Abstract
Wireless sensor networks (WSNs) consist of a large number of small devices or nodes, called micro controller units (MCUs) and located in homes and/or offices, to be operated through the internet from anywhere, making these devices smarter and more efficient. Quality of service routing is one of the critical challenges in WSNs, especially in surveillance systems. To improve the efficiency of the network, in this article we proposes a distributed learning fractal algorithm (DFLA) to design the control topology of a wireless sensor network (WSN), whose nodes are the MCUs distributed in a physical space and which are connected to share parameters of the sensors such as concentrations of , humidity, temperature within the space or adjustment of the intensity of light inside and outside the home or office. For this, we start defining the production rules of the L-systems to generate the Hilbert fractal, since these rules facilitate the generation of this fractal, which is a fill-space curve. Then, we model the optimization of a centralized control topology of WSNs and proposed a DFLA to find the best two nodes where a device can find the highly reliable link between these nodes. Thus, we propose a software defined network (SDN) with strong mobility since it can be reconfigured depending on the amount of nodes, also we employ a target coverage because distributed learning fractal algorithm (DLFA) only consider reliable links among devices. Finally, through laboratory tests and computer simulations, we demonstrate the effectiveness of our approach by means of a fractal routing in WSNs, by using a large amount of WSNs devices (from 16 to 64 sensors) for real time monitoring of different parameters, in order to make efficient WSNs and its application in a forthcoming Smart City.
Highlights
The fourth industrial revolution (4IR) will encompass a wide range of technologies that are fusing the physical, digital and biological aspects, transforming the way in which human beings live, work and interrelate
Mainstream topology, Selection of the hub MCU1 (t0 ), First approximation of the wireless sensor networks (WSNs) topology based on the Hilbert curve, Distributed learning fractal approximation of the WSN topology based on the Hilbert
In this article we used the systemic thinking to develop a distributed learning fractal algorithm (DLFA) for optimizing a central topology of a WSN, in order to extend the range transmission of a given WiFi network in an intelligent, adaptive and dynamic way when sharing of parameters under a swarm intelligence framework
Summary
The fourth industrial revolution (4IR) will encompass a wide range of technologies that are fusing the physical, digital and biological aspects, transforming the way in which human beings live, work and interrelate. Sensors 2019, 19, 1442 that will affect all disciplines, economies and industries, as is the case of robotics, artificial intelligence, nanotechnology, quantum computing, biotechnology, the internet of things (IoT), 3D printing and autonomous vehicles. Due to its great versatility, the AI can work in conjunction with the IoT, allowing devices or micro controller units (MCUs) that are part of wireless sensor networks (WSNs) to be able to collect, process, and share data of different nature that flows through the network. If that were not the idea and if we do not have to look for a single super-intelligent entity but something different, we can give a way to a collective intelligence as a distributed processing entity. An ant alone can not defend the colony or feed the queen, but many of them collaborate emerging as an intelligent entity
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