Abstract
Internet of things (IoT) devices heavily rely on wireless connectivity. There are intrinsic overlooked limitations such as reach, availability, security and safety vulnerabilities closely associated with wireless solutions. Wired connectivity is the alternative to tackle those issues, and optical fibers directly connecting IoT devices could provide them unique features such as huge bandwidth, long reach, signal integrity and high security grade for the transmitted information. Nevertheless, it can be prohibitive for IoT devices which are power hungry and have costly electrical-to-optical conversions. In this paper, first, a niche is identified for IoT over fiber (IoToF) based on fully passive optical solutions for long reach upstream of low data rate optical connectivity over dark fibers. Then, we proposed, implemented and characterized a prototype physical connectivity (PHY) based on fiber Bragg grating (FBG) low-cost acousto-optic modulation at IoT devices and respective optical edge-filtering as wavelength discriminator at the receiver. Finally, we performed an experimental demonstration of upstream data communication based on simple M-ary frequency-shift keying (FSK), with baud rate of 300 bps transmitted over 30 km range. In terms of data rate and reach for niche applications, IoToF can outperform traditional wireless technologies, such as Sigfox or LoRa. IoToF will enable monitoring urban areas with scarce and polluted spectrum, industrial areas requiring intrinsic safety, and upstreaming data from IoT devices in remote locations with unfavorable wireless propagation but with dark fibers available.
Highlights
The concept of the internet of things (IoT) is rapidly expanding its reach involving applications in different fields such as domotics, industry, healthcare, and smart cities [1,2,3,4]
This work made a case for IoT over fiber (IoToF) focusing on niche applications which require low data rates along extended reach links
A proper short framing link layer solution over IoToF physical connectivity (PHY) should be developed as future work
Summary
The concept of the internet of things (IoT) is rapidly expanding its reach involving applications in different fields such as domotics, industry, healthcare, and smart cities [1,2,3,4]. The original IoT concept appeared more than three decades ago, being used to combine people, processes and devices with communication technology to remotely exchange data for processing and management [5]. The term IoT was originally attributed to Kevin Ashton in 1999. In his definition, “internet” refers to Electronics 2019, 8, 359; doi:10.3390/electronics8030359 www.mdpi.com/journal/electronics. IoT can be considered as a global network, which allows the communication between human-to-human, human-to-things and things-to-things, each element with a unique identity [6]. Ubiquitous connectivity is an important challenge posed by IoT to communication infrastructures
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