An Energy-Efficient Multiobjective Scheduling Model for Monitoring in Internet of Things

Mostafa, Basma; Benslimane, Abderrahim; Saleh, Mohamed; Kassem, Sally; Molnar, Miklos

doi:10.1109/jiot.2018.2792326

Cited by 26 publications

(11 citation statements)

References 44 publications

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“…The best quality channel in terms T of stability and reliability was assigned to the sensor nodes by proposing a channel management mechanism to achieve reliable intra-cluster reporting. Highly effective results were achieved which showed that this approach provided highly spectrum efficient mechanism and was also better that previously existing approaches Basma Mostafa, et.al (2018) proposed an III-phase mathematical model for handling the optimized scheduling within IoT networks [10]. The Vertex Cover Problem was solved iteratively in the initial phase to generate the different subsets of nodes which cover the complete graph.…”

Section: Cache Nodes 4 Channel Management Schemementioning

confidence: 99%

Performance Analysis of Cognitive Radio Based Internet-Of-Things Network for Energy Efficiency and Spectrum Utilization

2019

IJITEE

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Energy and Spectrum are the two basic requirements in the realm of Internet-of-Things (IoT). The network of IoT is becoming larger day by day and the design of spectrum and energy efficient solution is a quite challenging task because of the rapid increase of connecting devices in IoT network. To make the system more energy and spectral efficient, energy harvesting and cognitive radio (CR) are the proficient solutions, respectively. This paper introduces a spectral and energy efficient design for CR based sensor networks. We present a network architecture, in which nodes or other sensing devices can use the spectrum opportunistically and energy harvesting can be done from different ambient sources. We then propose an 1) energy alancing scheme for heterogeneous network in which nodes will have different energy levels and 2) Cluster head (CH) selection scheme which will only be performed on the few nodes of network having the highest current energy to accomplish the ultimate goal of energy balancing in network, this analysis is performed with in the cluster. Furthermore, for the spectral efficiency, we propose a channel management scheme based on cognitive radio to allot the best available channel having highest reliability in respect of the bit error rate (BER) using. Comprehensive results exhibit the effectiveness in the performance of the proposed spectral and energy efficient schemes and show better performance over other schemes.

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Section: Cache Nodes 4 Channel Management Schemementioning

confidence: 99%

Performance Analysis of Cognitive Radio Based Internet-Of-Things Network for Energy Efficiency and Spectrum Utilization

2019

IJITEE

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“…Our work is different from [30] in that our parameter tuning is at the network and application layers, while their parameter tuning is at the physical and MAC layers. In [31], the authors propose an energy-efficient multi-objective scheduling model for monitoring-based IoT networks. Their objective is to minimize energy consumption and communication overhead of monitoring for each node while considering link faults due to energy limitations.…”

Section: Related Workmentioning

confidence: 99%

“…Their work however only considers IoT networks operating on a generated destination oriented directed acyclic graph (DODAG). Also, unlike our work which considers faults due to security, hardware, and energy failures, their work [31] only considers faults due to energy limitations. Rango et al [32] analyze energy-aware communication between smart IoT monitoring devices.…”

Section: Related Workmentioning

confidence: 99%

“…j : This parameter reflects the security failure probability of node j at location x due to capture attacks (theft or device tampering so a device is compromised and does not perform the intended functions). It can be measured by the environmental cloud by leveraging Geographic Information System (GIS)-based crime mapping tools and applications [31], [32] which provide the number of incidents logged in a location x over a time period with which the security failure rate at a location can be derived. With the information of security failure rate for node j at location x known, the environmental cloud can parameterize comp x j as the insecurity of the sensor.…”

Section: Comp Xmentioning

confidence: 99%

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Optimizing the Lifetime of IoT-Based Star and Mesh Networks

et al. 2020

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In this paper, we propose and analyze a novel optimization model to maximize the lifetime of Internet-of-Things (IoT) networks, including the Low Power Wide-Area Network (LPWAN) based Sigfox star networks and Time Slotted Channel Hopping (TSCH) mesh networks. An IoT cloud manages the IoT network adapting to sensed phenomenon changes in the deployment area retrieved from peered cloud-based environmental monitoring systems. While increasing the number of paths for IoT devices to cloud communication increases reliability, it also comes at the expense of increased energy consumption. We consider an optimization problem to determine the best redundancy level to be applied in the IoT network such that the lifetime is maximized while achieving the quality-of-service (QoS) requirements in the presence of unreliable sensing environments. Our model is generic and easily adaptable to a given IoT technology by considering the technology's devices, environmental, and protocol specifications while spanning single-hop, multi-hop, short-range, and long-range IoT technologies. We formulate the tradeoff between energy conservation vs. reliability of an IoT network as an Integer Non-Linear Programming (INLP) optimization problem. The feasibility of our approach in maximizing the lifetime of IoT networks for both the star and mesh network topologies is demonstrated using SigFox and TSCH as representative technologies, respectively. We conduct an extensive comparative performance analysis demonstrating that our model outperforms contemporary baseline models in both SigFox and TSCH IoT network technologies.

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“…The sensor network is a large-scale and self-organized sensing network which could achieve the information world integration and the physical world integration [1,2,3,4,5]. The deployment of this network is achieved by densely and randomly deploying the nodes which are in the monitoring area, while the sensor nodes behavior is mainly characterized by: a certain degree of computation, communication, storage and control ability, which could accomplish the collection, communication, computation, and storage of the information from the physical world [6,7,8,9]. The high-speed visual sensors are adopted by this work.…”

Section: Introductionmentioning

confidence: 99%

CMTN-SP: A Novel Coverage-Control Algorithm for Moving-Target Nodes Based on Sensing Probability Model in Sensor Networks

Sun

Xing

Yan

et al. 2019

Sensors

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The non-consecutive coverage problem for the target nodes in Sensor Networks could lead to the coverage blind area and a large amount of redundant data, which causes the bottleneck phenomenon for the communication link. A novel Coverage Control Algorithm for Moving Target Nodes Based on Sensing Probability Model (CMTN-SP) is proposed in this work. Firstly, according to the probability theory, we derive the calculation method for the expectation of the coverage quality with multiple joint nodes, which aims to reduce the coverage blind area and improving network coverage rate. Secondly, we employ the dynamic transferring mechanism of the nodes to re-optimize the deployment of the nodes, which alleviates the rapid exhaustion of the proper network energy. Finally, it is verified via the results of the simulation that the network coverage quality could not only be improved by the proposed algorithm, but the proposed algorithm could also effectively curb the rapid exhaustion of the node energy.

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An Energy-Efficient Multiobjective Scheduling Model for Monitoring in Internet of Things

Cited by 26 publications

References 44 publications

Performance Analysis of Cognitive Radio Based Internet-Of-Things Network for Energy Efficiency and Spectrum Utilization

Performance Analysis of Cognitive Radio Based Internet-Of-Things Network for Energy Efficiency and Spectrum Utilization

Optimizing the Lifetime of IoT-Based Star and Mesh Networks

CMTN-SP: A Novel Coverage-Control Algorithm for Moving-Target Nodes Based on Sensing Probability Model in Sensor Networks

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