CONTROL AND DATA ACQUISITION OF AC MOTOR WITH ZIGBEE TECHNOLOGY

In this project, a wireless control and monitoring system for an AC motor is realized using the Zigbee communication protocol for safe and economic data communication in industrial fields where the wired communication is either more expensive or impossible due to physical conditions. The induction motor can be started and stopped wireless due to the computer interface developed with Zigbee. It is also possible to protect of the motor against some faults such as over current, higher/lower voltage, over temperature in windings, overloading of motor. Moreover, a database is built to execute online measurements and to save the motor parameters received by radio frequency (RF) data acquisition system. Therefore, controlling, monitoring, and protection of the system are realized in real time. Since the wireless communication technology is used in this study, controlling abilities of the system are increased and also hardware and the necessities of other similar equipment for data communication are minimized. Wireless sensor networks have been very popular research field for the couple of years. ZigBee is a newly developed technology now being deployed for wireless sensor networks. ZigBee is a low data rate wireless network standard defined by the ZigBee Alliance and based on IEEE 802.15.4. The ZigBee wireless network has some advantages compared with other wireless networks, it has the characteristics of low power, low price, highly secured and reliable, so implementing a remote control and monitoring system proves to have a good cost performance ratio. This project presents the implementation of wireless sensor actor network (point to point) to control the speed of a AC Motor from a remote location. Varying speed of AC motor by means of changing firing angle of any thyristor is very widely used method. A zero crossing detector circuit is used here to interrupt ATMEGA AVR16 after every 10 ms. After getting an interrupt ATMEGA AVR16 will fire TRIAC after some delay from 1 to 9 ms. This will cut the current supplied to motor and so the speed of motor will reduce. Thus by varying the delay after which the TRIAC is triggered one can change the speed of motor. The speed sensing could be done by sensing and providing feedback with help of Tachogenerator .This paper also provides a provision for sensing the temperature, which is a crucial parameter of the motor, by using the facility of Thermister Sensing technology

The myExperiment Open Repository for Scientific Workflows

4th International Conference on Open RepositoriesThis presentation was part of the session : Conference PresentationsDate: 2009-05-19 10:00 AM – 11:30 AMmyExperiment is an open repository solution for the born-digital items arising in contemporary research practice, in particular scientific workflows and experiment plans. Launched in November 2007, the public repository (myexperiment.org) has established a significant collection of scientific workflows, spanning multiple disciplines and multiple workflow systems, which has been accessed by over 16,000 users worldwide. Built according to Web 2.0 design principles, myExperiment demonstrates the success of blending modern social curation methods with the demands of researchers sharing hard-won intellectual assets and research works within a scholarly communication lifecycle. myExperiment is an important component in the revolution in creating, sharing and publishing scientific results, and has already established itself as a valuable and unique repository with a growing international presence.JISC; EPSRC; Microsoft Corporatio

The Evolution of myExperiment

The myExperiment social website for sharing scientific workflows, designed according to Web 2.0 principles, has grown to be the largest public repository of its kind. It is distinctive for its focus on sharing methods, its researcher-centric design and its facility to aggregate content into sharable 'research objects'. This evolution of myExperiment has occurred hand in hand with its users. myExperiment now supports Linked Data as a step toward our vision of the future research environment, which we categorise here as '3rd generation e-Research'

myExperiment: a repository and social network for the sharing of bioinformatics workflows

myExperiment (http://www.myexperiment.org) is an online research environment that supports the social sharing of bioinformatics workflows. These workflows are procedures consisting of a series of computational tasks using web services, which may be performed on data from its retrieval, integration and analysis, to the visualization of the results. As a public repository of workflows, myExperiment allows anybody to discover those that are relevant to their research, which can then be reused and repurposed to their specific requirements. Conversely, developers can submit their workflows to myExperiment and enable them to be shared in a secure manner. Since its release in 2007, myExperiment currently has over 3500 registered users and contains more than 1000 workflows. The social aspect to the sharing of these workflows is facilitated by registered users forming virtual communities bound together by a common interest or research project. Contributors of workflows can build their reputation within these communities by receiving feedback and credit from individuals who reuse their work. Further documentation about myExperiment including its REST web service is available from http://wiki.myexperiment.org. Feedback and requests for support can be sent to [email protected]

Accelerating Time to Experiment – the myExperiment approach to Open Science

myExperiment has set out to provide the social software and services to support the scientific process, focusing on the ‘time to experiment’ phase of the scholarly knowledge cycle rather than the data deluge from new experimental techniques. In the context of open science this phase is also experiencing a deluge of scientific objects – not just data but protocols, methods and the new artefacts of digital science such as workflows, provenance records and ontologies. myExperiment has already demonstrated the role of a social web site in addressing this challenge, with significant usage in the first few months of the service. In this paper we consider the second way in which myExperiment undertakes to reduce time-to-experiment – by integrating with the everyday work practices of scientists

Discovering Scientific Workflows: The myExperiment Benchmarks

Automation in science is increasingly marked by the use of workflow technology. The sharing of workflows through publication mechanisms or repositories supports the verifiability, reproducibility and extensibility of computational experiments. However, the subsequent discovery of workflows remains a challenge, both from a technological and sociological viewpoint. We investigate current practices in workflow sharing, re-use and discovery amongst life scientists chiefly using the Taverna workflow management system. The study draws on two key sources: (i) a survey of researchers drawn from 19 research labs and (ii) an analysis of scientists’ behaviour on the myExperiment social network site, designed to encourage workflow exchange. The results reveal a multi-modal approach to workflow discovery, based on a mix of search on the content of the workflow and its situated context. We go on to develop a benchmark specifically for the evaluation of workflow discovery and to demonstrate it on two example approaches

myExperiment: a repository and social network for the sharing of bioinformatics workflows

myExperiment (http://www.myexperiment.org) is an online research environment that supports the social sharing of bioinformatics workflows. These workflows are procedures consisting of a series of computational tasks using web services performed on data from its retrieval, integration and analysis, to the visualisation of the results. As a public repository of workflows, myExperiment allows anybody to discover those that are relevant to their research which can then be reused and repurposed to their specific requirements. Conversely, developers can submit their workflows to myExperiment and enable them to be shared in a secure manner. Since its release in 2007, myExperiment currently has over 3500 registered users and contains more than 900 workflows. The social aspect to the sharing of these workflows is facilitated by registered users forming virtual communities bound together by a common interest or research project. Contributors of workflows can build their reputation within these communities by receiving feedback and credit from individuals who reuse their work. Further documentation about myExperiment including its REST web service is available from http://wiki.myexperiment.org. Feedback and requests for support can be sent to [email protected]

The myExperiment Open Repository for Scientific Workflows

myExperiment is an open repository solution for the born-digital items arising in contemporary research practice, in particular scientific workflows and experiment plans. Launched in November 2007, the public repository (myexperiment.org) has established a significant collection of scientific workflows, spanning multiple disciplines and multiple workflow systems, which has been accessed by over 16,000 users worldwide. Built according to Web 2.0 design principles, myExperiment demonstrates the success of blending modern social curation methods with the demands of researchers sharing hard-won intellectual assets and research works within a scholarly communication lifecycle. myExperiment is an important component in the revolution in creating, sharing and publishing scientific results, and has already established itself as a valuable and unique repository with a growing international presence