, we can reduce the risk of fatality