key: cord-0056630-yh559ftv
authors: Ahmad, Ishfaq
title: Discover Internet of Things editorial, inaugural issue: Welcome from Editor-in-Chief
date: 2021-02-24
journal: Discov Internet Things
DOI: 10.1007/s43926-021-00007-6
sha: c4e1059e08fb3395169904bb124148fde55ffa3a
doc_id: 56630
cord_uid: yh559ftv

nan

us to an era wherein cyber, physical, social, and psychological spaces are integrated with greater harmony. This implies more natural machine-human interfaces, greater access to information, and improved decision making.

This staggering technological expansion brings with it profound economic and social implications as well as promising research opportunities and challenges. New research directions, development of knowledgebase, and training a new IT workforce are imminently desirable. IoT applications generate massive amounts of data in a variety of formats. Storage and analysis of the data require efficient, effective and secure data analytics algorithms. Tools using machine learning and other advanced techniques are required. In cloud-oriented IoT systems, sensory data is extracted, accumulated, and processed at cloud data centers, leading to prohibitively high latencies. Fog/edge computing circumvents this problem by providing real-time support through efficient utilization of proximity based computational resources across the IoT layers such as gateways, cloudlets, and switches/routers. To support evolving IoT applications, large-centralized cloud computing infrastructures are migrating to micro datacenters located at the network's edge. This is leading to the escalation of the so called fog and edge computing paradigms that aim to utilize edge resources to off load computation which would normally have been carried out at the cloud data center to a resource that is closer to users or edge devices. Fog/ Edge computing aims to improve the agility of cloud service deployments in addition to bringing computing resources closer to end-users.

In the realm of transportation, communication via IoT-connected automated vehicles is poised to be a game changer for the transportation industry. Almost all sorts of vehicles, ranging from automated trucks to buses and shared passenger cars, are expected to benefit from such applications at various scales. In most applications, vehicles can decide their maneuvers and services using their on-board sensors, such as cameras, and radars. However, their surrounding environments cannot be discovered by their on-board sensors alone. Their efficient passage requires not only current traffic support substructures (such as, road-side message boards, traffic lights etc.), but also advanced communication mechanisms providing access to vast and dynamic information. These can help to mitigate traffic bottlenecks, reduce fuel costs, and enhance environmental sustainability.

In sports and entertainment, we are witnessing innovating gaming mechanisms, delivery of video and music as well as new means entertainment. Similarly, in commerce and trade, we want the results of complex data analytics (e.g. realestate, stock market and other investment tools) available in real-time on our cell phones. IoT-based applications are sorely needed in agriculture, manufacturing, wearable devices, energy and power, and driverless vehicles. The issue of data privacy and security, of course, must be an integral component these infrastructures.

The emergence of IoT coupled with fog/edge computing is leading to considerably greater computer system development. This includes engineering of scalable architectures, moving from closed systems to open systems, new operating systems, middleware, communication protocols, autonomic management, and addressing privacy and ethical issues involved in data sensing, storage, processing, and decision-making. Machine learning, deep learning, and artificial intelligence techniques are being widely explored for enhancing the scalability, reliability, and quality-of-service in the IoT applications. New extensions are required for current programming models that will allow developers to conceive and design novel applications to take advantage of the new paradigms. These challenges are prompting researchers to create knowledge that requires new avenues of publishing, sharing, and dissemination.

Discover IoT is among the Discover Journals series by Springer, which is a collection of fully open access journals committed to providing all authors a streamlined submission process, rapid review and publication, and a high level of author service at every stage. This new Series of OA journals from Springer Nature was announced in June 2020. The series will consist of up to 40 new titles covering hot topics from across the full range of applied science, physical, life, medical and social disciplines. More information about the Discover Series can be found here: www.sprin ger.com/gp/ campa ign/disco ver-journ als.

