Sensors for Sustainable Smart Cities: A Review

Antonio E. Mogro,Agostino M. Mangini,Mauricio A. Ramírez-Moreno,Michele Roccotelli,Diego A. Padilla-Reyes,Jurgen Mahlknecht,Subhas C. Mukhopadhyay,José Ignacio Huertas,Moisés García-Martínez,Mónica C. Hernández-Luna,Sajjad Keshtkar,Jorge de Jesús Lozoya-Santos,Blas L. Pérez-Henríquez,Rodrigo E. Peimbert-García,Edrick Ramos-López,Ricardo A. Ramírez-Mendoza

doi:10.3390/app11178198

Abstract

Experts confirm that 85% of the world’s population is expected to live in cities by 2050. Therefore, cities should be prepared to satisfy the needs of their citizens and provide the best services. The idea of a city of the future is commonly represented by the smart city, which is a more efficient system that optimizes its resources and services, through the use of monitoring and communication technology. Thus, one of the steps towards sustainability for cities around the world is to make a transition into smart cities. Here, sensors play an important role in the system, as they gather relevant information from the city, citizens, and the corresponding communication networks that transfer the information in real-time. Although the use of these sensors is diverse, their application can be categorized in six different groups: energy, health, mobility, security, water, and waste management. Based on these groups, this review presents an analysis of different sensors that are typically used in efforts toward creating smart cities. Insights about different applications and communication systems are provided, as well as the main opportunities and challenges faced when making a transition to a smart city. Ultimately, this process is not only about smart urban infrastructure, but more importantly about how these new sensing capabilities and digitization developments improve quality of life. Smarter communities are those that socialize, adapt, and invest through transparent and inclusive community engagement in these technologies based on local and regional societal needs and values. Cyber security disruptions and privacy remain chief vulnerabilities.

Highlights

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The ideal model of a smart city is based on the incorporation of the following subsystems and technologies: distributed energy generation [14], smart grids [15], smart metering [16], smart buildings [17], smart sensors [18], eMobility
The results showed that machine learning models based on the EEG recordings were able to predict with 85% accuracy, the cognitive performance of the students, and it could be used to identify unwanted conditions, such as mental fatigue, anxiety, and stress under different contexts in the healthcare sector

Summary

Introduction

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The use of these sensors is diverse, their application can be categorized in six different groups: energy, health, mobility, security, water, and waste management. Based on these groups, this review presents an analysis of different sensors that are typically used in efforts toward creating smart cities. Insights about different applications and communication systems are provided, as well as the main opportunities and challenges faced when making a transition to a smart city. This process is about smart urban infrastructure, but more importantly about how these new sensing capabilities and digitization developments improve quality of life

Objectives

Results

Conclusion