Your search keyword '"Umesh Chandra Samal"' showing total 2 results

1. I-SEP: An Improved Routing Protocol for Heterogeneous WSN for IoT-Based Environmental Monitoring

Author

Mohammad S. Khan, Sushanta Kumar Mohapatra, Mahmoud Daneshmand, Trupti Mayee Behera, Amir H. Gandomi, and Umesh Chandra Samal

Subjects

Routing protocol, Computer Networks and Communications, business.industry, Computer science, Heuristic (computer science), 020206 networking & telecommunications, Throughput, 02 engineering and technology, Computer Science Applications, Hardware and Architecture, Signal Processing, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Energy supply, Routing (electronic design automation), business, Cluster analysis, Wireless sensor network, Heterogeneous network, Information Systems, Computer network

Abstract

Wireless sensor networks (WSNs) is a virtual layer in the paradigm of the Internet of Things (IoT). It inter-relates information associated with the physical domain to the IoT drove computational systems. WSN provides an ubiquitous access to location, the status of different entities of the environment, and data acquisition for long-term IoT monitoring. Since energy is a major constraint in the design process of a WSN, recent advances have led to project various energy-efficient protocols. Routing of data involves energy expenditure in considerable amount. In recent times, various heuristic clustering protocols have been discussed to solve the purpose. This article is an improvement of the existing stable election protocol (SEP) that implements a threshold-based cluster head (CH) selection for a heterogeneous network. The threshold maintains uniform energy distribution between member and CH nodes. The sensor nodes are also categorized into three different types called normal, intermediate, and advanced depending on the initial energy supply to distribute the network load evenly. The simulation result shows that the proposed scheme outperforms SEP and DEEC protocols with an improvement of 300% in network lifetime and 56% in throughput.

Published

2020

2. Residual Energy-Based Cluster-Head Selection in WSNs for IoT Application

Author

Umesh Chandra Samal, Trupti Mayee Behera, Mahmoud Daneshmand, Mohammad S. Khan, Sushanta Kumar Mohapatra, and Amir H. Gandomi

Subjects

Computer Networks and Communications, Computer science, Distributed computing, 020206 networking & telecommunications, Throughput, 02 engineering and technology, Energy consumption, Computer Science Applications, Power (physics), Transducer, Hardware and Architecture, Signal Processing, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Cluster analysis, Protocol (object-oriented programming), Wireless sensor network, Energy (signal processing), Information Systems

Abstract

Wireless sensor networks (WSNs) groups specialized transducers that provide sensing services to Internet of Things (IoT) devices with limited energy and storage resources. Since replacement or recharging of batteries in sensor nodes is almost impossible, power consumption becomes one of the crucial design issues in WSN. Clustering algorithm plays an important role in power conservation for the energy constrained network. Choosing a cluster head (CH) can appropriately balance the load in the network thereby reducing energy consumption and enhancing lifetime. This paper focuses on an efficient CH election scheme that rotates the CH position among the nodes with higher energy level as compared to other. The algorithm considers initial energy, residual energy, and an optimum value of CHs to elect the next group of CHs for the network that suits for IoT applications, such as environmental monitoring, smart cities, and systems. Simulation analysis shows the modified version performs better than the low energy adaptive clustering hierarchy protocol by enhancing the throughput by 60%, lifetime by 66%, and residual energy by 64%.

Published

2019