My T. Thai scite author profile

Abstract-A critical aspect of applications with wireless sensor networks is network lifetime. Power-constrained wireless sensor networks are usable as long as they can communicate sensed data to a processing node. Sensing and communications consume energy, therefore judicious power management and sensor scheduling can effectively extend network lifetime. To cover a set of targets with known locations when ground access in the remote area is prohibited, one solution is to deploy the sensors remotely, from an aircraft. The lack of precise sensor placement is compensated by a large sensor population deployed in the drop zone, that would improve the probability of target coverage. The data collected from the sensors is sent to a central node (e.g. cluster head) for processing.In this paper we propose an efficient method to extend the sensor network life time by organizing the sensors into a maximal number of set covers that are activated successively. Only the sensors from the current active set are responsible for monitoring all targets and for transmitting the collected data, while all other nodes are in a low-energy sleep mode. By allowing sensors to participate in multiple sets, our problem formulation increases the network lifetime compared with related work [2], that has the additional requirements of sensor sets being disjoint and operating equal time intervals. In this paper we model the solution as the maximum set covers problem and design two heuristics that efficiently compute the sets, using linear programming and a greedy approach. Simulation results are presented to verify our approaches.

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AI and Blockchain: A Disruptive Integration

Dinh

2018

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Adaptive algorithms for detecting community structure in dynamic social networks

et al. 2011

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Social networks exhibit a very special property: community structure. Understanding the network community structure is of great advantages. It not only provides helpful information in developing more social-aware strategies for social network problems but also promises a wide range of applications enabled by mobile networking, such as routings in Mobile Ad Hoc Networks (MANETs) and worm containments in cellular networks. Unfortunately, understanding this structure is very challenging, especially in dynamic social networks where social activities and interactions are evolving rapidly. Can we quickly and efficiently identify the network community structure? Can we adaptively update the network structure based on previously known information instead of recomputing from scratch?In this paper, we present Quick Community Adaptation (QCA), an adaptive modularity-based method for identifying and tracing community structure of dynamic online social networks. Our approach has not only the power of quickly and efficiently updating network communities, through a series of changes, by only using the structures identified from previous network snapshots, but also the ability of tracing the evolution of community structure over time. To illustrate the effectiveness of our algorithm, we extensively test QCA on real-world dynamic social networks including ENRON email network, arXiv e-print citation network and Facebook network. Finally, we demonstrate the bright applicability of our algorithm via a realistic application on routing strategies in MANETs. The comparative results reveal that social-aware routing strategies employing QCA as a community detection core outperform current available methods.

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On greedy construction of connected dominating sets in wireless networks

Thai

Wang

et al. 2005

Wireless Communications

168

114

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Due to the fact that there is no fixed infrastructure or centralized management in ad hoc wireless networks, a Connected Dominating Set (CDS) of the graph representing the network is widely used as the virtual backbone of the network. Constructing a minimum CDS is NP-hard. In this paper, we propose a completely localized distributed algorithm which is r-CDS to construct a CDS with constant performance ratio. Our algorithm is better at maintenance since there is no need to build a tree or select a leader which are the common methods used in most of the distributed but serialized algorithms. We also compare our algorithm with other localized algorithms. The theoretical and simulation results show that our algorithm has a better performance ratio and constructs a CDS with smaller size in most cases.

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Detecting Critical Nodes in Interdependent Power Networks for Vulnerability Assessment

Nguyen

Shen

Thai

2013

IEEE Trans. Smart Grid

247

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My T. Thai

Energy-efficient target coverage in wireless sensor networks

AI and Blockchain: A Disruptive Integration

Adaptive algorithms for detecting community structure in dynamic social networks

On greedy construction of connected dominating sets in wireless networks

Detecting Critical Nodes in Interdependent Power Networks for Vulnerability Assessment

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