The Use of Internet of Things for Smart Cities

Jaime Lloret Mauri

Instituto de Investigación para la Gestión Integrada de Zonas Costeras, Universitat Politecnica de Valencia, Spain

jlloret@dcom.upv.es

Keywords: Internet of Things, Sensors, Smart Cities, Communication Protocols, Artificial Intelligence.

Abstract: This paper includes the information for the keynote speech of Jaime Lloret.

1 INTRODUCTION

Recent advances in new technologies jointly with

the appearance of low cost sensors with computing

and communication capacities have made possible to

implement new systems to improve citizens daylife.

Although the main constraints of Wireless Sensor

Networks are the power consumption and the

computing capacity (Sendra, 2011)(Azizi, 2016),

their flexibility and adaptability make them very

useful for any type of environment (Lloret,

2009)(Khaleeq, 2016). Data networks are evolving

towards the transport of large amounts of

information from sensor networks and the Internet of

Things (IoT). Through IoT, we can monitor and

control many sensors and devices, with the aim of

collecting information and acting on them. IoT

allows monitoring from everywhere at any time.

Technological advances, the implementation of

future fifth generation (5G) mobile networks and the

reduction of manufacturing costs of IoT devices

have boosted their use growth in a wide variety of

applications.

In order to build smart city, it is required three

basic components (see Figure 1):

• Sensors and (Wireless) Sensor Networks

• Communication Protocols and Algorithms

• Artificial Intelligence applied to Big Data

Figure 2 shows that sensors and internet of things

gather data from urban environments, so network

protocols, algorithms and architectures are required

to provide the most updated data in a big database.

The knowledge acquired by these sensors can be

tackled in order to improve the electric consumption,

the water wastage and even any type of lakes in gas,

electricity or water. Big data and artificial

intelligence techniques can be used to optimize the

resources of the cities and improve their

performance.

Figure 1: Basic IoT components to build a Smart City.

Lloret Mauri J.

The Use of Internet of Things for Smart Cities.

DOI: 10.5220/0007239600000000

In Proceedings of the 8th International Joint Conference on Pervasive and Embedded Computing and Communication Systems (PECCS 2018), pages 15-18

ISBN: 978-989-758-322-3

Figure 2: Information exchange between basic elements when using IoT for smart Cities.

2 SENSORS AND (WIRELESS)

SENSOR NETWORKS

Along the years, the hardware technology to develop

sensors and wireless sensor networks have evolved

hugely. In about 10 years, sensor node deployments

with few KBytes of Flash Memory and just 11 Mbps

of data transfer rate (e.g. XPort and Matchport

(Martchport, 2018), from Lantronicx, Figure 3), to

some hundreds of Kbytes 5 years ago (e.g. Flyport

(Flyport, 2018) and Waspmote (Waspmote, 2018),

Figure 4).

Currently, Arduino (Arduino, 2018) and

raspberry Pi (Raspberry, 2018) platforms are

allowing a wide range of applications because of

their low cost, computing capacity, modularity, and

flexibility. Figure 5 shows Arduino Mega 2560 and

Raspberry Pi 3.

Figure 3: XPort and Matchport, from Lantronix.

Figure 4: Flyport and Waspmote (Libelium).

Figure 5: Arduino Mega 2560 and Raspberry Pi 3.

3 COMMUNICATION

PROTOCOLS AND

ALGORITHMS

In order to deliver the collected data from the

sensors to a database one or several communication

technologies are required. The connectivity from IoT

can be from anywhere at any time (Lopez, 2017).

Moreover, some specific protocols are needed for

data, message frequency and alarms. The choice of

the technology depends on multiple factors such as

the type of data, the field of deployment, economical

aspect, etc. The amount of protocols that can be used

is high. Moreover, it is increasing constantly. Some

of them are well known communication standards,

and others are proprietary and developed exclusively

for water or electricity metering. They provide two-

way communications with the IoT, allowing sending

commands from the database to the smart meter for

multiple purposes, including monitor real time

values and change the frequency of readings among

others (Lloret, 2016). Communication protocols for

IoT should allow the network management,

improving their ability to operate autonomously,

flexibly and robustly.

Given the information obtained through IoT, it is

necessary to classify and differentiate the flows with

the objective of offering an appropriate treatment to

the priority and the relevance of the information

managed. Moreover, IoT must face aspects related to

privacy and information security. Furthermore,

network infrastructures require mechanisms and

protocols to discriminate the different needs of IoT

data.

4 ARTIFICIAL INTELLIGENCE

APPLIED TO BIG DATA

The amount of data collected from a single

environment could be huge (Bakhshad et al, 2018).

There must be one or several databases deployed in

the smart city to facilitate the process of saving and

treating high volume of data. Once the data has been

saved in a database, it is very important to use the

most powerful techniques to extract the useful data

from it. Given a series of inputs the system has to be

able to detect certain circumstances that require any

type of intervention. Here is where artificial

intelligence (AI) is required. Techniques such as

artificial neural networks or inductive inference

methods, that are able to anticipate the future based

on past observed data, are used (Hernández et al.,

2014). Machine learning employs statistical

techniques with the goal of enabling machines to

understand the set of data. AI can be applied to a

wide variety of sensor data and environments.

Moreover, the traffic generated by the IoT

devices must be determined and integrated into

different types of flows. Based on this information,

there should be a prioritization criteria and traffic

safety levels corresponding to each flow in order to

be able to be properly treated by the network

devices. Machine learning / deep learning techniques

can be used to apply the traffic classification criteria.

AI algorithms can be responsible for determining the

required Quality of Service (QoS) parameters and

priorities in order to make modifications to the

network device configurations required at each

instant and for each type of specific traffic flow. An

example of an algorithm that takes into account the

aforementioned issues is shown in Figure 6.

Figure 6: Algorithm that takes into account sensor data

and traffic behavior to perform actions in the network.

5 CONCLUSIONS

The amount of technology introduced in the cities is

growing hugely. The sensor devices are cheaper,

smaller and with higher computing capacity, which

allow them to be used to gather data from a wide

variety of environments. Wireless technologies

allow higher data transfer rates at higher distances

and the communication protocols are quite more

robust than years ago. All these issues are

facilitating the deployment of many IoT devices to

collect the data used by AI techniques to achieve a

smarter city.

ACKNOWLEDGEMENTS

This work has been partially supported by the

"Ministerio de Economía y Competitividad" in the

"Programa Estatal de Fomento de la Investigación

Científica y Técnica de Excelencia, Subprograma

Estatal de Generación de Conocimiento" within the

project under Grant TIN2017-84802-C2-1-P.

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