Discover IoT aims to publish original research papers in a variety of areas pertinent to IoT. The goal is to take advantage of new ideas about online data sharing and efficient publication tools designed to promptly present to its readers the state-of-the-art, addressing all parts of the value chain from concepts at the component, software, and system level as well as programming, operating systems, applications and other technology-oriented research topics. Discover IoT will publish a wide range of papers, survey articles, and comments that deal with all research areas of importance to experts, researchers, teachers, practitioners, engineers, and students. Thus, the journal will enable research communities across the globe to share their findings and ideas in the fast expanding field of IoT.

I am pleased to state that Discover IoT has gathered a very prestigious editorial board, with members hailing from around the world. In particular, one can notice that Discover IoT is very supportive of diversity (race, country, gender, etc.). There are six Associate Editors, representing six sub-sections (indicated in the parenthesis) given as follows: Our editorial board also includes editors who are well-known researchers. I am thankful to all section editors and editorial board members for their willingness and commitment to serve the editorial mission of Discover IoT. The list of colleagues who have joined us in this endeavor is available at https ://www.sprin ger.com/journ al/43926 /edito rs.

In addition, we are honored to have an advisory board, which comprises of highly respected researchers and academicians from around the world. They are: I am highly thankful to the Discover IoT staff, especially Sweater Shi, and the Springer Management. I sincerely thank Toby Charkin, Publishing Director at Springer, for recognizing the potential of this journal and for providing the necessary support to turn it into a reality.

Maintaining a high standard of paper review and quality and being at the forefront of scientific discovery and innovation are the prime aims of Discover IoT. As such, we will need to reach several milestones, including publishing high-quality papers with a rapid turnaround time, supporting cutting-edge research topics through topical issues, and encouraging multi-disciplinary themes.

Discover IoT is off to a good start. We have regular papers under review, and six topical collections are currently planned (while more are in the pipeline). The six collections are: The papers in the inaugural issue, published as a topical collection, were submitted by invitation. They were authored by leading experts in the field. We have five invited papers from these world-class researchers. A brief description of these follows:

• "Intelligent IoT Systems for Civil Infrastructure Monitoring: A Research Roadmap, " authored by Elisa Bertino, Mohammad Jahanshahi, Ankush Singla, and Rih-Teng Wu, provides a details perspective on using AI for IoT-based civil infrastructures [1] . • "QoE in IoT: A Vision, Survey and Future Directions," authored by Kaneez Fizza, Abhik Banerjee, Karan Mitra, Prem Prakash Jayaraman, Rajiv Ranjan, Pankesh Patel, and Dimitrios Georgakopoulos, addresses the notion of Quality-of-Experience, which can be a key factor for quality control and decision making in autonomic IoT applications [2] . • "Swarm-based Counter UAV Defense System, " authored by Matthias Brust, Grégoire Danoy, Daniel Stolfi, and Pascal

Bouvry. It gives a comprehensive overview of how to design a safety-and security-ensuring network of unmanned aerial vehicles [3] .

• ""Chatty Devices" and Edge-based Activity Classification," authored by Mike Lakoju, Amir Javed, Omer Rana, Peter Burnap, Samuelson Atiba, and Soumaya Cherkaoui, discusses human-man robot interaction in a manufacturing environment, touching upon critical research challenges [4] . • "Things in the Air: Tagging Wearable IoT Information on Drone Videos, " authored by Lan-Da Van, Ling-Yan Zhang, Chun-Hao Chang, Kit-Lun Tong, Kun-Ru Wu, and Yu-Chee Tseng, describes a surveillance system which employs drones that interact with wearable IoT devices for person identification. We expect to add one or two more papers in the inaugural issue [5] .

I hope that Discover IoT develops into a community where we realize and acknowledge the progress of knowledge in the IoT revolution. Let us work together on growing and strengthening this community for sharing new knowledge. Please feel free to contact us if you have any thoughts or suggestions that can help us do our job better.

Author' contributions Author's contribution is not applicable. The author read and approved the final manuscript.

The authors declare that they have no competing interests.

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Intelligent IoT systems for civil infrastructure monitoring: a research roadmap

QoE in IoT: a vision, survey and future directions

Swarm-based counter UAV defense system

Chatty devices" and edge-based activity classification

Things in the air: tagging wearable IoT information on drone videos