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Kandasamy, V.
- A Energy Efficient Routing Method for Under Water Aural Sensor Network
Authors
1 Department of Computer Science and Engineering, Kalaivani College of Technology, Coimbatore, Tamil Nadu, IN
2 Department of Information Technology, Loyola Institute of Technology, Chennai-600123, IN
3 Department of Electronics Communication Engineering, Kalaivani College of Technology, Coimbatore, Tamil Nadu, IN
Source
Networking and Communication Engineering, Vol 5, No 5 (2013), Pagination: 268-270Abstract
Underwater Aural Networks (UAN’s) are very unique and can be organized for commercial and military applications. Underwater Networks consists of an erratic number of sensors and vehicles that are organized to perform collaborative monitoring tasks over a given area. One of the main issues in wireless sensor network is developing an energy-efficient routing protocol. Since the sensor nodes have limited available power, energy preservation is a critical issue in under water sensor network for nodes and network life. Most of the existing routing protocols for sensor networks don’t turn off the radio frequency completely. They speed up the energy consumption. Acoustic signal is the only feasible tool that works in under water environment. They extract signals in the presence of noise and uncertainty. In this work, we propose a MECH (Maximum Energy Cluster Head) routing protocol. It has self-configuration and hierarchical tree routing properties. A contaminated Gaussian (CG) noise model is proposed to characterize the impulsive, non-Gaussian nature of acoustic background noise observed in some real-world WSNs.Keywords
Underwater Acoustic Networks, Maximum Energy Cluster Head.- Real Time E-Metering and Automation of KCT College Campus using an Android Mobile App and LAMP Technology
Authors
1 Department of EEE, Kumaraguru College of Technology, Coimbatore-49, IN
Source
International Journal of Advanced Networking and Applications, Vol 8, No 5 (2017), Pagination: 3220-3223Abstract
Automation is the technology stemming from web of things. To make a smart world to provide comfort for human life is the main focus of the researchers. In the current automated industry Embedded systems and IOT (Internet of Things) is becoming highly efficient and mandatory to exhibit the potential market. While performing various operations, power consumption and efficiency is an important issue with the comfort level of user. The combination of embedded technology and IOT is represented by using E-controller which is the appropriate one for system's energy consumption and efficiency experiments with size factor. The main objective of the system is real time information and data monitoring of energy consumption. The proposed system introduces the implementation of IOT using embedded technology to simplistic the peripheral circuit and to lower the power consumption, thereby providing a high quality solution for a Smart Hostel Management and Information system.
Keywords
Internet of Things (IOT), PIC 16F877A, E-Metering, HTTP Protocol, LAMP Web Technology.References
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- Automatic Monitoring of Soil Moisture and Controlling of Irrigation System
Authors
1 Department of EEE, Kumaraguru College of Technology, Coimbatore, IN
Source
International Journal of Advanced Networking and Applications, Vol 9, No 6 (2018), Pagination: 3658-3662Abstract
In past couple of decades, there is immediate growth in field of agricultural technology. Utilization of proper method of irrigation by drip is very reasonable and proficient. A various drip irrigation methods have been proposed, but they have been found to be very luxurious and dense to use. The farmer has to maintain watch on irrigation schedule in the conventional drip irrigation system, which is different for different types of crops. In remotely monitored embedded system for irrigation purposes have become a new essential for farmer to accumulate his energy, time and money and will take place only when there will be requirement of water. In this approach, the soil test for chemical constituents, water content, and salinity and fertilizer requirement data collected by wireless and processed for better drip irrigation plan. This paper reviews different monitoring systems and proposes an automatic monitoring system model using Wireless Sensor Network (WSN) which helps the farmer to improve the yield.Keywords
Drip Irrigation, Data Logger, Fertilizer, Hotspot, Multiplexer, Remote Monitoring, Soil, Sensors, ZigBee.References
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